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cosmopolitan/third_party/sqlite3/fts5.c
Justine Tunney 06f9a5b627
Get repository to build with GCC 11 
See #594
2022-09-13 04:14:55 -07:00

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#include "libc/assert.h"
#include "libc/assert.h"
#include "libc/math.h"
#include "libc/stdio/stdio.h"
#include "libc/str/str.h"
#include "third_party/sqlite3/sqlite3.h"
#include "third_party/sqlite3/sqlite3ext.h"
/* clang-format off */
#if !defined(SQLITE_CORE) || defined(SQLITE_ENABLE_FTS5)
#if !defined(NDEBUG) && !defined(SQLITE_DEBUG)
# define NDEBUG 1
#endif
#if defined(NDEBUG) && defined(SQLITE_DEBUG)
# undef NDEBUG
#endif
#line 1 "fts5.h"
/*
** 2014 May 31
**
** The author disclaims copyright to this source code. In place of
** a legal notice, here is a blessing:
**
** May you do good and not evil.
** May you find forgiveness for yourself and forgive others.
** May you share freely, never taking more than you give.
**
******************************************************************************
**
** Interfaces to extend FTS5. Using the interfaces defined in this file,
** FTS5 may be extended with:
**
** * custom tokenizers, and
** * custom auxiliary functions.
*/
#ifndef _FTS5_H
#define _FTS5_H
#ifdef __cplusplus
extern "C" {
#endif
/*************************************************************************
** CUSTOM AUXILIARY FUNCTIONS
**
** Virtual table implementations may overload SQL functions by implementing
** the sqlite3_module.xFindFunction() method.
*/
typedef struct Fts5ExtensionApi Fts5ExtensionApi;
typedef struct Fts5Context Fts5Context;
typedef struct Fts5PhraseIter Fts5PhraseIter;
typedef void (*fts5_extension_function)(
const Fts5ExtensionApi *pApi, /* API offered by current FTS version */
Fts5Context *pFts, /* First arg to pass to pApi functions */
sqlite3_context *pCtx, /* Context for returning result/error */
int nVal, /* Number of values in apVal[] array */
sqlite3_value **apVal /* Array of trailing arguments */
);
struct Fts5PhraseIter {
const unsigned char *a;
const unsigned char *b;
};
/*
** EXTENSION API FUNCTIONS
**
** xUserData(pFts):
** Return a copy of the context pointer the extension function was
** registered with.
**
** xColumnTotalSize(pFts, iCol, pnToken):
** If parameter iCol is less than zero, set output variable *pnToken
** to the total number of tokens in the FTS5 table. Or, if iCol is
** non-negative but less than the number of columns in the table, return
** the total number of tokens in column iCol, considering all rows in
** the FTS5 table.
**
** If parameter iCol is greater than or equal to the number of columns
** in the table, SQLITE_RANGE is returned. Or, if an error occurs (e.g.
** an OOM condition or IO error), an appropriate SQLite error code is
** returned.
**
** xColumnCount(pFts):
** Return the number of columns in the table.
**
** xColumnSize(pFts, iCol, pnToken):
** If parameter iCol is less than zero, set output variable *pnToken
** to the total number of tokens in the current row. Or, if iCol is
** non-negative but less than the number of columns in the table, set
** *pnToken to the number of tokens in column iCol of the current row.
**
** If parameter iCol is greater than or equal to the number of columns
** in the table, SQLITE_RANGE is returned. Or, if an error occurs (e.g.
** an OOM condition or IO error), an appropriate SQLite error code is
** returned.
**
** This function may be quite inefficient if used with an FTS5 table
** created with the "columnsize=0" option.
**
** xColumnText:
** This function attempts to retrieve the text of column iCol of the
** current document. If successful, (*pz) is set to point to a buffer
** containing the text in utf-8 encoding, (*pn) is set to the size in bytes
** (not characters) of the buffer and SQLITE_OK is returned. Otherwise,
** if an error occurs, an SQLite error code is returned and the final values
** of (*pz) and (*pn) are undefined.
**
** xPhraseCount:
** Returns the number of phrases in the current query expression.
**
** xPhraseSize:
** Returns the number of tokens in phrase iPhrase of the query. Phrases
** are numbered starting from zero.
**
** xInstCount:
** Set *pnInst to the total number of occurrences of all phrases within
** the query within the current row. Return SQLITE_OK if successful, or
** an error code (i.e. SQLITE_NOMEM) if an error occurs.
**
** This API can be quite slow if used with an FTS5 table created with the
** "detail=none" or "detail=column" option. If the FTS5 table is created
** with either "detail=none" or "detail=column" and "content=" option
** (i.e. if it is a contentless table), then this API always returns 0.
**
** xInst:
** Query for the details of phrase match iIdx within the current row.
** Phrase matches are numbered starting from zero, so the iIdx argument
** should be greater than or equal to zero and smaller than the value
** output by xInstCount().
**
** Usually, output parameter *piPhrase is set to the phrase number, *piCol
** to the column in which it occurs and *piOff the token offset of the
** first token of the phrase. Returns SQLITE_OK if successful, or an error
** code (i.e. SQLITE_NOMEM) if an error occurs.
**
** This API can be quite slow if used with an FTS5 table created with the
** "detail=none" or "detail=column" option.
**
** xRowid:
** Returns the rowid of the current row.
**
** xTokenize:
** Tokenize text using the tokenizer belonging to the FTS5 table.
**
** xQueryPhrase(pFts5, iPhrase, pUserData, xCallback):
** This API function is used to query the FTS table for phrase iPhrase
** of the current query. Specifically, a query equivalent to:
**
** ... FROM ftstable WHERE ftstable MATCH $p ORDER BY rowid
**
** with $p set to a phrase equivalent to the phrase iPhrase of the
** current query is executed. Any column filter that applies to
** phrase iPhrase of the current query is included in $p. For each
** row visited, the callback function passed as the fourth argument
** is invoked. The context and API objects passed to the callback
** function may be used to access the properties of each matched row.
** Invoking Api.xUserData() returns a copy of the pointer passed as
** the third argument to pUserData.
**
** If the callback function returns any value other than SQLITE_OK, the
** query is abandoned and the xQueryPhrase function returns immediately.
** If the returned value is SQLITE_DONE, xQueryPhrase returns SQLITE_OK.
** Otherwise, the error code is propagated upwards.
**
** If the query runs to completion without incident, SQLITE_OK is returned.
** Or, if some error occurs before the query completes or is aborted by
** the callback, an SQLite error code is returned.
**
**
** xSetAuxdata(pFts5, pAux, xDelete)
**
** Save the pointer passed as the second argument as the extension function's
** "auxiliary data". The pointer may then be retrieved by the current or any
** future invocation of the same fts5 extension function made as part of
** the same MATCH query using the xGetAuxdata() API.
**
** Each extension function is allocated a single auxiliary data slot for
** each FTS query (MATCH expression). If the extension function is invoked
** more than once for a single FTS query, then all invocations share a
** single auxiliary data context.
**
** If there is already an auxiliary data pointer when this function is
** invoked, then it is replaced by the new pointer. If an xDelete callback
** was specified along with the original pointer, it is invoked at this
** point.
**
** The xDelete callback, if one is specified, is also invoked on the
** auxiliary data pointer after the FTS5 query has finished.
**
** If an error (e.g. an OOM condition) occurs within this function,
** the auxiliary data is set to NULL and an error code returned. If the
** xDelete parameter was not NULL, it is invoked on the auxiliary data
** pointer before returning.
**
**
** xGetAuxdata(pFts5, bClear)
**
** Returns the current auxiliary data pointer for the fts5 extension
** function. See the xSetAuxdata() method for details.
**
** If the bClear argument is non-zero, then the auxiliary data is cleared
** (set to NULL) before this function returns. In this case the xDelete,
** if any, is not invoked.
**
**
** xRowCount(pFts5, pnRow)
**
** This function is used to retrieve the total number of rows in the table.
** In other words, the same value that would be returned by:
**
** SELECT count(*) FROM ftstable;
**
** xPhraseFirst()
** This function is used, along with type Fts5PhraseIter and the xPhraseNext
** method, to iterate through all instances of a single query phrase within
** the current row. This is the same information as is accessible via the
** xInstCount/xInst APIs. While the xInstCount/xInst APIs are more convenient
** to use, this API may be faster under some circumstances. To iterate
** through instances of phrase iPhrase, use the following code:
**
** Fts5PhraseIter iter;
** int iCol, iOff;
** for(pApi->xPhraseFirst(pFts, iPhrase, &iter, &iCol, &iOff);
** iCol>=0;
** pApi->xPhraseNext(pFts, &iter, &iCol, &iOff)
** ){
** // An instance of phrase iPhrase at offset iOff of column iCol
** }
**
** The Fts5PhraseIter structure is defined above. Applications should not
** modify this structure directly - it should only be used as shown above
** with the xPhraseFirst() and xPhraseNext() API methods (and by
** xPhraseFirstColumn() and xPhraseNextColumn() as illustrated below).
**
** This API can be quite slow if used with an FTS5 table created with the
** "detail=none" or "detail=column" option. If the FTS5 table is created
** with either "detail=none" or "detail=column" and "content=" option
** (i.e. if it is a contentless table), then this API always iterates
** through an empty set (all calls to xPhraseFirst() set iCol to -1).
**
** xPhraseNext()
** See xPhraseFirst above.
**
** xPhraseFirstColumn()
** This function and xPhraseNextColumn() are similar to the xPhraseFirst()
** and xPhraseNext() APIs described above. The difference is that instead
** of iterating through all instances of a phrase in the current row, these
** APIs are used to iterate through the set of columns in the current row
** that contain one or more instances of a specified phrase. For example:
**
** Fts5PhraseIter iter;
** int iCol;
** for(pApi->xPhraseFirstColumn(pFts, iPhrase, &iter, &iCol);
** iCol>=0;
** pApi->xPhraseNextColumn(pFts, &iter, &iCol)
** ){
** // Column iCol contains at least one instance of phrase iPhrase
** }
**
** This API can be quite slow if used with an FTS5 table created with the
** "detail=none" option. If the FTS5 table is created with either
** "detail=none" "content=" option (i.e. if it is a contentless table),
** then this API always iterates through an empty set (all calls to
** xPhraseFirstColumn() set iCol to -1).
**
** The information accessed using this API and its companion
** xPhraseFirstColumn() may also be obtained using xPhraseFirst/xPhraseNext
** (or xInst/xInstCount). The chief advantage of this API is that it is
** significantly more efficient than those alternatives when used with
** "detail=column" tables.
**
** xPhraseNextColumn()
** See xPhraseFirstColumn above.
*/
struct Fts5ExtensionApi {
int iVersion; /* Currently always set to 3 */
void *(*xUserData)(Fts5Context*);
int (*xColumnCount)(Fts5Context*);
int (*xRowCount)(Fts5Context*, sqlite3_int64 *pnRow);
int (*xColumnTotalSize)(Fts5Context*, int iCol, sqlite3_int64 *pnToken);
int (*xTokenize)(Fts5Context*,
const char *pText, int nText, /* Text to tokenize */
void *pCtx, /* Context passed to xToken() */
int (*xToken)(void*, int, const char*, int, int, int) /* Callback */
);
int (*xPhraseCount)(Fts5Context*);
int (*xPhraseSize)(Fts5Context*, int iPhrase);
int (*xInstCount)(Fts5Context*, int *pnInst);
int (*xInst)(Fts5Context*, int iIdx, int *piPhrase, int *piCol, int *piOff);
sqlite3_int64 (*xRowid)(Fts5Context*);
int (*xColumnText)(Fts5Context*, int iCol, const char **pz, int *pn);
int (*xColumnSize)(Fts5Context*, int iCol, int *pnToken);
int (*xQueryPhrase)(Fts5Context*, int iPhrase, void *pUserData,
int(*)(const Fts5ExtensionApi*,Fts5Context*,void*)
);
int (*xSetAuxdata)(Fts5Context*, void *pAux, void(*xDelete)(void*));
void *(*xGetAuxdata)(Fts5Context*, int bClear);
int (*xPhraseFirst)(Fts5Context*, int iPhrase, Fts5PhraseIter*, int*, int*);
void (*xPhraseNext)(Fts5Context*, Fts5PhraseIter*, int *piCol, int *piOff);
int (*xPhraseFirstColumn)(Fts5Context*, int iPhrase, Fts5PhraseIter*, int*);
void (*xPhraseNextColumn)(Fts5Context*, Fts5PhraseIter*, int *piCol);
};
/*
** CUSTOM AUXILIARY FUNCTIONS
*************************************************************************/
/*************************************************************************
** CUSTOM TOKENIZERS
**
** Applications may also register custom tokenizer types. A tokenizer
** is registered by providing fts5 with a populated instance of the
** following structure. All structure methods must be defined, setting
** any member of the fts5_tokenizer struct to NULL leads to undefined
** behaviour. The structure methods are expected to function as follows:
**
** xCreate:
** This function is used to allocate and initialize a tokenizer instance.
** A tokenizer instance is required to actually tokenize text.
**
** The first argument passed to this function is a copy of the (void*)
** pointer provided by the application when the fts5_tokenizer object
** was registered with FTS5 (the third argument to xCreateTokenizer()).
** The second and third arguments are an array of nul-terminated strings
** containing the tokenizer arguments, if any, specified following the
** tokenizer name as part of the CREATE VIRTUAL TABLE statement used
** to create the FTS5 table.
**
** The final argument is an output variable. If successful, (*ppOut)
** should be set to point to the new tokenizer handle and SQLITE_OK
** returned. If an error occurs, some value other than SQLITE_OK should
** be returned. In this case, fts5 assumes that the final value of *ppOut
** is undefined.
**
** xDelete:
** This function is invoked to delete a tokenizer handle previously
** allocated using xCreate(). Fts5 guarantees that this function will
** be invoked exactly once for each successful call to xCreate().
**
** xTokenize:
** This function is expected to tokenize the nText byte string indicated
** by argument pText. pText may or may not be nul-terminated. The first
** argument passed to this function is a pointer to an Fts5Tokenizer object
** returned by an earlier call to xCreate().
**
** The second argument indicates the reason that FTS5 is requesting
** tokenization of the supplied text. This is always one of the following
** four values:
**
** <ul><li> <b>FTS5_TOKENIZE_DOCUMENT</b> - A document is being inserted into
** or removed from the FTS table. The tokenizer is being invoked to
** determine the set of tokens to add to (or delete from) the
** FTS index.
**
** <li> <b>FTS5_TOKENIZE_QUERY</b> - A MATCH query is being executed
** against the FTS index. The tokenizer is being called to tokenize
** a bareword or quoted string specified as part of the query.
**
** <li> <b>(FTS5_TOKENIZE_QUERY | FTS5_TOKENIZE_PREFIX)</b> - Same as
** FTS5_TOKENIZE_QUERY, except that the bareword or quoted string is
** followed by a "*" character, indicating that the last token
** returned by the tokenizer will be treated as a token prefix.
**
** <li> <b>FTS5_TOKENIZE_AUX</b> - The tokenizer is being invoked to
** satisfy an fts5_api.xTokenize() request made by an auxiliary
** function. Or an fts5_api.xColumnSize() request made by the same
** on a columnsize=0 database.
** </ul>
**
** For each token in the input string, the supplied callback xToken() must
** be invoked. The first argument to it should be a copy of the pointer
** passed as the second argument to xTokenize(). The third and fourth
** arguments are a pointer to a buffer containing the token text, and the
** size of the token in bytes. The 4th and 5th arguments are the byte offsets
** of the first byte of and first byte immediately following the text from
** which the token is derived within the input.
**
** The second argument passed to the xToken() callback ("tflags") should
** normally be set to 0. The exception is if the tokenizer supports
** synonyms. In this case see the discussion below for details.
**
** FTS5 assumes the xToken() callback is invoked for each token in the
** order that they occur within the input text.
**
** If an xToken() callback returns any value other than SQLITE_OK, then
** the tokenization should be abandoned and the xTokenize() method should
** immediately return a copy of the xToken() return value. Or, if the
** input buffer is exhausted, xTokenize() should return SQLITE_OK. Finally,
** if an error occurs with the xTokenize() implementation itself, it
** may abandon the tokenization and return any error code other than
** SQLITE_OK or SQLITE_DONE.
**
** SYNONYM SUPPORT
**
** Custom tokenizers may also support synonyms. Consider a case in which a
** user wishes to query for a phrase such as "first place". Using the
** built-in tokenizers, the FTS5 query 'first + place' will match instances
** of "first place" within the document set, but not alternative forms
** such as "1st place". In some applications, it would be better to match
** all instances of "first place" or "1st place" regardless of which form
** the user specified in the MATCH query text.
**
** There are several ways to approach this in FTS5:
**
** <ol><li> By mapping all synonyms to a single token. In this case, using
** the above example, this means that the tokenizer returns the
** same token for inputs "first" and "1st". Say that token is in
** fact "first", so that when the user inserts the document "I won
** 1st place" entries are added to the index for tokens "i", "won",
** "first" and "place". If the user then queries for '1st + place',
** the tokenizer substitutes "first" for "1st" and the query works
** as expected.
**
** <li> By querying the index for all synonyms of each query term
** separately. In this case, when tokenizing query text, the
** tokenizer may provide multiple synonyms for a single term
** within the document. FTS5 then queries the index for each
** synonym individually. For example, faced with the query:
**
** <codeblock>
** ... MATCH 'first place'</codeblock>
**
** the tokenizer offers both "1st" and "first" as synonyms for the
** first token in the MATCH query and FTS5 effectively runs a query
** similar to:
**
** <codeblock>
** ... MATCH '(first OR 1st) place'</codeblock>
**
** except that, for the purposes of auxiliary functions, the query
** still appears to contain just two phrases - "(first OR 1st)"
** being treated as a single phrase.
**
** <li> By adding multiple synonyms for a single term to the FTS index.
** Using this method, when tokenizing document text, the tokenizer
** provides multiple synonyms for each token. So that when a
** document such as "I won first place" is tokenized, entries are
** added to the FTS index for "i", "won", "first", "1st" and
** "place".
**
** This way, even if the tokenizer does not provide synonyms
** when tokenizing query text (it should not - to do so would be
** inefficient), it doesn't matter if the user queries for
** 'first + place' or '1st + place', as there are entries in the
** FTS index corresponding to both forms of the first token.
** </ol>
**
** Whether it is parsing document or query text, any call to xToken that
** specifies a <i>tflags</i> argument with the FTS5_TOKEN_COLOCATED bit
** is considered to supply a synonym for the previous token. For example,
** when parsing the document "I won first place", a tokenizer that supports
** synonyms would call xToken() 5 times, as follows:
**
** <codeblock>
** xToken(pCtx, 0, "i", 1, 0, 1);
** xToken(pCtx, 0, "won", 3, 2, 5);
** xToken(pCtx, 0, "first", 5, 6, 11);
** xToken(pCtx, FTS5_TOKEN_COLOCATED, "1st", 3, 6, 11);
** xToken(pCtx, 0, "place", 5, 12, 17);
**</codeblock>
**
** It is an error to specify the FTS5_TOKEN_COLOCATED flag the first time
** xToken() is called. Multiple synonyms may be specified for a single token
** by making multiple calls to xToken(FTS5_TOKEN_COLOCATED) in sequence.
** There is no limit to the number of synonyms that may be provided for a
** single token.
**
** In many cases, method (1) above is the best approach. It does not add
** extra data to the FTS index or require FTS5 to query for multiple terms,
** so it is efficient in terms of disk space and query speed. However, it
** does not support prefix queries very well. If, as suggested above, the
** token "first" is substituted for "1st" by the tokenizer, then the query:
**
** <codeblock>
** ... MATCH '1s*'</codeblock>
**
** will not match documents that contain the token "1st" (as the tokenizer
** will probably not map "1s" to any prefix of "first").
**
** For full prefix support, method (3) may be preferred. In this case,
** because the index contains entries for both "first" and "1st", prefix
** queries such as 'fi*' or '1s*' will match correctly. However, because
** extra entries are added to the FTS index, this method uses more space
** within the database.
**
** Method (2) offers a midpoint between (1) and (3). Using this method,
** a query such as '1s*' will match documents that contain the literal
** token "1st", but not "first" (assuming the tokenizer is not able to
** provide synonyms for prefixes). However, a non-prefix query like '1st'
** will match against "1st" and "first". This method does not require
** extra disk space, as no extra entries are added to the FTS index.
** On the other hand, it may require more CPU cycles to run MATCH queries,
** as separate queries of the FTS index are required for each synonym.
**
** When using methods (2) or (3), it is important that the tokenizer only
** provide synonyms when tokenizing document text (method (2)) or query
** text (method (3)), not both. Doing so will not cause any errors, but is
** inefficient.
*/
typedef struct Fts5Tokenizer Fts5Tokenizer;
typedef struct fts5_tokenizer fts5_tokenizer;
struct fts5_tokenizer {
int (*xCreate)(void*, const char **azArg, int nArg, Fts5Tokenizer **ppOut);
void (*xDelete)(Fts5Tokenizer*);
int (*xTokenize)(Fts5Tokenizer*,
void *pCtx,
int flags, /* Mask of FTS5_TOKENIZE_* flags */
const char *pText, int nText,
int (*xToken)(
void *pCtx, /* Copy of 2nd argument to xTokenize() */
int tflags, /* Mask of FTS5_TOKEN_* flags */
const char *pToken, /* Pointer to buffer containing token */
int nToken, /* Size of token in bytes */
int iStart, /* Byte offset of token within input text */
int iEnd /* Byte offset of end of token within input text */
)
);
};
/* Flags that may be passed as the third argument to xTokenize() */
#define FTS5_TOKENIZE_QUERY 0x0001
#define FTS5_TOKENIZE_PREFIX 0x0002
#define FTS5_TOKENIZE_DOCUMENT 0x0004
#define FTS5_TOKENIZE_AUX 0x0008
/* Flags that may be passed by the tokenizer implementation back to FTS5
** as the third argument to the supplied xToken callback. */
#define FTS5_TOKEN_COLOCATED 0x0001 /* Same position as prev. token */
/*
** END OF CUSTOM TOKENIZERS
*************************************************************************/
/*************************************************************************
** FTS5 EXTENSION REGISTRATION API
*/
typedef struct fts5_api fts5_api;
struct fts5_api {
int iVersion; /* Currently always set to 2 */
/* Create a new tokenizer */
int (*xCreateTokenizer)(
fts5_api *pApi,
const char *zName,
void *pContext,
fts5_tokenizer *pTokenizer,
void (*xDestroy)(void*)
);
/* Find an existing tokenizer */
int (*xFindTokenizer)(
fts5_api *pApi,
const char *zName,
void **ppContext,
fts5_tokenizer *pTokenizer
);
/* Create a new auxiliary function */
int (*xCreateFunction)(
fts5_api *pApi,
const char *zName,
void *pContext,
fts5_extension_function xFunction,
void (*xDestroy)(void*)
);
};
/*
** END OF REGISTRATION API
*************************************************************************/
#ifdef __cplusplus
} /* end of the 'extern "C"' block */
#endif
#endif /* _FTS5_H */
#line 1 "fts5Int.h"
/*
** 2014 May 31
**
** The author disclaims copyright to this source code. In place of
** a legal notice, here is a blessing:
**
** May you do good and not evil.
** May you find forgiveness for yourself and forgive others.
** May you share freely, never taking more than you give.
**
******************************************************************************
**
*/
#ifndef _FTS5INT_H
#define _FTS5INT_H
SQLITE_EXTENSION_INIT1
#ifndef SQLITE_AMALGAMATION
typedef unsigned char u8;
typedef unsigned int u32;
typedef unsigned short u16;
typedef short i16;
typedef sqlite3_int64 i64;
typedef sqlite3_uint64 u64;
#ifndef ArraySize
# define ArraySize(x) ((int)(sizeof(x) / sizeof(x[0])))
#endif
#define testcase(x)
#define ALWAYS(x) 1
#define NEVER(x) 0
#define MIN(x,y) (((x) < (y)) ? (x) : (y))
#define MAX(x,y) (((x) > (y)) ? (x) : (y))
/*
** Constants for the largest and smallest possible 64-bit signed integers.
*/
# define LARGEST_INT64 (0xffffffff|(((i64)0x7fffffff)<<32))
# define SMALLEST_INT64 (((i64)-1) - LARGEST_INT64)
#endif
/* Truncate very long tokens to this many bytes. Hard limit is
** (65536-1-1-4-9)==65521 bytes. The limiting factor is the 16-bit offset
** field that occurs at the start of each leaf page (see fts5_index.c). */
#define FTS5_MAX_TOKEN_SIZE 32768
/*
** Maximum number of prefix indexes on single FTS5 table. This must be
** less than 32. If it is set to anything large than that, an #error
** directive in fts5_index.c will cause the build to fail.
*/
#define FTS5_MAX_PREFIX_INDEXES 31
/*
** Maximum segments permitted in a single index
*/
#define FTS5_MAX_SEGMENT 2000
#define FTS5_DEFAULT_NEARDIST 10
#define FTS5_DEFAULT_RANK "bm25"
/* Name of rank and rowid columns */
#define FTS5_RANK_NAME "rank"
#define FTS5_ROWID_NAME "rowid"
#ifdef SQLITE_DEBUG
# define FTS5_CORRUPT sqlite3Fts5Corrupt()
static int sqlite3Fts5Corrupt(void);
#else
# define FTS5_CORRUPT SQLITE_CORRUPT_VTAB
#endif
/*
** The assert_nc() macro is similar to the assert() macro, except that it
** is used for assert() conditions that are true only if it can be
** guranteed that the database is not corrupt.
*/
#ifdef SQLITE_DEBUG
extern int sqlite3_fts5_may_be_corrupt;
# define assert_nc(x) assert(sqlite3_fts5_may_be_corrupt || (x))
#else
# define assert_nc(x) assert(x)
#endif
/*
** A version of memcmp() that does not cause asan errors if one of the pointer
** parameters is NULL and the number of bytes to compare is zero.
*/
#define fts5Memcmp(s1, s2, n) ((n)==0 ? 0 : memcmp((s1), (s2), (n)))
/* Mark a function parameter as unused, to suppress nuisance compiler
** warnings. */
#ifndef UNUSED_PARAM
# define UNUSED_PARAM(X) (void)(X)
#endif
#ifndef UNUSED_PARAM2
# define UNUSED_PARAM2(X, Y) (void)(X), (void)(Y)
#endif
typedef struct Fts5Global Fts5Global;
typedef struct Fts5Colset Fts5Colset;
/* If a NEAR() clump or phrase may only match a specific set of columns,
** then an object of the following type is used to record the set of columns.
** Each entry in the aiCol[] array is a column that may be matched.
**
** This object is used by fts5_expr.c and fts5_index.c.
*/
struct Fts5Colset {
int nCol;
int aiCol[1];
};
/**************************************************************************
** Interface to code in fts5_config.c. fts5_config.c contains contains code
** to parse the arguments passed to the CREATE VIRTUAL TABLE statement.
*/
typedef struct Fts5Config Fts5Config;
/*
** An instance of the following structure encodes all information that can
** be gleaned from the CREATE VIRTUAL TABLE statement.
**
** And all information loaded from the %_config table.
**
** nAutomerge:
** The minimum number of segments that an auto-merge operation should
** attempt to merge together. A value of 1 sets the object to use the
** compile time default. Zero disables auto-merge altogether.
**
** zContent:
**
** zContentRowid:
** The value of the content_rowid= option, if one was specified. Or
** the string "rowid" otherwise. This text is not quoted - if it is
** used as part of an SQL statement it needs to be quoted appropriately.
**
** zContentExprlist:
**
** pzErrmsg:
** This exists in order to allow the fts5_index.c module to return a
** decent error message if it encounters a file-format version it does
** not understand.
**
** bColumnsize:
** True if the %_docsize table is created.
**
** bPrefixIndex:
** This is only used for debugging. If set to false, any prefix indexes
** are ignored. This value is configured using:
**
** INSERT INTO tbl(tbl, rank) VALUES('prefix-index', $bPrefixIndex);
**
*/
struct Fts5Config {
sqlite3 *db; /* Database handle */
char *zDb; /* Database holding FTS index (e.g. "main") */
char *zName; /* Name of FTS index */
int nCol; /* Number of columns */
char **azCol; /* Column names */
u8 *abUnindexed; /* True for unindexed columns */
int nPrefix; /* Number of prefix indexes */
int *aPrefix; /* Sizes in bytes of nPrefix prefix indexes */
int eContent; /* An FTS5_CONTENT value */
char *zContent; /* content table */
char *zContentRowid; /* "content_rowid=" option value */
int bColumnsize; /* "columnsize=" option value (dflt==1) */
int eDetail; /* FTS5_DETAIL_XXX value */
char *zContentExprlist;
Fts5Tokenizer *pTok;
fts5_tokenizer *pTokApi;
int bLock; /* True when table is preparing statement */
int ePattern; /* FTS_PATTERN_XXX constant */
/* Values loaded from the %_config table */
int iCookie; /* Incremented when %_config is modified */
int pgsz; /* Approximate page size used in %_data */
int nAutomerge; /* 'automerge' setting */
int nCrisisMerge; /* Maximum allowed segments per level */
int nUsermerge; /* 'usermerge' setting */
int nHashSize; /* Bytes of memory for in-memory hash */
char *zRank; /* Name of rank function */
char *zRankArgs; /* Arguments to rank function */
/* If non-NULL, points to sqlite3_vtab.base.zErrmsg. Often NULL. */
char **pzErrmsg;
#ifdef SQLITE_DEBUG
int bPrefixIndex; /* True to use prefix-indexes */
#endif
};
/* Current expected value of %_config table 'version' field */
#define FTS5_CURRENT_VERSION 4
#define FTS5_CONTENT_NORMAL 0
#define FTS5_CONTENT_NONE 1
#define FTS5_CONTENT_EXTERNAL 2
#define FTS5_DETAIL_FULL 0
#define FTS5_DETAIL_NONE 1
#define FTS5_DETAIL_COLUMNS 2
#define FTS5_PATTERN_NONE 0
#define FTS5_PATTERN_LIKE 65 /* matches SQLITE_INDEX_CONSTRAINT_LIKE */
#define FTS5_PATTERN_GLOB 66 /* matches SQLITE_INDEX_CONSTRAINT_GLOB */
static int sqlite3Fts5ConfigParse(
Fts5Global*, sqlite3*, int, const char **, Fts5Config**, char**
);
static void sqlite3Fts5ConfigFree(Fts5Config*);
static int sqlite3Fts5ConfigDeclareVtab(Fts5Config *pConfig);
static int sqlite3Fts5Tokenize(
Fts5Config *pConfig, /* FTS5 Configuration object */
int flags, /* FTS5_TOKENIZE_* flags */
const char *pText, int nText, /* Text to tokenize */
void *pCtx, /* Context passed to xToken() */
int (*xToken)(void*, int, const char*, int, int, int) /* Callback */
);
static void sqlite3Fts5Dequote(char *z);
/* Load the contents of the %_config table */
static int sqlite3Fts5ConfigLoad(Fts5Config*, int);
/* Set the value of a single config attribute */
static int sqlite3Fts5ConfigSetValue(Fts5Config*, const char*, sqlite3_value*, int*);
static int sqlite3Fts5ConfigParseRank(const char*, char**, char**);
/*
** End of interface to code in fts5_config.c.
**************************************************************************/
/**************************************************************************
** Interface to code in fts5_buffer.c.
*/
/*
** Buffer object for the incremental building of string data.
*/
typedef struct Fts5Buffer Fts5Buffer;
struct Fts5Buffer {
u8 *p;
int n;
int nSpace;
};
static int sqlite3Fts5BufferSize(int*, Fts5Buffer*, u32);
static void sqlite3Fts5BufferAppendVarint(int*, Fts5Buffer*, i64);
static void sqlite3Fts5BufferAppendBlob(int*, Fts5Buffer*, u32, const u8*);
static void sqlite3Fts5BufferAppendString(int *, Fts5Buffer*, const char*);
static void sqlite3Fts5BufferFree(Fts5Buffer*);
static void sqlite3Fts5BufferZero(Fts5Buffer*);
static void sqlite3Fts5BufferSet(int*, Fts5Buffer*, int, const u8*);
static void sqlite3Fts5BufferAppendPrintf(int *, Fts5Buffer*, char *zFmt, ...);
static char *sqlite3Fts5Mprintf(int *pRc, const char *zFmt, ...);
#define fts5BufferZero(x) sqlite3Fts5BufferZero(x)
#define fts5BufferAppendVarint(a,b,c) sqlite3Fts5BufferAppendVarint(a,b,c)
#define fts5BufferFree(a) sqlite3Fts5BufferFree(a)
#define fts5BufferAppendBlob(a,b,c,d) sqlite3Fts5BufferAppendBlob(a,b,c,d)
#define fts5BufferSet(a,b,c,d) sqlite3Fts5BufferSet(a,b,c,d)
#define fts5BufferGrow(pRc,pBuf,nn) ( \
(u32)((pBuf)->n) + (u32)(nn) <= (u32)((pBuf)->nSpace) ? 0 : \
sqlite3Fts5BufferSize((pRc),(pBuf),(nn)+(pBuf)->n) \
)
/* Write and decode big-endian 32-bit integer values */
static void sqlite3Fts5Put32(u8*, int);
static int sqlite3Fts5Get32(const u8*);
#define FTS5_POS2COLUMN(iPos) (int)(iPos >> 32)
#define FTS5_POS2OFFSET(iPos) (int)(iPos & 0x7FFFFFFF)
typedef struct Fts5PoslistReader Fts5PoslistReader;
struct Fts5PoslistReader {
/* Variables used only by sqlite3Fts5PoslistIterXXX() functions. */
const u8 *a; /* Position list to iterate through */
int n; /* Size of buffer at a[] in bytes */
int i; /* Current offset in a[] */
u8 bFlag; /* For client use (any custom purpose) */
/* Output variables */
u8 bEof; /* Set to true at EOF */
i64 iPos; /* (iCol<<32) + iPos */
};
static int sqlite3Fts5PoslistReaderInit(
const u8 *a, int n, /* Poslist buffer to iterate through */
Fts5PoslistReader *pIter /* Iterator object to initialize */
);
static int sqlite3Fts5PoslistReaderNext(Fts5PoslistReader*);
typedef struct Fts5PoslistWriter Fts5PoslistWriter;
struct Fts5PoslistWriter {
i64 iPrev;
};
static int sqlite3Fts5PoslistWriterAppend(Fts5Buffer*, Fts5PoslistWriter*, i64);
static void sqlite3Fts5PoslistSafeAppend(Fts5Buffer*, i64*, i64);
static int sqlite3Fts5PoslistNext64(
const u8 *a, int n, /* Buffer containing poslist */
int *pi, /* IN/OUT: Offset within a[] */
i64 *piOff /* IN/OUT: Current offset */
);
/* Malloc utility */
static void *sqlite3Fts5MallocZero(int *pRc, sqlite3_int64 nByte);
static char *sqlite3Fts5Strndup(int *pRc, const char *pIn, int nIn);
/* Character set tests (like isspace(), isalpha() etc.) */
static int sqlite3Fts5IsBareword(char t);
/* Bucket of terms object used by the integrity-check in offsets=0 mode. */
typedef struct Fts5Termset Fts5Termset;
static int sqlite3Fts5TermsetNew(Fts5Termset**);
static int sqlite3Fts5TermsetAdd(Fts5Termset*, int, const char*, int, int *pbPresent);
static void sqlite3Fts5TermsetFree(Fts5Termset*);
/*
** End of interface to code in fts5_buffer.c.
**************************************************************************/
/**************************************************************************
** Interface to code in fts5_index.c. fts5_index.c contains contains code
** to access the data stored in the %_data table.
*/
typedef struct Fts5Index Fts5Index;
typedef struct Fts5IndexIter Fts5IndexIter;
struct Fts5IndexIter {
i64 iRowid;
const u8 *pData;
int nData;
u8 bEof;
};
#define sqlite3Fts5IterEof(x) ((x)->bEof)
/*
** Values used as part of the flags argument passed to IndexQuery().
*/
#define FTS5INDEX_QUERY_PREFIX 0x0001 /* Prefix query */
#define FTS5INDEX_QUERY_DESC 0x0002 /* Docs in descending rowid order */
#define FTS5INDEX_QUERY_TEST_NOIDX 0x0004 /* Do not use prefix index */
#define FTS5INDEX_QUERY_SCAN 0x0008 /* Scan query (fts5vocab) */
/* The following are used internally by the fts5_index.c module. They are
** defined here only to make it easier to avoid clashes with the flags
** above. */
#define FTS5INDEX_QUERY_SKIPEMPTY 0x0010
#define FTS5INDEX_QUERY_NOOUTPUT 0x0020
/*
** Create/destroy an Fts5Index object.
*/
static int sqlite3Fts5IndexOpen(Fts5Config *pConfig, int bCreate, Fts5Index**, char**);
static int sqlite3Fts5IndexClose(Fts5Index *p);
/*
** Return a simple checksum value based on the arguments.
*/
static u64 sqlite3Fts5IndexEntryCksum(
i64 iRowid,
int iCol,
int iPos,
int iIdx,
const char *pTerm,
int nTerm
);
/*
** Argument p points to a buffer containing utf-8 text that is n bytes in
** size. Return the number of bytes in the nChar character prefix of the
** buffer, or 0 if there are less than nChar characters in total.
*/
static int sqlite3Fts5IndexCharlenToBytelen(
const char *p,
int nByte,
int nChar
);
/*
** Open a new iterator to iterate though all rowids that match the
** specified token or token prefix.
*/
static int sqlite3Fts5IndexQuery(
Fts5Index *p, /* FTS index to query */
const char *pToken, int nToken, /* Token (or prefix) to query for */
int flags, /* Mask of FTS5INDEX_QUERY_X flags */
Fts5Colset *pColset, /* Match these columns only */
Fts5IndexIter **ppIter /* OUT: New iterator object */
);
/*
** The various operations on open token or token prefix iterators opened
** using sqlite3Fts5IndexQuery().
*/
static int sqlite3Fts5IterNext(Fts5IndexIter*);
static int sqlite3Fts5IterNextFrom(Fts5IndexIter*, i64 iMatch);
/*
** Close an iterator opened by sqlite3Fts5IndexQuery().
*/
static void sqlite3Fts5IterClose(Fts5IndexIter*);
/*
** Close the reader blob handle, if it is open.
*/
static void sqlite3Fts5IndexCloseReader(Fts5Index*);
/*
** This interface is used by the fts5vocab module.
*/
static const char *sqlite3Fts5IterTerm(Fts5IndexIter*, int*);
static int sqlite3Fts5IterNextScan(Fts5IndexIter*);
/*
** Insert or remove data to or from the index. Each time a document is
** added to or removed from the index, this function is called one or more
** times.
**
** For an insert, it must be called once for each token in the new document.
** If the operation is a delete, it must be called (at least) once for each
** unique token in the document with an iCol value less than zero. The iPos
** argument is ignored for a delete.
*/
static int sqlite3Fts5IndexWrite(
Fts5Index *p, /* Index to write to */
int iCol, /* Column token appears in (-ve -> delete) */
int iPos, /* Position of token within column */
const char *pToken, int nToken /* Token to add or remove to or from index */
);
/*
** Indicate that subsequent calls to sqlite3Fts5IndexWrite() pertain to
** document iDocid.
*/
static int sqlite3Fts5IndexBeginWrite(
Fts5Index *p, /* Index to write to */
int bDelete, /* True if current operation is a delete */
i64 iDocid /* Docid to add or remove data from */
);
/*
** Flush any data stored in the in-memory hash tables to the database.
** Also close any open blob handles.
*/
static int sqlite3Fts5IndexSync(Fts5Index *p);
/*
** Discard any data stored in the in-memory hash tables. Do not write it
** to the database. Additionally, assume that the contents of the %_data
** table may have changed on disk. So any in-memory caches of %_data
** records must be invalidated.
*/
static int sqlite3Fts5IndexRollback(Fts5Index *p);
/*
** Get or set the "averages" values.
*/
static int sqlite3Fts5IndexGetAverages(Fts5Index *p, i64 *pnRow, i64 *anSize);
static int sqlite3Fts5IndexSetAverages(Fts5Index *p, const u8*, int);
/*
** Functions called by the storage module as part of integrity-check.
*/
static int sqlite3Fts5IndexIntegrityCheck(Fts5Index*, u64 cksum, int bUseCksum);
/*
** Called during virtual module initialization to register UDF
** fts5_decode() with SQLite
*/
static int sqlite3Fts5IndexInit(sqlite3*);
static int sqlite3Fts5IndexSetCookie(Fts5Index*, int);
/*
** Return the total number of entries read from the %_data table by
** this connection since it was created.
*/
static int sqlite3Fts5IndexReads(Fts5Index *p);
static int sqlite3Fts5IndexReinit(Fts5Index *p);
static int sqlite3Fts5IndexOptimize(Fts5Index *p);
static int sqlite3Fts5IndexMerge(Fts5Index *p, int nMerge);
static int sqlite3Fts5IndexReset(Fts5Index *p);
static int sqlite3Fts5IndexLoadConfig(Fts5Index *p);
/*
** End of interface to code in fts5_index.c.
**************************************************************************/
/**************************************************************************
** Interface to code in fts5_varint.c.
*/
static int sqlite3Fts5GetVarint32(const unsigned char *p, u32 *v);
static int sqlite3Fts5GetVarintLen(u32 iVal);
static u8 sqlite3Fts5GetVarint(const unsigned char*, u64*);
static int sqlite3Fts5PutVarint(unsigned char *p, u64 v);
#define fts5GetVarint32(a,b) sqlite3Fts5GetVarint32(a,(u32*)&b)
#define fts5GetVarint sqlite3Fts5GetVarint
#define fts5FastGetVarint32(a, iOff, nVal) { \
nVal = (a)[iOff++]; \
if( nVal & 0x80 ){ \
iOff--; \
iOff += fts5GetVarint32(&(a)[iOff], nVal); \
} \
}
/*
** End of interface to code in fts5_varint.c.
**************************************************************************/
/**************************************************************************
** Interface to code in fts5_main.c.
*/
/*
** Virtual-table object.
*/
typedef struct Fts5Table Fts5Table;
struct Fts5Table {
sqlite3_vtab base; /* Base class used by SQLite core */
Fts5Config *pConfig; /* Virtual table configuration */
Fts5Index *pIndex; /* Full-text index */
};
static int sqlite3Fts5GetTokenizer(
Fts5Global*,
const char **azArg,
int nArg,
Fts5Config*,
char **pzErr
);
static Fts5Table *sqlite3Fts5TableFromCsrid(Fts5Global*, i64);
static int sqlite3Fts5FlushToDisk(Fts5Table*);
/*
** End of interface to code in fts5.c.
**************************************************************************/
/**************************************************************************
** Interface to code in fts5_hash.c.
*/
typedef struct Fts5Hash Fts5Hash;
/*
** Create a hash table, free a hash table.
*/
static int sqlite3Fts5HashNew(Fts5Config*, Fts5Hash**, int *pnSize);
static void sqlite3Fts5HashFree(Fts5Hash*);
static int sqlite3Fts5HashWrite(
Fts5Hash*,
i64 iRowid, /* Rowid for this entry */
int iCol, /* Column token appears in (-ve -> delete) */
int iPos, /* Position of token within column */
char bByte,
const char *pToken, int nToken /* Token to add or remove to or from index */
);
/*
** Empty (but do not delete) a hash table.
*/
static void sqlite3Fts5HashClear(Fts5Hash*);
static int sqlite3Fts5HashQuery(
Fts5Hash*, /* Hash table to query */
int nPre,
const char *pTerm, int nTerm, /* Query term */
void **ppObj, /* OUT: Pointer to doclist for pTerm */
int *pnDoclist /* OUT: Size of doclist in bytes */
);
static int sqlite3Fts5HashScanInit(
Fts5Hash*, /* Hash table to query */
const char *pTerm, int nTerm /* Query prefix */
);
static void sqlite3Fts5HashScanNext(Fts5Hash*);
static int sqlite3Fts5HashScanEof(Fts5Hash*);
static void sqlite3Fts5HashScanEntry(Fts5Hash *,
const char **pzTerm, /* OUT: term (nul-terminated) */
const u8 **ppDoclist, /* OUT: pointer to doclist */
int *pnDoclist /* OUT: size of doclist in bytes */
);
/*
** End of interface to code in fts5_hash.c.
**************************************************************************/
/**************************************************************************
** Interface to code in fts5_storage.c. fts5_storage.c contains contains
** code to access the data stored in the %_content and %_docsize tables.
*/
#define FTS5_STMT_SCAN_ASC 0 /* SELECT rowid, * FROM ... ORDER BY 1 ASC */
#define FTS5_STMT_SCAN_DESC 1 /* SELECT rowid, * FROM ... ORDER BY 1 DESC */
#define FTS5_STMT_LOOKUP 2 /* SELECT rowid, * FROM ... WHERE rowid=? */
typedef struct Fts5Storage Fts5Storage;
static int sqlite3Fts5StorageOpen(Fts5Config*, Fts5Index*, int, Fts5Storage**, char**);
static int sqlite3Fts5StorageClose(Fts5Storage *p);
static int sqlite3Fts5StorageRename(Fts5Storage*, const char *zName);
static int sqlite3Fts5DropAll(Fts5Config*);
static int sqlite3Fts5CreateTable(Fts5Config*, const char*, const char*, int, char **);
static int sqlite3Fts5StorageDelete(Fts5Storage *p, i64, sqlite3_value**);
static int sqlite3Fts5StorageContentInsert(Fts5Storage *p, sqlite3_value**, i64*);
static int sqlite3Fts5StorageIndexInsert(Fts5Storage *p, sqlite3_value**, i64);
static int sqlite3Fts5StorageIntegrity(Fts5Storage *p, int iArg);
static int sqlite3Fts5StorageStmt(Fts5Storage *p, int eStmt, sqlite3_stmt**, char**);
static void sqlite3Fts5StorageStmtRelease(Fts5Storage *p, int eStmt, sqlite3_stmt*);
static int sqlite3Fts5StorageDocsize(Fts5Storage *p, i64 iRowid, int *aCol);
static int sqlite3Fts5StorageSize(Fts5Storage *p, int iCol, i64 *pnAvg);
static int sqlite3Fts5StorageRowCount(Fts5Storage *p, i64 *pnRow);
static int sqlite3Fts5StorageSync(Fts5Storage *p);
static int sqlite3Fts5StorageRollback(Fts5Storage *p);
static int sqlite3Fts5StorageConfigValue(
Fts5Storage *p, const char*, sqlite3_value*, int
);
static int sqlite3Fts5StorageDeleteAll(Fts5Storage *p);
static int sqlite3Fts5StorageRebuild(Fts5Storage *p);
static int sqlite3Fts5StorageOptimize(Fts5Storage *p);
static int sqlite3Fts5StorageMerge(Fts5Storage *p, int nMerge);
static int sqlite3Fts5StorageReset(Fts5Storage *p);
/*
** End of interface to code in fts5_storage.c.
**************************************************************************/
/**************************************************************************
** Interface to code in fts5_expr.c.
*/
typedef struct Fts5Expr Fts5Expr;
typedef struct Fts5ExprNode Fts5ExprNode;
typedef struct Fts5Parse Fts5Parse;
typedef struct Fts5Token Fts5Token;
typedef struct Fts5ExprPhrase Fts5ExprPhrase;
typedef struct Fts5ExprNearset Fts5ExprNearset;
struct Fts5Token {
const char *p; /* Token text (not NULL terminated) */
int n; /* Size of buffer p in bytes */
};
/* Parse a MATCH expression. */
static int sqlite3Fts5ExprNew(
Fts5Config *pConfig,
int bPhraseToAnd,
int iCol, /* Column on LHS of MATCH operator */
const char *zExpr,
Fts5Expr **ppNew,
char **pzErr
);
static int sqlite3Fts5ExprPattern(
Fts5Config *pConfig,
int bGlob,
int iCol,
const char *zText,
Fts5Expr **pp
);
/*
** for(rc = sqlite3Fts5ExprFirst(pExpr, pIdx, bDesc);
** rc==SQLITE_OK && 0==sqlite3Fts5ExprEof(pExpr);
** rc = sqlite3Fts5ExprNext(pExpr)
** ){
** // The document with rowid iRowid matches the expression!
** i64 iRowid = sqlite3Fts5ExprRowid(pExpr);
** }
*/
static int sqlite3Fts5ExprFirst(Fts5Expr*, Fts5Index *pIdx, i64 iMin, int bDesc);
static int sqlite3Fts5ExprNext(Fts5Expr*, i64 iMax);
static int sqlite3Fts5ExprEof(Fts5Expr*);
static i64 sqlite3Fts5ExprRowid(Fts5Expr*);
static void sqlite3Fts5ExprFree(Fts5Expr*);
static int sqlite3Fts5ExprAnd(Fts5Expr **pp1, Fts5Expr *p2);
/* Called during startup to register a UDF with SQLite */
static int sqlite3Fts5ExprInit(Fts5Global*, sqlite3*);
static int sqlite3Fts5ExprPhraseCount(Fts5Expr*);
static int sqlite3Fts5ExprPhraseSize(Fts5Expr*, int iPhrase);
static int sqlite3Fts5ExprPoslist(Fts5Expr*, int, const u8 **);
typedef struct Fts5PoslistPopulator Fts5PoslistPopulator;
static Fts5PoslistPopulator *sqlite3Fts5ExprClearPoslists(Fts5Expr*, int);
static int sqlite3Fts5ExprPopulatePoslists(
Fts5Config*, Fts5Expr*, Fts5PoslistPopulator*, int, const char*, int
);
static void sqlite3Fts5ExprCheckPoslists(Fts5Expr*, i64);
static int sqlite3Fts5ExprClonePhrase(Fts5Expr*, int, Fts5Expr**);
static int sqlite3Fts5ExprPhraseCollist(Fts5Expr *, int, const u8 **, int *);
/*******************************************
** The fts5_expr.c API above this point is used by the other hand-written
** C code in this module. The interfaces below this point are called by
** the parser code in fts5parse.y. */
static void sqlite3Fts5ParseError(Fts5Parse *pParse, const char *zFmt, ...);
static Fts5ExprNode *sqlite3Fts5ParseNode(
Fts5Parse *pParse,
int eType,
Fts5ExprNode *pLeft,
Fts5ExprNode *pRight,
Fts5ExprNearset *pNear
);
static Fts5ExprNode *sqlite3Fts5ParseImplicitAnd(
Fts5Parse *pParse,
Fts5ExprNode *pLeft,
Fts5ExprNode *pRight
);
static Fts5ExprPhrase *sqlite3Fts5ParseTerm(
Fts5Parse *pParse,
Fts5ExprPhrase *pPhrase,
Fts5Token *pToken,
int bPrefix
);
static void sqlite3Fts5ParseSetCaret(Fts5ExprPhrase*);
static Fts5ExprNearset *sqlite3Fts5ParseNearset(
Fts5Parse*,
Fts5ExprNearset*,
Fts5ExprPhrase*
);
static Fts5Colset *sqlite3Fts5ParseColset(
Fts5Parse*,
Fts5Colset*,
Fts5Token *
);
static void sqlite3Fts5ParsePhraseFree(Fts5ExprPhrase*);
static void sqlite3Fts5ParseNearsetFree(Fts5ExprNearset*);
static void sqlite3Fts5ParseNodeFree(Fts5ExprNode*);
static void sqlite3Fts5ParseSetDistance(Fts5Parse*, Fts5ExprNearset*, Fts5Token*);
static void sqlite3Fts5ParseSetColset(Fts5Parse*, Fts5ExprNode*, Fts5Colset*);
static Fts5Colset *sqlite3Fts5ParseColsetInvert(Fts5Parse*, Fts5Colset*);
static void sqlite3Fts5ParseFinished(Fts5Parse *pParse, Fts5ExprNode *p);
static void sqlite3Fts5ParseNear(Fts5Parse *pParse, Fts5Token*);
/*
** End of interface to code in fts5_expr.c.
**************************************************************************/
/**************************************************************************
** Interface to code in fts5_aux.c.
*/
static int sqlite3Fts5AuxInit(fts5_api*);
/*
** End of interface to code in fts5_aux.c.
**************************************************************************/
/**************************************************************************
** Interface to code in fts5_tokenizer.c.
*/
static int sqlite3Fts5TokenizerInit(fts5_api*);
static int sqlite3Fts5TokenizerPattern(
int (*xCreate)(void*, const char**, int, Fts5Tokenizer**),
Fts5Tokenizer *pTok
);
/*
** End of interface to code in fts5_tokenizer.c.
**************************************************************************/
/**************************************************************************
** Interface to code in fts5_vocab.c.
*/
static int sqlite3Fts5VocabInit(Fts5Global*, sqlite3*);
/*
** End of interface to code in fts5_vocab.c.
**************************************************************************/
/**************************************************************************
** Interface to automatically generated code in fts5_unicode2.c.
*/
static int sqlite3Fts5UnicodeIsdiacritic(int c);
static int sqlite3Fts5UnicodeFold(int c, int bRemoveDiacritic);
static int sqlite3Fts5UnicodeCatParse(const char*, u8*);
static int sqlite3Fts5UnicodeCategory(u32 iCode);
static void sqlite3Fts5UnicodeAscii(u8*, u8*);
/*
** End of interface to code in fts5_unicode2.c.
**************************************************************************/
#endif
#line 1 "fts5parse.h"
#define FTS5_OR 1
#define FTS5_AND 2
#define FTS5_NOT 3
#define FTS5_TERM 4
#define FTS5_COLON 5
#define FTS5_MINUS 6
#define FTS5_LCP 7
#define FTS5_RCP 8
#define FTS5_STRING 9
#define FTS5_LP 10
#define FTS5_RP 11
#define FTS5_CARET 12
#define FTS5_COMMA 13
#define FTS5_PLUS 14
#define FTS5_STAR 15
#line 1 "fts5parse.c"
/* This file is automatically generated by Lemon from input grammar
** source file "fts5parse.y". */
/*
** 2000-05-29
**
** The author disclaims copyright to this source code. In place of
** a legal notice, here is a blessing:
**
** May you do good and not evil.
** May you find forgiveness for yourself and forgive others.
** May you share freely, never taking more than you give.
**
*************************************************************************
** Driver template for the LEMON parser generator.
**
** The "lemon" program processes an LALR(1) input grammar file, then uses
** this template to construct a parser. The "lemon" program inserts text
** at each "%%" line. Also, any "P-a-r-s-e" identifer prefix (without the
** interstitial "-" characters) contained in this template is changed into
** the value of the %name directive from the grammar. Otherwise, the content
** of this template is copied straight through into the generate parser
** source file.
**
** The following is the concatenation of all %include directives from the
** input grammar file:
*/
/************ Begin %include sections from the grammar ************************/
#line 47 "fts5parse.y"
/*
** Disable all error recovery processing in the parser push-down
** automaton.
*/
#define fts5YYNOERRORRECOVERY 1
/*
** Make fts5yytestcase() the same as testcase()
*/
#define fts5yytestcase(X) testcase(X)
/*
** Indicate that sqlite3ParserFree() will never be called with a null
** pointer.
*/
#define fts5YYPARSEFREENOTNULL 1
/*
** Alternative datatype for the argument to the malloc() routine passed
** into sqlite3ParserAlloc(). The default is size_t.
*/
#define fts5YYMALLOCARGTYPE u64
#line 57 "fts5parse.c"
/**************** End of %include directives **********************************/
/* These constants specify the various numeric values for terminal symbols.
***************** Begin token definitions *************************************/
#ifndef FTS5_OR
#define FTS5_OR 1
#define FTS5_AND 2
#define FTS5_NOT 3
#define FTS5_TERM 4
#define FTS5_COLON 5
#define FTS5_MINUS 6
#define FTS5_LCP 7
#define FTS5_RCP 8
#define FTS5_STRING 9
#define FTS5_LP 10
#define FTS5_RP 11
#define FTS5_CARET 12
#define FTS5_COMMA 13
#define FTS5_PLUS 14
#define FTS5_STAR 15
#endif
/**************** End token definitions ***************************************/
/* The next sections is a series of control #defines.
** various aspects of the generated parser.
** fts5YYCODETYPE is the data type used to store the integer codes
** that represent terminal and non-terminal symbols.
** "unsigned char" is used if there are fewer than
** 256 symbols. Larger types otherwise.
** fts5YYNOCODE is a number of type fts5YYCODETYPE that is not used for
** any terminal or nonterminal symbol.
** fts5YYFALLBACK If defined, this indicates that one or more tokens
** (also known as: "terminal symbols") have fall-back
** values which should be used if the original symbol
** would not parse. This permits keywords to sometimes
** be used as identifiers, for example.
** fts5YYACTIONTYPE is the data type used for "action codes" - numbers
** that indicate what to do in response to the next
** token.
** sqlite3Fts5ParserFTS5TOKENTYPE is the data type used for minor type for terminal
** symbols. Background: A "minor type" is a semantic
** value associated with a terminal or non-terminal
** symbols. For example, for an "ID" terminal symbol,
** the minor type might be the name of the identifier.
** Each non-terminal can have a different minor type.
** Terminal symbols all have the same minor type, though.
** This macros defines the minor type for terminal
** symbols.
** fts5YYMINORTYPE is the data type used for all minor types.
** This is typically a union of many types, one of
** which is sqlite3Fts5ParserFTS5TOKENTYPE. The entry in the union
** for terminal symbols is called "fts5yy0".
** fts5YYSTACKDEPTH is the maximum depth of the parser's stack. If
** zero the stack is dynamically sized using realloc()
** sqlite3Fts5ParserARG_SDECL A static variable declaration for the %extra_argument
** sqlite3Fts5ParserARG_PDECL A parameter declaration for the %extra_argument
** sqlite3Fts5ParserARG_PARAM Code to pass %extra_argument as a subroutine parameter
** sqlite3Fts5ParserARG_STORE Code to store %extra_argument into fts5yypParser
** sqlite3Fts5ParserARG_FETCH Code to extract %extra_argument from fts5yypParser
** sqlite3Fts5ParserCTX_* As sqlite3Fts5ParserARG_ except for %extra_context
** fts5YYERRORSYMBOL is the code number of the error symbol. If not
** defined, then do no error processing.
** fts5YYNSTATE the combined number of states.
** fts5YYNRULE the number of rules in the grammar
** fts5YYNFTS5TOKEN Number of terminal symbols
** fts5YY_MAX_SHIFT Maximum value for shift actions
** fts5YY_MIN_SHIFTREDUCE Minimum value for shift-reduce actions
** fts5YY_MAX_SHIFTREDUCE Maximum value for shift-reduce actions
** fts5YY_ERROR_ACTION The fts5yy_action[] code for syntax error
** fts5YY_ACCEPT_ACTION The fts5yy_action[] code for accept
** fts5YY_NO_ACTION The fts5yy_action[] code for no-op
** fts5YY_MIN_REDUCE Minimum value for reduce actions
** fts5YY_MAX_REDUCE Maximum value for reduce actions
*/
#ifndef INTERFACE
# define INTERFACE 1
#endif
/************* Begin control #defines *****************************************/
#define fts5YYCODETYPE unsigned char
#define fts5YYNOCODE 27
#define fts5YYACTIONTYPE unsigned char
#define sqlite3Fts5ParserFTS5TOKENTYPE Fts5Token
typedef union {
int fts5yyinit;
sqlite3Fts5ParserFTS5TOKENTYPE fts5yy0;
int fts5yy4;
Fts5Colset* fts5yy11;
Fts5ExprNode* fts5yy24;
Fts5ExprNearset* fts5yy46;
Fts5ExprPhrase* fts5yy53;
} fts5YYMINORTYPE;
#ifndef fts5YYSTACKDEPTH
#define fts5YYSTACKDEPTH 100
#endif
#define sqlite3Fts5ParserARG_SDECL Fts5Parse *pParse;
#define sqlite3Fts5ParserARG_PDECL ,Fts5Parse *pParse
#define sqlite3Fts5ParserARG_PARAM ,pParse
#define sqlite3Fts5ParserARG_FETCH Fts5Parse *pParse=fts5yypParser->pParse;
#define sqlite3Fts5ParserARG_STORE fts5yypParser->pParse=pParse;
#define sqlite3Fts5ParserCTX_SDECL
#define sqlite3Fts5ParserCTX_PDECL
#define sqlite3Fts5ParserCTX_PARAM
#define sqlite3Fts5ParserCTX_FETCH
#define sqlite3Fts5ParserCTX_STORE
#define fts5YYNSTATE 35
#define fts5YYNRULE 28
#define fts5YYNRULE_WITH_ACTION 28
#define fts5YYNFTS5TOKEN 16
#define fts5YY_MAX_SHIFT 34
#define fts5YY_MIN_SHIFTREDUCE 52
#define fts5YY_MAX_SHIFTREDUCE 79
#define fts5YY_ERROR_ACTION 80
#define fts5YY_ACCEPT_ACTION 81
#define fts5YY_NO_ACTION 82
#define fts5YY_MIN_REDUCE 83
#define fts5YY_MAX_REDUCE 110
/************* End control #defines *******************************************/
#define fts5YY_NLOOKAHEAD ((int)(sizeof(fts5yy_lookahead)/sizeof(fts5yy_lookahead[0])))
/* Define the fts5yytestcase() macro to be a no-op if is not already defined
** otherwise.
**
** Applications can choose to define fts5yytestcase() in the %include section
** to a macro that can assist in verifying code coverage. For production
** code the fts5yytestcase() macro should be turned off. But it is useful
** for testing.
*/
#ifndef fts5yytestcase
# define fts5yytestcase(X)
#endif
/* Next are the tables used to determine what action to take based on the
** current state and lookahead token. These tables are used to implement
** functions that take a state number and lookahead value and return an
** action integer.
**
** Suppose the action integer is N. Then the action is determined as
** follows
**
** 0 <= N <= fts5YY_MAX_SHIFT Shift N. That is, push the lookahead
** token onto the stack and goto state N.
**
** N between fts5YY_MIN_SHIFTREDUCE Shift to an arbitrary state then
** and fts5YY_MAX_SHIFTREDUCE reduce by rule N-fts5YY_MIN_SHIFTREDUCE.
**
** N == fts5YY_ERROR_ACTION A syntax error has occurred.
**
** N == fts5YY_ACCEPT_ACTION The parser accepts its input.
**
** N == fts5YY_NO_ACTION No such action. Denotes unused
** slots in the fts5yy_action[] table.
**
** N between fts5YY_MIN_REDUCE Reduce by rule N-fts5YY_MIN_REDUCE
** and fts5YY_MAX_REDUCE
**
** The action table is constructed as a single large table named fts5yy_action[].
** Given state S and lookahead X, the action is computed as either:
**
** (A) N = fts5yy_action[ fts5yy_shift_ofst[S] + X ]
** (B) N = fts5yy_default[S]
**
** The (A) formula is preferred. The B formula is used instead if
** fts5yy_lookahead[fts5yy_shift_ofst[S]+X] is not equal to X.
**
** The formulas above are for computing the action when the lookahead is
** a terminal symbol. If the lookahead is a non-terminal (as occurs after
** a reduce action) then the fts5yy_reduce_ofst[] array is used in place of
** the fts5yy_shift_ofst[] array.
**
** The following are the tables generated in this section:
**
** fts5yy_action[] A single table containing all actions.
** fts5yy_lookahead[] A table containing the lookahead for each entry in
** fts5yy_action. Used to detect hash collisions.
** fts5yy_shift_ofst[] For each state, the offset into fts5yy_action for
** shifting terminals.
** fts5yy_reduce_ofst[] For each state, the offset into fts5yy_action for
** shifting non-terminals after a reduce.
** fts5yy_default[] Default action for each state.
**
*********** Begin parsing tables **********************************************/
#define fts5YY_ACTTAB_COUNT (105)
static const fts5YYACTIONTYPE fts5yy_action[] = {
/* 0 */ 81, 20, 96, 6, 28, 99, 98, 26, 26, 18,
/* 10 */ 96, 6, 28, 17, 98, 56, 26, 19, 96, 6,
/* 20 */ 28, 14, 98, 14, 26, 31, 92, 96, 6, 28,
/* 30 */ 108, 98, 25, 26, 21, 96, 6, 28, 78, 98,
/* 40 */ 58, 26, 29, 96, 6, 28, 107, 98, 22, 26,
/* 50 */ 24, 16, 12, 11, 1, 13, 13, 24, 16, 23,
/* 60 */ 11, 33, 34, 13, 97, 8, 27, 32, 98, 7,
/* 70 */ 26, 3, 4, 5, 3, 4, 5, 3, 83, 4,
/* 80 */ 5, 3, 63, 5, 3, 62, 12, 2, 86, 13,
/* 90 */ 9, 30, 10, 10, 54, 57, 75, 78, 78, 53,
/* 100 */ 57, 15, 82, 82, 71,
};
static const fts5YYCODETYPE fts5yy_lookahead[] = {
/* 0 */ 16, 17, 18, 19, 20, 22, 22, 24, 24, 17,
/* 10 */ 18, 19, 20, 7, 22, 9, 24, 17, 18, 19,
/* 20 */ 20, 9, 22, 9, 24, 13, 17, 18, 19, 20,
/* 30 */ 26, 22, 24, 24, 17, 18, 19, 20, 15, 22,
/* 40 */ 9, 24, 17, 18, 19, 20, 26, 22, 21, 24,
/* 50 */ 6, 7, 9, 9, 10, 12, 12, 6, 7, 21,
/* 60 */ 9, 24, 25, 12, 18, 5, 20, 14, 22, 5,
/* 70 */ 24, 3, 1, 2, 3, 1, 2, 3, 0, 1,
/* 80 */ 2, 3, 11, 2, 3, 11, 9, 10, 5, 12,
/* 90 */ 23, 24, 10, 10, 8, 9, 9, 15, 15, 8,
/* 100 */ 9, 9, 27, 27, 11, 27, 27, 27, 27, 27,
/* 110 */ 27, 27, 27, 27, 27, 27, 27, 27, 27, 27,
/* 120 */ 27,
};
#define fts5YY_SHIFT_COUNT (34)
#define fts5YY_SHIFT_MIN (0)
#define fts5YY_SHIFT_MAX (93)
static const unsigned char fts5yy_shift_ofst[] = {
/* 0 */ 44, 44, 44, 44, 44, 44, 51, 77, 43, 12,
/* 10 */ 14, 83, 82, 14, 23, 23, 31, 31, 71, 74,
/* 20 */ 78, 81, 86, 91, 6, 53, 53, 60, 64, 68,
/* 30 */ 53, 87, 92, 53, 93,
};
#define fts5YY_REDUCE_COUNT (17)
#define fts5YY_REDUCE_MIN (-17)
#define fts5YY_REDUCE_MAX (67)
static const signed char fts5yy_reduce_ofst[] = {
/* 0 */ -16, -8, 0, 9, 17, 25, 46, -17, -17, 37,
/* 10 */ 67, 4, 4, 8, 4, 20, 27, 38,
};
static const fts5YYACTIONTYPE fts5yy_default[] = {
/* 0 */ 80, 80, 80, 80, 80, 80, 95, 80, 80, 105,
/* 10 */ 80, 110, 110, 80, 110, 110, 80, 80, 80, 80,
/* 20 */ 80, 91, 80, 80, 80, 101, 100, 80, 80, 90,
/* 30 */ 103, 80, 80, 104, 80,
};
/********** End of lemon-generated parsing tables *****************************/
/* The next table maps tokens (terminal symbols) into fallback tokens.
** If a construct like the following:
**
** %fallback ID X Y Z.
**
** appears in the grammar, then ID becomes a fallback token for X, Y,
** and Z. Whenever one of the tokens X, Y, or Z is input to the parser
** but it does not parse, the type of the token is changed to ID and
** the parse is retried before an error is thrown.
**
** This feature can be used, for example, to cause some keywords in a language
** to revert to identifiers if they keyword does not apply in the context where
** it appears.
*/
#ifdef fts5YYFALLBACK
static const fts5YYCODETYPE fts5yyFallback[] = {
};
#endif /* fts5YYFALLBACK */
/* The following structure represents a single element of the
** parser's stack. Information stored includes:
**
** + The state number for the parser at this level of the stack.
**
** + The value of the token stored at this level of the stack.
** (In other words, the "major" token.)
**
** + The semantic value stored at this level of the stack. This is
** the information used by the action routines in the grammar.
** It is sometimes called the "minor" token.
**
** After the "shift" half of a SHIFTREDUCE action, the stateno field
** actually contains the reduce action for the second half of the
** SHIFTREDUCE.
*/
struct fts5yyStackEntry {
fts5YYACTIONTYPE stateno; /* The state-number, or reduce action in SHIFTREDUCE */
fts5YYCODETYPE major; /* The major token value. This is the code
** number for the token at this stack level */
fts5YYMINORTYPE minor; /* The user-supplied minor token value. This
** is the value of the token */
};
typedef struct fts5yyStackEntry fts5yyStackEntry;
/* The state of the parser is completely contained in an instance of
** the following structure */
struct fts5yyParser {
fts5yyStackEntry *fts5yytos; /* Pointer to top element of the stack */
#ifdef fts5YYTRACKMAXSTACKDEPTH
int fts5yyhwm; /* High-water mark of the stack */
#endif
#ifndef fts5YYNOERRORRECOVERY
int fts5yyerrcnt; /* Shifts left before out of the error */
#endif
sqlite3Fts5ParserARG_SDECL /* A place to hold %extra_argument */
sqlite3Fts5ParserCTX_SDECL /* A place to hold %extra_context */
#if fts5YYSTACKDEPTH<=0
int fts5yystksz; /* Current side of the stack */
fts5yyStackEntry *fts5yystack; /* The parser's stack */
fts5yyStackEntry fts5yystk0; /* First stack entry */
#else
fts5yyStackEntry fts5yystack[fts5YYSTACKDEPTH]; /* The parser's stack */
fts5yyStackEntry *fts5yystackEnd; /* Last entry in the stack */
#endif
};
typedef struct fts5yyParser fts5yyParser;
#ifndef NDEBUG
static FILE *fts5yyTraceFILE = 0;
static char *fts5yyTracePrompt = 0;
#endif /* NDEBUG */
#ifndef NDEBUG
/*
** Turn parser tracing on by giving a stream to which to write the trace
** and a prompt to preface each trace message. Tracing is turned off
** by making either argument NULL
**
** Inputs:
** <ul>
** <li> A FILE* to which trace output should be written.
** If NULL, then tracing is turned off.
** <li> A prefix string written at the beginning of every
** line of trace output. If NULL, then tracing is
** turned off.
** </ul>
**
** Outputs:
** None.
*/
static void sqlite3Fts5ParserTrace(FILE *TraceFILE, char *zTracePrompt){
fts5yyTraceFILE = TraceFILE;
fts5yyTracePrompt = zTracePrompt;
if( fts5yyTraceFILE==0 ) fts5yyTracePrompt = 0;
else if( fts5yyTracePrompt==0 ) fts5yyTraceFILE = 0;
}
#endif /* NDEBUG */
#if defined(fts5YYCOVERAGE) || !defined(NDEBUG)
/* For tracing shifts, the names of all terminals and nonterminals
** are required. The following table supplies these names */
static const char *const fts5yyTokenName[] = {
/* 0 */ "$",
/* 1 */ "OR",
/* 2 */ "AND",
/* 3 */ "NOT",
/* 4 */ "TERM",
/* 5 */ "COLON",
/* 6 */ "MINUS",
/* 7 */ "LCP",
/* 8 */ "RCP",
/* 9 */ "STRING",
/* 10 */ "LP",
/* 11 */ "RP",
/* 12 */ "CARET",
/* 13 */ "COMMA",
/* 14 */ "PLUS",
/* 15 */ "STAR",
/* 16 */ "input",
/* 17 */ "expr",
/* 18 */ "cnearset",
/* 19 */ "exprlist",
/* 20 */ "colset",
/* 21 */ "colsetlist",
/* 22 */ "nearset",
/* 23 */ "nearphrases",
/* 24 */ "phrase",
/* 25 */ "neardist_opt",
/* 26 */ "star_opt",
};
#endif /* defined(fts5YYCOVERAGE) || !defined(NDEBUG) */
#ifndef NDEBUG
/* For tracing reduce actions, the names of all rules are required.
*/
static const char *const fts5yyRuleName[] = {
/* 0 */ "input ::= expr",
/* 1 */ "colset ::= MINUS LCP colsetlist RCP",
/* 2 */ "colset ::= LCP colsetlist RCP",
/* 3 */ "colset ::= STRING",
/* 4 */ "colset ::= MINUS STRING",
/* 5 */ "colsetlist ::= colsetlist STRING",
/* 6 */ "colsetlist ::= STRING",
/* 7 */ "expr ::= expr AND expr",
/* 8 */ "expr ::= expr OR expr",
/* 9 */ "expr ::= expr NOT expr",
/* 10 */ "expr ::= colset COLON LP expr RP",
/* 11 */ "expr ::= LP expr RP",
/* 12 */ "expr ::= exprlist",
/* 13 */ "exprlist ::= cnearset",
/* 14 */ "exprlist ::= exprlist cnearset",
/* 15 */ "cnearset ::= nearset",
/* 16 */ "cnearset ::= colset COLON nearset",
/* 17 */ "nearset ::= phrase",
/* 18 */ "nearset ::= CARET phrase",
/* 19 */ "nearset ::= STRING LP nearphrases neardist_opt RP",
/* 20 */ "nearphrases ::= phrase",
/* 21 */ "nearphrases ::= nearphrases phrase",
/* 22 */ "neardist_opt ::=",
/* 23 */ "neardist_opt ::= COMMA STRING",
/* 24 */ "phrase ::= phrase PLUS STRING star_opt",
/* 25 */ "phrase ::= STRING star_opt",
/* 26 */ "star_opt ::= STAR",
/* 27 */ "star_opt ::=",
};
#endif /* NDEBUG */
#if fts5YYSTACKDEPTH<=0
/*
** Try to increase the size of the parser stack. Return the number
** of errors. Return 0 on success.
*/
static int fts5yyGrowStack(fts5yyParser *p){
int newSize;
int idx;
fts5yyStackEntry *pNew;
newSize = p->fts5yystksz*2 + 100;
idx = p->fts5yytos ? (int)(p->fts5yytos - p->fts5yystack) : 0;
if( p->fts5yystack==&p->fts5yystk0 ){
pNew = malloc(newSize*sizeof(pNew[0]));
if( pNew ) pNew[0] = p->fts5yystk0;
}else{
pNew = realloc(p->fts5yystack, newSize*sizeof(pNew[0]));
}
if( pNew ){
p->fts5yystack = pNew;
p->fts5yytos = &p->fts5yystack[idx];
#ifndef NDEBUG
if( fts5yyTraceFILE ){
fprintf(fts5yyTraceFILE,"%sStack grows from %d to %d entries.\n",
fts5yyTracePrompt, p->fts5yystksz, newSize);
}
#endif
p->fts5yystksz = newSize;
}
return pNew==0;
}
#endif
/* Datatype of the argument to the memory allocated passed as the
** second argument to sqlite3Fts5ParserAlloc() below. This can be changed by
** putting an appropriate #define in the %include section of the input
** grammar.
*/
#ifndef fts5YYMALLOCARGTYPE
# define fts5YYMALLOCARGTYPE size_t
#endif
/* Initialize a new parser that has already been allocated.
*/
static void sqlite3Fts5ParserInit(void *fts5yypRawParser sqlite3Fts5ParserCTX_PDECL){
fts5yyParser *fts5yypParser = (fts5yyParser*)fts5yypRawParser;
sqlite3Fts5ParserCTX_STORE
#ifdef fts5YYTRACKMAXSTACKDEPTH
fts5yypParser->fts5yyhwm = 0;
#endif
#if fts5YYSTACKDEPTH<=0
fts5yypParser->fts5yytos = NULL;
fts5yypParser->fts5yystack = NULL;
fts5yypParser->fts5yystksz = 0;
if( fts5yyGrowStack(fts5yypParser) ){
fts5yypParser->fts5yystack = &fts5yypParser->fts5yystk0;
fts5yypParser->fts5yystksz = 1;
}
#endif
#ifndef fts5YYNOERRORRECOVERY
fts5yypParser->fts5yyerrcnt = -1;
#endif
fts5yypParser->fts5yytos = fts5yypParser->fts5yystack;
fts5yypParser->fts5yystack[0].stateno = 0;
fts5yypParser->fts5yystack[0].major = 0;
#if fts5YYSTACKDEPTH>0
fts5yypParser->fts5yystackEnd = &fts5yypParser->fts5yystack[fts5YYSTACKDEPTH-1];
#endif
}
#ifndef sqlite3Fts5Parser_ENGINEALWAYSONSTACK
/*
** This function allocates a new parser.
** The only argument is a pointer to a function which works like
** malloc.
**
** Inputs:
** A pointer to the function used to allocate memory.
**
** Outputs:
** A pointer to a parser. This pointer is used in subsequent calls
** to sqlite3Fts5Parser and sqlite3Fts5ParserFree.
*/
static void *sqlite3Fts5ParserAlloc(void *(*mallocProc)(fts5YYMALLOCARGTYPE) sqlite3Fts5ParserCTX_PDECL){
fts5yyParser *fts5yypParser;
fts5yypParser = (fts5yyParser*)(*mallocProc)( (fts5YYMALLOCARGTYPE)sizeof(fts5yyParser) );
if( fts5yypParser ){
sqlite3Fts5ParserCTX_STORE
sqlite3Fts5ParserInit(fts5yypParser sqlite3Fts5ParserCTX_PARAM);
}
return (void*)fts5yypParser;
}
#endif /* sqlite3Fts5Parser_ENGINEALWAYSONSTACK */
/* The following function deletes the "minor type" or semantic value
** associated with a symbol. The symbol can be either a terminal
** or nonterminal. "fts5yymajor" is the symbol code, and "fts5yypminor" is
** a pointer to the value to be deleted. The code used to do the
** deletions is derived from the %destructor and/or %token_destructor
** directives of the input grammar.
*/
static void fts5yy_destructor(
fts5yyParser *fts5yypParser, /* The parser */
fts5YYCODETYPE fts5yymajor, /* Type code for object to destroy */
fts5YYMINORTYPE *fts5yypminor /* The object to be destroyed */
){
sqlite3Fts5ParserARG_FETCH
sqlite3Fts5ParserCTX_FETCH
switch( fts5yymajor ){
/* Here is inserted the actions which take place when a
** terminal or non-terminal is destroyed. This can happen
** when the symbol is popped from the stack during a
** reduce or during error processing or when a parser is
** being destroyed before it is finished parsing.
**
** Note: during a reduce, the only symbols destroyed are those
** which appear on the RHS of the rule, but which are *not* used
** inside the C code.
*/
/********* Begin destructor definitions ***************************************/
case 16: /* input */
{
#line 83 "fts5parse.y"
(void)pParse;
#line 586 "fts5parse.c"
}
break;
case 17: /* expr */
case 18: /* cnearset */
case 19: /* exprlist */
{
#line 89 "fts5parse.y"
sqlite3Fts5ParseNodeFree((fts5yypminor->fts5yy24));
#line 595 "fts5parse.c"
}
break;
case 20: /* colset */
case 21: /* colsetlist */
{
#line 93 "fts5parse.y"
sqlite3_free((fts5yypminor->fts5yy11));
#line 603 "fts5parse.c"
}
break;
case 22: /* nearset */
case 23: /* nearphrases */
{
#line 148 "fts5parse.y"
sqlite3Fts5ParseNearsetFree((fts5yypminor->fts5yy46));
#line 611 "fts5parse.c"
}
break;
case 24: /* phrase */
{
#line 183 "fts5parse.y"
sqlite3Fts5ParsePhraseFree((fts5yypminor->fts5yy53));
#line 618 "fts5parse.c"
}
break;
/********* End destructor definitions *****************************************/
default: break; /* If no destructor action specified: do nothing */
}
}
/*
** Pop the parser's stack once.
**
** If there is a destructor routine associated with the token which
** is popped from the stack, then call it.
*/
static void fts5yy_pop_parser_stack(fts5yyParser *pParser){
fts5yyStackEntry *fts5yytos;
assert( pParser->fts5yytos!=0 );
assert( pParser->fts5yytos > pParser->fts5yystack );
fts5yytos = pParser->fts5yytos--;
#ifndef NDEBUG
if( fts5yyTraceFILE ){
fprintf(fts5yyTraceFILE,"%sPopping %s\n",
fts5yyTracePrompt,
fts5yyTokenName[fts5yytos->major]);
}
#endif
fts5yy_destructor(pParser, fts5yytos->major, &fts5yytos->minor);
}
/*
** Clear all secondary memory allocations from the parser
*/
static void sqlite3Fts5ParserFinalize(void *p){
fts5yyParser *pParser = (fts5yyParser*)p;
while( pParser->fts5yytos>pParser->fts5yystack ) fts5yy_pop_parser_stack(pParser);
#if fts5YYSTACKDEPTH<=0
if( pParser->fts5yystack!=&pParser->fts5yystk0 ) free(pParser->fts5yystack);
#endif
}
#ifndef sqlite3Fts5Parser_ENGINEALWAYSONSTACK
/*
** Deallocate and destroy a parser. Destructors are called for
** all stack elements before shutting the parser down.
**
** If the fts5YYPARSEFREENEVERNULL macro exists (for example because it
** is defined in a %include section of the input grammar) then it is
** assumed that the input pointer is never NULL.
*/
static void sqlite3Fts5ParserFree(
void *p, /* The parser to be deleted */
void (*freeProc)(void*) /* Function used to reclaim memory */
){
#ifndef fts5YYPARSEFREENEVERNULL
if( p==0 ) return;
#endif
sqlite3Fts5ParserFinalize(p);
(*freeProc)(p);
}
#endif /* sqlite3Fts5Parser_ENGINEALWAYSONSTACK */
/*
** Return the peak depth of the stack for a parser.
*/
#ifdef fts5YYTRACKMAXSTACKDEPTH
static int sqlite3Fts5ParserStackPeak(void *p){
fts5yyParser *pParser = (fts5yyParser*)p;
return pParser->fts5yyhwm;
}
#endif
/* This array of booleans keeps track of the parser statement
** coverage. The element fts5yycoverage[X][Y] is set when the parser
** is in state X and has a lookahead token Y. In a well-tested
** systems, every element of this matrix should end up being set.
*/
#if defined(fts5YYCOVERAGE)
static unsigned char fts5yycoverage[fts5YYNSTATE][fts5YYNFTS5TOKEN];
#endif
/*
** Write into out a description of every state/lookahead combination that
**
** (1) has not been used by the parser, and
** (2) is not a syntax error.
**
** Return the number of missed state/lookahead combinations.
*/
#if defined(fts5YYCOVERAGE)
static int sqlite3Fts5ParserCoverage(FILE *out){
int stateno, iLookAhead, i;
int nMissed = 0;
for(stateno=0; stateno<fts5YYNSTATE; stateno++){
i = fts5yy_shift_ofst[stateno];
for(iLookAhead=0; iLookAhead<fts5YYNFTS5TOKEN; iLookAhead++){
if( fts5yy_lookahead[i+iLookAhead]!=iLookAhead ) continue;
if( fts5yycoverage[stateno][iLookAhead]==0 ) nMissed++;
if( out ){
fprintf(out,"State %d lookahead %s %s\n", stateno,
fts5yyTokenName[iLookAhead],
fts5yycoverage[stateno][iLookAhead] ? "ok" : "missed");
}
}
}
return nMissed;
}
#endif
/*
** Find the appropriate action for a parser given the terminal
** look-ahead token iLookAhead.
*/
static fts5YYACTIONTYPE fts5yy_find_shift_action(
fts5YYCODETYPE iLookAhead, /* The look-ahead token */
fts5YYACTIONTYPE stateno /* Current state number */
){
int i;
if( stateno>fts5YY_MAX_SHIFT ) return stateno;
assert( stateno <= fts5YY_SHIFT_COUNT );
#if defined(fts5YYCOVERAGE)
fts5yycoverage[stateno][iLookAhead] = 1;
#endif
do{
i = fts5yy_shift_ofst[stateno];
assert( i>=0 );
assert( i<=fts5YY_ACTTAB_COUNT );
assert( i+fts5YYNFTS5TOKEN<=(int)fts5YY_NLOOKAHEAD );
assert( iLookAhead!=fts5YYNOCODE );
assert( iLookAhead < fts5YYNFTS5TOKEN );
i += iLookAhead;
assert( i<(int)fts5YY_NLOOKAHEAD );
if( fts5yy_lookahead[i]!=iLookAhead ){
#ifdef fts5YYFALLBACK
fts5YYCODETYPE iFallback; /* Fallback token */
assert( iLookAhead<sizeof(fts5yyFallback)/sizeof(fts5yyFallback[0]) );
iFallback = fts5yyFallback[iLookAhead];
if( iFallback!=0 ){
#ifndef NDEBUG
if( fts5yyTraceFILE ){
fprintf(fts5yyTraceFILE, "%sFALLBACK %s => %s\n",
fts5yyTracePrompt, fts5yyTokenName[iLookAhead], fts5yyTokenName[iFallback]);
}
#endif
assert( fts5yyFallback[iFallback]==0 ); /* Fallback loop must terminate */
iLookAhead = iFallback;
continue;
}
#endif
#ifdef fts5YYWILDCARD
{
int j = i - iLookAhead + fts5YYWILDCARD;
assert( j<(int)(sizeof(fts5yy_lookahead)/sizeof(fts5yy_lookahead[0])) );
if( fts5yy_lookahead[j]==fts5YYWILDCARD && iLookAhead>0 ){
#ifndef NDEBUG
if( fts5yyTraceFILE ){
fprintf(fts5yyTraceFILE, "%sWILDCARD %s => %s\n",
fts5yyTracePrompt, fts5yyTokenName[iLookAhead],
fts5yyTokenName[fts5YYWILDCARD]);
}
#endif /* NDEBUG */
return fts5yy_action[j];
}
}
#endif /* fts5YYWILDCARD */
return fts5yy_default[stateno];
}else{
assert( i>=0 && i<(int)(sizeof(fts5yy_action)/sizeof(fts5yy_action[0])) );
return fts5yy_action[i];
}
}while(1);
}
/*
** Find the appropriate action for a parser given the non-terminal
** look-ahead token iLookAhead.
*/
static fts5YYACTIONTYPE fts5yy_find_reduce_action(
fts5YYACTIONTYPE stateno, /* Current state number */
fts5YYCODETYPE iLookAhead /* The look-ahead token */
){
int i;
#ifdef fts5YYERRORSYMBOL
if( stateno>fts5YY_REDUCE_COUNT ){
return fts5yy_default[stateno];
}
#else
assert( stateno<=fts5YY_REDUCE_COUNT );
#endif
i = fts5yy_reduce_ofst[stateno];
assert( iLookAhead!=fts5YYNOCODE );
i += iLookAhead;
#ifdef fts5YYERRORSYMBOL
if( i<0 || i>=fts5YY_ACTTAB_COUNT || fts5yy_lookahead[i]!=iLookAhead ){
return fts5yy_default[stateno];
}
#else
assert( i>=0 && i<fts5YY_ACTTAB_COUNT );
assert( fts5yy_lookahead[i]==iLookAhead );
#endif
return fts5yy_action[i];
}
/*
** The following routine is called if the stack overflows.
*/
static void fts5yyStackOverflow(fts5yyParser *fts5yypParser){
sqlite3Fts5ParserARG_FETCH
sqlite3Fts5ParserCTX_FETCH
#ifndef NDEBUG
if( fts5yyTraceFILE ){
fprintf(fts5yyTraceFILE,"%sStack Overflow!\n",fts5yyTracePrompt);
}
#endif
while( fts5yypParser->fts5yytos>fts5yypParser->fts5yystack ) fts5yy_pop_parser_stack(fts5yypParser);
/* Here code is inserted which will execute if the parser
** stack every overflows */
/******** Begin %stack_overflow code ******************************************/
#line 36 "fts5parse.y"
sqlite3Fts5ParseError(pParse, "fts5: parser stack overflow");
#line 839 "fts5parse.c"
/******** End %stack_overflow code ********************************************/
sqlite3Fts5ParserARG_STORE /* Suppress warning about unused %extra_argument var */
sqlite3Fts5ParserCTX_STORE
}
/*
** Print tracing information for a SHIFT action
*/
#ifndef NDEBUG
static void fts5yyTraceShift(fts5yyParser *fts5yypParser, int fts5yyNewState, const char *zTag){
if( fts5yyTraceFILE ){
if( fts5yyNewState<fts5YYNSTATE ){
fprintf(fts5yyTraceFILE,"%s%s '%s', go to state %d\n",
fts5yyTracePrompt, zTag, fts5yyTokenName[fts5yypParser->fts5yytos->major],
fts5yyNewState);
}else{
fprintf(fts5yyTraceFILE,"%s%s '%s', pending reduce %d\n",
fts5yyTracePrompt, zTag, fts5yyTokenName[fts5yypParser->fts5yytos->major],
fts5yyNewState - fts5YY_MIN_REDUCE);
}
}
}
#else
# define fts5yyTraceShift(X,Y,Z)
#endif
/*
** Perform a shift action.
*/
static void fts5yy_shift(
fts5yyParser *fts5yypParser, /* The parser to be shifted */
fts5YYACTIONTYPE fts5yyNewState, /* The new state to shift in */
fts5YYCODETYPE fts5yyMajor, /* The major token to shift in */
sqlite3Fts5ParserFTS5TOKENTYPE fts5yyMinor /* The minor token to shift in */
){
fts5yyStackEntry *fts5yytos;
fts5yypParser->fts5yytos++;
#ifdef fts5YYTRACKMAXSTACKDEPTH
if( (int)(fts5yypParser->fts5yytos - fts5yypParser->fts5yystack)>fts5yypParser->fts5yyhwm ){
fts5yypParser->fts5yyhwm++;
assert( fts5yypParser->fts5yyhwm == (int)(fts5yypParser->fts5yytos - fts5yypParser->fts5yystack) );
}
#endif
#if fts5YYSTACKDEPTH>0
if( fts5yypParser->fts5yytos>fts5yypParser->fts5yystackEnd ){
fts5yypParser->fts5yytos--;
fts5yyStackOverflow(fts5yypParser);
return;
}
#else
if( fts5yypParser->fts5yytos>=&fts5yypParser->fts5yystack[fts5yypParser->fts5yystksz] ){
if( fts5yyGrowStack(fts5yypParser) ){
fts5yypParser->fts5yytos--;
fts5yyStackOverflow(fts5yypParser);
return;
}
}
#endif
if( fts5yyNewState > fts5YY_MAX_SHIFT ){
fts5yyNewState += fts5YY_MIN_REDUCE - fts5YY_MIN_SHIFTREDUCE;
}
fts5yytos = fts5yypParser->fts5yytos;
fts5yytos->stateno = fts5yyNewState;
fts5yytos->major = fts5yyMajor;
fts5yytos->minor.fts5yy0 = fts5yyMinor;
fts5yyTraceShift(fts5yypParser, fts5yyNewState, "Shift");
}
/* For rule J, fts5yyRuleInfoLhs[J] contains the symbol on the left-hand side
** of that rule */
static const fts5YYCODETYPE fts5yyRuleInfoLhs[] = {
16, /* (0) input ::= expr */
20, /* (1) colset ::= MINUS LCP colsetlist RCP */
20, /* (2) colset ::= LCP colsetlist RCP */
20, /* (3) colset ::= STRING */
20, /* (4) colset ::= MINUS STRING */
21, /* (5) colsetlist ::= colsetlist STRING */
21, /* (6) colsetlist ::= STRING */
17, /* (7) expr ::= expr AND expr */
17, /* (8) expr ::= expr OR expr */
17, /* (9) expr ::= expr NOT expr */
17, /* (10) expr ::= colset COLON LP expr RP */
17, /* (11) expr ::= LP expr RP */
17, /* (12) expr ::= exprlist */
19, /* (13) exprlist ::= cnearset */
19, /* (14) exprlist ::= exprlist cnearset */
18, /* (15) cnearset ::= nearset */
18, /* (16) cnearset ::= colset COLON nearset */
22, /* (17) nearset ::= phrase */
22, /* (18) nearset ::= CARET phrase */
22, /* (19) nearset ::= STRING LP nearphrases neardist_opt RP */
23, /* (20) nearphrases ::= phrase */
23, /* (21) nearphrases ::= nearphrases phrase */
25, /* (22) neardist_opt ::= */
25, /* (23) neardist_opt ::= COMMA STRING */
24, /* (24) phrase ::= phrase PLUS STRING star_opt */
24, /* (25) phrase ::= STRING star_opt */
26, /* (26) star_opt ::= STAR */
26, /* (27) star_opt ::= */
};
/* For rule J, fts5yyRuleInfoNRhs[J] contains the negative of the number
** of symbols on the right-hand side of that rule. */
static const signed char fts5yyRuleInfoNRhs[] = {
-1, /* (0) input ::= expr */
-4, /* (1) colset ::= MINUS LCP colsetlist RCP */
-3, /* (2) colset ::= LCP colsetlist RCP */
-1, /* (3) colset ::= STRING */
-2, /* (4) colset ::= MINUS STRING */
-2, /* (5) colsetlist ::= colsetlist STRING */
-1, /* (6) colsetlist ::= STRING */
-3, /* (7) expr ::= expr AND expr */
-3, /* (8) expr ::= expr OR expr */
-3, /* (9) expr ::= expr NOT expr */
-5, /* (10) expr ::= colset COLON LP expr RP */
-3, /* (11) expr ::= LP expr RP */
-1, /* (12) expr ::= exprlist */
-1, /* (13) exprlist ::= cnearset */
-2, /* (14) exprlist ::= exprlist cnearset */
-1, /* (15) cnearset ::= nearset */
-3, /* (16) cnearset ::= colset COLON nearset */
-1, /* (17) nearset ::= phrase */
-2, /* (18) nearset ::= CARET phrase */
-5, /* (19) nearset ::= STRING LP nearphrases neardist_opt RP */
-1, /* (20) nearphrases ::= phrase */
-2, /* (21) nearphrases ::= nearphrases phrase */
0, /* (22) neardist_opt ::= */
-2, /* (23) neardist_opt ::= COMMA STRING */
-4, /* (24) phrase ::= phrase PLUS STRING star_opt */
-2, /* (25) phrase ::= STRING star_opt */
-1, /* (26) star_opt ::= STAR */
0, /* (27) star_opt ::= */
};
static void fts5yy_accept(fts5yyParser*); /* Forward Declaration */
/*
** Perform a reduce action and the shift that must immediately
** follow the reduce.
**
** The fts5yyLookahead and fts5yyLookaheadToken parameters provide reduce actions
** access to the lookahead token (if any). The fts5yyLookahead will be fts5YYNOCODE
** if the lookahead token has already been consumed. As this procedure is
** only called from one place, optimizing compilers will in-line it, which
** means that the extra parameters have no performance impact.
*/
static fts5YYACTIONTYPE fts5yy_reduce(
fts5yyParser *fts5yypParser, /* The parser */
unsigned int fts5yyruleno, /* Number of the rule by which to reduce */
int fts5yyLookahead, /* Lookahead token, or fts5YYNOCODE if none */
sqlite3Fts5ParserFTS5TOKENTYPE fts5yyLookaheadToken /* Value of the lookahead token */
sqlite3Fts5ParserCTX_PDECL /* %extra_context */
){
int fts5yygoto; /* The next state */
fts5YYACTIONTYPE fts5yyact; /* The next action */
fts5yyStackEntry *fts5yymsp; /* The top of the parser's stack */
int fts5yysize; /* Amount to pop the stack */
sqlite3Fts5ParserARG_FETCH
(void)fts5yyLookahead;
(void)fts5yyLookaheadToken;
fts5yymsp = fts5yypParser->fts5yytos;
switch( fts5yyruleno ){
/* Beginning here are the reduction cases. A typical example
** follows:
** case 0:
** #line <lineno> <grammarfile>
** { ... } // User supplied code
** #line <lineno> <thisfile>
** break;
*/
/********** Begin reduce actions **********************************************/
fts5YYMINORTYPE fts5yylhsminor;
case 0: /* input ::= expr */
#line 82 "fts5parse.y"
{ sqlite3Fts5ParseFinished(pParse, fts5yymsp[0].minor.fts5yy24); }
#line 1016 "fts5parse.c"
break;
case 1: /* colset ::= MINUS LCP colsetlist RCP */
#line 97 "fts5parse.y"
{
fts5yymsp[-3].minor.fts5yy11 = sqlite3Fts5ParseColsetInvert(pParse, fts5yymsp[-1].minor.fts5yy11);
}
#line 1023 "fts5parse.c"
break;
case 2: /* colset ::= LCP colsetlist RCP */
#line 100 "fts5parse.y"
{ fts5yymsp[-2].minor.fts5yy11 = fts5yymsp[-1].minor.fts5yy11; }
#line 1028 "fts5parse.c"
break;
case 3: /* colset ::= STRING */
#line 101 "fts5parse.y"
{
fts5yylhsminor.fts5yy11 = sqlite3Fts5ParseColset(pParse, 0, &fts5yymsp[0].minor.fts5yy0);
}
#line 1035 "fts5parse.c"
fts5yymsp[0].minor.fts5yy11 = fts5yylhsminor.fts5yy11;
break;
case 4: /* colset ::= MINUS STRING */
#line 104 "fts5parse.y"
{
fts5yymsp[-1].minor.fts5yy11 = sqlite3Fts5ParseColset(pParse, 0, &fts5yymsp[0].minor.fts5yy0);
fts5yymsp[-1].minor.fts5yy11 = sqlite3Fts5ParseColsetInvert(pParse, fts5yymsp[-1].minor.fts5yy11);
}
#line 1044 "fts5parse.c"
break;
case 5: /* colsetlist ::= colsetlist STRING */
#line 109 "fts5parse.y"
{
fts5yylhsminor.fts5yy11 = sqlite3Fts5ParseColset(pParse, fts5yymsp[-1].minor.fts5yy11, &fts5yymsp[0].minor.fts5yy0); }
#line 1050 "fts5parse.c"
fts5yymsp[-1].minor.fts5yy11 = fts5yylhsminor.fts5yy11;
break;
case 6: /* colsetlist ::= STRING */
#line 111 "fts5parse.y"
{
fts5yylhsminor.fts5yy11 = sqlite3Fts5ParseColset(pParse, 0, &fts5yymsp[0].minor.fts5yy0);
}
#line 1058 "fts5parse.c"
fts5yymsp[0].minor.fts5yy11 = fts5yylhsminor.fts5yy11;
break;
case 7: /* expr ::= expr AND expr */
#line 115 "fts5parse.y"
{
fts5yylhsminor.fts5yy24 = sqlite3Fts5ParseNode(pParse, FTS5_AND, fts5yymsp[-2].minor.fts5yy24, fts5yymsp[0].minor.fts5yy24, 0);
}
#line 1066 "fts5parse.c"
fts5yymsp[-2].minor.fts5yy24 = fts5yylhsminor.fts5yy24;
break;
case 8: /* expr ::= expr OR expr */
#line 118 "fts5parse.y"
{
fts5yylhsminor.fts5yy24 = sqlite3Fts5ParseNode(pParse, FTS5_OR, fts5yymsp[-2].minor.fts5yy24, fts5yymsp[0].minor.fts5yy24, 0);
}
#line 1074 "fts5parse.c"
fts5yymsp[-2].minor.fts5yy24 = fts5yylhsminor.fts5yy24;
break;
case 9: /* expr ::= expr NOT expr */
#line 121 "fts5parse.y"
{
fts5yylhsminor.fts5yy24 = sqlite3Fts5ParseNode(pParse, FTS5_NOT, fts5yymsp[-2].minor.fts5yy24, fts5yymsp[0].minor.fts5yy24, 0);
}
#line 1082 "fts5parse.c"
fts5yymsp[-2].minor.fts5yy24 = fts5yylhsminor.fts5yy24;
break;
case 10: /* expr ::= colset COLON LP expr RP */
#line 125 "fts5parse.y"
{
sqlite3Fts5ParseSetColset(pParse, fts5yymsp[-1].minor.fts5yy24, fts5yymsp[-4].minor.fts5yy11);
fts5yylhsminor.fts5yy24 = fts5yymsp[-1].minor.fts5yy24;
}
#line 1091 "fts5parse.c"
fts5yymsp[-4].minor.fts5yy24 = fts5yylhsminor.fts5yy24;
break;
case 11: /* expr ::= LP expr RP */
#line 129 "fts5parse.y"
{fts5yymsp[-2].minor.fts5yy24 = fts5yymsp[-1].minor.fts5yy24;}
#line 1097 "fts5parse.c"
break;
case 12: /* expr ::= exprlist */
case 13: /* exprlist ::= cnearset */ fts5yytestcase(fts5yyruleno==13);
#line 130 "fts5parse.y"
{fts5yylhsminor.fts5yy24 = fts5yymsp[0].minor.fts5yy24;}
#line 1103 "fts5parse.c"
fts5yymsp[0].minor.fts5yy24 = fts5yylhsminor.fts5yy24;
break;
case 14: /* exprlist ::= exprlist cnearset */
#line 133 "fts5parse.y"
{
fts5yylhsminor.fts5yy24 = sqlite3Fts5ParseImplicitAnd(pParse, fts5yymsp[-1].minor.fts5yy24, fts5yymsp[0].minor.fts5yy24);
}
#line 1111 "fts5parse.c"
fts5yymsp[-1].minor.fts5yy24 = fts5yylhsminor.fts5yy24;
break;
case 15: /* cnearset ::= nearset */
#line 137 "fts5parse.y"
{
fts5yylhsminor.fts5yy24 = sqlite3Fts5ParseNode(pParse, FTS5_STRING, 0, 0, fts5yymsp[0].minor.fts5yy46);
}
#line 1119 "fts5parse.c"
fts5yymsp[0].minor.fts5yy24 = fts5yylhsminor.fts5yy24;
break;
case 16: /* cnearset ::= colset COLON nearset */
#line 140 "fts5parse.y"
{
fts5yylhsminor.fts5yy24 = sqlite3Fts5ParseNode(pParse, FTS5_STRING, 0, 0, fts5yymsp[0].minor.fts5yy46);
sqlite3Fts5ParseSetColset(pParse, fts5yylhsminor.fts5yy24, fts5yymsp[-2].minor.fts5yy11);
}
#line 1128 "fts5parse.c"
fts5yymsp[-2].minor.fts5yy24 = fts5yylhsminor.fts5yy24;
break;
case 17: /* nearset ::= phrase */
#line 151 "fts5parse.y"
{ fts5yylhsminor.fts5yy46 = sqlite3Fts5ParseNearset(pParse, 0, fts5yymsp[0].minor.fts5yy53); }
#line 1134 "fts5parse.c"
fts5yymsp[0].minor.fts5yy46 = fts5yylhsminor.fts5yy46;
break;
case 18: /* nearset ::= CARET phrase */
#line 152 "fts5parse.y"
{
sqlite3Fts5ParseSetCaret(fts5yymsp[0].minor.fts5yy53);
fts5yymsp[-1].minor.fts5yy46 = sqlite3Fts5ParseNearset(pParse, 0, fts5yymsp[0].minor.fts5yy53);
}
#line 1143 "fts5parse.c"
break;
case 19: /* nearset ::= STRING LP nearphrases neardist_opt RP */
#line 156 "fts5parse.y"
{
sqlite3Fts5ParseNear(pParse, &fts5yymsp[-4].minor.fts5yy0);
sqlite3Fts5ParseSetDistance(pParse, fts5yymsp[-2].minor.fts5yy46, &fts5yymsp[-1].minor.fts5yy0);
fts5yylhsminor.fts5yy46 = fts5yymsp[-2].minor.fts5yy46;
}
#line 1152 "fts5parse.c"
fts5yymsp[-4].minor.fts5yy46 = fts5yylhsminor.fts5yy46;
break;
case 20: /* nearphrases ::= phrase */
#line 162 "fts5parse.y"
{
fts5yylhsminor.fts5yy46 = sqlite3Fts5ParseNearset(pParse, 0, fts5yymsp[0].minor.fts5yy53);
}
#line 1160 "fts5parse.c"
fts5yymsp[0].minor.fts5yy46 = fts5yylhsminor.fts5yy46;
break;
case 21: /* nearphrases ::= nearphrases phrase */
#line 165 "fts5parse.y"
{
fts5yylhsminor.fts5yy46 = sqlite3Fts5ParseNearset(pParse, fts5yymsp[-1].minor.fts5yy46, fts5yymsp[0].minor.fts5yy53);
}
#line 1168 "fts5parse.c"
fts5yymsp[-1].minor.fts5yy46 = fts5yylhsminor.fts5yy46;
break;
case 22: /* neardist_opt ::= */
#line 172 "fts5parse.y"
{ fts5yymsp[1].minor.fts5yy0.p = 0; fts5yymsp[1].minor.fts5yy0.n = 0; }
#line 1174 "fts5parse.c"
break;
case 23: /* neardist_opt ::= COMMA STRING */
#line 173 "fts5parse.y"
{ fts5yymsp[-1].minor.fts5yy0 = fts5yymsp[0].minor.fts5yy0; }
#line 1179 "fts5parse.c"
break;
case 24: /* phrase ::= phrase PLUS STRING star_opt */
#line 185 "fts5parse.y"
{
fts5yylhsminor.fts5yy53 = sqlite3Fts5ParseTerm(pParse, fts5yymsp[-3].minor.fts5yy53, &fts5yymsp[-1].minor.fts5yy0, fts5yymsp[0].minor.fts5yy4);
}
#line 1186 "fts5parse.c"
fts5yymsp[-3].minor.fts5yy53 = fts5yylhsminor.fts5yy53;
break;
case 25: /* phrase ::= STRING star_opt */
#line 188 "fts5parse.y"
{
fts5yylhsminor.fts5yy53 = sqlite3Fts5ParseTerm(pParse, 0, &fts5yymsp[-1].minor.fts5yy0, fts5yymsp[0].minor.fts5yy4);
}
#line 1194 "fts5parse.c"
fts5yymsp[-1].minor.fts5yy53 = fts5yylhsminor.fts5yy53;
break;
case 26: /* star_opt ::= STAR */
#line 196 "fts5parse.y"
{ fts5yymsp[0].minor.fts5yy4 = 1; }
#line 1200 "fts5parse.c"
break;
case 27: /* star_opt ::= */
#line 197 "fts5parse.y"
{ fts5yymsp[1].minor.fts5yy4 = 0; }
#line 1205 "fts5parse.c"
break;
default:
break;
/********** End reduce actions ************************************************/
};
assert( fts5yyruleno<sizeof(fts5yyRuleInfoLhs)/sizeof(fts5yyRuleInfoLhs[0]) );
fts5yygoto = fts5yyRuleInfoLhs[fts5yyruleno];
fts5yysize = fts5yyRuleInfoNRhs[fts5yyruleno];
fts5yyact = fts5yy_find_reduce_action(fts5yymsp[fts5yysize].stateno,(fts5YYCODETYPE)fts5yygoto);
/* There are no SHIFTREDUCE actions on nonterminals because the table
** generator has simplified them to pure REDUCE actions. */
assert( !(fts5yyact>fts5YY_MAX_SHIFT && fts5yyact<=fts5YY_MAX_SHIFTREDUCE) );
/* It is not possible for a REDUCE to be followed by an error */
assert( fts5yyact!=fts5YY_ERROR_ACTION );
fts5yymsp += fts5yysize+1;
fts5yypParser->fts5yytos = fts5yymsp;
fts5yymsp->stateno = (fts5YYACTIONTYPE)fts5yyact;
fts5yymsp->major = (fts5YYCODETYPE)fts5yygoto;
fts5yyTraceShift(fts5yypParser, fts5yyact, "... then shift");
return fts5yyact;
}
/*
** The following code executes when the parse fails
*/
#ifndef fts5YYNOERRORRECOVERY
static void fts5yy_parse_failed(
fts5yyParser *fts5yypParser /* The parser */
){
sqlite3Fts5ParserARG_FETCH
sqlite3Fts5ParserCTX_FETCH
#ifndef NDEBUG
if( fts5yyTraceFILE ){
fprintf(fts5yyTraceFILE,"%sFail!\n",fts5yyTracePrompt);
}
#endif
while( fts5yypParser->fts5yytos>fts5yypParser->fts5yystack ) fts5yy_pop_parser_stack(fts5yypParser);
/* Here code is inserted which will be executed whenever the
** parser fails */
/************ Begin %parse_failure code ***************************************/
/************ End %parse_failure code *****************************************/
sqlite3Fts5ParserARG_STORE /* Suppress warning about unused %extra_argument variable */
sqlite3Fts5ParserCTX_STORE
}
#endif /* fts5YYNOERRORRECOVERY */
/*
** The following code executes when a syntax error first occurs.
*/
static void fts5yy_syntax_error(
fts5yyParser *fts5yypParser, /* The parser */
int fts5yymajor, /* The major type of the error token */
sqlite3Fts5ParserFTS5TOKENTYPE fts5yyminor /* The minor type of the error token */
){
sqlite3Fts5ParserARG_FETCH
sqlite3Fts5ParserCTX_FETCH
#define FTS5TOKEN fts5yyminor
/************ Begin %syntax_error code ****************************************/
#line 30 "fts5parse.y"
UNUSED_PARAM(fts5yymajor); /* Silence a compiler warning */
sqlite3Fts5ParseError(
pParse, "fts5: syntax error near \"%.*s\"",FTS5TOKEN.n,FTS5TOKEN.p
);
#line 1273 "fts5parse.c"
/************ End %syntax_error code ******************************************/
sqlite3Fts5ParserARG_STORE /* Suppress warning about unused %extra_argument variable */
sqlite3Fts5ParserCTX_STORE
}
/*
** The following is executed when the parser accepts
*/
static void fts5yy_accept(
fts5yyParser *fts5yypParser /* The parser */
){
sqlite3Fts5ParserARG_FETCH
sqlite3Fts5ParserCTX_FETCH
#ifndef NDEBUG
if( fts5yyTraceFILE ){
fprintf(fts5yyTraceFILE,"%sAccept!\n",fts5yyTracePrompt);
}
#endif
#ifndef fts5YYNOERRORRECOVERY
fts5yypParser->fts5yyerrcnt = -1;
#endif
assert( fts5yypParser->fts5yytos==fts5yypParser->fts5yystack );
/* Here code is inserted which will be executed whenever the
** parser accepts */
/*********** Begin %parse_accept code *****************************************/
/*********** End %parse_accept code *******************************************/
sqlite3Fts5ParserARG_STORE /* Suppress warning about unused %extra_argument variable */
sqlite3Fts5ParserCTX_STORE
}
/* The main parser program.
** The first argument is a pointer to a structure obtained from
** "sqlite3Fts5ParserAlloc" which describes the current state of the parser.
** The second argument is the major token number. The third is
** the minor token. The fourth optional argument is whatever the
** user wants (and specified in the grammar) and is available for
** use by the action routines.
**
** Inputs:
** <ul>
** <li> A pointer to the parser (an opaque structure.)
** <li> The major token number.
** <li> The minor token number.
** <li> An option argument of a grammar-specified type.
** </ul>
**
** Outputs:
** None.
*/
static void sqlite3Fts5Parser(
void *fts5yyp, /* The parser */
int fts5yymajor, /* The major token code number */
sqlite3Fts5ParserFTS5TOKENTYPE fts5yyminor /* The value for the token */
sqlite3Fts5ParserARG_PDECL /* Optional %extra_argument parameter */
){
fts5YYMINORTYPE fts5yyminorunion;
fts5YYACTIONTYPE fts5yyact; /* The parser action. */
#if !defined(fts5YYERRORSYMBOL) && !defined(fts5YYNOERRORRECOVERY)
int fts5yyendofinput; /* True if we are at the end of input */
#endif
#ifdef fts5YYERRORSYMBOL
int fts5yyerrorhit = 0; /* True if fts5yymajor has invoked an error */
#endif
fts5yyParser *fts5yypParser = (fts5yyParser*)fts5yyp; /* The parser */
sqlite3Fts5ParserCTX_FETCH
sqlite3Fts5ParserARG_STORE
assert( fts5yypParser->fts5yytos!=0 );
#if !defined(fts5YYERRORSYMBOL) && !defined(fts5YYNOERRORRECOVERY)
fts5yyendofinput = (fts5yymajor==0);
#endif
fts5yyact = fts5yypParser->fts5yytos->stateno;
#ifndef NDEBUG
if( fts5yyTraceFILE ){
if( fts5yyact < fts5YY_MIN_REDUCE ){
fprintf(fts5yyTraceFILE,"%sInput '%s' in state %d\n",
fts5yyTracePrompt,fts5yyTokenName[fts5yymajor],fts5yyact);
}else{
fprintf(fts5yyTraceFILE,"%sInput '%s' with pending reduce %d\n",
fts5yyTracePrompt,fts5yyTokenName[fts5yymajor],fts5yyact-fts5YY_MIN_REDUCE);
}
}
#endif
while(1){ /* Exit by "break" */
assert( fts5yypParser->fts5yytos>=fts5yypParser->fts5yystack );
assert( fts5yyact==fts5yypParser->fts5yytos->stateno );
fts5yyact = fts5yy_find_shift_action((fts5YYCODETYPE)fts5yymajor,fts5yyact);
if( fts5yyact >= fts5YY_MIN_REDUCE ){
unsigned int fts5yyruleno = fts5yyact - fts5YY_MIN_REDUCE; /* Reduce by this rule */
assert( fts5yyruleno<(int)(sizeof(fts5yyRuleName)/sizeof(fts5yyRuleName[0])) );
#ifndef NDEBUG
if( fts5yyTraceFILE ){
int fts5yysize = fts5yyRuleInfoNRhs[fts5yyruleno];
if( fts5yysize ){
fprintf(fts5yyTraceFILE, "%sReduce %d [%s]%s, pop back to state %d.\n",
fts5yyTracePrompt,
fts5yyruleno, fts5yyRuleName[fts5yyruleno],
fts5yyruleno<fts5YYNRULE_WITH_ACTION ? "" : " without external action",
fts5yypParser->fts5yytos[fts5yysize].stateno);
}else{
fprintf(fts5yyTraceFILE, "%sReduce %d [%s]%s.\n",
fts5yyTracePrompt, fts5yyruleno, fts5yyRuleName[fts5yyruleno],
fts5yyruleno<fts5YYNRULE_WITH_ACTION ? "" : " without external action");
}
}
#endif /* NDEBUG */
/* Check that the stack is large enough to grow by a single entry
** if the RHS of the rule is empty. This ensures that there is room
** enough on the stack to push the LHS value */
if( fts5yyRuleInfoNRhs[fts5yyruleno]==0 ){
#ifdef fts5YYTRACKMAXSTACKDEPTH
if( (int)(fts5yypParser->fts5yytos - fts5yypParser->fts5yystack)>fts5yypParser->fts5yyhwm ){
fts5yypParser->fts5yyhwm++;
assert( fts5yypParser->fts5yyhwm ==
(int)(fts5yypParser->fts5yytos - fts5yypParser->fts5yystack));
}
#endif
#if fts5YYSTACKDEPTH>0
if( fts5yypParser->fts5yytos>=fts5yypParser->fts5yystackEnd ){
fts5yyStackOverflow(fts5yypParser);
break;
}
#else
if( fts5yypParser->fts5yytos>=&fts5yypParser->fts5yystack[fts5yypParser->fts5yystksz-1] ){
if( fts5yyGrowStack(fts5yypParser) ){
fts5yyStackOverflow(fts5yypParser);
break;
}
}
#endif
}
fts5yyact = fts5yy_reduce(fts5yypParser,fts5yyruleno,fts5yymajor,fts5yyminor sqlite3Fts5ParserCTX_PARAM);
}else if( fts5yyact <= fts5YY_MAX_SHIFTREDUCE ){
fts5yy_shift(fts5yypParser,fts5yyact,(fts5YYCODETYPE)fts5yymajor,fts5yyminor);
#ifndef fts5YYNOERRORRECOVERY
fts5yypParser->fts5yyerrcnt--;
#endif
break;
}else if( fts5yyact==fts5YY_ACCEPT_ACTION ){
fts5yypParser->fts5yytos--;
fts5yy_accept(fts5yypParser);
return;
}else{
assert( fts5yyact == fts5YY_ERROR_ACTION );
fts5yyminorunion.fts5yy0 = fts5yyminor;
#ifdef fts5YYERRORSYMBOL
int fts5yymx;
#endif
#ifndef NDEBUG
if( fts5yyTraceFILE ){
fprintf(fts5yyTraceFILE,"%sSyntax Error!\n",fts5yyTracePrompt);
}
#endif
#ifdef fts5YYERRORSYMBOL
/* A syntax error has occurred.
** The response to an error depends upon whether or not the
** grammar defines an error token "ERROR".
**
** This is what we do if the grammar does define ERROR:
**
** * Call the %syntax_error function.
**
** * Begin popping the stack until we enter a state where
** it is legal to shift the error symbol, then shift
** the error symbol.
**
** * Set the error count to three.
**
** * Begin accepting and shifting new tokens. No new error
** processing will occur until three tokens have been
** shifted successfully.
**
*/
if( fts5yypParser->fts5yyerrcnt<0 ){
fts5yy_syntax_error(fts5yypParser,fts5yymajor,fts5yyminor);
}
fts5yymx = fts5yypParser->fts5yytos->major;
if( fts5yymx==fts5YYERRORSYMBOL || fts5yyerrorhit ){
#ifndef NDEBUG
if( fts5yyTraceFILE ){
fprintf(fts5yyTraceFILE,"%sDiscard input token %s\n",
fts5yyTracePrompt,fts5yyTokenName[fts5yymajor]);
}
#endif
fts5yy_destructor(fts5yypParser, (fts5YYCODETYPE)fts5yymajor, &fts5yyminorunion);
fts5yymajor = fts5YYNOCODE;
}else{
while( fts5yypParser->fts5yytos >= fts5yypParser->fts5yystack
&& (fts5yyact = fts5yy_find_reduce_action(
fts5yypParser->fts5yytos->stateno,
fts5YYERRORSYMBOL)) > fts5YY_MAX_SHIFTREDUCE
){
fts5yy_pop_parser_stack(fts5yypParser);
}
if( fts5yypParser->fts5yytos < fts5yypParser->fts5yystack || fts5yymajor==0 ){
fts5yy_destructor(fts5yypParser,(fts5YYCODETYPE)fts5yymajor,&fts5yyminorunion);
fts5yy_parse_failed(fts5yypParser);
#ifndef fts5YYNOERRORRECOVERY
fts5yypParser->fts5yyerrcnt = -1;
#endif
fts5yymajor = fts5YYNOCODE;
}else if( fts5yymx!=fts5YYERRORSYMBOL ){
fts5yy_shift(fts5yypParser,fts5yyact,fts5YYERRORSYMBOL,fts5yyminor);
}
}
fts5yypParser->fts5yyerrcnt = 3;
fts5yyerrorhit = 1;
if( fts5yymajor==fts5YYNOCODE ) break;
fts5yyact = fts5yypParser->fts5yytos->stateno;
#elif defined(fts5YYNOERRORRECOVERY)
/* If the fts5YYNOERRORRECOVERY macro is defined, then do not attempt to
** do any kind of error recovery. Instead, simply invoke the syntax
** error routine and continue going as if nothing had happened.
**
** Applications can set this macro (for example inside %include) if
** they intend to abandon the parse upon the first syntax error seen.
*/
fts5yy_syntax_error(fts5yypParser,fts5yymajor, fts5yyminor);
fts5yy_destructor(fts5yypParser,(fts5YYCODETYPE)fts5yymajor,&fts5yyminorunion);
break;
#else /* fts5YYERRORSYMBOL is not defined */
/* This is what we do if the grammar does not define ERROR:
**
** * Report an error message, and throw away the input token.
**
** * If the input token is $, then fail the parse.
**
** As before, subsequent error messages are suppressed until
** three input tokens have been successfully shifted.
*/
if( fts5yypParser->fts5yyerrcnt<=0 ){
fts5yy_syntax_error(fts5yypParser,fts5yymajor, fts5yyminor);
}
fts5yypParser->fts5yyerrcnt = 3;
fts5yy_destructor(fts5yypParser,(fts5YYCODETYPE)fts5yymajor,&fts5yyminorunion);
if( fts5yyendofinput ){
fts5yy_parse_failed(fts5yypParser);
#ifndef fts5YYNOERRORRECOVERY
fts5yypParser->fts5yyerrcnt = -1;
#endif
}
break;
#endif
}
}
#ifndef NDEBUG
if( fts5yyTraceFILE ){
fts5yyStackEntry *i;
char cDiv = '[';
fprintf(fts5yyTraceFILE,"%sReturn. Stack=",fts5yyTracePrompt);
for(i=&fts5yypParser->fts5yystack[1]; i<=fts5yypParser->fts5yytos; i++){
fprintf(fts5yyTraceFILE,"%c%s", cDiv, fts5yyTokenName[i->major]);
cDiv = ' ';
}
fprintf(fts5yyTraceFILE,"]\n");
}
#endif
return;
}
/*
** Return the fallback token corresponding to canonical token iToken, or
** 0 if iToken has no fallback.
*/
static int sqlite3Fts5ParserFallback(int iToken){
#ifdef fts5YYFALLBACK
assert( iToken<(int)(sizeof(fts5yyFallback)/sizeof(fts5yyFallback[0])) );
return fts5yyFallback[iToken];
#else
(void)iToken;
return 0;
#endif
}
#line 1 "fts5_aux.c"
/*
** 2014 May 31
**
** The author disclaims copyright to this source code. In place of
** a legal notice, here is a blessing:
**
** May you do good and not evil.
** May you find forgiveness for yourself and forgive others.
** May you share freely, never taking more than you give.
**
******************************************************************************
*/
/*
** Object used to iterate through all "coalesced phrase instances" in
** a single column of the current row. If the phrase instances in the
** column being considered do not overlap, this object simply iterates
** through them. Or, if they do overlap (share one or more tokens in
** common), each set of overlapping instances is treated as a single
** match. See documentation for the highlight() auxiliary function for
** details.
**
** Usage is:
**
** for(rc = fts5CInstIterNext(pApi, pFts, iCol, &iter);
** (rc==SQLITE_OK && 0==fts5CInstIterEof(&iter);
** rc = fts5CInstIterNext(&iter)
** ){
** printf("instance starts at %d, ends at %d\n", iter.iStart, iter.iEnd);
** }
**
*/
typedef struct CInstIter CInstIter;
struct CInstIter {
const Fts5ExtensionApi *pApi; /* API offered by current FTS version */
Fts5Context *pFts; /* First arg to pass to pApi functions */
int iCol; /* Column to search */
int iInst; /* Next phrase instance index */
int nInst; /* Total number of phrase instances */
/* Output variables */
int iStart; /* First token in coalesced phrase instance */
int iEnd; /* Last token in coalesced phrase instance */
};
/*
** Advance the iterator to the next coalesced phrase instance. Return
** an SQLite error code if an error occurs, or SQLITE_OK otherwise.
*/
static int fts5CInstIterNext(CInstIter *pIter){
int rc = SQLITE_OK;
pIter->iStart = -1;
pIter->iEnd = -1;
while( rc==SQLITE_OK && pIter->iInst<pIter->nInst ){
int ip; int ic; int io;
rc = pIter->pApi->xInst(pIter->pFts, pIter->iInst, &ip, &ic, &io);
if( rc==SQLITE_OK ){
if( ic==pIter->iCol ){
int iEnd = io - 1 + pIter->pApi->xPhraseSize(pIter->pFts, ip);
if( pIter->iStart<0 ){
pIter->iStart = io;
pIter->iEnd = iEnd;
}else if( io<=pIter->iEnd ){
if( iEnd>pIter->iEnd ) pIter->iEnd = iEnd;
}else{
break;
}
}
pIter->iInst++;
}
}
return rc;
}
/*
** Initialize the iterator object indicated by the final parameter to
** iterate through coalesced phrase instances in column iCol.
*/
static int fts5CInstIterInit(
const Fts5ExtensionApi *pApi,
Fts5Context *pFts,
int iCol,
CInstIter *pIter
){
int rc;
memset(pIter, 0, sizeof(CInstIter));
pIter->pApi = pApi;
pIter->pFts = pFts;
pIter->iCol = iCol;
rc = pApi->xInstCount(pFts, &pIter->nInst);
if( rc==SQLITE_OK ){
rc = fts5CInstIterNext(pIter);
}
return rc;
}
/*************************************************************************
** Start of highlight() implementation.
*/
typedef struct HighlightContext HighlightContext;
struct HighlightContext {
CInstIter iter; /* Coalesced Instance Iterator */
int iPos; /* Current token offset in zIn[] */
int iRangeStart; /* First token to include */
int iRangeEnd; /* If non-zero, last token to include */
const char *zOpen; /* Opening highlight */
const char *zClose; /* Closing highlight */
const char *zIn; /* Input text */
int nIn; /* Size of input text in bytes */
int iOff; /* Current offset within zIn[] */
char *zOut; /* Output value */
};
/*
** Append text to the HighlightContext output string - p->zOut. Argument
** z points to a buffer containing n bytes of text to append. If n is
** negative, everything up until the first '\0' is appended to the output.
**
** If *pRc is set to any value other than SQLITE_OK when this function is
** called, it is a no-op. If an error (i.e. an OOM condition) is encountered,
** *pRc is set to an error code before returning.
*/
static void fts5HighlightAppend(
int *pRc,
HighlightContext *p,
const char *z, int n
){
if( *pRc==SQLITE_OK && z ){
if( n<0 ) n = (int)strlen(z);
p->zOut = sqlite3_mprintf("%z%.*s", p->zOut, n, z);
if( p->zOut==0 ) *pRc = SQLITE_NOMEM;
}
}
/*
** Tokenizer callback used by implementation of highlight() function.
*/
static int fts5HighlightCb(
void *pContext, /* Pointer to HighlightContext object */
int tflags, /* Mask of FTS5_TOKEN_* flags */
const char *pToken, /* Buffer containing token */
int nToken, /* Size of token in bytes */
int iStartOff, /* Start offset of token */
int iEndOff /* End offset of token */
){
HighlightContext *p = (HighlightContext*)pContext;
int rc = SQLITE_OK;
int iPos;
UNUSED_PARAM2(pToken, nToken);
if( tflags & FTS5_TOKEN_COLOCATED ) return SQLITE_OK;
iPos = p->iPos++;
if( p->iRangeEnd>0 ){
if( iPos<p->iRangeStart || iPos>p->iRangeEnd ) return SQLITE_OK;
if( p->iRangeStart && iPos==p->iRangeStart ) p->iOff = iStartOff;
}
if( iPos==p->iter.iStart ){
fts5HighlightAppend(&rc, p, &p->zIn[p->iOff], iStartOff - p->iOff);
fts5HighlightAppend(&rc, p, p->zOpen, -1);
p->iOff = iStartOff;
}
if( iPos==p->iter.iEnd ){
if( p->iRangeEnd && p->iter.iStart<p->iRangeStart ){
fts5HighlightAppend(&rc, p, p->zOpen, -1);
}
fts5HighlightAppend(&rc, p, &p->zIn[p->iOff], iEndOff - p->iOff);
fts5HighlightAppend(&rc, p, p->zClose, -1);
p->iOff = iEndOff;
if( rc==SQLITE_OK ){
rc = fts5CInstIterNext(&p->iter);
}
}
if( p->iRangeEnd>0 && iPos==p->iRangeEnd ){
fts5HighlightAppend(&rc, p, &p->zIn[p->iOff], iEndOff - p->iOff);
p->iOff = iEndOff;
if( iPos>=p->iter.iStart && iPos<p->iter.iEnd ){
fts5HighlightAppend(&rc, p, p->zClose, -1);
}
}
return rc;
}
/*
** Implementation of highlight() function.
*/
static void fts5HighlightFunction(
const Fts5ExtensionApi *pApi, /* API offered by current FTS version */
Fts5Context *pFts, /* First arg to pass to pApi functions */
sqlite3_context *pCtx, /* Context for returning result/error */
int nVal, /* Number of values in apVal[] array */
sqlite3_value **apVal /* Array of trailing arguments */
){
HighlightContext ctx;
int rc;
int iCol;
if( nVal!=3 ){
const char *zErr = "wrong number of arguments to function highlight()";
sqlite3_result_error(pCtx, zErr, -1);
return;
}
iCol = sqlite3_value_int(apVal[0]);
memset(&ctx, 0, sizeof(HighlightContext));
ctx.zOpen = (const char*)sqlite3_value_text(apVal[1]);
ctx.zClose = (const char*)sqlite3_value_text(apVal[2]);
rc = pApi->xColumnText(pFts, iCol, &ctx.zIn, &ctx.nIn);
if( ctx.zIn ){
if( rc==SQLITE_OK ){
rc = fts5CInstIterInit(pApi, pFts, iCol, &ctx.iter);
}
if( rc==SQLITE_OK ){
rc = pApi->xTokenize(pFts, ctx.zIn, ctx.nIn, (void*)&ctx,fts5HighlightCb);
}
fts5HighlightAppend(&rc, &ctx, &ctx.zIn[ctx.iOff], ctx.nIn - ctx.iOff);
if( rc==SQLITE_OK ){
sqlite3_result_text(pCtx, (const char*)ctx.zOut, -1, SQLITE_TRANSIENT);
}
sqlite3_free(ctx.zOut);
}
if( rc!=SQLITE_OK ){
sqlite3_result_error_code(pCtx, rc);
}
}
/*
** End of highlight() implementation.
**************************************************************************/
/*
** Context object passed to the fts5SentenceFinderCb() function.
*/
typedef struct Fts5SFinder Fts5SFinder;
struct Fts5SFinder {
int iPos; /* Current token position */
int nFirstAlloc; /* Allocated size of aFirst[] */
int nFirst; /* Number of entries in aFirst[] */
int *aFirst; /* Array of first token in each sentence */
const char *zDoc; /* Document being tokenized */
};
/*
** Add an entry to the Fts5SFinder.aFirst[] array. Grow the array if
** necessary. Return SQLITE_OK if successful, or SQLITE_NOMEM if an
** error occurs.
*/
static int fts5SentenceFinderAdd(Fts5SFinder *p, int iAdd){
if( p->nFirstAlloc==p->nFirst ){
int nNew = p->nFirstAlloc ? p->nFirstAlloc*2 : 64;
int *aNew;
aNew = (int*)sqlite3_realloc64(p->aFirst, nNew*sizeof(int));
if( aNew==0 ) return SQLITE_NOMEM;
p->aFirst = aNew;
p->nFirstAlloc = nNew;
}
p->aFirst[p->nFirst++] = iAdd;
return SQLITE_OK;
}
/*
** This function is an xTokenize() callback used by the auxiliary snippet()
** function. Its job is to identify tokens that are the first in a sentence.
** For each such token, an entry is added to the SFinder.aFirst[] array.
*/
static int fts5SentenceFinderCb(
void *pContext, /* Pointer to HighlightContext object */
int tflags, /* Mask of FTS5_TOKEN_* flags */
const char *pToken, /* Buffer containing token */
int nToken, /* Size of token in bytes */
int iStartOff, /* Start offset of token */
int iEndOff /* End offset of token */
){
int rc = SQLITE_OK;
UNUSED_PARAM2(pToken, nToken);
UNUSED_PARAM(iEndOff);
if( (tflags & FTS5_TOKEN_COLOCATED)==0 ){
Fts5SFinder *p = (Fts5SFinder*)pContext;
if( p->iPos>0 ){
int i;
char c = 0;
for(i=iStartOff-1; i>=0; i--){
c = p->zDoc[i];
if( c!=' ' && c!='\t' && c!='\n' && c!='\r' ) break;
}
if( i!=iStartOff-1 && (c=='.' || c==':') ){
rc = fts5SentenceFinderAdd(p, p->iPos);
}
}else{
rc = fts5SentenceFinderAdd(p, 0);
}
p->iPos++;
}
return rc;
}
static int fts5SnippetScore(
const Fts5ExtensionApi *pApi, /* API offered by current FTS version */
Fts5Context *pFts, /* First arg to pass to pApi functions */
int nDocsize, /* Size of column in tokens */
unsigned char *aSeen, /* Array with one element per query phrase */
int iCol, /* Column to score */
int iPos, /* Starting offset to score */
int nToken, /* Max tokens per snippet */
int *pnScore, /* OUT: Score */
int *piPos /* OUT: Adjusted offset */
){
int rc;
int i;
int ip = 0;
int ic = 0;
int iOff = 0;
int iFirst = -1;
int nInst;
int nScore = 0;
int iLast = 0;
sqlite3_int64 iEnd = (sqlite3_int64)iPos + nToken;
rc = pApi->xInstCount(pFts, &nInst);
for(i=0; i<nInst && rc==SQLITE_OK; i++){
rc = pApi->xInst(pFts, i, &ip, &ic, &iOff);
if( rc==SQLITE_OK && ic==iCol && iOff>=iPos && iOff<iEnd ){
nScore += (aSeen[ip] ? 1 : 1000);
aSeen[ip] = 1;
if( iFirst<0 ) iFirst = iOff;
iLast = iOff + pApi->xPhraseSize(pFts, ip);
}
}
*pnScore = nScore;
if( piPos ){
sqlite3_int64 iAdj = iFirst - (nToken - (iLast-iFirst)) / 2;
if( (iAdj+nToken)>nDocsize ) iAdj = nDocsize - nToken;
if( iAdj<0 ) iAdj = 0;
*piPos = (int)iAdj;
}
return rc;
}
/*
** Return the value in pVal interpreted as utf-8 text. Except, if pVal
** contains a NULL value, return a pointer to a static string zero
** bytes in length instead of a NULL pointer.
*/
static const char *fts5ValueToText(sqlite3_value *pVal){
const char *zRet = (const char*)sqlite3_value_text(pVal);
return zRet ? zRet : "";
}
/*
** Implementation of snippet() function.
*/
static void fts5SnippetFunction(
const Fts5ExtensionApi *pApi, /* API offered by current FTS version */
Fts5Context *pFts, /* First arg to pass to pApi functions */
sqlite3_context *pCtx, /* Context for returning result/error */
int nVal, /* Number of values in apVal[] array */
sqlite3_value **apVal /* Array of trailing arguments */
){
HighlightContext ctx;
int rc = SQLITE_OK; /* Return code */
int iCol; /* 1st argument to snippet() */
const char *zEllips; /* 4th argument to snippet() */
int nToken; /* 5th argument to snippet() */
int nInst = 0; /* Number of instance matches this row */
int i; /* Used to iterate through instances */
int nPhrase; /* Number of phrases in query */
unsigned char *aSeen; /* Array of "seen instance" flags */
int iBestCol; /* Column containing best snippet */
int iBestStart = 0; /* First token of best snippet */
int nBestScore = 0; /* Score of best snippet */
int nColSize = 0; /* Total size of iBestCol in tokens */
Fts5SFinder sFinder; /* Used to find the beginnings of sentences */
int nCol;
if( nVal!=5 ){
const char *zErr = "wrong number of arguments to function snippet()";
sqlite3_result_error(pCtx, zErr, -1);
return;
}
nCol = pApi->xColumnCount(pFts);
memset(&ctx, 0, sizeof(HighlightContext));
iCol = sqlite3_value_int(apVal[0]);
ctx.zOpen = fts5ValueToText(apVal[1]);
ctx.zClose = fts5ValueToText(apVal[2]);
zEllips = fts5ValueToText(apVal[3]);
nToken = sqlite3_value_int(apVal[4]);
iBestCol = (iCol>=0 ? iCol : 0);
nPhrase = pApi->xPhraseCount(pFts);
aSeen = sqlite3_malloc(nPhrase);
if( aSeen==0 ){
rc = SQLITE_NOMEM;
}
if( rc==SQLITE_OK ){
rc = pApi->xInstCount(pFts, &nInst);
}
memset(&sFinder, 0, sizeof(Fts5SFinder));
for(i=0; i<nCol; i++){
if( iCol<0 || iCol==i ){
int nDoc;
int nDocsize;
int ii;
sFinder.iPos = 0;
sFinder.nFirst = 0;
rc = pApi->xColumnText(pFts, i, &sFinder.zDoc, &nDoc);
if( rc!=SQLITE_OK ) break;
rc = pApi->xTokenize(pFts,
sFinder.zDoc, nDoc, (void*)&sFinder,fts5SentenceFinderCb
);
if( rc!=SQLITE_OK ) break;
rc = pApi->xColumnSize(pFts, i, &nDocsize);
if( rc!=SQLITE_OK ) break;
for(ii=0; rc==SQLITE_OK && ii<nInst; ii++){
int ip, ic, io;
int iAdj;
int nScore;
int jj;
rc = pApi->xInst(pFts, ii, &ip, &ic, &io);
if( ic!=i ) continue;
if( io>nDocsize ) rc = FTS5_CORRUPT;
if( rc!=SQLITE_OK ) continue;
memset(aSeen, 0, nPhrase);
rc = fts5SnippetScore(pApi, pFts, nDocsize, aSeen, i,
io, nToken, &nScore, &iAdj
);
if( rc==SQLITE_OK && nScore>nBestScore ){
nBestScore = nScore;
iBestCol = i;
iBestStart = iAdj;
nColSize = nDocsize;
}
if( rc==SQLITE_OK && sFinder.nFirst && nDocsize>nToken ){
for(jj=0; jj<(sFinder.nFirst-1); jj++){
if( sFinder.aFirst[jj+1]>io ) break;
}
if( sFinder.aFirst[jj]<io ){
memset(aSeen, 0, nPhrase);
rc = fts5SnippetScore(pApi, pFts, nDocsize, aSeen, i,
sFinder.aFirst[jj], nToken, &nScore, 0
);
nScore += (sFinder.aFirst[jj]==0 ? 120 : 100);
if( rc==SQLITE_OK && nScore>nBestScore ){
nBestScore = nScore;
iBestCol = i;
iBestStart = sFinder.aFirst[jj];
nColSize = nDocsize;
}
}
}
}
}
}
if( rc==SQLITE_OK ){
rc = pApi->xColumnText(pFts, iBestCol, &ctx.zIn, &ctx.nIn);
}
if( rc==SQLITE_OK && nColSize==0 ){
rc = pApi->xColumnSize(pFts, iBestCol, &nColSize);
}
if( ctx.zIn ){
if( rc==SQLITE_OK ){
rc = fts5CInstIterInit(pApi, pFts, iBestCol, &ctx.iter);
}
ctx.iRangeStart = iBestStart;
ctx.iRangeEnd = iBestStart + nToken - 1;
if( iBestStart>0 ){
fts5HighlightAppend(&rc, &ctx, zEllips, -1);
}
/* Advance iterator ctx.iter so that it points to the first coalesced
** phrase instance at or following position iBestStart. */
while( ctx.iter.iStart>=0 && ctx.iter.iStart<iBestStart && rc==SQLITE_OK ){
rc = fts5CInstIterNext(&ctx.iter);
}
if( rc==SQLITE_OK ){
rc = pApi->xTokenize(pFts, ctx.zIn, ctx.nIn, (void*)&ctx,fts5HighlightCb);
}
if( ctx.iRangeEnd>=(nColSize-1) ){
fts5HighlightAppend(&rc, &ctx, &ctx.zIn[ctx.iOff], ctx.nIn - ctx.iOff);
}else{
fts5HighlightAppend(&rc, &ctx, zEllips, -1);
}
}
if( rc==SQLITE_OK ){
sqlite3_result_text(pCtx, (const char*)ctx.zOut, -1, SQLITE_TRANSIENT);
}else{
sqlite3_result_error_code(pCtx, rc);
}
sqlite3_free(ctx.zOut);
sqlite3_free(aSeen);
sqlite3_free(sFinder.aFirst);
}
/************************************************************************/
/*
** The first time the bm25() function is called for a query, an instance
** of the following structure is allocated and populated.
*/
typedef struct Fts5Bm25Data Fts5Bm25Data;
struct Fts5Bm25Data {
int nPhrase; /* Number of phrases in query */
double avgdl; /* Average number of tokens in each row */
double *aIDF; /* IDF for each phrase */
double *aFreq; /* Array used to calculate phrase freq. */
};
/*
** Callback used by fts5Bm25GetData() to count the number of rows in the
** table matched by each individual phrase within the query.
*/
static int fts5CountCb(
const Fts5ExtensionApi *pApi,
Fts5Context *pFts,
void *pUserData /* Pointer to sqlite3_int64 variable */
){
sqlite3_int64 *pn = (sqlite3_int64*)pUserData;
UNUSED_PARAM2(pApi, pFts);
(*pn)++;
return SQLITE_OK;
}
/*
** Set *ppData to point to the Fts5Bm25Data object for the current query.
** If the object has not already been allocated, allocate and populate it
** now.
*/
static int fts5Bm25GetData(
const Fts5ExtensionApi *pApi,
Fts5Context *pFts,
Fts5Bm25Data **ppData /* OUT: bm25-data object for this query */
){
int rc = SQLITE_OK; /* Return code */
Fts5Bm25Data *p; /* Object to return */
p = (Fts5Bm25Data*)pApi->xGetAuxdata(pFts, 0);
if( p==0 ){
int nPhrase; /* Number of phrases in query */
sqlite3_int64 nRow = 0; /* Number of rows in table */
sqlite3_int64 nToken = 0; /* Number of tokens in table */
sqlite3_int64 nByte; /* Bytes of space to allocate */
int i;
/* Allocate the Fts5Bm25Data object */
nPhrase = pApi->xPhraseCount(pFts);
nByte = sizeof(Fts5Bm25Data) + nPhrase*2*sizeof(double);
p = (Fts5Bm25Data*)sqlite3_malloc64(nByte);
if( p==0 ){
rc = SQLITE_NOMEM;
}else{
memset(p, 0, (size_t)nByte);
p->nPhrase = nPhrase;
p->aIDF = (double*)&p[1];
p->aFreq = &p->aIDF[nPhrase];
}
/* Calculate the average document length for this FTS5 table */
if( rc==SQLITE_OK ) rc = pApi->xRowCount(pFts, &nRow);
assert( rc!=SQLITE_OK || nRow>0 );
if( rc==SQLITE_OK ) rc = pApi->xColumnTotalSize(pFts, -1, &nToken);
if( rc==SQLITE_OK ) p->avgdl = (double)nToken / (double)nRow;
/* Calculate an IDF for each phrase in the query */
for(i=0; rc==SQLITE_OK && i<nPhrase; i++){
sqlite3_int64 nHit = 0;
rc = pApi->xQueryPhrase(pFts, i, (void*)&nHit, fts5CountCb);
if( rc==SQLITE_OK ){
/* Calculate the IDF (Inverse Document Frequency) for phrase i.
** This is done using the standard BM25 formula as found on wikipedia:
**
** IDF = log( (N - nHit + 0.5) / (nHit + 0.5) )
**
** where "N" is the total number of documents in the set and nHit
** is the number that contain at least one instance of the phrase
** under consideration.
**
** The problem with this is that if (N < 2*nHit), the IDF is
** negative. Which is undesirable. So the mimimum allowable IDF is
** (1e-6) - roughly the same as a term that appears in just over
** half of set of 5,000,000 documents. */
double idf = log( (nRow - nHit + 0.5) / (nHit + 0.5) );
if( idf<=0.0 ) idf = 1e-6;
p->aIDF[i] = idf;
}
}
if( rc!=SQLITE_OK ){
sqlite3_free(p);
}else{
rc = pApi->xSetAuxdata(pFts, p, sqlite3_free);
}
if( rc!=SQLITE_OK ) p = 0;
}
*ppData = p;
return rc;
}
/*
** Implementation of bm25() function.
*/
static void fts5Bm25Function(
const Fts5ExtensionApi *pApi, /* API offered by current FTS version */
Fts5Context *pFts, /* First arg to pass to pApi functions */
sqlite3_context *pCtx, /* Context for returning result/error */
int nVal, /* Number of values in apVal[] array */
sqlite3_value **apVal /* Array of trailing arguments */
){
const double k1 = 1.2; /* Constant "k1" from BM25 formula */
const double b = 0.75; /* Constant "b" from BM25 formula */
int rc; /* Error code */
double score = 0.0; /* SQL function return value */
Fts5Bm25Data *pData; /* Values allocated/calculated once only */
int i; /* Iterator variable */
int nInst = 0; /* Value returned by xInstCount() */
double D = 0.0; /* Total number of tokens in row */
double *aFreq = 0; /* Array of phrase freq. for current row */
/* Calculate the phrase frequency (symbol "f(qi,D)" in the documentation)
** for each phrase in the query for the current row. */
rc = fts5Bm25GetData(pApi, pFts, &pData);
if( rc==SQLITE_OK ){
aFreq = pData->aFreq;
memset(aFreq, 0, sizeof(double) * pData->nPhrase);
rc = pApi->xInstCount(pFts, &nInst);
}
for(i=0; rc==SQLITE_OK && i<nInst; i++){
int ip; int ic; int io;
rc = pApi->xInst(pFts, i, &ip, &ic, &io);
if( rc==SQLITE_OK ){
double w = (nVal > ic) ? sqlite3_value_double(apVal[ic]) : 1.0;
aFreq[ip] += w;
}
}
/* Figure out the total size of the current row in tokens. */
if( rc==SQLITE_OK ){
int nTok;
rc = pApi->xColumnSize(pFts, -1, &nTok);
D = (double)nTok;
}
/* Determine and return the BM25 score for the current row. Or, if an
** error has occurred, throw an exception. */
if( rc==SQLITE_OK ){
for(i=0; i<pData->nPhrase; i++){
score += pData->aIDF[i] * (
( aFreq[i] * (k1 + 1.0) ) /
( aFreq[i] + k1 * (1 - b + b * D / pData->avgdl) )
);
}
sqlite3_result_double(pCtx, -1.0 * score);
}else{
sqlite3_result_error_code(pCtx, rc);
}
}
static int sqlite3Fts5AuxInit(fts5_api *pApi){
struct Builtin {
const char *zFunc; /* Function name (nul-terminated) */
void *pUserData; /* User-data pointer */
fts5_extension_function xFunc;/* Callback function */
void (*xDestroy)(void*); /* Destructor function */
} aBuiltin [] = {
{ "snippet", 0, fts5SnippetFunction, 0 },
{ "highlight", 0, fts5HighlightFunction, 0 },
{ "bm25", 0, fts5Bm25Function, 0 },
};
int rc = SQLITE_OK; /* Return code */
int i; /* To iterate through builtin functions */
for(i=0; rc==SQLITE_OK && i<ArraySize(aBuiltin); i++){
rc = pApi->xCreateFunction(pApi,
aBuiltin[i].zFunc,
aBuiltin[i].pUserData,
aBuiltin[i].xFunc,
aBuiltin[i].xDestroy
);
}
return rc;
}
#line 1 "fts5_buffer.c"
/*
** 2014 May 31
**
** The author disclaims copyright to this source code. In place of
** a legal notice, here is a blessing:
**
** May you do good and not evil.
** May you find forgiveness for yourself and forgive others.
** May you share freely, never taking more than you give.
**
******************************************************************************
*/
/* #include "third_party/sqlite3/fts5Int.h" */
static int sqlite3Fts5BufferSize(int *pRc, Fts5Buffer *pBuf, u32 nByte){
if( (u32)pBuf->nSpace<nByte ){
u64 nNew = pBuf->nSpace ? pBuf->nSpace : 64;
u8 *pNew;
while( nNew<nByte ){
nNew = nNew * 2;
}
pNew = sqlite3_realloc64(pBuf->p, nNew);
if( pNew==0 ){
*pRc = SQLITE_NOMEM;
return 1;
}else{
pBuf->nSpace = (int)nNew;
pBuf->p = pNew;
}
}
return 0;
}
/*
** Encode value iVal as an SQLite varint and append it to the buffer object
** pBuf. If an OOM error occurs, set the error code in p.
*/
static void sqlite3Fts5BufferAppendVarint(int *pRc, Fts5Buffer *pBuf, i64 iVal){
if( fts5BufferGrow(pRc, pBuf, 9) ) return;
pBuf->n += sqlite3Fts5PutVarint(&pBuf->p[pBuf->n], iVal);
}
static void sqlite3Fts5Put32(u8 *aBuf, int iVal){
aBuf[0] = (iVal>>24) & 0x00FF;
aBuf[1] = (iVal>>16) & 0x00FF;
aBuf[2] = (iVal>> 8) & 0x00FF;
aBuf[3] = (iVal>> 0) & 0x00FF;
}
static int sqlite3Fts5Get32(const u8 *aBuf){
return (int)((((u32)aBuf[0])<<24) + (aBuf[1]<<16) + (aBuf[2]<<8) + aBuf[3]);
}
/*
** Append buffer nData/pData to buffer pBuf. If an OOM error occurs, set
** the error code in p. If an error has already occurred when this function
** is called, it is a no-op.
*/
static void sqlite3Fts5BufferAppendBlob(
int *pRc,
Fts5Buffer *pBuf,
u32 nData,
const u8 *pData
){
assert_nc( *pRc || nData>=0 );
if( nData ){
if( fts5BufferGrow(pRc, pBuf, nData) ) return;
memcpy(&pBuf->p[pBuf->n], pData, nData);
pBuf->n += nData;
}
}
/*
** Append the nul-terminated string zStr to the buffer pBuf. This function
** ensures that the byte following the buffer data is set to 0x00, even
** though this byte is not included in the pBuf->n count.
*/
static void sqlite3Fts5BufferAppendString(
int *pRc,
Fts5Buffer *pBuf,
const char *zStr
){
int nStr = (int)strlen(zStr);
sqlite3Fts5BufferAppendBlob(pRc, pBuf, nStr+1, (const u8*)zStr);
pBuf->n--;
}
/*
** Argument zFmt is a printf() style format string. This function performs
** the printf() style processing, then appends the results to buffer pBuf.
**
** Like sqlite3Fts5BufferAppendString(), this function ensures that the byte
** following the buffer data is set to 0x00, even though this byte is not
** included in the pBuf->n count.
*/
static void sqlite3Fts5BufferAppendPrintf(
int *pRc,
Fts5Buffer *pBuf,
char *zFmt, ...
){
if( *pRc==SQLITE_OK ){
char *zTmp;
va_list ap;
va_start(ap, zFmt);
zTmp = sqlite3_vmprintf(zFmt, ap);
va_end(ap);
if( zTmp==0 ){
*pRc = SQLITE_NOMEM;
}else{
sqlite3Fts5BufferAppendString(pRc, pBuf, zTmp);
sqlite3_free(zTmp);
}
}
}
static char *sqlite3Fts5Mprintf(int *pRc, const char *zFmt, ...){
char *zRet = 0;
if( *pRc==SQLITE_OK ){
va_list ap;
va_start(ap, zFmt);
zRet = sqlite3_vmprintf(zFmt, ap);
va_end(ap);
if( zRet==0 ){
*pRc = SQLITE_NOMEM;
}
}
return zRet;
}
/*
** Free any buffer allocated by pBuf. Zero the structure before returning.
*/
static void sqlite3Fts5BufferFree(Fts5Buffer *pBuf){
sqlite3_free(pBuf->p);
memset(pBuf, 0, sizeof(Fts5Buffer));
}
/*
** Zero the contents of the buffer object. But do not free the associated
** memory allocation.
*/
static void sqlite3Fts5BufferZero(Fts5Buffer *pBuf){
pBuf->n = 0;
}
/*
** Set the buffer to contain nData/pData. If an OOM error occurs, leave an
** the error code in p. If an error has already occurred when this function
** is called, it is a no-op.
*/
static void sqlite3Fts5BufferSet(
int *pRc,
Fts5Buffer *pBuf,
int nData,
const u8 *pData
){
pBuf->n = 0;
sqlite3Fts5BufferAppendBlob(pRc, pBuf, nData, pData);
}
static int sqlite3Fts5PoslistNext64(
const u8 *a, int n, /* Buffer containing poslist */
int *pi, /* IN/OUT: Offset within a[] */
i64 *piOff /* IN/OUT: Current offset */
){
int i = *pi;
if( i>=n ){
/* EOF */
*piOff = -1;
return 1;
}else{
i64 iOff = *piOff;
int iVal;
fts5FastGetVarint32(a, i, iVal);
if( iVal<=1 ){
if( iVal==0 ){
*pi = i;
return 0;
}
fts5FastGetVarint32(a, i, iVal);
iOff = ((i64)iVal) << 32;
fts5FastGetVarint32(a, i, iVal);
if( iVal<2 ){
/* This is a corrupt record. So stop parsing it here. */
*piOff = -1;
return 1;
}
}
*piOff = iOff + ((iVal-2) & 0x7FFFFFFF);
*pi = i;
return 0;
}
}
/*
** Advance the iterator object passed as the only argument. Return true
** if the iterator reaches EOF, or false otherwise.
*/
static int sqlite3Fts5PoslistReaderNext(Fts5PoslistReader *pIter){
if( sqlite3Fts5PoslistNext64(pIter->a, pIter->n, &pIter->i, &pIter->iPos) ){
pIter->bEof = 1;
}
return pIter->bEof;
}
static int sqlite3Fts5PoslistReaderInit(
const u8 *a, int n, /* Poslist buffer to iterate through */
Fts5PoslistReader *pIter /* Iterator object to initialize */
){
memset(pIter, 0, sizeof(*pIter));
pIter->a = a;
pIter->n = n;
sqlite3Fts5PoslistReaderNext(pIter);
return pIter->bEof;
}
/*
** Append position iPos to the position list being accumulated in buffer
** pBuf, which must be already be large enough to hold the new data.
** The previous position written to this list is *piPrev. *piPrev is set
** to iPos before returning.
*/
static void sqlite3Fts5PoslistSafeAppend(
Fts5Buffer *pBuf,
i64 *piPrev,
i64 iPos
){
static const i64 colmask = ((i64)(0x7FFFFFFF)) << 32;
if( (iPos & colmask) != (*piPrev & colmask) ){
pBuf->p[pBuf->n++] = 1;
pBuf->n += sqlite3Fts5PutVarint(&pBuf->p[pBuf->n], (iPos>>32));
*piPrev = (iPos & colmask);
}
pBuf->n += sqlite3Fts5PutVarint(&pBuf->p[pBuf->n], (iPos-*piPrev)+2);
*piPrev = iPos;
}
static int sqlite3Fts5PoslistWriterAppend(
Fts5Buffer *pBuf,
Fts5PoslistWriter *pWriter,
i64 iPos
){
int rc = 0; /* Initialized only to suppress erroneous warning from Clang */
if( fts5BufferGrow(&rc, pBuf, 5+5+5) ) return rc;
sqlite3Fts5PoslistSafeAppend(pBuf, &pWriter->iPrev, iPos);
return SQLITE_OK;
}
static void *sqlite3Fts5MallocZero(int *pRc, sqlite3_int64 nByte){
void *pRet = 0;
if( *pRc==SQLITE_OK ){
pRet = sqlite3_malloc64(nByte);
if( pRet==0 ){
if( nByte>0 ) *pRc = SQLITE_NOMEM;
}else{
memset(pRet, 0, (size_t)nByte);
}
}
return pRet;
}
/*
** Return a nul-terminated copy of the string indicated by pIn. If nIn
** is non-negative, then it is the length of the string in bytes. Otherwise,
** the length of the string is determined using strlen().
**
** It is the responsibility of the caller to eventually free the returned
** buffer using sqlite3_free(). If an OOM error occurs, NULL is returned.
*/
static char *sqlite3Fts5Strndup(int *pRc, const char *pIn, int nIn){
char *zRet = 0;
if( *pRc==SQLITE_OK ){
if( nIn<0 ){
nIn = (int)strlen(pIn);
}
zRet = (char*)sqlite3_malloc(nIn+1);
if( zRet ){
memcpy(zRet, pIn, nIn);
zRet[nIn] = '\0';
}else{
*pRc = SQLITE_NOMEM;
}
}
return zRet;
}
/*
** Return true if character 't' may be part of an FTS5 bareword, or false
** otherwise. Characters that may be part of barewords:
**
** * All non-ASCII characters,
** * The 52 upper and lower case ASCII characters, and
** * The 10 integer ASCII characters.
** * The underscore character "_" (0x5F).
** * The unicode "subsitute" character (0x1A).
*/
static int sqlite3Fts5IsBareword(char t){
u8 aBareword[128] = {
0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, /* 0x00 .. 0x0F */
0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 1, 0, 0, 0, 0, 0, /* 0x10 .. 0x1F */
0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, /* 0x20 .. 0x2F */
1, 1, 1, 1, 1, 1, 1, 1, 1, 1, 0, 0, 0, 0, 0, 0, /* 0x30 .. 0x3F */
0, 1, 1, 1, 1, 1, 1, 1, 1, 1, 1, 1, 1, 1, 1, 1, /* 0x40 .. 0x4F */
1, 1, 1, 1, 1, 1, 1, 1, 1, 1, 1, 0, 0, 0, 0, 1, /* 0x50 .. 0x5F */
0, 1, 1, 1, 1, 1, 1, 1, 1, 1, 1, 1, 1, 1, 1, 1, /* 0x60 .. 0x6F */
1, 1, 1, 1, 1, 1, 1, 1, 1, 1, 1, 0, 0, 0, 0, 0 /* 0x70 .. 0x7F */
};
return (t & 0x80) || aBareword[(int)t];
}
/*************************************************************************
*/
typedef struct Fts5TermsetEntry Fts5TermsetEntry;
struct Fts5TermsetEntry {
char *pTerm;
int nTerm;
int iIdx; /* Index (main or aPrefix[] entry) */
Fts5TermsetEntry *pNext;
};
struct Fts5Termset {
Fts5TermsetEntry *apHash[512];
};
static int sqlite3Fts5TermsetNew(Fts5Termset **pp){
int rc = SQLITE_OK;
*pp = sqlite3Fts5MallocZero(&rc, sizeof(Fts5Termset));
return rc;
}
static int sqlite3Fts5TermsetAdd(
Fts5Termset *p,
int iIdx,
const char *pTerm, int nTerm,
int *pbPresent
){
int rc = SQLITE_OK;
*pbPresent = 0;
if( p ){
int i;
u32 hash = 13;
Fts5TermsetEntry *pEntry;
/* Calculate a hash value for this term. This is the same hash checksum
** used by the fts5_hash.c module. This is not important for correct
** operation of the module, but is necessary to ensure that some tests
** designed to produce hash table collisions really do work. */
for(i=nTerm-1; i>=0; i--){
hash = (hash << 3) ^ hash ^ pTerm[i];
}
hash = (hash << 3) ^ hash ^ iIdx;
hash = hash % ArraySize(p->apHash);
for(pEntry=p->apHash[hash]; pEntry; pEntry=pEntry->pNext){
if( pEntry->iIdx==iIdx
&& pEntry->nTerm==nTerm
&& memcmp(pEntry->pTerm, pTerm, nTerm)==0
){
*pbPresent = 1;
break;
}
}
if( pEntry==0 ){
pEntry = sqlite3Fts5MallocZero(&rc, sizeof(Fts5TermsetEntry) + nTerm);
if( pEntry ){
pEntry->pTerm = (char*)&pEntry[1];
pEntry->nTerm = nTerm;
pEntry->iIdx = iIdx;
memcpy(pEntry->pTerm, pTerm, nTerm);
pEntry->pNext = p->apHash[hash];
p->apHash[hash] = pEntry;
}
}
}
return rc;
}
static void sqlite3Fts5TermsetFree(Fts5Termset *p){
if( p ){
u32 i;
for(i=0; i<ArraySize(p->apHash); i++){
Fts5TermsetEntry *pEntry = p->apHash[i];
while( pEntry ){
Fts5TermsetEntry *pDel = pEntry;
pEntry = pEntry->pNext;
sqlite3_free(pDel);
}
}
sqlite3_free(p);
}
}
#line 1 "fts5_config.c"
/*
** 2014 Jun 09
**
** The author disclaims copyright to this source code. In place of
** a legal notice, here is a blessing:
**
** May you do good and not evil.
** May you find forgiveness for yourself and forgive others.
** May you share freely, never taking more than you give.
**
******************************************************************************
**
** This is an SQLite module implementing full-text search.
*/
/* #include "third_party/sqlite3/fts5Int.h" */
#define FTS5_DEFAULT_PAGE_SIZE 4050
#define FTS5_DEFAULT_AUTOMERGE 4
#define FTS5_DEFAULT_USERMERGE 4
#define FTS5_DEFAULT_CRISISMERGE 16
#define FTS5_DEFAULT_HASHSIZE (1024*1024)
/* Maximum allowed page size */
#define FTS5_MAX_PAGE_SIZE (64*1024)
static int fts5_iswhitespace(char x){
return (x==' ');
}
static int fts5_isopenquote(char x){
return (x=='"' || x=='\'' || x=='[' || x=='`');
}
/*
** Argument pIn points to a character that is part of a nul-terminated
** string. Return a pointer to the first character following *pIn in
** the string that is not a white-space character.
*/
static const char *fts5ConfigSkipWhitespace(const char *pIn){
const char *p = pIn;
if( p ){
while( fts5_iswhitespace(*p) ){ p++; }
}
return p;
}
/*
** Argument pIn points to a character that is part of a nul-terminated
** string. Return a pointer to the first character following *pIn in
** the string that is not a "bareword" character.
*/
static const char *fts5ConfigSkipBareword(const char *pIn){
const char *p = pIn;
while ( sqlite3Fts5IsBareword(*p) ) p++;
if( p==pIn ) p = 0;
return p;
}
static int fts5_isdigit(char a){
return (a>='0' && a<='9');
}
static const char *fts5ConfigSkipLiteral(const char *pIn){
const char *p = pIn;
switch( *p ){
case 'n': case 'N':
if( sqlite3_strnicmp("null", p, 4)==0 ){
p = &p[4];
}else{
p = 0;
}
break;
case 'x': case 'X':
p++;
if( *p=='\'' ){
p++;
while( (*p>='a' && *p<='f')
|| (*p>='A' && *p<='F')
|| (*p>='0' && *p<='9')
){
p++;
}
if( *p=='\'' && 0==((p-pIn)%2) ){
p++;
}else{
p = 0;
}
}else{
p = 0;
}
break;
case '\'':
p++;
while( p ){
if( *p=='\'' ){
p++;
if( *p!='\'' ) break;
}
p++;
if( *p==0 ) p = 0;
}
break;
default:
/* maybe a number */
if( *p=='+' || *p=='-' ) p++;
while( fts5_isdigit(*p) ) p++;
/* At this point, if the literal was an integer, the parse is
** finished. Or, if it is a floating point value, it may continue
** with either a decimal point or an 'E' character. */
if( *p=='.' && fts5_isdigit(p[1]) ){
p += 2;
while( fts5_isdigit(*p) ) p++;
}
if( p==pIn ) p = 0;
break;
}
return p;
}
/*
** The first character of the string pointed to by argument z is guaranteed
** to be an open-quote character (see function fts5_isopenquote()).
**
** This function searches for the corresponding close-quote character within
** the string and, if found, dequotes the string in place and adds a new
** nul-terminator byte.
**
** If the close-quote is found, the value returned is the byte offset of
** the character immediately following it. Or, if the close-quote is not
** found, -1 is returned. If -1 is returned, the buffer is left in an
** undefined state.
*/
static int fts5Dequote(char *z){
char q;
int iIn = 1;
int iOut = 0;
q = z[0];
/* Set stack variable q to the close-quote character */
assert( q=='[' || q=='\'' || q=='"' || q=='`' );
if( q=='[' ) q = ']';
while( z[iIn] ){
if( z[iIn]==q ){
if( z[iIn+1]!=q ){
/* Character iIn was the close quote. */
iIn++;
break;
}else{
/* Character iIn and iIn+1 form an escaped quote character. Skip
** the input cursor past both and copy a single quote character
** to the output buffer. */
iIn += 2;
z[iOut++] = q;
}
}else{
z[iOut++] = z[iIn++];
}
}
z[iOut] = '\0';
return iIn;
}
/*
** Convert an SQL-style quoted string into a normal string by removing
** the quote characters. The conversion is done in-place. If the
** input does not begin with a quote character, then this routine
** is a no-op.
**
** Examples:
**
** "abc" becomes abc
** 'xyz' becomes xyz
** [pqr] becomes pqr
** `mno` becomes mno
*/
static void sqlite3Fts5Dequote(char *z){
char quote; /* Quote character (if any ) */
assert( 0==fts5_iswhitespace(z[0]) );
quote = z[0];
if( quote=='[' || quote=='\'' || quote=='"' || quote=='`' ){
fts5Dequote(z);
}
}
struct Fts5Enum {
const char *zName;
int eVal;
};
typedef struct Fts5Enum Fts5Enum;
static int fts5ConfigSetEnum(
const Fts5Enum *aEnum,
const char *zEnum,
int *peVal
){
int nEnum = (int)strlen(zEnum);
int i;
int iVal = -1;
for(i=0; aEnum[i].zName; i++){
if( sqlite3_strnicmp(aEnum[i].zName, zEnum, nEnum)==0 ){
if( iVal>=0 ) return SQLITE_ERROR;
iVal = aEnum[i].eVal;
}
}
*peVal = iVal;
return iVal<0 ? SQLITE_ERROR : SQLITE_OK;
}
/*
** Parse a "special" CREATE VIRTUAL TABLE directive and update
** configuration object pConfig as appropriate.
**
** If successful, object pConfig is updated and SQLITE_OK returned. If
** an error occurs, an SQLite error code is returned and an error message
** may be left in *pzErr. It is the responsibility of the caller to
** eventually free any such error message using sqlite3_free().
*/
static int fts5ConfigParseSpecial(
Fts5Global *pGlobal,
Fts5Config *pConfig, /* Configuration object to update */
const char *zCmd, /* Special command to parse */
const char *zArg, /* Argument to parse */
char **pzErr /* OUT: Error message */
){
int rc = SQLITE_OK;
int nCmd = (int)strlen(zCmd);
if( sqlite3_strnicmp("prefix", zCmd, nCmd)==0 ){
const int nByte = sizeof(int) * FTS5_MAX_PREFIX_INDEXES;
const char *p;
int bFirst = 1;
if( pConfig->aPrefix==0 ){
pConfig->aPrefix = sqlite3Fts5MallocZero(&rc, nByte);
if( rc ) return rc;
}
p = zArg;
while( 1 ){
int nPre = 0;
while( p[0]==' ' ) p++;
if( bFirst==0 && p[0]==',' ){
p++;
while( p[0]==' ' ) p++;
}else if( p[0]=='\0' ){
break;
}
if( p[0]<'0' || p[0]>'9' ){
*pzErr = sqlite3_mprintf("malformed prefix=... directive");
rc = SQLITE_ERROR;
break;
}
if( pConfig->nPrefix==FTS5_MAX_PREFIX_INDEXES ){
*pzErr = sqlite3_mprintf(
"too many prefix indexes (max %d)", FTS5_MAX_PREFIX_INDEXES
);
rc = SQLITE_ERROR;
break;
}
while( p[0]>='0' && p[0]<='9' && nPre<1000 ){
nPre = nPre*10 + (p[0] - '0');
p++;
}
if( nPre<=0 || nPre>=1000 ){
*pzErr = sqlite3_mprintf("prefix length out of range (max 999)");
rc = SQLITE_ERROR;
break;
}
pConfig->aPrefix[pConfig->nPrefix] = nPre;
pConfig->nPrefix++;
bFirst = 0;
}
assert( pConfig->nPrefix<=FTS5_MAX_PREFIX_INDEXES );
return rc;
}
if( sqlite3_strnicmp("tokenize", zCmd, nCmd)==0 ){
const char *p = (const char*)zArg;
sqlite3_int64 nArg = strlen(zArg) + 1;
char **azArg = sqlite3Fts5MallocZero(&rc, sizeof(char*) * nArg);
char *pDel = sqlite3Fts5MallocZero(&rc, nArg * 2);
char *pSpace = pDel;
if( azArg && pSpace ){
if( pConfig->pTok ){
*pzErr = sqlite3_mprintf("multiple tokenize=... directives");
rc = SQLITE_ERROR;
}else{
for(nArg=0; p && *p; nArg++){
const char *p2 = fts5ConfigSkipWhitespace(p);
if( *p2=='\'' ){
p = fts5ConfigSkipLiteral(p2);
}else{
p = fts5ConfigSkipBareword(p2);
}
if( p ){
memcpy(pSpace, p2, p-p2);
azArg[nArg] = pSpace;
sqlite3Fts5Dequote(pSpace);
pSpace += (p - p2) + 1;
p = fts5ConfigSkipWhitespace(p);
}
}
if( p==0 ){
*pzErr = sqlite3_mprintf("parse error in tokenize directive");
rc = SQLITE_ERROR;
}else{
rc = sqlite3Fts5GetTokenizer(pGlobal,
(const char**)azArg, (int)nArg, pConfig,
pzErr
);
}
}
}
sqlite3_free(azArg);
sqlite3_free(pDel);
return rc;
}
if( sqlite3_strnicmp("content", zCmd, nCmd)==0 ){
if( pConfig->eContent!=FTS5_CONTENT_NORMAL ){
*pzErr = sqlite3_mprintf("multiple content=... directives");
rc = SQLITE_ERROR;
}else{
if( zArg[0] ){
pConfig->eContent = FTS5_CONTENT_EXTERNAL;
pConfig->zContent = sqlite3Fts5Mprintf(&rc, "%Q.%Q", pConfig->zDb,zArg);
}else{
pConfig->eContent = FTS5_CONTENT_NONE;
}
}
return rc;
}
if( sqlite3_strnicmp("content_rowid", zCmd, nCmd)==0 ){
if( pConfig->zContentRowid ){
*pzErr = sqlite3_mprintf("multiple content_rowid=... directives");
rc = SQLITE_ERROR;
}else{
pConfig->zContentRowid = sqlite3Fts5Strndup(&rc, zArg, -1);
}
return rc;
}
if( sqlite3_strnicmp("columnsize", zCmd, nCmd)==0 ){
if( (zArg[0]!='0' && zArg[0]!='1') || zArg[1]!='\0' ){
*pzErr = sqlite3_mprintf("malformed columnsize=... directive");
rc = SQLITE_ERROR;
}else{
pConfig->bColumnsize = (zArg[0]=='1');
}
return rc;
}
if( sqlite3_strnicmp("detail", zCmd, nCmd)==0 ){
const Fts5Enum aDetail[] = {
{ "none", FTS5_DETAIL_NONE },
{ "full", FTS5_DETAIL_FULL },
{ "columns", FTS5_DETAIL_COLUMNS },
{ 0, 0 }
};
if( (rc = fts5ConfigSetEnum(aDetail, zArg, &pConfig->eDetail)) ){
*pzErr = sqlite3_mprintf("malformed detail=... directive");
}
return rc;
}
*pzErr = sqlite3_mprintf("unrecognized option: \"%.*s\"", nCmd, zCmd);
return SQLITE_ERROR;
}
/*
** Allocate an instance of the default tokenizer ("simple") at
** Fts5Config.pTokenizer. Return SQLITE_OK if successful, or an SQLite error
** code if an error occurs.
*/
static int fts5ConfigDefaultTokenizer(Fts5Global *pGlobal, Fts5Config *pConfig){
assert( pConfig->pTok==0 && pConfig->pTokApi==0 );
return sqlite3Fts5GetTokenizer(pGlobal, 0, 0, pConfig, 0);
}
/*
** Gobble up the first bareword or quoted word from the input buffer zIn.
** Return a pointer to the character immediately following the last in
** the gobbled word if successful, or a NULL pointer otherwise (failed
** to find close-quote character).
**
** Before returning, set pzOut to point to a new buffer containing a
** nul-terminated, dequoted copy of the gobbled word. If the word was
** quoted, *pbQuoted is also set to 1 before returning.
**
** If *pRc is other than SQLITE_OK when this function is called, it is
** a no-op (NULL is returned). Otherwise, if an OOM occurs within this
** function, *pRc is set to SQLITE_NOMEM before returning. *pRc is *not*
** set if a parse error (failed to find close quote) occurs.
*/
static const char *fts5ConfigGobbleWord(
int *pRc, /* IN/OUT: Error code */
const char *zIn, /* Buffer to gobble string/bareword from */
char **pzOut, /* OUT: malloc'd buffer containing str/bw */
int *pbQuoted /* OUT: Set to true if dequoting required */
){
const char *zRet = 0;
sqlite3_int64 nIn = strlen(zIn);
char *zOut = sqlite3_malloc64(nIn+1);
assert( *pRc==SQLITE_OK );
*pbQuoted = 0;
*pzOut = 0;
if( zOut==0 ){
*pRc = SQLITE_NOMEM;
}else{
memcpy(zOut, zIn, (size_t)(nIn+1));
if( fts5_isopenquote(zOut[0]) ){
int ii = fts5Dequote(zOut);
zRet = &zIn[ii];
*pbQuoted = 1;
}else{
zRet = fts5ConfigSkipBareword(zIn);
if( zRet ){
zOut[zRet-zIn] = '\0';
}
}
}
if( zRet==0 ){
sqlite3_free(zOut);
}else{
*pzOut = zOut;
}
return zRet;
}
static int fts5ConfigParseColumn(
Fts5Config *p,
char *zCol,
char *zArg,
char **pzErr
){
int rc = SQLITE_OK;
if( 0==sqlite3_stricmp(zCol, FTS5_RANK_NAME)
|| 0==sqlite3_stricmp(zCol, FTS5_ROWID_NAME)
){
*pzErr = sqlite3_mprintf("reserved fts5 column name: %s", zCol);
rc = SQLITE_ERROR;
}else if( zArg ){
if( 0==sqlite3_stricmp(zArg, "unindexed") ){
p->abUnindexed[p->nCol] = 1;
}else{
*pzErr = sqlite3_mprintf("unrecognized column option: %s", zArg);
rc = SQLITE_ERROR;
}
}
p->azCol[p->nCol++] = zCol;
return rc;
}
/*
** Populate the Fts5Config.zContentExprlist string.
*/
static int fts5ConfigMakeExprlist(Fts5Config *p){
int i;
int rc = SQLITE_OK;
Fts5Buffer buf = {0, 0, 0};
sqlite3Fts5BufferAppendPrintf(&rc, &buf, "T.%Q", p->zContentRowid);
if( p->eContent!=FTS5_CONTENT_NONE ){
for(i=0; i<p->nCol; i++){
if( p->eContent==FTS5_CONTENT_EXTERNAL ){
sqlite3Fts5BufferAppendPrintf(&rc, &buf, ", T.%Q", p->azCol[i]);
}else{
sqlite3Fts5BufferAppendPrintf(&rc, &buf, ", T.c%d", i);
}
}
}
assert( p->zContentExprlist==0 );
p->zContentExprlist = (char*)buf.p;
return rc;
}
/*
** Arguments nArg/azArg contain the string arguments passed to the xCreate
** or xConnect method of the virtual table. This function attempts to
** allocate an instance of Fts5Config containing the results of parsing
** those arguments.
**
** If successful, SQLITE_OK is returned and *ppOut is set to point to the
** new Fts5Config object. If an error occurs, an SQLite error code is
** returned, *ppOut is set to NULL and an error message may be left in
** *pzErr. It is the responsibility of the caller to eventually free any
** such error message using sqlite3_free().
*/
static int sqlite3Fts5ConfigParse(
Fts5Global *pGlobal,
sqlite3 *db,
int nArg, /* Number of arguments */
const char **azArg, /* Array of nArg CREATE VIRTUAL TABLE args */
Fts5Config **ppOut, /* OUT: Results of parse */
char **pzErr /* OUT: Error message */
){
int rc = SQLITE_OK; /* Return code */
Fts5Config *pRet; /* New object to return */
int i;
sqlite3_int64 nByte;
*ppOut = pRet = (Fts5Config*)sqlite3_malloc(sizeof(Fts5Config));
if( pRet==0 ) return SQLITE_NOMEM;
memset(pRet, 0, sizeof(Fts5Config));
pRet->db = db;
pRet->iCookie = -1;
nByte = nArg * (sizeof(char*) + sizeof(u8));
pRet->azCol = (char**)sqlite3Fts5MallocZero(&rc, nByte);
pRet->abUnindexed = (u8*)&pRet->azCol[nArg];
pRet->zDb = sqlite3Fts5Strndup(&rc, azArg[1], -1);
pRet->zName = sqlite3Fts5Strndup(&rc, azArg[2], -1);
pRet->bColumnsize = 1;
pRet->eDetail = FTS5_DETAIL_FULL;
#ifdef SQLITE_DEBUG
pRet->bPrefixIndex = 1;
#endif
if( rc==SQLITE_OK && sqlite3_stricmp(pRet->zName, FTS5_RANK_NAME)==0 ){
*pzErr = sqlite3_mprintf("reserved fts5 table name: %s", pRet->zName);
rc = SQLITE_ERROR;
}
for(i=3; rc==SQLITE_OK && i<nArg; i++){
const char *zOrig = azArg[i];
const char *z;
char *zOne = 0;
char *zTwo = 0;
int bOption = 0;
int bMustBeCol = 0;
z = fts5ConfigGobbleWord(&rc, zOrig, &zOne, &bMustBeCol);
z = fts5ConfigSkipWhitespace(z);
if( z && *z=='=' ){
bOption = 1;
z++;
if( bMustBeCol ) z = 0;
}
z = fts5ConfigSkipWhitespace(z);
if( z && z[0] ){
int bDummy;
z = fts5ConfigGobbleWord(&rc, z, &zTwo, &bDummy);
if( z && z[0] ) z = 0;
}
if( rc==SQLITE_OK ){
if( z==0 ){
*pzErr = sqlite3_mprintf("parse error in \"%s\"", zOrig);
rc = SQLITE_ERROR;
}else{
if( bOption ){
rc = fts5ConfigParseSpecial(pGlobal, pRet, zOne, zTwo?zTwo:"", pzErr);
}else{
rc = fts5ConfigParseColumn(pRet, zOne, zTwo, pzErr);
zOne = 0;
}
}
}
sqlite3_free(zOne);
sqlite3_free(zTwo);
}
/* If a tokenizer= option was successfully parsed, the tokenizer has
** already been allocated. Otherwise, allocate an instance of the default
** tokenizer (unicode61) now. */
if( rc==SQLITE_OK && pRet->pTok==0 ){
rc = fts5ConfigDefaultTokenizer(pGlobal, pRet);
}
/* If no zContent option was specified, fill in the default values. */
if( rc==SQLITE_OK && pRet->zContent==0 ){
const char *zTail = 0;
assert( pRet->eContent==FTS5_CONTENT_NORMAL
|| pRet->eContent==FTS5_CONTENT_NONE
);
if( pRet->eContent==FTS5_CONTENT_NORMAL ){
zTail = "content";
}else if( pRet->bColumnsize ){
zTail = "docsize";
}
if( zTail ){
pRet->zContent = sqlite3Fts5Mprintf(
&rc, "%Q.'%q_%s'", pRet->zDb, pRet->zName, zTail
);
}
}
if( rc==SQLITE_OK && pRet->zContentRowid==0 ){
pRet->zContentRowid = sqlite3Fts5Strndup(&rc, "rowid", -1);
}
/* Formulate the zContentExprlist text */
if( rc==SQLITE_OK ){
rc = fts5ConfigMakeExprlist(pRet);
}
if( rc!=SQLITE_OK ){
sqlite3Fts5ConfigFree(pRet);
*ppOut = 0;
}
return rc;
}
/*
** Free the configuration object passed as the only argument.
*/
static void sqlite3Fts5ConfigFree(Fts5Config *pConfig){
if( pConfig ){
int i;
if( pConfig->pTok ){
pConfig->pTokApi->xDelete(pConfig->pTok);
}
sqlite3_free(pConfig->zDb);
sqlite3_free(pConfig->zName);
for(i=0; i<pConfig->nCol; i++){
sqlite3_free(pConfig->azCol[i]);
}
sqlite3_free(pConfig->azCol);
sqlite3_free(pConfig->aPrefix);
sqlite3_free(pConfig->zRank);
sqlite3_free(pConfig->zRankArgs);
sqlite3_free(pConfig->zContent);
sqlite3_free(pConfig->zContentRowid);
sqlite3_free(pConfig->zContentExprlist);
sqlite3_free(pConfig);
}
}
/*
** Call sqlite3_declare_vtab() based on the contents of the configuration
** object passed as the only argument. Return SQLITE_OK if successful, or
** an SQLite error code if an error occurs.
*/
static int sqlite3Fts5ConfigDeclareVtab(Fts5Config *pConfig){
int i;
int rc = SQLITE_OK;
char *zSql;
zSql = sqlite3Fts5Mprintf(&rc, "CREATE TABLE x(");
for(i=0; zSql && i<pConfig->nCol; i++){
const char *zSep = (i==0?"":", ");
zSql = sqlite3Fts5Mprintf(&rc, "%z%s%Q", zSql, zSep, pConfig->azCol[i]);
}
zSql = sqlite3Fts5Mprintf(&rc, "%z, %Q HIDDEN, %s HIDDEN)",
zSql, pConfig->zName, FTS5_RANK_NAME
);
assert( zSql || rc==SQLITE_NOMEM );
if( zSql ){
rc = sqlite3_declare_vtab(pConfig->db, zSql);
sqlite3_free(zSql);
}
return rc;
}
/*
** Tokenize the text passed via the second and third arguments.
**
** The callback is invoked once for each token in the input text. The
** arguments passed to it are, in order:
**
** void *pCtx // Copy of 4th argument to sqlite3Fts5Tokenize()
** const char *pToken // Pointer to buffer containing token
** int nToken // Size of token in bytes
** int iStart // Byte offset of start of token within input text
** int iEnd // Byte offset of end of token within input text
** int iPos // Position of token in input (first token is 0)
**
** If the callback returns a non-zero value the tokenization is abandoned
** and no further callbacks are issued.
**
** This function returns SQLITE_OK if successful or an SQLite error code
** if an error occurs. If the tokenization was abandoned early because
** the callback returned SQLITE_DONE, this is not an error and this function
** still returns SQLITE_OK. Or, if the tokenization was abandoned early
** because the callback returned another non-zero value, it is assumed
** to be an SQLite error code and returned to the caller.
*/
static int sqlite3Fts5Tokenize(
Fts5Config *pConfig, /* FTS5 Configuration object */
int flags, /* FTS5_TOKENIZE_* flags */
const char *pText, int nText, /* Text to tokenize */
void *pCtx, /* Context passed to xToken() */
int (*xToken)(void*, int, const char*, int, int, int) /* Callback */
){
if( pText==0 ) return SQLITE_OK;
return pConfig->pTokApi->xTokenize(
pConfig->pTok, pCtx, flags, pText, nText, xToken
);
}
/*
** Argument pIn points to the first character in what is expected to be
** a comma-separated list of SQL literals followed by a ')' character.
** If it actually is this, return a pointer to the ')'. Otherwise, return
** NULL to indicate a parse error.
*/
static const char *fts5ConfigSkipArgs(const char *pIn){
const char *p = pIn;
while( 1 ){
p = fts5ConfigSkipWhitespace(p);
p = fts5ConfigSkipLiteral(p);
p = fts5ConfigSkipWhitespace(p);
if( p==0 || *p==')' ) break;
if( *p!=',' ){
p = 0;
break;
}
p++;
}
return p;
}
/*
** Parameter zIn contains a rank() function specification. The format of
** this is:
**
** + Bareword (function name)
** + Open parenthesis - "("
** + Zero or more SQL literals in a comma separated list
** + Close parenthesis - ")"
*/
static int sqlite3Fts5ConfigParseRank(
const char *zIn, /* Input string */
char **pzRank, /* OUT: Rank function name */
char **pzRankArgs /* OUT: Rank function arguments */
){
const char *p = zIn;
const char *pRank;
char *zRank = 0;
char *zRankArgs = 0;
int rc = SQLITE_OK;
*pzRank = 0;
*pzRankArgs = 0;
if( p==0 ){
rc = SQLITE_ERROR;
}else{
p = fts5ConfigSkipWhitespace(p);
pRank = p;
p = fts5ConfigSkipBareword(p);
if( p ){
zRank = sqlite3Fts5MallocZero(&rc, 1 + p - pRank);
if( zRank ) memcpy(zRank, pRank, p-pRank);
}else{
rc = SQLITE_ERROR;
}
if( rc==SQLITE_OK ){
p = fts5ConfigSkipWhitespace(p);
if( *p!='(' ) rc = SQLITE_ERROR;
p++;
}
if( rc==SQLITE_OK ){
const char *pArgs;
p = fts5ConfigSkipWhitespace(p);
pArgs = p;
if( *p!=')' ){
p = fts5ConfigSkipArgs(p);
if( p==0 ){
rc = SQLITE_ERROR;
}else{
zRankArgs = sqlite3Fts5MallocZero(&rc, 1 + p - pArgs);
if( zRankArgs ) memcpy(zRankArgs, pArgs, p-pArgs);
}
}
}
}
if( rc!=SQLITE_OK ){
sqlite3_free(zRank);
assert( zRankArgs==0 );
}else{
*pzRank = zRank;
*pzRankArgs = zRankArgs;
}
return rc;
}
static int sqlite3Fts5ConfigSetValue(
Fts5Config *pConfig,
const char *zKey,
sqlite3_value *pVal,
int *pbBadkey
){
int rc = SQLITE_OK;
if( 0==sqlite3_stricmp(zKey, "pgsz") ){
int pgsz = 0;
if( SQLITE_INTEGER==sqlite3_value_numeric_type(pVal) ){
pgsz = sqlite3_value_int(pVal);
}
if( pgsz<32 || pgsz>FTS5_MAX_PAGE_SIZE ){
*pbBadkey = 1;
}else{
pConfig->pgsz = pgsz;
}
}
else if( 0==sqlite3_stricmp(zKey, "hashsize") ){
int nHashSize = -1;
if( SQLITE_INTEGER==sqlite3_value_numeric_type(pVal) ){
nHashSize = sqlite3_value_int(pVal);
}
if( nHashSize<=0 ){
*pbBadkey = 1;
}else{
pConfig->nHashSize = nHashSize;
}
}
else if( 0==sqlite3_stricmp(zKey, "automerge") ){
int nAutomerge = -1;
if( SQLITE_INTEGER==sqlite3_value_numeric_type(pVal) ){
nAutomerge = sqlite3_value_int(pVal);
}
if( nAutomerge<0 || nAutomerge>64 ){
*pbBadkey = 1;
}else{
if( nAutomerge==1 ) nAutomerge = FTS5_DEFAULT_AUTOMERGE;
pConfig->nAutomerge = nAutomerge;
}
}
else if( 0==sqlite3_stricmp(zKey, "usermerge") ){
int nUsermerge = -1;
if( SQLITE_INTEGER==sqlite3_value_numeric_type(pVal) ){
nUsermerge = sqlite3_value_int(pVal);
}
if( nUsermerge<2 || nUsermerge>16 ){
*pbBadkey = 1;
}else{
pConfig->nUsermerge = nUsermerge;
}
}
else if( 0==sqlite3_stricmp(zKey, "crisismerge") ){
int nCrisisMerge = -1;
if( SQLITE_INTEGER==sqlite3_value_numeric_type(pVal) ){
nCrisisMerge = sqlite3_value_int(pVal);
}
if( nCrisisMerge<0 ){
*pbBadkey = 1;
}else{
if( nCrisisMerge<=1 ) nCrisisMerge = FTS5_DEFAULT_CRISISMERGE;
if( nCrisisMerge>=FTS5_MAX_SEGMENT ) nCrisisMerge = FTS5_MAX_SEGMENT-1;
pConfig->nCrisisMerge = nCrisisMerge;
}
}
else if( 0==sqlite3_stricmp(zKey, "rank") ){
const char *zIn = (const char*)sqlite3_value_text(pVal);
char *zRank;
char *zRankArgs;
rc = sqlite3Fts5ConfigParseRank(zIn, &zRank, &zRankArgs);
if( rc==SQLITE_OK ){
sqlite3_free(pConfig->zRank);
sqlite3_free(pConfig->zRankArgs);
pConfig->zRank = zRank;
pConfig->zRankArgs = zRankArgs;
}else if( rc==SQLITE_ERROR ){
rc = SQLITE_OK;
*pbBadkey = 1;
}
}else{
*pbBadkey = 1;
}
return rc;
}
/*
** Load the contents of the %_config table into memory.
*/
static int sqlite3Fts5ConfigLoad(Fts5Config *pConfig, int iCookie){
const char *zSelect = "SELECT k, v FROM %Q.'%q_config'";
char *zSql;
sqlite3_stmt *p = 0;
int rc = SQLITE_OK;
int iVersion = 0;
/* Set default values */
pConfig->pgsz = FTS5_DEFAULT_PAGE_SIZE;
pConfig->nAutomerge = FTS5_DEFAULT_AUTOMERGE;
pConfig->nUsermerge = FTS5_DEFAULT_USERMERGE;
pConfig->nCrisisMerge = FTS5_DEFAULT_CRISISMERGE;
pConfig->nHashSize = FTS5_DEFAULT_HASHSIZE;
zSql = sqlite3Fts5Mprintf(&rc, zSelect, pConfig->zDb, pConfig->zName);
if( zSql ){
rc = sqlite3_prepare_v2(pConfig->db, zSql, -1, &p, 0);
sqlite3_free(zSql);
}
assert( rc==SQLITE_OK || p==0 );
if( rc==SQLITE_OK ){
while( SQLITE_ROW==sqlite3_step(p) ){
const char *zK = (const char*)sqlite3_column_text(p, 0);
sqlite3_value *pVal = sqlite3_column_value(p, 1);
if( 0==sqlite3_stricmp(zK, "version") ){
iVersion = sqlite3_value_int(pVal);
}else{
int bDummy = 0;
sqlite3Fts5ConfigSetValue(pConfig, zK, pVal, &bDummy);
}
}
rc = sqlite3_finalize(p);
}
if( rc==SQLITE_OK && iVersion!=FTS5_CURRENT_VERSION ){
rc = SQLITE_ERROR;
if( pConfig->pzErrmsg ){
assert( 0==*pConfig->pzErrmsg );
*pConfig->pzErrmsg = sqlite3_mprintf(
"invalid fts5 file format (found %d, expected %d) - run 'rebuild'",
iVersion, FTS5_CURRENT_VERSION
);
}
}
if( rc==SQLITE_OK ){
pConfig->iCookie = iCookie;
}
return rc;
}
#line 1 "fts5_expr.c"
/*
** 2014 May 31
**
** The author disclaims copyright to this source code. In place of
** a legal notice, here is a blessing:
**
** May you do good and not evil.
** May you find forgiveness for yourself and forgive others.
** May you share freely, never taking more than you give.
**
******************************************************************************
**
*/
/* #include "third_party/sqlite3/fts5Int.h" */
/* #include "third_party/sqlite3/fts5parse.h" */
/*
** All token types in the generated fts5parse.h file are greater than 0.
*/
#define FTS5_EOF 0
#define FTS5_LARGEST_INT64 (0xffffffff|(((i64)0x7fffffff)<<32))
typedef struct Fts5ExprTerm Fts5ExprTerm;
/*
** Functions generated by lemon from fts5parse.y.
*/
// static void *sqlite3Fts5ParserAlloc(void *(*mallocProc)(u64));
// static void sqlite3Fts5ParserFree(void *, void (*freeProc)(void *));
// static void sqlite3Fts5Parser(void *, int, Fts5Token, Fts5Parse *);
#ifndef NDEBUG
#include "libc/stdio/stdio.h"
static void sqlite3Fts5ParserTrace(FILE *, char *);
#endif
// static int sqlite3Fts5ParserFallback(int);
struct Fts5Expr {
Fts5Index *pIndex;
Fts5Config *pConfig;
Fts5ExprNode *pRoot;
int bDesc; /* Iterate in descending rowid order */
int nPhrase; /* Number of phrases in expression */
Fts5ExprPhrase **apExprPhrase; /* Pointers to phrase objects */
};
/*
** eType:
** Expression node type. Always one of:
**
** FTS5_AND (nChild, apChild valid)
** FTS5_OR (nChild, apChild valid)
** FTS5_NOT (nChild, apChild valid)
** FTS5_STRING (pNear valid)
** FTS5_TERM (pNear valid)
*/
struct Fts5ExprNode {
int eType; /* Node type */
int bEof; /* True at EOF */
int bNomatch; /* True if entry is not a match */
/* Next method for this node. */
int (*xNext)(Fts5Expr*, Fts5ExprNode*, int, i64);
i64 iRowid; /* Current rowid */
Fts5ExprNearset *pNear; /* For FTS5_STRING - cluster of phrases */
/* Child nodes. For a NOT node, this array always contains 2 entries. For
** AND or OR nodes, it contains 2 or more entries. */
int nChild; /* Number of child nodes */
Fts5ExprNode *apChild[1]; /* Array of child nodes */
};
#define Fts5NodeIsString(p) ((p)->eType==FTS5_TERM || (p)->eType==FTS5_STRING)
/*
** Invoke the xNext method of an Fts5ExprNode object. This macro should be
** used as if it has the same signature as the xNext() methods themselves.
*/
#define fts5ExprNodeNext(a,b,c,d) (b)->xNext((a), (b), (c), (d))
/*
** An instance of the following structure represents a single search term
** or term prefix.
*/
struct Fts5ExprTerm {
u8 bPrefix; /* True for a prefix term */
u8 bFirst; /* True if token must be first in column */
char *zTerm; /* nul-terminated term */
Fts5IndexIter *pIter; /* Iterator for this term */
Fts5ExprTerm *pSynonym; /* Pointer to first in list of synonyms */
};
/*
** A phrase. One or more terms that must appear in a contiguous sequence
** within a document for it to match.
*/
struct Fts5ExprPhrase {
Fts5ExprNode *pNode; /* FTS5_STRING node this phrase is part of */
Fts5Buffer poslist; /* Current position list */
int nTerm; /* Number of entries in aTerm[] */
Fts5ExprTerm aTerm[1]; /* Terms that make up this phrase */
};
/*
** One or more phrases that must appear within a certain token distance of
** each other within each matching document.
*/
struct Fts5ExprNearset {
int nNear; /* NEAR parameter */
Fts5Colset *pColset; /* Columns to search (NULL -> all columns) */
int nPhrase; /* Number of entries in aPhrase[] array */
Fts5ExprPhrase *apPhrase[1]; /* Array of phrase pointers */
};
/*
** Parse context.
*/
struct Fts5Parse {
Fts5Config *pConfig;
char *zErr;
int rc;
int nPhrase; /* Size of apPhrase array */
Fts5ExprPhrase **apPhrase; /* Array of all phrases */
Fts5ExprNode *pExpr; /* Result of a successful parse */
int bPhraseToAnd; /* Convert "a+b" to "a AND b" */
};
static void sqlite3Fts5ParseError(Fts5Parse *pParse, const char *zFmt, ...){
va_list ap;
va_start(ap, zFmt);
if( pParse->rc==SQLITE_OK ){
pParse->zErr = sqlite3_vmprintf(zFmt, ap);
pParse->rc = SQLITE_ERROR;
}
va_end(ap);
}
static int fts5ExprIsspace(char t){
return t==' ' || t=='\t' || t=='\n' || t=='\r';
}
/*
** Read the first token from the nul-terminated string at *pz.
*/
static int fts5ExprGetToken(
Fts5Parse *pParse,
const char **pz, /* IN/OUT: Pointer into buffer */
Fts5Token *pToken
){
const char *z = *pz;
int tok;
/* Skip past any whitespace */
while( fts5ExprIsspace(*z) ) z++;
pToken->p = z;
pToken->n = 1;
switch( *z ){
case '(': tok = FTS5_LP; break;
case ')': tok = FTS5_RP; break;
case '{': tok = FTS5_LCP; break;
case '}': tok = FTS5_RCP; break;
case ':': tok = FTS5_COLON; break;
case ',': tok = FTS5_COMMA; break;
case '+': tok = FTS5_PLUS; break;
case '*': tok = FTS5_STAR; break;
case '-': tok = FTS5_MINUS; break;
case '^': tok = FTS5_CARET; break;
case '\0': tok = FTS5_EOF; break;
case '"': {
const char *z2;
tok = FTS5_STRING;
for(z2=&z[1]; 1; z2++){
if( z2[0]=='"' ){
z2++;
if( z2[0]!='"' ) break;
}
if( z2[0]=='\0' ){
sqlite3Fts5ParseError(pParse, "unterminated string");
return FTS5_EOF;
}
}
pToken->n = (z2 - z);
break;
}
default: {
const char *z2;
if( sqlite3Fts5IsBareword(z[0])==0 ){
sqlite3Fts5ParseError(pParse, "fts5: syntax error near \"%.1s\"", z);
return FTS5_EOF;
}
tok = FTS5_STRING;
for(z2=&z[1]; sqlite3Fts5IsBareword(*z2); z2++);
pToken->n = (z2 - z);
if( pToken->n==2 && memcmp(pToken->p, "OR", 2)==0 ) tok = FTS5_OR;
if( pToken->n==3 && memcmp(pToken->p, "NOT", 3)==0 ) tok = FTS5_NOT;
if( pToken->n==3 && memcmp(pToken->p, "AND", 3)==0 ) tok = FTS5_AND;
break;
}
}
*pz = &pToken->p[pToken->n];
return tok;
}
static void *fts5ParseAlloc(u64 t){ return sqlite3_malloc64((sqlite3_int64)t);}
static void fts5ParseFree(void *p){ sqlite3_free(p); }
static int sqlite3Fts5ExprNew(
Fts5Config *pConfig, /* FTS5 Configuration */
int bPhraseToAnd,
int iCol,
const char *zExpr, /* Expression text */
Fts5Expr **ppNew,
char **pzErr
){
Fts5Parse sParse;
Fts5Token token;
const char *z = zExpr;
int t; /* Next token type */
void *pEngine;
Fts5Expr *pNew;
*ppNew = 0;
*pzErr = 0;
memset(&sParse, 0, sizeof(sParse));
sParse.bPhraseToAnd = bPhraseToAnd;
pEngine = sqlite3Fts5ParserAlloc(fts5ParseAlloc);
if( pEngine==0 ){ return SQLITE_NOMEM; }
sParse.pConfig = pConfig;
do {
t = fts5ExprGetToken(&sParse, &z, &token);
sqlite3Fts5Parser(pEngine, t, token, &sParse);
}while( sParse.rc==SQLITE_OK && t!=FTS5_EOF );
sqlite3Fts5ParserFree(pEngine, fts5ParseFree);
/* If the LHS of the MATCH expression was a user column, apply the
** implicit column-filter. */
if( iCol<pConfig->nCol && sParse.pExpr && sParse.rc==SQLITE_OK ){
int n = sizeof(Fts5Colset);
Fts5Colset *pColset = (Fts5Colset*)sqlite3Fts5MallocZero(&sParse.rc, n);
if( pColset ){
pColset->nCol = 1;
pColset->aiCol[0] = iCol;
sqlite3Fts5ParseSetColset(&sParse, sParse.pExpr, pColset);
}
}
assert( sParse.rc!=SQLITE_OK || sParse.zErr==0 );
if( sParse.rc==SQLITE_OK ){
*ppNew = pNew = sqlite3_malloc(sizeof(Fts5Expr));
if( pNew==0 ){
sParse.rc = SQLITE_NOMEM;
sqlite3Fts5ParseNodeFree(sParse.pExpr);
}else{
if( !sParse.pExpr ){
const int nByte = sizeof(Fts5ExprNode);
pNew->pRoot = (Fts5ExprNode*)sqlite3Fts5MallocZero(&sParse.rc, nByte);
if( pNew->pRoot ){
pNew->pRoot->bEof = 1;
}
}else{
pNew->pRoot = sParse.pExpr;
}
pNew->pIndex = 0;
pNew->pConfig = pConfig;
pNew->apExprPhrase = sParse.apPhrase;
pNew->nPhrase = sParse.nPhrase;
pNew->bDesc = 0;
sParse.apPhrase = 0;
}
}else{
sqlite3Fts5ParseNodeFree(sParse.pExpr);
}
sqlite3_free(sParse.apPhrase);
*pzErr = sParse.zErr;
return sParse.rc;
}
/*
** This function is only called when using the special 'trigram' tokenizer.
** Argument zText contains the text of a LIKE or GLOB pattern matched
** against column iCol. This function creates and compiles an FTS5 MATCH
** expression that will match a superset of the rows matched by the LIKE or
** GLOB. If successful, SQLITE_OK is returned. Otherwise, an SQLite error
** code.
*/
static int sqlite3Fts5ExprPattern(
Fts5Config *pConfig, int bGlob, int iCol, const char *zText, Fts5Expr **pp
){
i64 nText = strlen(zText);
char *zExpr = (char*)sqlite3_malloc64(nText*4 + 1);
int rc = SQLITE_OK;
if( zExpr==0 ){
rc = SQLITE_NOMEM;
}else{
char aSpec[3];
int iOut = 0;
int i = 0;
int iFirst = 0;
if( bGlob==0 ){
aSpec[0] = '_';
aSpec[1] = '%';
aSpec[2] = 0;
}else{
aSpec[0] = '*';
aSpec[1] = '?';
aSpec[2] = '[';
}
while( i<=nText ){
if( i==nText
|| zText[i]==aSpec[0] || zText[i]==aSpec[1] || zText[i]==aSpec[2]
){
if( i-iFirst>=3 ){
int jj;
zExpr[iOut++] = '"';
for(jj=iFirst; jj<i; jj++){
zExpr[iOut++] = zText[jj];
if( zText[jj]=='"' ) zExpr[iOut++] = '"';
}
zExpr[iOut++] = '"';
zExpr[iOut++] = ' ';
}
if( zText[i]==aSpec[2] ){
i += 2;
if( zText[i-1]=='^' ) i++;
while( i<nText && zText[i]!=']' ) i++;
}
iFirst = i+1;
}
i++;
}
if( iOut>0 ){
int bAnd = 0;
if( pConfig->eDetail!=FTS5_DETAIL_FULL ){
bAnd = 1;
if( pConfig->eDetail==FTS5_DETAIL_NONE ){
iCol = pConfig->nCol;
}
}
zExpr[iOut] = '\0';
rc = sqlite3Fts5ExprNew(pConfig, bAnd, iCol, zExpr, pp,pConfig->pzErrmsg);
}else{
*pp = 0;
}
sqlite3_free(zExpr);
}
return rc;
}
/*
** Free the expression node object passed as the only argument.
*/
static void sqlite3Fts5ParseNodeFree(Fts5ExprNode *p){
if( p ){
int i;
for(i=0; i<p->nChild; i++){
sqlite3Fts5ParseNodeFree(p->apChild[i]);
}
sqlite3Fts5ParseNearsetFree(p->pNear);
sqlite3_free(p);
}
}
/*
** Free the expression object passed as the only argument.
*/
static void sqlite3Fts5ExprFree(Fts5Expr *p){
if( p ){
sqlite3Fts5ParseNodeFree(p->pRoot);
sqlite3_free(p->apExprPhrase);
sqlite3_free(p);
}
}
static int sqlite3Fts5ExprAnd(Fts5Expr **pp1, Fts5Expr *p2){
Fts5Parse sParse;
memset(&sParse, 0, sizeof(sParse));
if( *pp1 ){
Fts5Expr *p1 = *pp1;
int nPhrase = p1->nPhrase + p2->nPhrase;
p1->pRoot = sqlite3Fts5ParseNode(&sParse, FTS5_AND, p1->pRoot, p2->pRoot,0);
p2->pRoot = 0;
if( sParse.rc==SQLITE_OK ){
Fts5ExprPhrase **ap = (Fts5ExprPhrase**)sqlite3_realloc(
p1->apExprPhrase, nPhrase * sizeof(Fts5ExprPhrase*)
);
if( ap==0 ){
sParse.rc = SQLITE_NOMEM;
}else{
int i;
memmove(&ap[p2->nPhrase], ap, p1->nPhrase*sizeof(Fts5ExprPhrase*));
for(i=0; i<p2->nPhrase; i++){
ap[i] = p2->apExprPhrase[i];
}
p1->nPhrase = nPhrase;
p1->apExprPhrase = ap;
}
}
sqlite3_free(p2->apExprPhrase);
sqlite3_free(p2);
}else{
*pp1 = p2;
}
return sParse.rc;
}
/*
** Argument pTerm must be a synonym iterator. Return the current rowid
** that it points to.
*/
static i64 fts5ExprSynonymRowid(Fts5ExprTerm *pTerm, int bDesc, int *pbEof){
i64 iRet = 0;
int bRetValid = 0;
Fts5ExprTerm *p;
assert( pTerm->pSynonym );
assert( bDesc==0 || bDesc==1 );
for(p=pTerm; p; p=p->pSynonym){
if( 0==sqlite3Fts5IterEof(p->pIter) ){
i64 iRowid = p->pIter->iRowid;
if( bRetValid==0 || (bDesc!=(iRowid<iRet)) ){
iRet = iRowid;
bRetValid = 1;
}
}
}
if( pbEof && bRetValid==0 ) *pbEof = 1;
return iRet;
}
/*
** Argument pTerm must be a synonym iterator.
*/
static int fts5ExprSynonymList(
Fts5ExprTerm *pTerm,
i64 iRowid,
Fts5Buffer *pBuf, /* Use this buffer for space if required */
u8 **pa, int *pn
){
Fts5PoslistReader aStatic[4];
Fts5PoslistReader *aIter = aStatic;
int nIter = 0;
int nAlloc = 4;
int rc = SQLITE_OK;
Fts5ExprTerm *p;
assert( pTerm->pSynonym );
for(p=pTerm; p; p=p->pSynonym){
Fts5IndexIter *pIter = p->pIter;
if( sqlite3Fts5IterEof(pIter)==0 && pIter->iRowid==iRowid ){
if( pIter->nData==0 ) continue;
if( nIter==nAlloc ){
sqlite3_int64 nByte = sizeof(Fts5PoslistReader) * nAlloc * 2;
Fts5PoslistReader *aNew = (Fts5PoslistReader*)sqlite3_malloc64(nByte);
if( aNew==0 ){
rc = SQLITE_NOMEM;
goto synonym_poslist_out;
}
memcpy(aNew, aIter, sizeof(Fts5PoslistReader) * nIter);
nAlloc = nAlloc*2;
if( aIter!=aStatic ) sqlite3_free(aIter);
aIter = aNew;
}
sqlite3Fts5PoslistReaderInit(pIter->pData, pIter->nData, &aIter[nIter]);
assert( aIter[nIter].bEof==0 );
nIter++;
}
}
if( nIter==1 ){
*pa = (u8*)aIter[0].a;
*pn = aIter[0].n;
}else{
Fts5PoslistWriter writer = {0};
i64 iPrev = -1;
fts5BufferZero(pBuf);
while( 1 ){
int i;
i64 iMin = FTS5_LARGEST_INT64;
for(i=0; i<nIter; i++){
if( aIter[i].bEof==0 ){
if( aIter[i].iPos==iPrev ){
if( sqlite3Fts5PoslistReaderNext(&aIter[i]) ) continue;
}
if( aIter[i].iPos<iMin ){
iMin = aIter[i].iPos;
}
}
}
if( iMin==FTS5_LARGEST_INT64 || rc!=SQLITE_OK ) break;
rc = sqlite3Fts5PoslistWriterAppend(pBuf, &writer, iMin);
iPrev = iMin;
}
if( rc==SQLITE_OK ){
*pa = pBuf->p;
*pn = pBuf->n;
}
}
synonym_poslist_out:
if( aIter!=aStatic ) sqlite3_free(aIter);
return rc;
}
/*
** All individual term iterators in pPhrase are guaranteed to be valid and
** pointing to the same rowid when this function is called. This function
** checks if the current rowid really is a match, and if so populates
** the pPhrase->poslist buffer accordingly. Output parameter *pbMatch
** is set to true if this is really a match, or false otherwise.
**
** SQLITE_OK is returned if an error occurs, or an SQLite error code
** otherwise. It is not considered an error code if the current rowid is
** not a match.
*/
static int fts5ExprPhraseIsMatch(
Fts5ExprNode *pNode, /* Node pPhrase belongs to */
Fts5ExprPhrase *pPhrase, /* Phrase object to initialize */
int *pbMatch /* OUT: Set to true if really a match */
){
Fts5PoslistWriter writer = {0};
Fts5PoslistReader aStatic[4];
Fts5PoslistReader *aIter = aStatic;
int i;
int rc = SQLITE_OK;
int bFirst = pPhrase->aTerm[0].bFirst;
fts5BufferZero(&pPhrase->poslist);
/* If the aStatic[] array is not large enough, allocate a large array
** using sqlite3_malloc(). This approach could be improved upon. */
if( pPhrase->nTerm>ArraySize(aStatic) ){
sqlite3_int64 nByte = sizeof(Fts5PoslistReader) * pPhrase->nTerm;
aIter = (Fts5PoslistReader*)sqlite3_malloc64(nByte);
if( !aIter ) return SQLITE_NOMEM;
}
memset(aIter, 0, sizeof(Fts5PoslistReader) * pPhrase->nTerm);
/* Initialize a term iterator for each term in the phrase */
for(i=0; i<pPhrase->nTerm; i++){
Fts5ExprTerm *pTerm = &pPhrase->aTerm[i];
int n = 0;
int bFlag = 0;
u8 *a = 0;
if( pTerm->pSynonym ){
Fts5Buffer buf = {0, 0, 0};
rc = fts5ExprSynonymList(pTerm, pNode->iRowid, &buf, &a, &n);
if( rc ){
sqlite3_free(a);
goto ismatch_out;
}
if( a==buf.p ) bFlag = 1;
}else{
a = (u8*)pTerm->pIter->pData;
n = pTerm->pIter->nData;
}
sqlite3Fts5PoslistReaderInit(a, n, &aIter[i]);
aIter[i].bFlag = (u8)bFlag;
if( aIter[i].bEof ) goto ismatch_out;
}
while( 1 ){
int bMatch;
i64 iPos = aIter[0].iPos;
do {
bMatch = 1;
for(i=0; i<pPhrase->nTerm; i++){
Fts5PoslistReader *pPos = &aIter[i];
i64 iAdj = iPos + i;
if( pPos->iPos!=iAdj ){
bMatch = 0;
while( pPos->iPos<iAdj ){
if( sqlite3Fts5PoslistReaderNext(pPos) ) goto ismatch_out;
}
if( pPos->iPos>iAdj ) iPos = pPos->iPos-i;
}
}
}while( bMatch==0 );
/* Append position iPos to the output */
if( bFirst==0 || FTS5_POS2OFFSET(iPos)==0 ){
rc = sqlite3Fts5PoslistWriterAppend(&pPhrase->poslist, &writer, iPos);
if( rc!=SQLITE_OK ) goto ismatch_out;
}
for(i=0; i<pPhrase->nTerm; i++){
if( sqlite3Fts5PoslistReaderNext(&aIter[i]) ) goto ismatch_out;
}
}
ismatch_out:
*pbMatch = (pPhrase->poslist.n>0);
for(i=0; i<pPhrase->nTerm; i++){
if( aIter[i].bFlag ) sqlite3_free((u8*)aIter[i].a);
}
if( aIter!=aStatic ) sqlite3_free(aIter);
return rc;
}
typedef struct Fts5LookaheadReader Fts5LookaheadReader;
struct Fts5LookaheadReader {
const u8 *a; /* Buffer containing position list */
int n; /* Size of buffer a[] in bytes */
int i; /* Current offset in position list */
i64 iPos; /* Current position */
i64 iLookahead; /* Next position */
};
#define FTS5_LOOKAHEAD_EOF (((i64)1) << 62)
static int fts5LookaheadReaderNext(Fts5LookaheadReader *p){
p->iPos = p->iLookahead;
if( sqlite3Fts5PoslistNext64(p->a, p->n, &p->i, &p->iLookahead) ){
p->iLookahead = FTS5_LOOKAHEAD_EOF;
}
return (p->iPos==FTS5_LOOKAHEAD_EOF);
}
static int fts5LookaheadReaderInit(
const u8 *a, int n, /* Buffer to read position list from */
Fts5LookaheadReader *p /* Iterator object to initialize */
){
memset(p, 0, sizeof(Fts5LookaheadReader));
p->a = a;
p->n = n;
fts5LookaheadReaderNext(p);
return fts5LookaheadReaderNext(p);
}
typedef struct Fts5NearTrimmer Fts5NearTrimmer;
struct Fts5NearTrimmer {
Fts5LookaheadReader reader; /* Input iterator */
Fts5PoslistWriter writer; /* Writer context */
Fts5Buffer *pOut; /* Output poslist */
};
/*
** The near-set object passed as the first argument contains more than
** one phrase. All phrases currently point to the same row. The
** Fts5ExprPhrase.poslist buffers are populated accordingly. This function
** tests if the current row contains instances of each phrase sufficiently
** close together to meet the NEAR constraint. Non-zero is returned if it
** does, or zero otherwise.
**
** If in/out parameter (*pRc) is set to other than SQLITE_OK when this
** function is called, it is a no-op. Or, if an error (e.g. SQLITE_NOMEM)
** occurs within this function (*pRc) is set accordingly before returning.
** The return value is undefined in both these cases.
**
** If no error occurs and non-zero (a match) is returned, the position-list
** of each phrase object is edited to contain only those entries that
** meet the constraint before returning.
*/
static int fts5ExprNearIsMatch(int *pRc, Fts5ExprNearset *pNear){
Fts5NearTrimmer aStatic[4];
Fts5NearTrimmer *a = aStatic;
Fts5ExprPhrase **apPhrase = pNear->apPhrase;
int i;
int rc = *pRc;
int bMatch;
assert( pNear->nPhrase>1 );
/* If the aStatic[] array is not large enough, allocate a large array
** using sqlite3_malloc(). This approach could be improved upon. */
if( pNear->nPhrase>ArraySize(aStatic) ){
sqlite3_int64 nByte = sizeof(Fts5NearTrimmer) * pNear->nPhrase;
a = (Fts5NearTrimmer*)sqlite3Fts5MallocZero(&rc, nByte);
}else{
memset(aStatic, 0, sizeof(aStatic));
}
if( rc!=SQLITE_OK ){
*pRc = rc;
return 0;
}
/* Initialize a lookahead iterator for each phrase. After passing the
** buffer and buffer size to the lookaside-reader init function, zero
** the phrase poslist buffer. The new poslist for the phrase (containing
** the same entries as the original with some entries removed on account
** of the NEAR constraint) is written over the original even as it is
** being read. This is safe as the entries for the new poslist are a
** subset of the old, so it is not possible for data yet to be read to
** be overwritten. */
for(i=0; i<pNear->nPhrase; i++){
Fts5Buffer *pPoslist = &apPhrase[i]->poslist;
fts5LookaheadReaderInit(pPoslist->p, pPoslist->n, &a[i].reader);
pPoslist->n = 0;
a[i].pOut = pPoslist;
}
while( 1 ){
int iAdv;
i64 iMin;
i64 iMax;
/* This block advances the phrase iterators until they point to a set of
** entries that together comprise a match. */
iMax = a[0].reader.iPos;
do {
bMatch = 1;
for(i=0; i<pNear->nPhrase; i++){
Fts5LookaheadReader *pPos = &a[i].reader;
iMin = iMax - pNear->apPhrase[i]->nTerm - pNear->nNear;
if( pPos->iPos<iMin || pPos->iPos>iMax ){
bMatch = 0;
while( pPos->iPos<iMin ){
if( fts5LookaheadReaderNext(pPos) ) goto ismatch_out;
}
if( pPos->iPos>iMax ) iMax = pPos->iPos;
}
}
}while( bMatch==0 );
/* Add an entry to each output position list */
for(i=0; i<pNear->nPhrase; i++){
i64 iPos = a[i].reader.iPos;
Fts5PoslistWriter *pWriter = &a[i].writer;
if( a[i].pOut->n==0 || iPos!=pWriter->iPrev ){
sqlite3Fts5PoslistWriterAppend(a[i].pOut, pWriter, iPos);
}
}
iAdv = 0;
iMin = a[0].reader.iLookahead;
for(i=0; i<pNear->nPhrase; i++){
if( a[i].reader.iLookahead < iMin ){
iMin = a[i].reader.iLookahead;
iAdv = i;
}
}
if( fts5LookaheadReaderNext(&a[iAdv].reader) ) goto ismatch_out;
}
ismatch_out: {
int bRet = a[0].pOut->n>0;
*pRc = rc;
if( a!=aStatic ) sqlite3_free(a);
return bRet;
}
}
/*
** Advance iterator pIter until it points to a value equal to or laster
** than the initial value of *piLast. If this means the iterator points
** to a value laster than *piLast, update *piLast to the new lastest value.
**
** If the iterator reaches EOF, set *pbEof to true before returning. If
** an error occurs, set *pRc to an error code. If either *pbEof or *pRc
** are set, return a non-zero value. Otherwise, return zero.
*/
static int fts5ExprAdvanceto(
Fts5IndexIter *pIter, /* Iterator to advance */
int bDesc, /* True if iterator is "rowid DESC" */
i64 *piLast, /* IN/OUT: Lastest rowid seen so far */
int *pRc, /* OUT: Error code */
int *pbEof /* OUT: Set to true if EOF */
){
i64 iLast = *piLast;
i64 iRowid;
iRowid = pIter->iRowid;
if( (bDesc==0 && iLast>iRowid) || (bDesc && iLast<iRowid) ){
int rc = sqlite3Fts5IterNextFrom(pIter, iLast);
if( rc || sqlite3Fts5IterEof(pIter) ){
*pRc = rc;
*pbEof = 1;
return 1;
}
iRowid = pIter->iRowid;
assert( (bDesc==0 && iRowid>=iLast) || (bDesc==1 && iRowid<=iLast) );
}
*piLast = iRowid;
return 0;
}
static int fts5ExprSynonymAdvanceto(
Fts5ExprTerm *pTerm, /* Term iterator to advance */
int bDesc, /* True if iterator is "rowid DESC" */
i64 *piLast, /* IN/OUT: Lastest rowid seen so far */
int *pRc /* OUT: Error code */
){
int rc = SQLITE_OK;
i64 iLast = *piLast;
Fts5ExprTerm *p;
int bEof = 0;
for(p=pTerm; rc==SQLITE_OK && p; p=p->pSynonym){
if( sqlite3Fts5IterEof(p->pIter)==0 ){
i64 iRowid = p->pIter->iRowid;
if( (bDesc==0 && iLast>iRowid) || (bDesc && iLast<iRowid) ){
rc = sqlite3Fts5IterNextFrom(p->pIter, iLast);
}
}
}
if( rc!=SQLITE_OK ){
*pRc = rc;
bEof = 1;
}else{
*piLast = fts5ExprSynonymRowid(pTerm, bDesc, &bEof);
}
return bEof;
}
static int fts5ExprNearTest(
int *pRc,
Fts5Expr *pExpr, /* Expression that pNear is a part of */
Fts5ExprNode *pNode /* The "NEAR" node (FTS5_STRING) */
){
Fts5ExprNearset *pNear = pNode->pNear;
int rc = *pRc;
if( pExpr->pConfig->eDetail!=FTS5_DETAIL_FULL ){
Fts5ExprTerm *pTerm;
Fts5ExprPhrase *pPhrase = pNear->apPhrase[0];
pPhrase->poslist.n = 0;
for(pTerm=&pPhrase->aTerm[0]; pTerm; pTerm=pTerm->pSynonym){
Fts5IndexIter *pIter = pTerm->pIter;
if( sqlite3Fts5IterEof(pIter)==0 ){
if( pIter->iRowid==pNode->iRowid && pIter->nData>0 ){
pPhrase->poslist.n = 1;
}
}
}
return pPhrase->poslist.n;
}else{
int i;
/* Check that each phrase in the nearset matches the current row.
** Populate the pPhrase->poslist buffers at the same time. If any
** phrase is not a match, break out of the loop early. */
for(i=0; rc==SQLITE_OK && i<pNear->nPhrase; i++){
Fts5ExprPhrase *pPhrase = pNear->apPhrase[i];
if( pPhrase->nTerm>1 || pPhrase->aTerm[0].pSynonym
|| pNear->pColset || pPhrase->aTerm[0].bFirst
){
int bMatch = 0;
rc = fts5ExprPhraseIsMatch(pNode, pPhrase, &bMatch);
if( bMatch==0 ) break;
}else{
Fts5IndexIter *pIter = pPhrase->aTerm[0].pIter;
fts5BufferSet(&rc, &pPhrase->poslist, pIter->nData, pIter->pData);
}
}
*pRc = rc;
if( i==pNear->nPhrase && (i==1 || fts5ExprNearIsMatch(pRc, pNear)) ){
return 1;
}
return 0;
}
}
/*
** Initialize all term iterators in the pNear object. If any term is found
** to match no documents at all, return immediately without initializing any
** further iterators.
**
** If an error occurs, return an SQLite error code. Otherwise, return
** SQLITE_OK. It is not considered an error if some term matches zero
** documents.
*/
static int fts5ExprNearInitAll(
Fts5Expr *pExpr,
Fts5ExprNode *pNode
){
Fts5ExprNearset *pNear = pNode->pNear;
int i;
assert( pNode->bNomatch==0 );
for(i=0; i<pNear->nPhrase; i++){
Fts5ExprPhrase *pPhrase = pNear->apPhrase[i];
if( pPhrase->nTerm==0 ){
pNode->bEof = 1;
return SQLITE_OK;
}else{
int j;
for(j=0; j<pPhrase->nTerm; j++){
Fts5ExprTerm *pTerm = &pPhrase->aTerm[j];
Fts5ExprTerm *p;
int bHit = 0;
for(p=pTerm; p; p=p->pSynonym){
int rc;
if( p->pIter ){
sqlite3Fts5IterClose(p->pIter);
p->pIter = 0;
}
rc = sqlite3Fts5IndexQuery(
pExpr->pIndex, p->zTerm, (int)strlen(p->zTerm),
(pTerm->bPrefix ? FTS5INDEX_QUERY_PREFIX : 0) |
(pExpr->bDesc ? FTS5INDEX_QUERY_DESC : 0),
pNear->pColset,
&p->pIter
);
assert( (rc==SQLITE_OK)==(p->pIter!=0) );
if( rc!=SQLITE_OK ) return rc;
if( 0==sqlite3Fts5IterEof(p->pIter) ){
bHit = 1;
}
}
if( bHit==0 ){
pNode->bEof = 1;
return SQLITE_OK;
}
}
}
}
pNode->bEof = 0;
return SQLITE_OK;
}
/*
** If pExpr is an ASC iterator, this function returns a value with the
** same sign as:
**
** (iLhs - iRhs)
**
** Otherwise, if this is a DESC iterator, the opposite is returned:
**
** (iRhs - iLhs)
*/
static int fts5RowidCmp(
Fts5Expr *pExpr,
i64 iLhs,
i64 iRhs
){
assert( pExpr->bDesc==0 || pExpr->bDesc==1 );
if( pExpr->bDesc==0 ){
if( iLhs<iRhs ) return -1;
return (iLhs > iRhs);
}else{
if( iLhs>iRhs ) return -1;
return (iLhs < iRhs);
}
}
static void fts5ExprSetEof(Fts5ExprNode *pNode){
int i;
pNode->bEof = 1;
pNode->bNomatch = 0;
for(i=0; i<pNode->nChild; i++){
fts5ExprSetEof(pNode->apChild[i]);
}
}
static void fts5ExprNodeZeroPoslist(Fts5ExprNode *pNode){
if( pNode->eType==FTS5_STRING || pNode->eType==FTS5_TERM ){
Fts5ExprNearset *pNear = pNode->pNear;
int i;
for(i=0; i<pNear->nPhrase; i++){
Fts5ExprPhrase *pPhrase = pNear->apPhrase[i];
pPhrase->poslist.n = 0;
}
}else{
int i;
for(i=0; i<pNode->nChild; i++){
fts5ExprNodeZeroPoslist(pNode->apChild[i]);
}
}
}
/*
** Compare the values currently indicated by the two nodes as follows:
**
** res = (*p1) - (*p2)
**
** Nodes that point to values that come later in the iteration order are
** considered to be larger. Nodes at EOF are the largest of all.
**
** This means that if the iteration order is ASC, then numerically larger
** rowids are considered larger. Or if it is the default DESC, numerically
** smaller rowids are larger.
*/
static int fts5NodeCompare(
Fts5Expr *pExpr,
Fts5ExprNode *p1,
Fts5ExprNode *p2
){
if( p2->bEof ) return -1;
if( p1->bEof ) return +1;
return fts5RowidCmp(pExpr, p1->iRowid, p2->iRowid);
}
/*
** All individual term iterators in pNear are guaranteed to be valid when
** this function is called. This function checks if all term iterators
** point to the same rowid, and if not, advances them until they do.
** If an EOF is reached before this happens, *pbEof is set to true before
** returning.
**
** SQLITE_OK is returned if an error occurs, or an SQLite error code
** otherwise. It is not considered an error code if an iterator reaches
** EOF.
*/
static int fts5ExprNodeTest_STRING(
Fts5Expr *pExpr, /* Expression pPhrase belongs to */
Fts5ExprNode *pNode
){
Fts5ExprNearset *pNear = pNode->pNear;
Fts5ExprPhrase *pLeft = pNear->apPhrase[0];
int rc = SQLITE_OK;
i64 iLast; /* Lastest rowid any iterator points to */
int i, j; /* Phrase and token index, respectively */
int bMatch; /* True if all terms are at the same rowid */
const int bDesc = pExpr->bDesc;
/* Check that this node should not be FTS5_TERM */
assert( pNear->nPhrase>1
|| pNear->apPhrase[0]->nTerm>1
|| pNear->apPhrase[0]->aTerm[0].pSynonym
|| pNear->apPhrase[0]->aTerm[0].bFirst
);
/* Initialize iLast, the "lastest" rowid any iterator points to. If the
** iterator skips through rowids in the default ascending order, this means
** the maximum rowid. Or, if the iterator is "ORDER BY rowid DESC", then it
** means the minimum rowid. */
if( pLeft->aTerm[0].pSynonym ){
iLast = fts5ExprSynonymRowid(&pLeft->aTerm[0], bDesc, 0);
}else{
iLast = pLeft->aTerm[0].pIter->iRowid;
}
do {
bMatch = 1;
for(i=0; i<pNear->nPhrase; i++){
Fts5ExprPhrase *pPhrase = pNear->apPhrase[i];
for(j=0; j<pPhrase->nTerm; j++){
Fts5ExprTerm *pTerm = &pPhrase->aTerm[j];
if( pTerm->pSynonym ){
i64 iRowid = fts5ExprSynonymRowid(pTerm, bDesc, 0);
if( iRowid==iLast ) continue;
bMatch = 0;
if( fts5ExprSynonymAdvanceto(pTerm, bDesc, &iLast, &rc) ){
pNode->bNomatch = 0;
pNode->bEof = 1;
return rc;
}
}else{
Fts5IndexIter *pIter = pPhrase->aTerm[j].pIter;
if( pIter->iRowid==iLast || pIter->bEof ) continue;
bMatch = 0;
if( fts5ExprAdvanceto(pIter, bDesc, &iLast, &rc, &pNode->bEof) ){
return rc;
}
}
}
}
}while( bMatch==0 );
pNode->iRowid = iLast;
pNode->bNomatch = ((0==fts5ExprNearTest(&rc, pExpr, pNode)) && rc==SQLITE_OK);
assert( pNode->bEof==0 || pNode->bNomatch==0 );
return rc;
}
/*
** Advance the first term iterator in the first phrase of pNear. Set output
** variable *pbEof to true if it reaches EOF or if an error occurs.
**
** Return SQLITE_OK if successful, or an SQLite error code if an error
** occurs.
*/
static int fts5ExprNodeNext_STRING(
Fts5Expr *pExpr, /* Expression pPhrase belongs to */
Fts5ExprNode *pNode, /* FTS5_STRING or FTS5_TERM node */
int bFromValid,
i64 iFrom
){
Fts5ExprTerm *pTerm = &pNode->pNear->apPhrase[0]->aTerm[0];
int rc = SQLITE_OK;
pNode->bNomatch = 0;
if( pTerm->pSynonym ){
int bEof = 1;
Fts5ExprTerm *p;
/* Find the firstest rowid any synonym points to. */
i64 iRowid = fts5ExprSynonymRowid(pTerm, pExpr->bDesc, 0);
/* Advance each iterator that currently points to iRowid. Or, if iFrom
** is valid - each iterator that points to a rowid before iFrom. */
for(p=pTerm; p; p=p->pSynonym){
if( sqlite3Fts5IterEof(p->pIter)==0 ){
i64 ii = p->pIter->iRowid;
if( ii==iRowid
|| (bFromValid && ii!=iFrom && (ii>iFrom)==pExpr->bDesc)
){
if( bFromValid ){
rc = sqlite3Fts5IterNextFrom(p->pIter, iFrom);
}else{
rc = sqlite3Fts5IterNext(p->pIter);
}
if( rc!=SQLITE_OK ) break;
if( sqlite3Fts5IterEof(p->pIter)==0 ){
bEof = 0;
}
}else{
bEof = 0;
}
}
}
/* Set the EOF flag if either all synonym iterators are at EOF or an
** error has occurred. */
pNode->bEof = (rc || bEof);
}else{
Fts5IndexIter *pIter = pTerm->pIter;
assert( Fts5NodeIsString(pNode) );
if( bFromValid ){
rc = sqlite3Fts5IterNextFrom(pIter, iFrom);
}else{
rc = sqlite3Fts5IterNext(pIter);
}
pNode->bEof = (rc || sqlite3Fts5IterEof(pIter));
}
if( pNode->bEof==0 ){
assert( rc==SQLITE_OK );
rc = fts5ExprNodeTest_STRING(pExpr, pNode);
}
return rc;
}
static int fts5ExprNodeTest_TERM(
Fts5Expr *pExpr, /* Expression that pNear is a part of */
Fts5ExprNode *pNode /* The "NEAR" node (FTS5_TERM) */
){
/* As this "NEAR" object is actually a single phrase that consists
** of a single term only, grab pointers into the poslist managed by the
** fts5_index.c iterator object. This is much faster than synthesizing
** a new poslist the way we have to for more complicated phrase or NEAR
** expressions. */
Fts5ExprPhrase *pPhrase = pNode->pNear->apPhrase[0];
Fts5IndexIter *pIter = pPhrase->aTerm[0].pIter;
assert( pNode->eType==FTS5_TERM );
assert( pNode->pNear->nPhrase==1 && pPhrase->nTerm==1 );
assert( pPhrase->aTerm[0].pSynonym==0 );
pPhrase->poslist.n = pIter->nData;
if( pExpr->pConfig->eDetail==FTS5_DETAIL_FULL ){
pPhrase->poslist.p = (u8*)pIter->pData;
}
pNode->iRowid = pIter->iRowid;
pNode->bNomatch = (pPhrase->poslist.n==0);
return SQLITE_OK;
}
/*
** xNext() method for a node of type FTS5_TERM.
*/
static int fts5ExprNodeNext_TERM(
Fts5Expr *pExpr,
Fts5ExprNode *pNode,
int bFromValid,
i64 iFrom
){
int rc;
Fts5IndexIter *pIter = pNode->pNear->apPhrase[0]->aTerm[0].pIter;
assert( pNode->bEof==0 );
if( bFromValid ){
rc = sqlite3Fts5IterNextFrom(pIter, iFrom);
}else{
rc = sqlite3Fts5IterNext(pIter);
}
if( rc==SQLITE_OK && sqlite3Fts5IterEof(pIter)==0 ){
rc = fts5ExprNodeTest_TERM(pExpr, pNode);
}else{
pNode->bEof = 1;
pNode->bNomatch = 0;
}
return rc;
}
static void fts5ExprNodeTest_OR(
Fts5Expr *pExpr, /* Expression of which pNode is a part */
Fts5ExprNode *pNode /* Expression node to test */
){
Fts5ExprNode *pNext = pNode->apChild[0];
int i;
for(i=1; i<pNode->nChild; i++){
Fts5ExprNode *pChild = pNode->apChild[i];
int cmp = fts5NodeCompare(pExpr, pNext, pChild);
if( cmp>0 || (cmp==0 && pChild->bNomatch==0) ){
pNext = pChild;
}
}
pNode->iRowid = pNext->iRowid;
pNode->bEof = pNext->bEof;
pNode->bNomatch = pNext->bNomatch;
}
static int fts5ExprNodeNext_OR(
Fts5Expr *pExpr,
Fts5ExprNode *pNode,
int bFromValid,
i64 iFrom
){
int i;
i64 iLast = pNode->iRowid;
for(i=0; i<pNode->nChild; i++){
Fts5ExprNode *p1 = pNode->apChild[i];
assert( p1->bEof || fts5RowidCmp(pExpr, p1->iRowid, iLast)>=0 );
if( p1->bEof==0 ){
if( (p1->iRowid==iLast)
|| (bFromValid && fts5RowidCmp(pExpr, p1->iRowid, iFrom)<0)
){
int rc = fts5ExprNodeNext(pExpr, p1, bFromValid, iFrom);
if( rc!=SQLITE_OK ){
pNode->bNomatch = 0;
return rc;
}
}
}
}
fts5ExprNodeTest_OR(pExpr, pNode);
return SQLITE_OK;
}
/*
** Argument pNode is an FTS5_AND node.
*/
static int fts5ExprNodeTest_AND(
Fts5Expr *pExpr, /* Expression pPhrase belongs to */
Fts5ExprNode *pAnd /* FTS5_AND node to advance */
){
int iChild;
i64 iLast = pAnd->iRowid;
int rc = SQLITE_OK;
int bMatch;
assert( pAnd->bEof==0 );
do {
pAnd->bNomatch = 0;
bMatch = 1;
for(iChild=0; iChild<pAnd->nChild; iChild++){
Fts5ExprNode *pChild = pAnd->apChild[iChild];
int cmp = fts5RowidCmp(pExpr, iLast, pChild->iRowid);
if( cmp>0 ){
/* Advance pChild until it points to iLast or laster */
rc = fts5ExprNodeNext(pExpr, pChild, 1, iLast);
if( rc!=SQLITE_OK ){
pAnd->bNomatch = 0;
return rc;
}
}
/* If the child node is now at EOF, so is the parent AND node. Otherwise,
** the child node is guaranteed to have advanced at least as far as
** rowid iLast. So if it is not at exactly iLast, pChild->iRowid is the
** new lastest rowid seen so far. */
assert( pChild->bEof || fts5RowidCmp(pExpr, iLast, pChild->iRowid)<=0 );
if( pChild->bEof ){
fts5ExprSetEof(pAnd);
bMatch = 1;
break;
}else if( iLast!=pChild->iRowid ){
bMatch = 0;
iLast = pChild->iRowid;
}
if( pChild->bNomatch ){
pAnd->bNomatch = 1;
}
}
}while( bMatch==0 );
if( pAnd->bNomatch && pAnd!=pExpr->pRoot ){
fts5ExprNodeZeroPoslist(pAnd);
}
pAnd->iRowid = iLast;
return SQLITE_OK;
}
static int fts5ExprNodeNext_AND(
Fts5Expr *pExpr,
Fts5ExprNode *pNode,
int bFromValid,
i64 iFrom
){
int rc = fts5ExprNodeNext(pExpr, pNode->apChild[0], bFromValid, iFrom);
if( rc==SQLITE_OK ){
rc = fts5ExprNodeTest_AND(pExpr, pNode);
}else{
pNode->bNomatch = 0;
}
return rc;
}
static int fts5ExprNodeTest_NOT(
Fts5Expr *pExpr, /* Expression pPhrase belongs to */
Fts5ExprNode *pNode /* FTS5_NOT node to advance */
){
int rc = SQLITE_OK;
Fts5ExprNode *p1 = pNode->apChild[0];
Fts5ExprNode *p2 = pNode->apChild[1];
assert( pNode->nChild==2 );
while( rc==SQLITE_OK && p1->bEof==0 ){
int cmp = fts5NodeCompare(pExpr, p1, p2);
if( cmp>0 ){
rc = fts5ExprNodeNext(pExpr, p2, 1, p1->iRowid);
cmp = fts5NodeCompare(pExpr, p1, p2);
}
assert( rc!=SQLITE_OK || cmp<=0 );
if( cmp || p2->bNomatch ) break;
rc = fts5ExprNodeNext(pExpr, p1, 0, 0);
}
pNode->bEof = p1->bEof;
pNode->bNomatch = p1->bNomatch;
pNode->iRowid = p1->iRowid;
if( p1->bEof ){
fts5ExprNodeZeroPoslist(p2);
}
return rc;
}
static int fts5ExprNodeNext_NOT(
Fts5Expr *pExpr,
Fts5ExprNode *pNode,
int bFromValid,
i64 iFrom
){
int rc = fts5ExprNodeNext(pExpr, pNode->apChild[0], bFromValid, iFrom);
if( rc==SQLITE_OK ){
rc = fts5ExprNodeTest_NOT(pExpr, pNode);
}
if( rc!=SQLITE_OK ){
pNode->bNomatch = 0;
}
return rc;
}
/*
** If pNode currently points to a match, this function returns SQLITE_OK
** without modifying it. Otherwise, pNode is advanced until it does point
** to a match or EOF is reached.
*/
static int fts5ExprNodeTest(
Fts5Expr *pExpr, /* Expression of which pNode is a part */
Fts5ExprNode *pNode /* Expression node to test */
){
int rc = SQLITE_OK;
if( pNode->bEof==0 ){
switch( pNode->eType ){
case FTS5_STRING: {
rc = fts5ExprNodeTest_STRING(pExpr, pNode);
break;
}
case FTS5_TERM: {
rc = fts5ExprNodeTest_TERM(pExpr, pNode);
break;
}
case FTS5_AND: {
rc = fts5ExprNodeTest_AND(pExpr, pNode);
break;
}
case FTS5_OR: {
fts5ExprNodeTest_OR(pExpr, pNode);
break;
}
default: assert( pNode->eType==FTS5_NOT ); {
rc = fts5ExprNodeTest_NOT(pExpr, pNode);
break;
}
}
}
return rc;
}
/*
** Set node pNode, which is part of expression pExpr, to point to the first
** match. If there are no matches, set the Node.bEof flag to indicate EOF.
**
** Return an SQLite error code if an error occurs, or SQLITE_OK otherwise.
** It is not an error if there are no matches.
*/
static int fts5ExprNodeFirst(Fts5Expr *pExpr, Fts5ExprNode *pNode){
int rc = SQLITE_OK;
pNode->bEof = 0;
pNode->bNomatch = 0;
if( Fts5NodeIsString(pNode) ){
/* Initialize all term iterators in the NEAR object. */
rc = fts5ExprNearInitAll(pExpr, pNode);
}else if( pNode->xNext==0 ){
pNode->bEof = 1;
}else{
int i;
int nEof = 0;
for(i=0; i<pNode->nChild && rc==SQLITE_OK; i++){
Fts5ExprNode *pChild = pNode->apChild[i];
rc = fts5ExprNodeFirst(pExpr, pNode->apChild[i]);
assert( pChild->bEof==0 || pChild->bEof==1 );
nEof += pChild->bEof;
}
pNode->iRowid = pNode->apChild[0]->iRowid;
switch( pNode->eType ){
case FTS5_AND:
if( nEof>0 ) fts5ExprSetEof(pNode);
break;
case FTS5_OR:
if( pNode->nChild==nEof ) fts5ExprSetEof(pNode);
break;
default:
assert( pNode->eType==FTS5_NOT );
pNode->bEof = pNode->apChild[0]->bEof;
break;
}
}
if( rc==SQLITE_OK ){
rc = fts5ExprNodeTest(pExpr, pNode);
}
return rc;
}
/*
** Begin iterating through the set of documents in index pIdx matched by
** the MATCH expression passed as the first argument. If the "bDesc"
** parameter is passed a non-zero value, iteration is in descending rowid
** order. Or, if it is zero, in ascending order.
**
** If iterating in ascending rowid order (bDesc==0), the first document
** visited is that with the smallest rowid that is larger than or equal
** to parameter iFirst. Or, if iterating in ascending order (bDesc==1),
** then the first document visited must have a rowid smaller than or
** equal to iFirst.
**
** Return SQLITE_OK if successful, or an SQLite error code otherwise. It
** is not considered an error if the query does not match any documents.
*/
static int sqlite3Fts5ExprFirst(Fts5Expr *p, Fts5Index *pIdx, i64 iFirst, int bDesc){
Fts5ExprNode *pRoot = p->pRoot;
int rc; /* Return code */
p->pIndex = pIdx;
p->bDesc = bDesc;
rc = fts5ExprNodeFirst(p, pRoot);
/* If not at EOF but the current rowid occurs earlier than iFirst in
** the iteration order, move to document iFirst or later. */
if( rc==SQLITE_OK
&& 0==pRoot->bEof
&& fts5RowidCmp(p, pRoot->iRowid, iFirst)<0
){
rc = fts5ExprNodeNext(p, pRoot, 1, iFirst);
}
/* If the iterator is not at a real match, skip forward until it is. */
while( pRoot->bNomatch && rc==SQLITE_OK ){
assert( pRoot->bEof==0 );
rc = fts5ExprNodeNext(p, pRoot, 0, 0);
}
return rc;
}
/*
** Move to the next document
**
** Return SQLITE_OK if successful, or an SQLite error code otherwise. It
** is not considered an error if the query does not match any documents.
*/
static int sqlite3Fts5ExprNext(Fts5Expr *p, i64 iLast){
int rc;
Fts5ExprNode *pRoot = p->pRoot;
assert( pRoot->bEof==0 && pRoot->bNomatch==0 );
do {
rc = fts5ExprNodeNext(p, pRoot, 0, 0);
assert( pRoot->bNomatch==0 || (rc==SQLITE_OK && pRoot->bEof==0) );
}while( pRoot->bNomatch );
if( fts5RowidCmp(p, pRoot->iRowid, iLast)>0 ){
pRoot->bEof = 1;
}
return rc;
}
static int sqlite3Fts5ExprEof(Fts5Expr *p){
return p->pRoot->bEof;
}
static i64 sqlite3Fts5ExprRowid(Fts5Expr *p){
return p->pRoot->iRowid;
}
static int fts5ParseStringFromToken(Fts5Token *pToken, char **pz){
int rc = SQLITE_OK;
*pz = sqlite3Fts5Strndup(&rc, pToken->p, pToken->n);
return rc;
}
/*
** Free the phrase object passed as the only argument.
*/
static void fts5ExprPhraseFree(Fts5ExprPhrase *pPhrase){
if( pPhrase ){
int i;
for(i=0; i<pPhrase->nTerm; i++){
Fts5ExprTerm *pSyn;
Fts5ExprTerm *pNext;
Fts5ExprTerm *pTerm = &pPhrase->aTerm[i];
sqlite3_free(pTerm->zTerm);
sqlite3Fts5IterClose(pTerm->pIter);
for(pSyn=pTerm->pSynonym; pSyn; pSyn=pNext){
pNext = pSyn->pSynonym;
sqlite3Fts5IterClose(pSyn->pIter);
fts5BufferFree((Fts5Buffer*)&pSyn[1]);
sqlite3_free(pSyn);
}
}
if( pPhrase->poslist.nSpace>0 ) fts5BufferFree(&pPhrase->poslist);
sqlite3_free(pPhrase);
}
}
/*
** Set the "bFirst" flag on the first token of the phrase passed as the
** only argument.
*/
static void sqlite3Fts5ParseSetCaret(Fts5ExprPhrase *pPhrase){
if( pPhrase && pPhrase->nTerm ){
pPhrase->aTerm[0].bFirst = 1;
}
}
/*
** If argument pNear is NULL, then a new Fts5ExprNearset object is allocated
** and populated with pPhrase. Or, if pNear is not NULL, phrase pPhrase is
** appended to it and the results returned.
**
** If an OOM error occurs, both the pNear and pPhrase objects are freed and
** NULL returned.
*/
static Fts5ExprNearset *sqlite3Fts5ParseNearset(
Fts5Parse *pParse, /* Parse context */
Fts5ExprNearset *pNear, /* Existing nearset, or NULL */
Fts5ExprPhrase *pPhrase /* Recently parsed phrase */
){
const int SZALLOC = 8;
Fts5ExprNearset *pRet = 0;
if( pParse->rc==SQLITE_OK ){
if( pPhrase==0 ){
return pNear;
}
if( pNear==0 ){
sqlite3_int64 nByte;
nByte = sizeof(Fts5ExprNearset) + SZALLOC * sizeof(Fts5ExprPhrase*);
pRet = sqlite3_malloc64(nByte);
if( pRet==0 ){
pParse->rc = SQLITE_NOMEM;
}else{
memset(pRet, 0, (size_t)nByte);
}
}else if( (pNear->nPhrase % SZALLOC)==0 ){
int nNew = pNear->nPhrase + SZALLOC;
sqlite3_int64 nByte;
nByte = sizeof(Fts5ExprNearset) + nNew * sizeof(Fts5ExprPhrase*);
pRet = (Fts5ExprNearset*)sqlite3_realloc64(pNear, nByte);
if( pRet==0 ){
pParse->rc = SQLITE_NOMEM;
}
}else{
pRet = pNear;
}
}
if( pRet==0 ){
assert( pParse->rc!=SQLITE_OK );
sqlite3Fts5ParseNearsetFree(pNear);
sqlite3Fts5ParsePhraseFree(pPhrase);
}else{
if( pRet->nPhrase>0 ){
Fts5ExprPhrase *pLast = pRet->apPhrase[pRet->nPhrase-1];
assert( pLast==pParse->apPhrase[pParse->nPhrase-2] );
if( pPhrase->nTerm==0 ){
fts5ExprPhraseFree(pPhrase);
pRet->nPhrase--;
pParse->nPhrase--;
pPhrase = pLast;
}else if( pLast->nTerm==0 ){
fts5ExprPhraseFree(pLast);
pParse->apPhrase[pParse->nPhrase-2] = pPhrase;
pParse->nPhrase--;
pRet->nPhrase--;
}
}
pRet->apPhrase[pRet->nPhrase++] = pPhrase;
}
return pRet;
}
typedef struct TokenCtx TokenCtx;
struct TokenCtx {
Fts5ExprPhrase *pPhrase;
int rc;
};
/*
** Callback for tokenizing terms used by ParseTerm().
*/
static int fts5ParseTokenize(
void *pContext, /* Pointer to Fts5InsertCtx object */
int tflags, /* Mask of FTS5_TOKEN_* flags */
const char *pToken, /* Buffer containing token */
int nToken, /* Size of token in bytes */
int iUnused1, /* Start offset of token */
int iUnused2 /* End offset of token */
){
int rc = SQLITE_OK;
const int SZALLOC = 8;
TokenCtx *pCtx = (TokenCtx*)pContext;
Fts5ExprPhrase *pPhrase = pCtx->pPhrase;
UNUSED_PARAM2(iUnused1, iUnused2);
/* If an error has already occurred, this is a no-op */
if( pCtx->rc!=SQLITE_OK ) return pCtx->rc;
if( nToken>FTS5_MAX_TOKEN_SIZE ) nToken = FTS5_MAX_TOKEN_SIZE;
if( pPhrase && pPhrase->nTerm>0 && (tflags & FTS5_TOKEN_COLOCATED) ){
Fts5ExprTerm *pSyn;
sqlite3_int64 nByte = sizeof(Fts5ExprTerm) + sizeof(Fts5Buffer) + nToken+1;
pSyn = (Fts5ExprTerm*)sqlite3_malloc64(nByte);
if( pSyn==0 ){
rc = SQLITE_NOMEM;
}else{
memset(pSyn, 0, (size_t)nByte);
pSyn->zTerm = ((char*)pSyn) + sizeof(Fts5ExprTerm) + sizeof(Fts5Buffer);
memcpy(pSyn->zTerm, pToken, nToken);
pSyn->pSynonym = pPhrase->aTerm[pPhrase->nTerm-1].pSynonym;
pPhrase->aTerm[pPhrase->nTerm-1].pSynonym = pSyn;
}
}else{
Fts5ExprTerm *pTerm;
if( pPhrase==0 || (pPhrase->nTerm % SZALLOC)==0 ){
Fts5ExprPhrase *pNew;
int nNew = SZALLOC + (pPhrase ? pPhrase->nTerm : 0);
pNew = (Fts5ExprPhrase*)sqlite3_realloc64(pPhrase,
sizeof(Fts5ExprPhrase) + sizeof(Fts5ExprTerm) * nNew
);
if( pNew==0 ){
rc = SQLITE_NOMEM;
}else{
if( pPhrase==0 ) memset(pNew, 0, sizeof(Fts5ExprPhrase));
pCtx->pPhrase = pPhrase = pNew;
pNew->nTerm = nNew - SZALLOC;
}
}
if( rc==SQLITE_OK ){
pTerm = &pPhrase->aTerm[pPhrase->nTerm++];
memset(pTerm, 0, sizeof(Fts5ExprTerm));
pTerm->zTerm = sqlite3Fts5Strndup(&rc, pToken, nToken);
}
}
pCtx->rc = rc;
return rc;
}
/*
** Free the phrase object passed as the only argument.
*/
static void sqlite3Fts5ParsePhraseFree(Fts5ExprPhrase *pPhrase){
fts5ExprPhraseFree(pPhrase);
}
/*
** Free the phrase object passed as the second argument.
*/
static void sqlite3Fts5ParseNearsetFree(Fts5ExprNearset *pNear){
if( pNear ){
int i;
for(i=0; i<pNear->nPhrase; i++){
fts5ExprPhraseFree(pNear->apPhrase[i]);
}
sqlite3_free(pNear->pColset);
sqlite3_free(pNear);
}
}
static void sqlite3Fts5ParseFinished(Fts5Parse *pParse, Fts5ExprNode *p){
assert( pParse->pExpr==0 );
pParse->pExpr = p;
}
static int parseGrowPhraseArray(Fts5Parse *pParse){
if( (pParse->nPhrase % 8)==0 ){
sqlite3_int64 nByte = sizeof(Fts5ExprPhrase*) * (pParse->nPhrase + 8);
Fts5ExprPhrase **apNew;
apNew = (Fts5ExprPhrase**)sqlite3_realloc64(pParse->apPhrase, nByte);
if( apNew==0 ){
pParse->rc = SQLITE_NOMEM;
return SQLITE_NOMEM;
}
pParse->apPhrase = apNew;
}
return SQLITE_OK;
}
/*
** This function is called by the parser to process a string token. The
** string may or may not be quoted. In any case it is tokenized and a
** phrase object consisting of all tokens returned.
*/
static Fts5ExprPhrase *sqlite3Fts5ParseTerm(
Fts5Parse *pParse, /* Parse context */
Fts5ExprPhrase *pAppend, /* Phrase to append to */
Fts5Token *pToken, /* String to tokenize */
int bPrefix /* True if there is a trailing "*" */
){
Fts5Config *pConfig = pParse->pConfig;
TokenCtx sCtx; /* Context object passed to callback */
int rc; /* Tokenize return code */
char *z = 0;
memset(&sCtx, 0, sizeof(TokenCtx));
sCtx.pPhrase = pAppend;
rc = fts5ParseStringFromToken(pToken, &z);
if( rc==SQLITE_OK ){
int flags = FTS5_TOKENIZE_QUERY | (bPrefix ? FTS5_TOKENIZE_PREFIX : 0);
int n;
sqlite3Fts5Dequote(z);
n = (int)strlen(z);
rc = sqlite3Fts5Tokenize(pConfig, flags, z, n, &sCtx, fts5ParseTokenize);
}
sqlite3_free(z);
if( rc || (rc = sCtx.rc) ){
pParse->rc = rc;
fts5ExprPhraseFree(sCtx.pPhrase);
sCtx.pPhrase = 0;
}else{
if( pAppend==0 ){
if( parseGrowPhraseArray(pParse) ){
fts5ExprPhraseFree(sCtx.pPhrase);
return 0;
}
pParse->nPhrase++;
}
if( sCtx.pPhrase==0 ){
/* This happens when parsing a token or quoted phrase that contains
** no token characters at all. (e.g ... MATCH '""'). */
sCtx.pPhrase = sqlite3Fts5MallocZero(&pParse->rc, sizeof(Fts5ExprPhrase));
}else if( sCtx.pPhrase->nTerm ){
sCtx.pPhrase->aTerm[sCtx.pPhrase->nTerm-1].bPrefix = (u8)bPrefix;
}
pParse->apPhrase[pParse->nPhrase-1] = sCtx.pPhrase;
}
return sCtx.pPhrase;
}
/*
** Create a new FTS5 expression by cloning phrase iPhrase of the
** expression passed as the second argument.
*/
static int sqlite3Fts5ExprClonePhrase(
Fts5Expr *pExpr,
int iPhrase,
Fts5Expr **ppNew
){
int rc = SQLITE_OK; /* Return code */
Fts5ExprPhrase *pOrig; /* The phrase extracted from pExpr */
Fts5Expr *pNew = 0; /* Expression to return via *ppNew */
TokenCtx sCtx = {0,0}; /* Context object for fts5ParseTokenize */
pOrig = pExpr->apExprPhrase[iPhrase];
pNew = (Fts5Expr*)sqlite3Fts5MallocZero(&rc, sizeof(Fts5Expr));
if( rc==SQLITE_OK ){
pNew->apExprPhrase = (Fts5ExprPhrase**)sqlite3Fts5MallocZero(&rc,
sizeof(Fts5ExprPhrase*));
}
if( rc==SQLITE_OK ){
pNew->pRoot = (Fts5ExprNode*)sqlite3Fts5MallocZero(&rc,
sizeof(Fts5ExprNode));
}
if( rc==SQLITE_OK ){
pNew->pRoot->pNear = (Fts5ExprNearset*)sqlite3Fts5MallocZero(&rc,
sizeof(Fts5ExprNearset) + sizeof(Fts5ExprPhrase*));
}
if( rc==SQLITE_OK ){
Fts5Colset *pColsetOrig = pOrig->pNode->pNear->pColset;
if( pColsetOrig ){
sqlite3_int64 nByte;
Fts5Colset *pColset;
nByte = sizeof(Fts5Colset) + (pColsetOrig->nCol-1) * sizeof(int);
pColset = (Fts5Colset*)sqlite3Fts5MallocZero(&rc, nByte);
if( pColset ){
memcpy(pColset, pColsetOrig, (size_t)nByte);
}
pNew->pRoot->pNear->pColset = pColset;
}
}
if( pOrig->nTerm ){
int i; /* Used to iterate through phrase terms */
for(i=0; rc==SQLITE_OK && i<pOrig->nTerm; i++){
int tflags = 0;
Fts5ExprTerm *p;
for(p=&pOrig->aTerm[i]; p && rc==SQLITE_OK; p=p->pSynonym){
const char *zTerm = p->zTerm;
rc = fts5ParseTokenize((void*)&sCtx, tflags, zTerm, (int)strlen(zTerm),
0, 0);
tflags = FTS5_TOKEN_COLOCATED;
}
if( rc==SQLITE_OK ){
sCtx.pPhrase->aTerm[i].bPrefix = pOrig->aTerm[i].bPrefix;
sCtx.pPhrase->aTerm[i].bFirst = pOrig->aTerm[i].bFirst;
}
}
}else{
/* This happens when parsing a token or quoted phrase that contains
** no token characters at all. (e.g ... MATCH '""'). */
sCtx.pPhrase = sqlite3Fts5MallocZero(&rc, sizeof(Fts5ExprPhrase));
}
if( rc==SQLITE_OK ){
/* All the allocations succeeded. Put the expression object together. */
pNew->pIndex = pExpr->pIndex;
pNew->pConfig = pExpr->pConfig;
pNew->nPhrase = 1;
pNew->apExprPhrase[0] = sCtx.pPhrase;
pNew->pRoot->pNear->apPhrase[0] = sCtx.pPhrase;
pNew->pRoot->pNear->nPhrase = 1;
sCtx.pPhrase->pNode = pNew->pRoot;
if( pOrig->nTerm==1
&& pOrig->aTerm[0].pSynonym==0
&& pOrig->aTerm[0].bFirst==0
){
pNew->pRoot->eType = FTS5_TERM;
pNew->pRoot->xNext = fts5ExprNodeNext_TERM;
}else{
pNew->pRoot->eType = FTS5_STRING;
pNew->pRoot->xNext = fts5ExprNodeNext_STRING;
}
}else{
sqlite3Fts5ExprFree(pNew);
fts5ExprPhraseFree(sCtx.pPhrase);
pNew = 0;
}
*ppNew = pNew;
return rc;
}
/*
** Token pTok has appeared in a MATCH expression where the NEAR operator
** is expected. If token pTok does not contain "NEAR", store an error
** in the pParse object.
*/
static void sqlite3Fts5ParseNear(Fts5Parse *pParse, Fts5Token *pTok){
if( pTok->n!=4 || memcmp("NEAR", pTok->p, 4) ){
sqlite3Fts5ParseError(
pParse, "fts5: syntax error near \"%.*s\"", pTok->n, pTok->p
);
}
}
static void sqlite3Fts5ParseSetDistance(
Fts5Parse *pParse,
Fts5ExprNearset *pNear,
Fts5Token *p
){
if( pNear ){
int nNear = 0;
int i;
if( p->n ){
for(i=0; i<p->n; i++){
char c = (char)p->p[i];
if( c<'0' || c>'9' ){
sqlite3Fts5ParseError(
pParse, "expected integer, got \"%.*s\"", p->n, p->p
);
return;
}
nNear = nNear * 10 + (p->p[i] - '0');
}
}else{
nNear = FTS5_DEFAULT_NEARDIST;
}
pNear->nNear = nNear;
}
}
/*
** The second argument passed to this function may be NULL, or it may be
** an existing Fts5Colset object. This function returns a pointer to
** a new colset object containing the contents of (p) with new value column
** number iCol appended.
**
** If an OOM error occurs, store an error code in pParse and return NULL.
** The old colset object (if any) is not freed in this case.
*/
static Fts5Colset *fts5ParseColset(
Fts5Parse *pParse, /* Store SQLITE_NOMEM here if required */
Fts5Colset *p, /* Existing colset object */
int iCol /* New column to add to colset object */
){
int nCol = p ? p->nCol : 0; /* Num. columns already in colset object */
Fts5Colset *pNew; /* New colset object to return */
assert( pParse->rc==SQLITE_OK );
assert( iCol>=0 && iCol<pParse->pConfig->nCol );
pNew = sqlite3_realloc64(p, sizeof(Fts5Colset) + sizeof(int)*nCol);
if( pNew==0 ){
pParse->rc = SQLITE_NOMEM;
}else{
int *aiCol = pNew->aiCol;
int i, j;
for(i=0; i<nCol; i++){
if( aiCol[i]==iCol ) return pNew;
if( aiCol[i]>iCol ) break;
}
for(j=nCol; j>i; j--){
aiCol[j] = aiCol[j-1];
}
aiCol[i] = iCol;
pNew->nCol = nCol+1;
#ifndef NDEBUG
/* Check that the array is in order and contains no duplicate entries. */
for(i=1; i<pNew->nCol; i++) assert( pNew->aiCol[i]>pNew->aiCol[i-1] );
#endif
}
return pNew;
}
/*
** Allocate and return an Fts5Colset object specifying the inverse of
** the colset passed as the second argument. Free the colset passed
** as the second argument before returning.
*/
static Fts5Colset *sqlite3Fts5ParseColsetInvert(Fts5Parse *pParse, Fts5Colset *p){
Fts5Colset *pRet;
int nCol = pParse->pConfig->nCol;
pRet = (Fts5Colset*)sqlite3Fts5MallocZero(&pParse->rc,
sizeof(Fts5Colset) + sizeof(int)*nCol
);
if( pRet ){
int i;
int iOld = 0;
for(i=0; i<nCol; i++){
if( iOld>=p->nCol || p->aiCol[iOld]!=i ){
pRet->aiCol[pRet->nCol++] = i;
}else{
iOld++;
}
}
}
sqlite3_free(p);
return pRet;
}
static Fts5Colset *sqlite3Fts5ParseColset(
Fts5Parse *pParse, /* Store SQLITE_NOMEM here if required */
Fts5Colset *pColset, /* Existing colset object */
Fts5Token *p
){
Fts5Colset *pRet = 0;
int iCol;
char *z; /* Dequoted copy of token p */
z = sqlite3Fts5Strndup(&pParse->rc, p->p, p->n);
if( pParse->rc==SQLITE_OK ){
Fts5Config *pConfig = pParse->pConfig;
sqlite3Fts5Dequote(z);
for(iCol=0; iCol<pConfig->nCol; iCol++){
if( 0==sqlite3_stricmp(pConfig->azCol[iCol], z) ) break;
}
if( iCol==pConfig->nCol ){
sqlite3Fts5ParseError(pParse, "no such column: %s", z);
}else{
pRet = fts5ParseColset(pParse, pColset, iCol);
}
sqlite3_free(z);
}
if( pRet==0 ){
assert( pParse->rc!=SQLITE_OK );
sqlite3_free(pColset);
}
return pRet;
}
/*
** If argument pOrig is NULL, or if (*pRc) is set to anything other than
** SQLITE_OK when this function is called, NULL is returned.
**
** Otherwise, a copy of (*pOrig) is made into memory obtained from
** sqlite3Fts5MallocZero() and a pointer to it returned. If the allocation
** fails, (*pRc) is set to SQLITE_NOMEM and NULL is returned.
*/
static Fts5Colset *fts5CloneColset(int *pRc, Fts5Colset *pOrig){
Fts5Colset *pRet;
if( pOrig ){
sqlite3_int64 nByte = sizeof(Fts5Colset) + (pOrig->nCol-1) * sizeof(int);
pRet = (Fts5Colset*)sqlite3Fts5MallocZero(pRc, nByte);
if( pRet ){
memcpy(pRet, pOrig, (size_t)nByte);
}
}else{
pRet = 0;
}
return pRet;
}
/*
** Remove from colset pColset any columns that are not also in colset pMerge.
*/
static void fts5MergeColset(Fts5Colset *pColset, Fts5Colset *pMerge){
int iIn = 0; /* Next input in pColset */
int iMerge = 0; /* Next input in pMerge */
int iOut = 0; /* Next output slot in pColset */
while( iIn<pColset->nCol && iMerge<pMerge->nCol ){
int iDiff = pColset->aiCol[iIn] - pMerge->aiCol[iMerge];
if( iDiff==0 ){
pColset->aiCol[iOut++] = pMerge->aiCol[iMerge];
iMerge++;
iIn++;
}else if( iDiff>0 ){
iMerge++;
}else{
iIn++;
}
}
pColset->nCol = iOut;
}
/*
** Recursively apply colset pColset to expression node pNode and all of
** its decendents. If (*ppFree) is not NULL, it contains a spare copy
** of pColset. This function may use the spare copy and set (*ppFree) to
** zero, or it may create copies of pColset using fts5CloneColset().
*/
static void fts5ParseSetColset(
Fts5Parse *pParse,
Fts5ExprNode *pNode,
Fts5Colset *pColset,
Fts5Colset **ppFree
){
if( pParse->rc==SQLITE_OK ){
assert( pNode->eType==FTS5_TERM || pNode->eType==FTS5_STRING
|| pNode->eType==FTS5_AND || pNode->eType==FTS5_OR
|| pNode->eType==FTS5_NOT || pNode->eType==FTS5_EOF
);
if( pNode->eType==FTS5_STRING || pNode->eType==FTS5_TERM ){
Fts5ExprNearset *pNear = pNode->pNear;
if( pNear->pColset ){
fts5MergeColset(pNear->pColset, pColset);
if( pNear->pColset->nCol==0 ){
pNode->eType = FTS5_EOF;
pNode->xNext = 0;
}
}else if( *ppFree ){
pNear->pColset = pColset;
*ppFree = 0;
}else{
pNear->pColset = fts5CloneColset(&pParse->rc, pColset);
}
}else{
int i;
assert( pNode->eType!=FTS5_EOF || pNode->nChild==0 );
for(i=0; i<pNode->nChild; i++){
fts5ParseSetColset(pParse, pNode->apChild[i], pColset, ppFree);
}
}
}
}
/*
** Apply colset pColset to expression node pExpr and all of its descendents.
*/
static void sqlite3Fts5ParseSetColset(
Fts5Parse *pParse,
Fts5ExprNode *pExpr,
Fts5Colset *pColset
){
Fts5Colset *pFree = pColset;
if( pParse->pConfig->eDetail==FTS5_DETAIL_NONE ){
pParse->rc = SQLITE_ERROR;
pParse->zErr = sqlite3_mprintf(
"fts5: column queries are not supported (detail=none)"
);
}else{
fts5ParseSetColset(pParse, pExpr, pColset, &pFree);
}
sqlite3_free(pFree);
}
static void fts5ExprAssignXNext(Fts5ExprNode *pNode){
switch( pNode->eType ){
case FTS5_STRING: {
Fts5ExprNearset *pNear = pNode->pNear;
if( pNear->nPhrase==1 && pNear->apPhrase[0]->nTerm==1
&& pNear->apPhrase[0]->aTerm[0].pSynonym==0
&& pNear->apPhrase[0]->aTerm[0].bFirst==0
){
pNode->eType = FTS5_TERM;
pNode->xNext = fts5ExprNodeNext_TERM;
}else{
pNode->xNext = fts5ExprNodeNext_STRING;
}
break;
};
case FTS5_OR: {
pNode->xNext = fts5ExprNodeNext_OR;
break;
};
case FTS5_AND: {
pNode->xNext = fts5ExprNodeNext_AND;
break;
};
default: assert( pNode->eType==FTS5_NOT ); {
pNode->xNext = fts5ExprNodeNext_NOT;
break;
};
}
}
static void fts5ExprAddChildren(Fts5ExprNode *p, Fts5ExprNode *pSub){
if( p->eType!=FTS5_NOT && pSub->eType==p->eType ){
int nByte = sizeof(Fts5ExprNode*) * pSub->nChild;
memcpy(&p->apChild[p->nChild], pSub->apChild, nByte);
p->nChild += pSub->nChild;
sqlite3_free(pSub);
}else{
p->apChild[p->nChild++] = pSub;
}
}
/*
** This function is used when parsing LIKE or GLOB patterns against
** trigram indexes that specify either detail=column or detail=none.
** It converts a phrase:
**
** abc + def + ghi
**
** into an AND tree:
**
** abc AND def AND ghi
*/
static Fts5ExprNode *fts5ParsePhraseToAnd(
Fts5Parse *pParse,
Fts5ExprNearset *pNear
){
int nTerm = pNear->apPhrase[0]->nTerm;
int ii;
int nByte;
Fts5ExprNode *pRet;
assert( pNear->nPhrase==1 );
assert( pParse->bPhraseToAnd );
nByte = sizeof(Fts5ExprNode) + nTerm*sizeof(Fts5ExprNode*);
pRet = (Fts5ExprNode*)sqlite3Fts5MallocZero(&pParse->rc, nByte);
if( pRet ){
pRet->eType = FTS5_AND;
pRet->nChild = nTerm;
fts5ExprAssignXNext(pRet);
pParse->nPhrase--;
for(ii=0; ii<nTerm; ii++){
Fts5ExprPhrase *pPhrase = (Fts5ExprPhrase*)sqlite3Fts5MallocZero(
&pParse->rc, sizeof(Fts5ExprPhrase)
);
if( pPhrase ){
if( parseGrowPhraseArray(pParse) ){
fts5ExprPhraseFree(pPhrase);
}else{
pParse->apPhrase[pParse->nPhrase++] = pPhrase;
pPhrase->nTerm = 1;
pPhrase->aTerm[0].zTerm = sqlite3Fts5Strndup(
&pParse->rc, pNear->apPhrase[0]->aTerm[ii].zTerm, -1
);
pRet->apChild[ii] = sqlite3Fts5ParseNode(pParse, FTS5_STRING,
0, 0, sqlite3Fts5ParseNearset(pParse, 0, pPhrase)
);
}
}
}
if( pParse->rc ){
sqlite3Fts5ParseNodeFree(pRet);
pRet = 0;
}else{
sqlite3Fts5ParseNearsetFree(pNear);
}
}
return pRet;
}
/*
** Allocate and return a new expression object. If anything goes wrong (i.e.
** OOM error), leave an error code in pParse and return NULL.
*/
static Fts5ExprNode *sqlite3Fts5ParseNode(
Fts5Parse *pParse, /* Parse context */
int eType, /* FTS5_STRING, AND, OR or NOT */
Fts5ExprNode *pLeft, /* Left hand child expression */
Fts5ExprNode *pRight, /* Right hand child expression */
Fts5ExprNearset *pNear /* For STRING expressions, the near cluster */
){
Fts5ExprNode *pRet = 0;
if( pParse->rc==SQLITE_OK ){
int nChild = 0; /* Number of children of returned node */
sqlite3_int64 nByte; /* Bytes of space to allocate for this node */
assert( (eType!=FTS5_STRING && !pNear)
|| (eType==FTS5_STRING && !pLeft && !pRight)
);
if( eType==FTS5_STRING && pNear==0 ) return 0;
if( eType!=FTS5_STRING && pLeft==0 ) return pRight;
if( eType!=FTS5_STRING && pRight==0 ) return pLeft;
if( eType==FTS5_STRING
&& pParse->bPhraseToAnd
&& pNear->apPhrase[0]->nTerm>1
){
pRet = fts5ParsePhraseToAnd(pParse, pNear);
}else{
if( eType==FTS5_NOT ){
nChild = 2;
}else if( eType==FTS5_AND || eType==FTS5_OR ){
nChild = 2;
if( pLeft->eType==eType ) nChild += pLeft->nChild-1;
if( pRight->eType==eType ) nChild += pRight->nChild-1;
}
nByte = sizeof(Fts5ExprNode) + sizeof(Fts5ExprNode*)*(nChild-1);
pRet = (Fts5ExprNode*)sqlite3Fts5MallocZero(&pParse->rc, nByte);
if( pRet ){
pRet->eType = eType;
pRet->pNear = pNear;
fts5ExprAssignXNext(pRet);
if( eType==FTS5_STRING ){
int iPhrase;
for(iPhrase=0; iPhrase<pNear->nPhrase; iPhrase++){
pNear->apPhrase[iPhrase]->pNode = pRet;
if( pNear->apPhrase[iPhrase]->nTerm==0 ){
pRet->xNext = 0;
pRet->eType = FTS5_EOF;
}
}
if( pParse->pConfig->eDetail!=FTS5_DETAIL_FULL ){
Fts5ExprPhrase *pPhrase = pNear->apPhrase[0];
if( pNear->nPhrase!=1
|| pPhrase->nTerm>1
|| (pPhrase->nTerm>0 && pPhrase->aTerm[0].bFirst)
){
assert( pParse->rc==SQLITE_OK );
pParse->rc = SQLITE_ERROR;
assert( pParse->zErr==0 );
pParse->zErr = sqlite3_mprintf(
"fts5: %s queries are not supported (detail!=full)",
pNear->nPhrase==1 ? "phrase": "NEAR"
);
sqlite3_free(pRet);
pRet = 0;
}
}
}else{
fts5ExprAddChildren(pRet, pLeft);
fts5ExprAddChildren(pRet, pRight);
}
}
}
}
if( pRet==0 ){
assert( pParse->rc!=SQLITE_OK );
sqlite3Fts5ParseNodeFree(pLeft);
sqlite3Fts5ParseNodeFree(pRight);
sqlite3Fts5ParseNearsetFree(pNear);
}
return pRet;
}
static Fts5ExprNode *sqlite3Fts5ParseImplicitAnd(
Fts5Parse *pParse, /* Parse context */
Fts5ExprNode *pLeft, /* Left hand child expression */
Fts5ExprNode *pRight /* Right hand child expression */
){
Fts5ExprNode *pRet = 0;
Fts5ExprNode *pPrev;
if( pParse->rc ){
sqlite3Fts5ParseNodeFree(pLeft);
sqlite3Fts5ParseNodeFree(pRight);
}else{
assert( pLeft->eType==FTS5_STRING
|| pLeft->eType==FTS5_TERM
|| pLeft->eType==FTS5_EOF
|| pLeft->eType==FTS5_AND
);
assert( pRight->eType==FTS5_STRING
|| pRight->eType==FTS5_TERM
|| pRight->eType==FTS5_EOF
);
if( pLeft->eType==FTS5_AND ){
pPrev = pLeft->apChild[pLeft->nChild-1];
}else{
pPrev = pLeft;
}
assert( pPrev->eType==FTS5_STRING
|| pPrev->eType==FTS5_TERM
|| pPrev->eType==FTS5_EOF
);
if( pRight->eType==FTS5_EOF ){
assert( pParse->apPhrase[pParse->nPhrase-1]==pRight->pNear->apPhrase[0] );
sqlite3Fts5ParseNodeFree(pRight);
pRet = pLeft;
pParse->nPhrase--;
}
else if( pPrev->eType==FTS5_EOF ){
Fts5ExprPhrase **ap;
if( pPrev==pLeft ){
pRet = pRight;
}else{
pLeft->apChild[pLeft->nChild-1] = pRight;
pRet = pLeft;
}
ap = &pParse->apPhrase[pParse->nPhrase-1-pRight->pNear->nPhrase];
assert( ap[0]==pPrev->pNear->apPhrase[0] );
memmove(ap, &ap[1], sizeof(Fts5ExprPhrase*)*pRight->pNear->nPhrase);
pParse->nPhrase--;
sqlite3Fts5ParseNodeFree(pPrev);
}
else{
pRet = sqlite3Fts5ParseNode(pParse, FTS5_AND, pLeft, pRight, 0);
}
}
return pRet;
}
static char *fts5ExprTermPrint(Fts5ExprTerm *pTerm){
sqlite3_int64 nByte = 0;
Fts5ExprTerm *p;
char *zQuoted;
/* Determine the maximum amount of space required. */
for(p=pTerm; p; p=p->pSynonym){
nByte += (int)strlen(pTerm->zTerm) * 2 + 3 + 2;
}
zQuoted = sqlite3_malloc64(nByte);
if( zQuoted ){
int i = 0;
for(p=pTerm; p; p=p->pSynonym){
char *zIn = p->zTerm;
zQuoted[i++] = '"';
while( *zIn ){
if( *zIn=='"' ) zQuoted[i++] = '"';
zQuoted[i++] = *zIn++;
}
zQuoted[i++] = '"';
if( p->pSynonym ) zQuoted[i++] = '|';
}
if( pTerm->bPrefix ){
zQuoted[i++] = ' ';
zQuoted[i++] = '*';
}
zQuoted[i++] = '\0';
}
return zQuoted;
}
static char *fts5PrintfAppend(char *zApp, const char *zFmt, ...){
char *zNew;
va_list ap;
va_start(ap, zFmt);
zNew = sqlite3_vmprintf(zFmt, ap);
va_end(ap);
if( zApp && zNew ){
char *zNew2 = sqlite3_mprintf("%s%s", zApp, zNew);
sqlite3_free(zNew);
zNew = zNew2;
}
sqlite3_free(zApp);
return zNew;
}
/*
** Compose a tcl-readable representation of expression pExpr. Return a
** pointer to a buffer containing that representation. It is the
** responsibility of the caller to at some point free the buffer using
** sqlite3_free().
*/
static char *fts5ExprPrintTcl(
Fts5Config *pConfig,
const char *zNearsetCmd,
Fts5ExprNode *pExpr
){
char *zRet = 0;
if( pExpr->eType==FTS5_STRING || pExpr->eType==FTS5_TERM ){
Fts5ExprNearset *pNear = pExpr->pNear;
int i;
int iTerm;
zRet = fts5PrintfAppend(zRet, "%s ", zNearsetCmd);
if( zRet==0 ) return 0;
if( pNear->pColset ){
int *aiCol = pNear->pColset->aiCol;
int nCol = pNear->pColset->nCol;
if( nCol==1 ){
zRet = fts5PrintfAppend(zRet, "-col %d ", aiCol[0]);
}else{
zRet = fts5PrintfAppend(zRet, "-col {%d", aiCol[0]);
for(i=1; i<pNear->pColset->nCol; i++){
zRet = fts5PrintfAppend(zRet, " %d", aiCol[i]);
}
zRet = fts5PrintfAppend(zRet, "} ");
}
if( zRet==0 ) return 0;
}
if( pNear->nPhrase>1 ){
zRet = fts5PrintfAppend(zRet, "-near %d ", pNear->nNear);
if( zRet==0 ) return 0;
}
zRet = fts5PrintfAppend(zRet, "--");
if( zRet==0 ) return 0;
for(i=0; i<pNear->nPhrase; i++){
Fts5ExprPhrase *pPhrase = pNear->apPhrase[i];
zRet = fts5PrintfAppend(zRet, " {");
for(iTerm=0; zRet && iTerm<pPhrase->nTerm; iTerm++){
char *zTerm = pPhrase->aTerm[iTerm].zTerm;
zRet = fts5PrintfAppend(zRet, "%s%s", iTerm==0?"":" ", zTerm);
if( pPhrase->aTerm[iTerm].bPrefix ){
zRet = fts5PrintfAppend(zRet, "*");
}
}
if( zRet ) zRet = fts5PrintfAppend(zRet, "}");
if( zRet==0 ) return 0;
}
}else{
char const *zOp = 0;
int i;
switch( pExpr->eType ){
case FTS5_AND: zOp = "AND"; break;
case FTS5_NOT: zOp = "NOT"; break;
default:
assert( pExpr->eType==FTS5_OR );
zOp = "OR";
break;
}
zRet = sqlite3_mprintf("%s", zOp);
for(i=0; zRet && i<pExpr->nChild; i++){
char *z = fts5ExprPrintTcl(pConfig, zNearsetCmd, pExpr->apChild[i]);
if( !z ){
sqlite3_free(zRet);
zRet = 0;
}else{
zRet = fts5PrintfAppend(zRet, " [%z]", z);
}
}
}
return zRet;
}
static char *fts5ExprPrint(Fts5Config *pConfig, Fts5ExprNode *pExpr){
char *zRet = 0;
if( pExpr->eType==0 ){
return sqlite3_mprintf("\"\"");
}else
if( pExpr->eType==FTS5_STRING || pExpr->eType==FTS5_TERM ){
Fts5ExprNearset *pNear = pExpr->pNear;
int i;
int iTerm;
if( pNear->pColset ){
int ii;
Fts5Colset *pColset = pNear->pColset;
if( pColset->nCol>1 ) zRet = fts5PrintfAppend(zRet, "{");
for(ii=0; ii<pColset->nCol; ii++){
zRet = fts5PrintfAppend(zRet, "%s%s",
pConfig->azCol[pColset->aiCol[ii]], ii==pColset->nCol-1 ? "" : " "
);
}
if( zRet ){
zRet = fts5PrintfAppend(zRet, "%s : ", pColset->nCol>1 ? "}" : "");
}
if( zRet==0 ) return 0;
}
if( pNear->nPhrase>1 ){
zRet = fts5PrintfAppend(zRet, "NEAR(");
if( zRet==0 ) return 0;
}
for(i=0; i<pNear->nPhrase; i++){
Fts5ExprPhrase *pPhrase = pNear->apPhrase[i];
if( i!=0 ){
zRet = fts5PrintfAppend(zRet, " ");
if( zRet==0 ) return 0;
}
for(iTerm=0; iTerm<pPhrase->nTerm; iTerm++){
char *zTerm = fts5ExprTermPrint(&pPhrase->aTerm[iTerm]);
if( zTerm ){
zRet = fts5PrintfAppend(zRet, "%s%s", iTerm==0?"":" + ", zTerm);
sqlite3_free(zTerm);
}
if( zTerm==0 || zRet==0 ){
sqlite3_free(zRet);
return 0;
}
}
}
if( pNear->nPhrase>1 ){
zRet = fts5PrintfAppend(zRet, ", %d)", pNear->nNear);
if( zRet==0 ) return 0;
}
}else{
char const *zOp = 0;
int i;
switch( pExpr->eType ){
case FTS5_AND: zOp = " AND "; break;
case FTS5_NOT: zOp = " NOT "; break;
default:
assert( pExpr->eType==FTS5_OR );
zOp = " OR ";
break;
}
for(i=0; i<pExpr->nChild; i++){
char *z = fts5ExprPrint(pConfig, pExpr->apChild[i]);
if( z==0 ){
sqlite3_free(zRet);
zRet = 0;
}else{
int e = pExpr->apChild[i]->eType;
int b = (e!=FTS5_STRING && e!=FTS5_TERM && e!=FTS5_EOF);
zRet = fts5PrintfAppend(zRet, "%s%s%z%s",
(i==0 ? "" : zOp),
(b?"(":""), z, (b?")":"")
);
}
if( zRet==0 ) break;
}
}
return zRet;
}
/*
** The implementation of user-defined scalar functions fts5_expr() (bTcl==0)
** and fts5_expr_tcl() (bTcl!=0).
*/
static void fts5ExprFunction(
sqlite3_context *pCtx, /* Function call context */
int nArg, /* Number of args */
sqlite3_value **apVal, /* Function arguments */
int bTcl
){
Fts5Global *pGlobal = (Fts5Global*)sqlite3_user_data(pCtx);
sqlite3 *db = sqlite3_context_db_handle(pCtx);
const char *zExpr = 0;
char *zErr = 0;
Fts5Expr *pExpr = 0;
int rc;
int i;
const char **azConfig; /* Array of arguments for Fts5Config */
const char *zNearsetCmd = "nearset";
int nConfig; /* Size of azConfig[] */
Fts5Config *pConfig = 0;
int iArg = 1;
if( nArg<1 ){
zErr = sqlite3_mprintf("wrong number of arguments to function %s",
bTcl ? "fts5_expr_tcl" : "fts5_expr"
);
sqlite3_result_error(pCtx, zErr, -1);
sqlite3_free(zErr);
return;
}
if( bTcl && nArg>1 ){
zNearsetCmd = (const char*)sqlite3_value_text(apVal[1]);
iArg = 2;
}
nConfig = 3 + (nArg-iArg);
azConfig = (const char**)sqlite3_malloc64(sizeof(char*) * nConfig);
if( azConfig==0 ){
sqlite3_result_error_nomem(pCtx);
return;
}
azConfig[0] = 0;
azConfig[1] = "main";
azConfig[2] = "tbl";
for(i=3; iArg<nArg; iArg++){
const char *z = (const char*)sqlite3_value_text(apVal[iArg]);
azConfig[i++] = (z ? z : "");
}
zExpr = (const char*)sqlite3_value_text(apVal[0]);
if( zExpr==0 ) zExpr = "";
rc = sqlite3Fts5ConfigParse(pGlobal, db, nConfig, azConfig, &pConfig, &zErr);
if( rc==SQLITE_OK ){
rc = sqlite3Fts5ExprNew(pConfig, 0, pConfig->nCol, zExpr, &pExpr, &zErr);
}
if( rc==SQLITE_OK ){
char *zText;
if( pExpr->pRoot->xNext==0 ){
zText = sqlite3_mprintf("");
}else if( bTcl ){
zText = fts5ExprPrintTcl(pConfig, zNearsetCmd, pExpr->pRoot);
}else{
zText = fts5ExprPrint(pConfig, pExpr->pRoot);
}
if( zText==0 ){
rc = SQLITE_NOMEM;
}else{
sqlite3_result_text(pCtx, zText, -1, SQLITE_TRANSIENT);
sqlite3_free(zText);
}
}
if( rc!=SQLITE_OK ){
if( zErr ){
sqlite3_result_error(pCtx, zErr, -1);
sqlite3_free(zErr);
}else{
sqlite3_result_error_code(pCtx, rc);
}
}
sqlite3_free((void *)azConfig);
sqlite3Fts5ConfigFree(pConfig);
sqlite3Fts5ExprFree(pExpr);
}
static void fts5ExprFunctionHr(
sqlite3_context *pCtx, /* Function call context */
int nArg, /* Number of args */
sqlite3_value **apVal /* Function arguments */
){
fts5ExprFunction(pCtx, nArg, apVal, 0);
}
static void fts5ExprFunctionTcl(
sqlite3_context *pCtx, /* Function call context */
int nArg, /* Number of args */
sqlite3_value **apVal /* Function arguments */
){
fts5ExprFunction(pCtx, nArg, apVal, 1);
}
/*
** The implementation of an SQLite user-defined-function that accepts a
** single integer as an argument. If the integer is an alpha-numeric
** unicode code point, 1 is returned. Otherwise 0.
*/
static void fts5ExprIsAlnum(
sqlite3_context *pCtx, /* Function call context */
int nArg, /* Number of args */
sqlite3_value **apVal /* Function arguments */
){
int iCode;
u8 aArr[32];
if( nArg!=1 ){
sqlite3_result_error(pCtx,
"wrong number of arguments to function fts5_isalnum", -1
);
return;
}
memset(aArr, 0, sizeof(aArr));
sqlite3Fts5UnicodeCatParse("L*", aArr);
sqlite3Fts5UnicodeCatParse("N*", aArr);
sqlite3Fts5UnicodeCatParse("Co", aArr);
iCode = sqlite3_value_int(apVal[0]);
sqlite3_result_int(pCtx, aArr[sqlite3Fts5UnicodeCategory((u32)iCode)]);
}
static void fts5ExprFold(
sqlite3_context *pCtx, /* Function call context */
int nArg, /* Number of args */
sqlite3_value **apVal /* Function arguments */
){
if( nArg!=1 && nArg!=2 ){
sqlite3_result_error(pCtx,
"wrong number of arguments to function fts5_fold", -1
);
}else{
int iCode;
int bRemoveDiacritics = 0;
iCode = sqlite3_value_int(apVal[0]);
if( nArg==2 ) bRemoveDiacritics = sqlite3_value_int(apVal[1]);
sqlite3_result_int(pCtx, sqlite3Fts5UnicodeFold(iCode, bRemoveDiacritics));
}
}
/*
** This is called during initialization to register the fts5_expr() scalar
** UDF with the SQLite handle passed as the only argument.
*/
static int sqlite3Fts5ExprInit(Fts5Global *pGlobal, sqlite3 *db){
struct Fts5ExprFunc {
const char *z;
void (*x)(sqlite3_context*,int,sqlite3_value**);
} aFunc[] = {
{ "fts5_expr", fts5ExprFunctionHr },
{ "fts5_expr_tcl", fts5ExprFunctionTcl },
{ "fts5_isalnum", fts5ExprIsAlnum },
{ "fts5_fold", fts5ExprFold },
};
int i;
int rc = SQLITE_OK;
void *pCtx = (void*)pGlobal;
for(i=0; rc==SQLITE_OK && i<ArraySize(aFunc); i++){
struct Fts5ExprFunc *p = &aFunc[i];
rc = sqlite3_create_function(db, p->z, -1, SQLITE_UTF8, pCtx, p->x, 0, 0);
}
/* Avoid warnings indicating that sqlite3Fts5ParserTrace() and
** sqlite3Fts5ParserFallback() are unused */
#ifndef NDEBUG
(void)sqlite3Fts5ParserTrace;
#endif
(void)sqlite3Fts5ParserFallback;
return rc;
}
/*
** Return the number of phrases in expression pExpr.
*/
static int sqlite3Fts5ExprPhraseCount(Fts5Expr *pExpr){
return (pExpr ? pExpr->nPhrase : 0);
}
/*
** Return the number of terms in the iPhrase'th phrase in pExpr.
*/
static int sqlite3Fts5ExprPhraseSize(Fts5Expr *pExpr, int iPhrase){
if( iPhrase<0 || iPhrase>=pExpr->nPhrase ) return 0;
return pExpr->apExprPhrase[iPhrase]->nTerm;
}
/*
** This function is used to access the current position list for phrase
** iPhrase.
*/
static int sqlite3Fts5ExprPoslist(Fts5Expr *pExpr, int iPhrase, const u8 **pa){
int nRet;
Fts5ExprPhrase *pPhrase = pExpr->apExprPhrase[iPhrase];
Fts5ExprNode *pNode = pPhrase->pNode;
if( pNode->bEof==0 && pNode->iRowid==pExpr->pRoot->iRowid ){
*pa = pPhrase->poslist.p;
nRet = pPhrase->poslist.n;
}else{
*pa = 0;
nRet = 0;
}
return nRet;
}
struct Fts5PoslistPopulator {
Fts5PoslistWriter writer;
int bOk; /* True if ok to populate */
int bMiss;
};
static Fts5PoslistPopulator *sqlite3Fts5ExprClearPoslists(Fts5Expr *pExpr, int bLive){
Fts5PoslistPopulator *pRet;
pRet = sqlite3_malloc64(sizeof(Fts5PoslistPopulator)*pExpr->nPhrase);
if( pRet ){
int i;
memset(pRet, 0, sizeof(Fts5PoslistPopulator)*pExpr->nPhrase);
for(i=0; i<pExpr->nPhrase; i++){
Fts5Buffer *pBuf = &pExpr->apExprPhrase[i]->poslist;
Fts5ExprNode *pNode = pExpr->apExprPhrase[i]->pNode;
assert( pExpr->apExprPhrase[i]->nTerm==1 );
if( bLive &&
(pBuf->n==0 || pNode->iRowid!=pExpr->pRoot->iRowid || pNode->bEof)
){
pRet[i].bMiss = 1;
}else{
pBuf->n = 0;
}
}
}
return pRet;
}
struct Fts5ExprCtx {
Fts5Expr *pExpr;
Fts5PoslistPopulator *aPopulator;
i64 iOff;
};
typedef struct Fts5ExprCtx Fts5ExprCtx;
/*
** TODO: Make this more efficient!
*/
static int fts5ExprColsetTest(Fts5Colset *pColset, int iCol){
int i;
for(i=0; i<pColset->nCol; i++){
if( pColset->aiCol[i]==iCol ) return 1;
}
return 0;
}
static int fts5ExprPopulatePoslistsCb(
void *pCtx, /* Copy of 2nd argument to xTokenize() */
int tflags, /* Mask of FTS5_TOKEN_* flags */
const char *pToken, /* Pointer to buffer containing token */
int nToken, /* Size of token in bytes */
int iUnused1, /* Byte offset of token within input text */
int iUnused2 /* Byte offset of end of token within input text */
){
Fts5ExprCtx *p = (Fts5ExprCtx*)pCtx;
Fts5Expr *pExpr = p->pExpr;
int i;
UNUSED_PARAM2(iUnused1, iUnused2);
if( nToken>FTS5_MAX_TOKEN_SIZE ) nToken = FTS5_MAX_TOKEN_SIZE;
if( (tflags & FTS5_TOKEN_COLOCATED)==0 ) p->iOff++;
for(i=0; i<pExpr->nPhrase; i++){
Fts5ExprTerm *pTerm;
if( p->aPopulator[i].bOk==0 ) continue;
for(pTerm=&pExpr->apExprPhrase[i]->aTerm[0]; pTerm; pTerm=pTerm->pSynonym){
int nTerm = (int)strlen(pTerm->zTerm);
if( (nTerm==nToken || (nTerm<nToken && pTerm->bPrefix))
&& memcmp(pTerm->zTerm, pToken, nTerm)==0
){
int rc = sqlite3Fts5PoslistWriterAppend(
&pExpr->apExprPhrase[i]->poslist, &p->aPopulator[i].writer, p->iOff
);
if( rc ) return rc;
break;
}
}
}
return SQLITE_OK;
}
static int sqlite3Fts5ExprPopulatePoslists(
Fts5Config *pConfig,
Fts5Expr *pExpr,
Fts5PoslistPopulator *aPopulator,
int iCol,
const char *z, int n
){
int i;
Fts5ExprCtx sCtx;
sCtx.pExpr = pExpr;
sCtx.aPopulator = aPopulator;
sCtx.iOff = (((i64)iCol) << 32) - 1;
for(i=0; i<pExpr->nPhrase; i++){
Fts5ExprNode *pNode = pExpr->apExprPhrase[i]->pNode;
Fts5Colset *pColset = pNode->pNear->pColset;
if( (pColset && 0==fts5ExprColsetTest(pColset, iCol))
|| aPopulator[i].bMiss
){
aPopulator[i].bOk = 0;
}else{
aPopulator[i].bOk = 1;
}
}
return sqlite3Fts5Tokenize(pConfig,
FTS5_TOKENIZE_DOCUMENT, z, n, (void*)&sCtx, fts5ExprPopulatePoslistsCb
);
}
static void fts5ExprClearPoslists(Fts5ExprNode *pNode){
if( pNode->eType==FTS5_TERM || pNode->eType==FTS5_STRING ){
pNode->pNear->apPhrase[0]->poslist.n = 0;
}else{
int i;
for(i=0; i<pNode->nChild; i++){
fts5ExprClearPoslists(pNode->apChild[i]);
}
}
}
static int fts5ExprCheckPoslists(Fts5ExprNode *pNode, i64 iRowid){
pNode->iRowid = iRowid;
pNode->bEof = 0;
switch( pNode->eType ){
case FTS5_TERM:
case FTS5_STRING:
return (pNode->pNear->apPhrase[0]->poslist.n>0);
case FTS5_AND: {
int i;
for(i=0; i<pNode->nChild; i++){
if( fts5ExprCheckPoslists(pNode->apChild[i], iRowid)==0 ){
fts5ExprClearPoslists(pNode);
return 0;
}
}
break;
}
case FTS5_OR: {
int i;
int bRet = 0;
for(i=0; i<pNode->nChild; i++){
if( fts5ExprCheckPoslists(pNode->apChild[i], iRowid) ){
bRet = 1;
}
}
return bRet;
}
default: {
assert( pNode->eType==FTS5_NOT );
if( 0==fts5ExprCheckPoslists(pNode->apChild[0], iRowid)
|| 0!=fts5ExprCheckPoslists(pNode->apChild[1], iRowid)
){
fts5ExprClearPoslists(pNode);
return 0;
}
break;
}
}
return 1;
}
static void sqlite3Fts5ExprCheckPoslists(Fts5Expr *pExpr, i64 iRowid){
fts5ExprCheckPoslists(pExpr->pRoot, iRowid);
}
/*
** This function is only called for detail=columns tables.
*/
static int sqlite3Fts5ExprPhraseCollist(
Fts5Expr *pExpr,
int iPhrase,
const u8 **ppCollist,
int *pnCollist
){
Fts5ExprPhrase *pPhrase = pExpr->apExprPhrase[iPhrase];
Fts5ExprNode *pNode = pPhrase->pNode;
int rc = SQLITE_OK;
assert( iPhrase>=0 && iPhrase<pExpr->nPhrase );
assert( pExpr->pConfig->eDetail==FTS5_DETAIL_COLUMNS );
if( pNode->bEof==0
&& pNode->iRowid==pExpr->pRoot->iRowid
&& pPhrase->poslist.n>0
){
Fts5ExprTerm *pTerm = &pPhrase->aTerm[0];
if( pTerm->pSynonym ){
Fts5Buffer *pBuf = (Fts5Buffer*)&pTerm->pSynonym[1];
rc = fts5ExprSynonymList(
pTerm, pNode->iRowid, pBuf, (u8**)ppCollist, pnCollist
);
}else{
*ppCollist = pPhrase->aTerm[0].pIter->pData;
*pnCollist = pPhrase->aTerm[0].pIter->nData;
}
}else{
*ppCollist = 0;
*pnCollist = 0;
}
return rc;
}
#line 1 "fts5_hash.c"
/*
** 2014 August 11
**
** The author disclaims copyright to this source code. In place of
** a legal notice, here is a blessing:
**
** May you do good and not evil.
** May you find forgiveness for yourself and forgive others.
** May you share freely, never taking more than you give.
**
******************************************************************************
**
*/
/* #include "third_party/sqlite3/fts5Int.h" */
typedef struct Fts5HashEntry Fts5HashEntry;
/*
** This file contains the implementation of an in-memory hash table used
** to accumuluate "term -> doclist" content before it is flused to a level-0
** segment.
*/
struct Fts5Hash {
int eDetail; /* Copy of Fts5Config.eDetail */
int *pnByte; /* Pointer to bytes counter */
int nEntry; /* Number of entries currently in hash */
int nSlot; /* Size of aSlot[] array */
Fts5HashEntry *pScan; /* Current ordered scan item */
Fts5HashEntry **aSlot; /* Array of hash slots */
};
/*
** Each entry in the hash table is represented by an object of the
** following type. Each object, its key (a nul-terminated string) and
** its current data are stored in a single memory allocation. The
** key immediately follows the object in memory. The position list
** data immediately follows the key data in memory.
**
** The data that follows the key is in a similar, but not identical format
** to the doclist data stored in the database. It is:
**
** * Rowid, as a varint
** * Position list, without 0x00 terminator.
** * Size of previous position list and rowid, as a 4 byte
** big-endian integer.
**
** iRowidOff:
** Offset of last rowid written to data area. Relative to first byte of
** structure.
**
** nData:
** Bytes of data written since iRowidOff.
*/
struct Fts5HashEntry {
Fts5HashEntry *pHashNext; /* Next hash entry with same hash-key */
Fts5HashEntry *pScanNext; /* Next entry in sorted order */
int nAlloc; /* Total size of allocation */
int iSzPoslist; /* Offset of space for 4-byte poslist size */
int nData; /* Total bytes of data (incl. structure) */
int nKey; /* Length of key in bytes */
u8 bDel; /* Set delete-flag @ iSzPoslist */
u8 bContent; /* Set content-flag (detail=none mode) */
i16 iCol; /* Column of last value written */
int iPos; /* Position of last value written */
i64 iRowid; /* Rowid of last value written */
};
/*
** Eqivalent to:
**
** char *fts5EntryKey(Fts5HashEntry *pEntry){ return zKey; }
*/
#define fts5EntryKey(p) ( ((char *)(&(p)[1])) )
/*
** Allocate a new hash table.
*/
static int sqlite3Fts5HashNew(Fts5Config *pConfig, Fts5Hash **ppNew, int *pnByte){
int rc = SQLITE_OK;
Fts5Hash *pNew;
*ppNew = pNew = (Fts5Hash*)sqlite3_malloc(sizeof(Fts5Hash));
if( pNew==0 ){
rc = SQLITE_NOMEM;
}else{
sqlite3_int64 nByte;
memset(pNew, 0, sizeof(Fts5Hash));
pNew->pnByte = pnByte;
pNew->eDetail = pConfig->eDetail;
pNew->nSlot = 1024;
nByte = sizeof(Fts5HashEntry*) * pNew->nSlot;
pNew->aSlot = (Fts5HashEntry**)sqlite3_malloc64(nByte);
if( pNew->aSlot==0 ){
sqlite3_free(pNew);
*ppNew = 0;
rc = SQLITE_NOMEM;
}else{
memset(pNew->aSlot, 0, (size_t)nByte);
}
}
return rc;
}
/*
** Free a hash table object.
*/
static void sqlite3Fts5HashFree(Fts5Hash *pHash){
if( pHash ){
sqlite3Fts5HashClear(pHash);
sqlite3_free(pHash->aSlot);
sqlite3_free(pHash);
}
}
/*
** Empty (but do not delete) a hash table.
*/
static void sqlite3Fts5HashClear(Fts5Hash *pHash){
int i;
for(i=0; i<pHash->nSlot; i++){
Fts5HashEntry *pNext;
Fts5HashEntry *pSlot;
for(pSlot=pHash->aSlot[i]; pSlot; pSlot=pNext){
pNext = pSlot->pHashNext;
sqlite3_free(pSlot);
}
}
memset(pHash->aSlot, 0, pHash->nSlot * sizeof(Fts5HashEntry*));
pHash->nEntry = 0;
}
static unsigned int fts5HashKey(int nSlot, const u8 *p, int n){
int i;
unsigned int h = 13;
for(i=n-1; i>=0; i--){
h = (h << 3) ^ h ^ p[i];
}
return (h % nSlot);
}
static unsigned int fts5HashKey2(int nSlot, u8 b, const u8 *p, int n){
int i;
unsigned int h = 13;
for(i=n-1; i>=0; i--){
h = (h << 3) ^ h ^ p[i];
}
h = (h << 3) ^ h ^ b;
return (h % nSlot);
}
/*
** Resize the hash table by doubling the number of slots.
*/
static int fts5HashResize(Fts5Hash *pHash){
int nNew = pHash->nSlot*2;
int i;
Fts5HashEntry **apNew;
Fts5HashEntry **apOld = pHash->aSlot;
apNew = (Fts5HashEntry**)sqlite3_malloc64(nNew*sizeof(Fts5HashEntry*));
if( !apNew ) return SQLITE_NOMEM;
memset(apNew, 0, nNew*sizeof(Fts5HashEntry*));
for(i=0; i<pHash->nSlot; i++){
while( apOld[i] ){
unsigned int iHash;
Fts5HashEntry *p = apOld[i];
apOld[i] = p->pHashNext;
iHash = fts5HashKey(nNew, (u8*)fts5EntryKey(p),
(int)strlen(fts5EntryKey(p)));
p->pHashNext = apNew[iHash];
apNew[iHash] = p;
}
}
sqlite3_free(apOld);
pHash->nSlot = nNew;
pHash->aSlot = apNew;
return SQLITE_OK;
}
static int fts5HashAddPoslistSize(
Fts5Hash *pHash,
Fts5HashEntry *p,
Fts5HashEntry *p2
){
int nRet = 0;
if( p->iSzPoslist ){
u8 *pPtr = p2 ? (u8*)p2 : (u8*)p;
int nData = p->nData;
if( pHash->eDetail==FTS5_DETAIL_NONE ){
assert( nData==p->iSzPoslist );
if( p->bDel ){
pPtr[nData++] = 0x00;
if( p->bContent ){
pPtr[nData++] = 0x00;
}
}
}else{
int nSz = (nData - p->iSzPoslist - 1); /* Size in bytes */
int nPos = nSz*2 + p->bDel; /* Value of nPos field */
assert( p->bDel==0 || p->bDel==1 );
if( nPos<=127 ){
pPtr[p->iSzPoslist] = (u8)nPos;
}else{
int nByte = sqlite3Fts5GetVarintLen((u32)nPos);
memmove(&pPtr[p->iSzPoslist + nByte], &pPtr[p->iSzPoslist + 1], nSz);
sqlite3Fts5PutVarint(&pPtr[p->iSzPoslist], nPos);
nData += (nByte-1);
}
}
nRet = nData - p->nData;
if( p2==0 ){
p->iSzPoslist = 0;
p->bDel = 0;
p->bContent = 0;
p->nData = nData;
}
}
return nRet;
}
/*
** Add an entry to the in-memory hash table. The key is the concatenation
** of bByte and (pToken/nToken). The value is (iRowid/iCol/iPos).
**
** (bByte || pToken) -> (iRowid,iCol,iPos)
**
** Or, if iCol is negative, then the value is a delete marker.
*/
static int sqlite3Fts5HashWrite(
Fts5Hash *pHash,
i64 iRowid, /* Rowid for this entry */
int iCol, /* Column token appears in (-ve -> delete) */
int iPos, /* Position of token within column */
char bByte, /* First byte of token */
const char *pToken, int nToken /* Token to add or remove to or from index */
){
unsigned int iHash;
Fts5HashEntry *p;
u8 *pPtr;
int nIncr = 0; /* Amount to increment (*pHash->pnByte) by */
int bNew; /* If non-delete entry should be written */
bNew = (pHash->eDetail==FTS5_DETAIL_FULL);
/* Attempt to locate an existing hash entry */
iHash = fts5HashKey2(pHash->nSlot, (u8)bByte, (const u8*)pToken, nToken);
for(p=pHash->aSlot[iHash]; p; p=p->pHashNext){
char *zKey = fts5EntryKey(p);
if( zKey[0]==bByte
&& p->nKey==nToken
&& memcmp(&zKey[1], pToken, nToken)==0
){
break;
}
}
/* If an existing hash entry cannot be found, create a new one. */
if( p==0 ){
/* Figure out how much space to allocate */
char *zKey;
sqlite3_int64 nByte = sizeof(Fts5HashEntry) + (nToken+1) + 1 + 64;
if( nByte<128 ) nByte = 128;
/* Grow the Fts5Hash.aSlot[] array if necessary. */
if( (pHash->nEntry*2)>=pHash->nSlot ){
int rc = fts5HashResize(pHash);
if( rc!=SQLITE_OK ) return rc;
iHash = fts5HashKey2(pHash->nSlot, (u8)bByte, (const u8*)pToken, nToken);
}
/* Allocate new Fts5HashEntry and add it to the hash table. */
p = (Fts5HashEntry*)sqlite3_malloc64(nByte);
if( !p ) return SQLITE_NOMEM;
memset(p, 0, sizeof(Fts5HashEntry));
p->nAlloc = (int)nByte;
zKey = fts5EntryKey(p);
zKey[0] = bByte;
memcpy(&zKey[1], pToken, nToken);
assert( iHash==fts5HashKey(pHash->nSlot, (u8*)zKey, nToken+1) );
p->nKey = nToken;
zKey[nToken+1] = '\0';
p->nData = nToken+1 + 1 + sizeof(Fts5HashEntry);
p->pHashNext = pHash->aSlot[iHash];
pHash->aSlot[iHash] = p;
pHash->nEntry++;
/* Add the first rowid field to the hash-entry */
p->nData += sqlite3Fts5PutVarint(&((u8*)p)[p->nData], iRowid);
p->iRowid = iRowid;
p->iSzPoslist = p->nData;
if( pHash->eDetail!=FTS5_DETAIL_NONE ){
p->nData += 1;
p->iCol = (pHash->eDetail==FTS5_DETAIL_FULL ? 0 : -1);
}
}else{
/* Appending to an existing hash-entry. Check that there is enough
** space to append the largest possible new entry. Worst case scenario
** is:
**
** + 9 bytes for a new rowid,
** + 4 byte reserved for the "poslist size" varint.
** + 1 byte for a "new column" byte,
** + 3 bytes for a new column number (16-bit max) as a varint,
** + 5 bytes for the new position offset (32-bit max).
*/
if( (p->nAlloc - p->nData) < (9 + 4 + 1 + 3 + 5) ){
sqlite3_int64 nNew = p->nAlloc * 2;
Fts5HashEntry *pNew;
Fts5HashEntry **pp;
pNew = (Fts5HashEntry*)sqlite3_realloc64(p, nNew);
if( pNew==0 ) return SQLITE_NOMEM;
pNew->nAlloc = (int)nNew;
for(pp=&pHash->aSlot[iHash]; *pp!=p; pp=&(*pp)->pHashNext);
*pp = pNew;
p = pNew;
}
nIncr -= p->nData;
}
assert( (p->nAlloc - p->nData) >= (9 + 4 + 1 + 3 + 5) );
pPtr = (u8*)p;
/* If this is a new rowid, append the 4-byte size field for the previous
** entry, and the new rowid for this entry. */
if( iRowid!=p->iRowid ){
u64 iDiff = (u64)iRowid - (u64)p->iRowid;
fts5HashAddPoslistSize(pHash, p, 0);
p->nData += sqlite3Fts5PutVarint(&pPtr[p->nData], iDiff);
p->iRowid = iRowid;
bNew = 1;
p->iSzPoslist = p->nData;
if( pHash->eDetail!=FTS5_DETAIL_NONE ){
p->nData += 1;
p->iCol = (pHash->eDetail==FTS5_DETAIL_FULL ? 0 : -1);
p->iPos = 0;
}
}
if( iCol>=0 ){
if( pHash->eDetail==FTS5_DETAIL_NONE ){
p->bContent = 1;
}else{
/* Append a new column value, if necessary */
assert( iCol>=p->iCol );
if( iCol!=p->iCol ){
if( pHash->eDetail==FTS5_DETAIL_FULL ){
pPtr[p->nData++] = 0x01;
p->nData += sqlite3Fts5PutVarint(&pPtr[p->nData], iCol);
p->iCol = (i16)iCol;
p->iPos = 0;
}else{
bNew = 1;
p->iCol = (i16)(iPos = iCol);
}
}
/* Append the new position offset, if necessary */
if( bNew ){
p->nData += sqlite3Fts5PutVarint(&pPtr[p->nData], iPos - p->iPos + 2);
p->iPos = iPos;
}
}
}else{
/* This is a delete. Set the delete flag. */
p->bDel = 1;
}
nIncr += p->nData;
*pHash->pnByte += nIncr;
return SQLITE_OK;
}
/*
** Arguments pLeft and pRight point to linked-lists of hash-entry objects,
** each sorted in key order. This function merges the two lists into a
** single list and returns a pointer to its first element.
*/
static Fts5HashEntry *fts5HashEntryMerge(
Fts5HashEntry *pLeft,
Fts5HashEntry *pRight
){
Fts5HashEntry *p1 = pLeft;
Fts5HashEntry *p2 = pRight;
Fts5HashEntry *pRet = 0;
Fts5HashEntry **ppOut = &pRet;
while( p1 || p2 ){
if( p1==0 ){
*ppOut = p2;
p2 = 0;
}else if( p2==0 ){
*ppOut = p1;
p1 = 0;
}else{
int i = 0;
char *zKey1 = fts5EntryKey(p1);
char *zKey2 = fts5EntryKey(p2);
while( zKey1[i]==zKey2[i] ) i++;
if( ((u8)zKey1[i])>((u8)zKey2[i]) ){
/* p2 is smaller */
*ppOut = p2;
ppOut = &p2->pScanNext;
p2 = p2->pScanNext;
}else{
/* p1 is smaller */
*ppOut = p1;
ppOut = &p1->pScanNext;
p1 = p1->pScanNext;
}
*ppOut = 0;
}
}
return pRet;
}
/*
** Extract all tokens from hash table iHash and link them into a list
** in sorted order. The hash table is cleared before returning. It is
** the responsibility of the caller to free the elements of the returned
** list.
*/
static int fts5HashEntrySort(
Fts5Hash *pHash,
const char *pTerm, int nTerm, /* Query prefix, if any */
Fts5HashEntry **ppSorted
){
const int nMergeSlot = 32;
Fts5HashEntry **ap;
Fts5HashEntry *pList;
int iSlot;
int i;
*ppSorted = 0;
ap = sqlite3_malloc64(sizeof(Fts5HashEntry*) * nMergeSlot);
if( !ap ) return SQLITE_NOMEM;
memset(ap, 0, sizeof(Fts5HashEntry*) * nMergeSlot);
for(iSlot=0; iSlot<pHash->nSlot; iSlot++){
Fts5HashEntry *pIter;
for(pIter=pHash->aSlot[iSlot]; pIter; pIter=pIter->pHashNext){
if( pTerm==0
|| (pIter->nKey+1>=nTerm && 0==memcmp(fts5EntryKey(pIter), pTerm, nTerm))
){
Fts5HashEntry *pEntry = pIter;
pEntry->pScanNext = 0;
for(i=0; ap[i]; i++){
pEntry = fts5HashEntryMerge(pEntry, ap[i]);
ap[i] = 0;
}
ap[i] = pEntry;
}
}
}
pList = 0;
for(i=0; i<nMergeSlot; i++){
pList = fts5HashEntryMerge(pList, ap[i]);
}
pHash->nEntry = 0;
sqlite3_free(ap);
*ppSorted = pList;
return SQLITE_OK;
}
/*
** Query the hash table for a doclist associated with term pTerm/nTerm.
*/
static int sqlite3Fts5HashQuery(
Fts5Hash *pHash, /* Hash table to query */
int nPre,
const char *pTerm, int nTerm, /* Query term */
void **ppOut, /* OUT: Pointer to new object */
int *pnDoclist /* OUT: Size of doclist in bytes */
){
unsigned int iHash = fts5HashKey(pHash->nSlot, (const u8*)pTerm, nTerm);
char *zKey = 0;
Fts5HashEntry *p;
for(p=pHash->aSlot[iHash]; p; p=p->pHashNext){
zKey = fts5EntryKey(p);
assert( p->nKey+1==(int)strlen(zKey) );
if( nTerm==p->nKey+1 && memcmp(zKey, pTerm, nTerm)==0 ) break;
}
if( p ){
int nHashPre = sizeof(Fts5HashEntry) + nTerm + 1;
int nList = p->nData - nHashPre;
u8 *pRet = (u8*)(*ppOut = sqlite3_malloc64(nPre + nList + 10));
if( pRet ){
Fts5HashEntry *pFaux = (Fts5HashEntry*)&pRet[nPre-nHashPre];
memcpy(&pRet[nPre], &((u8*)p)[nHashPre], nList);
nList += fts5HashAddPoslistSize(pHash, p, pFaux);
*pnDoclist = nList;
}else{
*pnDoclist = 0;
return SQLITE_NOMEM;
}
}else{
*ppOut = 0;
*pnDoclist = 0;
}
return SQLITE_OK;
}
static int sqlite3Fts5HashScanInit(
Fts5Hash *p, /* Hash table to query */
const char *pTerm, int nTerm /* Query prefix */
){
return fts5HashEntrySort(p, pTerm, nTerm, &p->pScan);
}
static void sqlite3Fts5HashScanNext(Fts5Hash *p){
assert( !sqlite3Fts5HashScanEof(p) );
p->pScan = p->pScan->pScanNext;
}
static int sqlite3Fts5HashScanEof(Fts5Hash *p){
return (p->pScan==0);
}
static void sqlite3Fts5HashScanEntry(
Fts5Hash *pHash,
const char **pzTerm, /* OUT: term (nul-terminated) */
const u8 **ppDoclist, /* OUT: pointer to doclist */
int *pnDoclist /* OUT: size of doclist in bytes */
){
Fts5HashEntry *p;
if( (p = pHash->pScan) ){
char *zKey = fts5EntryKey(p);
int nTerm = (int)strlen(zKey);
fts5HashAddPoslistSize(pHash, p, 0);
*pzTerm = zKey;
*ppDoclist = (const u8*)&zKey[nTerm+1];
*pnDoclist = p->nData - (sizeof(Fts5HashEntry) + nTerm + 1);
}else{
*pzTerm = 0;
*ppDoclist = 0;
*pnDoclist = 0;
}
}
#line 1 "fts5_index.c"
/*
** 2014 May 31
**
** The author disclaims copyright to this source code. In place of
** a legal notice, here is a blessing:
**
** May you do good and not evil.
** May you find forgiveness for yourself and forgive others.
** May you share freely, never taking more than you give.
**
******************************************************************************
**
** Low level access to the FTS index stored in the database file. The
** routines in this file file implement all read and write access to the
** %_data table. Other parts of the system access this functionality via
** the interface defined in fts5Int.h.
*/
/* #include "third_party/sqlite3/fts5Int.h" */
/*
** Overview:
**
** The %_data table contains all the FTS indexes for an FTS5 virtual table.
** As well as the main term index, there may be up to 31 prefix indexes.
** The format is similar to FTS3/4, except that:
**
** * all segment b-tree leaf data is stored in fixed size page records
** (e.g. 1000 bytes). A single doclist may span multiple pages. Care is
** taken to ensure it is possible to iterate in either direction through
** the entries in a doclist, or to seek to a specific entry within a
** doclist, without loading it into memory.
**
** * large doclists that span many pages have associated "doclist index"
** records that contain a copy of the first rowid on each page spanned by
** the doclist. This is used to speed up seek operations, and merges of
** large doclists with very small doclists.
**
** * extra fields in the "structure record" record the state of ongoing
** incremental merge operations.
**
*/
#define FTS5_OPT_WORK_UNIT 1000 /* Number of leaf pages per optimize step */
#define FTS5_WORK_UNIT 64 /* Number of leaf pages in unit of work */
#define FTS5_MIN_DLIDX_SIZE 4 /* Add dlidx if this many empty pages */
#define FTS5_MAIN_PREFIX '0'
#if FTS5_MAX_PREFIX_INDEXES > 31
# error "FTS5_MAX_PREFIX_INDEXES is too large"
#endif
/*
** Details:
**
** The %_data table managed by this module,
**
** CREATE TABLE %_data(id INTEGER PRIMARY KEY, block BLOB);
**
** , contains the following 5 types of records. See the comments surrounding
** the FTS5_*_ROWID macros below for a description of how %_data rowids are
** assigned to each fo them.
**
** 1. Structure Records:
**
** The set of segments that make up an index - the index structure - are
** recorded in a single record within the %_data table. The record consists
** of a single 32-bit configuration cookie value followed by a list of
** SQLite varints. If the FTS table features more than one index (because
** there are one or more prefix indexes), it is guaranteed that all share
** the same cookie value.
**
** Immediately following the configuration cookie, the record begins with
** three varints:
**
** + number of levels,
** + total number of segments on all levels,
** + value of write counter.
**
** Then, for each level from 0 to nMax:
**
** + number of input segments in ongoing merge.
** + total number of segments in level.
** + for each segment from oldest to newest:
** + segment id (always > 0)
** + first leaf page number (often 1, always greater than 0)
** + final leaf page number
**
** 2. The Averages Record:
**
** A single record within the %_data table. The data is a list of varints.
** The first value is the number of rows in the index. Then, for each column
** from left to right, the total number of tokens in the column for all
** rows of the table.
**
** 3. Segment leaves:
**
** TERM/DOCLIST FORMAT:
**
** Most of each segment leaf is taken up by term/doclist data. The
** general format of term/doclist, starting with the first term
** on the leaf page, is:
**
** varint : size of first term
** blob: first term data
** doclist: first doclist
** zero-or-more {
** varint: number of bytes in common with previous term
** varint: number of bytes of new term data (nNew)
** blob: nNew bytes of new term data
** doclist: next doclist
** }
**
** doclist format:
**
** varint: first rowid
** poslist: first poslist
** zero-or-more {
** varint: rowid delta (always > 0)
** poslist: next poslist
** }
**
** poslist format:
**
** varint: size of poslist in bytes multiplied by 2, not including
** this field. Plus 1 if this entry carries the "delete" flag.
** collist: collist for column 0
** zero-or-more {
** 0x01 byte
** varint: column number (I)
** collist: collist for column I
** }
**
** collist format:
**
** varint: first offset + 2
** zero-or-more {
** varint: offset delta + 2
** }
**
** PAGE FORMAT
**
** Each leaf page begins with a 4-byte header containing 2 16-bit
** unsigned integer fields in big-endian format. They are:
**
** * The byte offset of the first rowid on the page, if it exists
** and occurs before the first term (otherwise 0).
**
** * The byte offset of the start of the page footer. If the page
** footer is 0 bytes in size, then this field is the same as the
** size of the leaf page in bytes.
**
** The page footer consists of a single varint for each term located
** on the page. Each varint is the byte offset of the current term
** within the page, delta-compressed against the previous value. In
** other words, the first varint in the footer is the byte offset of
** the first term, the second is the byte offset of the second less that
** of the first, and so on.
**
** The term/doclist format described above is accurate if the entire
** term/doclist data fits on a single leaf page. If this is not the case,
** the format is changed in two ways:
**
** + if the first rowid on a page occurs before the first term, it
** is stored as a literal value:
**
** varint: first rowid
**
** + the first term on each page is stored in the same way as the
** very first term of the segment:
**
** varint : size of first term
** blob: first term data
**
** 5. Segment doclist indexes:
**
** Doclist indexes are themselves b-trees, however they usually consist of
** a single leaf record only. The format of each doclist index leaf page
** is:
**
** * Flags byte. Bits are:
** 0x01: Clear if leaf is also the root page, otherwise set.
**
** * Page number of fts index leaf page. As a varint.
**
** * First rowid on page indicated by previous field. As a varint.
**
** * A list of varints, one for each subsequent termless page. A
** positive delta if the termless page contains at least one rowid,
** or an 0x00 byte otherwise.
**
** Internal doclist index nodes are:
**
** * Flags byte. Bits are:
** 0x01: Clear for root page, otherwise set.
**
** * Page number of first child page. As a varint.
**
** * Copy of first rowid on page indicated by previous field. As a varint.
**
** * A list of delta-encoded varints - the first rowid on each subsequent
** child page.
**
*/
/*
** Rowids for the averages and structure records in the %_data table.
*/
#define FTS5_AVERAGES_ROWID 1 /* Rowid used for the averages record */
#define FTS5_STRUCTURE_ROWID 10 /* The structure record */
/*
** Macros determining the rowids used by segment leaves and dlidx leaves
** and nodes. All nodes and leaves are stored in the %_data table with large
** positive rowids.
**
** Each segment has a unique non-zero 16-bit id.
**
** The rowid for each segment leaf is found by passing the segment id and
** the leaf page number to the FTS5_SEGMENT_ROWID macro. Leaves are numbered
** sequentially starting from 1.
*/
#define FTS5_DATA_ID_B 16 /* Max seg id number 65535 */
#define FTS5_DATA_DLI_B 1 /* Doclist-index flag (1 bit) */
#define FTS5_DATA_HEIGHT_B 5 /* Max dlidx tree height of 32 */
#define FTS5_DATA_PAGE_B 31 /* Max page number of 2147483648 */
#define fts5_dri(segid, dlidx, height, pgno) ( \
((i64)(segid) << (FTS5_DATA_PAGE_B+FTS5_DATA_HEIGHT_B+FTS5_DATA_DLI_B)) + \
((i64)(dlidx) << (FTS5_DATA_PAGE_B + FTS5_DATA_HEIGHT_B)) + \
((i64)(height) << (FTS5_DATA_PAGE_B)) + \
((i64)(pgno)) \
)
#define FTS5_SEGMENT_ROWID(segid, pgno) fts5_dri(segid, 0, 0, pgno)
#define FTS5_DLIDX_ROWID(segid, height, pgno) fts5_dri(segid, 1, height, pgno)
#ifdef SQLITE_DEBUG
static int sqlite3Fts5Corrupt() { return SQLITE_CORRUPT_VTAB; }
#endif
/*
** Each time a blob is read from the %_data table, it is padded with this
** many zero bytes. This makes it easier to decode the various record formats
** without overreading if the records are corrupt.
*/
#define FTS5_DATA_ZERO_PADDING 8
#define FTS5_DATA_PADDING 20
typedef struct Fts5Data Fts5Data;
typedef struct Fts5DlidxIter Fts5DlidxIter;
typedef struct Fts5DlidxLvl Fts5DlidxLvl;
typedef struct Fts5DlidxWriter Fts5DlidxWriter;
typedef struct Fts5Iter Fts5Iter;
typedef struct Fts5PageWriter Fts5PageWriter;
typedef struct Fts5SegIter Fts5SegIter;
typedef struct Fts5DoclistIter Fts5DoclistIter;
typedef struct Fts5SegWriter Fts5SegWriter;
typedef struct Fts5Structure Fts5Structure;
typedef struct Fts5StructureLevel Fts5StructureLevel;
typedef struct Fts5StructureSegment Fts5StructureSegment;
struct Fts5Data {
u8 *p; /* Pointer to buffer containing record */
int nn; /* Size of record in bytes */
int szLeaf; /* Size of leaf without page-index */
};
/*
** One object per %_data table.
*/
struct Fts5Index {
Fts5Config *pConfig; /* Virtual table configuration */
char *zDataTbl; /* Name of %_data table */
int nWorkUnit; /* Leaf pages in a "unit" of work */
/*
** Variables related to the accumulation of tokens and doclists within the
** in-memory hash tables before they are flushed to disk.
*/
Fts5Hash *pHash; /* Hash table for in-memory data */
int nPendingData; /* Current bytes of pending data */
i64 iWriteRowid; /* Rowid for current doc being written */
int bDelete; /* Current write is a delete */
/* Error state. */
int rc; /* Current error code */
/* State used by the fts5DataXXX() functions. */
sqlite3_blob *pReader; /* RO incr-blob open on %_data table */
sqlite3_stmt *pWriter; /* "INSERT ... %_data VALUES(?,?)" */
sqlite3_stmt *pDeleter; /* "DELETE FROM %_data ... id>=? AND id<=?" */
sqlite3_stmt *pIdxWriter; /* "INSERT ... %_idx VALUES(?,?,?,?)" */
sqlite3_stmt *pIdxDeleter; /* "DELETE FROM %_idx WHERE segid=? */
sqlite3_stmt *pIdxSelect;
int nRead; /* Total number of blocks read */
sqlite3_stmt *pDataVersion;
i64 iStructVersion; /* data_version when pStruct read */
Fts5Structure *pStruct; /* Current db structure (or NULL) */
};
struct Fts5DoclistIter {
u8 *aEof; /* Pointer to 1 byte past end of doclist */
/* Output variables. aPoslist==0 at EOF */
i64 iRowid;
u8 *aPoslist;
int nPoslist;
int nSize;
};
/*
** The contents of the "structure" record for each index are represented
** using an Fts5Structure record in memory. Which uses instances of the
** other Fts5StructureXXX types as components.
*/
struct Fts5StructureSegment {
int iSegid; /* Segment id */
int pgnoFirst; /* First leaf page number in segment */
int pgnoLast; /* Last leaf page number in segment */
};
struct Fts5StructureLevel {
int nMerge; /* Number of segments in incr-merge */
int nSeg; /* Total number of segments on level */
Fts5StructureSegment *aSeg; /* Array of segments. aSeg[0] is oldest. */
};
struct Fts5Structure {
int nRef; /* Object reference count */
u64 nWriteCounter; /* Total leaves written to level 0 */
int nSegment; /* Total segments in this structure */
int nLevel; /* Number of levels in this index */
Fts5StructureLevel aLevel[1]; /* Array of nLevel level objects */
};
/*
** An object of type Fts5SegWriter is used to write to segments.
*/
struct Fts5PageWriter {
int pgno; /* Page number for this page */
int iPrevPgidx; /* Previous value written into pgidx */
Fts5Buffer buf; /* Buffer containing leaf data */
Fts5Buffer pgidx; /* Buffer containing page-index */
Fts5Buffer term; /* Buffer containing previous term on page */
};
struct Fts5DlidxWriter {
int pgno; /* Page number for this page */
int bPrevValid; /* True if iPrev is valid */
i64 iPrev; /* Previous rowid value written to page */
Fts5Buffer buf; /* Buffer containing page data */
};
struct Fts5SegWriter {
int iSegid; /* Segid to write to */
Fts5PageWriter writer; /* PageWriter object */
i64 iPrevRowid; /* Previous rowid written to current leaf */
u8 bFirstRowidInDoclist; /* True if next rowid is first in doclist */
u8 bFirstRowidInPage; /* True if next rowid is first in page */
/* TODO1: Can use (writer.pgidx.n==0) instead of bFirstTermInPage */
u8 bFirstTermInPage; /* True if next term will be first in leaf */
int nLeafWritten; /* Number of leaf pages written */
int nEmpty; /* Number of contiguous term-less nodes */
int nDlidx; /* Allocated size of aDlidx[] array */
Fts5DlidxWriter *aDlidx; /* Array of Fts5DlidxWriter objects */
/* Values to insert into the %_idx table */
Fts5Buffer btterm; /* Next term to insert into %_idx table */
int iBtPage; /* Page number corresponding to btterm */
};
typedef struct Fts5CResult Fts5CResult;
struct Fts5CResult {
u16 iFirst; /* aSeg[] index of firstest iterator */
u8 bTermEq; /* True if the terms are equal */
};
/*
** Object for iterating through a single segment, visiting each term/rowid
** pair in the segment.
**
** pSeg:
** The segment to iterate through.
**
** iLeafPgno:
** Current leaf page number within segment.
**
** iLeafOffset:
** Byte offset within the current leaf that is the first byte of the
** position list data (one byte passed the position-list size field).
** rowid field of the current entry. Usually this is the size field of the
** position list data. The exception is if the rowid for the current entry
** is the last thing on the leaf page.
**
** pLeaf:
** Buffer containing current leaf page data. Set to NULL at EOF.
**
** iTermLeafPgno, iTermLeafOffset:
** Leaf page number containing the last term read from the segment. And
** the offset immediately following the term data.
**
** flags:
** Mask of FTS5_SEGITER_XXX values. Interpreted as follows:
**
** FTS5_SEGITER_ONETERM:
** If set, set the iterator to point to EOF after the current doclist
** has been exhausted. Do not proceed to the next term in the segment.
**
** FTS5_SEGITER_REVERSE:
** This flag is only ever set if FTS5_SEGITER_ONETERM is also set. If
** it is set, iterate through rowid in descending order instead of the
** default ascending order.
**
** iRowidOffset/nRowidOffset/aRowidOffset:
** These are used if the FTS5_SEGITER_REVERSE flag is set.
**
** For each rowid on the page corresponding to the current term, the
** corresponding aRowidOffset[] entry is set to the byte offset of the
** start of the "position-list-size" field within the page.
**
** iTermIdx:
** Index of current term on iTermLeafPgno.
*/
struct Fts5SegIter {
Fts5StructureSegment *pSeg; /* Segment to iterate through */
int flags; /* Mask of configuration flags */
int iLeafPgno; /* Current leaf page number */
Fts5Data *pLeaf; /* Current leaf data */
Fts5Data *pNextLeaf; /* Leaf page (iLeafPgno+1) */
int iLeafOffset; /* Byte offset within current leaf */
/* Next method */
void (*xNext)(Fts5Index*, Fts5SegIter*, int*);
/* The page and offset from which the current term was read. The offset
** is the offset of the first rowid in the current doclist. */
int iTermLeafPgno;
int iTermLeafOffset;
int iPgidxOff; /* Next offset in pgidx */
int iEndofDoclist;
/* The following are only used if the FTS5_SEGITER_REVERSE flag is set. */
int iRowidOffset; /* Current entry in aRowidOffset[] */
int nRowidOffset; /* Allocated size of aRowidOffset[] array */
int *aRowidOffset; /* Array of offset to rowid fields */
Fts5DlidxIter *pDlidx; /* If there is a doclist-index */
/* Variables populated based on current entry. */
Fts5Buffer term; /* Current term */
i64 iRowid; /* Current rowid */
int nPos; /* Number of bytes in current position list */
u8 bDel; /* True if the delete flag is set */
};
/*
** Argument is a pointer to an Fts5Data structure that contains a
** leaf page.
*/
#define ASSERT_SZLEAF_OK(x) assert( \
(x)->szLeaf==(x)->nn || (x)->szLeaf==fts5GetU16(&(x)->p[2]) \
)
#define FTS5_SEGITER_ONETERM 0x01
#define FTS5_SEGITER_REVERSE 0x02
/*
** Argument is a pointer to an Fts5Data structure that contains a leaf
** page. This macro evaluates to true if the leaf contains no terms, or
** false if it contains at least one term.
*/
#define fts5LeafIsTermless(x) ((x)->szLeaf >= (x)->nn)
#define fts5LeafTermOff(x, i) (fts5GetU16(&(x)->p[(x)->szLeaf + (i)*2]))
#define fts5LeafFirstRowidOff(x) (fts5GetU16((x)->p))
/*
** Object for iterating through the merged results of one or more segments,
** visiting each term/rowid pair in the merged data.
**
** nSeg is always a power of two greater than or equal to the number of
** segments that this object is merging data from. Both the aSeg[] and
** aFirst[] arrays are sized at nSeg entries. The aSeg[] array is padded
** with zeroed objects - these are handled as if they were iterators opened
** on empty segments.
**
** The results of comparing segments aSeg[N] and aSeg[N+1], where N is an
** even number, is stored in aFirst[(nSeg+N)/2]. The "result" of the
** comparison in this context is the index of the iterator that currently
** points to the smaller term/rowid combination. Iterators at EOF are
** considered to be greater than all other iterators.
**
** aFirst[1] contains the index in aSeg[] of the iterator that points to
** the smallest key overall. aFirst[0] is unused.
**
** poslist:
** Used by sqlite3Fts5IterPoslist() when the poslist needs to be buffered.
** There is no way to tell if this is populated or not.
*/
struct Fts5Iter {
Fts5IndexIter base; /* Base class containing output vars */
Fts5Index *pIndex; /* Index that owns this iterator */
Fts5Buffer poslist; /* Buffer containing current poslist */
Fts5Colset *pColset; /* Restrict matches to these columns */
/* Invoked to set output variables. */
void (*xSetOutputs)(Fts5Iter*, Fts5SegIter*);
int nSeg; /* Size of aSeg[] array */
int bRev; /* True to iterate in reverse order */
u8 bSkipEmpty; /* True to skip deleted entries */
i64 iSwitchRowid; /* Firstest rowid of other than aFirst[1] */
Fts5CResult *aFirst; /* Current merge state (see above) */
Fts5SegIter aSeg[1]; /* Array of segment iterators */
};
/*
** An instance of the following type is used to iterate through the contents
** of a doclist-index record.
**
** pData:
** Record containing the doclist-index data.
**
** bEof:
** Set to true once iterator has reached EOF.
**
** iOff:
** Set to the current offset within record pData.
*/
struct Fts5DlidxLvl {
Fts5Data *pData; /* Data for current page of this level */
int iOff; /* Current offset into pData */
int bEof; /* At EOF already */
int iFirstOff; /* Used by reverse iterators */
/* Output variables */
int iLeafPgno; /* Page number of current leaf page */
i64 iRowid; /* First rowid on leaf iLeafPgno */
};
struct Fts5DlidxIter {
int nLvl;
int iSegid;
Fts5DlidxLvl aLvl[1];
};
static void fts5PutU16(u8 *aOut, u16 iVal){
aOut[0] = (iVal>>8);
aOut[1] = (iVal&0xFF);
}
static u16 fts5GetU16(const u8 *aIn){
return ((u16)aIn[0] << 8) + aIn[1];
}
/*
** Allocate and return a buffer at least nByte bytes in size.
**
** If an OOM error is encountered, return NULL and set the error code in
** the Fts5Index handle passed as the first argument.
*/
static void *fts5IdxMalloc(Fts5Index *p, sqlite3_int64 nByte){
return sqlite3Fts5MallocZero(&p->rc, nByte);
}
/*
** Compare the contents of the pLeft buffer with the pRight/nRight blob.
**
** Return -ve if pLeft is smaller than pRight, 0 if they are equal or
** +ve if pRight is smaller than pLeft. In other words:
**
** res = *pLeft - *pRight
*/
#ifdef SQLITE_DEBUG
static int fts5BufferCompareBlob(
Fts5Buffer *pLeft, /* Left hand side of comparison */
const u8 *pRight, int nRight /* Right hand side of comparison */
){
int nCmp = MIN(pLeft->n, nRight);
int res = memcmp(pLeft->p, pRight, nCmp);
return (res==0 ? (pLeft->n - nRight) : res);
}
#endif
/*
** Compare the contents of the two buffers using memcmp(). If one buffer
** is a prefix of the other, it is considered the lesser.
**
** Return -ve if pLeft is smaller than pRight, 0 if they are equal or
** +ve if pRight is smaller than pLeft. In other words:
**
** res = *pLeft - *pRight
*/
static int fts5BufferCompare(Fts5Buffer *pLeft, Fts5Buffer *pRight){
int nCmp = MIN(pLeft->n, pRight->n);
int res = fts5Memcmp(pLeft->p, pRight->p, nCmp);
return (res==0 ? (pLeft->n - pRight->n) : res);
}
static int fts5LeafFirstTermOff(Fts5Data *pLeaf){
int ret;
fts5GetVarint32(&pLeaf->p[pLeaf->szLeaf], ret);
return ret;
}
/*
** Close the read-only blob handle, if it is open.
*/
static void sqlite3Fts5IndexCloseReader(Fts5Index *p){
if( p->pReader ){
sqlite3_blob *pReader = p->pReader;
p->pReader = 0;
sqlite3_blob_close(pReader);
}
}
/*
** Retrieve a record from the %_data table.
**
** If an error occurs, NULL is returned and an error left in the
** Fts5Index object.
*/
static Fts5Data *fts5DataRead(Fts5Index *p, i64 iRowid){
Fts5Data *pRet = 0;
if( p->rc==SQLITE_OK ){
int rc = SQLITE_OK;
if( p->pReader ){
/* This call may return SQLITE_ABORT if there has been a savepoint
** rollback since it was last used. In this case a new blob handle
** is required. */
sqlite3_blob *pBlob = p->pReader;
p->pReader = 0;
rc = sqlite3_blob_reopen(pBlob, iRowid);
assert( p->pReader==0 );
p->pReader = pBlob;
if( rc!=SQLITE_OK ){
sqlite3Fts5IndexCloseReader(p);
}
if( rc==SQLITE_ABORT ) rc = SQLITE_OK;
}
/* If the blob handle is not open at this point, open it and seek
** to the requested entry. */
if( p->pReader==0 && rc==SQLITE_OK ){
Fts5Config *pConfig = p->pConfig;
rc = sqlite3_blob_open(pConfig->db,
pConfig->zDb, p->zDataTbl, "block", iRowid, 0, &p->pReader
);
}
/* If either of the sqlite3_blob_open() or sqlite3_blob_reopen() calls
** above returned SQLITE_ERROR, return SQLITE_CORRUPT_VTAB instead.
** All the reasons those functions might return SQLITE_ERROR - missing
** table, missing row, non-blob/text in block column - indicate
** backing store corruption. */
if( rc==SQLITE_ERROR ) rc = FTS5_CORRUPT;
if( rc==SQLITE_OK ){
u8 *aOut = 0; /* Read blob data into this buffer */
int nByte = sqlite3_blob_bytes(p->pReader);
sqlite3_int64 nAlloc = sizeof(Fts5Data) + nByte + FTS5_DATA_PADDING;
pRet = (Fts5Data*)sqlite3_malloc64(nAlloc);
if( pRet ){
pRet->nn = nByte;
aOut = pRet->p = (u8*)&pRet[1];
}else{
rc = SQLITE_NOMEM;
}
if( rc==SQLITE_OK ){
rc = sqlite3_blob_read(p->pReader, aOut, nByte, 0);
}
if( rc!=SQLITE_OK ){
sqlite3_free(pRet);
pRet = 0;
}else{
/* TODO1: Fix this */
pRet->p[nByte] = 0x00;
pRet->p[nByte+1] = 0x00;
pRet->szLeaf = fts5GetU16(&pRet->p[2]);
}
}
p->rc = rc;
p->nRead++;
}
assert( (pRet==0)==(p->rc!=SQLITE_OK) );
return pRet;
}
/*
** Release a reference to data record returned by an earlier call to
** fts5DataRead().
*/
static void fts5DataRelease(Fts5Data *pData){
sqlite3_free(pData);
}
static Fts5Data *fts5LeafRead(Fts5Index *p, i64 iRowid){
Fts5Data *pRet = fts5DataRead(p, iRowid);
if( pRet ){
if( pRet->nn<4 || pRet->szLeaf>pRet->nn ){
p->rc = FTS5_CORRUPT;
fts5DataRelease(pRet);
pRet = 0;
}
}
return pRet;
}
static int fts5IndexPrepareStmt(
Fts5Index *p,
sqlite3_stmt **ppStmt,
char *zSql
){
if( p->rc==SQLITE_OK ){
if( zSql ){
p->rc = sqlite3_prepare_v3(p->pConfig->db, zSql, -1,
SQLITE_PREPARE_PERSISTENT|SQLITE_PREPARE_NO_VTAB,
ppStmt, 0);
}else{
p->rc = SQLITE_NOMEM;
}
}
sqlite3_free(zSql);
return p->rc;
}
/*
** INSERT OR REPLACE a record into the %_data table.
*/
static void fts5DataWrite(Fts5Index *p, i64 iRowid, const u8 *pData, int nData){
if( p->rc!=SQLITE_OK ) return;
if( p->pWriter==0 ){
Fts5Config *pConfig = p->pConfig;
fts5IndexPrepareStmt(p, &p->pWriter, sqlite3_mprintf(
"REPLACE INTO '%q'.'%q_data'(id, block) VALUES(?,?)",
pConfig->zDb, pConfig->zName
));
if( p->rc ) return;
}
sqlite3_bind_int64(p->pWriter, 1, iRowid);
sqlite3_bind_blob(p->pWriter, 2, pData, nData, SQLITE_STATIC);
sqlite3_step(p->pWriter);
p->rc = sqlite3_reset(p->pWriter);
sqlite3_bind_null(p->pWriter, 2);
}
/*
** Execute the following SQL:
**
** DELETE FROM %_data WHERE id BETWEEN $iFirst AND $iLast
*/
static void fts5DataDelete(Fts5Index *p, i64 iFirst, i64 iLast){
if( p->rc!=SQLITE_OK ) return;
if( p->pDeleter==0 ){
Fts5Config *pConfig = p->pConfig;
char *zSql = sqlite3_mprintf(
"DELETE FROM '%q'.'%q_data' WHERE id>=? AND id<=?",
pConfig->zDb, pConfig->zName
);
if( fts5IndexPrepareStmt(p, &p->pDeleter, zSql) ) return;
}
sqlite3_bind_int64(p->pDeleter, 1, iFirst);
sqlite3_bind_int64(p->pDeleter, 2, iLast);
sqlite3_step(p->pDeleter);
p->rc = sqlite3_reset(p->pDeleter);
}
/*
** Remove all records associated with segment iSegid.
*/
static void fts5DataRemoveSegment(Fts5Index *p, int iSegid){
i64 iFirst = FTS5_SEGMENT_ROWID(iSegid, 0);
i64 iLast = FTS5_SEGMENT_ROWID(iSegid+1, 0)-1;
fts5DataDelete(p, iFirst, iLast);
if( p->pIdxDeleter==0 ){
Fts5Config *pConfig = p->pConfig;
fts5IndexPrepareStmt(p, &p->pIdxDeleter, sqlite3_mprintf(
"DELETE FROM '%q'.'%q_idx' WHERE segid=?",
pConfig->zDb, pConfig->zName
));
}
if( p->rc==SQLITE_OK ){
sqlite3_bind_int(p->pIdxDeleter, 1, iSegid);
sqlite3_step(p->pIdxDeleter);
p->rc = sqlite3_reset(p->pIdxDeleter);
}
}
/*
** Release a reference to an Fts5Structure object returned by an earlier
** call to fts5StructureRead() or fts5StructureDecode().
*/
static void fts5StructureRelease(Fts5Structure *pStruct){
if( pStruct && 0>=(--pStruct->nRef) ){
int i;
assert( pStruct->nRef==0 );
for(i=0; i<pStruct->nLevel; i++){
sqlite3_free(pStruct->aLevel[i].aSeg);
}
sqlite3_free(pStruct);
}
}
static void fts5StructureRef(Fts5Structure *pStruct){
pStruct->nRef++;
}
/*
** Deserialize and return the structure record currently stored in serialized
** form within buffer pData/nData.
**
** The Fts5Structure.aLevel[] and each Fts5StructureLevel.aSeg[] array
** are over-allocated by one slot. This allows the structure contents
** to be more easily edited.
**
** If an error occurs, *ppOut is set to NULL and an SQLite error code
** returned. Otherwise, *ppOut is set to point to the new object and
** SQLITE_OK returned.
*/
static int fts5StructureDecode(
const u8 *pData, /* Buffer containing serialized structure */
int nData, /* Size of buffer pData in bytes */
int *piCookie, /* Configuration cookie value */
Fts5Structure **ppOut /* OUT: Deserialized object */
){
int rc = SQLITE_OK;
int i = 0;
int iLvl;
int nLevel = 0;
int nSegment = 0;
sqlite3_int64 nByte; /* Bytes of space to allocate at pRet */
Fts5Structure *pRet = 0; /* Structure object to return */
/* Grab the cookie value */
if( piCookie ) *piCookie = sqlite3Fts5Get32(pData);
i = 4;
/* Read the total number of levels and segments from the start of the
** structure record. */
i += fts5GetVarint32(&pData[i], nLevel);
i += fts5GetVarint32(&pData[i], nSegment);
if( nLevel>FTS5_MAX_SEGMENT || nLevel<0
|| nSegment>FTS5_MAX_SEGMENT || nSegment<0
){
return FTS5_CORRUPT;
}
nByte = (
sizeof(Fts5Structure) + /* Main structure */
sizeof(Fts5StructureLevel) * (nLevel-1) /* aLevel[] array */
);
pRet = (Fts5Structure*)sqlite3Fts5MallocZero(&rc, nByte);
if( pRet ){
pRet->nRef = 1;
pRet->nLevel = nLevel;
pRet->nSegment = nSegment;
i += sqlite3Fts5GetVarint(&pData[i], &pRet->nWriteCounter);
for(iLvl=0; rc==SQLITE_OK && iLvl<nLevel; iLvl++){
Fts5StructureLevel *pLvl = &pRet->aLevel[iLvl];
int nTotal = 0;
int iSeg;
if( i>=nData ){
rc = FTS5_CORRUPT;
}else{
i += fts5GetVarint32(&pData[i], pLvl->nMerge);
i += fts5GetVarint32(&pData[i], nTotal);
if( nTotal<pLvl->nMerge ) rc = FTS5_CORRUPT;
pLvl->aSeg = (Fts5StructureSegment*)sqlite3Fts5MallocZero(&rc,
nTotal * sizeof(Fts5StructureSegment)
);
nSegment -= nTotal;
}
if( rc==SQLITE_OK ){
pLvl->nSeg = nTotal;
for(iSeg=0; iSeg<nTotal; iSeg++){
Fts5StructureSegment *pSeg = &pLvl->aSeg[iSeg];
if( i>=nData ){
rc = FTS5_CORRUPT;
break;
}
i += fts5GetVarint32(&pData[i], pSeg->iSegid);
i += fts5GetVarint32(&pData[i], pSeg->pgnoFirst);
i += fts5GetVarint32(&pData[i], pSeg->pgnoLast);
if( pSeg->pgnoLast<pSeg->pgnoFirst ){
rc = FTS5_CORRUPT;
break;
}
}
if( iLvl>0 && pLvl[-1].nMerge && nTotal==0 ) rc = FTS5_CORRUPT;
if( iLvl==nLevel-1 && pLvl->nMerge ) rc = FTS5_CORRUPT;
}
}
if( nSegment!=0 && rc==SQLITE_OK ) rc = FTS5_CORRUPT;
if( rc!=SQLITE_OK ){
fts5StructureRelease(pRet);
pRet = 0;
}
}
*ppOut = pRet;
return rc;
}
/*
**
*/
static void fts5StructureAddLevel(int *pRc, Fts5Structure **ppStruct){
if( *pRc==SQLITE_OK ){
Fts5Structure *pStruct = *ppStruct;
int nLevel = pStruct->nLevel;
sqlite3_int64 nByte = (
sizeof(Fts5Structure) + /* Main structure */
sizeof(Fts5StructureLevel) * (nLevel+1) /* aLevel[] array */
);
pStruct = sqlite3_realloc64(pStruct, nByte);
if( pStruct ){
memset(&pStruct->aLevel[nLevel], 0, sizeof(Fts5StructureLevel));
pStruct->nLevel++;
*ppStruct = pStruct;
}else{
*pRc = SQLITE_NOMEM;
}
}
}
/*
** Extend level iLvl so that there is room for at least nExtra more
** segments.
*/
static void fts5StructureExtendLevel(
int *pRc,
Fts5Structure *pStruct,
int iLvl,
int nExtra,
int bInsert
){
if( *pRc==SQLITE_OK ){
Fts5StructureLevel *pLvl = &pStruct->aLevel[iLvl];
Fts5StructureSegment *aNew;
sqlite3_int64 nByte;
nByte = (pLvl->nSeg + nExtra) * sizeof(Fts5StructureSegment);
aNew = sqlite3_realloc64(pLvl->aSeg, nByte);
if( aNew ){
if( bInsert==0 ){
memset(&aNew[pLvl->nSeg], 0, sizeof(Fts5StructureSegment) * nExtra);
}else{
int nMove = pLvl->nSeg * sizeof(Fts5StructureSegment);
memmove(&aNew[nExtra], aNew, nMove);
memset(aNew, 0, sizeof(Fts5StructureSegment) * nExtra);
}
pLvl->aSeg = aNew;
}else{
*pRc = SQLITE_NOMEM;
}
}
}
static Fts5Structure *fts5StructureReadUncached(Fts5Index *p){
Fts5Structure *pRet = 0;
Fts5Config *pConfig = p->pConfig;
int iCookie; /* Configuration cookie */
Fts5Data *pData;
pData = fts5DataRead(p, FTS5_STRUCTURE_ROWID);
if( p->rc==SQLITE_OK ){
/* TODO: Do we need this if the leaf-index is appended? Probably... */
memset(&pData->p[pData->nn], 0, FTS5_DATA_PADDING);
p->rc = fts5StructureDecode(pData->p, pData->nn, &iCookie, &pRet);
if( p->rc==SQLITE_OK && (pConfig->pgsz==0 || pConfig->iCookie!=iCookie) ){
p->rc = sqlite3Fts5ConfigLoad(pConfig, iCookie);
}
fts5DataRelease(pData);
if( p->rc!=SQLITE_OK ){
fts5StructureRelease(pRet);
pRet = 0;
}
}
return pRet;
}
static i64 fts5IndexDataVersion(Fts5Index *p){
i64 iVersion = 0;
if( p->rc==SQLITE_OK ){
if( p->pDataVersion==0 ){
p->rc = fts5IndexPrepareStmt(p, &p->pDataVersion,
sqlite3_mprintf("PRAGMA %Q.data_version", p->pConfig->zDb)
);
if( p->rc ) return 0;
}
if( SQLITE_ROW==sqlite3_step(p->pDataVersion) ){
iVersion = sqlite3_column_int64(p->pDataVersion, 0);
}
p->rc = sqlite3_reset(p->pDataVersion);
}
return iVersion;
}
/*
** Read, deserialize and return the structure record.
**
** The Fts5Structure.aLevel[] and each Fts5StructureLevel.aSeg[] array
** are over-allocated as described for function fts5StructureDecode()
** above.
**
** If an error occurs, NULL is returned and an error code left in the
** Fts5Index handle. If an error has already occurred when this function
** is called, it is a no-op.
*/
static Fts5Structure *fts5StructureRead(Fts5Index *p){
if( p->pStruct==0 ){
p->iStructVersion = fts5IndexDataVersion(p);
if( p->rc==SQLITE_OK ){
p->pStruct = fts5StructureReadUncached(p);
}
}
#if 0
else{
Fts5Structure *pTest = fts5StructureReadUncached(p);
if( pTest ){
int i, j;
assert_nc( p->pStruct->nSegment==pTest->nSegment );
assert_nc( p->pStruct->nLevel==pTest->nLevel );
for(i=0; i<pTest->nLevel; i++){
assert_nc( p->pStruct->aLevel[i].nMerge==pTest->aLevel[i].nMerge );
assert_nc( p->pStruct->aLevel[i].nSeg==pTest->aLevel[i].nSeg );
for(j=0; j<pTest->aLevel[i].nSeg; j++){
Fts5StructureSegment *p1 = &pTest->aLevel[i].aSeg[j];
Fts5StructureSegment *p2 = &p->pStruct->aLevel[i].aSeg[j];
assert_nc( p1->iSegid==p2->iSegid );
assert_nc( p1->pgnoFirst==p2->pgnoFirst );
assert_nc( p1->pgnoLast==p2->pgnoLast );
}
}
fts5StructureRelease(pTest);
}
}
#endif
if( p->rc!=SQLITE_OK ) return 0;
assert( p->iStructVersion!=0 );
assert( p->pStruct!=0 );
fts5StructureRef(p->pStruct);
return p->pStruct;
}
static void fts5StructureInvalidate(Fts5Index *p){
if( p->pStruct ){
fts5StructureRelease(p->pStruct);
p->pStruct = 0;
}
}
/*
** Return the total number of segments in index structure pStruct. This
** function is only ever used as part of assert() conditions.
*/
#ifdef SQLITE_DEBUG
static int fts5StructureCountSegments(Fts5Structure *pStruct){
int nSegment = 0; /* Total number of segments */
if( pStruct ){
int iLvl; /* Used to iterate through levels */
for(iLvl=0; iLvl<pStruct->nLevel; iLvl++){
nSegment += pStruct->aLevel[iLvl].nSeg;
}
}
return nSegment;
}
#endif
#define fts5BufferSafeAppendBlob(pBuf, pBlob, nBlob) { \
assert( (pBuf)->nSpace>=((pBuf)->n+nBlob) ); \
memcpy(&(pBuf)->p[(pBuf)->n], pBlob, nBlob); \
(pBuf)->n += nBlob; \
}
#define fts5BufferSafeAppendVarint(pBuf, iVal) { \
(pBuf)->n += sqlite3Fts5PutVarint(&(pBuf)->p[(pBuf)->n], (iVal)); \
assert( (pBuf)->nSpace>=(pBuf)->n ); \
}
/*
** Serialize and store the "structure" record.
**
** If an error occurs, leave an error code in the Fts5Index object. If an
** error has already occurred, this function is a no-op.
*/
static void fts5StructureWrite(Fts5Index *p, Fts5Structure *pStruct){
if( p->rc==SQLITE_OK ){
Fts5Buffer buf; /* Buffer to serialize record into */
int iLvl; /* Used to iterate through levels */
int iCookie; /* Cookie value to store */
assert( pStruct->nSegment==fts5StructureCountSegments(pStruct) );
memset(&buf, 0, sizeof(Fts5Buffer));
/* Append the current configuration cookie */
iCookie = p->pConfig->iCookie;
if( iCookie<0 ) iCookie = 0;
if( 0==sqlite3Fts5BufferSize(&p->rc, &buf, 4+9+9+9) ){
sqlite3Fts5Put32(buf.p, iCookie);
buf.n = 4;
fts5BufferSafeAppendVarint(&buf, pStruct->nLevel);
fts5BufferSafeAppendVarint(&buf, pStruct->nSegment);
fts5BufferSafeAppendVarint(&buf, (i64)pStruct->nWriteCounter);
}
for(iLvl=0; iLvl<pStruct->nLevel; iLvl++){
int iSeg; /* Used to iterate through segments */
Fts5StructureLevel *pLvl = &pStruct->aLevel[iLvl];
fts5BufferAppendVarint(&p->rc, &buf, pLvl->nMerge);
fts5BufferAppendVarint(&p->rc, &buf, pLvl->nSeg);
assert( pLvl->nMerge<=pLvl->nSeg );
for(iSeg=0; iSeg<pLvl->nSeg; iSeg++){
fts5BufferAppendVarint(&p->rc, &buf, pLvl->aSeg[iSeg].iSegid);
fts5BufferAppendVarint(&p->rc, &buf, pLvl->aSeg[iSeg].pgnoFirst);
fts5BufferAppendVarint(&p->rc, &buf, pLvl->aSeg[iSeg].pgnoLast);
}
}
fts5DataWrite(p, FTS5_STRUCTURE_ROWID, buf.p, buf.n);
fts5BufferFree(&buf);
}
}
#if 0
static void fts5DebugStructure(int*,Fts5Buffer*,Fts5Structure*);
static void fts5PrintStructure(const char *zCaption, Fts5Structure *pStruct){
int rc = SQLITE_OK;
Fts5Buffer buf;
memset(&buf, 0, sizeof(buf));
fts5DebugStructure(&rc, &buf, pStruct);
fprintf(stdout, "%s: %s\n", zCaption, buf.p);
fflush(stdout);
fts5BufferFree(&buf);
}
#else
# define fts5PrintStructure(x,y)
#endif
static int fts5SegmentSize(Fts5StructureSegment *pSeg){
return 1 + pSeg->pgnoLast - pSeg->pgnoFirst;
}
/*
** Return a copy of index structure pStruct. Except, promote as many
** segments as possible to level iPromote. If an OOM occurs, NULL is
** returned.
*/
static void fts5StructurePromoteTo(
Fts5Index *p,
int iPromote,
int szPromote,
Fts5Structure *pStruct
){
int il, is;
Fts5StructureLevel *pOut = &pStruct->aLevel[iPromote];
if( pOut->nMerge==0 ){
for(il=iPromote+1; il<pStruct->nLevel; il++){
Fts5StructureLevel *pLvl = &pStruct->aLevel[il];
if( pLvl->nMerge ) return;
for(is=pLvl->nSeg-1; is>=0; is--){
int sz = fts5SegmentSize(&pLvl->aSeg[is]);
if( sz>szPromote ) return;
fts5StructureExtendLevel(&p->rc, pStruct, iPromote, 1, 1);
if( p->rc ) return;
memcpy(pOut->aSeg, &pLvl->aSeg[is], sizeof(Fts5StructureSegment));
pOut->nSeg++;
pLvl->nSeg--;
}
}
}
}
/*
** A new segment has just been written to level iLvl of index structure
** pStruct. This function determines if any segments should be promoted
** as a result. Segments are promoted in two scenarios:
**
** a) If the segment just written is smaller than one or more segments
** within the previous populated level, it is promoted to the previous
** populated level.
**
** b) If the segment just written is larger than the newest segment on
** the next populated level, then that segment, and any other adjacent
** segments that are also smaller than the one just written, are
** promoted.
**
** If one or more segments are promoted, the structure object is updated
** to reflect this.
*/
static void fts5StructurePromote(
Fts5Index *p, /* FTS5 backend object */
int iLvl, /* Index level just updated */
Fts5Structure *pStruct /* Index structure */
){
if( p->rc==SQLITE_OK ){
int iTst;
int iPromote = -1;
int szPromote = 0; /* Promote anything this size or smaller */
Fts5StructureSegment *pSeg; /* Segment just written */
int szSeg; /* Size of segment just written */
int nSeg = pStruct->aLevel[iLvl].nSeg;
if( nSeg==0 ) return;
pSeg = &pStruct->aLevel[iLvl].aSeg[pStruct->aLevel[iLvl].nSeg-1];
szSeg = (1 + pSeg->pgnoLast - pSeg->pgnoFirst);
/* Check for condition (a) */
for(iTst=iLvl-1; iTst>=0 && pStruct->aLevel[iTst].nSeg==0; iTst--);
if( iTst>=0 ){
int i;
int szMax = 0;
Fts5StructureLevel *pTst = &pStruct->aLevel[iTst];
assert( pTst->nMerge==0 );
for(i=0; i<pTst->nSeg; i++){
int sz = pTst->aSeg[i].pgnoLast - pTst->aSeg[i].pgnoFirst + 1;
if( sz>szMax ) szMax = sz;
}
if( szMax>=szSeg ){
/* Condition (a) is true. Promote the newest segment on level
** iLvl to level iTst. */
iPromote = iTst;
szPromote = szMax;
}
}
/* If condition (a) is not met, assume (b) is true. StructurePromoteTo()
** is a no-op if it is not. */
if( iPromote<0 ){
iPromote = iLvl;
szPromote = szSeg;
}
fts5StructurePromoteTo(p, iPromote, szPromote, pStruct);
}
}
/*
** Advance the iterator passed as the only argument. If the end of the
** doclist-index page is reached, return non-zero.
*/
static int fts5DlidxLvlNext(Fts5DlidxLvl *pLvl){
Fts5Data *pData = pLvl->pData;
if( pLvl->iOff==0 ){
assert( pLvl->bEof==0 );
pLvl->iOff = 1;
pLvl->iOff += fts5GetVarint32(&pData->p[1], pLvl->iLeafPgno);
pLvl->iOff += fts5GetVarint(&pData->p[pLvl->iOff], (u64*)&pLvl->iRowid);
pLvl->iFirstOff = pLvl->iOff;
}else{
int iOff;
for(iOff=pLvl->iOff; iOff<pData->nn; iOff++){
if( pData->p[iOff] ) break;
}
if( iOff<pData->nn ){
i64 iVal;
pLvl->iLeafPgno += (iOff - pLvl->iOff) + 1;
iOff += fts5GetVarint(&pData->p[iOff], (u64*)&iVal);
pLvl->iRowid += iVal;
pLvl->iOff = iOff;
}else{
pLvl->bEof = 1;
}
}
return pLvl->bEof;
}
/*
** Advance the iterator passed as the only argument.
*/
static int fts5DlidxIterNextR(Fts5Index *p, Fts5DlidxIter *pIter, int iLvl){
Fts5DlidxLvl *pLvl = &pIter->aLvl[iLvl];
assert( iLvl<pIter->nLvl );
if( fts5DlidxLvlNext(pLvl) ){
if( (iLvl+1) < pIter->nLvl ){
fts5DlidxIterNextR(p, pIter, iLvl+1);
if( pLvl[1].bEof==0 ){
fts5DataRelease(pLvl->pData);
memset(pLvl, 0, sizeof(Fts5DlidxLvl));
pLvl->pData = fts5DataRead(p,
FTS5_DLIDX_ROWID(pIter->iSegid, iLvl, pLvl[1].iLeafPgno)
);
if( pLvl->pData ) fts5DlidxLvlNext(pLvl);
}
}
}
return pIter->aLvl[0].bEof;
}
static int fts5DlidxIterNext(Fts5Index *p, Fts5DlidxIter *pIter){
return fts5DlidxIterNextR(p, pIter, 0);
}
/*
** The iterator passed as the first argument has the following fields set
** as follows. This function sets up the rest of the iterator so that it
** points to the first rowid in the doclist-index.
**
** pData:
** pointer to doclist-index record,
**
** When this function is called pIter->iLeafPgno is the page number the
** doclist is associated with (the one featuring the term).
*/
static int fts5DlidxIterFirst(Fts5DlidxIter *pIter){
int i;
for(i=0; i<pIter->nLvl; i++){
fts5DlidxLvlNext(&pIter->aLvl[i]);
}
return pIter->aLvl[0].bEof;
}
static int fts5DlidxIterEof(Fts5Index *p, Fts5DlidxIter *pIter){
return p->rc!=SQLITE_OK || pIter->aLvl[0].bEof;
}
static void fts5DlidxIterLast(Fts5Index *p, Fts5DlidxIter *pIter){
int i;
/* Advance each level to the last entry on the last page */
for(i=pIter->nLvl-1; p->rc==SQLITE_OK && i>=0; i--){
Fts5DlidxLvl *pLvl = &pIter->aLvl[i];
while( fts5DlidxLvlNext(pLvl)==0 );
pLvl->bEof = 0;
if( i>0 ){
Fts5DlidxLvl *pChild = &pLvl[-1];
fts5DataRelease(pChild->pData);
memset(pChild, 0, sizeof(Fts5DlidxLvl));
pChild->pData = fts5DataRead(p,
FTS5_DLIDX_ROWID(pIter->iSegid, i-1, pLvl->iLeafPgno)
);
}
}
}
/*
** Move the iterator passed as the only argument to the previous entry.
*/
static int fts5DlidxLvlPrev(Fts5DlidxLvl *pLvl){
int iOff = pLvl->iOff;
assert( pLvl->bEof==0 );
if( iOff<=pLvl->iFirstOff ){
pLvl->bEof = 1;
}else{
u8 *a = pLvl->pData->p;
i64 iVal;
int iLimit;
int ii;
int nZero = 0;
/* Currently iOff points to the first byte of a varint. This block
** decrements iOff until it points to the first byte of the previous
** varint. Taking care not to read any memory locations that occur
** before the buffer in memory. */
iLimit = (iOff>9 ? iOff-9 : 0);
for(iOff--; iOff>iLimit; iOff--){
if( (a[iOff-1] & 0x80)==0 ) break;
}
fts5GetVarint(&a[iOff], (u64*)&iVal);
pLvl->iRowid -= iVal;
pLvl->iLeafPgno--;
/* Skip backwards past any 0x00 varints. */
for(ii=iOff-1; ii>=pLvl->iFirstOff && a[ii]==0x00; ii--){
nZero++;
}
if( ii>=pLvl->iFirstOff && (a[ii] & 0x80) ){
/* The byte immediately before the last 0x00 byte has the 0x80 bit
** set. So the last 0x00 is only a varint 0 if there are 8 more 0x80
** bytes before a[ii]. */
int bZero = 0; /* True if last 0x00 counts */
if( (ii-8)>=pLvl->iFirstOff ){
int j;
for(j=1; j<=8 && (a[ii-j] & 0x80); j++);
bZero = (j>8);
}
if( bZero==0 ) nZero--;
}
pLvl->iLeafPgno -= nZero;
pLvl->iOff = iOff - nZero;
}
return pLvl->bEof;
}
static int fts5DlidxIterPrevR(Fts5Index *p, Fts5DlidxIter *pIter, int iLvl){
Fts5DlidxLvl *pLvl = &pIter->aLvl[iLvl];
assert( iLvl<pIter->nLvl );
if( fts5DlidxLvlPrev(pLvl) ){
if( (iLvl+1) < pIter->nLvl ){
fts5DlidxIterPrevR(p, pIter, iLvl+1);
if( pLvl[1].bEof==0 ){
fts5DataRelease(pLvl->pData);
memset(pLvl, 0, sizeof(Fts5DlidxLvl));
pLvl->pData = fts5DataRead(p,
FTS5_DLIDX_ROWID(pIter->iSegid, iLvl, pLvl[1].iLeafPgno)
);
if( pLvl->pData ){
while( fts5DlidxLvlNext(pLvl)==0 );
pLvl->bEof = 0;
}
}
}
}
return pIter->aLvl[0].bEof;
}
static int fts5DlidxIterPrev(Fts5Index *p, Fts5DlidxIter *pIter){
return fts5DlidxIterPrevR(p, pIter, 0);
}
/*
** Free a doclist-index iterator object allocated by fts5DlidxIterInit().
*/
static void fts5DlidxIterFree(Fts5DlidxIter *pIter){
if( pIter ){
int i;
for(i=0; i<pIter->nLvl; i++){
fts5DataRelease(pIter->aLvl[i].pData);
}
sqlite3_free(pIter);
}
}
static Fts5DlidxIter *fts5DlidxIterInit(
Fts5Index *p, /* Fts5 Backend to iterate within */
int bRev, /* True for ORDER BY ASC */
int iSegid, /* Segment id */
int iLeafPg /* Leaf page number to load dlidx for */
){
Fts5DlidxIter *pIter = 0;
int i;
int bDone = 0;
for(i=0; p->rc==SQLITE_OK && bDone==0; i++){
sqlite3_int64 nByte = sizeof(Fts5DlidxIter) + i * sizeof(Fts5DlidxLvl);
Fts5DlidxIter *pNew;
pNew = (Fts5DlidxIter*)sqlite3_realloc64(pIter, nByte);
if( pNew==0 ){
p->rc = SQLITE_NOMEM;
}else{
i64 iRowid = FTS5_DLIDX_ROWID(iSegid, i, iLeafPg);
Fts5DlidxLvl *pLvl = &pNew->aLvl[i];
pIter = pNew;
memset(pLvl, 0, sizeof(Fts5DlidxLvl));
pLvl->pData = fts5DataRead(p, iRowid);
if( pLvl->pData && (pLvl->pData->p[0] & 0x0001)==0 ){
bDone = 1;
}
pIter->nLvl = i+1;
}
}
if( p->rc==SQLITE_OK ){
pIter->iSegid = iSegid;
if( bRev==0 ){
fts5DlidxIterFirst(pIter);
}else{
fts5DlidxIterLast(p, pIter);
}
}
if( p->rc!=SQLITE_OK ){
fts5DlidxIterFree(pIter);
pIter = 0;
}
return pIter;
}
static i64 fts5DlidxIterRowid(Fts5DlidxIter *pIter){
return pIter->aLvl[0].iRowid;
}
static int fts5DlidxIterPgno(Fts5DlidxIter *pIter){
return pIter->aLvl[0].iLeafPgno;
}
/*
** Load the next leaf page into the segment iterator.
*/
static void fts5SegIterNextPage(
Fts5Index *p, /* FTS5 backend object */
Fts5SegIter *pIter /* Iterator to advance to next page */
){
Fts5Data *pLeaf;
Fts5StructureSegment *pSeg = pIter->pSeg;
fts5DataRelease(pIter->pLeaf);
pIter->iLeafPgno++;
if( pIter->pNextLeaf ){
pIter->pLeaf = pIter->pNextLeaf;
pIter->pNextLeaf = 0;
}else if( pIter->iLeafPgno<=pSeg->pgnoLast ){
pIter->pLeaf = fts5LeafRead(p,
FTS5_SEGMENT_ROWID(pSeg->iSegid, pIter->iLeafPgno)
);
}else{
pIter->pLeaf = 0;
}
pLeaf = pIter->pLeaf;
if( pLeaf ){
pIter->iPgidxOff = pLeaf->szLeaf;
if( fts5LeafIsTermless(pLeaf) ){
pIter->iEndofDoclist = pLeaf->nn+1;
}else{
pIter->iPgidxOff += fts5GetVarint32(&pLeaf->p[pIter->iPgidxOff],
pIter->iEndofDoclist
);
}
}
}
/*
** Argument p points to a buffer containing a varint to be interpreted as a
** position list size field. Read the varint and return the number of bytes
** read. Before returning, set *pnSz to the number of bytes in the position
** list, and *pbDel to true if the delete flag is set, or false otherwise.
*/
static int fts5GetPoslistSize(const u8 *p, int *pnSz, int *pbDel){
int nSz;
int n = 0;
fts5FastGetVarint32(p, n, nSz);
assert_nc( nSz>=0 );
*pnSz = nSz/2;
*pbDel = nSz & 0x0001;
return n;
}
/*
** Fts5SegIter.iLeafOffset currently points to the first byte of a
** position-list size field. Read the value of the field and store it
** in the following variables:
**
** Fts5SegIter.nPos
** Fts5SegIter.bDel
**
** Leave Fts5SegIter.iLeafOffset pointing to the first byte of the
** position list content (if any).
*/
static void fts5SegIterLoadNPos(Fts5Index *p, Fts5SegIter *pIter){
if( p->rc==SQLITE_OK ){
int iOff = pIter->iLeafOffset; /* Offset to read at */
ASSERT_SZLEAF_OK(pIter->pLeaf);
if( p->pConfig->eDetail==FTS5_DETAIL_NONE ){
int iEod = MIN(pIter->iEndofDoclist, pIter->pLeaf->szLeaf);
pIter->bDel = 0;
pIter->nPos = 1;
if( iOff<iEod && pIter->pLeaf->p[iOff]==0 ){
pIter->bDel = 1;
iOff++;
if( iOff<iEod && pIter->pLeaf->p[iOff]==0 ){
pIter->nPos = 1;
iOff++;
}else{
pIter->nPos = 0;
}
}
}else{
int nSz;
fts5FastGetVarint32(pIter->pLeaf->p, iOff, nSz);
pIter->bDel = (nSz & 0x0001);
pIter->nPos = nSz>>1;
assert_nc( pIter->nPos>=0 );
}
pIter->iLeafOffset = iOff;
}
}
static void fts5SegIterLoadRowid(Fts5Index *p, Fts5SegIter *pIter){
u8 *a = pIter->pLeaf->p; /* Buffer to read data from */
int iOff = pIter->iLeafOffset;
ASSERT_SZLEAF_OK(pIter->pLeaf);
if( iOff>=pIter->pLeaf->szLeaf ){
fts5SegIterNextPage(p, pIter);
if( pIter->pLeaf==0 ){
if( p->rc==SQLITE_OK ) p->rc = FTS5_CORRUPT;
return;
}
iOff = 4;
a = pIter->pLeaf->p;
}
iOff += sqlite3Fts5GetVarint(&a[iOff], (u64*)&pIter->iRowid);
pIter->iLeafOffset = iOff;
}
/*
** Fts5SegIter.iLeafOffset currently points to the first byte of the
** "nSuffix" field of a term. Function parameter nKeep contains the value
** of the "nPrefix" field (if there was one - it is passed 0 if this is
** the first term in the segment).
**
** This function populates:
**
** Fts5SegIter.term
** Fts5SegIter.rowid
**
** accordingly and leaves (Fts5SegIter.iLeafOffset) set to the content of
** the first position list. The position list belonging to document
** (Fts5SegIter.iRowid).
*/
static void fts5SegIterLoadTerm(Fts5Index *p, Fts5SegIter *pIter, int nKeep){
u8 *a = pIter->pLeaf->p; /* Buffer to read data from */
int iOff = pIter->iLeafOffset; /* Offset to read at */
int nNew; /* Bytes of new data */
iOff += fts5GetVarint32(&a[iOff], nNew);
if( iOff+nNew>pIter->pLeaf->szLeaf || nKeep>pIter->term.n || nNew==0 ){
p->rc = FTS5_CORRUPT;
return;
}
pIter->term.n = nKeep;
fts5BufferAppendBlob(&p->rc, &pIter->term, nNew, &a[iOff]);
assert( pIter->term.n<=pIter->term.nSpace );
iOff += nNew;
pIter->iTermLeafOffset = iOff;
pIter->iTermLeafPgno = pIter->iLeafPgno;
pIter->iLeafOffset = iOff;
if( pIter->iPgidxOff>=pIter->pLeaf->nn ){
pIter->iEndofDoclist = pIter->pLeaf->nn+1;
}else{
int nExtra;
pIter->iPgidxOff += fts5GetVarint32(&a[pIter->iPgidxOff], nExtra);
pIter->iEndofDoclist += nExtra;
}
fts5SegIterLoadRowid(p, pIter);
}
static void fts5SegIterNext(Fts5Index*, Fts5SegIter*, int*);
static void fts5SegIterNext_Reverse(Fts5Index*, Fts5SegIter*, int*);
static void fts5SegIterNext_None(Fts5Index*, Fts5SegIter*, int*);
static void fts5SegIterSetNext(Fts5Index *p, Fts5SegIter *pIter){
if( pIter->flags & FTS5_SEGITER_REVERSE ){
pIter->xNext = fts5SegIterNext_Reverse;
}else if( p->pConfig->eDetail==FTS5_DETAIL_NONE ){
pIter->xNext = fts5SegIterNext_None;
}else{
pIter->xNext = fts5SegIterNext;
}
}
/*
** Initialize the iterator object pIter to iterate through the entries in
** segment pSeg. The iterator is left pointing to the first entry when
** this function returns.
**
** If an error occurs, Fts5Index.rc is set to an appropriate error code. If
** an error has already occurred when this function is called, it is a no-op.
*/
static void fts5SegIterInit(
Fts5Index *p, /* FTS index object */
Fts5StructureSegment *pSeg, /* Description of segment */
Fts5SegIter *pIter /* Object to populate */
){
if( pSeg->pgnoFirst==0 ){
/* This happens if the segment is being used as an input to an incremental
** merge and all data has already been "trimmed". See function
** fts5TrimSegments() for details. In this case leave the iterator empty.
** The caller will see the (pIter->pLeaf==0) and assume the iterator is
** at EOF already. */
assert( pIter->pLeaf==0 );
return;
}
if( p->rc==SQLITE_OK ){
memset(pIter, 0, sizeof(*pIter));
fts5SegIterSetNext(p, pIter);
pIter->pSeg = pSeg;
pIter->iLeafPgno = pSeg->pgnoFirst-1;
fts5SegIterNextPage(p, pIter);
}
if( p->rc==SQLITE_OK ){
pIter->iLeafOffset = 4;
assert_nc( pIter->pLeaf->nn>4 );
assert_nc( fts5LeafFirstTermOff(pIter->pLeaf)==4 );
pIter->iPgidxOff = pIter->pLeaf->szLeaf+1;
fts5SegIterLoadTerm(p, pIter, 0);
fts5SegIterLoadNPos(p, pIter);
}
}
/*
** This function is only ever called on iterators created by calls to
** Fts5IndexQuery() with the FTS5INDEX_QUERY_DESC flag set.
**
** The iterator is in an unusual state when this function is called: the
** Fts5SegIter.iLeafOffset variable is set to the offset of the start of
** the position-list size field for the first relevant rowid on the page.
** Fts5SegIter.rowid is set, but nPos and bDel are not.
**
** This function advances the iterator so that it points to the last
** relevant rowid on the page and, if necessary, initializes the
** aRowidOffset[] and iRowidOffset variables. At this point the iterator
** is in its regular state - Fts5SegIter.iLeafOffset points to the first
** byte of the position list content associated with said rowid.
*/
static void fts5SegIterReverseInitPage(Fts5Index *p, Fts5SegIter *pIter){
int eDetail = p->pConfig->eDetail;
int n = pIter->pLeaf->szLeaf;
int i = pIter->iLeafOffset;
u8 *a = pIter->pLeaf->p;
int iRowidOffset = 0;
if( n>pIter->iEndofDoclist ){
n = pIter->iEndofDoclist;
}
ASSERT_SZLEAF_OK(pIter->pLeaf);
while( 1 ){
u64 iDelta = 0;
if( eDetail==FTS5_DETAIL_NONE ){
/* todo */
if( i<n && a[i]==0 ){
i++;
if( i<n && a[i]==0 ) i++;
}
}else{
int nPos;
int bDummy;
i += fts5GetPoslistSize(&a[i], &nPos, &bDummy);
i += nPos;
}
if( i>=n ) break;
i += fts5GetVarint(&a[i], &iDelta);
pIter->iRowid += iDelta;
/* If necessary, grow the pIter->aRowidOffset[] array. */
if( iRowidOffset>=pIter->nRowidOffset ){
int nNew = pIter->nRowidOffset + 8;
int *aNew = (int*)sqlite3_realloc64(pIter->aRowidOffset,nNew*sizeof(int));
if( aNew==0 ){
p->rc = SQLITE_NOMEM;
break;
}
pIter->aRowidOffset = aNew;
pIter->nRowidOffset = nNew;
}
pIter->aRowidOffset[iRowidOffset++] = pIter->iLeafOffset;
pIter->iLeafOffset = i;
}
pIter->iRowidOffset = iRowidOffset;
fts5SegIterLoadNPos(p, pIter);
}
/*
**
*/
static void fts5SegIterReverseNewPage(Fts5Index *p, Fts5SegIter *pIter){
assert( pIter->flags & FTS5_SEGITER_REVERSE );
assert( pIter->flags & FTS5_SEGITER_ONETERM );
fts5DataRelease(pIter->pLeaf);
pIter->pLeaf = 0;
while( p->rc==SQLITE_OK && pIter->iLeafPgno>pIter->iTermLeafPgno ){
Fts5Data *pNew;
pIter->iLeafPgno--;
pNew = fts5DataRead(p, FTS5_SEGMENT_ROWID(
pIter->pSeg->iSegid, pIter->iLeafPgno
));
if( pNew ){
/* iTermLeafOffset may be equal to szLeaf if the term is the last
** thing on the page - i.e. the first rowid is on the following page.
** In this case leave pIter->pLeaf==0, this iterator is at EOF. */
if( pIter->iLeafPgno==pIter->iTermLeafPgno ){
assert( pIter->pLeaf==0 );
if( pIter->iTermLeafOffset<pNew->szLeaf ){
pIter->pLeaf = pNew;
pIter->iLeafOffset = pIter->iTermLeafOffset;
}
}else{
int iRowidOff;
iRowidOff = fts5LeafFirstRowidOff(pNew);
if( iRowidOff ){
pIter->pLeaf = pNew;
pIter->iLeafOffset = iRowidOff;
}
}
if( pIter->pLeaf ){
u8 *a = &pIter->pLeaf->p[pIter->iLeafOffset];
pIter->iLeafOffset += fts5GetVarint(a, (u64*)&pIter->iRowid);
break;
}else{
fts5DataRelease(pNew);
}
}
}
if( pIter->pLeaf ){
pIter->iEndofDoclist = pIter->pLeaf->nn+1;
fts5SegIterReverseInitPage(p, pIter);
}
}
/*
** Return true if the iterator passed as the second argument currently
** points to a delete marker. A delete marker is an entry with a 0 byte
** position-list.
*/
static int fts5MultiIterIsEmpty(Fts5Index *p, Fts5Iter *pIter){
Fts5SegIter *pSeg = &pIter->aSeg[pIter->aFirst[1].iFirst];
return (p->rc==SQLITE_OK && pSeg->pLeaf && pSeg->nPos==0);
}
/*
** Advance iterator pIter to the next entry.
**
** This version of fts5SegIterNext() is only used by reverse iterators.
*/
static void fts5SegIterNext_Reverse(
Fts5Index *p, /* FTS5 backend object */
Fts5SegIter *pIter, /* Iterator to advance */
int *pbUnused /* Unused */
){
assert( pIter->flags & FTS5_SEGITER_REVERSE );
assert( pIter->pNextLeaf==0 );
UNUSED_PARAM(pbUnused);
if( pIter->iRowidOffset>0 ){
u8 *a = pIter->pLeaf->p;
int iOff;
u64 iDelta;
pIter->iRowidOffset--;
pIter->iLeafOffset = pIter->aRowidOffset[pIter->iRowidOffset];
fts5SegIterLoadNPos(p, pIter);
iOff = pIter->iLeafOffset;
if( p->pConfig->eDetail!=FTS5_DETAIL_NONE ){
iOff += pIter->nPos;
}
fts5GetVarint(&a[iOff], &iDelta);
pIter->iRowid -= iDelta;
}else{
fts5SegIterReverseNewPage(p, pIter);
}
}
/*
** Advance iterator pIter to the next entry.
**
** This version of fts5SegIterNext() is only used if detail=none and the
** iterator is not a reverse direction iterator.
*/
static void fts5SegIterNext_None(
Fts5Index *p, /* FTS5 backend object */
Fts5SegIter *pIter, /* Iterator to advance */
int *pbNewTerm /* OUT: Set for new term */
){
int iOff;
assert( p->rc==SQLITE_OK );
assert( (pIter->flags & FTS5_SEGITER_REVERSE)==0 );
assert( p->pConfig->eDetail==FTS5_DETAIL_NONE );
ASSERT_SZLEAF_OK(pIter->pLeaf);
iOff = pIter->iLeafOffset;
/* Next entry is on the next page */
if( pIter->pSeg && iOff>=pIter->pLeaf->szLeaf ){
fts5SegIterNextPage(p, pIter);
if( p->rc || pIter->pLeaf==0 ) return;
pIter->iRowid = 0;
iOff = 4;
}
if( iOff<pIter->iEndofDoclist ){
/* Next entry is on the current page */
i64 iDelta;
iOff += sqlite3Fts5GetVarint(&pIter->pLeaf->p[iOff], (u64*)&iDelta);
pIter->iLeafOffset = iOff;
pIter->iRowid += iDelta;
}else if( (pIter->flags & FTS5_SEGITER_ONETERM)==0 ){
if( pIter->pSeg ){
int nKeep = 0;
if( iOff!=fts5LeafFirstTermOff(pIter->pLeaf) ){
iOff += fts5GetVarint32(&pIter->pLeaf->p[iOff], nKeep);
}
pIter->iLeafOffset = iOff;
fts5SegIterLoadTerm(p, pIter, nKeep);
}else{
const u8 *pList = 0;
const char *zTerm = 0;
int nList;
sqlite3Fts5HashScanNext(p->pHash);
sqlite3Fts5HashScanEntry(p->pHash, &zTerm, &pList, &nList);
if( pList==0 ) goto next_none_eof;
pIter->pLeaf->p = (u8*)pList;
pIter->pLeaf->nn = nList;
pIter->pLeaf->szLeaf = nList;
pIter->iEndofDoclist = nList;
sqlite3Fts5BufferSet(&p->rc,&pIter->term, (int)strlen(zTerm), (u8*)zTerm);
pIter->iLeafOffset = fts5GetVarint(pList, (u64*)&pIter->iRowid);
}
if( pbNewTerm ) *pbNewTerm = 1;
}else{
goto next_none_eof;
}
fts5SegIterLoadNPos(p, pIter);
return;
next_none_eof:
fts5DataRelease(pIter->pLeaf);
pIter->pLeaf = 0;
}
/*
** Advance iterator pIter to the next entry.
**
** If an error occurs, Fts5Index.rc is set to an appropriate error code. It
** is not considered an error if the iterator reaches EOF. If an error has
** already occurred when this function is called, it is a no-op.
*/
static void fts5SegIterNext(
Fts5Index *p, /* FTS5 backend object */
Fts5SegIter *pIter, /* Iterator to advance */
int *pbNewTerm /* OUT: Set for new term */
){
Fts5Data *pLeaf = pIter->pLeaf;
int iOff;
int bNewTerm = 0;
int nKeep = 0;
u8 *a;
int n;
assert( pbNewTerm==0 || *pbNewTerm==0 );
assert( p->pConfig->eDetail!=FTS5_DETAIL_NONE );
/* Search for the end of the position list within the current page. */
a = pLeaf->p;
n = pLeaf->szLeaf;
ASSERT_SZLEAF_OK(pLeaf);
iOff = pIter->iLeafOffset + pIter->nPos;
if( iOff<n ){
/* The next entry is on the current page. */
assert_nc( iOff<=pIter->iEndofDoclist );
if( iOff>=pIter->iEndofDoclist ){
bNewTerm = 1;
if( iOff!=fts5LeafFirstTermOff(pLeaf) ){
iOff += fts5GetVarint32(&a[iOff], nKeep);
}
}else{
u64 iDelta;
iOff += sqlite3Fts5GetVarint(&a[iOff], &iDelta);
pIter->iRowid += iDelta;
assert_nc( iDelta>0 );
}
pIter->iLeafOffset = iOff;
}else if( pIter->pSeg==0 ){
const u8 *pList = 0;
const char *zTerm = 0;
int nList = 0;
assert( (pIter->flags & FTS5_SEGITER_ONETERM) || pbNewTerm );
if( 0==(pIter->flags & FTS5_SEGITER_ONETERM) ){
sqlite3Fts5HashScanNext(p->pHash);
sqlite3Fts5HashScanEntry(p->pHash, &zTerm, &pList, &nList);
}
if( pList==0 ){
fts5DataRelease(pIter->pLeaf);
pIter->pLeaf = 0;
}else{
pIter->pLeaf->p = (u8*)pList;
pIter->pLeaf->nn = nList;
pIter->pLeaf->szLeaf = nList;
pIter->iEndofDoclist = nList+1;
sqlite3Fts5BufferSet(&p->rc, &pIter->term, (int)strlen(zTerm),
(u8*)zTerm);
pIter->iLeafOffset = fts5GetVarint(pList, (u64*)&pIter->iRowid);
*pbNewTerm = 1;
}
}else{
iOff = 0;
/* Next entry is not on the current page */
while( iOff==0 ){
fts5SegIterNextPage(p, pIter);
pLeaf = pIter->pLeaf;
if( pLeaf==0 ) break;
ASSERT_SZLEAF_OK(pLeaf);
if( (iOff = fts5LeafFirstRowidOff(pLeaf)) && iOff<pLeaf->szLeaf ){
iOff += sqlite3Fts5GetVarint(&pLeaf->p[iOff], (u64*)&pIter->iRowid);
pIter->iLeafOffset = iOff;
if( pLeaf->nn>pLeaf->szLeaf ){
pIter->iPgidxOff = pLeaf->szLeaf + fts5GetVarint32(
&pLeaf->p[pLeaf->szLeaf], pIter->iEndofDoclist
);
}
}
else if( pLeaf->nn>pLeaf->szLeaf ){
pIter->iPgidxOff = pLeaf->szLeaf + fts5GetVarint32(
&pLeaf->p[pLeaf->szLeaf], iOff
);
pIter->iLeafOffset = iOff;
pIter->iEndofDoclist = iOff;
bNewTerm = 1;
}
assert_nc( iOff<pLeaf->szLeaf );
if( iOff>pLeaf->szLeaf ){
p->rc = FTS5_CORRUPT;
return;
}
}
}
/* Check if the iterator is now at EOF. If so, return early. */
if( pIter->pLeaf ){
if( bNewTerm ){
if( pIter->flags & FTS5_SEGITER_ONETERM ){
fts5DataRelease(pIter->pLeaf);
pIter->pLeaf = 0;
}else{
fts5SegIterLoadTerm(p, pIter, nKeep);
fts5SegIterLoadNPos(p, pIter);
if( pbNewTerm ) *pbNewTerm = 1;
}
}else{
/* The following could be done by calling fts5SegIterLoadNPos(). But
** this block is particularly performance critical, so equivalent
** code is inlined. */
int nSz;
assert( p->rc==SQLITE_OK );
assert_nc( pIter->iLeafOffset<=pIter->pLeaf->nn );
fts5FastGetVarint32(pIter->pLeaf->p, pIter->iLeafOffset, nSz);
pIter->bDel = (nSz & 0x0001);
pIter->nPos = nSz>>1;
assert_nc( pIter->nPos>=0 );
}
}
}
#define SWAPVAL(T, a, b) { T tmp; tmp=a; a=b; b=tmp; }
#define fts5IndexSkipVarint(a, iOff) { \
int iEnd = iOff+9; \
while( (a[iOff++] & 0x80) && iOff<iEnd ); \
}
/*
** Iterator pIter currently points to the first rowid in a doclist. This
** function sets the iterator up so that iterates in reverse order through
** the doclist.
*/
static void fts5SegIterReverse(Fts5Index *p, Fts5SegIter *pIter){
Fts5DlidxIter *pDlidx = pIter->pDlidx;
Fts5Data *pLast = 0;
int pgnoLast = 0;
if( pDlidx ){
int iSegid = pIter->pSeg->iSegid;
pgnoLast = fts5DlidxIterPgno(pDlidx);
pLast = fts5DataRead(p, FTS5_SEGMENT_ROWID(iSegid, pgnoLast));
}else{
Fts5Data *pLeaf = pIter->pLeaf; /* Current leaf data */
/* Currently, Fts5SegIter.iLeafOffset points to the first byte of
** position-list content for the current rowid. Back it up so that it
** points to the start of the position-list size field. */
int iPoslist;
if( pIter->iTermLeafPgno==pIter->iLeafPgno ){
iPoslist = pIter->iTermLeafOffset;
}else{
iPoslist = 4;
}
fts5IndexSkipVarint(pLeaf->p, iPoslist);
pIter->iLeafOffset = iPoslist;
/* If this condition is true then the largest rowid for the current
** term may not be stored on the current page. So search forward to
** see where said rowid really is. */
if( pIter->iEndofDoclist>=pLeaf->szLeaf ){
int pgno;
Fts5StructureSegment *pSeg = pIter->pSeg;
/* The last rowid in the doclist may not be on the current page. Search
** forward to find the page containing the last rowid. */
for(pgno=pIter->iLeafPgno+1; !p->rc && pgno<=pSeg->pgnoLast; pgno++){
i64 iAbs = FTS5_SEGMENT_ROWID(pSeg->iSegid, pgno);
Fts5Data *pNew = fts5DataRead(p, iAbs);
if( pNew ){
int iRowid, bTermless;
iRowid = fts5LeafFirstRowidOff(pNew);
bTermless = fts5LeafIsTermless(pNew);
if( iRowid ){
SWAPVAL(Fts5Data*, pNew, pLast);
pgnoLast = pgno;
}
fts5DataRelease(pNew);
if( bTermless==0 ) break;
}
}
}
}
/* If pLast is NULL at this point, then the last rowid for this doclist
** lies on the page currently indicated by the iterator. In this case
** pIter->iLeafOffset is already set to point to the position-list size
** field associated with the first relevant rowid on the page.
**
** Or, if pLast is non-NULL, then it is the page that contains the last
** rowid. In this case configure the iterator so that it points to the
** first rowid on this page.
*/
if( pLast ){
int iOff;
fts5DataRelease(pIter->pLeaf);
pIter->pLeaf = pLast;
pIter->iLeafPgno = pgnoLast;
iOff = fts5LeafFirstRowidOff(pLast);
iOff += fts5GetVarint(&pLast->p[iOff], (u64*)&pIter->iRowid);
pIter->iLeafOffset = iOff;
if( fts5LeafIsTermless(pLast) ){
pIter->iEndofDoclist = pLast->nn+1;
}else{
pIter->iEndofDoclist = fts5LeafFirstTermOff(pLast);
}
}
fts5SegIterReverseInitPage(p, pIter);
}
/*
** Iterator pIter currently points to the first rowid of a doclist.
** There is a doclist-index associated with the final term on the current
** page. If the current term is the last term on the page, load the
** doclist-index from disk and initialize an iterator at (pIter->pDlidx).
*/
static void fts5SegIterLoadDlidx(Fts5Index *p, Fts5SegIter *pIter){
int iSeg = pIter->pSeg->iSegid;
int bRev = (pIter->flags & FTS5_SEGITER_REVERSE);
Fts5Data *pLeaf = pIter->pLeaf; /* Current leaf data */
assert( pIter->flags & FTS5_SEGITER_ONETERM );
assert( pIter->pDlidx==0 );
/* Check if the current doclist ends on this page. If it does, return
** early without loading the doclist-index (as it belongs to a different
** term. */
if( pIter->iTermLeafPgno==pIter->iLeafPgno
&& pIter->iEndofDoclist<pLeaf->szLeaf
){
return;
}
pIter->pDlidx = fts5DlidxIterInit(p, bRev, iSeg, pIter->iTermLeafPgno);
}
/*
** The iterator object passed as the second argument currently contains
** no valid values except for the Fts5SegIter.pLeaf member variable. This
** function searches the leaf page for a term matching (pTerm/nTerm).
**
** If the specified term is found on the page, then the iterator is left
** pointing to it. If argument bGe is zero and the term is not found,
** the iterator is left pointing at EOF.
**
** If bGe is non-zero and the specified term is not found, then the
** iterator is left pointing to the smallest term in the segment that
** is larger than the specified term, even if this term is not on the
** current page.
*/
static void fts5LeafSeek(
Fts5Index *p, /* Leave any error code here */
int bGe, /* True for a >= search */
Fts5SegIter *pIter, /* Iterator to seek */
const u8 *pTerm, int nTerm /* Term to search for */
){
int iOff;
const u8 *a = pIter->pLeaf->p;
int szLeaf = pIter->pLeaf->szLeaf;
int n = pIter->pLeaf->nn;
u32 nMatch = 0;
u32 nKeep = 0;
u32 nNew = 0;
u32 iTermOff;
int iPgidx; /* Current offset in pgidx */
int bEndOfPage = 0;
assert( p->rc==SQLITE_OK );
iPgidx = szLeaf;
iPgidx += fts5GetVarint32(&a[iPgidx], iTermOff);
iOff = iTermOff;
if( iOff>n ){
p->rc = FTS5_CORRUPT;
return;
}
while( 1 ){
/* Figure out how many new bytes are in this term */
fts5FastGetVarint32(a, iOff, nNew);
if( nKeep<nMatch ){
goto search_failed;
}
assert( nKeep>=nMatch );
if( nKeep==nMatch ){
u32 nCmp;
u32 i;
nCmp = (u32)MIN(nNew, nTerm-nMatch);
for(i=0; i<nCmp; i++){
if( a[iOff+i]!=pTerm[nMatch+i] ) break;
}
nMatch += i;
if( (u32)nTerm==nMatch ){
if( i==nNew ){
goto search_success;
}else{
goto search_failed;
}
}else if( i<nNew && a[iOff+i]>pTerm[nMatch] ){
goto search_failed;
}
}
if( iPgidx>=n ){
bEndOfPage = 1;
break;
}
iPgidx += fts5GetVarint32(&a[iPgidx], nKeep);
iTermOff += nKeep;
iOff = iTermOff;
if( iOff>=n ){
p->rc = FTS5_CORRUPT;
return;
}
/* Read the nKeep field of the next term. */
fts5FastGetVarint32(a, iOff, nKeep);
}
search_failed:
if( bGe==0 ){
fts5DataRelease(pIter->pLeaf);
pIter->pLeaf = 0;
return;
}else if( bEndOfPage ){
do {
fts5SegIterNextPage(p, pIter);
if( pIter->pLeaf==0 ) return;
a = pIter->pLeaf->p;
if( fts5LeafIsTermless(pIter->pLeaf)==0 ){
iPgidx = pIter->pLeaf->szLeaf;
iPgidx += fts5GetVarint32(&pIter->pLeaf->p[iPgidx], iOff);
if( iOff<4 || iOff>=pIter->pLeaf->szLeaf ){
p->rc = FTS5_CORRUPT;
return;
}else{
nKeep = 0;
iTermOff = iOff;
n = pIter->pLeaf->nn;
iOff += fts5GetVarint32(&a[iOff], nNew);
break;
}
}
}while( 1 );
}
search_success:
if( (i64)iOff+nNew>n || nNew<1 ){
p->rc = FTS5_CORRUPT;
return;
}
pIter->iLeafOffset = iOff + nNew;
pIter->iTermLeafOffset = pIter->iLeafOffset;
pIter->iTermLeafPgno = pIter->iLeafPgno;
fts5BufferSet(&p->rc, &pIter->term, nKeep, pTerm);
fts5BufferAppendBlob(&p->rc, &pIter->term, nNew, &a[iOff]);
if( iPgidx>=n ){
pIter->iEndofDoclist = pIter->pLeaf->nn+1;
}else{
int nExtra;
iPgidx += fts5GetVarint32(&a[iPgidx], nExtra);
pIter->iEndofDoclist = iTermOff + nExtra;
}
pIter->iPgidxOff = iPgidx;
fts5SegIterLoadRowid(p, pIter);
fts5SegIterLoadNPos(p, pIter);
}
static sqlite3_stmt *fts5IdxSelectStmt(Fts5Index *p){
if( p->pIdxSelect==0 ){
Fts5Config *pConfig = p->pConfig;
fts5IndexPrepareStmt(p, &p->pIdxSelect, sqlite3_mprintf(
"SELECT pgno FROM '%q'.'%q_idx' WHERE "
"segid=? AND term<=? ORDER BY term DESC LIMIT 1",
pConfig->zDb, pConfig->zName
));
}
return p->pIdxSelect;
}
/*
** Initialize the object pIter to point to term pTerm/nTerm within segment
** pSeg. If there is no such term in the index, the iterator is set to EOF.
**
** If an error occurs, Fts5Index.rc is set to an appropriate error code. If
** an error has already occurred when this function is called, it is a no-op.
*/
static void fts5SegIterSeekInit(
Fts5Index *p, /* FTS5 backend */
const u8 *pTerm, int nTerm, /* Term to seek to */
int flags, /* Mask of FTS5INDEX_XXX flags */
Fts5StructureSegment *pSeg, /* Description of segment */
Fts5SegIter *pIter /* Object to populate */
){
int iPg = 1;
int bGe = (flags & FTS5INDEX_QUERY_SCAN);
int bDlidx = 0; /* True if there is a doclist-index */
sqlite3_stmt *pIdxSelect = 0;
assert( bGe==0 || (flags & FTS5INDEX_QUERY_DESC)==0 );
assert( pTerm && nTerm );
memset(pIter, 0, sizeof(*pIter));
pIter->pSeg = pSeg;
/* This block sets stack variable iPg to the leaf page number that may
** contain term (pTerm/nTerm), if it is present in the segment. */
pIdxSelect = fts5IdxSelectStmt(p);
if( p->rc ) return;
sqlite3_bind_int(pIdxSelect, 1, pSeg->iSegid);
sqlite3_bind_blob(pIdxSelect, 2, pTerm, nTerm, SQLITE_STATIC);
if( SQLITE_ROW==sqlite3_step(pIdxSelect) ){
i64 val = sqlite3_column_int(pIdxSelect, 0);
iPg = (int)(val>>1);
bDlidx = (val & 0x0001);
}
p->rc = sqlite3_reset(pIdxSelect);
sqlite3_bind_null(pIdxSelect, 2);
if( iPg<pSeg->pgnoFirst ){
iPg = pSeg->pgnoFirst;
bDlidx = 0;
}
pIter->iLeafPgno = iPg - 1;
fts5SegIterNextPage(p, pIter);
if( pIter->pLeaf ){
fts5LeafSeek(p, bGe, pIter, pTerm, nTerm);
}
if( p->rc==SQLITE_OK && bGe==0 ){
pIter->flags |= FTS5_SEGITER_ONETERM;
if( pIter->pLeaf ){
if( flags & FTS5INDEX_QUERY_DESC ){
pIter->flags |= FTS5_SEGITER_REVERSE;
}
if( bDlidx ){
fts5SegIterLoadDlidx(p, pIter);
}
if( flags & FTS5INDEX_QUERY_DESC ){
fts5SegIterReverse(p, pIter);
}
}
}
fts5SegIterSetNext(p, pIter);
/* Either:
**
** 1) an error has occurred, or
** 2) the iterator points to EOF, or
** 3) the iterator points to an entry with term (pTerm/nTerm), or
** 4) the FTS5INDEX_QUERY_SCAN flag was set and the iterator points
** to an entry with a term greater than or equal to (pTerm/nTerm).
*/
assert_nc( p->rc!=SQLITE_OK /* 1 */
|| pIter->pLeaf==0 /* 2 */
|| fts5BufferCompareBlob(&pIter->term, pTerm, nTerm)==0 /* 3 */
|| (bGe && fts5BufferCompareBlob(&pIter->term, pTerm, nTerm)>0) /* 4 */
);
}
/*
** Initialize the object pIter to point to term pTerm/nTerm within the
** in-memory hash table. If there is no such term in the hash-table, the
** iterator is set to EOF.
**
** If an error occurs, Fts5Index.rc is set to an appropriate error code. If
** an error has already occurred when this function is called, it is a no-op.
*/
static void fts5SegIterHashInit(
Fts5Index *p, /* FTS5 backend */
const u8 *pTerm, int nTerm, /* Term to seek to */
int flags, /* Mask of FTS5INDEX_XXX flags */
Fts5SegIter *pIter /* Object to populate */
){
int nList = 0;
const u8 *z = 0;
int n = 0;
Fts5Data *pLeaf = 0;
assert( p->pHash );
assert( p->rc==SQLITE_OK );
if( pTerm==0 || (flags & FTS5INDEX_QUERY_SCAN) ){
const u8 *pList = 0;
p->rc = sqlite3Fts5HashScanInit(p->pHash, (const char*)pTerm, nTerm);
sqlite3Fts5HashScanEntry(p->pHash, (const char**)&z, &pList, &nList);
n = (z ? (int)strlen((const char*)z) : 0);
if( pList ){
pLeaf = fts5IdxMalloc(p, sizeof(Fts5Data));
if( pLeaf ){
pLeaf->p = (u8*)pList;
}
}
}else{
p->rc = sqlite3Fts5HashQuery(p->pHash, sizeof(Fts5Data),
(const char*)pTerm, nTerm, (void**)&pLeaf, &nList
);
if( pLeaf ){
pLeaf->p = (u8*)&pLeaf[1];
}
z = pTerm;
n = nTerm;
pIter->flags |= FTS5_SEGITER_ONETERM;
}
if( pLeaf ){
sqlite3Fts5BufferSet(&p->rc, &pIter->term, n, z);
pLeaf->nn = pLeaf->szLeaf = nList;
pIter->pLeaf = pLeaf;
pIter->iLeafOffset = fts5GetVarint(pLeaf->p, (u64*)&pIter->iRowid);
pIter->iEndofDoclist = pLeaf->nn;
if( flags & FTS5INDEX_QUERY_DESC ){
pIter->flags |= FTS5_SEGITER_REVERSE;
fts5SegIterReverseInitPage(p, pIter);
}else{
fts5SegIterLoadNPos(p, pIter);
}
}
fts5SegIterSetNext(p, pIter);
}
/*
** Zero the iterator passed as the only argument.
*/
static void fts5SegIterClear(Fts5SegIter *pIter){
fts5BufferFree(&pIter->term);
fts5DataRelease(pIter->pLeaf);
fts5DataRelease(pIter->pNextLeaf);
fts5DlidxIterFree(pIter->pDlidx);
sqlite3_free(pIter->aRowidOffset);
memset(pIter, 0, sizeof(Fts5SegIter));
}
#ifdef SQLITE_DEBUG
/*
** This function is used as part of the big assert() procedure implemented by
** fts5AssertMultiIterSetup(). It ensures that the result currently stored
** in *pRes is the correct result of comparing the current positions of the
** two iterators.
*/
static void fts5AssertComparisonResult(
Fts5Iter *pIter,
Fts5SegIter *p1,
Fts5SegIter *p2,
Fts5CResult *pRes
){
int i1 = p1 - pIter->aSeg;
int i2 = p2 - pIter->aSeg;
if( p1->pLeaf || p2->pLeaf ){
if( p1->pLeaf==0 ){
assert( pRes->iFirst==i2 );
}else if( p2->pLeaf==0 ){
assert( pRes->iFirst==i1 );
}else{
int nMin = MIN(p1->term.n, p2->term.n);
int res = fts5Memcmp(p1->term.p, p2->term.p, nMin);
if( res==0 ) res = p1->term.n - p2->term.n;
if( res==0 ){
assert( pRes->bTermEq==1 );
assert( p1->iRowid!=p2->iRowid );
res = ((p1->iRowid > p2->iRowid)==pIter->bRev) ? -1 : 1;
}else{
assert( pRes->bTermEq==0 );
}
if( res<0 ){
assert( pRes->iFirst==i1 );
}else{
assert( pRes->iFirst==i2 );
}
}
}
}
/*
** This function is a no-op unless SQLITE_DEBUG is defined when this module
** is compiled. In that case, this function is essentially an assert()
** statement used to verify that the contents of the pIter->aFirst[] array
** are correct.
*/
static void fts5AssertMultiIterSetup(Fts5Index *p, Fts5Iter *pIter){
if( p->rc==SQLITE_OK ){
Fts5SegIter *pFirst = &pIter->aSeg[ pIter->aFirst[1].iFirst ];
int i;
assert( (pFirst->pLeaf==0)==pIter->base.bEof );
/* Check that pIter->iSwitchRowid is set correctly. */
for(i=0; i<pIter->nSeg; i++){
Fts5SegIter *p1 = &pIter->aSeg[i];
assert( p1==pFirst
|| p1->pLeaf==0
|| fts5BufferCompare(&pFirst->term, &p1->term)
|| p1->iRowid==pIter->iSwitchRowid
|| (p1->iRowid<pIter->iSwitchRowid)==pIter->bRev
);
}
for(i=0; i<pIter->nSeg; i+=2){
Fts5SegIter *p1 = &pIter->aSeg[i];
Fts5SegIter *p2 = &pIter->aSeg[i+1];
Fts5CResult *pRes = &pIter->aFirst[(pIter->nSeg + i) / 2];
fts5AssertComparisonResult(pIter, p1, p2, pRes);
}
for(i=1; i<(pIter->nSeg / 2); i+=2){
Fts5SegIter *p1 = &pIter->aSeg[ pIter->aFirst[i*2].iFirst ];
Fts5SegIter *p2 = &pIter->aSeg[ pIter->aFirst[i*2+1].iFirst ];
Fts5CResult *pRes = &pIter->aFirst[i];
fts5AssertComparisonResult(pIter, p1, p2, pRes);
}
}
}
#else
# define fts5AssertMultiIterSetup(x,y)
#endif
/*
** Do the comparison necessary to populate pIter->aFirst[iOut].
**
** If the returned value is non-zero, then it is the index of an entry
** in the pIter->aSeg[] array that is (a) not at EOF, and (b) pointing
** to a key that is a duplicate of another, higher priority,
** segment-iterator in the pSeg->aSeg[] array.
*/
static int fts5MultiIterDoCompare(Fts5Iter *pIter, int iOut){
int i1; /* Index of left-hand Fts5SegIter */
int i2; /* Index of right-hand Fts5SegIter */
int iRes;
Fts5SegIter *p1; /* Left-hand Fts5SegIter */
Fts5SegIter *p2; /* Right-hand Fts5SegIter */
Fts5CResult *pRes = &pIter->aFirst[iOut];
assert( iOut<pIter->nSeg && iOut>0 );
assert( pIter->bRev==0 || pIter->bRev==1 );
if( iOut>=(pIter->nSeg/2) ){
i1 = (iOut - pIter->nSeg/2) * 2;
i2 = i1 + 1;
}else{
i1 = pIter->aFirst[iOut*2].iFirst;
i2 = pIter->aFirst[iOut*2+1].iFirst;
}
p1 = &pIter->aSeg[i1];
p2 = &pIter->aSeg[i2];
pRes->bTermEq = 0;
if( p1->pLeaf==0 ){ /* If p1 is at EOF */
iRes = i2;
}else if( p2->pLeaf==0 ){ /* If p2 is at EOF */
iRes = i1;
}else{
int res = fts5BufferCompare(&p1->term, &p2->term);
if( res==0 ){
assert_nc( i2>i1 );
assert_nc( i2!=0 );
pRes->bTermEq = 1;
if( p1->iRowid==p2->iRowid ){
p1->bDel = p2->bDel;
return i2;
}
res = ((p1->iRowid > p2->iRowid)==pIter->bRev) ? -1 : +1;
}
assert( res!=0 );
if( res<0 ){
iRes = i1;
}else{
iRes = i2;
}
}
pRes->iFirst = (u16)iRes;
return 0;
}
/*
** Move the seg-iter so that it points to the first rowid on page iLeafPgno.
** It is an error if leaf iLeafPgno does not exist or contains no rowids.
*/
static void fts5SegIterGotoPage(
Fts5Index *p, /* FTS5 backend object */
Fts5SegIter *pIter, /* Iterator to advance */
int iLeafPgno
){
assert( iLeafPgno>pIter->iLeafPgno );
if( iLeafPgno>pIter->pSeg->pgnoLast ){
p->rc = FTS5_CORRUPT;
}else{
fts5DataRelease(pIter->pNextLeaf);
pIter->pNextLeaf = 0;
pIter->iLeafPgno = iLeafPgno-1;
fts5SegIterNextPage(p, pIter);
assert( p->rc!=SQLITE_OK || pIter->iLeafPgno==iLeafPgno );
if( p->rc==SQLITE_OK ){
int iOff;
u8 *a = pIter->pLeaf->p;
int n = pIter->pLeaf->szLeaf;
iOff = fts5LeafFirstRowidOff(pIter->pLeaf);
if( iOff<4 || iOff>=n ){
p->rc = FTS5_CORRUPT;
}else{
iOff += fts5GetVarint(&a[iOff], (u64*)&pIter->iRowid);
pIter->iLeafOffset = iOff;
fts5SegIterLoadNPos(p, pIter);
}
}
}
}
/*
** Advance the iterator passed as the second argument until it is at or
** past rowid iFrom. Regardless of the value of iFrom, the iterator is
** always advanced at least once.
*/
static void fts5SegIterNextFrom(
Fts5Index *p, /* FTS5 backend object */
Fts5SegIter *pIter, /* Iterator to advance */
i64 iMatch /* Advance iterator at least this far */
){
int bRev = (pIter->flags & FTS5_SEGITER_REVERSE);
Fts5DlidxIter *pDlidx = pIter->pDlidx;
int iLeafPgno = pIter->iLeafPgno;
int bMove = 1;
assert( pIter->flags & FTS5_SEGITER_ONETERM );
assert( pIter->pDlidx );
assert( pIter->pLeaf );
if( bRev==0 ){
while( !fts5DlidxIterEof(p, pDlidx) && iMatch>fts5DlidxIterRowid(pDlidx) ){
iLeafPgno = fts5DlidxIterPgno(pDlidx);
fts5DlidxIterNext(p, pDlidx);
}
assert_nc( iLeafPgno>=pIter->iLeafPgno || p->rc );
if( iLeafPgno>pIter->iLeafPgno ){
fts5SegIterGotoPage(p, pIter, iLeafPgno);
bMove = 0;
}
}else{
assert( pIter->pNextLeaf==0 );
assert( iMatch<pIter->iRowid );
while( !fts5DlidxIterEof(p, pDlidx) && iMatch<fts5DlidxIterRowid(pDlidx) ){
fts5DlidxIterPrev(p, pDlidx);
}
iLeafPgno = fts5DlidxIterPgno(pDlidx);
assert( fts5DlidxIterEof(p, pDlidx) || iLeafPgno<=pIter->iLeafPgno );
if( iLeafPgno<pIter->iLeafPgno ){
pIter->iLeafPgno = iLeafPgno+1;
fts5SegIterReverseNewPage(p, pIter);
bMove = 0;
}
}
do{
if( bMove && p->rc==SQLITE_OK ) pIter->xNext(p, pIter, 0);
if( pIter->pLeaf==0 ) break;
if( bRev==0 && pIter->iRowid>=iMatch ) break;
if( bRev!=0 && pIter->iRowid<=iMatch ) break;
bMove = 1;
}while( p->rc==SQLITE_OK );
}
/*
** Free the iterator object passed as the second argument.
*/
static void fts5MultiIterFree(Fts5Iter *pIter){
if( pIter ){
int i;
for(i=0; i<pIter->nSeg; i++){
fts5SegIterClear(&pIter->aSeg[i]);
}
fts5BufferFree(&pIter->poslist);
sqlite3_free(pIter);
}
}
static void fts5MultiIterAdvanced(
Fts5Index *p, /* FTS5 backend to iterate within */
Fts5Iter *pIter, /* Iterator to update aFirst[] array for */
int iChanged, /* Index of sub-iterator just advanced */
int iMinset /* Minimum entry in aFirst[] to set */
){
int i;
for(i=(pIter->nSeg+iChanged)/2; i>=iMinset && p->rc==SQLITE_OK; i=i/2){
int iEq;
if( (iEq = fts5MultiIterDoCompare(pIter, i)) ){
Fts5SegIter *pSeg = &pIter->aSeg[iEq];
assert( p->rc==SQLITE_OK );
pSeg->xNext(p, pSeg, 0);
i = pIter->nSeg + iEq;
}
}
}
/*
** Sub-iterator iChanged of iterator pIter has just been advanced. It still
** points to the same term though - just a different rowid. This function
** attempts to update the contents of the pIter->aFirst[] accordingly.
** If it does so successfully, 0 is returned. Otherwise 1.
**
** If non-zero is returned, the caller should call fts5MultiIterAdvanced()
** on the iterator instead. That function does the same as this one, except
** that it deals with more complicated cases as well.
*/
static int fts5MultiIterAdvanceRowid(
Fts5Iter *pIter, /* Iterator to update aFirst[] array for */
int iChanged, /* Index of sub-iterator just advanced */
Fts5SegIter **ppFirst
){
Fts5SegIter *pNew = &pIter->aSeg[iChanged];
if( pNew->iRowid==pIter->iSwitchRowid
|| (pNew->iRowid<pIter->iSwitchRowid)==pIter->bRev
){
int i;
Fts5SegIter *pOther = &pIter->aSeg[iChanged ^ 0x0001];
pIter->iSwitchRowid = pIter->bRev ? SMALLEST_INT64 : LARGEST_INT64;
for(i=(pIter->nSeg+iChanged)/2; 1; i=i/2){
Fts5CResult *pRes = &pIter->aFirst[i];
assert( pNew->pLeaf );
assert( pRes->bTermEq==0 || pOther->pLeaf );
if( pRes->bTermEq ){
if( pNew->iRowid==pOther->iRowid ){
return 1;
}else if( (pOther->iRowid>pNew->iRowid)==pIter->bRev ){
pIter->iSwitchRowid = pOther->iRowid;
pNew = pOther;
}else if( (pOther->iRowid>pIter->iSwitchRowid)==pIter->bRev ){
pIter->iSwitchRowid = pOther->iRowid;
}
}
pRes->iFirst = (u16)(pNew - pIter->aSeg);
if( i==1 ) break;
pOther = &pIter->aSeg[ pIter->aFirst[i ^ 0x0001].iFirst ];
}
}
*ppFirst = pNew;
return 0;
}
/*
** Set the pIter->bEof variable based on the state of the sub-iterators.
*/
static void fts5MultiIterSetEof(Fts5Iter *pIter){
Fts5SegIter *pSeg = &pIter->aSeg[ pIter->aFirst[1].iFirst ];
pIter->base.bEof = pSeg->pLeaf==0;
pIter->iSwitchRowid = pSeg->iRowid;
}
/*
** Move the iterator to the next entry.
**
** If an error occurs, an error code is left in Fts5Index.rc. It is not
** considered an error if the iterator reaches EOF, or if it is already at
** EOF when this function is called.
*/
static void fts5MultiIterNext(
Fts5Index *p,
Fts5Iter *pIter,
int bFrom, /* True if argument iFrom is valid */
i64 iFrom /* Advance at least as far as this */
){
int bUseFrom = bFrom;
assert( pIter->base.bEof==0 );
while( p->rc==SQLITE_OK ){
int iFirst = pIter->aFirst[1].iFirst;
int bNewTerm = 0;
Fts5SegIter *pSeg = &pIter->aSeg[iFirst];
assert( p->rc==SQLITE_OK );
if( bUseFrom && pSeg->pDlidx ){
fts5SegIterNextFrom(p, pSeg, iFrom);
}else{
pSeg->xNext(p, pSeg, &bNewTerm);
}
if( pSeg->pLeaf==0 || bNewTerm
|| fts5MultiIterAdvanceRowid(pIter, iFirst, &pSeg)
){
fts5MultiIterAdvanced(p, pIter, iFirst, 1);
fts5MultiIterSetEof(pIter);
pSeg = &pIter->aSeg[pIter->aFirst[1].iFirst];
if( pSeg->pLeaf==0 ) return;
}
fts5AssertMultiIterSetup(p, pIter);
assert( pSeg==&pIter->aSeg[pIter->aFirst[1].iFirst] && pSeg->pLeaf );
if( pIter->bSkipEmpty==0 || pSeg->nPos ){
pIter->xSetOutputs(pIter, pSeg);
return;
}
bUseFrom = 0;
}
}
static void fts5MultiIterNext2(
Fts5Index *p,
Fts5Iter *pIter,
int *pbNewTerm /* OUT: True if *might* be new term */
){
assert( pIter->bSkipEmpty );
if( p->rc==SQLITE_OK ){
*pbNewTerm = 0;
do{
int iFirst = pIter->aFirst[1].iFirst;
Fts5SegIter *pSeg = &pIter->aSeg[iFirst];
int bNewTerm = 0;
assert( p->rc==SQLITE_OK );
pSeg->xNext(p, pSeg, &bNewTerm);
if( pSeg->pLeaf==0 || bNewTerm
|| fts5MultiIterAdvanceRowid(pIter, iFirst, &pSeg)
){
fts5MultiIterAdvanced(p, pIter, iFirst, 1);
fts5MultiIterSetEof(pIter);
*pbNewTerm = 1;
}
fts5AssertMultiIterSetup(p, pIter);
}while( fts5MultiIterIsEmpty(p, pIter) );
}
}
static void fts5IterSetOutputs_Noop(Fts5Iter *pUnused1, Fts5SegIter *pUnused2){
UNUSED_PARAM2(pUnused1, pUnused2);
}
static Fts5Iter *fts5MultiIterAlloc(
Fts5Index *p, /* FTS5 backend to iterate within */
int nSeg
){
Fts5Iter *pNew;
int nSlot; /* Power of two >= nSeg */
for(nSlot=2; nSlot<nSeg; nSlot=nSlot*2);
pNew = fts5IdxMalloc(p,
sizeof(Fts5Iter) + /* pNew */
sizeof(Fts5SegIter) * (nSlot-1) + /* pNew->aSeg[] */
sizeof(Fts5CResult) * nSlot /* pNew->aFirst[] */
);
if( pNew ){
pNew->nSeg = nSlot;
pNew->aFirst = (Fts5CResult*)&pNew->aSeg[nSlot];
pNew->pIndex = p;
pNew->xSetOutputs = fts5IterSetOutputs_Noop;
}
return pNew;
}
static void fts5PoslistCallback(
Fts5Index *pUnused,
void *pContext,
const u8 *pChunk, int nChunk
){
UNUSED_PARAM(pUnused);
assert_nc( nChunk>=0 );
if( nChunk>0 ){
fts5BufferSafeAppendBlob((Fts5Buffer*)pContext, pChunk, nChunk);
}
}
typedef struct PoslistCallbackCtx PoslistCallbackCtx;
struct PoslistCallbackCtx {
Fts5Buffer *pBuf; /* Append to this buffer */
Fts5Colset *pColset; /* Restrict matches to this column */
int eState; /* See above */
};
typedef struct PoslistOffsetsCtx PoslistOffsetsCtx;
struct PoslistOffsetsCtx {
Fts5Buffer *pBuf; /* Append to this buffer */
Fts5Colset *pColset; /* Restrict matches to this column */
int iRead;
int iWrite;
};
/*
** TODO: Make this more efficient!
*/
static int fts5IndexColsetTest(Fts5Colset *pColset, int iCol){
int i;
for(i=0; i<pColset->nCol; i++){
if( pColset->aiCol[i]==iCol ) return 1;
}
return 0;
}
static void fts5PoslistOffsetsCallback(
Fts5Index *pUnused,
void *pContext,
const u8 *pChunk, int nChunk
){
PoslistOffsetsCtx *pCtx = (PoslistOffsetsCtx*)pContext;
UNUSED_PARAM(pUnused);
assert_nc( nChunk>=0 );
if( nChunk>0 ){
int i = 0;
while( i<nChunk ){
int iVal;
i += fts5GetVarint32(&pChunk[i], iVal);
iVal += pCtx->iRead - 2;
pCtx->iRead = iVal;
if( fts5IndexColsetTest(pCtx->pColset, iVal) ){
fts5BufferSafeAppendVarint(pCtx->pBuf, iVal + 2 - pCtx->iWrite);
pCtx->iWrite = iVal;
}
}
}
}
static void fts5PoslistFilterCallback(
Fts5Index *pUnused,
void *pContext,
const u8 *pChunk, int nChunk
){
PoslistCallbackCtx *pCtx = (PoslistCallbackCtx*)pContext;
UNUSED_PARAM(pUnused);
assert_nc( nChunk>=0 );
if( nChunk>0 ){
/* Search through to find the first varint with value 1. This is the
** start of the next columns hits. */
int i = 0;
int iStart = 0;
if( pCtx->eState==2 ){
int iCol;
fts5FastGetVarint32(pChunk, i, iCol);
if( fts5IndexColsetTest(pCtx->pColset, iCol) ){
pCtx->eState = 1;
fts5BufferSafeAppendVarint(pCtx->pBuf, 1);
}else{
pCtx->eState = 0;
}
}
do {
while( i<nChunk && pChunk[i]!=0x01 ){
while( pChunk[i] & 0x80 ) i++;
i++;
}
if( pCtx->eState ){
fts5BufferSafeAppendBlob(pCtx->pBuf, &pChunk[iStart], i-iStart);
}
if( i<nChunk ){
int iCol;
iStart = i;
i++;
if( i>=nChunk ){
pCtx->eState = 2;
}else{
fts5FastGetVarint32(pChunk, i, iCol);
pCtx->eState = fts5IndexColsetTest(pCtx->pColset, iCol);
if( pCtx->eState ){
fts5BufferSafeAppendBlob(pCtx->pBuf, &pChunk[iStart], i-iStart);
iStart = i;
}
}
}
}while( i<nChunk );
}
}
static void fts5ChunkIterate(
Fts5Index *p, /* Index object */
Fts5SegIter *pSeg, /* Poslist of this iterator */
void *pCtx, /* Context pointer for xChunk callback */
void (*xChunk)(Fts5Index*, void*, const u8*, int)
){
int nRem = pSeg->nPos; /* Number of bytes still to come */
Fts5Data *pData = 0;
u8 *pChunk = &pSeg->pLeaf->p[pSeg->iLeafOffset];
int nChunk = MIN(nRem, pSeg->pLeaf->szLeaf - pSeg->iLeafOffset);
int pgno = pSeg->iLeafPgno;
int pgnoSave = 0;
/* This function does not work with detail=none databases. */
assert( p->pConfig->eDetail!=FTS5_DETAIL_NONE );
if( (pSeg->flags & FTS5_SEGITER_REVERSE)==0 ){
pgnoSave = pgno+1;
}
while( 1 ){
xChunk(p, pCtx, pChunk, nChunk);
nRem -= nChunk;
fts5DataRelease(pData);
if( nRem<=0 ){
break;
}else if( pSeg->pSeg==0 ){
p->rc = FTS5_CORRUPT;
return;
}else{
pgno++;
pData = fts5LeafRead(p, FTS5_SEGMENT_ROWID(pSeg->pSeg->iSegid, pgno));
if( pData==0 ) break;
pChunk = &pData->p[4];
nChunk = MIN(nRem, pData->szLeaf - 4);
if( pgno==pgnoSave ){
assert( pSeg->pNextLeaf==0 );
pSeg->pNextLeaf = pData;
pData = 0;
}
}
}
}
/*
** Iterator pIter currently points to a valid entry (not EOF). This
** function appends the position list data for the current entry to
** buffer pBuf. It does not make a copy of the position-list size
** field.
*/
static void fts5SegiterPoslist(
Fts5Index *p,
Fts5SegIter *pSeg,
Fts5Colset *pColset,
Fts5Buffer *pBuf
){
if( 0==fts5BufferGrow(&p->rc, pBuf, pSeg->nPos+FTS5_DATA_ZERO_PADDING) ){
memset(&pBuf->p[pBuf->n+pSeg->nPos], 0, FTS5_DATA_ZERO_PADDING);
if( pColset==0 ){
fts5ChunkIterate(p, pSeg, (void*)pBuf, fts5PoslistCallback);
}else{
if( p->pConfig->eDetail==FTS5_DETAIL_FULL ){
PoslistCallbackCtx sCtx;
sCtx.pBuf = pBuf;
sCtx.pColset = pColset;
sCtx.eState = fts5IndexColsetTest(pColset, 0);
assert( sCtx.eState==0 || sCtx.eState==1 );
fts5ChunkIterate(p, pSeg, (void*)&sCtx, fts5PoslistFilterCallback);
}else{
PoslistOffsetsCtx sCtx;
memset(&sCtx, 0, sizeof(sCtx));
sCtx.pBuf = pBuf;
sCtx.pColset = pColset;
fts5ChunkIterate(p, pSeg, (void*)&sCtx, fts5PoslistOffsetsCallback);
}
}
}
}
/*
** Parameter pPos points to a buffer containing a position list, size nPos.
** This function filters it according to pColset (which must be non-NULL)
** and sets pIter->base.pData/nData to point to the new position list.
** If memory is required for the new position list, use buffer pIter->poslist.
** Or, if the new position list is a contiguous subset of the input, set
** pIter->base.pData/nData to point directly to it.
**
** This function is a no-op if *pRc is other than SQLITE_OK when it is
** called. If an OOM error is encountered, *pRc is set to SQLITE_NOMEM
** before returning.
*/
static void fts5IndexExtractColset(
int *pRc,
Fts5Colset *pColset, /* Colset to filter on */
const u8 *pPos, int nPos, /* Position list */
Fts5Iter *pIter
){
if( *pRc==SQLITE_OK ){
const u8 *p = pPos;
const u8 *aCopy = p;
const u8 *pEnd = &p[nPos]; /* One byte past end of position list */
int i = 0;
int iCurrent = 0;
if( pColset->nCol>1 && sqlite3Fts5BufferSize(pRc, &pIter->poslist, nPos) ){
return;
}
while( 1 ){
while( pColset->aiCol[i]<iCurrent ){
i++;
if( i==pColset->nCol ){
pIter->base.pData = pIter->poslist.p;
pIter->base.nData = pIter->poslist.n;
return;
}
}
/* Advance pointer p until it points to pEnd or an 0x01 byte that is
** not part of a varint */
while( p<pEnd && *p!=0x01 ){
while( *p++ & 0x80 );
}
if( pColset->aiCol[i]==iCurrent ){
if( pColset->nCol==1 ){
pIter->base.pData = aCopy;
pIter->base.nData = p-aCopy;
return;
}
fts5BufferSafeAppendBlob(&pIter->poslist, aCopy, p-aCopy);
}
if( p==pEnd ){
pIter->base.pData = pIter->poslist.p;
pIter->base.nData = pIter->poslist.n;
return;
}
aCopy = p++;
iCurrent = *p++;
if( iCurrent & 0x80 ){
p--;
p += fts5GetVarint32(p, iCurrent);
}
}
}
}
/*
** xSetOutputs callback used by detail=none tables.
*/
static void fts5IterSetOutputs_None(Fts5Iter *pIter, Fts5SegIter *pSeg){
assert( pIter->pIndex->pConfig->eDetail==FTS5_DETAIL_NONE );
pIter->base.iRowid = pSeg->iRowid;
pIter->base.nData = pSeg->nPos;
}
/*
** xSetOutputs callback used by detail=full and detail=col tables when no
** column filters are specified.
*/
static void fts5IterSetOutputs_Nocolset(Fts5Iter *pIter, Fts5SegIter *pSeg){
pIter->base.iRowid = pSeg->iRowid;
pIter->base.nData = pSeg->nPos;
assert( pIter->pIndex->pConfig->eDetail!=FTS5_DETAIL_NONE );
assert( pIter->pColset==0 );
if( pSeg->iLeafOffset+pSeg->nPos<=pSeg->pLeaf->szLeaf ){
/* All data is stored on the current page. Populate the output
** variables to point into the body of the page object. */
pIter->base.pData = &pSeg->pLeaf->p[pSeg->iLeafOffset];
}else{
/* The data is distributed over two or more pages. Copy it into the
** Fts5Iter.poslist buffer and then set the output pointer to point
** to this buffer. */
fts5BufferZero(&pIter->poslist);
fts5SegiterPoslist(pIter->pIndex, pSeg, 0, &pIter->poslist);
pIter->base.pData = pIter->poslist.p;
}
}
/*
** xSetOutputs callback used when the Fts5Colset object has nCol==0 (match
** against no columns at all).
*/
static void fts5IterSetOutputs_ZeroColset(Fts5Iter *pIter, Fts5SegIter *pSeg){
UNUSED_PARAM(pSeg);
pIter->base.nData = 0;
}
/*
** xSetOutputs callback used by detail=col when there is a column filter
** and there are 100 or more columns. Also called as a fallback from
** fts5IterSetOutputs_Col100 if the column-list spans more than one page.
*/
static void fts5IterSetOutputs_Col(Fts5Iter *pIter, Fts5SegIter *pSeg){
fts5BufferZero(&pIter->poslist);
fts5SegiterPoslist(pIter->pIndex, pSeg, pIter->pColset, &pIter->poslist);
pIter->base.iRowid = pSeg->iRowid;
pIter->base.pData = pIter->poslist.p;
pIter->base.nData = pIter->poslist.n;
}
/*
** xSetOutputs callback used when:
**
** * detail=col,
** * there is a column filter, and
** * the table contains 100 or fewer columns.
**
** The last point is to ensure all column numbers are stored as
** single-byte varints.
*/
static void fts5IterSetOutputs_Col100(Fts5Iter *pIter, Fts5SegIter *pSeg){
assert( pIter->pIndex->pConfig->eDetail==FTS5_DETAIL_COLUMNS );
assert( pIter->pColset );
if( pSeg->iLeafOffset+pSeg->nPos>pSeg->pLeaf->szLeaf ){
fts5IterSetOutputs_Col(pIter, pSeg);
}else{
u8 *a = (u8*)&pSeg->pLeaf->p[pSeg->iLeafOffset];
u8 *pEnd = (u8*)&a[pSeg->nPos];
int iPrev = 0;
int *aiCol = pIter->pColset->aiCol;
int *aiColEnd = &aiCol[pIter->pColset->nCol];
u8 *aOut = pIter->poslist.p;
int iPrevOut = 0;
pIter->base.iRowid = pSeg->iRowid;
while( a<pEnd ){
iPrev += (int)a++[0] - 2;
while( *aiCol<iPrev ){
aiCol++;
if( aiCol==aiColEnd ) goto setoutputs_col_out;
}
if( *aiCol==iPrev ){
*aOut++ = (u8)((iPrev - iPrevOut) + 2);
iPrevOut = iPrev;
}
}
setoutputs_col_out:
pIter->base.pData = pIter->poslist.p;
pIter->base.nData = aOut - pIter->poslist.p;
}
}
/*
** xSetOutputs callback used by detail=full when there is a column filter.
*/
static void fts5IterSetOutputs_Full(Fts5Iter *pIter, Fts5SegIter *pSeg){
Fts5Colset *pColset = pIter->pColset;
pIter->base.iRowid = pSeg->iRowid;
assert( pIter->pIndex->pConfig->eDetail==FTS5_DETAIL_FULL );
assert( pColset );
if( pSeg->iLeafOffset+pSeg->nPos<=pSeg->pLeaf->szLeaf ){
/* All data is stored on the current page. Populate the output
** variables to point into the body of the page object. */
const u8 *a = &pSeg->pLeaf->p[pSeg->iLeafOffset];
int *pRc = &pIter->pIndex->rc;
fts5BufferZero(&pIter->poslist);
fts5IndexExtractColset(pRc, pColset, a, pSeg->nPos, pIter);
}else{
/* The data is distributed over two or more pages. Copy it into the
** Fts5Iter.poslist buffer and then set the output pointer to point
** to this buffer. */
fts5BufferZero(&pIter->poslist);
fts5SegiterPoslist(pIter->pIndex, pSeg, pColset, &pIter->poslist);
pIter->base.pData = pIter->poslist.p;
pIter->base.nData = pIter->poslist.n;
}
}
static void fts5IterSetOutputCb(int *pRc, Fts5Iter *pIter){
if( *pRc==SQLITE_OK ){
Fts5Config *pConfig = pIter->pIndex->pConfig;
if( pConfig->eDetail==FTS5_DETAIL_NONE ){
pIter->xSetOutputs = fts5IterSetOutputs_None;
}
else if( pIter->pColset==0 ){
pIter->xSetOutputs = fts5IterSetOutputs_Nocolset;
}
else if( pIter->pColset->nCol==0 ){
pIter->xSetOutputs = fts5IterSetOutputs_ZeroColset;
}
else if( pConfig->eDetail==FTS5_DETAIL_FULL ){
pIter->xSetOutputs = fts5IterSetOutputs_Full;
}
else{
assert( pConfig->eDetail==FTS5_DETAIL_COLUMNS );
if( pConfig->nCol<=100 ){
pIter->xSetOutputs = fts5IterSetOutputs_Col100;
sqlite3Fts5BufferSize(pRc, &pIter->poslist, pConfig->nCol);
}else{
pIter->xSetOutputs = fts5IterSetOutputs_Col;
}
}
}
}
/*
** Allocate a new Fts5Iter object.
**
** The new object will be used to iterate through data in structure pStruct.
** If iLevel is -ve, then all data in all segments is merged. Or, if iLevel
** is zero or greater, data from the first nSegment segments on level iLevel
** is merged.
**
** The iterator initially points to the first term/rowid entry in the
** iterated data.
*/
static void fts5MultiIterNew(
Fts5Index *p, /* FTS5 backend to iterate within */
Fts5Structure *pStruct, /* Structure of specific index */
int flags, /* FTS5INDEX_QUERY_XXX flags */
Fts5Colset *pColset, /* Colset to filter on (or NULL) */
const u8 *pTerm, int nTerm, /* Term to seek to (or NULL/0) */
int iLevel, /* Level to iterate (-1 for all) */
int nSegment, /* Number of segments to merge (iLevel>=0) */
Fts5Iter **ppOut /* New object */
){
int nSeg = 0; /* Number of segment-iters in use */
int iIter = 0; /* */
int iSeg; /* Used to iterate through segments */
Fts5StructureLevel *pLvl;
Fts5Iter *pNew;
assert( (pTerm==0 && nTerm==0) || iLevel<0 );
/* Allocate space for the new multi-seg-iterator. */
if( p->rc==SQLITE_OK ){
if( iLevel<0 ){
assert( pStruct->nSegment==fts5StructureCountSegments(pStruct) );
nSeg = pStruct->nSegment;
nSeg += (p->pHash ? 1 : 0);
}else{
nSeg = MIN(pStruct->aLevel[iLevel].nSeg, nSegment);
}
}
*ppOut = pNew = fts5MultiIterAlloc(p, nSeg);
if( pNew==0 ) return;
pNew->bRev = (0!=(flags & FTS5INDEX_QUERY_DESC));
pNew->bSkipEmpty = (0!=(flags & FTS5INDEX_QUERY_SKIPEMPTY));
pNew->pColset = pColset;
if( (flags & FTS5INDEX_QUERY_NOOUTPUT)==0 ){
fts5IterSetOutputCb(&p->rc, pNew);
}
/* Initialize each of the component segment iterators. */
if( p->rc==SQLITE_OK ){
if( iLevel<0 ){
Fts5StructureLevel *pEnd = &pStruct->aLevel[pStruct->nLevel];
if( p->pHash ){
/* Add a segment iterator for the current contents of the hash table. */
Fts5SegIter *pIter = &pNew->aSeg[iIter++];
fts5SegIterHashInit(p, pTerm, nTerm, flags, pIter);
}
for(pLvl=&pStruct->aLevel[0]; pLvl<pEnd; pLvl++){
for(iSeg=pLvl->nSeg-1; iSeg>=0; iSeg--){
Fts5StructureSegment *pSeg = &pLvl->aSeg[iSeg];
Fts5SegIter *pIter = &pNew->aSeg[iIter++];
if( pTerm==0 ){
fts5SegIterInit(p, pSeg, pIter);
}else{
fts5SegIterSeekInit(p, pTerm, nTerm, flags, pSeg, pIter);
}
}
}
}else{
pLvl = &pStruct->aLevel[iLevel];
for(iSeg=nSeg-1; iSeg>=0; iSeg--){
fts5SegIterInit(p, &pLvl->aSeg[iSeg], &pNew->aSeg[iIter++]);
}
}
assert( iIter==nSeg );
}
/* If the above was successful, each component iterators now points
** to the first entry in its segment. In this case initialize the
** aFirst[] array. Or, if an error has occurred, free the iterator
** object and set the output variable to NULL. */
if( p->rc==SQLITE_OK ){
for(iIter=pNew->nSeg-1; iIter>0; iIter--){
int iEq;
if( (iEq = fts5MultiIterDoCompare(pNew, iIter)) ){
Fts5SegIter *pSeg = &pNew->aSeg[iEq];
if( p->rc==SQLITE_OK ) pSeg->xNext(p, pSeg, 0);
fts5MultiIterAdvanced(p, pNew, iEq, iIter);
}
}
fts5MultiIterSetEof(pNew);
fts5AssertMultiIterSetup(p, pNew);
if( pNew->bSkipEmpty && fts5MultiIterIsEmpty(p, pNew) ){
fts5MultiIterNext(p, pNew, 0, 0);
}else if( pNew->base.bEof==0 ){
Fts5SegIter *pSeg = &pNew->aSeg[pNew->aFirst[1].iFirst];
pNew->xSetOutputs(pNew, pSeg);
}
}else{
fts5MultiIterFree(pNew);
*ppOut = 0;
}
}
/*
** Create an Fts5Iter that iterates through the doclist provided
** as the second argument.
*/
static void fts5MultiIterNew2(
Fts5Index *p, /* FTS5 backend to iterate within */
Fts5Data *pData, /* Doclist to iterate through */
int bDesc, /* True for descending rowid order */
Fts5Iter **ppOut /* New object */
){
Fts5Iter *pNew;
pNew = fts5MultiIterAlloc(p, 2);
if( pNew ){
Fts5SegIter *pIter = &pNew->aSeg[1];
pIter->flags = FTS5_SEGITER_ONETERM;
if( pData->szLeaf>0 ){
pIter->pLeaf = pData;
pIter->iLeafOffset = fts5GetVarint(pData->p, (u64*)&pIter->iRowid);
pIter->iEndofDoclist = pData->nn;
pNew->aFirst[1].iFirst = 1;
if( bDesc ){
pNew->bRev = 1;
pIter->flags |= FTS5_SEGITER_REVERSE;
fts5SegIterReverseInitPage(p, pIter);
}else{
fts5SegIterLoadNPos(p, pIter);
}
pData = 0;
}else{
pNew->base.bEof = 1;
}
fts5SegIterSetNext(p, pIter);
*ppOut = pNew;
}
fts5DataRelease(pData);
}
/*
** Return true if the iterator is at EOF or if an error has occurred.
** False otherwise.
*/
static int fts5MultiIterEof(Fts5Index *p, Fts5Iter *pIter){
assert( p->rc
|| (pIter->aSeg[ pIter->aFirst[1].iFirst ].pLeaf==0)==pIter->base.bEof
);
return (p->rc || pIter->base.bEof);
}
/*
** Return the rowid of the entry that the iterator currently points
** to. If the iterator points to EOF when this function is called the
** results are undefined.
*/
static i64 fts5MultiIterRowid(Fts5Iter *pIter){
assert( pIter->aSeg[ pIter->aFirst[1].iFirst ].pLeaf );
return pIter->aSeg[ pIter->aFirst[1].iFirst ].iRowid;
}
/*
** Move the iterator to the next entry at or following iMatch.
*/
static void fts5MultiIterNextFrom(
Fts5Index *p,
Fts5Iter *pIter,
i64 iMatch
){
while( 1 ){
i64 iRowid;
fts5MultiIterNext(p, pIter, 1, iMatch);
if( fts5MultiIterEof(p, pIter) ) break;
iRowid = fts5MultiIterRowid(pIter);
if( pIter->bRev==0 && iRowid>=iMatch ) break;
if( pIter->bRev!=0 && iRowid<=iMatch ) break;
}
}
/*
** Return a pointer to a buffer containing the term associated with the
** entry that the iterator currently points to.
*/
static const u8 *fts5MultiIterTerm(Fts5Iter *pIter, int *pn){
Fts5SegIter *p = &pIter->aSeg[ pIter->aFirst[1].iFirst ];
*pn = p->term.n;
return p->term.p;
}
/*
** Allocate a new segment-id for the structure pStruct. The new segment
** id must be between 1 and 65335 inclusive, and must not be used by
** any currently existing segment. If a free segment id cannot be found,
** SQLITE_FULL is returned.
**
** If an error has already occurred, this function is a no-op. 0 is
** returned in this case.
*/
static int fts5AllocateSegid(Fts5Index *p, Fts5Structure *pStruct){
int iSegid = 0;
if( p->rc==SQLITE_OK ){
if( pStruct->nSegment>=FTS5_MAX_SEGMENT ){
p->rc = SQLITE_FULL;
}else{
/* FTS5_MAX_SEGMENT is currently defined as 2000. So the following
** array is 63 elements, or 252 bytes, in size. */
u32 aUsed[(FTS5_MAX_SEGMENT+31) / 32];
int iLvl, iSeg;
int i;
u32 mask;
memset(aUsed, 0, sizeof(aUsed));
for(iLvl=0; iLvl<pStruct->nLevel; iLvl++){
for(iSeg=0; iSeg<pStruct->aLevel[iLvl].nSeg; iSeg++){
int iId = pStruct->aLevel[iLvl].aSeg[iSeg].iSegid;
if( iId<=FTS5_MAX_SEGMENT && iId>0 ){
aUsed[(iId-1) / 32] |= (u32)1 << ((iId-1) % 32);
}
}
}
for(i=0; aUsed[i]==0xFFFFFFFF; i++);
mask = aUsed[i];
for(iSegid=0; mask & ((u32)1 << iSegid); iSegid++);
iSegid += 1 + i*32;
#ifdef SQLITE_DEBUG
for(iLvl=0; iLvl<pStruct->nLevel; iLvl++){
for(iSeg=0; iSeg<pStruct->aLevel[iLvl].nSeg; iSeg++){
assert_nc( iSegid!=pStruct->aLevel[iLvl].aSeg[iSeg].iSegid );
}
}
assert_nc( iSegid>0 && iSegid<=FTS5_MAX_SEGMENT );
{
sqlite3_stmt *pIdxSelect = fts5IdxSelectStmt(p);
if( p->rc==SQLITE_OK ){
u8 aBlob[2] = {0xff, 0xff};
sqlite3_bind_int(pIdxSelect, 1, iSegid);
sqlite3_bind_blob(pIdxSelect, 2, aBlob, 2, SQLITE_STATIC);
assert_nc( sqlite3_step(pIdxSelect)!=SQLITE_ROW );
p->rc = sqlite3_reset(pIdxSelect);
sqlite3_bind_null(pIdxSelect, 2);
}
}
#endif
}
}
return iSegid;
}
/*
** Discard all data currently cached in the hash-tables.
*/
static void fts5IndexDiscardData(Fts5Index *p){
assert( p->pHash || p->nPendingData==0 );
if( p->pHash ){
sqlite3Fts5HashClear(p->pHash);
p->nPendingData = 0;
}
}
/*
** Return the size of the prefix, in bytes, that buffer
** (pNew/<length-unknown>) shares with buffer (pOld/nOld).
**
** Buffer (pNew/<length-unknown>) is guaranteed to be greater
** than buffer (pOld/nOld).
*/
static int fts5PrefixCompress(int nOld, const u8 *pOld, const u8 *pNew){
int i;
for(i=0; i<nOld; i++){
if( pOld[i]!=pNew[i] ) break;
}
return i;
}
static void fts5WriteDlidxClear(
Fts5Index *p,
Fts5SegWriter *pWriter,
int bFlush /* If true, write dlidx to disk */
){
int i;
assert( bFlush==0 || (pWriter->nDlidx>0 && pWriter->aDlidx[0].buf.n>0) );
for(i=0; i<pWriter->nDlidx; i++){
Fts5DlidxWriter *pDlidx = &pWriter->aDlidx[i];
if( pDlidx->buf.n==0 ) break;
if( bFlush ){
assert( pDlidx->pgno!=0 );
fts5DataWrite(p,
FTS5_DLIDX_ROWID(pWriter->iSegid, i, pDlidx->pgno),
pDlidx->buf.p, pDlidx->buf.n
);
}
sqlite3Fts5BufferZero(&pDlidx->buf);
pDlidx->bPrevValid = 0;
}
}
/*
** Grow the pWriter->aDlidx[] array to at least nLvl elements in size.
** Any new array elements are zeroed before returning.
*/
static int fts5WriteDlidxGrow(
Fts5Index *p,
Fts5SegWriter *pWriter,
int nLvl
){
if( p->rc==SQLITE_OK && nLvl>=pWriter->nDlidx ){
Fts5DlidxWriter *aDlidx = (Fts5DlidxWriter*)sqlite3_realloc64(
pWriter->aDlidx, sizeof(Fts5DlidxWriter) * nLvl
);
if( aDlidx==0 ){
p->rc = SQLITE_NOMEM;
}else{
size_t nByte = sizeof(Fts5DlidxWriter) * (nLvl - pWriter->nDlidx);
memset(&aDlidx[pWriter->nDlidx], 0, nByte);
pWriter->aDlidx = aDlidx;
pWriter->nDlidx = nLvl;
}
}
return p->rc;
}
/*
** If the current doclist-index accumulating in pWriter->aDlidx[] is large
** enough, flush it to disk and return 1. Otherwise discard it and return
** zero.
*/
static int fts5WriteFlushDlidx(Fts5Index *p, Fts5SegWriter *pWriter){
int bFlag = 0;
/* If there were FTS5_MIN_DLIDX_SIZE or more empty leaf pages written
** to the database, also write the doclist-index to disk. */
if( pWriter->aDlidx[0].buf.n>0 && pWriter->nEmpty>=FTS5_MIN_DLIDX_SIZE ){
bFlag = 1;
}
fts5WriteDlidxClear(p, pWriter, bFlag);
pWriter->nEmpty = 0;
return bFlag;
}
/*
** This function is called whenever processing of the doclist for the
** last term on leaf page (pWriter->iBtPage) is completed.
**
** The doclist-index for that term is currently stored in-memory within the
** Fts5SegWriter.aDlidx[] array. If it is large enough, this function
** writes it out to disk. Or, if it is too small to bother with, discards
** it.
**
** Fts5SegWriter.btterm currently contains the first term on page iBtPage.
*/
static void fts5WriteFlushBtree(Fts5Index *p, Fts5SegWriter *pWriter){
int bFlag;
assert( pWriter->iBtPage || pWriter->nEmpty==0 );
if( pWriter->iBtPage==0 ) return;
bFlag = fts5WriteFlushDlidx(p, pWriter);
if( p->rc==SQLITE_OK ){
const char *z = (pWriter->btterm.n>0?(const char*)pWriter->btterm.p:"");
/* The following was already done in fts5WriteInit(): */
/* sqlite3_bind_int(p->pIdxWriter, 1, pWriter->iSegid); */
sqlite3_bind_blob(p->pIdxWriter, 2, z, pWriter->btterm.n, SQLITE_STATIC);
sqlite3_bind_int64(p->pIdxWriter, 3, bFlag + ((i64)pWriter->iBtPage<<1));
sqlite3_step(p->pIdxWriter);
p->rc = sqlite3_reset(p->pIdxWriter);
sqlite3_bind_null(p->pIdxWriter, 2);
}
pWriter->iBtPage = 0;
}
/*
** This is called once for each leaf page except the first that contains
** at least one term. Argument (nTerm/pTerm) is the split-key - a term that
** is larger than all terms written to earlier leaves, and equal to or
** smaller than the first term on the new leaf.
**
** If an error occurs, an error code is left in Fts5Index.rc. If an error
** has already occurred when this function is called, it is a no-op.
*/
static void fts5WriteBtreeTerm(
Fts5Index *p, /* FTS5 backend object */
Fts5SegWriter *pWriter, /* Writer object */
int nTerm, const u8 *pTerm /* First term on new page */
){
fts5WriteFlushBtree(p, pWriter);
if( p->rc==SQLITE_OK ){
fts5BufferSet(&p->rc, &pWriter->btterm, nTerm, pTerm);
pWriter->iBtPage = pWriter->writer.pgno;
}
}
/*
** This function is called when flushing a leaf page that contains no
** terms at all to disk.
*/
static void fts5WriteBtreeNoTerm(
Fts5Index *p, /* FTS5 backend object */
Fts5SegWriter *pWriter /* Writer object */
){
/* If there were no rowids on the leaf page either and the doclist-index
** has already been started, append an 0x00 byte to it. */
if( pWriter->bFirstRowidInPage && pWriter->aDlidx[0].buf.n>0 ){
Fts5DlidxWriter *pDlidx = &pWriter->aDlidx[0];
assert( pDlidx->bPrevValid );
sqlite3Fts5BufferAppendVarint(&p->rc, &pDlidx->buf, 0);
}
/* Increment the "number of sequential leaves without a term" counter. */
pWriter->nEmpty++;
}
static i64 fts5DlidxExtractFirstRowid(Fts5Buffer *pBuf){
i64 iRowid;
int iOff;
iOff = 1 + fts5GetVarint(&pBuf->p[1], (u64*)&iRowid);
fts5GetVarint(&pBuf->p[iOff], (u64*)&iRowid);
return iRowid;
}
/*
** Rowid iRowid has just been appended to the current leaf page. It is the
** first on the page. This function appends an appropriate entry to the current
** doclist-index.
*/
static void fts5WriteDlidxAppend(
Fts5Index *p,
Fts5SegWriter *pWriter,
i64 iRowid
){
int i;
int bDone = 0;
for(i=0; p->rc==SQLITE_OK && bDone==0; i++){
i64 iVal;
Fts5DlidxWriter *pDlidx = &pWriter->aDlidx[i];
if( pDlidx->buf.n>=p->pConfig->pgsz ){
/* The current doclist-index page is full. Write it to disk and push
** a copy of iRowid (which will become the first rowid on the next
** doclist-index leaf page) up into the next level of the b-tree
** hierarchy. If the node being flushed is currently the root node,
** also push its first rowid upwards. */
pDlidx->buf.p[0] = 0x01; /* Not the root node */
fts5DataWrite(p,
FTS5_DLIDX_ROWID(pWriter->iSegid, i, pDlidx->pgno),
pDlidx->buf.p, pDlidx->buf.n
);
fts5WriteDlidxGrow(p, pWriter, i+2);
pDlidx = &pWriter->aDlidx[i];
if( p->rc==SQLITE_OK && pDlidx[1].buf.n==0 ){
i64 iFirst = fts5DlidxExtractFirstRowid(&pDlidx->buf);
/* This was the root node. Push its first rowid up to the new root. */
pDlidx[1].pgno = pDlidx->pgno;
sqlite3Fts5BufferAppendVarint(&p->rc, &pDlidx[1].buf, 0);
sqlite3Fts5BufferAppendVarint(&p->rc, &pDlidx[1].buf, pDlidx->pgno);
sqlite3Fts5BufferAppendVarint(&p->rc, &pDlidx[1].buf, iFirst);
pDlidx[1].bPrevValid = 1;
pDlidx[1].iPrev = iFirst;
}
sqlite3Fts5BufferZero(&pDlidx->buf);
pDlidx->bPrevValid = 0;
pDlidx->pgno++;
}else{
bDone = 1;
}
if( pDlidx->bPrevValid ){
iVal = iRowid - pDlidx->iPrev;
}else{
i64 iPgno = (i==0 ? pWriter->writer.pgno : pDlidx[-1].pgno);
assert( pDlidx->buf.n==0 );
sqlite3Fts5BufferAppendVarint(&p->rc, &pDlidx->buf, !bDone);
sqlite3Fts5BufferAppendVarint(&p->rc, &pDlidx->buf, iPgno);
iVal = iRowid;
}
sqlite3Fts5BufferAppendVarint(&p->rc, &pDlidx->buf, iVal);
pDlidx->bPrevValid = 1;
pDlidx->iPrev = iRowid;
}
}
static void fts5WriteFlushLeaf(Fts5Index *p, Fts5SegWriter *pWriter){
static const u8 zero[] = { 0x00, 0x00, 0x00, 0x00 };
Fts5PageWriter *pPage = &pWriter->writer;
i64 iRowid;
assert( (pPage->pgidx.n==0)==(pWriter->bFirstTermInPage) );
/* Set the szLeaf header field. */
assert( 0==fts5GetU16(&pPage->buf.p[2]) );
fts5PutU16(&pPage->buf.p[2], (u16)pPage->buf.n);
if( pWriter->bFirstTermInPage ){
/* No term was written to this page. */
assert( pPage->pgidx.n==0 );
fts5WriteBtreeNoTerm(p, pWriter);
}else{
/* Append the pgidx to the page buffer. Set the szLeaf header field. */
fts5BufferAppendBlob(&p->rc, &pPage->buf, pPage->pgidx.n, pPage->pgidx.p);
}
/* Write the page out to disk */
iRowid = FTS5_SEGMENT_ROWID(pWriter->iSegid, pPage->pgno);
fts5DataWrite(p, iRowid, pPage->buf.p, pPage->buf.n);
/* Initialize the next page. */
fts5BufferZero(&pPage->buf);
fts5BufferZero(&pPage->pgidx);
fts5BufferAppendBlob(&p->rc, &pPage->buf, 4, zero);
pPage->iPrevPgidx = 0;
pPage->pgno++;
/* Increase the leaves written counter */
pWriter->nLeafWritten++;
/* The new leaf holds no terms or rowids */
pWriter->bFirstTermInPage = 1;
pWriter->bFirstRowidInPage = 1;
}
/*
** Append term pTerm/nTerm to the segment being written by the writer passed
** as the second argument.
**
** If an error occurs, set the Fts5Index.rc error code. If an error has
** already occurred, this function is a no-op.
*/
static void fts5WriteAppendTerm(
Fts5Index *p,
Fts5SegWriter *pWriter,
int nTerm, const u8 *pTerm
){
int nPrefix; /* Bytes of prefix compression for term */
Fts5PageWriter *pPage = &pWriter->writer;
Fts5Buffer *pPgidx = &pWriter->writer.pgidx;
int nMin = MIN(pPage->term.n, nTerm);
assert( p->rc==SQLITE_OK );
assert( pPage->buf.n>=4 );
assert( pPage->buf.n>4 || pWriter->bFirstTermInPage );
/* If the current leaf page is full, flush it to disk. */
if( (pPage->buf.n + pPgidx->n + nTerm + 2)>=p->pConfig->pgsz ){
if( pPage->buf.n>4 ){
fts5WriteFlushLeaf(p, pWriter);
if( p->rc!=SQLITE_OK ) return;
}
fts5BufferGrow(&p->rc, &pPage->buf, nTerm+FTS5_DATA_PADDING);
}
/* TODO1: Updating pgidx here. */
pPgidx->n += sqlite3Fts5PutVarint(
&pPgidx->p[pPgidx->n], pPage->buf.n - pPage->iPrevPgidx
);
pPage->iPrevPgidx = pPage->buf.n;
#if 0
fts5PutU16(&pPgidx->p[pPgidx->n], pPage->buf.n);
pPgidx->n += 2;
#endif
if( pWriter->bFirstTermInPage ){
nPrefix = 0;
if( pPage->pgno!=1 ){
/* This is the first term on a leaf that is not the leftmost leaf in
** the segment b-tree. In this case it is necessary to add a term to
** the b-tree hierarchy that is (a) larger than the largest term
** already written to the segment and (b) smaller than or equal to
** this term. In other words, a prefix of (pTerm/nTerm) that is one
** byte longer than the longest prefix (pTerm/nTerm) shares with the
** previous term.
**
** Usually, the previous term is available in pPage->term. The exception
** is if this is the first term written in an incremental-merge step.
** In this case the previous term is not available, so just write a
** copy of (pTerm/nTerm) into the parent node. This is slightly
** inefficient, but still correct. */
int n = nTerm;
if( pPage->term.n ){
n = 1 + fts5PrefixCompress(nMin, pPage->term.p, pTerm);
}
fts5WriteBtreeTerm(p, pWriter, n, pTerm);
if( p->rc!=SQLITE_OK ) return;
pPage = &pWriter->writer;
}
}else{
nPrefix = fts5PrefixCompress(nMin, pPage->term.p, pTerm);
fts5BufferAppendVarint(&p->rc, &pPage->buf, nPrefix);
}
/* Append the number of bytes of new data, then the term data itself
** to the page. */
fts5BufferAppendVarint(&p->rc, &pPage->buf, nTerm - nPrefix);
fts5BufferAppendBlob(&p->rc, &pPage->buf, nTerm - nPrefix, &pTerm[nPrefix]);
/* Update the Fts5PageWriter.term field. */
fts5BufferSet(&p->rc, &pPage->term, nTerm, pTerm);
pWriter->bFirstTermInPage = 0;
pWriter->bFirstRowidInPage = 0;
pWriter->bFirstRowidInDoclist = 1;
assert( p->rc || (pWriter->nDlidx>0 && pWriter->aDlidx[0].buf.n==0) );
pWriter->aDlidx[0].pgno = pPage->pgno;
}
/*
** Append a rowid and position-list size field to the writers output.
*/
static void fts5WriteAppendRowid(
Fts5Index *p,
Fts5SegWriter *pWriter,
i64 iRowid
){
if( p->rc==SQLITE_OK ){
Fts5PageWriter *pPage = &pWriter->writer;
if( (pPage->buf.n + pPage->pgidx.n)>=p->pConfig->pgsz ){
fts5WriteFlushLeaf(p, pWriter);
}
/* If this is to be the first rowid written to the page, set the
** rowid-pointer in the page-header. Also append a value to the dlidx
** buffer, in case a doclist-index is required. */
if( pWriter->bFirstRowidInPage ){
fts5PutU16(pPage->buf.p, (u16)pPage->buf.n);
fts5WriteDlidxAppend(p, pWriter, iRowid);
}
/* Write the rowid. */
if( pWriter->bFirstRowidInDoclist || pWriter->bFirstRowidInPage ){
fts5BufferAppendVarint(&p->rc, &pPage->buf, iRowid);
}else{
assert_nc( p->rc || iRowid>pWriter->iPrevRowid );
fts5BufferAppendVarint(&p->rc, &pPage->buf, iRowid - pWriter->iPrevRowid);
}
pWriter->iPrevRowid = iRowid;
pWriter->bFirstRowidInDoclist = 0;
pWriter->bFirstRowidInPage = 0;
}
}
static void fts5WriteAppendPoslistData(
Fts5Index *p,
Fts5SegWriter *pWriter,
const u8 *aData,
int nData
){
Fts5PageWriter *pPage = &pWriter->writer;
const u8 *a = aData;
int n = nData;
assert( p->pConfig->pgsz>0 );
while( p->rc==SQLITE_OK
&& (pPage->buf.n + pPage->pgidx.n + n)>=p->pConfig->pgsz
){
int nReq = p->pConfig->pgsz - pPage->buf.n - pPage->pgidx.n;
int nCopy = 0;
while( nCopy<nReq ){
i64 dummy;
nCopy += fts5GetVarint(&a[nCopy], (u64*)&dummy);
}
fts5BufferAppendBlob(&p->rc, &pPage->buf, nCopy, a);
a += nCopy;
n -= nCopy;
fts5WriteFlushLeaf(p, pWriter);
}
if( n>0 ){
fts5BufferAppendBlob(&p->rc, &pPage->buf, n, a);
}
}
/*
** Flush any data cached by the writer object to the database. Free any
** allocations associated with the writer.
*/
static void fts5WriteFinish(
Fts5Index *p,
Fts5SegWriter *pWriter, /* Writer object */
int *pnLeaf /* OUT: Number of leaf pages in b-tree */
){
int i;
Fts5PageWriter *pLeaf = &pWriter->writer;
if( p->rc==SQLITE_OK ){
assert( pLeaf->pgno>=1 );
if( pLeaf->buf.n>4 ){
fts5WriteFlushLeaf(p, pWriter);
}
*pnLeaf = pLeaf->pgno-1;
if( pLeaf->pgno>1 ){
fts5WriteFlushBtree(p, pWriter);
}
}
fts5BufferFree(&pLeaf->term);
fts5BufferFree(&pLeaf->buf);
fts5BufferFree(&pLeaf->pgidx);
fts5BufferFree(&pWriter->btterm);
for(i=0; i<pWriter->nDlidx; i++){
sqlite3Fts5BufferFree(&pWriter->aDlidx[i].buf);
}
sqlite3_free(pWriter->aDlidx);
}
static void fts5WriteInit(
Fts5Index *p,
Fts5SegWriter *pWriter,
int iSegid
){
const int nBuffer = p->pConfig->pgsz + FTS5_DATA_PADDING;
memset(pWriter, 0, sizeof(Fts5SegWriter));
pWriter->iSegid = iSegid;
fts5WriteDlidxGrow(p, pWriter, 1);
pWriter->writer.pgno = 1;
pWriter->bFirstTermInPage = 1;
pWriter->iBtPage = 1;
assert( pWriter->writer.buf.n==0 );
assert( pWriter->writer.pgidx.n==0 );
/* Grow the two buffers to pgsz + padding bytes in size. */
sqlite3Fts5BufferSize(&p->rc, &pWriter->writer.pgidx, nBuffer);
sqlite3Fts5BufferSize(&p->rc, &pWriter->writer.buf, nBuffer);
if( p->pIdxWriter==0 ){
Fts5Config *pConfig = p->pConfig;
fts5IndexPrepareStmt(p, &p->pIdxWriter, sqlite3_mprintf(
"INSERT INTO '%q'.'%q_idx'(segid,term,pgno) VALUES(?,?,?)",
pConfig->zDb, pConfig->zName
));
}
if( p->rc==SQLITE_OK ){
/* Initialize the 4-byte leaf-page header to 0x00. */
memset(pWriter->writer.buf.p, 0, 4);
pWriter->writer.buf.n = 4;
/* Bind the current output segment id to the index-writer. This is an
** optimization over binding the same value over and over as rows are
** inserted into %_idx by the current writer. */
sqlite3_bind_int(p->pIdxWriter, 1, pWriter->iSegid);
}
}
/*
** Iterator pIter was used to iterate through the input segments of on an
** incremental merge operation. This function is called if the incremental
** merge step has finished but the input has not been completely exhausted.
*/
static void fts5TrimSegments(Fts5Index *p, Fts5Iter *pIter){
int i;
Fts5Buffer buf;
memset(&buf, 0, sizeof(Fts5Buffer));
for(i=0; i<pIter->nSeg && p->rc==SQLITE_OK; i++){
Fts5SegIter *pSeg = &pIter->aSeg[i];
if( pSeg->pSeg==0 ){
/* no-op */
}else if( pSeg->pLeaf==0 ){
/* All keys from this input segment have been transfered to the output.
** Set both the first and last page-numbers to 0 to indicate that the
** segment is now empty. */
pSeg->pSeg->pgnoLast = 0;
pSeg->pSeg->pgnoFirst = 0;
}else{
int iOff = pSeg->iTermLeafOffset; /* Offset on new first leaf page */
i64 iLeafRowid;
Fts5Data *pData;
int iId = pSeg->pSeg->iSegid;
u8 aHdr[4] = {0x00, 0x00, 0x00, 0x00};
iLeafRowid = FTS5_SEGMENT_ROWID(iId, pSeg->iTermLeafPgno);
pData = fts5LeafRead(p, iLeafRowid);
if( pData ){
if( iOff>pData->szLeaf ){
/* This can occur if the pages that the segments occupy overlap - if
** a single page has been assigned to more than one segment. In
** this case a prior iteration of this loop may have corrupted the
** segment currently being trimmed. */
p->rc = FTS5_CORRUPT;
}else{
fts5BufferZero(&buf);
fts5BufferGrow(&p->rc, &buf, pData->nn);
fts5BufferAppendBlob(&p->rc, &buf, sizeof(aHdr), aHdr);
fts5BufferAppendVarint(&p->rc, &buf, pSeg->term.n);
fts5BufferAppendBlob(&p->rc, &buf, pSeg->term.n, pSeg->term.p);
fts5BufferAppendBlob(&p->rc, &buf, pData->szLeaf-iOff,&pData->p[iOff]);
if( p->rc==SQLITE_OK ){
/* Set the szLeaf field */
fts5PutU16(&buf.p[2], (u16)buf.n);
}
/* Set up the new page-index array */
fts5BufferAppendVarint(&p->rc, &buf, 4);
if( pSeg->iLeafPgno==pSeg->iTermLeafPgno
&& pSeg->iEndofDoclist<pData->szLeaf
&& pSeg->iPgidxOff<=pData->nn
){
int nDiff = pData->szLeaf - pSeg->iEndofDoclist;
fts5BufferAppendVarint(&p->rc, &buf, buf.n - 1 - nDiff - 4);
fts5BufferAppendBlob(&p->rc, &buf,
pData->nn - pSeg->iPgidxOff, &pData->p[pSeg->iPgidxOff]
);
}
pSeg->pSeg->pgnoFirst = pSeg->iTermLeafPgno;
fts5DataDelete(p, FTS5_SEGMENT_ROWID(iId, 1), iLeafRowid);
fts5DataWrite(p, iLeafRowid, buf.p, buf.n);
}
fts5DataRelease(pData);
}
}
}
fts5BufferFree(&buf);
}
static void fts5MergeChunkCallback(
Fts5Index *p,
void *pCtx,
const u8 *pChunk, int nChunk
){
Fts5SegWriter *pWriter = (Fts5SegWriter*)pCtx;
fts5WriteAppendPoslistData(p, pWriter, pChunk, nChunk);
}
/*
**
*/
static void fts5IndexMergeLevel(
Fts5Index *p, /* FTS5 backend object */
Fts5Structure **ppStruct, /* IN/OUT: Stucture of index */
int iLvl, /* Level to read input from */
int *pnRem /* Write up to this many output leaves */
){
Fts5Structure *pStruct = *ppStruct;
Fts5StructureLevel *pLvl = &pStruct->aLevel[iLvl];
Fts5StructureLevel *pLvlOut;
Fts5Iter *pIter = 0; /* Iterator to read input data */
int nRem = pnRem ? *pnRem : 0; /* Output leaf pages left to write */
int nInput; /* Number of input segments */
Fts5SegWriter writer; /* Writer object */
Fts5StructureSegment *pSeg; /* Output segment */
Fts5Buffer term;
int bOldest; /* True if the output segment is the oldest */
int eDetail = p->pConfig->eDetail;
const int flags = FTS5INDEX_QUERY_NOOUTPUT;
int bTermWritten = 0; /* True if current term already output */
assert( iLvl<pStruct->nLevel );
assert( pLvl->nMerge<=pLvl->nSeg );
memset(&writer, 0, sizeof(Fts5SegWriter));
memset(&term, 0, sizeof(Fts5Buffer));
if( pLvl->nMerge ){
pLvlOut = &pStruct->aLevel[iLvl+1];
assert( pLvlOut->nSeg>0 );
nInput = pLvl->nMerge;
pSeg = &pLvlOut->aSeg[pLvlOut->nSeg-1];
fts5WriteInit(p, &writer, pSeg->iSegid);
writer.writer.pgno = pSeg->pgnoLast+1;
writer.iBtPage = 0;
}else{
int iSegid = fts5AllocateSegid(p, pStruct);
/* Extend the Fts5Structure object as required to ensure the output
** segment exists. */
if( iLvl==pStruct->nLevel-1 ){
fts5StructureAddLevel(&p->rc, ppStruct);
pStruct = *ppStruct;
}
fts5StructureExtendLevel(&p->rc, pStruct, iLvl+1, 1, 0);
if( p->rc ) return;
pLvl = &pStruct->aLevel[iLvl];
pLvlOut = &pStruct->aLevel[iLvl+1];
fts5WriteInit(p, &writer, iSegid);
/* Add the new segment to the output level */
pSeg = &pLvlOut->aSeg[pLvlOut->nSeg];
pLvlOut->nSeg++;
pSeg->pgnoFirst = 1;
pSeg->iSegid = iSegid;
pStruct->nSegment++;
/* Read input from all segments in the input level */
nInput = pLvl->nSeg;
}
bOldest = (pLvlOut->nSeg==1 && pStruct->nLevel==iLvl+2);
assert( iLvl>=0 );
for(fts5MultiIterNew(p, pStruct, flags, 0, 0, 0, iLvl, nInput, &pIter);
fts5MultiIterEof(p, pIter)==0;
fts5MultiIterNext(p, pIter, 0, 0)
){
Fts5SegIter *pSegIter = &pIter->aSeg[ pIter->aFirst[1].iFirst ];
int nPos; /* position-list size field value */
int nTerm;
const u8 *pTerm;
pTerm = fts5MultiIterTerm(pIter, &nTerm);
if( nTerm!=term.n || fts5Memcmp(pTerm, term.p, nTerm) ){
if( pnRem && writer.nLeafWritten>nRem ){
break;
}
fts5BufferSet(&p->rc, &term, nTerm, pTerm);
bTermWritten =0;
}
/* Check for key annihilation. */
if( pSegIter->nPos==0 && (bOldest || pSegIter->bDel==0) ) continue;
if( p->rc==SQLITE_OK && bTermWritten==0 ){
/* This is a new term. Append a term to the output segment. */
fts5WriteAppendTerm(p, &writer, nTerm, pTerm);
bTermWritten = 1;
}
/* Append the rowid to the output */
/* WRITEPOSLISTSIZE */
fts5WriteAppendRowid(p, &writer, fts5MultiIterRowid(pIter));
if( eDetail==FTS5_DETAIL_NONE ){
if( pSegIter->bDel ){
fts5BufferAppendVarint(&p->rc, &writer.writer.buf, 0);
if( pSegIter->nPos>0 ){
fts5BufferAppendVarint(&p->rc, &writer.writer.buf, 0);
}
}
}else{
/* Append the position-list data to the output */
nPos = pSegIter->nPos*2 + pSegIter->bDel;
fts5BufferAppendVarint(&p->rc, &writer.writer.buf, nPos);
fts5ChunkIterate(p, pSegIter, (void*)&writer, fts5MergeChunkCallback);
}
}
/* Flush the last leaf page to disk. Set the output segment b-tree height
** and last leaf page number at the same time. */
fts5WriteFinish(p, &writer, &pSeg->pgnoLast);
if( fts5MultiIterEof(p, pIter) ){
int i;
/* Remove the redundant segments from the %_data table */
for(i=0; i<nInput; i++){
fts5DataRemoveSegment(p, pLvl->aSeg[i].iSegid);
}
/* Remove the redundant segments from the input level */
if( pLvl->nSeg!=nInput ){
int nMove = (pLvl->nSeg - nInput) * sizeof(Fts5StructureSegment);
memmove(pLvl->aSeg, &pLvl->aSeg[nInput], nMove);
}
pStruct->nSegment -= nInput;
pLvl->nSeg -= nInput;
pLvl->nMerge = 0;
if( pSeg->pgnoLast==0 ){
pLvlOut->nSeg--;
pStruct->nSegment--;
}
}else{
assert( pSeg->pgnoLast>0 );
fts5TrimSegments(p, pIter);
pLvl->nMerge = nInput;
}
fts5MultiIterFree(pIter);
fts5BufferFree(&term);
if( pnRem ) *pnRem -= writer.nLeafWritten;
}
/*
** Do up to nPg pages of automerge work on the index.
**
** Return true if any changes were actually made, or false otherwise.
*/
static int fts5IndexMerge(
Fts5Index *p, /* FTS5 backend object */
Fts5Structure **ppStruct, /* IN/OUT: Current structure of index */
int nPg, /* Pages of work to do */
int nMin /* Minimum number of segments to merge */
){
int nRem = nPg;
int bRet = 0;
Fts5Structure *pStruct = *ppStruct;
while( nRem>0 && p->rc==SQLITE_OK ){
int iLvl; /* To iterate through levels */
int iBestLvl = 0; /* Level offering the most input segments */
int nBest = 0; /* Number of input segments on best level */
/* Set iBestLvl to the level to read input segments from. */
assert( pStruct->nLevel>0 );
for(iLvl=0; iLvl<pStruct->nLevel; iLvl++){
Fts5StructureLevel *pLvl = &pStruct->aLevel[iLvl];
if( pLvl->nMerge ){
if( pLvl->nMerge>nBest ){
iBestLvl = iLvl;
nBest = pLvl->nMerge;
}
break;
}
if( pLvl->nSeg>nBest ){
nBest = pLvl->nSeg;
iBestLvl = iLvl;
}
}
/* If nBest is still 0, then the index must be empty. */
#ifdef SQLITE_DEBUG
for(iLvl=0; nBest==0 && iLvl<pStruct->nLevel; iLvl++){
assert( pStruct->aLevel[iLvl].nSeg==0 );
}
#endif
if( nBest<nMin && pStruct->aLevel[iBestLvl].nMerge==0 ){
break;
}
bRet = 1;
fts5IndexMergeLevel(p, &pStruct, iBestLvl, &nRem);
if( p->rc==SQLITE_OK && pStruct->aLevel[iBestLvl].nMerge==0 ){
fts5StructurePromote(p, iBestLvl+1, pStruct);
}
}
*ppStruct = pStruct;
return bRet;
}
/*
** A total of nLeaf leaf pages of data has just been flushed to a level-0
** segment. This function updates the write-counter accordingly and, if
** necessary, performs incremental merge work.
**
** If an error occurs, set the Fts5Index.rc error code. If an error has
** already occurred, this function is a no-op.
*/
static void fts5IndexAutomerge(
Fts5Index *p, /* FTS5 backend object */
Fts5Structure **ppStruct, /* IN/OUT: Current structure of index */
int nLeaf /* Number of output leaves just written */
){
if( p->rc==SQLITE_OK && p->pConfig->nAutomerge>0 ){
Fts5Structure *pStruct = *ppStruct;
u64 nWrite; /* Initial value of write-counter */
int nWork; /* Number of work-quanta to perform */
int nRem; /* Number of leaf pages left to write */
/* Update the write-counter. While doing so, set nWork. */
nWrite = pStruct->nWriteCounter;
nWork = (int)(((nWrite + nLeaf) / p->nWorkUnit) - (nWrite / p->nWorkUnit));
pStruct->nWriteCounter += nLeaf;
nRem = (int)(p->nWorkUnit * nWork * pStruct->nLevel);
fts5IndexMerge(p, ppStruct, nRem, p->pConfig->nAutomerge);
}
}
static void fts5IndexCrisismerge(
Fts5Index *p, /* FTS5 backend object */
Fts5Structure **ppStruct /* IN/OUT: Current structure of index */
){
const int nCrisis = p->pConfig->nCrisisMerge;
Fts5Structure *pStruct = *ppStruct;
int iLvl = 0;
assert( p->rc!=SQLITE_OK || pStruct->nLevel>0 );
while( p->rc==SQLITE_OK && pStruct->aLevel[iLvl].nSeg>=nCrisis ){
fts5IndexMergeLevel(p, &pStruct, iLvl, 0);
assert( p->rc!=SQLITE_OK || pStruct->nLevel>(iLvl+1) );
fts5StructurePromote(p, iLvl+1, pStruct);
iLvl++;
}
*ppStruct = pStruct;
}
static int fts5IndexReturn(Fts5Index *p){
int rc = p->rc;
p->rc = SQLITE_OK;
return rc;
}
typedef struct Fts5FlushCtx Fts5FlushCtx;
struct Fts5FlushCtx {
Fts5Index *pIdx;
Fts5SegWriter writer;
};
/*
** Buffer aBuf[] contains a list of varints, all small enough to fit
** in a 32-bit integer. Return the size of the largest prefix of this
** list nMax bytes or less in size.
*/
static int fts5PoslistPrefix(const u8 *aBuf, int nMax){
int ret;
u32 dummy;
ret = fts5GetVarint32(aBuf, dummy);
if( ret<nMax ){
while( 1 ){
int i = fts5GetVarint32(&aBuf[ret], dummy);
if( (ret + i) > nMax ) break;
ret += i;
}
}
return ret;
}
/*
** Flush the contents of in-memory hash table iHash to a new level-0
** segment on disk. Also update the corresponding structure record.
**
** If an error occurs, set the Fts5Index.rc error code. If an error has
** already occurred, this function is a no-op.
*/
static void fts5FlushOneHash(Fts5Index *p){
Fts5Hash *pHash = p->pHash;
Fts5Structure *pStruct;
int iSegid;
int pgnoLast = 0; /* Last leaf page number in segment */
/* Obtain a reference to the index structure and allocate a new segment-id
** for the new level-0 segment. */
pStruct = fts5StructureRead(p);
iSegid = fts5AllocateSegid(p, pStruct);
fts5StructureInvalidate(p);
if( iSegid ){
const int pgsz = p->pConfig->pgsz;
int eDetail = p->pConfig->eDetail;
Fts5StructureSegment *pSeg; /* New segment within pStruct */
Fts5Buffer *pBuf; /* Buffer in which to assemble leaf page */
Fts5Buffer *pPgidx; /* Buffer in which to assemble pgidx */
Fts5SegWriter writer;
fts5WriteInit(p, &writer, iSegid);
pBuf = &writer.writer.buf;
pPgidx = &writer.writer.pgidx;
/* fts5WriteInit() should have initialized the buffers to (most likely)
** the maximum space required. */
assert( p->rc || pBuf->nSpace>=(pgsz + FTS5_DATA_PADDING) );
assert( p->rc || pPgidx->nSpace>=(pgsz + FTS5_DATA_PADDING) );
/* Begin scanning through hash table entries. This loop runs once for each
** term/doclist currently stored within the hash table. */
if( p->rc==SQLITE_OK ){
p->rc = sqlite3Fts5HashScanInit(pHash, 0, 0);
}
while( p->rc==SQLITE_OK && 0==sqlite3Fts5HashScanEof(pHash) ){
const char *zTerm; /* Buffer containing term */
const u8 *pDoclist; /* Pointer to doclist for this term */
int nDoclist; /* Size of doclist in bytes */
/* Write the term for this entry to disk. */
sqlite3Fts5HashScanEntry(pHash, &zTerm, &pDoclist, &nDoclist);
fts5WriteAppendTerm(p, &writer, (int)strlen(zTerm), (const u8*)zTerm);
if( p->rc!=SQLITE_OK ) break;
assert( writer.bFirstRowidInPage==0 );
if( pgsz>=(pBuf->n + pPgidx->n + nDoclist + 1) ){
/* The entire doclist will fit on the current leaf. */
fts5BufferSafeAppendBlob(pBuf, pDoclist, nDoclist);
}else{
i64 iRowid = 0;
i64 iDelta = 0;
int iOff = 0;
/* The entire doclist will not fit on this leaf. The following
** loop iterates through the poslists that make up the current
** doclist. */
while( p->rc==SQLITE_OK && iOff<nDoclist ){
iOff += fts5GetVarint(&pDoclist[iOff], (u64*)&iDelta);
iRowid += iDelta;
if( writer.bFirstRowidInPage ){
fts5PutU16(&pBuf->p[0], (u16)pBuf->n); /* first rowid on page */
pBuf->n += sqlite3Fts5PutVarint(&pBuf->p[pBuf->n], iRowid);
writer.bFirstRowidInPage = 0;
fts5WriteDlidxAppend(p, &writer, iRowid);
if( p->rc!=SQLITE_OK ) break;
}else{
pBuf->n += sqlite3Fts5PutVarint(&pBuf->p[pBuf->n], iDelta);
}
assert( pBuf->n<=pBuf->nSpace );
if( eDetail==FTS5_DETAIL_NONE ){
if( iOff<nDoclist && pDoclist[iOff]==0 ){
pBuf->p[pBuf->n++] = 0;
iOff++;
if( iOff<nDoclist && pDoclist[iOff]==0 ){
pBuf->p[pBuf->n++] = 0;
iOff++;
}
}
if( (pBuf->n + pPgidx->n)>=pgsz ){
fts5WriteFlushLeaf(p, &writer);
}
}else{
int bDummy;
int nPos;
int nCopy = fts5GetPoslistSize(&pDoclist[iOff], &nPos, &bDummy);
nCopy += nPos;
if( (pBuf->n + pPgidx->n + nCopy) <= pgsz ){
/* The entire poslist will fit on the current leaf. So copy
** it in one go. */
fts5BufferSafeAppendBlob(pBuf, &pDoclist[iOff], nCopy);
}else{
/* The entire poslist will not fit on this leaf. So it needs
** to be broken into sections. The only qualification being
** that each varint must be stored contiguously. */
const u8 *pPoslist = &pDoclist[iOff];
int iPos = 0;
while( p->rc==SQLITE_OK ){
int nSpace = pgsz - pBuf->n - pPgidx->n;
int n = 0;
if( (nCopy - iPos)<=nSpace ){
n = nCopy - iPos;
}else{
n = fts5PoslistPrefix(&pPoslist[iPos], nSpace);
}
assert( n>0 );
fts5BufferSafeAppendBlob(pBuf, &pPoslist[iPos], n);
iPos += n;
if( (pBuf->n + pPgidx->n)>=pgsz ){
fts5WriteFlushLeaf(p, &writer);
}
if( iPos>=nCopy ) break;
}
}
iOff += nCopy;
}
}
}
/* TODO2: Doclist terminator written here. */
/* pBuf->p[pBuf->n++] = '\0'; */
assert( pBuf->n<=pBuf->nSpace );
if( p->rc==SQLITE_OK ) sqlite3Fts5HashScanNext(pHash);
}
sqlite3Fts5HashClear(pHash);
fts5WriteFinish(p, &writer, &pgnoLast);
/* Update the Fts5Structure. It is written back to the database by the
** fts5StructureRelease() call below. */
if( pStruct->nLevel==0 ){
fts5StructureAddLevel(&p->rc, &pStruct);
}
fts5StructureExtendLevel(&p->rc, pStruct, 0, 1, 0);
if( p->rc==SQLITE_OK ){
pSeg = &pStruct->aLevel[0].aSeg[ pStruct->aLevel[0].nSeg++ ];
pSeg->iSegid = iSegid;
pSeg->pgnoFirst = 1;
pSeg->pgnoLast = pgnoLast;
pStruct->nSegment++;
}
fts5StructurePromote(p, 0, pStruct);
}
fts5IndexAutomerge(p, &pStruct, pgnoLast);
fts5IndexCrisismerge(p, &pStruct);
fts5StructureWrite(p, pStruct);
fts5StructureRelease(pStruct);
}
/*
** Flush any data stored in the in-memory hash tables to the database.
*/
static void fts5IndexFlush(Fts5Index *p){
/* Unless it is empty, flush the hash table to disk */
if( p->nPendingData ){
assert( p->pHash );
p->nPendingData = 0;
fts5FlushOneHash(p);
}
}
static Fts5Structure *fts5IndexOptimizeStruct(
Fts5Index *p,
Fts5Structure *pStruct
){
Fts5Structure *pNew = 0;
sqlite3_int64 nByte = sizeof(Fts5Structure);
int nSeg = pStruct->nSegment;
int i;
/* Figure out if this structure requires optimization. A structure does
** not require optimization if either:
**
** + it consists of fewer than two segments, or
** + all segments are on the same level, or
** + all segments except one are currently inputs to a merge operation.
**
** In the first case, return NULL. In the second, increment the ref-count
** on *pStruct and return a copy of the pointer to it.
*/
if( nSeg<2 ) return 0;
for(i=0; i<pStruct->nLevel; i++){
int nThis = pStruct->aLevel[i].nSeg;
if( nThis==nSeg || (nThis==nSeg-1 && pStruct->aLevel[i].nMerge==nThis) ){
fts5StructureRef(pStruct);
return pStruct;
}
assert( pStruct->aLevel[i].nMerge<=nThis );
}
nByte += (pStruct->nLevel+1) * sizeof(Fts5StructureLevel);
pNew = (Fts5Structure*)sqlite3Fts5MallocZero(&p->rc, nByte);
if( pNew ){
Fts5StructureLevel *pLvl;
nByte = nSeg * sizeof(Fts5StructureSegment);
pNew->nLevel = pStruct->nLevel+1;
pNew->nRef = 1;
pNew->nWriteCounter = pStruct->nWriteCounter;
pLvl = &pNew->aLevel[pStruct->nLevel];
pLvl->aSeg = (Fts5StructureSegment*)sqlite3Fts5MallocZero(&p->rc, nByte);
if( pLvl->aSeg ){
int iLvl, iSeg;
int iSegOut = 0;
/* Iterate through all segments, from oldest to newest. Add them to
** the new Fts5Level object so that pLvl->aSeg[0] is the oldest
** segment in the data structure. */
for(iLvl=pStruct->nLevel-1; iLvl>=0; iLvl--){
for(iSeg=0; iSeg<pStruct->aLevel[iLvl].nSeg; iSeg++){
pLvl->aSeg[iSegOut] = pStruct->aLevel[iLvl].aSeg[iSeg];
iSegOut++;
}
}
pNew->nSegment = pLvl->nSeg = nSeg;
}else{
sqlite3_free(pNew);
pNew = 0;
}
}
return pNew;
}
static int sqlite3Fts5IndexOptimize(Fts5Index *p){
Fts5Structure *pStruct;
Fts5Structure *pNew = 0;
assert( p->rc==SQLITE_OK );
fts5IndexFlush(p);
pStruct = fts5StructureRead(p);
fts5StructureInvalidate(p);
if( pStruct ){
pNew = fts5IndexOptimizeStruct(p, pStruct);
}
fts5StructureRelease(pStruct);
assert( pNew==0 || pNew->nSegment>0 );
if( pNew ){
int iLvl;
for(iLvl=0; pNew->aLevel[iLvl].nSeg==0; iLvl++){}
while( p->rc==SQLITE_OK && pNew->aLevel[iLvl].nSeg>0 ){
int nRem = FTS5_OPT_WORK_UNIT;
fts5IndexMergeLevel(p, &pNew, iLvl, &nRem);
}
fts5StructureWrite(p, pNew);
fts5StructureRelease(pNew);
}
return fts5IndexReturn(p);
}
/*
** This is called to implement the special "VALUES('merge', $nMerge)"
** INSERT command.
*/
static int sqlite3Fts5IndexMerge(Fts5Index *p, int nMerge){
Fts5Structure *pStruct = fts5StructureRead(p);
if( pStruct ){
int nMin = p->pConfig->nUsermerge;
fts5StructureInvalidate(p);
if( nMerge<0 ){
Fts5Structure *pNew = fts5IndexOptimizeStruct(p, pStruct);
fts5StructureRelease(pStruct);
pStruct = pNew;
nMin = 2;
nMerge = nMerge*-1;
}
if( pStruct && pStruct->nLevel ){
if( fts5IndexMerge(p, &pStruct, nMerge, nMin) ){
fts5StructureWrite(p, pStruct);
}
}
fts5StructureRelease(pStruct);
}
return fts5IndexReturn(p);
}
static void fts5AppendRowid(
Fts5Index *p,
i64 iDelta,
Fts5Iter *pUnused,
Fts5Buffer *pBuf
){
UNUSED_PARAM(pUnused);
fts5BufferAppendVarint(&p->rc, pBuf, iDelta);
}
static void fts5AppendPoslist(
Fts5Index *p,
i64 iDelta,
Fts5Iter *pMulti,
Fts5Buffer *pBuf
){
int nData = pMulti->base.nData;
int nByte = nData + 9 + 9 + FTS5_DATA_ZERO_PADDING;
assert( nData>0 );
if( p->rc==SQLITE_OK && 0==fts5BufferGrow(&p->rc, pBuf, nByte) ){
fts5BufferSafeAppendVarint(pBuf, iDelta);
fts5BufferSafeAppendVarint(pBuf, nData*2);
fts5BufferSafeAppendBlob(pBuf, pMulti->base.pData, nData);
memset(&pBuf->p[pBuf->n], 0, FTS5_DATA_ZERO_PADDING);
}
}
static void fts5DoclistIterNext(Fts5DoclistIter *pIter){
u8 *p = pIter->aPoslist + pIter->nSize + pIter->nPoslist;
assert( pIter->aPoslist || (p==0 && pIter->aPoslist==0) );
if( p>=pIter->aEof ){
pIter->aPoslist = 0;
}else{
i64 iDelta;
p += fts5GetVarint(p, (u64*)&iDelta);
pIter->iRowid += iDelta;
/* Read position list size */
if( p[0] & 0x80 ){
int nPos;
pIter->nSize = fts5GetVarint32(p, nPos);
pIter->nPoslist = (nPos>>1);
}else{
pIter->nPoslist = ((int)(p[0])) >> 1;
pIter->nSize = 1;
}
pIter->aPoslist = p;
if( &pIter->aPoslist[pIter->nPoslist]>pIter->aEof ){
pIter->aPoslist = 0;
}
}
}
static void fts5DoclistIterInit(
Fts5Buffer *pBuf,
Fts5DoclistIter *pIter
){
memset(pIter, 0, sizeof(*pIter));
if( pBuf->n>0 ){
pIter->aPoslist = pBuf->p;
pIter->aEof = &pBuf->p[pBuf->n];
fts5DoclistIterNext(pIter);
}
}
#if 0
/*
** Append a doclist to buffer pBuf.
**
** This function assumes that space within the buffer has already been
** allocated.
*/
static void fts5MergeAppendDocid(
Fts5Buffer *pBuf, /* Buffer to write to */
i64 *piLastRowid, /* IN/OUT: Previous rowid written (if any) */
i64 iRowid /* Rowid to append */
){
assert( pBuf->n!=0 || (*piLastRowid)==0 );
fts5BufferSafeAppendVarint(pBuf, iRowid - *piLastRowid);
*piLastRowid = iRowid;
}
#endif
#define fts5MergeAppendDocid(pBuf, iLastRowid, iRowid) { \
assert( (pBuf)->n!=0 || (iLastRowid)==0 ); \
fts5BufferSafeAppendVarint((pBuf), (iRowid) - (iLastRowid)); \
(iLastRowid) = (iRowid); \
}
/*
** Swap the contents of buffer *p1 with that of *p2.
*/
static void fts5BufferSwap(Fts5Buffer *p1, Fts5Buffer *p2){
Fts5Buffer tmp = *p1;
*p1 = *p2;
*p2 = tmp;
}
static void fts5NextRowid(Fts5Buffer *pBuf, int *piOff, i64 *piRowid){
int i = *piOff;
if( i>=pBuf->n ){
*piOff = -1;
}else{
u64 iVal;
*piOff = i + sqlite3Fts5GetVarint(&pBuf->p[i], &iVal);
*piRowid += iVal;
}
}
/*
** This is the equivalent of fts5MergePrefixLists() for detail=none mode.
** In this case the buffers consist of a delta-encoded list of rowids only.
*/
static void fts5MergeRowidLists(
Fts5Index *p, /* FTS5 backend object */
Fts5Buffer *p1, /* First list to merge */
int nBuf, /* Number of entries in apBuf[] */
Fts5Buffer *aBuf /* Array of other lists to merge into p1 */
){
int i1 = 0;
int i2 = 0;
i64 iRowid1 = 0;
i64 iRowid2 = 0;
i64 iOut = 0;
Fts5Buffer *p2 = &aBuf[0];
Fts5Buffer out;
(void)nBuf;
memset(&out, 0, sizeof(out));
assert( nBuf==1 );
sqlite3Fts5BufferSize(&p->rc, &out, p1->n + p2->n);
if( p->rc ) return;
fts5NextRowid(p1, &i1, &iRowid1);
fts5NextRowid(p2, &i2, &iRowid2);
while( i1>=0 || i2>=0 ){
if( i1>=0 && (i2<0 || iRowid1<iRowid2) ){
assert( iOut==0 || iRowid1>iOut );
fts5BufferSafeAppendVarint(&out, iRowid1 - iOut);
iOut = iRowid1;
fts5NextRowid(p1, &i1, &iRowid1);
}else{
assert( iOut==0 || iRowid2>iOut );
fts5BufferSafeAppendVarint(&out, iRowid2 - iOut);
iOut = iRowid2;
if( i1>=0 && iRowid1==iRowid2 ){
fts5NextRowid(p1, &i1, &iRowid1);
}
fts5NextRowid(p2, &i2, &iRowid2);
}
}
fts5BufferSwap(&out, p1);
fts5BufferFree(&out);
}
typedef struct PrefixMerger PrefixMerger;
struct PrefixMerger {
Fts5DoclistIter iter; /* Doclist iterator */
i64 iPos; /* For iterating through a position list */
int iOff;
u8 *aPos;
PrefixMerger *pNext; /* Next in docid/poslist order */
};
static void fts5PrefixMergerInsertByRowid(
PrefixMerger **ppHead,
PrefixMerger *p
){
if( p->iter.aPoslist ){
PrefixMerger **pp = ppHead;
while( *pp && p->iter.iRowid>(*pp)->iter.iRowid ){
pp = &(*pp)->pNext;
}
p->pNext = *pp;
*pp = p;
}
}
static void fts5PrefixMergerInsertByPosition(
PrefixMerger **ppHead,
PrefixMerger *p
){
if( p->iPos>=0 ){
PrefixMerger **pp = ppHead;
while( *pp && p->iPos>(*pp)->iPos ){
pp = &(*pp)->pNext;
}
p->pNext = *pp;
*pp = p;
}
}
/*
** Array aBuf[] contains nBuf doclists. These are all merged in with the
** doclist in buffer p1.
*/
static void fts5MergePrefixLists(
Fts5Index *p, /* FTS5 backend object */
Fts5Buffer *p1, /* First list to merge */
int nBuf, /* Number of buffers in array aBuf[] */
Fts5Buffer *aBuf /* Other lists to merge in */
){
#define fts5PrefixMergerNextPosition(p) \
sqlite3Fts5PoslistNext64((p)->aPos,(p)->iter.nPoslist,&(p)->iOff,&(p)->iPos);
#define FTS5_MERGE_NLIST 16
PrefixMerger aMerger[FTS5_MERGE_NLIST];
PrefixMerger *pHead = 0;
int i;
int nOut = 0;
Fts5Buffer out = {0, 0, 0};
Fts5Buffer tmp = {0, 0, 0};
i64 iLastRowid = 0;
/* Initialize a doclist-iterator for each input buffer. Arrange them in
** a linked-list starting at pHead in ascending order of rowid. Avoid
** linking any iterators already at EOF into the linked list at all. */
assert( nBuf+1<=sizeof(aMerger)/sizeof(aMerger[0]) );
memset(aMerger, 0, sizeof(PrefixMerger)*(nBuf+1));
pHead = &aMerger[nBuf];
fts5DoclistIterInit(p1, &pHead->iter);
for(i=0; i<nBuf; i++){
fts5DoclistIterInit(&aBuf[i], &aMerger[i].iter);
fts5PrefixMergerInsertByRowid(&pHead, &aMerger[i]);
nOut += aBuf[i].n;
}
if( nOut==0 ) return;
nOut += p1->n + 9 + 10*nBuf;
/* The maximum size of the output is equal to the sum of the
** input sizes + 1 varint (9 bytes). The extra varint is because if the
** first rowid in one input is a large negative number, and the first in
** the other a non-negative number, the delta for the non-negative
** number will be larger on disk than the literal integer value
** was.
**
** Or, if the input position-lists are corrupt, then the output might
** include up to (nBuf+1) extra 10-byte positions created by interpreting -1
** (the value PoslistNext64() uses for EOF) as a position and appending
** it to the output. This can happen at most once for each input
** position-list, hence (nBuf+1) 10 byte paddings. */
if( sqlite3Fts5BufferSize(&p->rc, &out, nOut) ) return;
while( pHead ){
fts5MergeAppendDocid(&out, iLastRowid, pHead->iter.iRowid);
if( pHead->pNext && iLastRowid==pHead->pNext->iter.iRowid ){
/* Merge data from two or more poslists */
i64 iPrev = 0;
int nTmp = FTS5_DATA_ZERO_PADDING;
int nMerge = 0;
PrefixMerger *pSave = pHead;
PrefixMerger *pThis = 0;
int nTail = 0;
pHead = 0;
while( pSave && pSave->iter.iRowid==iLastRowid ){
PrefixMerger *pNext = pSave->pNext;
pSave->iOff = 0;
pSave->iPos = 0;
pSave->aPos = &pSave->iter.aPoslist[pSave->iter.nSize];
fts5PrefixMergerNextPosition(pSave);
nTmp += pSave->iter.nPoslist + 10;
nMerge++;
fts5PrefixMergerInsertByPosition(&pHead, pSave);
pSave = pNext;
}
if( pHead==0 || pHead->pNext==0 ){
p->rc = FTS5_CORRUPT;
break;
}
/* See the earlier comment in this function for an explanation of why
** corrupt input position lists might cause the output to consume
** at most nMerge*10 bytes of unexpected space. */
if( sqlite3Fts5BufferSize(&p->rc, &tmp, nTmp+nMerge*10) ){
break;
}
fts5BufferZero(&tmp);
pThis = pHead;
pHead = pThis->pNext;
sqlite3Fts5PoslistSafeAppend(&tmp, &iPrev, pThis->iPos);
fts5PrefixMergerNextPosition(pThis);
fts5PrefixMergerInsertByPosition(&pHead, pThis);
while( pHead->pNext ){
pThis = pHead;
if( pThis->iPos!=iPrev ){
sqlite3Fts5PoslistSafeAppend(&tmp, &iPrev, pThis->iPos);
}
fts5PrefixMergerNextPosition(pThis);
pHead = pThis->pNext;
fts5PrefixMergerInsertByPosition(&pHead, pThis);
}
if( pHead->iPos!=iPrev ){
sqlite3Fts5PoslistSafeAppend(&tmp, &iPrev, pHead->iPos);
}
nTail = pHead->iter.nPoslist - pHead->iOff;
/* WRITEPOSLISTSIZE */
assert( tmp.n+nTail<=nTmp );
if( tmp.n+nTail>nTmp-FTS5_DATA_ZERO_PADDING ){
if( p->rc==SQLITE_OK ) p->rc = FTS5_CORRUPT;
break;
}
fts5BufferSafeAppendVarint(&out, (tmp.n+nTail) * 2);
fts5BufferSafeAppendBlob(&out, tmp.p, tmp.n);
if( nTail>0 ){
fts5BufferSafeAppendBlob(&out, &pHead->aPos[pHead->iOff], nTail);
}
pHead = pSave;
for(i=0; i<nBuf+1; i++){
PrefixMerger *pX = &aMerger[i];
if( pX->iter.aPoslist && pX->iter.iRowid==iLastRowid ){
fts5DoclistIterNext(&pX->iter);
fts5PrefixMergerInsertByRowid(&pHead, pX);
}
}
}else{
/* Copy poslist from pHead to output */
PrefixMerger *pThis = pHead;
Fts5DoclistIter *pI = &pThis->iter;
fts5BufferSafeAppendBlob(&out, pI->aPoslist, pI->nPoslist+pI->nSize);
fts5DoclistIterNext(pI);
pHead = pThis->pNext;
fts5PrefixMergerInsertByRowid(&pHead, pThis);
}
}
fts5BufferFree(p1);
fts5BufferFree(&tmp);
memset(&out.p[out.n], 0, FTS5_DATA_ZERO_PADDING);
*p1 = out;
}
static void fts5SetupPrefixIter(
Fts5Index *p, /* Index to read from */
int bDesc, /* True for "ORDER BY rowid DESC" */
int iIdx, /* Index to scan for data */
u8 *pToken, /* Buffer containing prefix to match */
int nToken, /* Size of buffer pToken in bytes */
Fts5Colset *pColset, /* Restrict matches to these columns */
Fts5Iter **ppIter /* OUT: New iterator */
){
Fts5Structure *pStruct;
Fts5Buffer *aBuf;
int nBuf = 32;
int nMerge = 1;
void (*xMerge)(Fts5Index*, Fts5Buffer*, int, Fts5Buffer*);
void (*xAppend)(Fts5Index*, i64, Fts5Iter*, Fts5Buffer*);
if( p->pConfig->eDetail==FTS5_DETAIL_NONE ){
xMerge = fts5MergeRowidLists;
xAppend = fts5AppendRowid;
}else{
nMerge = FTS5_MERGE_NLIST-1;
nBuf = nMerge*8; /* Sufficient to merge (16^8)==(2^32) lists */
xMerge = fts5MergePrefixLists;
xAppend = fts5AppendPoslist;
}
aBuf = (Fts5Buffer*)fts5IdxMalloc(p, sizeof(Fts5Buffer)*nBuf);
pStruct = fts5StructureRead(p);
if( aBuf && pStruct ){
const int flags = FTS5INDEX_QUERY_SCAN
| FTS5INDEX_QUERY_SKIPEMPTY
| FTS5INDEX_QUERY_NOOUTPUT;
int i;
i64 iLastRowid = 0;
Fts5Iter *p1 = 0; /* Iterator used to gather data from index */
Fts5Data *pData;
Fts5Buffer doclist;
int bNewTerm = 1;
memset(&doclist, 0, sizeof(doclist));
if( iIdx!=0 ){
int dummy = 0;
const int f2 = FTS5INDEX_QUERY_SKIPEMPTY|FTS5INDEX_QUERY_NOOUTPUT;
pToken[0] = FTS5_MAIN_PREFIX;
fts5MultiIterNew(p, pStruct, f2, pColset, pToken, nToken, -1, 0, &p1);
fts5IterSetOutputCb(&p->rc, p1);
for(;
fts5MultiIterEof(p, p1)==0;
fts5MultiIterNext2(p, p1, &dummy)
){
Fts5SegIter *pSeg = &p1->aSeg[ p1->aFirst[1].iFirst ];
p1->xSetOutputs(p1, pSeg);
if( p1->base.nData ){
xAppend(p, p1->base.iRowid-iLastRowid, p1, &doclist);
iLastRowid = p1->base.iRowid;
}
}
fts5MultiIterFree(p1);
}
pToken[0] = FTS5_MAIN_PREFIX + iIdx;
fts5MultiIterNew(p, pStruct, flags, pColset, pToken, nToken, -1, 0, &p1);
fts5IterSetOutputCb(&p->rc, p1);
for( /* no-op */ ;
fts5MultiIterEof(p, p1)==0;
fts5MultiIterNext2(p, p1, &bNewTerm)
){
Fts5SegIter *pSeg = &p1->aSeg[ p1->aFirst[1].iFirst ];
int nTerm = pSeg->term.n;
const u8 *pTerm = pSeg->term.p;
p1->xSetOutputs(p1, pSeg);
assert_nc( memcmp(pToken, pTerm, MIN(nToken, nTerm))<=0 );
if( bNewTerm ){
if( nTerm<nToken || memcmp(pToken, pTerm, nToken) ) break;
}
if( p1->base.nData==0 ) continue;
if( p1->base.iRowid<=iLastRowid && doclist.n>0 ){
for(i=0; p->rc==SQLITE_OK && doclist.n; i++){
int i1 = i*nMerge;
int iStore;
assert( i1+nMerge<=nBuf );
for(iStore=i1; iStore<i1+nMerge; iStore++){
if( aBuf[iStore].n==0 ){
fts5BufferSwap(&doclist, &aBuf[iStore]);
fts5BufferZero(&doclist);
break;
}
}
if( iStore==i1+nMerge ){
xMerge(p, &doclist, nMerge, &aBuf[i1]);
for(iStore=i1; iStore<i1+nMerge; iStore++){
fts5BufferZero(&aBuf[iStore]);
}
}
}
iLastRowid = 0;
}
xAppend(p, p1->base.iRowid-iLastRowid, p1, &doclist);
iLastRowid = p1->base.iRowid;
}
assert( (nBuf%nMerge)==0 );
for(i=0; i<nBuf; i+=nMerge){
int iFree;
if( p->rc==SQLITE_OK ){
xMerge(p, &doclist, nMerge, &aBuf[i]);
}
for(iFree=i; iFree<i+nMerge; iFree++){
fts5BufferFree(&aBuf[iFree]);
}
}
fts5MultiIterFree(p1);
pData = fts5IdxMalloc(p, sizeof(Fts5Data)+doclist.n+FTS5_DATA_ZERO_PADDING);
if( pData ){
pData->p = (u8*)&pData[1];
pData->nn = pData->szLeaf = doclist.n;
if( doclist.n ) memcpy(pData->p, doclist.p, doclist.n);
fts5MultiIterNew2(p, pData, bDesc, ppIter);
}
fts5BufferFree(&doclist);
}
fts5StructureRelease(pStruct);
sqlite3_free(aBuf);
}
/*
** Indicate that all subsequent calls to sqlite3Fts5IndexWrite() pertain
** to the document with rowid iRowid.
*/
static int sqlite3Fts5IndexBeginWrite(Fts5Index *p, int bDelete, i64 iRowid){
assert( p->rc==SQLITE_OK );
/* Allocate the hash table if it has not already been allocated */
if( p->pHash==0 ){
p->rc = sqlite3Fts5HashNew(p->pConfig, &p->pHash, &p->nPendingData);
}
/* Flush the hash table to disk if required */
if( iRowid<p->iWriteRowid
|| (iRowid==p->iWriteRowid && p->bDelete==0)
|| (p->nPendingData > p->pConfig->nHashSize)
){
fts5IndexFlush(p);
}
p->iWriteRowid = iRowid;
p->bDelete = bDelete;
return fts5IndexReturn(p);
}
/*
** Commit data to disk.
*/
static int sqlite3Fts5IndexSync(Fts5Index *p){
assert( p->rc==SQLITE_OK );
fts5IndexFlush(p);
sqlite3Fts5IndexCloseReader(p);
return fts5IndexReturn(p);
}
/*
** Discard any data stored in the in-memory hash tables. Do not write it
** to the database. Additionally, assume that the contents of the %_data
** table may have changed on disk. So any in-memory caches of %_data
** records must be invalidated.
*/
static int sqlite3Fts5IndexRollback(Fts5Index *p){
sqlite3Fts5IndexCloseReader(p);
fts5IndexDiscardData(p);
fts5StructureInvalidate(p);
/* assert( p->rc==SQLITE_OK ); */
return SQLITE_OK;
}
/*
** The %_data table is completely empty when this function is called. This
** function populates it with the initial structure objects for each index,
** and the initial version of the "averages" record (a zero-byte blob).
*/
static int sqlite3Fts5IndexReinit(Fts5Index *p){
Fts5Structure s;
fts5StructureInvalidate(p);
fts5IndexDiscardData(p);
memset(&s, 0, sizeof(Fts5Structure));
fts5DataWrite(p, FTS5_AVERAGES_ROWID, (const u8*)"", 0);
fts5StructureWrite(p, &s);
return fts5IndexReturn(p);
}
/*
** Open a new Fts5Index handle. If the bCreate argument is true, create
** and initialize the underlying %_data table.
**
** If successful, set *pp to point to the new object and return SQLITE_OK.
** Otherwise, set *pp to NULL and return an SQLite error code.
*/
static int sqlite3Fts5IndexOpen(
Fts5Config *pConfig,
int bCreate,
Fts5Index **pp,
char **pzErr
){
int rc = SQLITE_OK;
Fts5Index *p; /* New object */
*pp = p = (Fts5Index*)sqlite3Fts5MallocZero(&rc, sizeof(Fts5Index));
if( rc==SQLITE_OK ){
p->pConfig = pConfig;
p->nWorkUnit = FTS5_WORK_UNIT;
p->zDataTbl = sqlite3Fts5Mprintf(&rc, "%s_data", pConfig->zName);
if( p->zDataTbl && bCreate ){
rc = sqlite3Fts5CreateTable(
pConfig, "data", "id INTEGER PRIMARY KEY, block BLOB", 0, pzErr
);
if( rc==SQLITE_OK ){
rc = sqlite3Fts5CreateTable(pConfig, "idx",
"segid, term, pgno, PRIMARY KEY(segid, term)",
1, pzErr
);
}
if( rc==SQLITE_OK ){
rc = sqlite3Fts5IndexReinit(p);
}
}
}
assert( rc!=SQLITE_OK || p->rc==SQLITE_OK );
if( rc ){
sqlite3Fts5IndexClose(p);
*pp = 0;
}
return rc;
}
/*
** Close a handle opened by an earlier call to sqlite3Fts5IndexOpen().
*/
static int sqlite3Fts5IndexClose(Fts5Index *p){
int rc = SQLITE_OK;
if( p ){
assert( p->pReader==0 );
fts5StructureInvalidate(p);
sqlite3_finalize(p->pWriter);
sqlite3_finalize(p->pDeleter);
sqlite3_finalize(p->pIdxWriter);
sqlite3_finalize(p->pIdxDeleter);
sqlite3_finalize(p->pIdxSelect);
sqlite3_finalize(p->pDataVersion);
sqlite3Fts5HashFree(p->pHash);
sqlite3_free(p->zDataTbl);
sqlite3_free(p);
}
return rc;
}
/*
** Argument p points to a buffer containing utf-8 text that is n bytes in
** size. Return the number of bytes in the nChar character prefix of the
** buffer, or 0 if there are less than nChar characters in total.
*/
static int sqlite3Fts5IndexCharlenToBytelen(
const char *p,
int nByte,
int nChar
){
int n = 0;
int i;
for(i=0; i<nChar; i++){
if( n>=nByte ) return 0; /* Input contains fewer than nChar chars */
if( (unsigned char)p[n++]>=0xc0 ){
if( n>=nByte ) return 0;
while( (p[n] & 0xc0)==0x80 ){
n++;
if( n>=nByte ){
if( i+1==nChar ) break;
return 0;
}
}
}
}
return n;
}
/*
** pIn is a UTF-8 encoded string, nIn bytes in size. Return the number of
** unicode characters in the string.
*/
static int fts5IndexCharlen(const char *pIn, int nIn){
int nChar = 0;
int i = 0;
while( i<nIn ){
if( (unsigned char)pIn[i++]>=0xc0 ){
while( i<nIn && (pIn[i] & 0xc0)==0x80 ) i++;
}
nChar++;
}
return nChar;
}
/*
** Insert or remove data to or from the index. Each time a document is
** added to or removed from the index, this function is called one or more
** times.
**
** For an insert, it must be called once for each token in the new document.
** If the operation is a delete, it must be called (at least) once for each
** unique token in the document with an iCol value less than zero. The iPos
** argument is ignored for a delete.
*/
static int sqlite3Fts5IndexWrite(
Fts5Index *p, /* Index to write to */
int iCol, /* Column token appears in (-ve -> delete) */
int iPos, /* Position of token within column */
const char *pToken, int nToken /* Token to add or remove to or from index */
){
int i; /* Used to iterate through indexes */
int rc = SQLITE_OK; /* Return code */
Fts5Config *pConfig = p->pConfig;
assert( p->rc==SQLITE_OK );
assert( (iCol<0)==p->bDelete );
/* Add the entry to the main terms index. */
rc = sqlite3Fts5HashWrite(
p->pHash, p->iWriteRowid, iCol, iPos, FTS5_MAIN_PREFIX, pToken, nToken
);
for(i=0; i<pConfig->nPrefix && rc==SQLITE_OK; i++){
const int nChar = pConfig->aPrefix[i];
int nByte = sqlite3Fts5IndexCharlenToBytelen(pToken, nToken, nChar);
if( nByte ){
rc = sqlite3Fts5HashWrite(p->pHash,
p->iWriteRowid, iCol, iPos, (char)(FTS5_MAIN_PREFIX+i+1), pToken,
nByte
);
}
}
return rc;
}
/*
** Open a new iterator to iterate though all rowid that match the
** specified token or token prefix.
*/
static int sqlite3Fts5IndexQuery(
Fts5Index *p, /* FTS index to query */
const char *pToken, int nToken, /* Token (or prefix) to query for */
int flags, /* Mask of FTS5INDEX_QUERY_X flags */
Fts5Colset *pColset, /* Match these columns only */
Fts5IndexIter **ppIter /* OUT: New iterator object */
){
Fts5Config *pConfig = p->pConfig;
Fts5Iter *pRet = 0;
Fts5Buffer buf = {0, 0, 0};
/* If the QUERY_SCAN flag is set, all other flags must be clear. */
assert( (flags & FTS5INDEX_QUERY_SCAN)==0 || flags==FTS5INDEX_QUERY_SCAN );
/* [jart] what is with these gcc11 warnings */
void *MemCpy(void *, const void *, size_t) asm("memcpy");
if( sqlite3Fts5BufferSize(&p->rc, &buf, nToken+1)==0 ){
int iIdx = 0; /* Index to search */
int iPrefixIdx = 0; /* +1 prefix index */
if( nToken ) MemCpy(&buf.p[1], pToken, nToken);
/* Figure out which index to search and set iIdx accordingly. If this
** is a prefix query for which there is no prefix index, set iIdx to
** greater than pConfig->nPrefix to indicate that the query will be
** satisfied by scanning multiple terms in the main index.
**
** If the QUERY_TEST_NOIDX flag was specified, then this must be a
** prefix-query. Instead of using a prefix-index (if one exists),
** evaluate the prefix query using the main FTS index. This is used
** for internal sanity checking by the integrity-check in debug
** mode only. */
#ifdef SQLITE_DEBUG
if( pConfig->bPrefixIndex==0 || (flags & FTS5INDEX_QUERY_TEST_NOIDX) ){
assert( flags & FTS5INDEX_QUERY_PREFIX );
iIdx = 1+pConfig->nPrefix;
}else
#endif
if( flags & FTS5INDEX_QUERY_PREFIX ){
int nChar = fts5IndexCharlen(pToken, nToken);
for(iIdx=1; iIdx<=pConfig->nPrefix; iIdx++){
int nIdxChar = pConfig->aPrefix[iIdx-1];
if( nIdxChar==nChar ) break;
if( nIdxChar==nChar+1 ) iPrefixIdx = iIdx;
}
}
if( iIdx<=pConfig->nPrefix ){
/* Straight index lookup */
Fts5Structure *pStruct = fts5StructureRead(p);
buf.p[0] = (u8)(FTS5_MAIN_PREFIX + iIdx);
if( pStruct ){
fts5MultiIterNew(p, pStruct, flags | FTS5INDEX_QUERY_SKIPEMPTY,
pColset, buf.p, nToken+1, -1, 0, &pRet
);
fts5StructureRelease(pStruct);
}
}else{
/* Scan multiple terms in the main index */
int bDesc = (flags & FTS5INDEX_QUERY_DESC)!=0;
fts5SetupPrefixIter(p, bDesc, iPrefixIdx, buf.p, nToken+1, pColset,&pRet);
assert( p->rc!=SQLITE_OK || pRet->pColset==0 );
fts5IterSetOutputCb(&p->rc, pRet);
if( p->rc==SQLITE_OK ){
Fts5SegIter *pSeg = &pRet->aSeg[pRet->aFirst[1].iFirst];
if( pSeg->pLeaf ) pRet->xSetOutputs(pRet, pSeg);
}
}
if( p->rc ){
sqlite3Fts5IterClose((Fts5IndexIter*)pRet);
pRet = 0;
sqlite3Fts5IndexCloseReader(p);
}
*ppIter = (Fts5IndexIter*)pRet;
sqlite3Fts5BufferFree(&buf);
}
return fts5IndexReturn(p);
}
/*
** Return true if the iterator passed as the only argument is at EOF.
*/
/*
** Move to the next matching rowid.
*/
static int sqlite3Fts5IterNext(Fts5IndexIter *pIndexIter){
Fts5Iter *pIter = (Fts5Iter*)pIndexIter;
assert( pIter->pIndex->rc==SQLITE_OK );
fts5MultiIterNext(pIter->pIndex, pIter, 0, 0);
return fts5IndexReturn(pIter->pIndex);
}
/*
** Move to the next matching term/rowid. Used by the fts5vocab module.
*/
static int sqlite3Fts5IterNextScan(Fts5IndexIter *pIndexIter){
Fts5Iter *pIter = (Fts5Iter*)pIndexIter;
Fts5Index *p = pIter->pIndex;
assert( pIter->pIndex->rc==SQLITE_OK );
fts5MultiIterNext(p, pIter, 0, 0);
if( p->rc==SQLITE_OK ){
Fts5SegIter *pSeg = &pIter->aSeg[ pIter->aFirst[1].iFirst ];
if( pSeg->pLeaf && pSeg->term.p[0]!=FTS5_MAIN_PREFIX ){
fts5DataRelease(pSeg->pLeaf);
pSeg->pLeaf = 0;
pIter->base.bEof = 1;
}
}
return fts5IndexReturn(pIter->pIndex);
}
/*
** Move to the next matching rowid that occurs at or after iMatch. The
** definition of "at or after" depends on whether this iterator iterates
** in ascending or descending rowid order.
*/
static int sqlite3Fts5IterNextFrom(Fts5IndexIter *pIndexIter, i64 iMatch){
Fts5Iter *pIter = (Fts5Iter*)pIndexIter;
fts5MultiIterNextFrom(pIter->pIndex, pIter, iMatch);
return fts5IndexReturn(pIter->pIndex);
}
/*
** Return the current term.
*/
static const char *sqlite3Fts5IterTerm(Fts5IndexIter *pIndexIter, int *pn){
int n;
const char *z = (const char*)fts5MultiIterTerm((Fts5Iter*)pIndexIter, &n);
assert_nc( z || n<=1 );
*pn = n-1;
return (z ? &z[1] : 0);
}
/*
** Close an iterator opened by an earlier call to sqlite3Fts5IndexQuery().
*/
static void sqlite3Fts5IterClose(Fts5IndexIter *pIndexIter){
if( pIndexIter ){
Fts5Iter *pIter = (Fts5Iter*)pIndexIter;
Fts5Index *pIndex = pIter->pIndex;
fts5MultiIterFree(pIter);
sqlite3Fts5IndexCloseReader(pIndex);
}
}
/*
** Read and decode the "averages" record from the database.
**
** Parameter anSize must point to an array of size nCol, where nCol is
** the number of user defined columns in the FTS table.
*/
static int sqlite3Fts5IndexGetAverages(Fts5Index *p, i64 *pnRow, i64 *anSize){
int nCol = p->pConfig->nCol;
Fts5Data *pData;
*pnRow = 0;
memset(anSize, 0, sizeof(i64) * nCol);
pData = fts5DataRead(p, FTS5_AVERAGES_ROWID);
if( p->rc==SQLITE_OK && pData->nn ){
int i = 0;
int iCol;
i += fts5GetVarint(&pData->p[i], (u64*)pnRow);
for(iCol=0; i<pData->nn && iCol<nCol; iCol++){
i += fts5GetVarint(&pData->p[i], (u64*)&anSize[iCol]);
}
}
fts5DataRelease(pData);
return fts5IndexReturn(p);
}
/*
** Replace the current "averages" record with the contents of the buffer
** supplied as the second argument.
*/
static int sqlite3Fts5IndexSetAverages(Fts5Index *p, const u8 *pData, int nData){
assert( p->rc==SQLITE_OK );
fts5DataWrite(p, FTS5_AVERAGES_ROWID, pData, nData);
return fts5IndexReturn(p);
}
/*
** Return the total number of blocks this module has read from the %_data
** table since it was created.
*/
static int sqlite3Fts5IndexReads(Fts5Index *p){
return p->nRead;
}
/*
** Set the 32-bit cookie value stored at the start of all structure
** records to the value passed as the second argument.
**
** Return SQLITE_OK if successful, or an SQLite error code if an error
** occurs.
*/
static int sqlite3Fts5IndexSetCookie(Fts5Index *p, int iNew){
int rc; /* Return code */
Fts5Config *pConfig = p->pConfig; /* Configuration object */
u8 aCookie[4]; /* Binary representation of iNew */
sqlite3_blob *pBlob = 0;
assert( p->rc==SQLITE_OK );
sqlite3Fts5Put32(aCookie, iNew);
rc = sqlite3_blob_open(pConfig->db, pConfig->zDb, p->zDataTbl,
"block", FTS5_STRUCTURE_ROWID, 1, &pBlob
);
if( rc==SQLITE_OK ){
sqlite3_blob_write(pBlob, aCookie, 4, 0);
rc = sqlite3_blob_close(pBlob);
}
return rc;
}
static int sqlite3Fts5IndexLoadConfig(Fts5Index *p){
Fts5Structure *pStruct;
pStruct = fts5StructureRead(p);
fts5StructureRelease(pStruct);
return fts5IndexReturn(p);
}
/*************************************************************************
**************************************************************************
** Below this point is the implementation of the integrity-check
** functionality.
*/
/*
** Return a simple checksum value based on the arguments.
*/
static u64 sqlite3Fts5IndexEntryCksum(
i64 iRowid,
int iCol,
int iPos,
int iIdx,
const char *pTerm,
int nTerm
){
int i;
u64 ret = iRowid;
ret += (ret<<3) + iCol;
ret += (ret<<3) + iPos;
if( iIdx>=0 ) ret += (ret<<3) + (FTS5_MAIN_PREFIX + iIdx);
for(i=0; i<nTerm; i++) ret += (ret<<3) + pTerm[i];
return ret;
}
#ifdef SQLITE_DEBUG
/*
** This function is purely an internal test. It does not contribute to
** FTS functionality, or even the integrity-check, in any way.
**
** Instead, it tests that the same set of pgno/rowid combinations are
** visited regardless of whether the doclist-index identified by parameters
** iSegid/iLeaf is iterated in forwards or reverse order.
*/
static void fts5TestDlidxReverse(
Fts5Index *p,
int iSegid, /* Segment id to load from */
int iLeaf /* Load doclist-index for this leaf */
){
Fts5DlidxIter *pDlidx = 0;
u64 cksum1 = 13;
u64 cksum2 = 13;
for(pDlidx=fts5DlidxIterInit(p, 0, iSegid, iLeaf);
fts5DlidxIterEof(p, pDlidx)==0;
fts5DlidxIterNext(p, pDlidx)
){
i64 iRowid = fts5DlidxIterRowid(pDlidx);
int pgno = fts5DlidxIterPgno(pDlidx);
assert( pgno>iLeaf );
cksum1 += iRowid + ((i64)pgno<<32);
}
fts5DlidxIterFree(pDlidx);
pDlidx = 0;
for(pDlidx=fts5DlidxIterInit(p, 1, iSegid, iLeaf);
fts5DlidxIterEof(p, pDlidx)==0;
fts5DlidxIterPrev(p, pDlidx)
){
i64 iRowid = fts5DlidxIterRowid(pDlidx);
int pgno = fts5DlidxIterPgno(pDlidx);
assert( fts5DlidxIterPgno(pDlidx)>iLeaf );
cksum2 += iRowid + ((i64)pgno<<32);
}
fts5DlidxIterFree(pDlidx);
pDlidx = 0;
if( p->rc==SQLITE_OK && cksum1!=cksum2 ) p->rc = FTS5_CORRUPT;
}
static int fts5QueryCksum(
Fts5Index *p, /* Fts5 index object */
int iIdx,
const char *z, /* Index key to query for */
int n, /* Size of index key in bytes */
int flags, /* Flags for Fts5IndexQuery */
u64 *pCksum /* IN/OUT: Checksum value */
){
int eDetail = p->pConfig->eDetail;
u64 cksum = *pCksum;
Fts5IndexIter *pIter = 0;
int rc = sqlite3Fts5IndexQuery(p, z, n, flags, 0, &pIter);
while( rc==SQLITE_OK && 0==sqlite3Fts5IterEof(pIter) ){
i64 rowid = pIter->iRowid;
if( eDetail==FTS5_DETAIL_NONE ){
cksum ^= sqlite3Fts5IndexEntryCksum(rowid, 0, 0, iIdx, z, n);
}else{
Fts5PoslistReader sReader;
for(sqlite3Fts5PoslistReaderInit(pIter->pData, pIter->nData, &sReader);
sReader.bEof==0;
sqlite3Fts5PoslistReaderNext(&sReader)
){
int iCol = FTS5_POS2COLUMN(sReader.iPos);
int iOff = FTS5_POS2OFFSET(sReader.iPos);
cksum ^= sqlite3Fts5IndexEntryCksum(rowid, iCol, iOff, iIdx, z, n);
}
}
if( rc==SQLITE_OK ){
rc = sqlite3Fts5IterNext(pIter);
}
}
sqlite3Fts5IterClose(pIter);
*pCksum = cksum;
return rc;
}
/*
** Check if buffer z[], size n bytes, contains as series of valid utf-8
** encoded codepoints. If so, return 0. Otherwise, if the buffer does not
** contain valid utf-8, return non-zero.
*/
static int fts5TestUtf8(const char *z, int n){
int i = 0;
assert_nc( n>0 );
while( i<n ){
if( (z[i] & 0x80)==0x00 ){
i++;
}else
if( (z[i] & 0xE0)==0xC0 ){
if( i+1>=n || (z[i+1] & 0xC0)!=0x80 ) return 1;
i += 2;
}else
if( (z[i] & 0xF0)==0xE0 ){
if( i+2>=n || (z[i+1] & 0xC0)!=0x80 || (z[i+2] & 0xC0)!=0x80 ) return 1;
i += 3;
}else
if( (z[i] & 0xF8)==0xF0 ){
if( i+3>=n || (z[i+1] & 0xC0)!=0x80 || (z[i+2] & 0xC0)!=0x80 ) return 1;
if( (z[i+2] & 0xC0)!=0x80 ) return 1;
i += 3;
}else{
return 1;
}
}
return 0;
}
/*
** This function is also purely an internal test. It does not contribute to
** FTS functionality, or even the integrity-check, in any way.
*/
static void fts5TestTerm(
Fts5Index *p,
Fts5Buffer *pPrev, /* Previous term */
const char *z, int n, /* Possibly new term to test */
u64 expected,
u64 *pCksum
){
int rc = p->rc;
if( pPrev->n==0 ){
fts5BufferSet(&rc, pPrev, n, (const u8*)z);
}else
if( rc==SQLITE_OK && (pPrev->n!=n || memcmp(pPrev->p, z, n)) ){
u64 cksum3 = *pCksum;
const char *zTerm = (const char*)&pPrev->p[1]; /* term sans prefix-byte */
int nTerm = pPrev->n-1; /* Size of zTerm in bytes */
int iIdx = (pPrev->p[0] - FTS5_MAIN_PREFIX);
int flags = (iIdx==0 ? 0 : FTS5INDEX_QUERY_PREFIX);
u64 ck1 = 0;
u64 ck2 = 0;
/* Check that the results returned for ASC and DESC queries are
** the same. If not, call this corruption. */
rc = fts5QueryCksum(p, iIdx, zTerm, nTerm, flags, &ck1);
if( rc==SQLITE_OK ){
int f = flags|FTS5INDEX_QUERY_DESC;
rc = fts5QueryCksum(p, iIdx, zTerm, nTerm, f, &ck2);
}
if( rc==SQLITE_OK && ck1!=ck2 ) rc = FTS5_CORRUPT;
/* If this is a prefix query, check that the results returned if the
** the index is disabled are the same. In both ASC and DESC order.
**
** This check may only be performed if the hash table is empty. This
** is because the hash table only supports a single scan query at
** a time, and the multi-iter loop from which this function is called
** is already performing such a scan.
**
** Also only do this if buffer zTerm contains nTerm bytes of valid
** utf-8. Otherwise, the last part of the buffer contents might contain
** a non-utf-8 sequence that happens to be a prefix of a valid utf-8
** character stored in the main fts index, which will cause the
** test to fail. */
if( p->nPendingData==0 && 0==fts5TestUtf8(zTerm, nTerm) ){
if( iIdx>0 && rc==SQLITE_OK ){
int f = flags|FTS5INDEX_QUERY_TEST_NOIDX;
ck2 = 0;
rc = fts5QueryCksum(p, iIdx, zTerm, nTerm, f, &ck2);
if( rc==SQLITE_OK && ck1!=ck2 ) rc = FTS5_CORRUPT;
}
if( iIdx>0 && rc==SQLITE_OK ){
int f = flags|FTS5INDEX_QUERY_TEST_NOIDX|FTS5INDEX_QUERY_DESC;
ck2 = 0;
rc = fts5QueryCksum(p, iIdx, zTerm, nTerm, f, &ck2);
if( rc==SQLITE_OK && ck1!=ck2 ) rc = FTS5_CORRUPT;
}
}
cksum3 ^= ck1;
fts5BufferSet(&rc, pPrev, n, (const u8*)z);
if( rc==SQLITE_OK && cksum3!=expected ){
rc = FTS5_CORRUPT;
}
*pCksum = cksum3;
}
p->rc = rc;
}
#else
# define fts5TestDlidxReverse(x,y,z)
# define fts5TestTerm(u,v,w,x,y,z)
#endif
/*
** Check that:
**
** 1) All leaves of pSeg between iFirst and iLast (inclusive) exist and
** contain zero terms.
** 2) All leaves of pSeg between iNoRowid and iLast (inclusive) exist and
** contain zero rowids.
*/
static void fts5IndexIntegrityCheckEmpty(
Fts5Index *p,
Fts5StructureSegment *pSeg, /* Segment to check internal consistency */
int iFirst,
int iNoRowid,
int iLast
){
int i;
/* Now check that the iter.nEmpty leaves following the current leaf
** (a) exist and (b) contain no terms. */
for(i=iFirst; p->rc==SQLITE_OK && i<=iLast; i++){
Fts5Data *pLeaf = fts5DataRead(p, FTS5_SEGMENT_ROWID(pSeg->iSegid, i));
if( pLeaf ){
if( !fts5LeafIsTermless(pLeaf) ) p->rc = FTS5_CORRUPT;
if( i>=iNoRowid && 0!=fts5LeafFirstRowidOff(pLeaf) ) p->rc = FTS5_CORRUPT;
}
fts5DataRelease(pLeaf);
}
}
static void fts5IntegrityCheckPgidx(Fts5Index *p, Fts5Data *pLeaf){
int iTermOff = 0;
int ii;
Fts5Buffer buf1 = {0,0,0};
Fts5Buffer buf2 = {0,0,0};
ii = pLeaf->szLeaf;
while( ii<pLeaf->nn && p->rc==SQLITE_OK ){
int res;
int iOff;
int nIncr;
ii += fts5GetVarint32(&pLeaf->p[ii], nIncr);
iTermOff += nIncr;
iOff = iTermOff;
if( iOff>=pLeaf->szLeaf ){
p->rc = FTS5_CORRUPT;
}else if( iTermOff==nIncr ){
int nByte;
iOff += fts5GetVarint32(&pLeaf->p[iOff], nByte);
if( (iOff+nByte)>pLeaf->szLeaf ){
p->rc = FTS5_CORRUPT;
}else{
fts5BufferSet(&p->rc, &buf1, nByte, &pLeaf->p[iOff]);
}
}else{
int nKeep, nByte;
iOff += fts5GetVarint32(&pLeaf->p[iOff], nKeep);
iOff += fts5GetVarint32(&pLeaf->p[iOff], nByte);
if( nKeep>buf1.n || (iOff+nByte)>pLeaf->szLeaf ){
p->rc = FTS5_CORRUPT;
}else{
buf1.n = nKeep;
fts5BufferAppendBlob(&p->rc, &buf1, nByte, &pLeaf->p[iOff]);
}
if( p->rc==SQLITE_OK ){
res = fts5BufferCompare(&buf1, &buf2);
if( res<=0 ) p->rc = FTS5_CORRUPT;
}
}
fts5BufferSet(&p->rc, &buf2, buf1.n, buf1.p);
}
fts5BufferFree(&buf1);
fts5BufferFree(&buf2);
}
static void fts5IndexIntegrityCheckSegment(
Fts5Index *p, /* FTS5 backend object */
Fts5StructureSegment *pSeg /* Segment to check internal consistency */
){
Fts5Config *pConfig = p->pConfig;
sqlite3_stmt *pStmt = 0;
int rc2;
int iIdxPrevLeaf = pSeg->pgnoFirst-1;
int iDlidxPrevLeaf = pSeg->pgnoLast;
if( pSeg->pgnoFirst==0 ) return;
fts5IndexPrepareStmt(p, &pStmt, sqlite3_mprintf(
"SELECT segid, term, (pgno>>1), (pgno&1) FROM %Q.'%q_idx' WHERE segid=%d "
"ORDER BY 1, 2",
pConfig->zDb, pConfig->zName, pSeg->iSegid
));
/* Iterate through the b-tree hierarchy. */
while( p->rc==SQLITE_OK && SQLITE_ROW==sqlite3_step(pStmt) ){
i64 iRow; /* Rowid for this leaf */
Fts5Data *pLeaf; /* Data for this leaf */
const char *zIdxTerm = (const char*)sqlite3_column_blob(pStmt, 1);
int nIdxTerm = sqlite3_column_bytes(pStmt, 1);
int iIdxLeaf = sqlite3_column_int(pStmt, 2);
int bIdxDlidx = sqlite3_column_int(pStmt, 3);
/* If the leaf in question has already been trimmed from the segment,
** ignore this b-tree entry. Otherwise, load it into memory. */
if( iIdxLeaf<pSeg->pgnoFirst ) continue;
iRow = FTS5_SEGMENT_ROWID(pSeg->iSegid, iIdxLeaf);
pLeaf = fts5LeafRead(p, iRow);
if( pLeaf==0 ) break;
/* Check that the leaf contains at least one term, and that it is equal
** to or larger than the split-key in zIdxTerm. Also check that if there
** is also a rowid pointer within the leaf page header, it points to a
** location before the term. */
if( pLeaf->nn<=pLeaf->szLeaf ){
p->rc = FTS5_CORRUPT;
}else{
int iOff; /* Offset of first term on leaf */
int iRowidOff; /* Offset of first rowid on leaf */
int nTerm; /* Size of term on leaf in bytes */
int res; /* Comparison of term and split-key */
iOff = fts5LeafFirstTermOff(pLeaf);
iRowidOff = fts5LeafFirstRowidOff(pLeaf);
if( iRowidOff>=iOff || iOff>=pLeaf->szLeaf ){
p->rc = FTS5_CORRUPT;
}else{
iOff += fts5GetVarint32(&pLeaf->p[iOff], nTerm);
res = fts5Memcmp(&pLeaf->p[iOff], zIdxTerm, MIN(nTerm, nIdxTerm));
if( res==0 ) res = nTerm - nIdxTerm;
if( res<0 ) p->rc = FTS5_CORRUPT;
}
fts5IntegrityCheckPgidx(p, pLeaf);
}
fts5DataRelease(pLeaf);
if( p->rc ) break;
/* Now check that the iter.nEmpty leaves following the current leaf
** (a) exist and (b) contain no terms. */
fts5IndexIntegrityCheckEmpty(
p, pSeg, iIdxPrevLeaf+1, iDlidxPrevLeaf+1, iIdxLeaf-1
);
if( p->rc ) break;
/* If there is a doclist-index, check that it looks right. */
if( bIdxDlidx ){
Fts5DlidxIter *pDlidx = 0; /* For iterating through doclist index */
int iPrevLeaf = iIdxLeaf;
int iSegid = pSeg->iSegid;
int iPg = 0;
i64 iKey;
for(pDlidx=fts5DlidxIterInit(p, 0, iSegid, iIdxLeaf);
fts5DlidxIterEof(p, pDlidx)==0;
fts5DlidxIterNext(p, pDlidx)
){
/* Check any rowid-less pages that occur before the current leaf. */
for(iPg=iPrevLeaf+1; iPg<fts5DlidxIterPgno(pDlidx); iPg++){
iKey = FTS5_SEGMENT_ROWID(iSegid, iPg);
pLeaf = fts5DataRead(p, iKey);
if( pLeaf ){
if( fts5LeafFirstRowidOff(pLeaf)!=0 ) p->rc = FTS5_CORRUPT;
fts5DataRelease(pLeaf);
}
}
iPrevLeaf = fts5DlidxIterPgno(pDlidx);
/* Check that the leaf page indicated by the iterator really does
** contain the rowid suggested by the same. */
iKey = FTS5_SEGMENT_ROWID(iSegid, iPrevLeaf);
pLeaf = fts5DataRead(p, iKey);
if( pLeaf ){
i64 iRowid;
int iRowidOff = fts5LeafFirstRowidOff(pLeaf);
ASSERT_SZLEAF_OK(pLeaf);
if( iRowidOff>=pLeaf->szLeaf ){
p->rc = FTS5_CORRUPT;
}else{
fts5GetVarint(&pLeaf->p[iRowidOff], (u64*)&iRowid);
if( iRowid!=fts5DlidxIterRowid(pDlidx) ) p->rc = FTS5_CORRUPT;
}
fts5DataRelease(pLeaf);
}
}
iDlidxPrevLeaf = iPg;
fts5DlidxIterFree(pDlidx);
fts5TestDlidxReverse(p, iSegid, iIdxLeaf);
}else{
iDlidxPrevLeaf = pSeg->pgnoLast;
/* TODO: Check there is no doclist index */
}
iIdxPrevLeaf = iIdxLeaf;
}
rc2 = sqlite3_finalize(pStmt);
if( p->rc==SQLITE_OK ) p->rc = rc2;
/* Page iter.iLeaf must now be the rightmost leaf-page in the segment */
#if 0
if( p->rc==SQLITE_OK && iter.iLeaf!=pSeg->pgnoLast ){
p->rc = FTS5_CORRUPT;
}
#endif
}
/*
** Run internal checks to ensure that the FTS index (a) is internally
** consistent and (b) contains entries for which the XOR of the checksums
** as calculated by sqlite3Fts5IndexEntryCksum() is cksum.
**
** Return SQLITE_CORRUPT if any of the internal checks fail, or if the
** checksum does not match. Return SQLITE_OK if all checks pass without
** error, or some other SQLite error code if another error (e.g. OOM)
** occurs.
*/
static int sqlite3Fts5IndexIntegrityCheck(Fts5Index *p, u64 cksum, int bUseCksum){
int eDetail = p->pConfig->eDetail;
u64 cksum2 = 0; /* Checksum based on contents of indexes */
Fts5Buffer poslist = {0,0,0}; /* Buffer used to hold a poslist */
Fts5Iter *pIter; /* Used to iterate through entire index */
Fts5Structure *pStruct; /* Index structure */
#ifdef SQLITE_DEBUG
/* Used by extra internal tests only run if NDEBUG is not defined */
u64 cksum3 = 0; /* Checksum based on contents of indexes */
Fts5Buffer term = {0,0,0}; /* Buffer used to hold most recent term */
#endif
const int flags = FTS5INDEX_QUERY_NOOUTPUT;
/* Load the FTS index structure */
pStruct = fts5StructureRead(p);
/* Check that the internal nodes of each segment match the leaves */
if( pStruct ){
int iLvl, iSeg;
for(iLvl=0; iLvl<pStruct->nLevel; iLvl++){
for(iSeg=0; iSeg<pStruct->aLevel[iLvl].nSeg; iSeg++){
Fts5StructureSegment *pSeg = &pStruct->aLevel[iLvl].aSeg[iSeg];
fts5IndexIntegrityCheckSegment(p, pSeg);
}
}
}
/* The cksum argument passed to this function is a checksum calculated
** based on all expected entries in the FTS index (including prefix index
** entries). This block checks that a checksum calculated based on the
** actual contents of FTS index is identical.
**
** Two versions of the same checksum are calculated. The first (stack
** variable cksum2) based on entries extracted from the full-text index
** while doing a linear scan of each individual index in turn.
**
** As each term visited by the linear scans, a separate query for the
** same term is performed. cksum3 is calculated based on the entries
** extracted by these queries.
*/
for(fts5MultiIterNew(p, pStruct, flags, 0, 0, 0, -1, 0, &pIter);
fts5MultiIterEof(p, pIter)==0;
fts5MultiIterNext(p, pIter, 0, 0)
){
int n; /* Size of term in bytes */
i64 iPos = 0; /* Position read from poslist */
int iOff = 0; /* Offset within poslist */
i64 iRowid = fts5MultiIterRowid(pIter);
char *z = (char*)fts5MultiIterTerm(pIter, &n);
/* If this is a new term, query for it. Update cksum3 with the results. */
fts5TestTerm(p, &term, z, n, cksum2, &cksum3);
if( eDetail==FTS5_DETAIL_NONE ){
if( 0==fts5MultiIterIsEmpty(p, pIter) ){
cksum2 ^= sqlite3Fts5IndexEntryCksum(iRowid, 0, 0, -1, z, n);
}
}else{
poslist.n = 0;
fts5SegiterPoslist(p, &pIter->aSeg[pIter->aFirst[1].iFirst], 0, &poslist);
fts5BufferAppendBlob(&p->rc, &poslist, 4, (const u8*)"\0\0\0\0");
while( 0==sqlite3Fts5PoslistNext64(poslist.p, poslist.n, &iOff, &iPos) ){
int iCol = FTS5_POS2COLUMN(iPos);
int iTokOff = FTS5_POS2OFFSET(iPos);
cksum2 ^= sqlite3Fts5IndexEntryCksum(iRowid, iCol, iTokOff, -1, z, n);
}
}
}
fts5TestTerm(p, &term, 0, 0, cksum2, &cksum3);
fts5MultiIterFree(pIter);
if( p->rc==SQLITE_OK && bUseCksum && cksum!=cksum2 ) p->rc = FTS5_CORRUPT;
fts5StructureRelease(pStruct);
#ifdef SQLITE_DEBUG
fts5BufferFree(&term);
#endif
fts5BufferFree(&poslist);
return fts5IndexReturn(p);
}
/*************************************************************************
**************************************************************************
** Below this point is the implementation of the fts5_decode() scalar
** function only.
*/
/*
** Decode a segment-data rowid from the %_data table. This function is
** the opposite of macro FTS5_SEGMENT_ROWID().
*/
static void fts5DecodeRowid(
i64 iRowid, /* Rowid from %_data table */
int *piSegid, /* OUT: Segment id */
int *pbDlidx, /* OUT: Dlidx flag */
int *piHeight, /* OUT: Height */
int *piPgno /* OUT: Page number */
){
*piPgno = (int)(iRowid & (((i64)1 << FTS5_DATA_PAGE_B) - 1));
iRowid >>= FTS5_DATA_PAGE_B;
*piHeight = (int)(iRowid & (((i64)1 << FTS5_DATA_HEIGHT_B) - 1));
iRowid >>= FTS5_DATA_HEIGHT_B;
*pbDlidx = (int)(iRowid & 0x0001);
iRowid >>= FTS5_DATA_DLI_B;
*piSegid = (int)(iRowid & (((i64)1 << FTS5_DATA_ID_B) - 1));
}
static void fts5DebugRowid(int *pRc, Fts5Buffer *pBuf, i64 iKey){
int iSegid, iHeight, iPgno, bDlidx; /* Rowid compenents */
fts5DecodeRowid(iKey, &iSegid, &bDlidx, &iHeight, &iPgno);
if( iSegid==0 ){
if( iKey==FTS5_AVERAGES_ROWID ){
sqlite3Fts5BufferAppendPrintf(pRc, pBuf, "{averages} ");
}else{
sqlite3Fts5BufferAppendPrintf(pRc, pBuf, "{structure}");
}
}
else{
sqlite3Fts5BufferAppendPrintf(pRc, pBuf, "{%ssegid=%d h=%d pgno=%d}",
bDlidx ? "dlidx " : "", iSegid, iHeight, iPgno
);
}
}
static void fts5DebugStructure(
int *pRc, /* IN/OUT: error code */
Fts5Buffer *pBuf,
Fts5Structure *p
){
int iLvl, iSeg; /* Iterate through levels, segments */
for(iLvl=0; iLvl<p->nLevel; iLvl++){
Fts5StructureLevel *pLvl = &p->aLevel[iLvl];
sqlite3Fts5BufferAppendPrintf(pRc, pBuf,
" {lvl=%d nMerge=%d nSeg=%d", iLvl, pLvl->nMerge, pLvl->nSeg
);
for(iSeg=0; iSeg<pLvl->nSeg; iSeg++){
Fts5StructureSegment *pSeg = &pLvl->aSeg[iSeg];
sqlite3Fts5BufferAppendPrintf(pRc, pBuf, " {id=%d leaves=%d..%d}",
pSeg->iSegid, pSeg->pgnoFirst, pSeg->pgnoLast
);
}
sqlite3Fts5BufferAppendPrintf(pRc, pBuf, "}");
}
}
/*
** This is part of the fts5_decode() debugging aid.
**
** Arguments pBlob/nBlob contain a serialized Fts5Structure object. This
** function appends a human-readable representation of the same object
** to the buffer passed as the second argument.
*/
static void fts5DecodeStructure(
int *pRc, /* IN/OUT: error code */
Fts5Buffer *pBuf,
const u8 *pBlob, int nBlob
){
int rc; /* Return code */
Fts5Structure *p = 0; /* Decoded structure object */
rc = fts5StructureDecode(pBlob, nBlob, 0, &p);
if( rc!=SQLITE_OK ){
*pRc = rc;
return;
}
fts5DebugStructure(pRc, pBuf, p);
fts5StructureRelease(p);
}
/*
** This is part of the fts5_decode() debugging aid.
**
** Arguments pBlob/nBlob contain an "averages" record. This function
** appends a human-readable representation of record to the buffer passed
** as the second argument.
*/
static void fts5DecodeAverages(
int *pRc, /* IN/OUT: error code */
Fts5Buffer *pBuf,
const u8 *pBlob, int nBlob
){
int i = 0;
const char *zSpace = "";
while( i<nBlob ){
u64 iVal;
i += sqlite3Fts5GetVarint(&pBlob[i], &iVal);
sqlite3Fts5BufferAppendPrintf(pRc, pBuf, "%s%d", zSpace, (int)iVal);
zSpace = " ";
}
}
/*
** Buffer (a/n) is assumed to contain a list of serialized varints. Read
** each varint and append its string representation to buffer pBuf. Return
** after either the input buffer is exhausted or a 0 value is read.
**
** The return value is the number of bytes read from the input buffer.
*/
static int fts5DecodePoslist(int *pRc, Fts5Buffer *pBuf, const u8 *a, int n){
int iOff = 0;
while( iOff<n ){
int iVal;
iOff += fts5GetVarint32(&a[iOff], iVal);
sqlite3Fts5BufferAppendPrintf(pRc, pBuf, " %d", iVal);
}
return iOff;
}
/*
** The start of buffer (a/n) contains the start of a doclist. The doclist
** may or may not finish within the buffer. This function appends a text
** representation of the part of the doclist that is present to buffer
** pBuf.
**
** The return value is the number of bytes read from the input buffer.
*/
static int fts5DecodeDoclist(int *pRc, Fts5Buffer *pBuf, const u8 *a, int n){
i64 iDocid = 0;
int iOff = 0;
if( n>0 ){
iOff = sqlite3Fts5GetVarint(a, (u64*)&iDocid);
sqlite3Fts5BufferAppendPrintf(pRc, pBuf, " id=%lld", iDocid);
}
while( iOff<n ){
int nPos;
int bDel;
iOff += fts5GetPoslistSize(&a[iOff], &nPos, &bDel);
sqlite3Fts5BufferAppendPrintf(pRc, pBuf, " nPos=%d%s", nPos, bDel?"*":"");
iOff += fts5DecodePoslist(pRc, pBuf, &a[iOff], MIN(n-iOff, nPos));
if( iOff<n ){
i64 iDelta;
iOff += sqlite3Fts5GetVarint(&a[iOff], (u64*)&iDelta);
iDocid += iDelta;
sqlite3Fts5BufferAppendPrintf(pRc, pBuf, " id=%lld", iDocid);
}
}
return iOff;
}
/*
** This function is part of the fts5_decode() debugging function. It is
** only ever used with detail=none tables.
**
** Buffer (pData/nData) contains a doclist in the format used by detail=none
** tables. This function appends a human-readable version of that list to
** buffer pBuf.
**
** If *pRc is other than SQLITE_OK when this function is called, it is a
** no-op. If an OOM or other error occurs within this function, *pRc is
** set to an SQLite error code before returning. The final state of buffer
** pBuf is undefined in this case.
*/
static void fts5DecodeRowidList(
int *pRc, /* IN/OUT: Error code */
Fts5Buffer *pBuf, /* Buffer to append text to */
const u8 *pData, int nData /* Data to decode list-of-rowids from */
){
int i = 0;
i64 iRowid = 0;
while( i<nData ){
const char *zApp = "";
u64 iVal;
i += sqlite3Fts5GetVarint(&pData[i], &iVal);
iRowid += iVal;
if( i<nData && pData[i]==0x00 ){
i++;
if( i<nData && pData[i]==0x00 ){
i++;
zApp = "+";
}else{
zApp = "*";
}
}
sqlite3Fts5BufferAppendPrintf(pRc, pBuf, " %lld%s", iRowid, zApp);
}
}
/*
** The implementation of user-defined scalar function fts5_decode().
*/
static void fts5DecodeFunction(
sqlite3_context *pCtx, /* Function call context */
int nArg, /* Number of args (always 2) */
sqlite3_value **apVal /* Function arguments */
){
i64 iRowid; /* Rowid for record being decoded */
int iSegid,iHeight,iPgno,bDlidx;/* Rowid components */
const u8 *aBlob; int n; /* Record to decode */
u8 *a = 0;
Fts5Buffer s; /* Build up text to return here */
int rc = SQLITE_OK; /* Return code */
sqlite3_int64 nSpace = 0;
int eDetailNone = (sqlite3_user_data(pCtx)!=0);
assert( nArg==2 );
UNUSED_PARAM(nArg);
memset(&s, 0, sizeof(Fts5Buffer));
iRowid = sqlite3_value_int64(apVal[0]);
/* Make a copy of the second argument (a blob) in aBlob[]. The aBlob[]
** copy is followed by FTS5_DATA_ZERO_PADDING 0x00 bytes, which prevents
** buffer overreads even if the record is corrupt. */
n = sqlite3_value_bytes(apVal[1]);
aBlob = sqlite3_value_blob(apVal[1]);
nSpace = n + FTS5_DATA_ZERO_PADDING;
a = (u8*)sqlite3Fts5MallocZero(&rc, nSpace);
if( a==0 ) goto decode_out;
if( n>0 ) memcpy(a, aBlob, n);
fts5DecodeRowid(iRowid, &iSegid, &bDlidx, &iHeight, &iPgno);
fts5DebugRowid(&rc, &s, iRowid);
if( bDlidx ){
Fts5Data dlidx;
Fts5DlidxLvl lvl;
dlidx.p = a;
dlidx.nn = n;
memset(&lvl, 0, sizeof(Fts5DlidxLvl));
lvl.pData = &dlidx;
lvl.iLeafPgno = iPgno;
for(fts5DlidxLvlNext(&lvl); lvl.bEof==0; fts5DlidxLvlNext(&lvl)){
sqlite3Fts5BufferAppendPrintf(&rc, &s,
" %d(%lld)", lvl.iLeafPgno, lvl.iRowid
);
}
}else if( iSegid==0 ){
if( iRowid==FTS5_AVERAGES_ROWID ){
fts5DecodeAverages(&rc, &s, a, n);
}else{
fts5DecodeStructure(&rc, &s, a, n);
}
}else if( eDetailNone ){
Fts5Buffer term; /* Current term read from page */
int szLeaf;
int iPgidxOff = szLeaf = fts5GetU16(&a[2]);
int iTermOff;
int nKeep = 0;
int iOff;
memset(&term, 0, sizeof(Fts5Buffer));
/* Decode any entries that occur before the first term. */
if( szLeaf<n ){
iPgidxOff += fts5GetVarint32(&a[iPgidxOff], iTermOff);
}else{
iTermOff = szLeaf;
}
fts5DecodeRowidList(&rc, &s, &a[4], iTermOff-4);
iOff = iTermOff;
while( iOff<szLeaf ){
int nAppend;
/* Read the term data for the next term*/
iOff += fts5GetVarint32(&a[iOff], nAppend);
term.n = nKeep;
fts5BufferAppendBlob(&rc, &term, nAppend, &a[iOff]);
sqlite3Fts5BufferAppendPrintf(
&rc, &s, " term=%.*s", term.n, (const char*)term.p
);
iOff += nAppend;
/* Figure out where the doclist for this term ends */
if( iPgidxOff<n ){
int nIncr;
iPgidxOff += fts5GetVarint32(&a[iPgidxOff], nIncr);
iTermOff += nIncr;
}else{
iTermOff = szLeaf;
}
fts5DecodeRowidList(&rc, &s, &a[iOff], iTermOff-iOff);
iOff = iTermOff;
if( iOff<szLeaf ){
iOff += fts5GetVarint32(&a[iOff], nKeep);
}
}
fts5BufferFree(&term);
}else{
Fts5Buffer term; /* Current term read from page */
int szLeaf; /* Offset of pgidx in a[] */
int iPgidxOff;
int iPgidxPrev = 0; /* Previous value read from pgidx */
int iTermOff = 0;
int iRowidOff = 0;
int iOff;
int nDoclist;
memset(&term, 0, sizeof(Fts5Buffer));
if( n<4 ){
sqlite3Fts5BufferSet(&rc, &s, 7, (const u8*)"corrupt");
goto decode_out;
}else{
iRowidOff = fts5GetU16(&a[0]);
iPgidxOff = szLeaf = fts5GetU16(&a[2]);
if( iPgidxOff<n ){
fts5GetVarint32(&a[iPgidxOff], iTermOff);
}else if( iPgidxOff>n ){
rc = FTS5_CORRUPT;
goto decode_out;
}
}
/* Decode the position list tail at the start of the page */
if( iRowidOff!=0 ){
iOff = iRowidOff;
}else if( iTermOff!=0 ){
iOff = iTermOff;
}else{
iOff = szLeaf;
}
if( iOff>n ){
rc = FTS5_CORRUPT;
goto decode_out;
}
fts5DecodePoslist(&rc, &s, &a[4], iOff-4);
/* Decode any more doclist data that appears on the page before the
** first term. */
nDoclist = (iTermOff ? iTermOff : szLeaf) - iOff;
if( nDoclist+iOff>n ){
rc = FTS5_CORRUPT;
goto decode_out;
}
fts5DecodeDoclist(&rc, &s, &a[iOff], nDoclist);
while( iPgidxOff<n && rc==SQLITE_OK ){
int bFirst = (iPgidxOff==szLeaf); /* True for first term on page */
int nByte; /* Bytes of data */
int iEnd;
iPgidxOff += fts5GetVarint32(&a[iPgidxOff], nByte);
iPgidxPrev += nByte;
iOff = iPgidxPrev;
if( iPgidxOff<n ){
fts5GetVarint32(&a[iPgidxOff], nByte);
iEnd = iPgidxPrev + nByte;
}else{
iEnd = szLeaf;
}
if( iEnd>szLeaf ){
rc = FTS5_CORRUPT;
break;
}
if( bFirst==0 ){
iOff += fts5GetVarint32(&a[iOff], nByte);
if( nByte>term.n ){
rc = FTS5_CORRUPT;
break;
}
term.n = nByte;
}
iOff += fts5GetVarint32(&a[iOff], nByte);
if( iOff+nByte>n ){
rc = FTS5_CORRUPT;
break;
}
fts5BufferAppendBlob(&rc, &term, nByte, &a[iOff]);
iOff += nByte;
sqlite3Fts5BufferAppendPrintf(
&rc, &s, " term=%.*s", term.n, (const char*)term.p
);
iOff += fts5DecodeDoclist(&rc, &s, &a[iOff], iEnd-iOff);
}
fts5BufferFree(&term);
}
decode_out:
sqlite3_free(a);
if( rc==SQLITE_OK ){
sqlite3_result_text(pCtx, (const char*)s.p, s.n, SQLITE_TRANSIENT);
}else{
sqlite3_result_error_code(pCtx, rc);
}
fts5BufferFree(&s);
}
/*
** The implementation of user-defined scalar function fts5_rowid().
*/
static void fts5RowidFunction(
sqlite3_context *pCtx, /* Function call context */
int nArg, /* Number of args (always 2) */
sqlite3_value **apVal /* Function arguments */
){
const char *zArg;
if( nArg==0 ){
sqlite3_result_error(pCtx, "should be: fts5_rowid(subject, ....)", -1);
}else{
zArg = (const char*)sqlite3_value_text(apVal[0]);
if( 0==sqlite3_stricmp(zArg, "segment") ){
i64 iRowid;
int segid, pgno;
if( nArg!=3 ){
sqlite3_result_error(pCtx,
"should be: fts5_rowid('segment', segid, pgno))", -1
);
}else{
segid = sqlite3_value_int(apVal[1]);
pgno = sqlite3_value_int(apVal[2]);
iRowid = FTS5_SEGMENT_ROWID(segid, pgno);
sqlite3_result_int64(pCtx, iRowid);
}
}else{
sqlite3_result_error(pCtx,
"first arg to fts5_rowid() must be 'segment'" , -1
);
}
}
}
/*
** This is called as part of registering the FTS5 module with database
** connection db. It registers several user-defined scalar functions useful
** with FTS5.
**
** If successful, SQLITE_OK is returned. If an error occurs, some other
** SQLite error code is returned instead.
*/
static int sqlite3Fts5IndexInit(sqlite3 *db){
int rc = sqlite3_create_function(
db, "fts5_decode", 2, SQLITE_UTF8, 0, fts5DecodeFunction, 0, 0
);
if( rc==SQLITE_OK ){
rc = sqlite3_create_function(
db, "fts5_decode_none", 2,
SQLITE_UTF8, (void*)db, fts5DecodeFunction, 0, 0
);
}
if( rc==SQLITE_OK ){
rc = sqlite3_create_function(
db, "fts5_rowid", -1, SQLITE_UTF8, 0, fts5RowidFunction, 0, 0
);
}
return rc;
}
static int sqlite3Fts5IndexReset(Fts5Index *p){
assert( p->pStruct==0 || p->iStructVersion!=0 );
if( fts5IndexDataVersion(p)!=p->iStructVersion ){
fts5StructureInvalidate(p);
}
return fts5IndexReturn(p);
}
#line 1 "fts5_main.c"
/*
** 2014 Jun 09
**
** The author disclaims copyright to this source code. In place of
** a legal notice, here is a blessing:
**
** May you do good and not evil.
** May you find forgiveness for yourself and forgive others.
** May you share freely, never taking more than you give.
**
******************************************************************************
**
** This is an SQLite module implementing full-text search.
*/
/* #include "third_party/sqlite3/fts5Int.h" */
/*
** This variable is set to false when running tests for which the on disk
** structures should not be corrupt. Otherwise, true. If it is false, extra
** assert() conditions in the fts5 code are activated - conditions that are
** only true if it is guaranteed that the fts5 database is not corrupt.
*/
int sqlite3_fts5_may_be_corrupt = 1;
typedef struct Fts5Auxdata Fts5Auxdata;
typedef struct Fts5Auxiliary Fts5Auxiliary;
typedef struct Fts5Cursor Fts5Cursor;
typedef struct Fts5FullTable Fts5FullTable;
typedef struct Fts5Sorter Fts5Sorter;
typedef struct Fts5TokenizerModule Fts5TokenizerModule;
/*
** NOTES ON TRANSACTIONS:
**
** SQLite invokes the following virtual table methods as transactions are
** opened and closed by the user:
**
** xBegin(): Start of a new transaction.
** xSync(): Initial part of two-phase commit.
** xCommit(): Final part of two-phase commit.
** xRollback(): Rollback the transaction.
**
** Anything that is required as part of a commit that may fail is performed
** in the xSync() callback. Current versions of SQLite ignore any errors
** returned by xCommit().
**
** And as sub-transactions are opened/closed:
**
** xSavepoint(int S): Open savepoint S.
** xRelease(int S): Commit and close savepoint S.
** xRollbackTo(int S): Rollback to start of savepoint S.
**
** During a write-transaction the fts5_index.c module may cache some data
** in-memory. It is flushed to disk whenever xSync(), xRelease() or
** xSavepoint() is called. And discarded whenever xRollback() or xRollbackTo()
** is called.
**
** Additionally, if SQLITE_DEBUG is defined, an instance of the following
** structure is used to record the current transaction state. This information
** is not required, but it is used in the assert() statements executed by
** function fts5CheckTransactionState() (see below).
*/
struct Fts5TransactionState {
int eState; /* 0==closed, 1==open, 2==synced */
int iSavepoint; /* Number of open savepoints (0 -> none) */
};
/*
** A single object of this type is allocated when the FTS5 module is
** registered with a database handle. It is used to store pointers to
** all registered FTS5 extensions - tokenizers and auxiliary functions.
*/
struct Fts5Global {
fts5_api api; /* User visible part of object (see fts5.h) */
sqlite3 *db; /* Associated database connection */
i64 iNextId; /* Used to allocate unique cursor ids */
Fts5Auxiliary *pAux; /* First in list of all aux. functions */
Fts5TokenizerModule *pTok; /* First in list of all tokenizer modules */
Fts5TokenizerModule *pDfltTok; /* Default tokenizer module */
Fts5Cursor *pCsr; /* First in list of all open cursors */
};
/*
** Each auxiliary function registered with the FTS5 module is represented
** by an object of the following type. All such objects are stored as part
** of the Fts5Global.pAux list.
*/
struct Fts5Auxiliary {
Fts5Global *pGlobal; /* Global context for this function */
char *zFunc; /* Function name (nul-terminated) */
void *pUserData; /* User-data pointer */
fts5_extension_function xFunc; /* Callback function */
void (*xDestroy)(void*); /* Destructor function */
Fts5Auxiliary *pNext; /* Next registered auxiliary function */
};
/*
** Each tokenizer module registered with the FTS5 module is represented
** by an object of the following type. All such objects are stored as part
** of the Fts5Global.pTok list.
*/
struct Fts5TokenizerModule {
char *zName; /* Name of tokenizer */
void *pUserData; /* User pointer passed to xCreate() */
fts5_tokenizer x; /* Tokenizer functions */
void (*xDestroy)(void*); /* Destructor function */
Fts5TokenizerModule *pNext; /* Next registered tokenizer module */
};
struct Fts5FullTable {
Fts5Table p; /* Public class members from fts5Int.h */
Fts5Storage *pStorage; /* Document store */
Fts5Global *pGlobal; /* Global (connection wide) data */
Fts5Cursor *pSortCsr; /* Sort data from this cursor */
#ifdef SQLITE_DEBUG
struct Fts5TransactionState ts;
#endif
};
struct Fts5MatchPhrase {
Fts5Buffer *pPoslist; /* Pointer to current poslist */
int nTerm; /* Size of phrase in terms */
};
/*
** pStmt:
** SELECT rowid, <fts> FROM <fts> ORDER BY +rank;
**
** aIdx[]:
** There is one entry in the aIdx[] array for each phrase in the query,
** the value of which is the offset within aPoslist[] following the last
** byte of the position list for the corresponding phrase.
*/
struct Fts5Sorter {
sqlite3_stmt *pStmt;
i64 iRowid; /* Current rowid */
const u8 *aPoslist; /* Position lists for current row */
int nIdx; /* Number of entries in aIdx[] */
int aIdx[1]; /* Offsets into aPoslist for current row */
};
/*
** Virtual-table cursor object.
**
** iSpecial:
** If this is a 'special' query (refer to function fts5SpecialMatch()),
** then this variable contains the result of the query.
**
** iFirstRowid, iLastRowid:
** These variables are only used for FTS5_PLAN_MATCH cursors. Assuming the
** cursor iterates in ascending order of rowids, iFirstRowid is the lower
** limit of rowids to return, and iLastRowid the upper. In other words, the
** WHERE clause in the user's query might have been:
**
** <tbl> MATCH <expr> AND rowid BETWEEN $iFirstRowid AND $iLastRowid
**
** If the cursor iterates in descending order of rowid, iFirstRowid
** is the upper limit (i.e. the "first" rowid visited) and iLastRowid
** the lower.
*/
struct Fts5Cursor {
sqlite3_vtab_cursor base; /* Base class used by SQLite core */
Fts5Cursor *pNext; /* Next cursor in Fts5Cursor.pCsr list */
int *aColumnSize; /* Values for xColumnSize() */
i64 iCsrId; /* Cursor id */
/* Zero from this point onwards on cursor reset */
int ePlan; /* FTS5_PLAN_XXX value */
int bDesc; /* True for "ORDER BY rowid DESC" queries */
i64 iFirstRowid; /* Return no rowids earlier than this */
i64 iLastRowid; /* Return no rowids later than this */
sqlite3_stmt *pStmt; /* Statement used to read %_content */
Fts5Expr *pExpr; /* Expression for MATCH queries */
Fts5Sorter *pSorter; /* Sorter for "ORDER BY rank" queries */
int csrflags; /* Mask of cursor flags (see below) */
i64 iSpecial; /* Result of special query */
/* "rank" function. Populated on demand from vtab.xColumn(). */
char *zRank; /* Custom rank function */
char *zRankArgs; /* Custom rank function args */
Fts5Auxiliary *pRank; /* Rank callback (or NULL) */
int nRankArg; /* Number of trailing arguments for rank() */
sqlite3_value **apRankArg; /* Array of trailing arguments */
sqlite3_stmt *pRankArgStmt; /* Origin of objects in apRankArg[] */
/* Auxiliary data storage */
Fts5Auxiliary *pAux; /* Currently executing extension function */
Fts5Auxdata *pAuxdata; /* First in linked list of saved aux-data */
/* Cache used by auxiliary functions xInst() and xInstCount() */
Fts5PoslistReader *aInstIter; /* One for each phrase */
int nInstAlloc; /* Size of aInst[] array (entries / 3) */
int nInstCount; /* Number of phrase instances */
int *aInst; /* 3 integers per phrase instance */
};
/*
** Bits that make up the "idxNum" parameter passed indirectly by
** xBestIndex() to xFilter().
*/
#define FTS5_BI_MATCH 0x0001 /* <tbl> MATCH ? */
#define FTS5_BI_RANK 0x0002 /* rank MATCH ? */
#define FTS5_BI_ROWID_EQ 0x0004 /* rowid == ? */
#define FTS5_BI_ROWID_LE 0x0008 /* rowid <= ? */
#define FTS5_BI_ROWID_GE 0x0010 /* rowid >= ? */
#define FTS5_BI_ORDER_RANK 0x0020
#define FTS5_BI_ORDER_ROWID 0x0040
#define FTS5_BI_ORDER_DESC 0x0080
/*
** Values for Fts5Cursor.csrflags
*/
#define FTS5CSR_EOF 0x01
#define FTS5CSR_REQUIRE_CONTENT 0x02
#define FTS5CSR_REQUIRE_DOCSIZE 0x04
#define FTS5CSR_REQUIRE_INST 0x08
#define FTS5CSR_FREE_ZRANK 0x10
#define FTS5CSR_REQUIRE_RESEEK 0x20
#define FTS5CSR_REQUIRE_POSLIST 0x40
#define BitFlagAllTest(x,y) (((x) & (y))==(y))
#define BitFlagTest(x,y) (((x) & (y))!=0)
/*
** Macros to Set(), Clear() and Test() cursor flags.
*/
#define CsrFlagSet(pCsr, flag) ((pCsr)->csrflags |= (flag))
#define CsrFlagClear(pCsr, flag) ((pCsr)->csrflags &= ~(flag))
#define CsrFlagTest(pCsr, flag) ((pCsr)->csrflags & (flag))
struct Fts5Auxdata {
Fts5Auxiliary *pAux; /* Extension to which this belongs */
void *pPtr; /* Pointer value */
void(*xDelete)(void*); /* Destructor */
Fts5Auxdata *pNext; /* Next object in linked list */
};
#ifdef SQLITE_DEBUG
#define FTS5_BEGIN 1
#define FTS5_SYNC 2
#define FTS5_COMMIT 3
#define FTS5_ROLLBACK 4
#define FTS5_SAVEPOINT 5
#define FTS5_RELEASE 6
#define FTS5_ROLLBACKTO 7
static void fts5CheckTransactionState(Fts5FullTable *p, int op, int iSavepoint){
switch( op ){
case FTS5_BEGIN:
assert( p->ts.eState==0 );
p->ts.eState = 1;
p->ts.iSavepoint = -1;
break;
case FTS5_SYNC:
assert( p->ts.eState==1 );
p->ts.eState = 2;
break;
case FTS5_COMMIT:
assert( p->ts.eState==2 );
p->ts.eState = 0;
break;
case FTS5_ROLLBACK:
assert( p->ts.eState==1 || p->ts.eState==2 || p->ts.eState==0 );
p->ts.eState = 0;
break;
case FTS5_SAVEPOINT:
assert( p->ts.eState==1 );
assert( iSavepoint>=0 );
assert( iSavepoint>=p->ts.iSavepoint );
p->ts.iSavepoint = iSavepoint;
break;
case FTS5_RELEASE:
assert( p->ts.eState==1 );
assert( iSavepoint>=0 );
assert( iSavepoint<=p->ts.iSavepoint );
p->ts.iSavepoint = iSavepoint-1;
break;
case FTS5_ROLLBACKTO:
assert( p->ts.eState==1 );
assert( iSavepoint>=-1 );
/* The following assert() can fail if another vtab strikes an error
** within an xSavepoint() call then SQLite calls xRollbackTo() - without
** having called xSavepoint() on this vtab. */
/* assert( iSavepoint<=p->ts.iSavepoint ); */
p->ts.iSavepoint = iSavepoint;
break;
}
}
#else
# define fts5CheckTransactionState(x,y,z)
#endif
/*
** Return true if pTab is a contentless table.
*/
static int fts5IsContentless(Fts5FullTable *pTab){
return pTab->p.pConfig->eContent==FTS5_CONTENT_NONE;
}
/*
** Delete a virtual table handle allocated by fts5InitVtab().
*/
static void fts5FreeVtab(Fts5FullTable *pTab){
if( pTab ){
sqlite3Fts5IndexClose(pTab->p.pIndex);
sqlite3Fts5StorageClose(pTab->pStorage);
sqlite3Fts5ConfigFree(pTab->p.pConfig);
sqlite3_free(pTab);
}
}
/*
** The xDisconnect() virtual table method.
*/
static int fts5DisconnectMethod(sqlite3_vtab *pVtab){
fts5FreeVtab((Fts5FullTable*)pVtab);
return SQLITE_OK;
}
/*
** The xDestroy() virtual table method.
*/
static int fts5DestroyMethod(sqlite3_vtab *pVtab){
Fts5Table *pTab = (Fts5Table*)pVtab;
int rc = sqlite3Fts5DropAll(pTab->pConfig);
if( rc==SQLITE_OK ){
fts5FreeVtab((Fts5FullTable*)pVtab);
}
return rc;
}
/*
** This function is the implementation of both the xConnect and xCreate
** methods of the FTS3 virtual table.
**
** The argv[] array contains the following:
**
** argv[0] -> module name ("fts5")
** argv[1] -> database name
** argv[2] -> table name
** argv[...] -> "column name" and other module argument fields.
*/
static int fts5InitVtab(
int bCreate, /* True for xCreate, false for xConnect */
sqlite3 *db, /* The SQLite database connection */
void *pAux, /* Hash table containing tokenizers */
int argc, /* Number of elements in argv array */
const char * const *argv, /* xCreate/xConnect argument array */
sqlite3_vtab **ppVTab, /* Write the resulting vtab structure here */
char **pzErr /* Write any error message here */
){
Fts5Global *pGlobal = (Fts5Global*)pAux;
const char **azConfig = (const char**)argv;
int rc = SQLITE_OK; /* Return code */
Fts5Config *pConfig = 0; /* Results of parsing argc/argv */
Fts5FullTable *pTab = 0; /* New virtual table object */
/* Allocate the new vtab object and parse the configuration */
pTab = (Fts5FullTable*)sqlite3Fts5MallocZero(&rc, sizeof(Fts5FullTable));
if( rc==SQLITE_OK ){
rc = sqlite3Fts5ConfigParse(pGlobal, db, argc, azConfig, &pConfig, pzErr);
assert( (rc==SQLITE_OK && *pzErr==0) || pConfig==0 );
}
if( rc==SQLITE_OK ){
pTab->p.pConfig = pConfig;
pTab->pGlobal = pGlobal;
}
/* Open the index sub-system */
if( rc==SQLITE_OK ){
rc = sqlite3Fts5IndexOpen(pConfig, bCreate, &pTab->p.pIndex, pzErr);
}
/* Open the storage sub-system */
if( rc==SQLITE_OK ){
rc = sqlite3Fts5StorageOpen(
pConfig, pTab->p.pIndex, bCreate, &pTab->pStorage, pzErr
);
}
/* Call sqlite3_declare_vtab() */
if( rc==SQLITE_OK ){
rc = sqlite3Fts5ConfigDeclareVtab(pConfig);
}
/* Load the initial configuration */
if( rc==SQLITE_OK ){
assert( pConfig->pzErrmsg==0 );
pConfig->pzErrmsg = pzErr;
rc = sqlite3Fts5IndexLoadConfig(pTab->p.pIndex);
sqlite3Fts5IndexRollback(pTab->p.pIndex);
pConfig->pzErrmsg = 0;
}
if( rc!=SQLITE_OK ){
fts5FreeVtab(pTab);
pTab = 0;
}else if( bCreate ){
fts5CheckTransactionState(pTab, FTS5_BEGIN, 0);
}
*ppVTab = (sqlite3_vtab*)pTab;
return rc;
}
/*
** The xConnect() and xCreate() methods for the virtual table. All the
** work is done in function fts5InitVtab().
*/
static int fts5ConnectMethod(
sqlite3 *db, /* Database connection */
void *pAux, /* Pointer to tokenizer hash table */
int argc, /* Number of elements in argv array */
const char * const *argv, /* xCreate/xConnect argument array */
sqlite3_vtab **ppVtab, /* OUT: New sqlite3_vtab object */
char **pzErr /* OUT: sqlite3_malloc'd error message */
){
return fts5InitVtab(0, db, pAux, argc, argv, ppVtab, pzErr);
}
static int fts5CreateMethod(
sqlite3 *db, /* Database connection */
void *pAux, /* Pointer to tokenizer hash table */
int argc, /* Number of elements in argv array */
const char * const *argv, /* xCreate/xConnect argument array */
sqlite3_vtab **ppVtab, /* OUT: New sqlite3_vtab object */
char **pzErr /* OUT: sqlite3_malloc'd error message */
){
return fts5InitVtab(1, db, pAux, argc, argv, ppVtab, pzErr);
}
/*
** The different query plans.
*/
#define FTS5_PLAN_MATCH 1 /* (<tbl> MATCH ?) */
#define FTS5_PLAN_SOURCE 2 /* A source cursor for SORTED_MATCH */
#define FTS5_PLAN_SPECIAL 3 /* An internal query */
#define FTS5_PLAN_SORTED_MATCH 4 /* (<tbl> MATCH ? ORDER BY rank) */
#define FTS5_PLAN_SCAN 5 /* No usable constraint */
#define FTS5_PLAN_ROWID 6 /* (rowid = ?) */
/*
** Set the SQLITE_INDEX_SCAN_UNIQUE flag in pIdxInfo->flags. Unless this
** extension is currently being used by a version of SQLite too old to
** support index-info flags. In that case this function is a no-op.
*/
static void fts5SetUniqueFlag(sqlite3_index_info *pIdxInfo){
#if SQLITE_VERSION_NUMBER>=3008012
#ifndef SQLITE_CORE
if( sqlite3_libversion_number()>=3008012 )
#endif
{
pIdxInfo->idxFlags |= SQLITE_INDEX_SCAN_UNIQUE;
}
#endif
}
static int fts5UsePatternMatch(
Fts5Config *pConfig,
struct sqlite3_index_constraint *p
){
assert( FTS5_PATTERN_GLOB==SQLITE_INDEX_CONSTRAINT_GLOB );
assert( FTS5_PATTERN_LIKE==SQLITE_INDEX_CONSTRAINT_LIKE );
if( pConfig->ePattern==FTS5_PATTERN_GLOB && p->op==FTS5_PATTERN_GLOB ){
return 1;
}
if( pConfig->ePattern==FTS5_PATTERN_LIKE
&& (p->op==FTS5_PATTERN_LIKE || p->op==FTS5_PATTERN_GLOB)
){
return 1;
}
return 0;
}
/*
** Implementation of the xBestIndex method for FTS5 tables. Within the
** WHERE constraint, it searches for the following:
**
** 1. A MATCH constraint against the table column.
** 2. A MATCH constraint against the "rank" column.
** 3. A MATCH constraint against some other column.
** 4. An == constraint against the rowid column.
** 5. A < or <= constraint against the rowid column.
** 6. A > or >= constraint against the rowid column.
**
** Within the ORDER BY, the following are supported:
**
** 5. ORDER BY rank [ASC|DESC]
** 6. ORDER BY rowid [ASC|DESC]
**
** Information for the xFilter call is passed via both the idxNum and
** idxStr variables. Specifically, idxNum is a bitmask of the following
** flags used to encode the ORDER BY clause:
**
** FTS5_BI_ORDER_RANK
** FTS5_BI_ORDER_ROWID
** FTS5_BI_ORDER_DESC
**
** idxStr is used to encode data from the WHERE clause. For each argument
** passed to the xFilter method, the following is appended to idxStr:
**
** Match against table column: "m"
** Match against rank column: "r"
** Match against other column: "M<column-number>"
** LIKE against other column: "L<column-number>"
** GLOB against other column: "G<column-number>"
** Equality constraint against the rowid: "="
** A < or <= against the rowid: "<"
** A > or >= against the rowid: ">"
**
** This function ensures that there is at most one "r" or "=". And that if
** there exists an "=" then there is no "<" or ">".
**
** Costs are assigned as follows:
**
** a) If an unusable MATCH operator is present in the WHERE clause, the
** cost is unconditionally set to 1e50 (a really big number).
**
** a) If a MATCH operator is present, the cost depends on the other
** constraints also present. As follows:
**
** * No other constraints: cost=1000.0
** * One rowid range constraint: cost=750.0
** * Both rowid range constraints: cost=500.0
** * An == rowid constraint: cost=100.0
**
** b) Otherwise, if there is no MATCH:
**
** * No other constraints: cost=1000000.0
** * One rowid range constraint: cost=750000.0
** * Both rowid range constraints: cost=250000.0
** * An == rowid constraint: cost=10.0
**
** Costs are not modified by the ORDER BY clause.
*/
static int fts5BestIndexMethod(sqlite3_vtab *pVTab, sqlite3_index_info *pInfo){
Fts5Table *pTab = (Fts5Table*)pVTab;
Fts5Config *pConfig = pTab->pConfig;
const int nCol = pConfig->nCol;
int idxFlags = 0; /* Parameter passed through to xFilter() */
int i;
char *idxStr;
int iIdxStr = 0;
int iCons = 0;
int bSeenEq = 0;
int bSeenGt = 0;
int bSeenLt = 0;
int bSeenMatch = 0;
int bSeenRank = 0;
assert( SQLITE_INDEX_CONSTRAINT_EQ<SQLITE_INDEX_CONSTRAINT_MATCH );
assert( SQLITE_INDEX_CONSTRAINT_GT<SQLITE_INDEX_CONSTRAINT_MATCH );
assert( SQLITE_INDEX_CONSTRAINT_LE<SQLITE_INDEX_CONSTRAINT_MATCH );
assert( SQLITE_INDEX_CONSTRAINT_GE<SQLITE_INDEX_CONSTRAINT_MATCH );
assert( SQLITE_INDEX_CONSTRAINT_LE<SQLITE_INDEX_CONSTRAINT_MATCH );
if( pConfig->bLock ){
pTab->base.zErrMsg = sqlite3_mprintf(
"recursively defined fts5 content table"
);
return SQLITE_ERROR;
}
idxStr = (char*)sqlite3_malloc(pInfo->nConstraint * 8 + 1);
if( idxStr==0 ) return SQLITE_NOMEM;
pInfo->idxStr = idxStr;
pInfo->needToFreeIdxStr = 1;
for(i=0; i<pInfo->nConstraint; i++){
struct sqlite3_index_constraint *p = &pInfo->aConstraint[i];
int iCol = p->iColumn;
if( p->op==SQLITE_INDEX_CONSTRAINT_MATCH
|| (p->op==SQLITE_INDEX_CONSTRAINT_EQ && iCol>=nCol)
){
/* A MATCH operator or equivalent */
if( p->usable==0 || iCol<0 ){
/* As there exists an unusable MATCH constraint this is an
** unusable plan. Set a prohibitively high cost. */
pInfo->estimatedCost = 1e50;
assert( iIdxStr < pInfo->nConstraint*6 + 1 );
idxStr[iIdxStr] = 0;
return SQLITE_OK;
}else{
if( iCol==nCol+1 ){
if( bSeenRank ) continue;
idxStr[iIdxStr++] = 'r';
bSeenRank = 1;
}else if( iCol>=0 ){
bSeenMatch = 1;
idxStr[iIdxStr++] = 'M';
sqlite3_snprintf(6, &idxStr[iIdxStr], "%d", iCol);
idxStr += strlen(&idxStr[iIdxStr]);
assert( idxStr[iIdxStr]=='\0' );
}
pInfo->aConstraintUsage[i].argvIndex = ++iCons;
pInfo->aConstraintUsage[i].omit = 1;
}
}else if( p->usable ){
if( iCol>=0 && iCol<nCol && fts5UsePatternMatch(pConfig, p) ){
assert( p->op==FTS5_PATTERN_LIKE || p->op==FTS5_PATTERN_GLOB );
idxStr[iIdxStr++] = p->op==FTS5_PATTERN_LIKE ? 'L' : 'G';
sqlite3_snprintf(6, &idxStr[iIdxStr], "%d", iCol);
idxStr += strlen(&idxStr[iIdxStr]);
pInfo->aConstraintUsage[i].argvIndex = ++iCons;
assert( idxStr[iIdxStr]=='\0' );
}else if( bSeenEq==0 && p->op==SQLITE_INDEX_CONSTRAINT_EQ && iCol<0 ){
idxStr[iIdxStr++] = '=';
bSeenEq = 1;
pInfo->aConstraintUsage[i].argvIndex = ++iCons;
}
}
}
if( bSeenEq==0 ){
for(i=0; i<pInfo->nConstraint; i++){
struct sqlite3_index_constraint *p = &pInfo->aConstraint[i];
if( p->iColumn<0 && p->usable ){
int op = p->op;
if( op==SQLITE_INDEX_CONSTRAINT_LT || op==SQLITE_INDEX_CONSTRAINT_LE ){
if( bSeenLt ) continue;
idxStr[iIdxStr++] = '<';
pInfo->aConstraintUsage[i].argvIndex = ++iCons;
bSeenLt = 1;
}else
if( op==SQLITE_INDEX_CONSTRAINT_GT || op==SQLITE_INDEX_CONSTRAINT_GE ){
if( bSeenGt ) continue;
idxStr[iIdxStr++] = '>';
pInfo->aConstraintUsage[i].argvIndex = ++iCons;
bSeenGt = 1;
}
}
}
}
idxStr[iIdxStr] = '\0';
/* Set idxFlags flags for the ORDER BY clause */
if( pInfo->nOrderBy==1 ){
int iSort = pInfo->aOrderBy[0].iColumn;
if( iSort==(pConfig->nCol+1) && bSeenMatch ){
idxFlags |= FTS5_BI_ORDER_RANK;
}else if( iSort==-1 ){
idxFlags |= FTS5_BI_ORDER_ROWID;
}
if( BitFlagTest(idxFlags, FTS5_BI_ORDER_RANK|FTS5_BI_ORDER_ROWID) ){
pInfo->orderByConsumed = 1;
if( pInfo->aOrderBy[0].desc ){
idxFlags |= FTS5_BI_ORDER_DESC;
}
}
}
/* Calculate the estimated cost based on the flags set in idxFlags. */
if( bSeenEq ){
pInfo->estimatedCost = bSeenMatch ? 100.0 : 10.0;
if( bSeenMatch==0 ) fts5SetUniqueFlag(pInfo);
}else if( bSeenLt && bSeenGt ){
pInfo->estimatedCost = bSeenMatch ? 500.0 : 250000.0;
}else if( bSeenLt || bSeenGt ){
pInfo->estimatedCost = bSeenMatch ? 750.0 : 750000.0;
}else{
pInfo->estimatedCost = bSeenMatch ? 1000.0 : 1000000.0;
}
pInfo->idxNum = idxFlags;
return SQLITE_OK;
}
static int fts5NewTransaction(Fts5FullTable *pTab){
Fts5Cursor *pCsr;
for(pCsr=pTab->pGlobal->pCsr; pCsr; pCsr=pCsr->pNext){
if( pCsr->base.pVtab==(sqlite3_vtab*)pTab ) return SQLITE_OK;
}
return sqlite3Fts5StorageReset(pTab->pStorage);
}
/*
** Implementation of xOpen method.
*/
static int fts5OpenMethod(sqlite3_vtab *pVTab, sqlite3_vtab_cursor **ppCsr){
Fts5FullTable *pTab = (Fts5FullTable*)pVTab;
Fts5Config *pConfig = pTab->p.pConfig;
Fts5Cursor *pCsr = 0; /* New cursor object */
sqlite3_int64 nByte; /* Bytes of space to allocate */
int rc; /* Return code */
rc = fts5NewTransaction(pTab);
if( rc==SQLITE_OK ){
nByte = sizeof(Fts5Cursor) + pConfig->nCol * sizeof(int);
pCsr = (Fts5Cursor*)sqlite3_malloc64(nByte);
if( pCsr ){
Fts5Global *pGlobal = pTab->pGlobal;
memset(pCsr, 0, (size_t)nByte);
pCsr->aColumnSize = (int*)&pCsr[1];
pCsr->pNext = pGlobal->pCsr;
pGlobal->pCsr = pCsr;
pCsr->iCsrId = ++pGlobal->iNextId;
}else{
rc = SQLITE_NOMEM;
}
}
*ppCsr = (sqlite3_vtab_cursor*)pCsr;
return rc;
}
static int fts5StmtType(Fts5Cursor *pCsr){
if( pCsr->ePlan==FTS5_PLAN_SCAN ){
return (pCsr->bDesc) ? FTS5_STMT_SCAN_DESC : FTS5_STMT_SCAN_ASC;
}
return FTS5_STMT_LOOKUP;
}
/*
** This function is called after the cursor passed as the only argument
** is moved to point at a different row. It clears all cached data
** specific to the previous row stored by the cursor object.
*/
static void fts5CsrNewrow(Fts5Cursor *pCsr){
CsrFlagSet(pCsr,
FTS5CSR_REQUIRE_CONTENT
| FTS5CSR_REQUIRE_DOCSIZE
| FTS5CSR_REQUIRE_INST
| FTS5CSR_REQUIRE_POSLIST
);
}
static void fts5FreeCursorComponents(Fts5Cursor *pCsr){
Fts5FullTable *pTab = (Fts5FullTable*)(pCsr->base.pVtab);
Fts5Auxdata *pData;
Fts5Auxdata *pNext;
sqlite3_free(pCsr->aInstIter);
sqlite3_free(pCsr->aInst);
if( pCsr->pStmt ){
int eStmt = fts5StmtType(pCsr);
sqlite3Fts5StorageStmtRelease(pTab->pStorage, eStmt, pCsr->pStmt);
}
if( pCsr->pSorter ){
Fts5Sorter *pSorter = pCsr->pSorter;
sqlite3_finalize(pSorter->pStmt);
sqlite3_free(pSorter);
}
if( pCsr->ePlan!=FTS5_PLAN_SOURCE ){
sqlite3Fts5ExprFree(pCsr->pExpr);
}
for(pData=pCsr->pAuxdata; pData; pData=pNext){
pNext = pData->pNext;
if( pData->xDelete ) pData->xDelete(pData->pPtr);
sqlite3_free(pData);
}
sqlite3_finalize(pCsr->pRankArgStmt);
sqlite3_free(pCsr->apRankArg);
if( CsrFlagTest(pCsr, FTS5CSR_FREE_ZRANK) ){
sqlite3_free(pCsr->zRank);
sqlite3_free(pCsr->zRankArgs);
}
sqlite3Fts5IndexCloseReader(pTab->p.pIndex);
memset(&pCsr->ePlan, 0, sizeof(Fts5Cursor) - ((u8*)&pCsr->ePlan - (u8*)pCsr));
}
/*
** Close the cursor. For additional information see the documentation
** on the xClose method of the virtual table interface.
*/
static int fts5CloseMethod(sqlite3_vtab_cursor *pCursor){
if( pCursor ){
Fts5FullTable *pTab = (Fts5FullTable*)(pCursor->pVtab);
Fts5Cursor *pCsr = (Fts5Cursor*)pCursor;
Fts5Cursor **pp;
fts5FreeCursorComponents(pCsr);
/* Remove the cursor from the Fts5Global.pCsr list */
for(pp=&pTab->pGlobal->pCsr; (*pp)!=pCsr; pp=&(*pp)->pNext);
*pp = pCsr->pNext;
sqlite3_free(pCsr);
}
return SQLITE_OK;
}
static int fts5SorterNext(Fts5Cursor *pCsr){
Fts5Sorter *pSorter = pCsr->pSorter;
int rc;
rc = sqlite3_step(pSorter->pStmt);
if( rc==SQLITE_DONE ){
rc = SQLITE_OK;
CsrFlagSet(pCsr, FTS5CSR_EOF);
}else if( rc==SQLITE_ROW ){
const u8 *a;
const u8 *aBlob;
int nBlob;
int i;
int iOff = 0;
rc = SQLITE_OK;
pSorter->iRowid = sqlite3_column_int64(pSorter->pStmt, 0);
nBlob = sqlite3_column_bytes(pSorter->pStmt, 1);
aBlob = a = sqlite3_column_blob(pSorter->pStmt, 1);
/* nBlob==0 in detail=none mode. */
if( nBlob>0 ){
for(i=0; i<(pSorter->nIdx-1); i++){
int iVal;
a += fts5GetVarint32(a, iVal);
iOff += iVal;
pSorter->aIdx[i] = iOff;
}
pSorter->aIdx[i] = &aBlob[nBlob] - a;
pSorter->aPoslist = a;
}
fts5CsrNewrow(pCsr);
}
return rc;
}
/*
** Set the FTS5CSR_REQUIRE_RESEEK flag on all FTS5_PLAN_MATCH cursors
** open on table pTab.
*/
static void fts5TripCursors(Fts5FullTable *pTab){
Fts5Cursor *pCsr;
for(pCsr=pTab->pGlobal->pCsr; pCsr; pCsr=pCsr->pNext){
if( pCsr->ePlan==FTS5_PLAN_MATCH
&& pCsr->base.pVtab==(sqlite3_vtab*)pTab
){
CsrFlagSet(pCsr, FTS5CSR_REQUIRE_RESEEK);
}
}
}
/*
** If the REQUIRE_RESEEK flag is set on the cursor passed as the first
** argument, close and reopen all Fts5IndexIter iterators that the cursor
** is using. Then attempt to move the cursor to a rowid equal to or laster
** (in the cursors sort order - ASC or DESC) than the current rowid.
**
** If the new rowid is not equal to the old, set output parameter *pbSkip
** to 1 before returning. Otherwise, leave it unchanged.
**
** Return SQLITE_OK if successful or if no reseek was required, or an
** error code if an error occurred.
*/
static int fts5CursorReseek(Fts5Cursor *pCsr, int *pbSkip){
int rc = SQLITE_OK;
assert( *pbSkip==0 );
if( CsrFlagTest(pCsr, FTS5CSR_REQUIRE_RESEEK) ){
Fts5FullTable *pTab = (Fts5FullTable*)(pCsr->base.pVtab);
int bDesc = pCsr->bDesc;
i64 iRowid = sqlite3Fts5ExprRowid(pCsr->pExpr);
rc = sqlite3Fts5ExprFirst(pCsr->pExpr, pTab->p.pIndex, iRowid, bDesc);
if( rc==SQLITE_OK && iRowid!=sqlite3Fts5ExprRowid(pCsr->pExpr) ){
*pbSkip = 1;
}
CsrFlagClear(pCsr, FTS5CSR_REQUIRE_RESEEK);
fts5CsrNewrow(pCsr);
if( sqlite3Fts5ExprEof(pCsr->pExpr) ){
CsrFlagSet(pCsr, FTS5CSR_EOF);
*pbSkip = 1;
}
}
return rc;
}
/*
** Advance the cursor to the next row in the table that matches the
** search criteria.
**
** Return SQLITE_OK if nothing goes wrong. SQLITE_OK is returned
** even if we reach end-of-file. The fts5EofMethod() will be called
** subsequently to determine whether or not an EOF was hit.
*/
static int fts5NextMethod(sqlite3_vtab_cursor *pCursor){
Fts5Cursor *pCsr = (Fts5Cursor*)pCursor;
int rc;
assert( (pCsr->ePlan<3)==
(pCsr->ePlan==FTS5_PLAN_MATCH || pCsr->ePlan==FTS5_PLAN_SOURCE)
);
assert( !CsrFlagTest(pCsr, FTS5CSR_EOF) );
if( pCsr->ePlan<3 ){
int bSkip = 0;
if( (rc = fts5CursorReseek(pCsr, &bSkip)) || bSkip ) return rc;
rc = sqlite3Fts5ExprNext(pCsr->pExpr, pCsr->iLastRowid);
CsrFlagSet(pCsr, sqlite3Fts5ExprEof(pCsr->pExpr));
fts5CsrNewrow(pCsr);
}else{
switch( pCsr->ePlan ){
case FTS5_PLAN_SPECIAL: {
CsrFlagSet(pCsr, FTS5CSR_EOF);
rc = SQLITE_OK;
break;
}
case FTS5_PLAN_SORTED_MATCH: {
rc = fts5SorterNext(pCsr);
break;
}
default: {
Fts5Config *pConfig = ((Fts5Table*)pCursor->pVtab)->pConfig;
pConfig->bLock++;
rc = sqlite3_step(pCsr->pStmt);
pConfig->bLock--;
if( rc!=SQLITE_ROW ){
CsrFlagSet(pCsr, FTS5CSR_EOF);
rc = sqlite3_reset(pCsr->pStmt);
if( rc!=SQLITE_OK ){
pCursor->pVtab->zErrMsg = sqlite3_mprintf(
"%s", sqlite3_errmsg(pConfig->db)
);
}
}else{
rc = SQLITE_OK;
}
break;
}
}
}
return rc;
}
static int fts5PrepareStatement(
sqlite3_stmt **ppStmt,
Fts5Config *pConfig,
const char *zFmt,
...
){
sqlite3_stmt *pRet = 0;
int rc;
char *zSql;
va_list ap;
va_start(ap, zFmt);
zSql = sqlite3_vmprintf(zFmt, ap);
if( zSql==0 ){
rc = SQLITE_NOMEM;
}else{
rc = sqlite3_prepare_v3(pConfig->db, zSql, -1,
SQLITE_PREPARE_PERSISTENT, &pRet, 0);
if( rc!=SQLITE_OK ){
*pConfig->pzErrmsg = sqlite3_mprintf("%s", sqlite3_errmsg(pConfig->db));
}
sqlite3_free(zSql);
}
va_end(ap);
*ppStmt = pRet;
return rc;
}
static int fts5CursorFirstSorted(
Fts5FullTable *pTab,
Fts5Cursor *pCsr,
int bDesc
){
Fts5Config *pConfig = pTab->p.pConfig;
Fts5Sorter *pSorter;
int nPhrase;
sqlite3_int64 nByte;
int rc;
const char *zRank = pCsr->zRank;
const char *zRankArgs = pCsr->zRankArgs;
nPhrase = sqlite3Fts5ExprPhraseCount(pCsr->pExpr);
nByte = sizeof(Fts5Sorter) + sizeof(int) * (nPhrase-1);
pSorter = (Fts5Sorter*)sqlite3_malloc64(nByte);
if( pSorter==0 ) return SQLITE_NOMEM;
memset(pSorter, 0, (size_t)nByte);
pSorter->nIdx = nPhrase;
/* TODO: It would be better to have some system for reusing statement
** handles here, rather than preparing a new one for each query. But that
** is not possible as SQLite reference counts the virtual table objects.
** And since the statement required here reads from this very virtual
** table, saving it creates a circular reference.
**
** If SQLite a built-in statement cache, this wouldn't be a problem. */
rc = fts5PrepareStatement(&pSorter->pStmt, pConfig,
"SELECT rowid, rank FROM %Q.%Q ORDER BY %s(\"%w\"%s%s) %s",
pConfig->zDb, pConfig->zName, zRank, pConfig->zName,
(zRankArgs ? ", " : ""),
(zRankArgs ? zRankArgs : ""),
bDesc ? "DESC" : "ASC"
);
pCsr->pSorter = pSorter;
if( rc==SQLITE_OK ){
assert( pTab->pSortCsr==0 );
pTab->pSortCsr = pCsr;
rc = fts5SorterNext(pCsr);
pTab->pSortCsr = 0;
}
if( rc!=SQLITE_OK ){
sqlite3_finalize(pSorter->pStmt);
sqlite3_free(pSorter);
pCsr->pSorter = 0;
}
return rc;
}
static int fts5CursorFirst(Fts5FullTable *pTab, Fts5Cursor *pCsr, int bDesc){
int rc;
Fts5Expr *pExpr = pCsr->pExpr;
rc = sqlite3Fts5ExprFirst(pExpr, pTab->p.pIndex, pCsr->iFirstRowid, bDesc);
if( sqlite3Fts5ExprEof(pExpr) ){
CsrFlagSet(pCsr, FTS5CSR_EOF);
}
fts5CsrNewrow(pCsr);
return rc;
}
/*
** Process a "special" query. A special query is identified as one with a
** MATCH expression that begins with a '*' character. The remainder of
** the text passed to the MATCH operator are used as the special query
** parameters.
*/
static int fts5SpecialMatch(
Fts5FullTable *pTab,
Fts5Cursor *pCsr,
const char *zQuery
){
int rc = SQLITE_OK; /* Return code */
const char *z = zQuery; /* Special query text */
int n; /* Number of bytes in text at z */
while( z[0]==' ' ) z++;
for(n=0; z[n] && z[n]!=' '; n++);
assert( pTab->p.base.zErrMsg==0 );
pCsr->ePlan = FTS5_PLAN_SPECIAL;
if( n==5 && 0==sqlite3_strnicmp("reads", z, n) ){
pCsr->iSpecial = sqlite3Fts5IndexReads(pTab->p.pIndex);
}
else if( n==2 && 0==sqlite3_strnicmp("id", z, n) ){
pCsr->iSpecial = pCsr->iCsrId;
}
else{
/* An unrecognized directive. Return an error message. */
pTab->p.base.zErrMsg = sqlite3_mprintf("unknown special query: %.*s", n, z);
rc = SQLITE_ERROR;
}
return rc;
}
/*
** Search for an auxiliary function named zName that can be used with table
** pTab. If one is found, return a pointer to the corresponding Fts5Auxiliary
** structure. Otherwise, if no such function exists, return NULL.
*/
static Fts5Auxiliary *fts5FindAuxiliary(Fts5FullTable *pTab, const char *zName){
Fts5Auxiliary *pAux;
for(pAux=pTab->pGlobal->pAux; pAux; pAux=pAux->pNext){
if( sqlite3_stricmp(zName, pAux->zFunc)==0 ) return pAux;
}
/* No function of the specified name was found. Return 0. */
return 0;
}
static int fts5FindRankFunction(Fts5Cursor *pCsr){
Fts5FullTable *pTab = (Fts5FullTable*)(pCsr->base.pVtab);
Fts5Config *pConfig = pTab->p.pConfig;
int rc = SQLITE_OK;
Fts5Auxiliary *pAux = 0;
const char *zRank = pCsr->zRank;
const char *zRankArgs = pCsr->zRankArgs;
if( zRankArgs ){
char *zSql = sqlite3Fts5Mprintf(&rc, "SELECT %s", zRankArgs);
if( zSql ){
sqlite3_stmt *pStmt = 0;
rc = sqlite3_prepare_v3(pConfig->db, zSql, -1,
SQLITE_PREPARE_PERSISTENT, &pStmt, 0);
sqlite3_free(zSql);
assert( rc==SQLITE_OK || pCsr->pRankArgStmt==0 );
if( rc==SQLITE_OK ){
if( SQLITE_ROW==sqlite3_step(pStmt) ){
sqlite3_int64 nByte;
pCsr->nRankArg = sqlite3_column_count(pStmt);
nByte = sizeof(sqlite3_value*)*pCsr->nRankArg;
pCsr->apRankArg = (sqlite3_value**)sqlite3Fts5MallocZero(&rc, nByte);
if( rc==SQLITE_OK ){
int i;
for(i=0; i<pCsr->nRankArg; i++){
pCsr->apRankArg[i] = sqlite3_column_value(pStmt, i);
}
}
pCsr->pRankArgStmt = pStmt;
}else{
rc = sqlite3_finalize(pStmt);
assert( rc!=SQLITE_OK );
}
}
}
}
if( rc==SQLITE_OK ){
pAux = fts5FindAuxiliary(pTab, zRank);
if( pAux==0 ){
assert( pTab->p.base.zErrMsg==0 );
pTab->p.base.zErrMsg = sqlite3_mprintf("no such function: %s", zRank);
rc = SQLITE_ERROR;
}
}
pCsr->pRank = pAux;
return rc;
}
static int fts5CursorParseRank(
Fts5Config *pConfig,
Fts5Cursor *pCsr,
sqlite3_value *pRank
){
int rc = SQLITE_OK;
if( pRank ){
const char *z = (const char*)sqlite3_value_text(pRank);
char *zRank = 0;
char *zRankArgs = 0;
if( z==0 ){
if( sqlite3_value_type(pRank)==SQLITE_NULL ) rc = SQLITE_ERROR;
}else{
rc = sqlite3Fts5ConfigParseRank(z, &zRank, &zRankArgs);
}
if( rc==SQLITE_OK ){
pCsr->zRank = zRank;
pCsr->zRankArgs = zRankArgs;
CsrFlagSet(pCsr, FTS5CSR_FREE_ZRANK);
}else if( rc==SQLITE_ERROR ){
pCsr->base.pVtab->zErrMsg = sqlite3_mprintf(
"parse error in rank function: %s", z
);
}
}else{
if( pConfig->zRank ){
pCsr->zRank = (char*)pConfig->zRank;
pCsr->zRankArgs = (char*)pConfig->zRankArgs;
}else{
pCsr->zRank = (char*)FTS5_DEFAULT_RANK;
pCsr->zRankArgs = 0;
}
}
return rc;
}
static i64 fts5GetRowidLimit(sqlite3_value *pVal, i64 iDefault){
if( pVal ){
int eType = sqlite3_value_numeric_type(pVal);
if( eType==SQLITE_INTEGER ){
return sqlite3_value_int64(pVal);
}
}
return iDefault;
}
/*
** This is the xFilter interface for the virtual table. See
** the virtual table xFilter method documentation for additional
** information.
**
** There are three possible query strategies:
**
** 1. Full-text search using a MATCH operator.
** 2. A by-rowid lookup.
** 3. A full-table scan.
*/
static int fts5FilterMethod(
sqlite3_vtab_cursor *pCursor, /* The cursor used for this query */
int idxNum, /* Strategy index */
const char *idxStr, /* Unused */
int nVal, /* Number of elements in apVal */
sqlite3_value **apVal /* Arguments for the indexing scheme */
){
Fts5FullTable *pTab = (Fts5FullTable*)(pCursor->pVtab);
Fts5Config *pConfig = pTab->p.pConfig;
Fts5Cursor *pCsr = (Fts5Cursor*)pCursor;
int rc = SQLITE_OK; /* Error code */
int bDesc; /* True if ORDER BY [rank|rowid] DESC */
int bOrderByRank; /* True if ORDER BY rank */
sqlite3_value *pRank = 0; /* rank MATCH ? expression (or NULL) */
sqlite3_value *pRowidEq = 0; /* rowid = ? expression (or NULL) */
sqlite3_value *pRowidLe = 0; /* rowid <= ? expression (or NULL) */
sqlite3_value *pRowidGe = 0; /* rowid >= ? expression (or NULL) */
int iCol; /* Column on LHS of MATCH operator */
char **pzErrmsg = pConfig->pzErrmsg;
int i;
int iIdxStr = 0;
Fts5Expr *pExpr = 0;
if( pConfig->bLock ){
pTab->p.base.zErrMsg = sqlite3_mprintf(
"recursively defined fts5 content table"
);
return SQLITE_ERROR;
}
if( pCsr->ePlan ){
fts5FreeCursorComponents(pCsr);
memset(&pCsr->ePlan, 0, sizeof(Fts5Cursor) - ((u8*)&pCsr->ePlan-(u8*)pCsr));
}
assert( pCsr->pStmt==0 );
assert( pCsr->pExpr==0 );
assert( pCsr->csrflags==0 );
assert( pCsr->pRank==0 );
assert( pCsr->zRank==0 );
assert( pCsr->zRankArgs==0 );
assert( pTab->pSortCsr==0 || nVal==0 );
assert( pzErrmsg==0 || pzErrmsg==&pTab->p.base.zErrMsg );
pConfig->pzErrmsg = &pTab->p.base.zErrMsg;
/* Decode the arguments passed through to this function. */
for(i=0; i<nVal; i++){
switch( idxStr[iIdxStr++] ){
case 'r':
pRank = apVal[i];
break;
case 'M': {
const char *zText = (const char*)sqlite3_value_text(apVal[i]);
if( zText==0 ) zText = "";
iCol = 0;
do{
iCol = iCol*10 + (idxStr[iIdxStr]-'0');
iIdxStr++;
}while( idxStr[iIdxStr]>='0' && idxStr[iIdxStr]<='9' );
if( zText[0]=='*' ){
/* The user has issued a query of the form "MATCH '*...'". This
** indicates that the MATCH expression is not a full text query,
** but a request for an internal parameter. */
rc = fts5SpecialMatch(pTab, pCsr, &zText[1]);
goto filter_out;
}else{
char **pzErr = &pTab->p.base.zErrMsg;
rc = sqlite3Fts5ExprNew(pConfig, 0, iCol, zText, &pExpr, pzErr);
if( rc==SQLITE_OK ){
rc = sqlite3Fts5ExprAnd(&pCsr->pExpr, pExpr);
pExpr = 0;
}
if( rc!=SQLITE_OK ) goto filter_out;
}
break;
}
case 'L':
case 'G': {
int bGlob = (idxStr[iIdxStr-1]=='G');
const char *zText = (const char*)sqlite3_value_text(apVal[i]);
iCol = 0;
do{
iCol = iCol*10 + (idxStr[iIdxStr]-'0');
iIdxStr++;
}while( idxStr[iIdxStr]>='0' && idxStr[iIdxStr]<='9' );
if( zText ){
rc = sqlite3Fts5ExprPattern(pConfig, bGlob, iCol, zText, &pExpr);
}
if( rc==SQLITE_OK ){
rc = sqlite3Fts5ExprAnd(&pCsr->pExpr, pExpr);
pExpr = 0;
}
if( rc!=SQLITE_OK ) goto filter_out;
break;
}
case '=':
pRowidEq = apVal[i];
break;
case '<':
pRowidLe = apVal[i];
break;
default: assert( idxStr[iIdxStr-1]=='>' );
pRowidGe = apVal[i];
break;
}
}
bOrderByRank = ((idxNum & FTS5_BI_ORDER_RANK) ? 1 : 0);
pCsr->bDesc = bDesc = ((idxNum & FTS5_BI_ORDER_DESC) ? 1 : 0);
/* Set the cursor upper and lower rowid limits. Only some strategies
** actually use them. This is ok, as the xBestIndex() method leaves the
** sqlite3_index_constraint.omit flag clear for range constraints
** on the rowid field. */
if( pRowidEq ){
pRowidLe = pRowidGe = pRowidEq;
}
if( bDesc ){
pCsr->iFirstRowid = fts5GetRowidLimit(pRowidLe, LARGEST_INT64);
pCsr->iLastRowid = fts5GetRowidLimit(pRowidGe, SMALLEST_INT64);
}else{
pCsr->iLastRowid = fts5GetRowidLimit(pRowidLe, LARGEST_INT64);
pCsr->iFirstRowid = fts5GetRowidLimit(pRowidGe, SMALLEST_INT64);
}
if( pTab->pSortCsr ){
/* If pSortCsr is non-NULL, then this call is being made as part of
** processing for a "... MATCH <expr> ORDER BY rank" query (ePlan is
** set to FTS5_PLAN_SORTED_MATCH). pSortCsr is the cursor that will
** return results to the user for this query. The current cursor
** (pCursor) is used to execute the query issued by function
** fts5CursorFirstSorted() above. */
assert( pRowidEq==0 && pRowidLe==0 && pRowidGe==0 && pRank==0 );
assert( nVal==0 && bOrderByRank==0 && bDesc==0 );
assert( pCsr->iLastRowid==LARGEST_INT64 );
assert( pCsr->iFirstRowid==SMALLEST_INT64 );
if( pTab->pSortCsr->bDesc ){
pCsr->iLastRowid = pTab->pSortCsr->iFirstRowid;
pCsr->iFirstRowid = pTab->pSortCsr->iLastRowid;
}else{
pCsr->iLastRowid = pTab->pSortCsr->iLastRowid;
pCsr->iFirstRowid = pTab->pSortCsr->iFirstRowid;
}
pCsr->ePlan = FTS5_PLAN_SOURCE;
pCsr->pExpr = pTab->pSortCsr->pExpr;
rc = fts5CursorFirst(pTab, pCsr, bDesc);
}else if( pCsr->pExpr ){
rc = fts5CursorParseRank(pConfig, pCsr, pRank);
if( rc==SQLITE_OK ){
if( bOrderByRank ){
pCsr->ePlan = FTS5_PLAN_SORTED_MATCH;
rc = fts5CursorFirstSorted(pTab, pCsr, bDesc);
}else{
pCsr->ePlan = FTS5_PLAN_MATCH;
rc = fts5CursorFirst(pTab, pCsr, bDesc);
}
}
}else if( pConfig->zContent==0 ){
*pConfig->pzErrmsg = sqlite3_mprintf(
"%s: table does not support scanning", pConfig->zName
);
rc = SQLITE_ERROR;
}else{
/* This is either a full-table scan (ePlan==FTS5_PLAN_SCAN) or a lookup
** by rowid (ePlan==FTS5_PLAN_ROWID). */
pCsr->ePlan = (pRowidEq ? FTS5_PLAN_ROWID : FTS5_PLAN_SCAN);
rc = sqlite3Fts5StorageStmt(
pTab->pStorage, fts5StmtType(pCsr), &pCsr->pStmt, &pTab->p.base.zErrMsg
);
if( rc==SQLITE_OK ){
if( pCsr->ePlan==FTS5_PLAN_ROWID ){
sqlite3_bind_value(pCsr->pStmt, 1, pRowidEq);
}else{
sqlite3_bind_int64(pCsr->pStmt, 1, pCsr->iFirstRowid);
sqlite3_bind_int64(pCsr->pStmt, 2, pCsr->iLastRowid);
}
rc = fts5NextMethod(pCursor);
}
}
filter_out:
sqlite3Fts5ExprFree(pExpr);
pConfig->pzErrmsg = pzErrmsg;
return rc;
}
/*
** This is the xEof method of the virtual table. SQLite calls this
** routine to find out if it has reached the end of a result set.
*/
static int fts5EofMethod(sqlite3_vtab_cursor *pCursor){
Fts5Cursor *pCsr = (Fts5Cursor*)pCursor;
return (CsrFlagTest(pCsr, FTS5CSR_EOF) ? 1 : 0);
}
/*
** Return the rowid that the cursor currently points to.
*/
static i64 fts5CursorRowid(Fts5Cursor *pCsr){
assert( pCsr->ePlan==FTS5_PLAN_MATCH
|| pCsr->ePlan==FTS5_PLAN_SORTED_MATCH
|| pCsr->ePlan==FTS5_PLAN_SOURCE
);
if( pCsr->pSorter ){
return pCsr->pSorter->iRowid;
}else{
return sqlite3Fts5ExprRowid(pCsr->pExpr);
}
}
/*
** This is the xRowid method. The SQLite core calls this routine to
** retrieve the rowid for the current row of the result set. fts5
** exposes %_content.rowid as the rowid for the virtual table. The
** rowid should be written to *pRowid.
*/
static int fts5RowidMethod(sqlite3_vtab_cursor *pCursor, sqlite_int64 *pRowid){
Fts5Cursor *pCsr = (Fts5Cursor*)pCursor;
int ePlan = pCsr->ePlan;
assert( CsrFlagTest(pCsr, FTS5CSR_EOF)==0 );
switch( ePlan ){
case FTS5_PLAN_SPECIAL:
*pRowid = 0;
break;
case FTS5_PLAN_SOURCE:
case FTS5_PLAN_MATCH:
case FTS5_PLAN_SORTED_MATCH:
*pRowid = fts5CursorRowid(pCsr);
break;
default:
*pRowid = sqlite3_column_int64(pCsr->pStmt, 0);
break;
}
return SQLITE_OK;
}
/*
** If the cursor requires seeking (bSeekRequired flag is set), seek it.
** Return SQLITE_OK if no error occurs, or an SQLite error code otherwise.
**
** If argument bErrormsg is true and an error occurs, an error message may
** be left in sqlite3_vtab.zErrMsg.
*/
static int fts5SeekCursor(Fts5Cursor *pCsr, int bErrormsg){
int rc = SQLITE_OK;
/* If the cursor does not yet have a statement handle, obtain one now. */
if( pCsr->pStmt==0 ){
Fts5FullTable *pTab = (Fts5FullTable*)(pCsr->base.pVtab);
int eStmt = fts5StmtType(pCsr);
rc = sqlite3Fts5StorageStmt(
pTab->pStorage, eStmt, &pCsr->pStmt, (bErrormsg?&pTab->p.base.zErrMsg:0)
);
assert( rc!=SQLITE_OK || pTab->p.base.zErrMsg==0 );
assert( CsrFlagTest(pCsr, FTS5CSR_REQUIRE_CONTENT) );
}
if( rc==SQLITE_OK && CsrFlagTest(pCsr, FTS5CSR_REQUIRE_CONTENT) ){
Fts5Table *pTab = (Fts5Table*)(pCsr->base.pVtab);
assert( pCsr->pExpr );
sqlite3_reset(pCsr->pStmt);
sqlite3_bind_int64(pCsr->pStmt, 1, fts5CursorRowid(pCsr));
pTab->pConfig->bLock++;
rc = sqlite3_step(pCsr->pStmt);
pTab->pConfig->bLock--;
if( rc==SQLITE_ROW ){
rc = SQLITE_OK;
CsrFlagClear(pCsr, FTS5CSR_REQUIRE_CONTENT);
}else{
rc = sqlite3_reset(pCsr->pStmt);
if( rc==SQLITE_OK ){
rc = FTS5_CORRUPT;
}else if( pTab->pConfig->pzErrmsg ){
*pTab->pConfig->pzErrmsg = sqlite3_mprintf(
"%s", sqlite3_errmsg(pTab->pConfig->db)
);
}
}
}
return rc;
}
static void fts5SetVtabError(Fts5FullTable *p, const char *zFormat, ...){
va_list ap; /* ... printf arguments */
va_start(ap, zFormat);
assert( p->p.base.zErrMsg==0 );
p->p.base.zErrMsg = sqlite3_vmprintf(zFormat, ap);
va_end(ap);
}
/*
** This function is called to handle an FTS INSERT command. In other words,
** an INSERT statement of the form:
**
** INSERT INTO fts(fts) VALUES($pCmd)
** INSERT INTO fts(fts, rank) VALUES($pCmd, $pVal)
**
** Argument pVal is the value assigned to column "fts" by the INSERT
** statement. This function returns SQLITE_OK if successful, or an SQLite
** error code if an error occurs.
**
** The commands implemented by this function are documented in the "Special
** INSERT Directives" section of the documentation. It should be updated if
** more commands are added to this function.
*/
static int fts5SpecialInsert(
Fts5FullTable *pTab, /* Fts5 table object */
const char *zCmd, /* Text inserted into table-name column */
sqlite3_value *pVal /* Value inserted into rank column */
){
Fts5Config *pConfig = pTab->p.pConfig;
int rc = SQLITE_OK;
int bError = 0;
if( 0==sqlite3_stricmp("delete-all", zCmd) ){
if( pConfig->eContent==FTS5_CONTENT_NORMAL ){
fts5SetVtabError(pTab,
"'delete-all' may only be used with a "
"contentless or external content fts5 table"
);
rc = SQLITE_ERROR;
}else{
rc = sqlite3Fts5StorageDeleteAll(pTab->pStorage);
}
}else if( 0==sqlite3_stricmp("rebuild", zCmd) ){
if( pConfig->eContent==FTS5_CONTENT_NONE ){
fts5SetVtabError(pTab,
"'rebuild' may not be used with a contentless fts5 table"
);
rc = SQLITE_ERROR;
}else{
rc = sqlite3Fts5StorageRebuild(pTab->pStorage);
}
}else if( 0==sqlite3_stricmp("optimize", zCmd) ){
rc = sqlite3Fts5StorageOptimize(pTab->pStorage);
}else if( 0==sqlite3_stricmp("merge", zCmd) ){
int nMerge = sqlite3_value_int(pVal);
rc = sqlite3Fts5StorageMerge(pTab->pStorage, nMerge);
}else if( 0==sqlite3_stricmp("integrity-check", zCmd) ){
int iArg = sqlite3_value_int(pVal);
rc = sqlite3Fts5StorageIntegrity(pTab->pStorage, iArg);
#ifdef SQLITE_DEBUG
}else if( 0==sqlite3_stricmp("prefix-index", zCmd) ){
pConfig->bPrefixIndex = sqlite3_value_int(pVal);
#endif
}else{
rc = sqlite3Fts5IndexLoadConfig(pTab->p.pIndex);
if( rc==SQLITE_OK ){
rc = sqlite3Fts5ConfigSetValue(pTab->p.pConfig, zCmd, pVal, &bError);
}
if( rc==SQLITE_OK ){
if( bError ){
rc = SQLITE_ERROR;
}else{
rc = sqlite3Fts5StorageConfigValue(pTab->pStorage, zCmd, pVal, 0);
}
}
}
return rc;
}
static int fts5SpecialDelete(
Fts5FullTable *pTab,
sqlite3_value **apVal
){
int rc = SQLITE_OK;
int eType1 = sqlite3_value_type(apVal[1]);
if( eType1==SQLITE_INTEGER ){
sqlite3_int64 iDel = sqlite3_value_int64(apVal[1]);
rc = sqlite3Fts5StorageDelete(pTab->pStorage, iDel, &apVal[2]);
}
return rc;
}
static void fts5StorageInsert(
int *pRc,
Fts5FullTable *pTab,
sqlite3_value **apVal,
i64 *piRowid
){
int rc = *pRc;
if( rc==SQLITE_OK ){
rc = sqlite3Fts5StorageContentInsert(pTab->pStorage, apVal, piRowid);
}
if( rc==SQLITE_OK ){
rc = sqlite3Fts5StorageIndexInsert(pTab->pStorage, apVal, *piRowid);
}
*pRc = rc;
}
/*
** This function is the implementation of the xUpdate callback used by
** FTS3 virtual tables. It is invoked by SQLite each time a row is to be
** inserted, updated or deleted.
**
** A delete specifies a single argument - the rowid of the row to remove.
**
** Update and insert operations pass:
**
** 1. The "old" rowid, or NULL.
** 2. The "new" rowid.
** 3. Values for each of the nCol matchable columns.
** 4. Values for the two hidden columns (<tablename> and "rank").
*/
static int fts5UpdateMethod(
sqlite3_vtab *pVtab, /* Virtual table handle */
int nArg, /* Size of argument array */
sqlite3_value **apVal, /* Array of arguments */
sqlite_int64 *pRowid /* OUT: The affected (or effected) rowid */
){
Fts5FullTable *pTab = (Fts5FullTable*)pVtab;
Fts5Config *pConfig = pTab->p.pConfig;
int eType0; /* value_type() of apVal[0] */
int rc = SQLITE_OK; /* Return code */
/* A transaction must be open when this is called. */
assert( pTab->ts.eState==1 );
assert( pVtab->zErrMsg==0 );
assert( nArg==1 || nArg==(2+pConfig->nCol+2) );
assert( sqlite3_value_type(apVal[0])==SQLITE_INTEGER
|| sqlite3_value_type(apVal[0])==SQLITE_NULL
);
assert( pTab->p.pConfig->pzErrmsg==0 );
pTab->p.pConfig->pzErrmsg = &pTab->p.base.zErrMsg;
/* Put any active cursors into REQUIRE_SEEK state. */
fts5TripCursors(pTab);
eType0 = sqlite3_value_type(apVal[0]);
if( eType0==SQLITE_NULL
&& sqlite3_value_type(apVal[2+pConfig->nCol])!=SQLITE_NULL
){
/* A "special" INSERT op. These are handled separately. */
const char *z = (const char*)sqlite3_value_text(apVal[2+pConfig->nCol]);
if( pConfig->eContent!=FTS5_CONTENT_NORMAL
&& 0==sqlite3_stricmp("delete", z)
){
rc = fts5SpecialDelete(pTab, apVal);
}else{
rc = fts5SpecialInsert(pTab, z, apVal[2 + pConfig->nCol + 1]);
}
}else{
/* A regular INSERT, UPDATE or DELETE statement. The trick here is that
** any conflict on the rowid value must be detected before any
** modifications are made to the database file. There are 4 cases:
**
** 1) DELETE
** 2) UPDATE (rowid not modified)
** 3) UPDATE (rowid modified)
** 4) INSERT
**
** Cases 3 and 4 may violate the rowid constraint.
*/
int eConflict = SQLITE_ABORT;
if( pConfig->eContent==FTS5_CONTENT_NORMAL ){
eConflict = sqlite3_vtab_on_conflict(pConfig->db);
}
assert( eType0==SQLITE_INTEGER || eType0==SQLITE_NULL );
assert( nArg!=1 || eType0==SQLITE_INTEGER );
/* Filter out attempts to run UPDATE or DELETE on contentless tables.
** This is not suported. */
if( eType0==SQLITE_INTEGER && fts5IsContentless(pTab) ){
pTab->p.base.zErrMsg = sqlite3_mprintf(
"cannot %s contentless fts5 table: %s",
(nArg>1 ? "UPDATE" : "DELETE from"), pConfig->zName
);
rc = SQLITE_ERROR;
}
/* DELETE */
else if( nArg==1 ){
i64 iDel = sqlite3_value_int64(apVal[0]); /* Rowid to delete */
rc = sqlite3Fts5StorageDelete(pTab->pStorage, iDel, 0);
}
/* INSERT or UPDATE */
else{
int eType1 = sqlite3_value_numeric_type(apVal[1]);
if( eType1!=SQLITE_INTEGER && eType1!=SQLITE_NULL ){
rc = SQLITE_MISMATCH;
}
else if( eType0!=SQLITE_INTEGER ){
/* If this is a REPLACE, first remove the current entry (if any) */
if( eConflict==SQLITE_REPLACE && eType1==SQLITE_INTEGER ){
i64 iNew = sqlite3_value_int64(apVal[1]); /* Rowid to delete */
rc = sqlite3Fts5StorageDelete(pTab->pStorage, iNew, 0);
}
fts5StorageInsert(&rc, pTab, apVal, pRowid);
}
/* UPDATE */
else{
i64 iOld = sqlite3_value_int64(apVal[0]); /* Old rowid */
i64 iNew = sqlite3_value_int64(apVal[1]); /* New rowid */
if( eType1==SQLITE_INTEGER && iOld!=iNew ){
if( eConflict==SQLITE_REPLACE ){
rc = sqlite3Fts5StorageDelete(pTab->pStorage, iOld, 0);
if( rc==SQLITE_OK ){
rc = sqlite3Fts5StorageDelete(pTab->pStorage, iNew, 0);
}
fts5StorageInsert(&rc, pTab, apVal, pRowid);
}else{
rc = sqlite3Fts5StorageContentInsert(pTab->pStorage, apVal, pRowid);
if( rc==SQLITE_OK ){
rc = sqlite3Fts5StorageDelete(pTab->pStorage, iOld, 0);
}
if( rc==SQLITE_OK ){
rc = sqlite3Fts5StorageIndexInsert(pTab->pStorage, apVal,*pRowid);
}
}
}else{
rc = sqlite3Fts5StorageDelete(pTab->pStorage, iOld, 0);
fts5StorageInsert(&rc, pTab, apVal, pRowid);
}
}
}
}
pTab->p.pConfig->pzErrmsg = 0;
return rc;
}
/*
** Implementation of xSync() method.
*/
static int fts5SyncMethod(sqlite3_vtab *pVtab){
int rc;
Fts5FullTable *pTab = (Fts5FullTable*)pVtab;
fts5CheckTransactionState(pTab, FTS5_SYNC, 0);
pTab->p.pConfig->pzErrmsg = &pTab->p.base.zErrMsg;
fts5TripCursors(pTab);
rc = sqlite3Fts5StorageSync(pTab->pStorage);
pTab->p.pConfig->pzErrmsg = 0;
return rc;
}
/*
** Implementation of xBegin() method.
*/
static int fts5BeginMethod(sqlite3_vtab *pVtab){
fts5CheckTransactionState((Fts5FullTable*)pVtab, FTS5_BEGIN, 0);
fts5NewTransaction((Fts5FullTable*)pVtab);
return SQLITE_OK;
}
/*
** Implementation of xCommit() method. This is a no-op. The contents of
** the pending-terms hash-table have already been flushed into the database
** by fts5SyncMethod().
*/
static int fts5CommitMethod(sqlite3_vtab *pVtab){
UNUSED_PARAM(pVtab); /* Call below is a no-op for NDEBUG builds */
fts5CheckTransactionState((Fts5FullTable*)pVtab, FTS5_COMMIT, 0);
return SQLITE_OK;
}
/*
** Implementation of xRollback(). Discard the contents of the pending-terms
** hash-table. Any changes made to the database are reverted by SQLite.
*/
static int fts5RollbackMethod(sqlite3_vtab *pVtab){
int rc;
Fts5FullTable *pTab = (Fts5FullTable*)pVtab;
fts5CheckTransactionState(pTab, FTS5_ROLLBACK, 0);
rc = sqlite3Fts5StorageRollback(pTab->pStorage);
return rc;
}
static int fts5CsrPoslist(Fts5Cursor*, int, const u8**, int*);
static void *fts5ApiUserData(Fts5Context *pCtx){
Fts5Cursor *pCsr = (Fts5Cursor*)pCtx;
return pCsr->pAux->pUserData;
}
static int fts5ApiColumnCount(Fts5Context *pCtx){
Fts5Cursor *pCsr = (Fts5Cursor*)pCtx;
return ((Fts5Table*)(pCsr->base.pVtab))->pConfig->nCol;
}
static int fts5ApiColumnTotalSize(
Fts5Context *pCtx,
int iCol,
sqlite3_int64 *pnToken
){
Fts5Cursor *pCsr = (Fts5Cursor*)pCtx;
Fts5FullTable *pTab = (Fts5FullTable*)(pCsr->base.pVtab);
return sqlite3Fts5StorageSize(pTab->pStorage, iCol, pnToken);
}
static int fts5ApiRowCount(Fts5Context *pCtx, i64 *pnRow){
Fts5Cursor *pCsr = (Fts5Cursor*)pCtx;
Fts5FullTable *pTab = (Fts5FullTable*)(pCsr->base.pVtab);
return sqlite3Fts5StorageRowCount(pTab->pStorage, pnRow);
}
static int fts5ApiTokenize(
Fts5Context *pCtx,
const char *pText, int nText,
void *pUserData,
int (*xToken)(void*, int, const char*, int, int, int)
){
Fts5Cursor *pCsr = (Fts5Cursor*)pCtx;
Fts5Table *pTab = (Fts5Table*)(pCsr->base.pVtab);
return sqlite3Fts5Tokenize(
pTab->pConfig, FTS5_TOKENIZE_AUX, pText, nText, pUserData, xToken
);
}
static int fts5ApiPhraseCount(Fts5Context *pCtx){
Fts5Cursor *pCsr = (Fts5Cursor*)pCtx;
return sqlite3Fts5ExprPhraseCount(pCsr->pExpr);
}
static int fts5ApiPhraseSize(Fts5Context *pCtx, int iPhrase){
Fts5Cursor *pCsr = (Fts5Cursor*)pCtx;
return sqlite3Fts5ExprPhraseSize(pCsr->pExpr, iPhrase);
}
static int fts5ApiColumnText(
Fts5Context *pCtx,
int iCol,
const char **pz,
int *pn
){
int rc = SQLITE_OK;
Fts5Cursor *pCsr = (Fts5Cursor*)pCtx;
if( fts5IsContentless((Fts5FullTable*)(pCsr->base.pVtab))
|| pCsr->ePlan==FTS5_PLAN_SPECIAL
){
*pz = 0;
*pn = 0;
}else{
rc = fts5SeekCursor(pCsr, 0);
if( rc==SQLITE_OK ){
*pz = (const char*)sqlite3_column_text(pCsr->pStmt, iCol+1);
*pn = sqlite3_column_bytes(pCsr->pStmt, iCol+1);
}
}
return rc;
}
static int fts5CsrPoslist(
Fts5Cursor *pCsr,
int iPhrase,
const u8 **pa,
int *pn
){
Fts5Config *pConfig = ((Fts5Table*)(pCsr->base.pVtab))->pConfig;
int rc = SQLITE_OK;
int bLive = (pCsr->pSorter==0);
if( CsrFlagTest(pCsr, FTS5CSR_REQUIRE_POSLIST) ){
if( pConfig->eDetail!=FTS5_DETAIL_FULL ){
Fts5PoslistPopulator *aPopulator;
int i;
aPopulator = sqlite3Fts5ExprClearPoslists(pCsr->pExpr, bLive);
if( aPopulator==0 ) rc = SQLITE_NOMEM;
for(i=0; i<pConfig->nCol && rc==SQLITE_OK; i++){
int n; const char *z;
rc = fts5ApiColumnText((Fts5Context*)pCsr, i, &z, &n);
if( rc==SQLITE_OK ){
rc = sqlite3Fts5ExprPopulatePoslists(
pConfig, pCsr->pExpr, aPopulator, i, z, n
);
}
}
sqlite3_free(aPopulator);
if( pCsr->pSorter ){
sqlite3Fts5ExprCheckPoslists(pCsr->pExpr, pCsr->pSorter->iRowid);
}
}
CsrFlagClear(pCsr, FTS5CSR_REQUIRE_POSLIST);
}
if( pCsr->pSorter && pConfig->eDetail==FTS5_DETAIL_FULL ){
Fts5Sorter *pSorter = pCsr->pSorter;
int i1 = (iPhrase==0 ? 0 : pSorter->aIdx[iPhrase-1]);
*pn = pSorter->aIdx[iPhrase] - i1;
*pa = &pSorter->aPoslist[i1];
}else{
*pn = sqlite3Fts5ExprPoslist(pCsr->pExpr, iPhrase, pa);
}
return rc;
}
/*
** Ensure that the Fts5Cursor.nInstCount and aInst[] variables are populated
** correctly for the current view. Return SQLITE_OK if successful, or an
** SQLite error code otherwise.
*/
static int fts5CacheInstArray(Fts5Cursor *pCsr){
int rc = SQLITE_OK;
Fts5PoslistReader *aIter; /* One iterator for each phrase */
int nIter; /* Number of iterators/phrases */
int nCol = ((Fts5Table*)pCsr->base.pVtab)->pConfig->nCol;
nIter = sqlite3Fts5ExprPhraseCount(pCsr->pExpr);
if( pCsr->aInstIter==0 ){
sqlite3_int64 nByte = sizeof(Fts5PoslistReader) * nIter;
pCsr->aInstIter = (Fts5PoslistReader*)sqlite3Fts5MallocZero(&rc, nByte);
}
aIter = pCsr->aInstIter;
if( aIter ){
int nInst = 0; /* Number instances seen so far */
int i;
/* Initialize all iterators */
for(i=0; i<nIter && rc==SQLITE_OK; i++){
const u8 *a;
int n;
rc = fts5CsrPoslist(pCsr, i, &a, &n);
if( rc==SQLITE_OK ){
sqlite3Fts5PoslistReaderInit(a, n, &aIter[i]);
}
}
if( rc==SQLITE_OK ){
while( 1 ){
int *aInst;
int iBest = -1;
for(i=0; i<nIter; i++){
if( (aIter[i].bEof==0)
&& (iBest<0 || aIter[i].iPos<aIter[iBest].iPos)
){
iBest = i;
}
}
if( iBest<0 ) break;
nInst++;
if( nInst>=pCsr->nInstAlloc ){
pCsr->nInstAlloc = pCsr->nInstAlloc ? pCsr->nInstAlloc*2 : 32;
aInst = (int*)sqlite3_realloc64(
pCsr->aInst, pCsr->nInstAlloc*sizeof(int)*3
);
if( aInst ){
pCsr->aInst = aInst;
}else{
rc = SQLITE_NOMEM;
break;
}
}
aInst = &pCsr->aInst[3 * (nInst-1)];
aInst[0] = iBest;
aInst[1] = FTS5_POS2COLUMN(aIter[iBest].iPos);
aInst[2] = FTS5_POS2OFFSET(aIter[iBest].iPos);
if( aInst[1]<0 || aInst[1]>=nCol ){
rc = FTS5_CORRUPT;
break;
}
sqlite3Fts5PoslistReaderNext(&aIter[iBest]);
}
}
pCsr->nInstCount = nInst;
CsrFlagClear(pCsr, FTS5CSR_REQUIRE_INST);
}
return rc;
}
static int fts5ApiInstCount(Fts5Context *pCtx, int *pnInst){
Fts5Cursor *pCsr = (Fts5Cursor*)pCtx;
int rc = SQLITE_OK;
if( CsrFlagTest(pCsr, FTS5CSR_REQUIRE_INST)==0
|| SQLITE_OK==(rc = fts5CacheInstArray(pCsr)) ){
*pnInst = pCsr->nInstCount;
}
return rc;
}
static int fts5ApiInst(
Fts5Context *pCtx,
int iIdx,
int *piPhrase,
int *piCol,
int *piOff
){
Fts5Cursor *pCsr = (Fts5Cursor*)pCtx;
int rc = SQLITE_OK;
if( CsrFlagTest(pCsr, FTS5CSR_REQUIRE_INST)==0
|| SQLITE_OK==(rc = fts5CacheInstArray(pCsr))
){
if( iIdx<0 || iIdx>=pCsr->nInstCount ){
rc = SQLITE_RANGE;
#if 0
}else if( fts5IsOffsetless((Fts5Table*)pCsr->base.pVtab) ){
*piPhrase = pCsr->aInst[iIdx*3];
*piCol = pCsr->aInst[iIdx*3 + 2];
*piOff = -1;
#endif
}else{
*piPhrase = pCsr->aInst[iIdx*3];
*piCol = pCsr->aInst[iIdx*3 + 1];
*piOff = pCsr->aInst[iIdx*3 + 2];
}
}
return rc;
}
static sqlite3_int64 fts5ApiRowid(Fts5Context *pCtx){
return fts5CursorRowid((Fts5Cursor*)pCtx);
}
static int fts5ColumnSizeCb(
void *pContext, /* Pointer to int */
int tflags,
const char *pUnused, /* Buffer containing token */
int nUnused, /* Size of token in bytes */
int iUnused1, /* Start offset of token */
int iUnused2 /* End offset of token */
){
int *pCnt = (int*)pContext;
UNUSED_PARAM2(pUnused, nUnused);
UNUSED_PARAM2(iUnused1, iUnused2);
if( (tflags & FTS5_TOKEN_COLOCATED)==0 ){
(*pCnt)++;
}
return SQLITE_OK;
}
static int fts5ApiColumnSize(Fts5Context *pCtx, int iCol, int *pnToken){
Fts5Cursor *pCsr = (Fts5Cursor*)pCtx;
Fts5FullTable *pTab = (Fts5FullTable*)(pCsr->base.pVtab);
Fts5Config *pConfig = pTab->p.pConfig;
int rc = SQLITE_OK;
if( CsrFlagTest(pCsr, FTS5CSR_REQUIRE_DOCSIZE) ){
if( pConfig->bColumnsize ){
i64 iRowid = fts5CursorRowid(pCsr);
rc = sqlite3Fts5StorageDocsize(pTab->pStorage, iRowid, pCsr->aColumnSize);
}else if( pConfig->zContent==0 ){
int i;
for(i=0; i<pConfig->nCol; i++){
if( pConfig->abUnindexed[i]==0 ){
pCsr->aColumnSize[i] = -1;
}
}
}else{
int i;
for(i=0; rc==SQLITE_OK && i<pConfig->nCol; i++){
if( pConfig->abUnindexed[i]==0 ){
const char *z; int n;
void *p = (void*)(&pCsr->aColumnSize[i]);
pCsr->aColumnSize[i] = 0;
rc = fts5ApiColumnText(pCtx, i, &z, &n);
if( rc==SQLITE_OK ){
rc = sqlite3Fts5Tokenize(
pConfig, FTS5_TOKENIZE_AUX, z, n, p, fts5ColumnSizeCb
);
}
}
}
}
CsrFlagClear(pCsr, FTS5CSR_REQUIRE_DOCSIZE);
}
if( iCol<0 ){
int i;
*pnToken = 0;
for(i=0; i<pConfig->nCol; i++){
*pnToken += pCsr->aColumnSize[i];
}
}else if( iCol<pConfig->nCol ){
*pnToken = pCsr->aColumnSize[iCol];
}else{
*pnToken = 0;
rc = SQLITE_RANGE;
}
return rc;
}
/*
** Implementation of the xSetAuxdata() method.
*/
static int fts5ApiSetAuxdata(
Fts5Context *pCtx, /* Fts5 context */
void *pPtr, /* Pointer to save as auxdata */
void(*xDelete)(void*) /* Destructor for pPtr (or NULL) */
){
Fts5Cursor *pCsr = (Fts5Cursor*)pCtx;
Fts5Auxdata *pData;
/* Search through the cursors list of Fts5Auxdata objects for one that
** corresponds to the currently executing auxiliary function. */
for(pData=pCsr->pAuxdata; pData; pData=pData->pNext){
if( pData->pAux==pCsr->pAux ) break;
}
if( pData ){
if( pData->xDelete ){
pData->xDelete(pData->pPtr);
}
}else{
int rc = SQLITE_OK;
pData = (Fts5Auxdata*)sqlite3Fts5MallocZero(&rc, sizeof(Fts5Auxdata));
if( pData==0 ){
if( xDelete ) xDelete(pPtr);
return rc;
}
pData->pAux = pCsr->pAux;
pData->pNext = pCsr->pAuxdata;
pCsr->pAuxdata = pData;
}
pData->xDelete = xDelete;
pData->pPtr = pPtr;
return SQLITE_OK;
}
static void *fts5ApiGetAuxdata(Fts5Context *pCtx, int bClear){
Fts5Cursor *pCsr = (Fts5Cursor*)pCtx;
Fts5Auxdata *pData;
void *pRet = 0;
for(pData=pCsr->pAuxdata; pData; pData=pData->pNext){
if( pData->pAux==pCsr->pAux ) break;
}
if( pData ){
pRet = pData->pPtr;
if( bClear ){
pData->pPtr = 0;
pData->xDelete = 0;
}
}
return pRet;
}
static void fts5ApiPhraseNext(
Fts5Context *pUnused,
Fts5PhraseIter *pIter,
int *piCol, int *piOff
){
UNUSED_PARAM(pUnused);
if( pIter->a>=pIter->b ){
*piCol = -1;
*piOff = -1;
}else{
int iVal;
pIter->a += fts5GetVarint32(pIter->a, iVal);
if( iVal==1 ){
pIter->a += fts5GetVarint32(pIter->a, iVal);
*piCol = iVal;
*piOff = 0;
pIter->a += fts5GetVarint32(pIter->a, iVal);
}
*piOff += (iVal-2);
}
}
static int fts5ApiPhraseFirst(
Fts5Context *pCtx,
int iPhrase,
Fts5PhraseIter *pIter,
int *piCol, int *piOff
){
Fts5Cursor *pCsr = (Fts5Cursor*)pCtx;
int n;
int rc = fts5CsrPoslist(pCsr, iPhrase, &pIter->a, &n);
if( rc==SQLITE_OK ){
assert( pIter->a || n==0 );
pIter->b = (pIter->a ? &pIter->a[n] : 0);
*piCol = 0;
*piOff = 0;
fts5ApiPhraseNext(pCtx, pIter, piCol, piOff);
}
return rc;
}
static void fts5ApiPhraseNextColumn(
Fts5Context *pCtx,
Fts5PhraseIter *pIter,
int *piCol
){
Fts5Cursor *pCsr = (Fts5Cursor*)pCtx;
Fts5Config *pConfig = ((Fts5Table*)(pCsr->base.pVtab))->pConfig;
if( pConfig->eDetail==FTS5_DETAIL_COLUMNS ){
if( pIter->a>=pIter->b ){
*piCol = -1;
}else{
int iIncr;
pIter->a += fts5GetVarint32(&pIter->a[0], iIncr);
*piCol += (iIncr-2);
}
}else{
while( 1 ){
int dummy;
if( pIter->a>=pIter->b ){
*piCol = -1;
return;
}
if( pIter->a[0]==0x01 ) break;
pIter->a += fts5GetVarint32(pIter->a, dummy);
}
pIter->a += 1 + fts5GetVarint32(&pIter->a[1], *piCol);
}
}
static int fts5ApiPhraseFirstColumn(
Fts5Context *pCtx,
int iPhrase,
Fts5PhraseIter *pIter,
int *piCol
){
int rc = SQLITE_OK;
Fts5Cursor *pCsr = (Fts5Cursor*)pCtx;
Fts5Config *pConfig = ((Fts5Table*)(pCsr->base.pVtab))->pConfig;
if( pConfig->eDetail==FTS5_DETAIL_COLUMNS ){
Fts5Sorter *pSorter = pCsr->pSorter;
int n;
if( pSorter ){
int i1 = (iPhrase==0 ? 0 : pSorter->aIdx[iPhrase-1]);
n = pSorter->aIdx[iPhrase] - i1;
pIter->a = &pSorter->aPoslist[i1];
}else{
rc = sqlite3Fts5ExprPhraseCollist(pCsr->pExpr, iPhrase, &pIter->a, &n);
}
if( rc==SQLITE_OK ){
assert( pIter->a || n==0 );
pIter->b = (pIter->a ? &pIter->a[n] : 0);
*piCol = 0;
fts5ApiPhraseNextColumn(pCtx, pIter, piCol);
}
}else{
int n;
rc = fts5CsrPoslist(pCsr, iPhrase, &pIter->a, &n);
if( rc==SQLITE_OK ){
assert( pIter->a || n==0 );
pIter->b = (pIter->a ? &pIter->a[n] : 0);
if( n<=0 ){
*piCol = -1;
}else if( pIter->a[0]==0x01 ){
pIter->a += 1 + fts5GetVarint32(&pIter->a[1], *piCol);
}else{
*piCol = 0;
}
}
}
return rc;
}
static int fts5ApiQueryPhrase(Fts5Context*, int, void*,
int(*)(const Fts5ExtensionApi*, Fts5Context*, void*)
);
static const Fts5ExtensionApi sFts5Api = {
2, /* iVersion */
fts5ApiUserData,
fts5ApiColumnCount,
fts5ApiRowCount,
fts5ApiColumnTotalSize,
fts5ApiTokenize,
fts5ApiPhraseCount,
fts5ApiPhraseSize,
fts5ApiInstCount,
fts5ApiInst,
fts5ApiRowid,
fts5ApiColumnText,
fts5ApiColumnSize,
fts5ApiQueryPhrase,
fts5ApiSetAuxdata,
fts5ApiGetAuxdata,
fts5ApiPhraseFirst,
fts5ApiPhraseNext,
fts5ApiPhraseFirstColumn,
fts5ApiPhraseNextColumn,
};
/*
** Implementation of API function xQueryPhrase().
*/
static int fts5ApiQueryPhrase(
Fts5Context *pCtx,
int iPhrase,
void *pUserData,
int(*xCallback)(const Fts5ExtensionApi*, Fts5Context*, void*)
){
Fts5Cursor *pCsr = (Fts5Cursor*)pCtx;
Fts5FullTable *pTab = (Fts5FullTable*)(pCsr->base.pVtab);
int rc;
Fts5Cursor *pNew = 0;
rc = fts5OpenMethod(pCsr->base.pVtab, (sqlite3_vtab_cursor**)&pNew);
if( rc==SQLITE_OK ){
pNew->ePlan = FTS5_PLAN_MATCH;
pNew->iFirstRowid = SMALLEST_INT64;
pNew->iLastRowid = LARGEST_INT64;
pNew->base.pVtab = (sqlite3_vtab*)pTab;
rc = sqlite3Fts5ExprClonePhrase(pCsr->pExpr, iPhrase, &pNew->pExpr);
}
if( rc==SQLITE_OK ){
for(rc = fts5CursorFirst(pTab, pNew, 0);
rc==SQLITE_OK && CsrFlagTest(pNew, FTS5CSR_EOF)==0;
rc = fts5NextMethod((sqlite3_vtab_cursor*)pNew)
){
rc = xCallback(&sFts5Api, (Fts5Context*)pNew, pUserData);
if( rc!=SQLITE_OK ){
if( rc==SQLITE_DONE ) rc = SQLITE_OK;
break;
}
}
}
fts5CloseMethod((sqlite3_vtab_cursor*)pNew);
return rc;
}
static void fts5ApiInvoke(
Fts5Auxiliary *pAux,
Fts5Cursor *pCsr,
sqlite3_context *context,
int argc,
sqlite3_value **argv
){
assert( pCsr->pAux==0 );
pCsr->pAux = pAux;
pAux->xFunc(&sFts5Api, (Fts5Context*)pCsr, context, argc, argv);
pCsr->pAux = 0;
}
static Fts5Cursor *fts5CursorFromCsrid(Fts5Global *pGlobal, i64 iCsrId){
Fts5Cursor *pCsr;
for(pCsr=pGlobal->pCsr; pCsr; pCsr=pCsr->pNext){
if( pCsr->iCsrId==iCsrId ) break;
}
return pCsr;
}
static void fts5ApiCallback(
sqlite3_context *context,
int argc,
sqlite3_value **argv
){
Fts5Auxiliary *pAux;
Fts5Cursor *pCsr;
i64 iCsrId;
assert( argc>=1 );
pAux = (Fts5Auxiliary*)sqlite3_user_data(context);
iCsrId = sqlite3_value_int64(argv[0]);
pCsr = fts5CursorFromCsrid(pAux->pGlobal, iCsrId);
if( pCsr==0 || pCsr->ePlan==0 ){
char *zErr = sqlite3_mprintf("no such cursor: %lld", iCsrId);
sqlite3_result_error(context, zErr, -1);
sqlite3_free(zErr);
}else{
fts5ApiInvoke(pAux, pCsr, context, argc-1, &argv[1]);
}
}
/*
** Given cursor id iId, return a pointer to the corresponding Fts5Table
** object. Or NULL If the cursor id does not exist.
*/
static Fts5Table *sqlite3Fts5TableFromCsrid(
Fts5Global *pGlobal, /* FTS5 global context for db handle */
i64 iCsrId /* Id of cursor to find */
){
Fts5Cursor *pCsr;
pCsr = fts5CursorFromCsrid(pGlobal, iCsrId);
if( pCsr ){
return (Fts5Table*)pCsr->base.pVtab;
}
return 0;
}
/*
** Return a "position-list blob" corresponding to the current position of
** cursor pCsr via sqlite3_result_blob(). A position-list blob contains
** the current position-list for each phrase in the query associated with
** cursor pCsr.
**
** A position-list blob begins with (nPhrase-1) varints, where nPhrase is
** the number of phrases in the query. Following the varints are the
** concatenated position lists for each phrase, in order.
**
** The first varint (if it exists) contains the size of the position list
** for phrase 0. The second (same disclaimer) contains the size of position
** list 1. And so on. There is no size field for the final position list,
** as it can be derived from the total size of the blob.
*/
static int fts5PoslistBlob(sqlite3_context *pCtx, Fts5Cursor *pCsr){
int i;
int rc = SQLITE_OK;
int nPhrase = sqlite3Fts5ExprPhraseCount(pCsr->pExpr);
Fts5Buffer val;
memset(&val, 0, sizeof(Fts5Buffer));
switch( ((Fts5Table*)(pCsr->base.pVtab))->pConfig->eDetail ){
case FTS5_DETAIL_FULL:
/* Append the varints */
for(i=0; i<(nPhrase-1); i++){
const u8 *dummy;
int nByte = sqlite3Fts5ExprPoslist(pCsr->pExpr, i, &dummy);
sqlite3Fts5BufferAppendVarint(&rc, &val, nByte);
}
/* Append the position lists */
for(i=0; i<nPhrase; i++){
const u8 *pPoslist;
int nPoslist;
nPoslist = sqlite3Fts5ExprPoslist(pCsr->pExpr, i, &pPoslist);
sqlite3Fts5BufferAppendBlob(&rc, &val, nPoslist, pPoslist);
}
break;
case FTS5_DETAIL_COLUMNS:
/* Append the varints */
for(i=0; rc==SQLITE_OK && i<(nPhrase-1); i++){
const u8 *dummy;
int nByte;
rc = sqlite3Fts5ExprPhraseCollist(pCsr->pExpr, i, &dummy, &nByte);
sqlite3Fts5BufferAppendVarint(&rc, &val, nByte);
}
/* Append the position lists */
for(i=0; rc==SQLITE_OK && i<nPhrase; i++){
const u8 *pPoslist;
int nPoslist;
rc = sqlite3Fts5ExprPhraseCollist(pCsr->pExpr, i, &pPoslist, &nPoslist);
sqlite3Fts5BufferAppendBlob(&rc, &val, nPoslist, pPoslist);
}
break;
default:
break;
}
sqlite3_result_blob(pCtx, val.p, val.n, sqlite3_free);
return rc;
}
/*
** This is the xColumn method, called by SQLite to request a value from
** the row that the supplied cursor currently points to.
*/
static int fts5ColumnMethod(
sqlite3_vtab_cursor *pCursor, /* Cursor to retrieve value from */
sqlite3_context *pCtx, /* Context for sqlite3_result_xxx() calls */
int iCol /* Index of column to read value from */
){
Fts5FullTable *pTab = (Fts5FullTable*)(pCursor->pVtab);
Fts5Config *pConfig = pTab->p.pConfig;
Fts5Cursor *pCsr = (Fts5Cursor*)pCursor;
int rc = SQLITE_OK;
assert( CsrFlagTest(pCsr, FTS5CSR_EOF)==0 );
if( pCsr->ePlan==FTS5_PLAN_SPECIAL ){
if( iCol==pConfig->nCol ){
sqlite3_result_int64(pCtx, pCsr->iSpecial);
}
}else
if( iCol==pConfig->nCol ){
/* User is requesting the value of the special column with the same name
** as the table. Return the cursor integer id number. This value is only
** useful in that it may be passed as the first argument to an FTS5
** auxiliary function. */
sqlite3_result_int64(pCtx, pCsr->iCsrId);
}else if( iCol==pConfig->nCol+1 ){
/* The value of the "rank" column. */
if( pCsr->ePlan==FTS5_PLAN_SOURCE ){
fts5PoslistBlob(pCtx, pCsr);
}else if(
pCsr->ePlan==FTS5_PLAN_MATCH
|| pCsr->ePlan==FTS5_PLAN_SORTED_MATCH
){
if( pCsr->pRank || SQLITE_OK==(rc = fts5FindRankFunction(pCsr)) ){
fts5ApiInvoke(pCsr->pRank, pCsr, pCtx, pCsr->nRankArg, pCsr->apRankArg);
}
}
}else if( !fts5IsContentless(pTab) ){
pConfig->pzErrmsg = &pTab->p.base.zErrMsg;
rc = fts5SeekCursor(pCsr, 1);
if( rc==SQLITE_OK ){
sqlite3_result_value(pCtx, sqlite3_column_value(pCsr->pStmt, iCol+1));
}
pConfig->pzErrmsg = 0;
}
return rc;
}
/*
** This routine implements the xFindFunction method for the FTS3
** virtual table.
*/
static int fts5FindFunctionMethod(
sqlite3_vtab *pVtab, /* Virtual table handle */
int nUnused, /* Number of SQL function arguments */
const char *zName, /* Name of SQL function */
void (**pxFunc)(sqlite3_context*,int,sqlite3_value**), /* OUT: Result */
void **ppArg /* OUT: User data for *pxFunc */
){
Fts5FullTable *pTab = (Fts5FullTable*)pVtab;
Fts5Auxiliary *pAux;
UNUSED_PARAM(nUnused);
pAux = fts5FindAuxiliary(pTab, zName);
if( pAux ){
*pxFunc = fts5ApiCallback;
*ppArg = (void*)pAux;
return 1;
}
/* No function of the specified name was found. Return 0. */
return 0;
}
/*
** Implementation of FTS5 xRename method. Rename an fts5 table.
*/
static int fts5RenameMethod(
sqlite3_vtab *pVtab, /* Virtual table handle */
const char *zName /* New name of table */
){
Fts5FullTable *pTab = (Fts5FullTable*)pVtab;
return sqlite3Fts5StorageRename(pTab->pStorage, zName);
}
static int sqlite3Fts5FlushToDisk(Fts5Table *pTab){
fts5TripCursors((Fts5FullTable*)pTab);
return sqlite3Fts5StorageSync(((Fts5FullTable*)pTab)->pStorage);
}
/*
** The xSavepoint() method.
**
** Flush the contents of the pending-terms table to disk.
*/
static int fts5SavepointMethod(sqlite3_vtab *pVtab, int iSavepoint){
UNUSED_PARAM(iSavepoint); /* Call below is a no-op for NDEBUG builds */
fts5CheckTransactionState((Fts5FullTable*)pVtab, FTS5_SAVEPOINT, iSavepoint);
return sqlite3Fts5FlushToDisk((Fts5Table*)pVtab);
}
/*
** The xRelease() method.
**
** This is a no-op.
*/
static int fts5ReleaseMethod(sqlite3_vtab *pVtab, int iSavepoint){
UNUSED_PARAM(iSavepoint); /* Call below is a no-op for NDEBUG builds */
fts5CheckTransactionState((Fts5FullTable*)pVtab, FTS5_RELEASE, iSavepoint);
return sqlite3Fts5FlushToDisk((Fts5Table*)pVtab);
}
/*
** The xRollbackTo() method.
**
** Discard the contents of the pending terms table.
*/
static int fts5RollbackToMethod(sqlite3_vtab *pVtab, int iSavepoint){
Fts5FullTable *pTab = (Fts5FullTable*)pVtab;
UNUSED_PARAM(iSavepoint); /* Call below is a no-op for NDEBUG builds */
fts5CheckTransactionState(pTab, FTS5_ROLLBACKTO, iSavepoint);
fts5TripCursors(pTab);
return sqlite3Fts5StorageRollback(pTab->pStorage);
}
/*
** Register a new auxiliary function with global context pGlobal.
*/
static int fts5CreateAux(
fts5_api *pApi, /* Global context (one per db handle) */
const char *zName, /* Name of new function */
void *pUserData, /* User data for aux. function */
fts5_extension_function xFunc, /* Aux. function implementation */
void(*xDestroy)(void*) /* Destructor for pUserData */
){
Fts5Global *pGlobal = (Fts5Global*)pApi;
int rc = sqlite3_overload_function(pGlobal->db, zName, -1);
if( rc==SQLITE_OK ){
Fts5Auxiliary *pAux;
sqlite3_int64 nName; /* Size of zName in bytes, including \0 */
sqlite3_int64 nByte; /* Bytes of space to allocate */
nName = strlen(zName) + 1;
nByte = sizeof(Fts5Auxiliary) + nName;
pAux = (Fts5Auxiliary*)sqlite3_malloc64(nByte);
if( pAux ){
memset(pAux, 0, (size_t)nByte);
pAux->zFunc = (char*)&pAux[1];
memcpy(pAux->zFunc, zName, nName);
pAux->pGlobal = pGlobal;
pAux->pUserData = pUserData;
pAux->xFunc = xFunc;
pAux->xDestroy = xDestroy;
pAux->pNext = pGlobal->pAux;
pGlobal->pAux = pAux;
}else{
rc = SQLITE_NOMEM;
}
}
return rc;
}
/*
** Register a new tokenizer. This is the implementation of the
** fts5_api.xCreateTokenizer() method.
*/
static int fts5CreateTokenizer(
fts5_api *pApi, /* Global context (one per db handle) */
const char *zName, /* Name of new function */
void *pUserData, /* User data for aux. function */
fts5_tokenizer *pTokenizer, /* Tokenizer implementation */
void(*xDestroy)(void*) /* Destructor for pUserData */
){
Fts5Global *pGlobal = (Fts5Global*)pApi;
Fts5TokenizerModule *pNew;
sqlite3_int64 nName; /* Size of zName and its \0 terminator */
sqlite3_int64 nByte; /* Bytes of space to allocate */
int rc = SQLITE_OK;
nName = strlen(zName) + 1;
nByte = sizeof(Fts5TokenizerModule) + nName;
pNew = (Fts5TokenizerModule*)sqlite3_malloc64(nByte);
if( pNew ){
memset(pNew, 0, (size_t)nByte);
pNew->zName = (char*)&pNew[1];
memcpy(pNew->zName, zName, nName);
pNew->pUserData = pUserData;
pNew->x = *pTokenizer;
pNew->xDestroy = xDestroy;
pNew->pNext = pGlobal->pTok;
pGlobal->pTok = pNew;
if( pNew->pNext==0 ){
pGlobal->pDfltTok = pNew;
}
}else{
rc = SQLITE_NOMEM;
}
return rc;
}
static Fts5TokenizerModule *fts5LocateTokenizer(
Fts5Global *pGlobal,
const char *zName
){
Fts5TokenizerModule *pMod = 0;
if( zName==0 ){
pMod = pGlobal->pDfltTok;
}else{
for(pMod=pGlobal->pTok; pMod; pMod=pMod->pNext){
if( sqlite3_stricmp(zName, pMod->zName)==0 ) break;
}
}
return pMod;
}
/*
** Find a tokenizer. This is the implementation of the
** fts5_api.xFindTokenizer() method.
*/
static int fts5FindTokenizer(
fts5_api *pApi, /* Global context (one per db handle) */
const char *zName, /* Name of new function */
void **ppUserData,
fts5_tokenizer *pTokenizer /* Populate this object */
){
int rc = SQLITE_OK;
Fts5TokenizerModule *pMod;
pMod = fts5LocateTokenizer((Fts5Global*)pApi, zName);
if( pMod ){
*pTokenizer = pMod->x;
*ppUserData = pMod->pUserData;
}else{
memset(pTokenizer, 0, sizeof(fts5_tokenizer));
rc = SQLITE_ERROR;
}
return rc;
}
static int sqlite3Fts5GetTokenizer(
Fts5Global *pGlobal,
const char **azArg,
int nArg,
Fts5Config *pConfig,
char **pzErr
){
Fts5TokenizerModule *pMod;
int rc = SQLITE_OK;
pMod = fts5LocateTokenizer(pGlobal, nArg==0 ? 0 : azArg[0]);
if( pMod==0 ){
assert( nArg>0 );
rc = SQLITE_ERROR;
*pzErr = sqlite3_mprintf("no such tokenizer: %s", azArg[0]);
}else{
rc = pMod->x.xCreate(
pMod->pUserData, (azArg?&azArg[1]:0), (nArg?nArg-1:0), &pConfig->pTok
);
pConfig->pTokApi = &pMod->x;
if( rc!=SQLITE_OK ){
if( pzErr ) *pzErr = sqlite3_mprintf("error in tokenizer constructor");
}else{
pConfig->ePattern = sqlite3Fts5TokenizerPattern(
pMod->x.xCreate, pConfig->pTok
);
}
}
if( rc!=SQLITE_OK ){
pConfig->pTokApi = 0;
pConfig->pTok = 0;
}
return rc;
}
static void fts5ModuleDestroy(void *pCtx){
Fts5TokenizerModule *pTok, *pNextTok;
Fts5Auxiliary *pAux, *pNextAux;
Fts5Global *pGlobal = (Fts5Global*)pCtx;
for(pAux=pGlobal->pAux; pAux; pAux=pNextAux){
pNextAux = pAux->pNext;
if( pAux->xDestroy ) pAux->xDestroy(pAux->pUserData);
sqlite3_free(pAux);
}
for(pTok=pGlobal->pTok; pTok; pTok=pNextTok){
pNextTok = pTok->pNext;
if( pTok->xDestroy ) pTok->xDestroy(pTok->pUserData);
sqlite3_free(pTok);
}
sqlite3_free(pGlobal);
}
static void fts5Fts5Func(
sqlite3_context *pCtx, /* Function call context */
int nArg, /* Number of args */
sqlite3_value **apArg /* Function arguments */
){
Fts5Global *pGlobal = (Fts5Global*)sqlite3_user_data(pCtx);
fts5_api **ppApi;
UNUSED_PARAM(nArg);
assert( nArg==1 );
ppApi = (fts5_api**)sqlite3_value_pointer(apArg[0], "fts5_api_ptr");
if( ppApi ) *ppApi = &pGlobal->api;
}
/*
** Implementation of fts5_source_id() function.
*/
static void fts5SourceIdFunc(
sqlite3_context *pCtx, /* Function call context */
int nArg, /* Number of args */
sqlite3_value **apUnused /* Function arguments */
){
assert( nArg==0 );
UNUSED_PARAM2(nArg, apUnused);
sqlite3_result_text(pCtx, "fts5: 2021-04-19 18:32:05 1b256d97b553a9611efca188a3d995a2fff712759044ba480f9a0c9e98fae886", -1, SQLITE_TRANSIENT);
}
/*
** Return true if zName is the extension on one of the shadow tables used
** by this module.
*/
static int fts5ShadowName(const char *zName){
static const char *azName[] = {
"config", "content", "data", "docsize", "idx"
};
unsigned int i;
for(i=0; i<sizeof(azName)/sizeof(azName[0]); i++){
if( sqlite3_stricmp(zName, azName[i])==0 ) return 1;
}
return 0;
}
static int fts5Init(sqlite3 *db){
static const sqlite3_module fts5Mod = {
/* iVersion */ 3,
/* xCreate */ fts5CreateMethod,
/* xConnect */ fts5ConnectMethod,
/* xBestIndex */ fts5BestIndexMethod,
/* xDisconnect */ fts5DisconnectMethod,
/* xDestroy */ fts5DestroyMethod,
/* xOpen */ fts5OpenMethod,
/* xClose */ fts5CloseMethod,
/* xFilter */ fts5FilterMethod,
/* xNext */ fts5NextMethod,
/* xEof */ fts5EofMethod,
/* xColumn */ fts5ColumnMethod,
/* xRowid */ fts5RowidMethod,
/* xUpdate */ fts5UpdateMethod,
/* xBegin */ fts5BeginMethod,
/* xSync */ fts5SyncMethod,
/* xCommit */ fts5CommitMethod,
/* xRollback */ fts5RollbackMethod,
/* xFindFunction */ fts5FindFunctionMethod,
/* xRename */ fts5RenameMethod,
/* xSavepoint */ fts5SavepointMethod,
/* xRelease */ fts5ReleaseMethod,
/* xRollbackTo */ fts5RollbackToMethod,
/* xShadowName */ fts5ShadowName
};
int rc;
Fts5Global *pGlobal = 0;
pGlobal = (Fts5Global*)sqlite3_malloc(sizeof(Fts5Global));
if( pGlobal==0 ){
rc = SQLITE_NOMEM;
}else{
void *p = (void*)pGlobal;
memset(pGlobal, 0, sizeof(Fts5Global));
pGlobal->db = db;
pGlobal->api.iVersion = 2;
pGlobal->api.xCreateFunction = fts5CreateAux;
pGlobal->api.xCreateTokenizer = fts5CreateTokenizer;
pGlobal->api.xFindTokenizer = fts5FindTokenizer;
rc = sqlite3_create_module_v2(db, "fts5", &fts5Mod, p, fts5ModuleDestroy);
if( rc==SQLITE_OK ) rc = sqlite3Fts5IndexInit(db);
if( rc==SQLITE_OK ) rc = sqlite3Fts5ExprInit(pGlobal, db);
if( rc==SQLITE_OK ) rc = sqlite3Fts5AuxInit(&pGlobal->api);
if( rc==SQLITE_OK ) rc = sqlite3Fts5TokenizerInit(&pGlobal->api);
if( rc==SQLITE_OK ) rc = sqlite3Fts5VocabInit(pGlobal, db);
if( rc==SQLITE_OK ){
rc = sqlite3_create_function(
db, "fts5", 1, SQLITE_UTF8, p, fts5Fts5Func, 0, 0
);
}
if( rc==SQLITE_OK ){
rc = sqlite3_create_function(
db, "fts5_source_id", 0, SQLITE_UTF8, p, fts5SourceIdFunc, 0, 0
);
}
}
/* If SQLITE_FTS5_ENABLE_TEST_MI is defined, assume that the file
** fts5_test_mi.c is compiled and linked into the executable. And call
** its entry point to enable the matchinfo() demo. */
#ifdef SQLITE_FTS5_ENABLE_TEST_MI
if( rc==SQLITE_OK ){
extern int sqlite3Fts5TestRegisterMatchinfo(sqlite3*);
rc = sqlite3Fts5TestRegisterMatchinfo(db);
}
#endif
return rc;
}
/*
** The following functions are used to register the module with SQLite. If
** this module is being built as part of the SQLite core (SQLITE_CORE is
** defined), then sqlite3_open() will call sqlite3Fts5Init() directly.
**
** Or, if this module is being built as a loadable extension,
** sqlite3Fts5Init() is omitted and the two standard entry points
** sqlite3_fts_init() and sqlite3_fts5_init() defined instead.
*/
#ifndef SQLITE_CORE
#ifdef _WIN32
__declspec(dllexport)
#endif
int sqlite3_fts_init(
sqlite3 *db,
char **pzErrMsg,
const sqlite3_api_routines *pApi
){
SQLITE_EXTENSION_INIT2(pApi);
(void)pzErrMsg; /* Unused parameter */
return fts5Init(db);
}
#ifdef _WIN32
__declspec(dllexport)
#endif
int sqlite3_fts5_init(
sqlite3 *db,
char **pzErrMsg,
const sqlite3_api_routines *pApi
){
SQLITE_EXTENSION_INIT2(pApi);
(void)pzErrMsg; /* Unused parameter */
return fts5Init(db);
}
#else
int sqlite3Fts5Init(sqlite3 *db){
return fts5Init(db);
}
#endif
#line 1 "fts5_storage.c"
/*
** 2014 May 31
**
** The author disclaims copyright to this source code. In place of
** a legal notice, here is a blessing:
**
** May you do good and not evil.
** May you find forgiveness for yourself and forgive others.
** May you share freely, never taking more than you give.
**
******************************************************************************
**
*/
/* #include "third_party/sqlite3/fts5Int.h" */
struct Fts5Storage {
Fts5Config *pConfig;
Fts5Index *pIndex;
int bTotalsValid; /* True if nTotalRow/aTotalSize[] are valid */
i64 nTotalRow; /* Total number of rows in FTS table */
i64 *aTotalSize; /* Total sizes of each column */
sqlite3_stmt *aStmt[11];
};
#if FTS5_STMT_SCAN_ASC!=0
# error "FTS5_STMT_SCAN_ASC mismatch"
#endif
#if FTS5_STMT_SCAN_DESC!=1
# error "FTS5_STMT_SCAN_DESC mismatch"
#endif
#if FTS5_STMT_LOOKUP!=2
# error "FTS5_STMT_LOOKUP mismatch"
#endif
#define FTS5_STMT_INSERT_CONTENT 3
#define FTS5_STMT_REPLACE_CONTENT 4
#define FTS5_STMT_DELETE_CONTENT 5
#define FTS5_STMT_REPLACE_DOCSIZE 6
#define FTS5_STMT_DELETE_DOCSIZE 7
#define FTS5_STMT_LOOKUP_DOCSIZE 8
#define FTS5_STMT_REPLACE_CONFIG 9
#define FTS5_STMT_SCAN 10
/*
** Prepare the two insert statements - Fts5Storage.pInsertContent and
** Fts5Storage.pInsertDocsize - if they have not already been prepared.
** Return SQLITE_OK if successful, or an SQLite error code if an error
** occurs.
*/
static int fts5StorageGetStmt(
Fts5Storage *p, /* Storage handle */
int eStmt, /* FTS5_STMT_XXX constant */
sqlite3_stmt **ppStmt, /* OUT: Prepared statement handle */
char **pzErrMsg /* OUT: Error message (if any) */
){
int rc = SQLITE_OK;
/* If there is no %_docsize table, there should be no requests for
** statements to operate on it. */
assert( p->pConfig->bColumnsize || (
eStmt!=FTS5_STMT_REPLACE_DOCSIZE
&& eStmt!=FTS5_STMT_DELETE_DOCSIZE
&& eStmt!=FTS5_STMT_LOOKUP_DOCSIZE
));
assert( eStmt>=0 && eStmt<ArraySize(p->aStmt) );
if( p->aStmt[eStmt]==0 ){
const char *azStmt[] = {
"SELECT %s FROM %s T WHERE T.%Q >= ? AND T.%Q <= ? ORDER BY T.%Q ASC",
"SELECT %s FROM %s T WHERE T.%Q <= ? AND T.%Q >= ? ORDER BY T.%Q DESC",
"SELECT %s FROM %s T WHERE T.%Q=?", /* LOOKUP */
"INSERT INTO %Q.'%q_content' VALUES(%s)", /* INSERT_CONTENT */
"REPLACE INTO %Q.'%q_content' VALUES(%s)", /* REPLACE_CONTENT */
"DELETE FROM %Q.'%q_content' WHERE id=?", /* DELETE_CONTENT */
"REPLACE INTO %Q.'%q_docsize' VALUES(?,?)", /* REPLACE_DOCSIZE */
"DELETE FROM %Q.'%q_docsize' WHERE id=?", /* DELETE_DOCSIZE */
"SELECT sz FROM %Q.'%q_docsize' WHERE id=?", /* LOOKUP_DOCSIZE */
"REPLACE INTO %Q.'%q_config' VALUES(?,?)", /* REPLACE_CONFIG */
"SELECT %s FROM %s AS T", /* SCAN */
};
Fts5Config *pC = p->pConfig;
char *zSql = 0;
switch( eStmt ){
case FTS5_STMT_SCAN:
zSql = sqlite3_mprintf(azStmt[eStmt],
pC->zContentExprlist, pC->zContent
);
break;
case FTS5_STMT_SCAN_ASC:
case FTS5_STMT_SCAN_DESC:
zSql = sqlite3_mprintf(azStmt[eStmt], pC->zContentExprlist,
pC->zContent, pC->zContentRowid, pC->zContentRowid,
pC->zContentRowid
);
break;
case FTS5_STMT_LOOKUP:
zSql = sqlite3_mprintf(azStmt[eStmt],
pC->zContentExprlist, pC->zContent, pC->zContentRowid
);
break;
case FTS5_STMT_INSERT_CONTENT:
case FTS5_STMT_REPLACE_CONTENT: {
int nCol = pC->nCol + 1;
char *zBind;
int i;
zBind = sqlite3_malloc64(1 + nCol*2);
if( zBind ){
for(i=0; i<nCol; i++){
zBind[i*2] = '?';
zBind[i*2 + 1] = ',';
}
zBind[i*2-1] = '\0';
zSql = sqlite3_mprintf(azStmt[eStmt], pC->zDb, pC->zName, zBind);
sqlite3_free(zBind);
}
break;
}
default:
zSql = sqlite3_mprintf(azStmt[eStmt], pC->zDb, pC->zName);
break;
}
if( zSql==0 ){
rc = SQLITE_NOMEM;
}else{
int f = SQLITE_PREPARE_PERSISTENT;
if( eStmt>FTS5_STMT_LOOKUP ) f |= SQLITE_PREPARE_NO_VTAB;
p->pConfig->bLock++;
rc = sqlite3_prepare_v3(pC->db, zSql, -1, f, &p->aStmt[eStmt], 0);
p->pConfig->bLock--;
sqlite3_free(zSql);
if( rc!=SQLITE_OK && pzErrMsg ){
*pzErrMsg = sqlite3_mprintf("%s", sqlite3_errmsg(pC->db));
}
}
}
*ppStmt = p->aStmt[eStmt];
sqlite3_reset(*ppStmt);
return rc;
}
static int fts5ExecPrintf(
sqlite3 *db,
char **pzErr,
const char *zFormat,
...
){
int rc;
va_list ap; /* ... printf arguments */
char *zSql;
va_start(ap, zFormat);
zSql = sqlite3_vmprintf(zFormat, ap);
if( zSql==0 ){
rc = SQLITE_NOMEM;
}else{
rc = sqlite3_exec(db, zSql, 0, 0, pzErr);
sqlite3_free(zSql);
}
va_end(ap);
return rc;
}
/*
** Drop all shadow tables. Return SQLITE_OK if successful or an SQLite error
** code otherwise.
*/
static int sqlite3Fts5DropAll(Fts5Config *pConfig){
int rc = fts5ExecPrintf(pConfig->db, 0,
"DROP TABLE IF EXISTS %Q.'%q_data';"
"DROP TABLE IF EXISTS %Q.'%q_idx';"
"DROP TABLE IF EXISTS %Q.'%q_config';",
pConfig->zDb, pConfig->zName,
pConfig->zDb, pConfig->zName,
pConfig->zDb, pConfig->zName
);
if( rc==SQLITE_OK && pConfig->bColumnsize ){
rc = fts5ExecPrintf(pConfig->db, 0,
"DROP TABLE IF EXISTS %Q.'%q_docsize';",
pConfig->zDb, pConfig->zName
);
}
if( rc==SQLITE_OK && pConfig->eContent==FTS5_CONTENT_NORMAL ){
rc = fts5ExecPrintf(pConfig->db, 0,
"DROP TABLE IF EXISTS %Q.'%q_content';",
pConfig->zDb, pConfig->zName
);
}
return rc;
}
static void fts5StorageRenameOne(
Fts5Config *pConfig, /* Current FTS5 configuration */
int *pRc, /* IN/OUT: Error code */
const char *zTail, /* Tail of table name e.g. "data", "config" */
const char *zName /* New name of FTS5 table */
){
if( *pRc==SQLITE_OK ){
*pRc = fts5ExecPrintf(pConfig->db, 0,
"ALTER TABLE %Q.'%q_%s' RENAME TO '%q_%s';",
pConfig->zDb, pConfig->zName, zTail, zName, zTail
);
}
}
static int sqlite3Fts5StorageRename(Fts5Storage *pStorage, const char *zName){
Fts5Config *pConfig = pStorage->pConfig;
int rc = sqlite3Fts5StorageSync(pStorage);
fts5StorageRenameOne(pConfig, &rc, "data", zName);
fts5StorageRenameOne(pConfig, &rc, "idx", zName);
fts5StorageRenameOne(pConfig, &rc, "config", zName);
if( pConfig->bColumnsize ){
fts5StorageRenameOne(pConfig, &rc, "docsize", zName);
}
if( pConfig->eContent==FTS5_CONTENT_NORMAL ){
fts5StorageRenameOne(pConfig, &rc, "content", zName);
}
return rc;
}
/*
** Create the shadow table named zPost, with definition zDefn. Return
** SQLITE_OK if successful, or an SQLite error code otherwise.
*/
static int sqlite3Fts5CreateTable(
Fts5Config *pConfig, /* FTS5 configuration */
const char *zPost, /* Shadow table to create (e.g. "content") */
const char *zDefn, /* Columns etc. for shadow table */
int bWithout, /* True for without rowid */
char **pzErr /* OUT: Error message */
){
int rc;
char *zErr = 0;
rc = fts5ExecPrintf(pConfig->db, &zErr, "CREATE TABLE %Q.'%q_%q'(%s)%s",
pConfig->zDb, pConfig->zName, zPost, zDefn,
#ifndef SQLITE_FTS5_NO_WITHOUT_ROWID
bWithout?" WITHOUT ROWID":
#endif
""
);
if( zErr ){
*pzErr = sqlite3_mprintf(
"fts5: error creating shadow table %q_%s: %s",
pConfig->zName, zPost, zErr
);
sqlite3_free(zErr);
}
return rc;
}
/*
** Open a new Fts5Index handle. If the bCreate argument is true, create
** and initialize the underlying tables
**
** If successful, set *pp to point to the new object and return SQLITE_OK.
** Otherwise, set *pp to NULL and return an SQLite error code.
*/
static int sqlite3Fts5StorageOpen(
Fts5Config *pConfig,
Fts5Index *pIndex,
int bCreate,
Fts5Storage **pp,
char **pzErr /* OUT: Error message */
){
int rc = SQLITE_OK;
Fts5Storage *p; /* New object */
sqlite3_int64 nByte; /* Bytes of space to allocate */
nByte = sizeof(Fts5Storage) /* Fts5Storage object */
+ pConfig->nCol * sizeof(i64); /* Fts5Storage.aTotalSize[] */
*pp = p = (Fts5Storage*)sqlite3_malloc64(nByte);
if( !p ) return SQLITE_NOMEM;
memset(p, 0, (size_t)nByte);
p->aTotalSize = (i64*)&p[1];
p->pConfig = pConfig;
p->pIndex = pIndex;
if( bCreate ){
if( pConfig->eContent==FTS5_CONTENT_NORMAL ){
int nDefn = 32 + pConfig->nCol*10;
char *zDefn = sqlite3_malloc64(32 + (sqlite3_int64)pConfig->nCol * 10);
if( zDefn==0 ){
rc = SQLITE_NOMEM;
}else{
int i;
int iOff;
sqlite3_snprintf(nDefn, zDefn, "id INTEGER PRIMARY KEY");
iOff = (int)strlen(zDefn);
for(i=0; i<pConfig->nCol; i++){
sqlite3_snprintf(nDefn-iOff, &zDefn[iOff], ", c%d", i);
iOff += (int)strlen(&zDefn[iOff]);
}
rc = sqlite3Fts5CreateTable(pConfig, "content", zDefn, 0, pzErr);
}
sqlite3_free(zDefn);
}
if( rc==SQLITE_OK && pConfig->bColumnsize ){
rc = sqlite3Fts5CreateTable(
pConfig, "docsize", "id INTEGER PRIMARY KEY, sz BLOB", 0, pzErr
);
}
if( rc==SQLITE_OK ){
rc = sqlite3Fts5CreateTable(
pConfig, "config", "k PRIMARY KEY, v", 1, pzErr
);
}
if( rc==SQLITE_OK ){
rc = sqlite3Fts5StorageConfigValue(p, "version", 0, FTS5_CURRENT_VERSION);
}
}
if( rc ){
sqlite3Fts5StorageClose(p);
*pp = 0;
}
return rc;
}
/*
** Close a handle opened by an earlier call to sqlite3Fts5StorageOpen().
*/
static int sqlite3Fts5StorageClose(Fts5Storage *p){
int rc = SQLITE_OK;
if( p ){
int i;
/* Finalize all SQL statements */
for(i=0; i<ArraySize(p->aStmt); i++){
sqlite3_finalize(p->aStmt[i]);
}
sqlite3_free(p);
}
return rc;
}
typedef struct Fts5InsertCtx Fts5InsertCtx;
struct Fts5InsertCtx {
Fts5Storage *pStorage;
int iCol;
int szCol; /* Size of column value in tokens */
};
/*
** Tokenization callback used when inserting tokens into the FTS index.
*/
static int fts5StorageInsertCallback(
void *pContext, /* Pointer to Fts5InsertCtx object */
int tflags,
const char *pToken, /* Buffer containing token */
int nToken, /* Size of token in bytes */
int iUnused1, /* Start offset of token */
int iUnused2 /* End offset of token */
){
Fts5InsertCtx *pCtx = (Fts5InsertCtx*)pContext;
Fts5Index *pIdx = pCtx->pStorage->pIndex;
UNUSED_PARAM2(iUnused1, iUnused2);
if( nToken>FTS5_MAX_TOKEN_SIZE ) nToken = FTS5_MAX_TOKEN_SIZE;
if( (tflags & FTS5_TOKEN_COLOCATED)==0 || pCtx->szCol==0 ){
pCtx->szCol++;
}
return sqlite3Fts5IndexWrite(pIdx, pCtx->iCol, pCtx->szCol-1, pToken, nToken);
}
/*
** If a row with rowid iDel is present in the %_content table, add the
** delete-markers to the FTS index necessary to delete it. Do not actually
** remove the %_content row at this time though.
*/
static int fts5StorageDeleteFromIndex(
Fts5Storage *p,
i64 iDel,
sqlite3_value **apVal
){
Fts5Config *pConfig = p->pConfig;
sqlite3_stmt *pSeek = 0; /* SELECT to read row iDel from %_data */
int rc; /* Return code */
int rc2; /* sqlite3_reset() return code */
int iCol;
Fts5InsertCtx ctx;
if( apVal==0 ){
rc = fts5StorageGetStmt(p, FTS5_STMT_LOOKUP, &pSeek, 0);
if( rc!=SQLITE_OK ) return rc;
sqlite3_bind_int64(pSeek, 1, iDel);
if( sqlite3_step(pSeek)!=SQLITE_ROW ){
return sqlite3_reset(pSeek);
}
}
ctx.pStorage = p;
ctx.iCol = -1;
rc = sqlite3Fts5IndexBeginWrite(p->pIndex, 1, iDel);
for(iCol=1; rc==SQLITE_OK && iCol<=pConfig->nCol; iCol++){
if( pConfig->abUnindexed[iCol-1]==0 ){
const char *zText;
int nText;
if( pSeek ){
zText = (const char*)sqlite3_column_text(pSeek, iCol);
nText = sqlite3_column_bytes(pSeek, iCol);
}else{
zText = (const char*)sqlite3_value_text(apVal[iCol-1]);
nText = sqlite3_value_bytes(apVal[iCol-1]);
}
ctx.szCol = 0;
rc = sqlite3Fts5Tokenize(pConfig, FTS5_TOKENIZE_DOCUMENT,
zText, nText, (void*)&ctx, fts5StorageInsertCallback
);
p->aTotalSize[iCol-1] -= (i64)ctx.szCol;
if( p->aTotalSize[iCol-1]<0 ){
rc = FTS5_CORRUPT;
}
}
}
if( rc==SQLITE_OK && p->nTotalRow<1 ){
rc = FTS5_CORRUPT;
}else{
p->nTotalRow--;
}
rc2 = sqlite3_reset(pSeek);
if( rc==SQLITE_OK ) rc = rc2;
return rc;
}
/*
** Insert a record into the %_docsize table. Specifically, do:
**
** INSERT OR REPLACE INTO %_docsize(id, sz) VALUES(iRowid, pBuf);
**
** If there is no %_docsize table (as happens if the columnsize=0 option
** is specified when the FTS5 table is created), this function is a no-op.
*/
static int fts5StorageInsertDocsize(
Fts5Storage *p, /* Storage module to write to */
i64 iRowid, /* id value */
Fts5Buffer *pBuf /* sz value */
){
int rc = SQLITE_OK;
if( p->pConfig->bColumnsize ){
sqlite3_stmt *pReplace = 0;
rc = fts5StorageGetStmt(p, FTS5_STMT_REPLACE_DOCSIZE, &pReplace, 0);
if( rc==SQLITE_OK ){
sqlite3_bind_int64(pReplace, 1, iRowid);
sqlite3_bind_blob(pReplace, 2, pBuf->p, pBuf->n, SQLITE_STATIC);
sqlite3_step(pReplace);
rc = sqlite3_reset(pReplace);
sqlite3_bind_null(pReplace, 2);
}
}
return rc;
}
/*
** Load the contents of the "averages" record from disk into the
** p->nTotalRow and p->aTotalSize[] variables. If successful, and if
** argument bCache is true, set the p->bTotalsValid flag to indicate
** that the contents of aTotalSize[] and nTotalRow are valid until
** further notice.
**
** Return SQLITE_OK if successful, or an SQLite error code if an error
** occurs.
*/
static int fts5StorageLoadTotals(Fts5Storage *p, int bCache){
int rc = SQLITE_OK;
if( p->bTotalsValid==0 ){
rc = sqlite3Fts5IndexGetAverages(p->pIndex, &p->nTotalRow, p->aTotalSize);
p->bTotalsValid = bCache;
}
return rc;
}
/*
** Store the current contents of the p->nTotalRow and p->aTotalSize[]
** variables in the "averages" record on disk.
**
** Return SQLITE_OK if successful, or an SQLite error code if an error
** occurs.
*/
static int fts5StorageSaveTotals(Fts5Storage *p){
int nCol = p->pConfig->nCol;
int i;
Fts5Buffer buf;
int rc = SQLITE_OK;
memset(&buf, 0, sizeof(buf));
sqlite3Fts5BufferAppendVarint(&rc, &buf, p->nTotalRow);
for(i=0; i<nCol; i++){
sqlite3Fts5BufferAppendVarint(&rc, &buf, p->aTotalSize[i]);
}
if( rc==SQLITE_OK ){
rc = sqlite3Fts5IndexSetAverages(p->pIndex, buf.p, buf.n);
}
sqlite3_free(buf.p);
return rc;
}
/*
** Remove a row from the FTS table.
*/
static int sqlite3Fts5StorageDelete(Fts5Storage *p, i64 iDel, sqlite3_value **apVal){
Fts5Config *pConfig = p->pConfig;
int rc;
sqlite3_stmt *pDel = 0;
assert( pConfig->eContent!=FTS5_CONTENT_NORMAL || apVal==0 );
rc = fts5StorageLoadTotals(p, 1);
/* Delete the index records */
if( rc==SQLITE_OK ){
rc = fts5StorageDeleteFromIndex(p, iDel, apVal);
}
/* Delete the %_docsize record */
if( rc==SQLITE_OK && pConfig->bColumnsize ){
rc = fts5StorageGetStmt(p, FTS5_STMT_DELETE_DOCSIZE, &pDel, 0);
if( rc==SQLITE_OK ){
sqlite3_bind_int64(pDel, 1, iDel);
sqlite3_step(pDel);
rc = sqlite3_reset(pDel);
}
}
/* Delete the %_content record */
if( pConfig->eContent==FTS5_CONTENT_NORMAL ){
if( rc==SQLITE_OK ){
rc = fts5StorageGetStmt(p, FTS5_STMT_DELETE_CONTENT, &pDel, 0);
}
if( rc==SQLITE_OK ){
sqlite3_bind_int64(pDel, 1, iDel);
sqlite3_step(pDel);
rc = sqlite3_reset(pDel);
}
}
return rc;
}
/*
** Delete all entries in the FTS5 index.
*/
static int sqlite3Fts5StorageDeleteAll(Fts5Storage *p){
Fts5Config *pConfig = p->pConfig;
int rc;
p->bTotalsValid = 0;
/* Delete the contents of the %_data and %_docsize tables. */
rc = fts5ExecPrintf(pConfig->db, 0,
"DELETE FROM %Q.'%q_data';"
"DELETE FROM %Q.'%q_idx';",
pConfig->zDb, pConfig->zName,
pConfig->zDb, pConfig->zName
);
if( rc==SQLITE_OK && pConfig->bColumnsize ){
rc = fts5ExecPrintf(pConfig->db, 0,
"DELETE FROM %Q.'%q_docsize';",
pConfig->zDb, pConfig->zName
);
}
/* Reinitialize the %_data table. This call creates the initial structure
** and averages records. */
if( rc==SQLITE_OK ){
rc = sqlite3Fts5IndexReinit(p->pIndex);
}
if( rc==SQLITE_OK ){
rc = sqlite3Fts5StorageConfigValue(p, "version", 0, FTS5_CURRENT_VERSION);
}
return rc;
}
static int sqlite3Fts5StorageRebuild(Fts5Storage *p){
Fts5Buffer buf = {0,0,0};
Fts5Config *pConfig = p->pConfig;
sqlite3_stmt *pScan = 0;
Fts5InsertCtx ctx;
int rc, rc2;
memset(&ctx, 0, sizeof(Fts5InsertCtx));
ctx.pStorage = p;
rc = sqlite3Fts5StorageDeleteAll(p);
if( rc==SQLITE_OK ){
rc = fts5StorageLoadTotals(p, 1);
}
if( rc==SQLITE_OK ){
rc = fts5StorageGetStmt(p, FTS5_STMT_SCAN, &pScan, 0);
}
while( rc==SQLITE_OK && SQLITE_ROW==sqlite3_step(pScan) ){
i64 iRowid = sqlite3_column_int64(pScan, 0);
sqlite3Fts5BufferZero(&buf);
rc = sqlite3Fts5IndexBeginWrite(p->pIndex, 0, iRowid);
for(ctx.iCol=0; rc==SQLITE_OK && ctx.iCol<pConfig->nCol; ctx.iCol++){
ctx.szCol = 0;
if( pConfig->abUnindexed[ctx.iCol]==0 ){
const char *zText = (const char*)sqlite3_column_text(pScan, ctx.iCol+1);
int nText = sqlite3_column_bytes(pScan, ctx.iCol+1);
rc = sqlite3Fts5Tokenize(pConfig,
FTS5_TOKENIZE_DOCUMENT,
zText, nText,
(void*)&ctx,
fts5StorageInsertCallback
);
}
sqlite3Fts5BufferAppendVarint(&rc, &buf, ctx.szCol);
p->aTotalSize[ctx.iCol] += (i64)ctx.szCol;
}
p->nTotalRow++;
if( rc==SQLITE_OK ){
rc = fts5StorageInsertDocsize(p, iRowid, &buf);
}
}
sqlite3_free(buf.p);
rc2 = sqlite3_reset(pScan);
if( rc==SQLITE_OK ) rc = rc2;
/* Write the averages record */
if( rc==SQLITE_OK ){
rc = fts5StorageSaveTotals(p);
}
return rc;
}
static int sqlite3Fts5StorageOptimize(Fts5Storage *p){
return sqlite3Fts5IndexOptimize(p->pIndex);
}
static int sqlite3Fts5StorageMerge(Fts5Storage *p, int nMerge){
return sqlite3Fts5IndexMerge(p->pIndex, nMerge);
}
static int sqlite3Fts5StorageReset(Fts5Storage *p){
return sqlite3Fts5IndexReset(p->pIndex);
}
/*
** Allocate a new rowid. This is used for "external content" tables when
** a NULL value is inserted into the rowid column. The new rowid is allocated
** by inserting a dummy row into the %_docsize table. The dummy will be
** overwritten later.
**
** If the %_docsize table does not exist, SQLITE_MISMATCH is returned. In
** this case the user is required to provide a rowid explicitly.
*/
static int fts5StorageNewRowid(Fts5Storage *p, i64 *piRowid){
int rc = SQLITE_MISMATCH;
if( p->pConfig->bColumnsize ){
sqlite3_stmt *pReplace = 0;
rc = fts5StorageGetStmt(p, FTS5_STMT_REPLACE_DOCSIZE, &pReplace, 0);
if( rc==SQLITE_OK ){
sqlite3_bind_null(pReplace, 1);
sqlite3_bind_null(pReplace, 2);
sqlite3_step(pReplace);
rc = sqlite3_reset(pReplace);
}
if( rc==SQLITE_OK ){
*piRowid = sqlite3_last_insert_rowid(p->pConfig->db);
}
}
return rc;
}
/*
** Insert a new row into the FTS content table.
*/
static int sqlite3Fts5StorageContentInsert(
Fts5Storage *p,
sqlite3_value **apVal,
i64 *piRowid
){
Fts5Config *pConfig = p->pConfig;
int rc = SQLITE_OK;
/* Insert the new row into the %_content table. */
if( pConfig->eContent!=FTS5_CONTENT_NORMAL ){
if( sqlite3_value_type(apVal[1])==SQLITE_INTEGER ){
*piRowid = sqlite3_value_int64(apVal[1]);
}else{
rc = fts5StorageNewRowid(p, piRowid);
}
}else{
sqlite3_stmt *pInsert = 0; /* Statement to write %_content table */
int i; /* Counter variable */
rc = fts5StorageGetStmt(p, FTS5_STMT_INSERT_CONTENT, &pInsert, 0);
for(i=1; rc==SQLITE_OK && i<=pConfig->nCol+1; i++){
rc = sqlite3_bind_value(pInsert, i, apVal[i]);
}
if( rc==SQLITE_OK ){
sqlite3_step(pInsert);
rc = sqlite3_reset(pInsert);
}
*piRowid = sqlite3_last_insert_rowid(pConfig->db);
}
return rc;
}
/*
** Insert new entries into the FTS index and %_docsize table.
*/
static int sqlite3Fts5StorageIndexInsert(
Fts5Storage *p,
sqlite3_value **apVal,
i64 iRowid
){
Fts5Config *pConfig = p->pConfig;
int rc = SQLITE_OK; /* Return code */
Fts5InsertCtx ctx; /* Tokenization callback context object */
Fts5Buffer buf; /* Buffer used to build up %_docsize blob */
memset(&buf, 0, sizeof(Fts5Buffer));
ctx.pStorage = p;
rc = fts5StorageLoadTotals(p, 1);
if( rc==SQLITE_OK ){
rc = sqlite3Fts5IndexBeginWrite(p->pIndex, 0, iRowid);
}
for(ctx.iCol=0; rc==SQLITE_OK && ctx.iCol<pConfig->nCol; ctx.iCol++){
ctx.szCol = 0;
if( pConfig->abUnindexed[ctx.iCol]==0 ){
const char *zText = (const char*)sqlite3_value_text(apVal[ctx.iCol+2]);
int nText = sqlite3_value_bytes(apVal[ctx.iCol+2]);
rc = sqlite3Fts5Tokenize(pConfig,
FTS5_TOKENIZE_DOCUMENT,
zText, nText,
(void*)&ctx,
fts5StorageInsertCallback
);
}
sqlite3Fts5BufferAppendVarint(&rc, &buf, ctx.szCol);
p->aTotalSize[ctx.iCol] += (i64)ctx.szCol;
}
p->nTotalRow++;
/* Write the %_docsize record */
if( rc==SQLITE_OK ){
rc = fts5StorageInsertDocsize(p, iRowid, &buf);
}
sqlite3_free(buf.p);
return rc;
}
static int fts5StorageCount(Fts5Storage *p, const char *zSuffix, i64 *pnRow){
Fts5Config *pConfig = p->pConfig;
char *zSql;
int rc;
zSql = sqlite3_mprintf("SELECT count(*) FROM %Q.'%q_%s'",
pConfig->zDb, pConfig->zName, zSuffix
);
if( zSql==0 ){
rc = SQLITE_NOMEM;
}else{
sqlite3_stmt *pCnt = 0;
rc = sqlite3_prepare_v2(pConfig->db, zSql, -1, &pCnt, 0);
if( rc==SQLITE_OK ){
if( SQLITE_ROW==sqlite3_step(pCnt) ){
*pnRow = sqlite3_column_int64(pCnt, 0);
}
rc = sqlite3_finalize(pCnt);
}
}
sqlite3_free(zSql);
return rc;
}
/*
** Context object used by sqlite3Fts5StorageIntegrity().
*/
typedef struct Fts5IntegrityCtx Fts5IntegrityCtx;
struct Fts5IntegrityCtx {
i64 iRowid;
int iCol;
int szCol;
u64 cksum;
Fts5Termset *pTermset;
Fts5Config *pConfig;
};
/*
** Tokenization callback used by integrity check.
*/
static int fts5StorageIntegrityCallback(
void *pContext, /* Pointer to Fts5IntegrityCtx object */
int tflags,
const char *pToken, /* Buffer containing token */
int nToken, /* Size of token in bytes */
int iUnused1, /* Start offset of token */
int iUnused2 /* End offset of token */
){
Fts5IntegrityCtx *pCtx = (Fts5IntegrityCtx*)pContext;
Fts5Termset *pTermset = pCtx->pTermset;
int bPresent;
int ii;
int rc = SQLITE_OK;
int iPos;
int iCol;
UNUSED_PARAM2(iUnused1, iUnused2);
if( nToken>FTS5_MAX_TOKEN_SIZE ) nToken = FTS5_MAX_TOKEN_SIZE;
if( (tflags & FTS5_TOKEN_COLOCATED)==0 || pCtx->szCol==0 ){
pCtx->szCol++;
}
switch( pCtx->pConfig->eDetail ){
case FTS5_DETAIL_FULL:
iPos = pCtx->szCol-1;
iCol = pCtx->iCol;
break;
case FTS5_DETAIL_COLUMNS:
iPos = pCtx->iCol;
iCol = 0;
break;
default:
assert( pCtx->pConfig->eDetail==FTS5_DETAIL_NONE );
iPos = 0;
iCol = 0;
break;
}
rc = sqlite3Fts5TermsetAdd(pTermset, 0, pToken, nToken, &bPresent);
if( rc==SQLITE_OK && bPresent==0 ){
pCtx->cksum ^= sqlite3Fts5IndexEntryCksum(
pCtx->iRowid, iCol, iPos, 0, pToken, nToken
);
}
for(ii=0; rc==SQLITE_OK && ii<pCtx->pConfig->nPrefix; ii++){
const int nChar = pCtx->pConfig->aPrefix[ii];
int nByte = sqlite3Fts5IndexCharlenToBytelen(pToken, nToken, nChar);
if( nByte ){
rc = sqlite3Fts5TermsetAdd(pTermset, ii+1, pToken, nByte, &bPresent);
if( bPresent==0 ){
pCtx->cksum ^= sqlite3Fts5IndexEntryCksum(
pCtx->iRowid, iCol, iPos, ii+1, pToken, nByte
);
}
}
}
return rc;
}
/*
** Check that the contents of the FTS index match that of the %_content
** table. Return SQLITE_OK if they do, or SQLITE_CORRUPT if not. Return
** some other SQLite error code if an error occurs while attempting to
** determine this.
*/
static int sqlite3Fts5StorageIntegrity(Fts5Storage *p, int iArg){
Fts5Config *pConfig = p->pConfig;
int rc = SQLITE_OK; /* Return code */
int *aColSize; /* Array of size pConfig->nCol */
i64 *aTotalSize; /* Array of size pConfig->nCol */
Fts5IntegrityCtx ctx;
sqlite3_stmt *pScan;
int bUseCksum;
memset(&ctx, 0, sizeof(Fts5IntegrityCtx));
ctx.pConfig = p->pConfig;
aTotalSize = (i64*)sqlite3_malloc64(pConfig->nCol*(sizeof(int)+sizeof(i64)));
if( !aTotalSize ) return SQLITE_NOMEM;
aColSize = (int*)&aTotalSize[pConfig->nCol];
memset(aTotalSize, 0, sizeof(i64) * pConfig->nCol);
bUseCksum = (pConfig->eContent==FTS5_CONTENT_NORMAL
|| (pConfig->eContent==FTS5_CONTENT_EXTERNAL && iArg)
);
if( bUseCksum ){
/* Generate the expected index checksum based on the contents of the
** %_content table. This block stores the checksum in ctx.cksum. */
rc = fts5StorageGetStmt(p, FTS5_STMT_SCAN, &pScan, 0);
if( rc==SQLITE_OK ){
int rc2;
while( SQLITE_ROW==sqlite3_step(pScan) ){
int i;
ctx.iRowid = sqlite3_column_int64(pScan, 0);
ctx.szCol = 0;
if( pConfig->bColumnsize ){
rc = sqlite3Fts5StorageDocsize(p, ctx.iRowid, aColSize);
}
if( rc==SQLITE_OK && pConfig->eDetail==FTS5_DETAIL_NONE ){
rc = sqlite3Fts5TermsetNew(&ctx.pTermset);
}
for(i=0; rc==SQLITE_OK && i<pConfig->nCol; i++){
if( pConfig->abUnindexed[i] ) continue;
ctx.iCol = i;
ctx.szCol = 0;
if( pConfig->eDetail==FTS5_DETAIL_COLUMNS ){
rc = sqlite3Fts5TermsetNew(&ctx.pTermset);
}
if( rc==SQLITE_OK ){
const char *zText = (const char*)sqlite3_column_text(pScan, i+1);
int nText = sqlite3_column_bytes(pScan, i+1);
rc = sqlite3Fts5Tokenize(pConfig,
FTS5_TOKENIZE_DOCUMENT,
zText, nText,
(void*)&ctx,
fts5StorageIntegrityCallback
);
}
if( rc==SQLITE_OK && pConfig->bColumnsize && ctx.szCol!=aColSize[i] ){
rc = FTS5_CORRUPT;
}
aTotalSize[i] += ctx.szCol;
if( pConfig->eDetail==FTS5_DETAIL_COLUMNS ){
sqlite3Fts5TermsetFree(ctx.pTermset);
ctx.pTermset = 0;
}
}
sqlite3Fts5TermsetFree(ctx.pTermset);
ctx.pTermset = 0;
if( rc!=SQLITE_OK ) break;
}
rc2 = sqlite3_reset(pScan);
if( rc==SQLITE_OK ) rc = rc2;
}
/* Test that the "totals" (sometimes called "averages") record looks Ok */
if( rc==SQLITE_OK ){
int i;
rc = fts5StorageLoadTotals(p, 0);
for(i=0; rc==SQLITE_OK && i<pConfig->nCol; i++){
if( p->aTotalSize[i]!=aTotalSize[i] ) rc = FTS5_CORRUPT;
}
}
/* Check that the %_docsize and %_content tables contain the expected
** number of rows. */
if( rc==SQLITE_OK && pConfig->eContent==FTS5_CONTENT_NORMAL ){
i64 nRow = 0;
rc = fts5StorageCount(p, "content", &nRow);
if( rc==SQLITE_OK && nRow!=p->nTotalRow ) rc = FTS5_CORRUPT;
}
if( rc==SQLITE_OK && pConfig->bColumnsize ){
i64 nRow = 0;
rc = fts5StorageCount(p, "docsize", &nRow);
if( rc==SQLITE_OK && nRow!=p->nTotalRow ) rc = FTS5_CORRUPT;
}
}
/* Pass the expected checksum down to the FTS index module. It will
** verify, amongst other things, that it matches the checksum generated by
** inspecting the index itself. */
if( rc==SQLITE_OK ){
rc = sqlite3Fts5IndexIntegrityCheck(p->pIndex, ctx.cksum, bUseCksum);
}
sqlite3_free(aTotalSize);
return rc;
}
/*
** Obtain an SQLite statement handle that may be used to read data from the
** %_content table.
*/
static int sqlite3Fts5StorageStmt(
Fts5Storage *p,
int eStmt,
sqlite3_stmt **pp,
char **pzErrMsg
){
int rc;
assert( eStmt==FTS5_STMT_SCAN_ASC
|| eStmt==FTS5_STMT_SCAN_DESC
|| eStmt==FTS5_STMT_LOOKUP
);
rc = fts5StorageGetStmt(p, eStmt, pp, pzErrMsg);
if( rc==SQLITE_OK ){
assert( p->aStmt[eStmt]==*pp );
p->aStmt[eStmt] = 0;
}
return rc;
}
/*
** Release an SQLite statement handle obtained via an earlier call to
** sqlite3Fts5StorageStmt(). The eStmt parameter passed to this function
** must match that passed to the sqlite3Fts5StorageStmt() call.
*/
static void sqlite3Fts5StorageStmtRelease(
Fts5Storage *p,
int eStmt,
sqlite3_stmt *pStmt
){
assert( eStmt==FTS5_STMT_SCAN_ASC
|| eStmt==FTS5_STMT_SCAN_DESC
|| eStmt==FTS5_STMT_LOOKUP
);
if( p->aStmt[eStmt]==0 ){
sqlite3_reset(pStmt);
p->aStmt[eStmt] = pStmt;
}else{
sqlite3_finalize(pStmt);
}
}
static int fts5StorageDecodeSizeArray(
int *aCol, int nCol, /* Array to populate */
const u8 *aBlob, int nBlob /* Record to read varints from */
){
int i;
int iOff = 0;
for(i=0; i<nCol; i++){
if( iOff>=nBlob ) return 1;
iOff += fts5GetVarint32(&aBlob[iOff], aCol[i]);
}
return (iOff!=nBlob);
}
/*
** Argument aCol points to an array of integers containing one entry for
** each table column. This function reads the %_docsize record for the
** specified rowid and populates aCol[] with the results.
**
** An SQLite error code is returned if an error occurs, or SQLITE_OK
** otherwise.
*/
static int sqlite3Fts5StorageDocsize(Fts5Storage *p, i64 iRowid, int *aCol){
int nCol = p->pConfig->nCol; /* Number of user columns in table */
sqlite3_stmt *pLookup = 0; /* Statement to query %_docsize */
int rc; /* Return Code */
assert( p->pConfig->bColumnsize );
rc = fts5StorageGetStmt(p, FTS5_STMT_LOOKUP_DOCSIZE, &pLookup, 0);
if( rc==SQLITE_OK ){
int bCorrupt = 1;
sqlite3_bind_int64(pLookup, 1, iRowid);
if( SQLITE_ROW==sqlite3_step(pLookup) ){
const u8 *aBlob = sqlite3_column_blob(pLookup, 0);
int nBlob = sqlite3_column_bytes(pLookup, 0);
if( 0==fts5StorageDecodeSizeArray(aCol, nCol, aBlob, nBlob) ){
bCorrupt = 0;
}
}
rc = sqlite3_reset(pLookup);
if( bCorrupt && rc==SQLITE_OK ){
rc = FTS5_CORRUPT;
}
}
return rc;
}
static int sqlite3Fts5StorageSize(Fts5Storage *p, int iCol, i64 *pnToken){
int rc = fts5StorageLoadTotals(p, 0);
if( rc==SQLITE_OK ){
*pnToken = 0;
if( iCol<0 ){
int i;
for(i=0; i<p->pConfig->nCol; i++){
*pnToken += p->aTotalSize[i];
}
}else if( iCol<p->pConfig->nCol ){
*pnToken = p->aTotalSize[iCol];
}else{
rc = SQLITE_RANGE;
}
}
return rc;
}
static int sqlite3Fts5StorageRowCount(Fts5Storage *p, i64 *pnRow){
int rc = fts5StorageLoadTotals(p, 0);
if( rc==SQLITE_OK ){
/* nTotalRow being zero does not necessarily indicate a corrupt
** database - it might be that the FTS5 table really does contain zero
** rows. However this function is only called from the xRowCount() API,
** and there is no way for that API to be invoked if the table contains
** no rows. Hence the FTS5_CORRUPT return. */
*pnRow = p->nTotalRow;
if( p->nTotalRow<=0 ) rc = FTS5_CORRUPT;
}
return rc;
}
/*
** Flush any data currently held in-memory to disk.
*/
static int sqlite3Fts5StorageSync(Fts5Storage *p){
int rc = SQLITE_OK;
i64 iLastRowid = sqlite3_last_insert_rowid(p->pConfig->db);
if( p->bTotalsValid ){
rc = fts5StorageSaveTotals(p);
p->bTotalsValid = 0;
}
if( rc==SQLITE_OK ){
rc = sqlite3Fts5IndexSync(p->pIndex);
}
sqlite3_set_last_insert_rowid(p->pConfig->db, iLastRowid);
return rc;
}
static int sqlite3Fts5StorageRollback(Fts5Storage *p){
p->bTotalsValid = 0;
return sqlite3Fts5IndexRollback(p->pIndex);
}
static int sqlite3Fts5StorageConfigValue(
Fts5Storage *p,
const char *z,
sqlite3_value *pVal,
int iVal
){
sqlite3_stmt *pReplace = 0;
int rc = fts5StorageGetStmt(p, FTS5_STMT_REPLACE_CONFIG, &pReplace, 0);
if( rc==SQLITE_OK ){
sqlite3_bind_text(pReplace, 1, z, -1, SQLITE_STATIC);
if( pVal ){
sqlite3_bind_value(pReplace, 2, pVal);
}else{
sqlite3_bind_int(pReplace, 2, iVal);
}
sqlite3_step(pReplace);
rc = sqlite3_reset(pReplace);
sqlite3_bind_null(pReplace, 1);
}
if( rc==SQLITE_OK && pVal ){
int iNew = p->pConfig->iCookie + 1;
rc = sqlite3Fts5IndexSetCookie(p->pIndex, iNew);
if( rc==SQLITE_OK ){
p->pConfig->iCookie = iNew;
}
}
return rc;
}
#line 1 "fts5_tokenize.c"
/*
** 2014 May 31
**
** The author disclaims copyright to this source code. In place of
** a legal notice, here is a blessing:
**
** May you do good and not evil.
** May you find forgiveness for yourself and forgive others.
** May you share freely, never taking more than you give.
**
******************************************************************************
*/
/* #include "third_party/sqlite3/fts5Int.h" */
/**************************************************************************
** Start of ascii tokenizer implementation.
*/
/*
** For tokenizers with no "unicode" modifier, the set of token characters
** is the same as the set of ASCII range alphanumeric characters.
*/
static unsigned char aAsciiTokenChar[128] = {
0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, /* 0x00..0x0F */
0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, /* 0x10..0x1F */
0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, /* 0x20..0x2F */
1, 1, 1, 1, 1, 1, 1, 1, 1, 1, 0, 0, 0, 0, 0, 0, /* 0x30..0x3F */
0, 1, 1, 1, 1, 1, 1, 1, 1, 1, 1, 1, 1, 1, 1, 1, /* 0x40..0x4F */
1, 1, 1, 1, 1, 1, 1, 1, 1, 1, 1, 0, 0, 0, 0, 0, /* 0x50..0x5F */
0, 1, 1, 1, 1, 1, 1, 1, 1, 1, 1, 1, 1, 1, 1, 1, /* 0x60..0x6F */
1, 1, 1, 1, 1, 1, 1, 1, 1, 1, 1, 0, 0, 0, 0, 0, /* 0x70..0x7F */
};
typedef struct AsciiTokenizer AsciiTokenizer;
struct AsciiTokenizer {
unsigned char aTokenChar[128];
};
static void fts5AsciiAddExceptions(
AsciiTokenizer *p,
const char *zArg,
int bTokenChars
){
int i;
for(i=0; zArg[i]; i++){
if( (zArg[i] & 0x80)==0 ){
p->aTokenChar[(int)zArg[i]] = (unsigned char)bTokenChars;
}
}
}
/*
** Delete a "ascii" tokenizer.
*/
static void fts5AsciiDelete(Fts5Tokenizer *p){
sqlite3_free(p);
}
/*
** Create an "ascii" tokenizer.
*/
static int fts5AsciiCreate(
void *pUnused,
const char **azArg, int nArg,
Fts5Tokenizer **ppOut
){
int rc = SQLITE_OK;
AsciiTokenizer *p = 0;
UNUSED_PARAM(pUnused);
if( nArg%2 ){
rc = SQLITE_ERROR;
}else{
p = sqlite3_malloc(sizeof(AsciiTokenizer));
if( p==0 ){
rc = SQLITE_NOMEM;
}else{
int i;
memset(p, 0, sizeof(AsciiTokenizer));
memcpy(p->aTokenChar, aAsciiTokenChar, sizeof(aAsciiTokenChar));
for(i=0; rc==SQLITE_OK && i<nArg; i+=2){
const char *zArg = azArg[i+1];
if( 0==sqlite3_stricmp(azArg[i], "tokenchars") ){
fts5AsciiAddExceptions(p, zArg, 1);
}else
if( 0==sqlite3_stricmp(azArg[i], "separators") ){
fts5AsciiAddExceptions(p, zArg, 0);
}else{
rc = SQLITE_ERROR;
}
}
if( rc!=SQLITE_OK ){
fts5AsciiDelete((Fts5Tokenizer*)p);
p = 0;
}
}
}
*ppOut = (Fts5Tokenizer*)p;
return rc;
}
static void asciiFold(char *aOut, const char *aIn, int nByte){
int i;
for(i=0; i<nByte; i++){
char c = aIn[i];
if( c>='A' && c<='Z' ) c += 32;
aOut[i] = c;
}
}
/*
** Tokenize some text using the ascii tokenizer.
*/
static int fts5AsciiTokenize(
Fts5Tokenizer *pTokenizer,
void *pCtx,
int iUnused,
const char *pText, int nText,
int (*xToken)(void*, int, const char*, int nToken, int iStart, int iEnd)
){
AsciiTokenizer *p = (AsciiTokenizer*)pTokenizer;
int rc = SQLITE_OK;
int ie;
int is = 0;
char aFold[64];
int nFold = sizeof(aFold);
char *pFold = aFold;
unsigned char *a = p->aTokenChar;
UNUSED_PARAM(iUnused);
while( is<nText && rc==SQLITE_OK ){
int nByte;
/* Skip any leading divider characters. */
while( is<nText && ((pText[is]&0x80)==0 && a[(int)pText[is]]==0) ){
is++;
}
if( is==nText ) break;
/* Count the token characters */
ie = is+1;
while( ie<nText && ((pText[ie]&0x80) || a[(int)pText[ie]] ) ){
ie++;
}
/* Fold to lower case */
nByte = ie-is;
if( nByte>nFold ){
if( pFold!=aFold ) sqlite3_free(pFold);
pFold = sqlite3_malloc64((sqlite3_int64)nByte*2);
if( pFold==0 ){
rc = SQLITE_NOMEM;
break;
}
nFold = nByte*2;
}
asciiFold(pFold, &pText[is], nByte);
/* Invoke the token callback */
rc = xToken(pCtx, 0, pFold, nByte, is, ie);
is = ie+1;
}
if( pFold!=aFold ) sqlite3_free(pFold);
if( rc==SQLITE_DONE ) rc = SQLITE_OK;
return rc;
}
/**************************************************************************
** Start of unicode61 tokenizer implementation.
*/
/*
** The following two macros - READ_UTF8 and WRITE_UTF8 - have been copied
** from the sqlite3 source file utf.c. If this file is compiled as part
** of the amalgamation, they are not required.
*/
#ifndef SQLITE_AMALGAMATION
static const unsigned char sqlite3Utf8Trans1[] = {
0x00, 0x01, 0x02, 0x03, 0x04, 0x05, 0x06, 0x07,
0x08, 0x09, 0x0a, 0x0b, 0x0c, 0x0d, 0x0e, 0x0f,
0x10, 0x11, 0x12, 0x13, 0x14, 0x15, 0x16, 0x17,
0x18, 0x19, 0x1a, 0x1b, 0x1c, 0x1d, 0x1e, 0x1f,
0x00, 0x01, 0x02, 0x03, 0x04, 0x05, 0x06, 0x07,
0x08, 0x09, 0x0a, 0x0b, 0x0c, 0x0d, 0x0e, 0x0f,
0x00, 0x01, 0x02, 0x03, 0x04, 0x05, 0x06, 0x07,
0x00, 0x01, 0x02, 0x03, 0x00, 0x01, 0x00, 0x00,
};
#define READ_UTF8(zIn, zTerm, c) \
c = *(zIn++); \
if( c>=0xc0 ){ \
c = sqlite3Utf8Trans1[c-0xc0]; \
while( zIn!=zTerm && (*zIn & 0xc0)==0x80 ){ \
c = (c<<6) + (0x3f & *(zIn++)); \
} \
if( c<0x80 \
|| (c&0xFFFFF800)==0xD800 \
|| (c&0xFFFFFFFE)==0xFFFE ){ c = 0xFFFD; } \
}
#define WRITE_UTF8(zOut, c) { \
if( c<0x00080 ){ \
*zOut++ = (unsigned char)(c&0xFF); \
} \
else if( c<0x00800 ){ \
*zOut++ = 0xC0 + (unsigned char)((c>>6)&0x1F); \
*zOut++ = 0x80 + (unsigned char)(c & 0x3F); \
} \
else if( c<0x10000 ){ \
*zOut++ = 0xE0 + (unsigned char)((c>>12)&0x0F); \
*zOut++ = 0x80 + (unsigned char)((c>>6) & 0x3F); \
*zOut++ = 0x80 + (unsigned char)(c & 0x3F); \
}else{ \
*zOut++ = 0xF0 + (unsigned char)((c>>18) & 0x07); \
*zOut++ = 0x80 + (unsigned char)((c>>12) & 0x3F); \
*zOut++ = 0x80 + (unsigned char)((c>>6) & 0x3F); \
*zOut++ = 0x80 + (unsigned char)(c & 0x3F); \
} \
}
#endif /* ifndef SQLITE_AMALGAMATION */
typedef struct Unicode61Tokenizer Unicode61Tokenizer;
struct Unicode61Tokenizer {
unsigned char aTokenChar[128]; /* ASCII range token characters */
char *aFold; /* Buffer to fold text into */
int nFold; /* Size of aFold[] in bytes */
int eRemoveDiacritic; /* True if remove_diacritics=1 is set */
int nException;
int *aiException;
unsigned char aCategory[32]; /* True for token char categories */
};
/* Values for eRemoveDiacritic (must match internals of fts5_unicode2.c) */
#define FTS5_REMOVE_DIACRITICS_NONE 0
#define FTS5_REMOVE_DIACRITICS_SIMPLE 1
#define FTS5_REMOVE_DIACRITICS_COMPLEX 2
static int fts5UnicodeAddExceptions(
Unicode61Tokenizer *p, /* Tokenizer object */
const char *z, /* Characters to treat as exceptions */
int bTokenChars /* 1 for 'tokenchars', 0 for 'separators' */
){
int rc = SQLITE_OK;
int n = (int)strlen(z);
int *aNew;
if( n>0 ){
aNew = (int*)sqlite3_realloc64(p->aiException,
(n+p->nException)*sizeof(int));
if( aNew ){
int nNew = p->nException;
const unsigned char *zCsr = (const unsigned char*)z;
const unsigned char *zTerm = (const unsigned char*)&z[n];
while( zCsr<zTerm ){
u32 iCode;
int bToken;
READ_UTF8(zCsr, zTerm, iCode);
if( iCode<128 ){
p->aTokenChar[iCode] = (unsigned char)bTokenChars;
}else{
bToken = p->aCategory[sqlite3Fts5UnicodeCategory(iCode)];
assert( (bToken==0 || bToken==1) );
assert( (bTokenChars==0 || bTokenChars==1) );
if( bToken!=bTokenChars && sqlite3Fts5UnicodeIsdiacritic(iCode)==0 ){
int i;
for(i=0; i<nNew; i++){
if( (u32)aNew[i]>iCode ) break;
}
memmove(&aNew[i+1], &aNew[i], (nNew-i)*sizeof(int));
aNew[i] = iCode;
nNew++;
}
}
}
p->aiException = aNew;
p->nException = nNew;
}else{
rc = SQLITE_NOMEM;
}
}
return rc;
}
/*
** Return true if the p->aiException[] array contains the value iCode.
*/
static int fts5UnicodeIsException(Unicode61Tokenizer *p, int iCode){
if( p->nException>0 ){
int *a = p->aiException;
int iLo = 0;
int iHi = p->nException-1;
while( iHi>=iLo ){
int iTest = (iHi + iLo) / 2;
if( iCode==a[iTest] ){
return 1;
}else if( iCode>a[iTest] ){
iLo = iTest+1;
}else{
iHi = iTest-1;
}
}
}
return 0;
}
/*
** Delete a "unicode61" tokenizer.
*/
static void fts5UnicodeDelete(Fts5Tokenizer *pTok){
if( pTok ){
Unicode61Tokenizer *p = (Unicode61Tokenizer*)pTok;
sqlite3_free(p->aiException);
sqlite3_free(p->aFold);
sqlite3_free(p);
}
return;
}
static int unicodeSetCategories(Unicode61Tokenizer *p, const char *zCat){
const char *z = zCat;
while( *z ){
while( *z==' ' || *z=='\t' ) z++;
if( *z && sqlite3Fts5UnicodeCatParse(z, p->aCategory) ){
return SQLITE_ERROR;
}
while( *z!=' ' && *z!='\t' && *z!='\0' ) z++;
}
sqlite3Fts5UnicodeAscii(p->aCategory, p->aTokenChar);
return SQLITE_OK;
}
/*
** Create a "unicode61" tokenizer.
*/
static int fts5UnicodeCreate(
void *pUnused,
const char **azArg, int nArg,
Fts5Tokenizer **ppOut
){
int rc = SQLITE_OK; /* Return code */
Unicode61Tokenizer *p = 0; /* New tokenizer object */
UNUSED_PARAM(pUnused);
if( nArg%2 ){
rc = SQLITE_ERROR;
}else{
p = (Unicode61Tokenizer*)sqlite3_malloc(sizeof(Unicode61Tokenizer));
if( p ){
const char *zCat = "L* N* Co";
int i;
memset(p, 0, sizeof(Unicode61Tokenizer));
p->eRemoveDiacritic = FTS5_REMOVE_DIACRITICS_SIMPLE;
p->nFold = 64;
p->aFold = sqlite3_malloc64(p->nFold * sizeof(char));
if( p->aFold==0 ){
rc = SQLITE_NOMEM;
}
/* Search for a "categories" argument */
for(i=0; rc==SQLITE_OK && i<nArg; i+=2){
if( 0==sqlite3_stricmp(azArg[i], "categories") ){
zCat = azArg[i+1];
}
}
if( rc==SQLITE_OK ){
rc = unicodeSetCategories(p, zCat);
}
for(i=0; rc==SQLITE_OK && i<nArg; i+=2){
const char *zArg = azArg[i+1];
if( 0==sqlite3_stricmp(azArg[i], "remove_diacritics") ){
if( (zArg[0]!='0' && zArg[0]!='1' && zArg[0]!='2') || zArg[1] ){
rc = SQLITE_ERROR;
}else{
p->eRemoveDiacritic = (zArg[0] - '0');
assert( p->eRemoveDiacritic==FTS5_REMOVE_DIACRITICS_NONE
|| p->eRemoveDiacritic==FTS5_REMOVE_DIACRITICS_SIMPLE
|| p->eRemoveDiacritic==FTS5_REMOVE_DIACRITICS_COMPLEX
);
}
}else
if( 0==sqlite3_stricmp(azArg[i], "tokenchars") ){
rc = fts5UnicodeAddExceptions(p, zArg, 1);
}else
if( 0==sqlite3_stricmp(azArg[i], "separators") ){
rc = fts5UnicodeAddExceptions(p, zArg, 0);
}else
if( 0==sqlite3_stricmp(azArg[i], "categories") ){
/* no-op */
}else{
rc = SQLITE_ERROR;
}
}
}else{
rc = SQLITE_NOMEM;
}
if( rc!=SQLITE_OK ){
fts5UnicodeDelete((Fts5Tokenizer*)p);
p = 0;
}
*ppOut = (Fts5Tokenizer*)p;
}
return rc;
}
/*
** Return true if, for the purposes of tokenizing with the tokenizer
** passed as the first argument, codepoint iCode is considered a token
** character (not a separator).
*/
static int fts5UnicodeIsAlnum(Unicode61Tokenizer *p, int iCode){
return (
p->aCategory[sqlite3Fts5UnicodeCategory((u32)iCode)]
^ fts5UnicodeIsException(p, iCode)
);
}
static int fts5UnicodeTokenize(
Fts5Tokenizer *pTokenizer,
void *pCtx,
int iUnused,
const char *pText, int nText,
int (*xToken)(void*, int, const char*, int nToken, int iStart, int iEnd)
){
Unicode61Tokenizer *p = (Unicode61Tokenizer*)pTokenizer;
int rc = SQLITE_OK;
unsigned char *a = p->aTokenChar;
unsigned char *zTerm = (unsigned char*)&pText[nText];
unsigned char *zCsr = (unsigned char *)pText;
/* Output buffer */
char *aFold = p->aFold;
int nFold = p->nFold;
const char *pEnd = &aFold[nFold-6];
UNUSED_PARAM(iUnused);
/* Each iteration of this loop gobbles up a contiguous run of separators,
** then the next token. */
while( rc==SQLITE_OK ){
u32 iCode; /* non-ASCII codepoint read from input */
char *zOut = aFold;
int is;
int ie;
/* Skip any separator characters. */
while( 1 ){
if( zCsr>=zTerm ) goto tokenize_done;
if( *zCsr & 0x80 ) {
/* A character outside of the ascii range. Skip past it if it is
** a separator character. Or break out of the loop if it is not. */
is = zCsr - (unsigned char*)pText;
READ_UTF8(zCsr, zTerm, iCode);
if( fts5UnicodeIsAlnum(p, iCode) ){
goto non_ascii_tokenchar;
}
}else{
if( a[*zCsr] ){
is = zCsr - (unsigned char*)pText;
goto ascii_tokenchar;
}
zCsr++;
}
}
/* Run through the tokenchars. Fold them into the output buffer along
** the way. */
while( zCsr<zTerm ){
/* Grow the output buffer so that there is sufficient space to fit the
** largest possible utf-8 character. */
if( zOut>pEnd ){
aFold = sqlite3_malloc64((sqlite3_int64)nFold*2);
if( aFold==0 ){
rc = SQLITE_NOMEM;
goto tokenize_done;
}
zOut = &aFold[zOut - p->aFold];
memcpy(aFold, p->aFold, nFold);
sqlite3_free(p->aFold);
p->aFold = aFold;
p->nFold = nFold = nFold*2;
pEnd = &aFold[nFold-6];
}
if( *zCsr & 0x80 ){
/* An non-ascii-range character. Fold it into the output buffer if
** it is a token character, or break out of the loop if it is not. */
READ_UTF8(zCsr, zTerm, iCode);
if( fts5UnicodeIsAlnum(p,iCode)||sqlite3Fts5UnicodeIsdiacritic(iCode) ){
non_ascii_tokenchar:
iCode = sqlite3Fts5UnicodeFold(iCode, p->eRemoveDiacritic);
if( iCode ) WRITE_UTF8(zOut, iCode);
}else{
break;
}
}else if( a[*zCsr]==0 ){
/* An ascii-range separator character. End of token. */
break;
}else{
ascii_tokenchar:
if( *zCsr>='A' && *zCsr<='Z' ){
*zOut++ = *zCsr + 32;
}else{
*zOut++ = *zCsr;
}
zCsr++;
}
ie = zCsr - (unsigned char*)pText;
}
/* Invoke the token callback */
rc = xToken(pCtx, 0, aFold, zOut-aFold, is, ie);
}
tokenize_done:
if( rc==SQLITE_DONE ) rc = SQLITE_OK;
return rc;
}
/**************************************************************************
** Start of porter stemmer implementation.
*/
/* Any tokens larger than this (in bytes) are passed through without
** stemming. */
#define FTS5_PORTER_MAX_TOKEN 64
typedef struct PorterTokenizer PorterTokenizer;
struct PorterTokenizer {
fts5_tokenizer tokenizer; /* Parent tokenizer module */
Fts5Tokenizer *pTokenizer; /* Parent tokenizer instance */
char aBuf[FTS5_PORTER_MAX_TOKEN + 64];
};
/*
** Delete a "porter" tokenizer.
*/
static void fts5PorterDelete(Fts5Tokenizer *pTok){
if( pTok ){
PorterTokenizer *p = (PorterTokenizer*)pTok;
if( p->pTokenizer ){
p->tokenizer.xDelete(p->pTokenizer);
}
sqlite3_free(p);
}
}
/*
** Create a "porter" tokenizer.
*/
static int fts5PorterCreate(
void *pCtx,
const char **azArg, int nArg,
Fts5Tokenizer **ppOut
){
fts5_api *pApi = (fts5_api*)pCtx;
int rc = SQLITE_OK;
PorterTokenizer *pRet;
void *pUserdata = 0;
const char *zBase = "unicode61";
if( nArg>0 ){
zBase = azArg[0];
}
pRet = (PorterTokenizer*)sqlite3_malloc(sizeof(PorterTokenizer));
if( pRet ){
memset(pRet, 0, sizeof(PorterTokenizer));
rc = pApi->xFindTokenizer(pApi, zBase, &pUserdata, &pRet->tokenizer);
}else{
rc = SQLITE_NOMEM;
}
if( rc==SQLITE_OK ){
int nArg2 = (nArg>0 ? nArg-1 : 0);
const char **azArg2 = (nArg2 ? &azArg[1] : 0);
rc = pRet->tokenizer.xCreate(pUserdata, azArg2, nArg2, &pRet->pTokenizer);
}
if( rc!=SQLITE_OK ){
fts5PorterDelete((Fts5Tokenizer*)pRet);
pRet = 0;
}
*ppOut = (Fts5Tokenizer*)pRet;
return rc;
}
typedef struct PorterContext PorterContext;
struct PorterContext {
void *pCtx;
int (*xToken)(void*, int, const char*, int, int, int);
char *aBuf;
};
typedef struct PorterRule PorterRule;
struct PorterRule {
const char *zSuffix;
int nSuffix;
int (*xCond)(char *zStem, int nStem);
const char *zOutput;
int nOutput;
};
#if 0
static int fts5PorterApply(char *aBuf, int *pnBuf, PorterRule *aRule){
int ret = -1;
int nBuf = *pnBuf;
PorterRule *p;
for(p=aRule; p->zSuffix; p++){
assert( strlen(p->zSuffix)==p->nSuffix );
assert( strlen(p->zOutput)==p->nOutput );
if( nBuf<p->nSuffix ) continue;
if( 0==memcmp(&aBuf[nBuf - p->nSuffix], p->zSuffix, p->nSuffix) ) break;
}
if( p->zSuffix ){
int nStem = nBuf - p->nSuffix;
if( p->xCond==0 || p->xCond(aBuf, nStem) ){
memcpy(&aBuf[nStem], p->zOutput, p->nOutput);
*pnBuf = nStem + p->nOutput;
ret = p - aRule;
}
}
return ret;
}
#endif
static int fts5PorterIsVowel(char c, int bYIsVowel){
return (
c=='a' || c=='e' || c=='i' || c=='o' || c=='u' || (bYIsVowel && c=='y')
);
}
static int fts5PorterGobbleVC(char *zStem, int nStem, int bPrevCons){
int i;
int bCons = bPrevCons;
/* Scan for a vowel */
for(i=0; i<nStem; i++){
if( 0==(bCons = !fts5PorterIsVowel(zStem[i], bCons)) ) break;
}
/* Scan for a consonent */
for(i++; i<nStem; i++){
if( (bCons = !fts5PorterIsVowel(zStem[i], bCons)) ) return i+1;
}
return 0;
}
/* porter rule condition: (m > 0) */
static int fts5Porter_MGt0(char *zStem, int nStem){
return !!fts5PorterGobbleVC(zStem, nStem, 0);
}
/* porter rule condition: (m > 1) */
static int fts5Porter_MGt1(char *zStem, int nStem){
int n;
n = fts5PorterGobbleVC(zStem, nStem, 0);
if( n && fts5PorterGobbleVC(&zStem[n], nStem-n, 1) ){
return 1;
}
return 0;
}
/* porter rule condition: (m = 1) */
static int fts5Porter_MEq1(char *zStem, int nStem){
int n;
n = fts5PorterGobbleVC(zStem, nStem, 0);
if( n && 0==fts5PorterGobbleVC(&zStem[n], nStem-n, 1) ){
return 1;
}
return 0;
}
/* porter rule condition: (*o) */
static int fts5Porter_Ostar(char *zStem, int nStem){
if( zStem[nStem-1]=='w' || zStem[nStem-1]=='x' || zStem[nStem-1]=='y' ){
return 0;
}else{
int i;
int mask = 0;
int bCons = 0;
for(i=0; i<nStem; i++){
bCons = !fts5PorterIsVowel(zStem[i], bCons);
assert( bCons==0 || bCons==1 );
mask = (mask << 1) + bCons;
}
return ((mask & 0x0007)==0x0005);
}
}
/* porter rule condition: (m > 1 and (*S or *T)) */
static int fts5Porter_MGt1_and_S_or_T(char *zStem, int nStem){
assert( nStem>0 );
return (zStem[nStem-1]=='s' || zStem[nStem-1]=='t')
&& fts5Porter_MGt1(zStem, nStem);
}
/* porter rule condition: (*v*) */
static int fts5Porter_Vowel(char *zStem, int nStem){
int i;
for(i=0; i<nStem; i++){
if( fts5PorterIsVowel(zStem[i], i>0) ){
return 1;
}
}
return 0;
}
/**************************************************************************
***************************************************************************
** GENERATED CODE STARTS HERE (mkportersteps.tcl)
*/
static int fts5PorterStep4(char *aBuf, int *pnBuf){
int ret = 0;
int nBuf = *pnBuf;
switch( aBuf[nBuf-2] ){
case 'a':
if( nBuf>2 && 0==memcmp("al", &aBuf[nBuf-2], 2) ){
if( fts5Porter_MGt1(aBuf, nBuf-2) ){
*pnBuf = nBuf - 2;
}
}
break;
case 'c':
if( nBuf>4 && 0==memcmp("ance", &aBuf[nBuf-4], 4) ){
if( fts5Porter_MGt1(aBuf, nBuf-4) ){
*pnBuf = nBuf - 4;
}
}else if( nBuf>4 && 0==memcmp("ence", &aBuf[nBuf-4], 4) ){
if( fts5Porter_MGt1(aBuf, nBuf-4) ){
*pnBuf = nBuf - 4;
}
}
break;
case 'e':
if( nBuf>2 && 0==memcmp("er", &aBuf[nBuf-2], 2) ){
if( fts5Porter_MGt1(aBuf, nBuf-2) ){
*pnBuf = nBuf - 2;
}
}
break;
case 'i':
if( nBuf>2 && 0==memcmp("ic", &aBuf[nBuf-2], 2) ){
if( fts5Porter_MGt1(aBuf, nBuf-2) ){
*pnBuf = nBuf - 2;
}
}
break;
case 'l':
if( nBuf>4 && 0==memcmp("able", &aBuf[nBuf-4], 4) ){
if( fts5Porter_MGt1(aBuf, nBuf-4) ){
*pnBuf = nBuf - 4;
}
}else if( nBuf>4 && 0==memcmp("ible", &aBuf[nBuf-4], 4) ){
if( fts5Porter_MGt1(aBuf, nBuf-4) ){
*pnBuf = nBuf - 4;
}
}
break;
case 'n':
if( nBuf>3 && 0==memcmp("ant", &aBuf[nBuf-3], 3) ){
if( fts5Porter_MGt1(aBuf, nBuf-3) ){
*pnBuf = nBuf - 3;
}
}else if( nBuf>5 && 0==memcmp("ement", &aBuf[nBuf-5], 5) ){
if( fts5Porter_MGt1(aBuf, nBuf-5) ){
*pnBuf = nBuf - 5;
}
}else if( nBuf>4 && 0==memcmp("ment", &aBuf[nBuf-4], 4) ){
if( fts5Porter_MGt1(aBuf, nBuf-4) ){
*pnBuf = nBuf - 4;
}
}else if( nBuf>3 && 0==memcmp("ent", &aBuf[nBuf-3], 3) ){
if( fts5Porter_MGt1(aBuf, nBuf-3) ){
*pnBuf = nBuf - 3;
}
}
break;
case 'o':
if( nBuf>3 && 0==memcmp("ion", &aBuf[nBuf-3], 3) ){
if( fts5Porter_MGt1_and_S_or_T(aBuf, nBuf-3) ){
*pnBuf = nBuf - 3;
}
}else if( nBuf>2 && 0==memcmp("ou", &aBuf[nBuf-2], 2) ){
if( fts5Porter_MGt1(aBuf, nBuf-2) ){
*pnBuf = nBuf - 2;
}
}
break;
case 's':
if( nBuf>3 && 0==memcmp("ism", &aBuf[nBuf-3], 3) ){
if( fts5Porter_MGt1(aBuf, nBuf-3) ){
*pnBuf = nBuf - 3;
}
}
break;
case 't':
if( nBuf>3 && 0==memcmp("ate", &aBuf[nBuf-3], 3) ){
if( fts5Porter_MGt1(aBuf, nBuf-3) ){
*pnBuf = nBuf - 3;
}
}else if( nBuf>3 && 0==memcmp("iti", &aBuf[nBuf-3], 3) ){
if( fts5Porter_MGt1(aBuf, nBuf-3) ){
*pnBuf = nBuf - 3;
}
}
break;
case 'u':
if( nBuf>3 && 0==memcmp("ous", &aBuf[nBuf-3], 3) ){
if( fts5Porter_MGt1(aBuf, nBuf-3) ){
*pnBuf = nBuf - 3;
}
}
break;
case 'v':
if( nBuf>3 && 0==memcmp("ive", &aBuf[nBuf-3], 3) ){
if( fts5Porter_MGt1(aBuf, nBuf-3) ){
*pnBuf = nBuf - 3;
}
}
break;
case 'z':
if( nBuf>3 && 0==memcmp("ize", &aBuf[nBuf-3], 3) ){
if( fts5Porter_MGt1(aBuf, nBuf-3) ){
*pnBuf = nBuf - 3;
}
}
break;
}
return ret;
}
static int fts5PorterStep1B2(char *aBuf, int *pnBuf){
int ret = 0;
int nBuf = *pnBuf;
switch( aBuf[nBuf-2] ){
case 'a':
if( nBuf>2 && 0==memcmp("at", &aBuf[nBuf-2], 2) ){
memcpy(&aBuf[nBuf-2], "ate", 3);
*pnBuf = nBuf - 2 + 3;
ret = 1;
}
break;
case 'b':
if( nBuf>2 && 0==memcmp("bl", &aBuf[nBuf-2], 2) ){
memcpy(&aBuf[nBuf-2], "ble", 3);
*pnBuf = nBuf - 2 + 3;
ret = 1;
}
break;
case 'i':
if( nBuf>2 && 0==memcmp("iz", &aBuf[nBuf-2], 2) ){
memcpy(&aBuf[nBuf-2], "ize", 3);
*pnBuf = nBuf - 2 + 3;
ret = 1;
}
break;
}
return ret;
}
static int fts5PorterStep2(char *aBuf, int *pnBuf){
int ret = 0;
int nBuf = *pnBuf;
switch( aBuf[nBuf-2] ){
case 'a':
if( nBuf>7 && 0==memcmp("ational", &aBuf[nBuf-7], 7) ){
if( fts5Porter_MGt0(aBuf, nBuf-7) ){
memcpy(&aBuf[nBuf-7], "ate", 3);
*pnBuf = nBuf - 7 + 3;
}
}else if( nBuf>6 && 0==memcmp("tional", &aBuf[nBuf-6], 6) ){
if( fts5Porter_MGt0(aBuf, nBuf-6) ){
memcpy(&aBuf[nBuf-6], "tion", 4);
*pnBuf = nBuf - 6 + 4;
}
}
break;
case 'c':
if( nBuf>4 && 0==memcmp("enci", &aBuf[nBuf-4], 4) ){
if( fts5Porter_MGt0(aBuf, nBuf-4) ){
memcpy(&aBuf[nBuf-4], "ence", 4);
*pnBuf = nBuf - 4 + 4;
}
}else if( nBuf>4 && 0==memcmp("anci", &aBuf[nBuf-4], 4) ){
if( fts5Porter_MGt0(aBuf, nBuf-4) ){
memcpy(&aBuf[nBuf-4], "ance", 4);
*pnBuf = nBuf - 4 + 4;
}
}
break;
case 'e':
if( nBuf>4 && 0==memcmp("izer", &aBuf[nBuf-4], 4) ){
if( fts5Porter_MGt0(aBuf, nBuf-4) ){
memcpy(&aBuf[nBuf-4], "ize", 3);
*pnBuf = nBuf - 4 + 3;
}
}
break;
case 'g':
if( nBuf>4 && 0==memcmp("logi", &aBuf[nBuf-4], 4) ){
if( fts5Porter_MGt0(aBuf, nBuf-4) ){
memcpy(&aBuf[nBuf-4], "log", 3);
*pnBuf = nBuf - 4 + 3;
}
}
break;
case 'l':
if( nBuf>3 && 0==memcmp("bli", &aBuf[nBuf-3], 3) ){
if( fts5Porter_MGt0(aBuf, nBuf-3) ){
memcpy(&aBuf[nBuf-3], "ble", 3);
*pnBuf = nBuf - 3 + 3;
}
}else if( nBuf>4 && 0==memcmp("alli", &aBuf[nBuf-4], 4) ){
if( fts5Porter_MGt0(aBuf, nBuf-4) ){
memcpy(&aBuf[nBuf-4], "al", 2);
*pnBuf = nBuf - 4 + 2;
}
}else if( nBuf>5 && 0==memcmp("entli", &aBuf[nBuf-5], 5) ){
if( fts5Porter_MGt0(aBuf, nBuf-5) ){
memcpy(&aBuf[nBuf-5], "ent", 3);
*pnBuf = nBuf - 5 + 3;
}
}else if( nBuf>3 && 0==memcmp("eli", &aBuf[nBuf-3], 3) ){
if( fts5Porter_MGt0(aBuf, nBuf-3) ){
memcpy(&aBuf[nBuf-3], "e", 1);
*pnBuf = nBuf - 3 + 1;
}
}else if( nBuf>5 && 0==memcmp("ousli", &aBuf[nBuf-5], 5) ){
if( fts5Porter_MGt0(aBuf, nBuf-5) ){
memcpy(&aBuf[nBuf-5], "ous", 3);
*pnBuf = nBuf - 5 + 3;
}
}
break;
case 'o':
if( nBuf>7 && 0==memcmp("ization", &aBuf[nBuf-7], 7) ){
if( fts5Porter_MGt0(aBuf, nBuf-7) ){
memcpy(&aBuf[nBuf-7], "ize", 3);
*pnBuf = nBuf - 7 + 3;
}
}else if( nBuf>5 && 0==memcmp("ation", &aBuf[nBuf-5], 5) ){
if( fts5Porter_MGt0(aBuf, nBuf-5) ){
memcpy(&aBuf[nBuf-5], "ate", 3);
*pnBuf = nBuf - 5 + 3;
}
}else if( nBuf>4 && 0==memcmp("ator", &aBuf[nBuf-4], 4) ){
if( fts5Porter_MGt0(aBuf, nBuf-4) ){
memcpy(&aBuf[nBuf-4], "ate", 3);
*pnBuf = nBuf - 4 + 3;
}
}
break;
case 's':
if( nBuf>5 && 0==memcmp("alism", &aBuf[nBuf-5], 5) ){
if( fts5Porter_MGt0(aBuf, nBuf-5) ){
memcpy(&aBuf[nBuf-5], "al", 2);
*pnBuf = nBuf - 5 + 2;
}
}else if( nBuf>7 && 0==memcmp("iveness", &aBuf[nBuf-7], 7) ){
if( fts5Porter_MGt0(aBuf, nBuf-7) ){
memcpy(&aBuf[nBuf-7], "ive", 3);
*pnBuf = nBuf - 7 + 3;
}
}else if( nBuf>7 && 0==memcmp("fulness", &aBuf[nBuf-7], 7) ){
if( fts5Porter_MGt0(aBuf, nBuf-7) ){
memcpy(&aBuf[nBuf-7], "ful", 3);
*pnBuf = nBuf - 7 + 3;
}
}else if( nBuf>7 && 0==memcmp("ousness", &aBuf[nBuf-7], 7) ){
if( fts5Porter_MGt0(aBuf, nBuf-7) ){
memcpy(&aBuf[nBuf-7], "ous", 3);
*pnBuf = nBuf - 7 + 3;
}
}
break;
case 't':
if( nBuf>5 && 0==memcmp("aliti", &aBuf[nBuf-5], 5) ){
if( fts5Porter_MGt0(aBuf, nBuf-5) ){
memcpy(&aBuf[nBuf-5], "al", 2);
*pnBuf = nBuf - 5 + 2;
}
}else if( nBuf>5 && 0==memcmp("iviti", &aBuf[nBuf-5], 5) ){
if( fts5Porter_MGt0(aBuf, nBuf-5) ){
memcpy(&aBuf[nBuf-5], "ive", 3);
*pnBuf = nBuf - 5 + 3;
}
}else if( nBuf>6 && 0==memcmp("biliti", &aBuf[nBuf-6], 6) ){
if( fts5Porter_MGt0(aBuf, nBuf-6) ){
memcpy(&aBuf[nBuf-6], "ble", 3);
*pnBuf = nBuf - 6 + 3;
}
}
break;
}
return ret;
}
static int fts5PorterStep3(char *aBuf, int *pnBuf){
int ret = 0;
int nBuf = *pnBuf;
switch( aBuf[nBuf-2] ){
case 'a':
if( nBuf>4 && 0==memcmp("ical", &aBuf[nBuf-4], 4) ){
if( fts5Porter_MGt0(aBuf, nBuf-4) ){
memcpy(&aBuf[nBuf-4], "ic", 2);
*pnBuf = nBuf - 4 + 2;
}
}
break;
case 's':
if( nBuf>4 && 0==memcmp("ness", &aBuf[nBuf-4], 4) ){
if( fts5Porter_MGt0(aBuf, nBuf-4) ){
*pnBuf = nBuf - 4;
}
}
break;
case 't':
if( nBuf>5 && 0==memcmp("icate", &aBuf[nBuf-5], 5) ){
if( fts5Porter_MGt0(aBuf, nBuf-5) ){
memcpy(&aBuf[nBuf-5], "ic", 2);
*pnBuf = nBuf - 5 + 2;
}
}else if( nBuf>5 && 0==memcmp("iciti", &aBuf[nBuf-5], 5) ){
if( fts5Porter_MGt0(aBuf, nBuf-5) ){
memcpy(&aBuf[nBuf-5], "ic", 2);
*pnBuf = nBuf - 5 + 2;
}
}
break;
case 'u':
if( nBuf>3 && 0==memcmp("ful", &aBuf[nBuf-3], 3) ){
if( fts5Porter_MGt0(aBuf, nBuf-3) ){
*pnBuf = nBuf - 3;
}
}
break;
case 'v':
if( nBuf>5 && 0==memcmp("ative", &aBuf[nBuf-5], 5) ){
if( fts5Porter_MGt0(aBuf, nBuf-5) ){
*pnBuf = nBuf - 5;
}
}
break;
case 'z':
if( nBuf>5 && 0==memcmp("alize", &aBuf[nBuf-5], 5) ){
if( fts5Porter_MGt0(aBuf, nBuf-5) ){
memcpy(&aBuf[nBuf-5], "al", 2);
*pnBuf = nBuf - 5 + 2;
}
}
break;
}
return ret;
}
static int fts5PorterStep1B(char *aBuf, int *pnBuf){
int ret = 0;
int nBuf = *pnBuf;
switch( aBuf[nBuf-2] ){
case 'e':
if( nBuf>3 && 0==memcmp("eed", &aBuf[nBuf-3], 3) ){
if( fts5Porter_MGt0(aBuf, nBuf-3) ){
memcpy(&aBuf[nBuf-3], "ee", 2);
*pnBuf = nBuf - 3 + 2;
}
}else if( nBuf>2 && 0==memcmp("ed", &aBuf[nBuf-2], 2) ){
if( fts5Porter_Vowel(aBuf, nBuf-2) ){
*pnBuf = nBuf - 2;
ret = 1;
}
}
break;
case 'n':
if( nBuf>3 && 0==memcmp("ing", &aBuf[nBuf-3], 3) ){
if( fts5Porter_Vowel(aBuf, nBuf-3) ){
*pnBuf = nBuf - 3;
ret = 1;
}
}
break;
}
return ret;
}
/*
** GENERATED CODE ENDS HERE (mkportersteps.tcl)
***************************************************************************
**************************************************************************/
static void fts5PorterStep1A(char *aBuf, int *pnBuf){
int nBuf = *pnBuf;
if( aBuf[nBuf-1]=='s' ){
if( aBuf[nBuf-2]=='e' ){
if( (nBuf>4 && aBuf[nBuf-4]=='s' && aBuf[nBuf-3]=='s')
|| (nBuf>3 && aBuf[nBuf-3]=='i' )
){
*pnBuf = nBuf-2;
}else{
*pnBuf = nBuf-1;
}
}
else if( aBuf[nBuf-2]!='s' ){
*pnBuf = nBuf-1;
}
}
}
static int fts5PorterCb(
void *pCtx,
int tflags,
const char *pToken,
int nToken,
int iStart,
int iEnd
){
PorterContext *p = (PorterContext*)pCtx;
char *aBuf;
int nBuf;
if( nToken>FTS5_PORTER_MAX_TOKEN || nToken<3 ) goto pass_through;
aBuf = p->aBuf;
nBuf = nToken;
memcpy(aBuf, pToken, nBuf);
/* Step 1. */
fts5PorterStep1A(aBuf, &nBuf);
if( fts5PorterStep1B(aBuf, &nBuf) ){
if( fts5PorterStep1B2(aBuf, &nBuf)==0 ){
char c = aBuf[nBuf-1];
if( fts5PorterIsVowel(c, 0)==0
&& c!='l' && c!='s' && c!='z' && c==aBuf[nBuf-2]
){
nBuf--;
}else if( fts5Porter_MEq1(aBuf, nBuf) && fts5Porter_Ostar(aBuf, nBuf) ){
aBuf[nBuf++] = 'e';
}
}
}
/* Step 1C. */
if( aBuf[nBuf-1]=='y' && fts5Porter_Vowel(aBuf, nBuf-1) ){
aBuf[nBuf-1] = 'i';
}
/* Steps 2 through 4. */
fts5PorterStep2(aBuf, &nBuf);
fts5PorterStep3(aBuf, &nBuf);
fts5PorterStep4(aBuf, &nBuf);
/* Step 5a. */
assert( nBuf>0 );
if( aBuf[nBuf-1]=='e' ){
if( fts5Porter_MGt1(aBuf, nBuf-1)
|| (fts5Porter_MEq1(aBuf, nBuf-1) && !fts5Porter_Ostar(aBuf, nBuf-1))
){
nBuf--;
}
}
/* Step 5b. */
if( nBuf>1 && aBuf[nBuf-1]=='l'
&& aBuf[nBuf-2]=='l' && fts5Porter_MGt1(aBuf, nBuf-1)
){
nBuf--;
}
return p->xToken(p->pCtx, tflags, aBuf, nBuf, iStart, iEnd);
pass_through:
return p->xToken(p->pCtx, tflags, pToken, nToken, iStart, iEnd);
}
/*
** Tokenize using the porter tokenizer.
*/
static int fts5PorterTokenize(
Fts5Tokenizer *pTokenizer,
void *pCtx,
int flags,
const char *pText, int nText,
int (*xToken)(void*, int, const char*, int nToken, int iStart, int iEnd)
){
PorterTokenizer *p = (PorterTokenizer*)pTokenizer;
PorterContext sCtx;
sCtx.xToken = xToken;
sCtx.pCtx = pCtx;
sCtx.aBuf = p->aBuf;
return p->tokenizer.xTokenize(
p->pTokenizer, (void*)&sCtx, flags, pText, nText, fts5PorterCb
);
}
/**************************************************************************
** Start of trigram implementation.
*/
typedef struct TrigramTokenizer TrigramTokenizer;
struct TrigramTokenizer {
int bFold; /* True to fold to lower-case */
};
/*
** Free a trigram tokenizer.
*/
static void fts5TriDelete(Fts5Tokenizer *p){
sqlite3_free(p);
}
/*
** Allocate a trigram tokenizer.
*/
static int fts5TriCreate(
void *pUnused,
const char **azArg,
int nArg,
Fts5Tokenizer **ppOut
){
int rc = SQLITE_OK;
TrigramTokenizer *pNew = (TrigramTokenizer*)sqlite3_malloc(sizeof(*pNew));
UNUSED_PARAM(pUnused);
if( pNew==0 ){
rc = SQLITE_NOMEM;
}else{
int i;
pNew->bFold = 1;
for(i=0; rc==SQLITE_OK && i<nArg; i+=2){
const char *zArg = azArg[i+1];
if( 0==sqlite3_stricmp(azArg[i], "case_sensitive") ){
if( (zArg[0]!='0' && zArg[0]!='1') || zArg[1] ){
rc = SQLITE_ERROR;
}else{
pNew->bFold = (zArg[0]=='0');
}
}else{
rc = SQLITE_ERROR;
}
}
if( rc!=SQLITE_OK ){
fts5TriDelete((Fts5Tokenizer*)pNew);
pNew = 0;
}
}
*ppOut = (Fts5Tokenizer*)pNew;
return rc;
}
/*
** Trigram tokenizer tokenize routine.
*/
static int fts5TriTokenize(
Fts5Tokenizer *pTok,
void *pCtx,
int unusedFlags,
const char *pText, int nText,
int (*xToken)(void*, int, const char*, int, int, int)
){
TrigramTokenizer *p = (TrigramTokenizer*)pTok;
int rc = SQLITE_OK;
char aBuf[32];
const unsigned char *zIn = (const unsigned char*)pText;
const unsigned char *zEof = &zIn[nText];
u32 iCode;
UNUSED_PARAM(unusedFlags);
while( 1 ){
char *zOut = aBuf;
int iStart = zIn - (const unsigned char*)pText;
const unsigned char *zNext;
READ_UTF8(zIn, zEof, iCode);
if( iCode==0 ) break;
zNext = zIn;
if( zIn<zEof ){
if( p->bFold ) iCode = sqlite3Fts5UnicodeFold(iCode, 0);
WRITE_UTF8(zOut, iCode);
READ_UTF8(zIn, zEof, iCode);
if( iCode==0 ) break;
}else{
break;
}
if( zIn<zEof ){
if( p->bFold ) iCode = sqlite3Fts5UnicodeFold(iCode, 0);
WRITE_UTF8(zOut, iCode);
READ_UTF8(zIn, zEof, iCode);
if( iCode==0 ) break;
if( p->bFold ) iCode = sqlite3Fts5UnicodeFold(iCode, 0);
WRITE_UTF8(zOut, iCode);
}else{
break;
}
rc = xToken(pCtx, 0, aBuf, zOut-aBuf, iStart, iStart + zOut-aBuf);
if( rc!=SQLITE_OK ) break;
zIn = zNext;
}
return rc;
}
/*
** Argument xCreate is a pointer to a constructor function for a tokenizer.
** pTok is a tokenizer previously created using the same method. This function
** returns one of FTS5_PATTERN_NONE, FTS5_PATTERN_LIKE or FTS5_PATTERN_GLOB
** indicating the style of pattern matching that the tokenizer can support.
** In practice, this is:
**
** "trigram" tokenizer, case_sensitive=1 - FTS5_PATTERN_GLOB
** "trigram" tokenizer, case_sensitive=0 (the default) - FTS5_PATTERN_LIKE
** all other tokenizers - FTS5_PATTERN_NONE
*/
static int sqlite3Fts5TokenizerPattern(
int (*xCreate)(void*, const char**, int, Fts5Tokenizer**),
Fts5Tokenizer *pTok
){
if( xCreate==fts5TriCreate ){
TrigramTokenizer *p = (TrigramTokenizer*)pTok;
return p->bFold ? FTS5_PATTERN_LIKE : FTS5_PATTERN_GLOB;
}
return FTS5_PATTERN_NONE;
}
/*
** Register all built-in tokenizers with FTS5.
*/
static int sqlite3Fts5TokenizerInit(fts5_api *pApi){
struct BuiltinTokenizer {
const char *zName;
fts5_tokenizer x;
} aBuiltin[] = {
{ "unicode61", {fts5UnicodeCreate, fts5UnicodeDelete, fts5UnicodeTokenize}},
{ "ascii", {fts5AsciiCreate, fts5AsciiDelete, fts5AsciiTokenize }},
{ "porter", {fts5PorterCreate, fts5PorterDelete, fts5PorterTokenize }},
{ "trigram", {fts5TriCreate, fts5TriDelete, fts5TriTokenize}},
};
int rc = SQLITE_OK; /* Return code */
int i; /* To iterate through builtin functions */
for(i=0; rc==SQLITE_OK && i<ArraySize(aBuiltin); i++){
rc = pApi->xCreateTokenizer(pApi,
aBuiltin[i].zName,
(void*)pApi,
&aBuiltin[i].x,
0
);
}
return rc;
}
#line 1 "fts5_unicode2.c"
/*
** 2012-05-25
**
** The author disclaims copyright to this source code. In place of
** a legal notice, here is a blessing:
**
** May you do good and not evil.
** May you find forgiveness for yourself and forgive others.
** May you share freely, never taking more than you give.
**
******************************************************************************
*/
/*
** DO NOT EDIT THIS MACHINE GENERATED FILE.
*/
#include "libc/assert.h"
/*
** If the argument is a codepoint corresponding to a lowercase letter
** in the ASCII range with a diacritic added, return the codepoint
** of the ASCII letter only. For example, if passed 235 - "LATIN
** SMALL LETTER E WITH DIAERESIS" - return 65 ("LATIN SMALL LETTER
** E"). The resuls of passing a codepoint that corresponds to an
** uppercase letter are undefined.
*/
static int fts5_remove_diacritic(int c, int bComplex){
unsigned short aDia[] = {
0, 1797, 1848, 1859, 1891, 1928, 1940, 1995,
2024, 2040, 2060, 2110, 2168, 2206, 2264, 2286,
2344, 2383, 2472, 2488, 2516, 2596, 2668, 2732,
2782, 2842, 2894, 2954, 2984, 3000, 3028, 3336,
3456, 3696, 3712, 3728, 3744, 3766, 3832, 3896,
3912, 3928, 3944, 3968, 4008, 4040, 4056, 4106,
4138, 4170, 4202, 4234, 4266, 4296, 4312, 4344,
4408, 4424, 4442, 4472, 4488, 4504, 6148, 6198,
6264, 6280, 6360, 6429, 6505, 6529, 61448, 61468,
61512, 61534, 61592, 61610, 61642, 61672, 61688, 61704,
61726, 61784, 61800, 61816, 61836, 61880, 61896, 61914,
61948, 61998, 62062, 62122, 62154, 62184, 62200, 62218,
62252, 62302, 62364, 62410, 62442, 62478, 62536, 62554,
62584, 62604, 62640, 62648, 62656, 62664, 62730, 62766,
62830, 62890, 62924, 62974, 63032, 63050, 63082, 63118,
63182, 63242, 63274, 63310, 63368, 63390,
};
#define HIBIT ((unsigned char)0x80)
unsigned char aChar[] = {
'\0', 'a', 'c', 'e', 'i', 'n',
'o', 'u', 'y', 'y', 'a', 'c',
'd', 'e', 'e', 'g', 'h', 'i',
'j', 'k', 'l', 'n', 'o', 'r',
's', 't', 'u', 'u', 'w', 'y',
'z', 'o', 'u', 'a', 'i', 'o',
'u', 'u'|HIBIT, 'a'|HIBIT, 'g', 'k', 'o',
'o'|HIBIT, 'j', 'g', 'n', 'a'|HIBIT, 'a',
'e', 'i', 'o', 'r', 'u', 's',
't', 'h', 'a', 'e', 'o'|HIBIT, 'o',
'o'|HIBIT, 'y', '\0', '\0', '\0', '\0',
'\0', '\0', '\0', '\0', 'a', 'b',
'c'|HIBIT, 'd', 'd', 'e'|HIBIT, 'e', 'e'|HIBIT,
'f', 'g', 'h', 'h', 'i', 'i'|HIBIT,
'k', 'l', 'l'|HIBIT, 'l', 'm', 'n',
'o'|HIBIT, 'p', 'r', 'r'|HIBIT, 'r', 's',
's'|HIBIT, 't', 'u', 'u'|HIBIT, 'v', 'w',
'w', 'x', 'y', 'z', 'h', 't',
'w', 'y', 'a', 'a'|HIBIT, 'a'|HIBIT, 'a'|HIBIT,
'e', 'e'|HIBIT, 'e'|HIBIT, 'i', 'o', 'o'|HIBIT,
'o'|HIBIT, 'o'|HIBIT, 'u', 'u'|HIBIT, 'u'|HIBIT, 'y',
};
unsigned int key = (((unsigned int)c)<<3) | 0x00000007;
int iRes = 0;
int iHi = sizeof(aDia)/sizeof(aDia[0]) - 1;
int iLo = 0;
while( iHi>=iLo ){
int iTest = (iHi + iLo) / 2;
if( key >= aDia[iTest] ){
iRes = iTest;
iLo = iTest+1;
}else{
iHi = iTest-1;
}
}
assert( key>=aDia[iRes] );
if( bComplex==0 && (aChar[iRes] & 0x80) ) return c;
return (c > (aDia[iRes]>>3) + (aDia[iRes]&0x07)) ? c : ((int)aChar[iRes] & 0x7F);
}
/*
** Return true if the argument interpreted as a unicode codepoint
** is a diacritical modifier character.
*/
static int sqlite3Fts5UnicodeIsdiacritic(int c){
unsigned int mask0 = 0x08029FDF;
unsigned int mask1 = 0x000361F8;
if( c<768 || c>817 ) return 0;
return (c < 768+32) ?
(mask0 & ((unsigned int)1 << (c-768))) :
(mask1 & ((unsigned int)1 << (c-768-32)));
}
/*
** Interpret the argument as a unicode codepoint. If the codepoint
** is an upper case character that has a lower case equivalent,
** return the codepoint corresponding to the lower case version.
** Otherwise, return a copy of the argument.
**
** The results are undefined if the value passed to this function
** is less than zero.
*/
static int sqlite3Fts5UnicodeFold(int c, int eRemoveDiacritic){
/* Each entry in the following array defines a rule for folding a range
** of codepoints to lower case. The rule applies to a range of nRange
** codepoints starting at codepoint iCode.
**
** If the least significant bit in flags is clear, then the rule applies
** to all nRange codepoints (i.e. all nRange codepoints are upper case and
** need to be folded). Or, if it is set, then the rule only applies to
** every second codepoint in the range, starting with codepoint C.
**
** The 7 most significant bits in flags are an index into the aiOff[]
** array. If a specific codepoint C does require folding, then its lower
** case equivalent is ((C + aiOff[flags>>1]) & 0xFFFF).
**
** The contents of this array are generated by parsing the CaseFolding.txt
** file distributed as part of the "Unicode Character Database". See
** http://www.unicode.org for details.
*/
static const struct TableEntry {
unsigned short iCode;
unsigned char flags;
unsigned char nRange;
} aEntry[] = {
{65, 14, 26}, {181, 64, 1}, {192, 14, 23},
{216, 14, 7}, {256, 1, 48}, {306, 1, 6},
{313, 1, 16}, {330, 1, 46}, {376, 116, 1},
{377, 1, 6}, {383, 104, 1}, {385, 50, 1},
{386, 1, 4}, {390, 44, 1}, {391, 0, 1},
{393, 42, 2}, {395, 0, 1}, {398, 32, 1},
{399, 38, 1}, {400, 40, 1}, {401, 0, 1},
{403, 42, 1}, {404, 46, 1}, {406, 52, 1},
{407, 48, 1}, {408, 0, 1}, {412, 52, 1},
{413, 54, 1}, {415, 56, 1}, {416, 1, 6},
{422, 60, 1}, {423, 0, 1}, {425, 60, 1},
{428, 0, 1}, {430, 60, 1}, {431, 0, 1},
{433, 58, 2}, {435, 1, 4}, {439, 62, 1},
{440, 0, 1}, {444, 0, 1}, {452, 2, 1},
{453, 0, 1}, {455, 2, 1}, {456, 0, 1},
{458, 2, 1}, {459, 1, 18}, {478, 1, 18},
{497, 2, 1}, {498, 1, 4}, {502, 122, 1},
{503, 134, 1}, {504, 1, 40}, {544, 110, 1},
{546, 1, 18}, {570, 70, 1}, {571, 0, 1},
{573, 108, 1}, {574, 68, 1}, {577, 0, 1},
{579, 106, 1}, {580, 28, 1}, {581, 30, 1},
{582, 1, 10}, {837, 36, 1}, {880, 1, 4},
{886, 0, 1}, {902, 18, 1}, {904, 16, 3},
{908, 26, 1}, {910, 24, 2}, {913, 14, 17},
{931, 14, 9}, {962, 0, 1}, {975, 4, 1},
{976, 140, 1}, {977, 142, 1}, {981, 146, 1},
{982, 144, 1}, {984, 1, 24}, {1008, 136, 1},
{1009, 138, 1}, {1012, 130, 1}, {1013, 128, 1},
{1015, 0, 1}, {1017, 152, 1}, {1018, 0, 1},
{1021, 110, 3}, {1024, 34, 16}, {1040, 14, 32},
{1120, 1, 34}, {1162, 1, 54}, {1216, 6, 1},
{1217, 1, 14}, {1232, 1, 88}, {1329, 22, 38},
{4256, 66, 38}, {4295, 66, 1}, {4301, 66, 1},
{7680, 1, 150}, {7835, 132, 1}, {7838, 96, 1},
{7840, 1, 96}, {7944, 150, 8}, {7960, 150, 6},
{7976, 150, 8}, {7992, 150, 8}, {8008, 150, 6},
{8025, 151, 8}, {8040, 150, 8}, {8072, 150, 8},
{8088, 150, 8}, {8104, 150, 8}, {8120, 150, 2},
{8122, 126, 2}, {8124, 148, 1}, {8126, 100, 1},
{8136, 124, 4}, {8140, 148, 1}, {8152, 150, 2},
{8154, 120, 2}, {8168, 150, 2}, {8170, 118, 2},
{8172, 152, 1}, {8184, 112, 2}, {8186, 114, 2},
{8188, 148, 1}, {8486, 98, 1}, {8490, 92, 1},
{8491, 94, 1}, {8498, 12, 1}, {8544, 8, 16},
{8579, 0, 1}, {9398, 10, 26}, {11264, 22, 47},
{11360, 0, 1}, {11362, 88, 1}, {11363, 102, 1},
{11364, 90, 1}, {11367, 1, 6}, {11373, 84, 1},
{11374, 86, 1}, {11375, 80, 1}, {11376, 82, 1},
{11378, 0, 1}, {11381, 0, 1}, {11390, 78, 2},
{11392, 1, 100}, {11499, 1, 4}, {11506, 0, 1},
{42560, 1, 46}, {42624, 1, 24}, {42786, 1, 14},
{42802, 1, 62}, {42873, 1, 4}, {42877, 76, 1},
{42878, 1, 10}, {42891, 0, 1}, {42893, 74, 1},
{42896, 1, 4}, {42912, 1, 10}, {42922, 72, 1},
{65313, 14, 26},
};
static const unsigned short aiOff[] = {
1, 2, 8, 15, 16, 26, 28, 32,
37, 38, 40, 48, 63, 64, 69, 71,
79, 80, 116, 202, 203, 205, 206, 207,
209, 210, 211, 213, 214, 217, 218, 219,
775, 7264, 10792, 10795, 23228, 23256, 30204, 54721,
54753, 54754, 54756, 54787, 54793, 54809, 57153, 57274,
57921, 58019, 58363, 61722, 65268, 65341, 65373, 65406,
65408, 65410, 65415, 65424, 65436, 65439, 65450, 65462,
65472, 65476, 65478, 65480, 65482, 65488, 65506, 65511,
65514, 65521, 65527, 65528, 65529,
};
int ret = c;
assert( sizeof(unsigned short)==2 && sizeof(unsigned char)==1 );
if( c<128 ){
if( c>='A' && c<='Z' ) ret = c + ('a' - 'A');
}else if( c<65536 ){
const struct TableEntry *p;
int iHi = sizeof(aEntry)/sizeof(aEntry[0]) - 1;
int iLo = 0;
int iRes = -1;
assert( c>aEntry[0].iCode );
while( iHi>=iLo ){
int iTest = (iHi + iLo) / 2;
int cmp = (c - aEntry[iTest].iCode);
if( cmp>=0 ){
iRes = iTest;
iLo = iTest+1;
}else{
iHi = iTest-1;
}
}
assert( iRes>=0 && c>=aEntry[iRes].iCode );
p = &aEntry[iRes];
if( c<(p->iCode + p->nRange) && 0==(0x01 & p->flags & (p->iCode ^ c)) ){
ret = (c + (aiOff[p->flags>>1])) & 0x0000FFFF;
assert( ret>0 );
}
if( eRemoveDiacritic ){
ret = fts5_remove_diacritic(ret, eRemoveDiacritic==2);
}
}
else if( c>=66560 && c<66600 ){
ret = c + 40;
}
return ret;
}
static int sqlite3Fts5UnicodeCatParse(const char *zCat, u8 *aArray){
aArray[0] = 1;
switch( zCat[0] ){
case 'C':
switch( zCat[1] ){
case 'c': aArray[1] = 1; break;
case 'f': aArray[2] = 1; break;
case 'n': aArray[3] = 1; break;
case 's': aArray[4] = 1; break;
case 'o': aArray[31] = 1; break;
case '*':
aArray[1] = 1;
aArray[2] = 1;
aArray[3] = 1;
aArray[4] = 1;
aArray[31] = 1;
break;
default: return 1; }
break;
case 'L':
switch( zCat[1] ){
case 'l': aArray[5] = 1; break;
case 'm': aArray[6] = 1; break;
case 'o': aArray[7] = 1; break;
case 't': aArray[8] = 1; break;
case 'u': aArray[9] = 1; break;
case 'C': aArray[30] = 1; break;
case '*':
aArray[5] = 1;
aArray[6] = 1;
aArray[7] = 1;
aArray[8] = 1;
aArray[9] = 1;
aArray[30] = 1;
break;
default: return 1; }
break;
case 'M':
switch( zCat[1] ){
case 'c': aArray[10] = 1; break;
case 'e': aArray[11] = 1; break;
case 'n': aArray[12] = 1; break;
case '*':
aArray[10] = 1;
aArray[11] = 1;
aArray[12] = 1;
break;
default: return 1; }
break;
case 'N':
switch( zCat[1] ){
case 'd': aArray[13] = 1; break;
case 'l': aArray[14] = 1; break;
case 'o': aArray[15] = 1; break;
case '*':
aArray[13] = 1;
aArray[14] = 1;
aArray[15] = 1;
break;
default: return 1; }
break;
case 'P':
switch( zCat[1] ){
case 'c': aArray[16] = 1; break;
case 'd': aArray[17] = 1; break;
case 'e': aArray[18] = 1; break;
case 'f': aArray[19] = 1; break;
case 'i': aArray[20] = 1; break;
case 'o': aArray[21] = 1; break;
case 's': aArray[22] = 1; break;
case '*':
aArray[16] = 1;
aArray[17] = 1;
aArray[18] = 1;
aArray[19] = 1;
aArray[20] = 1;
aArray[21] = 1;
aArray[22] = 1;
break;
default: return 1; }
break;
case 'S':
switch( zCat[1] ){
case 'c': aArray[23] = 1; break;
case 'k': aArray[24] = 1; break;
case 'm': aArray[25] = 1; break;
case 'o': aArray[26] = 1; break;
case '*':
aArray[23] = 1;
aArray[24] = 1;
aArray[25] = 1;
aArray[26] = 1;
break;
default: return 1; }
break;
case 'Z':
switch( zCat[1] ){
case 'l': aArray[27] = 1; break;
case 'p': aArray[28] = 1; break;
case 's': aArray[29] = 1; break;
case '*':
aArray[27] = 1;
aArray[28] = 1;
aArray[29] = 1;
break;
default: return 1; }
break;
}
return 0;
}
static u16 aFts5UnicodeBlock[] = {
0, 1471, 1753, 1760, 1760, 1760, 1760, 1760, 1760, 1760,
1760, 1760, 1760, 1760, 1760, 1763, 1765,
};
static u16 aFts5UnicodeMap[] = {
0, 32, 33, 36, 37, 40, 41, 42, 43, 44,
45, 46, 48, 58, 60, 63, 65, 91, 92, 93,
94, 95, 96, 97, 123, 124, 125, 126, 127, 160,
161, 162, 166, 167, 168, 169, 170, 171, 172, 173,
174, 175, 176, 177, 178, 180, 181, 182, 184, 185,
186, 187, 188, 191, 192, 215, 216, 223, 247, 248,
256, 312, 313, 329, 330, 377, 383, 385, 387, 388,
391, 394, 396, 398, 402, 403, 405, 406, 409, 412,
414, 415, 417, 418, 423, 427, 428, 431, 434, 436,
437, 440, 442, 443, 444, 446, 448, 452, 453, 454,
455, 456, 457, 458, 459, 460, 461, 477, 478, 496,
497, 498, 499, 500, 503, 505, 506, 564, 570, 572,
573, 575, 577, 580, 583, 584, 592, 660, 661, 688,
706, 710, 722, 736, 741, 748, 749, 750, 751, 768,
880, 884, 885, 886, 890, 891, 894, 900, 902, 903,
904, 908, 910, 912, 913, 931, 940, 975, 977, 978,
981, 984, 1008, 1012, 1014, 1015, 1018, 1020, 1021, 1072,
1120, 1154, 1155, 1160, 1162, 1217, 1231, 1232, 1329, 1369,
1370, 1377, 1417, 1418, 1423, 1425, 1470, 1471, 1472, 1473,
1475, 1476, 1478, 1479, 1488, 1520, 1523, 1536, 1542, 1545,
1547, 1548, 1550, 1552, 1563, 1566, 1568, 1600, 1601, 1611,
1632, 1642, 1646, 1648, 1649, 1748, 1749, 1750, 1757, 1758,
1759, 1765, 1767, 1769, 1770, 1774, 1776, 1786, 1789, 1791,
1792, 1807, 1808, 1809, 1810, 1840, 1869, 1958, 1969, 1984,
1994, 2027, 2036, 2038, 2039, 2042, 2048, 2070, 2074, 2075,
2084, 2085, 2088, 2089, 2096, 2112, 2137, 2142, 2208, 2210,
2276, 2304, 2307, 2308, 2362, 2363, 2364, 2365, 2366, 2369,
2377, 2381, 2382, 2384, 2385, 2392, 2402, 2404, 2406, 2416,
2417, 2418, 2425, 2433, 2434, 2437, 2447, 2451, 2474, 2482,
2486, 2492, 2493, 2494, 2497, 2503, 2507, 2509, 2510, 2519,
2524, 2527, 2530, 2534, 2544, 2546, 2548, 2554, 2555, 2561,
2563, 2565, 2575, 2579, 2602, 2610, 2613, 2616, 2620, 2622,
2625, 2631, 2635, 2641, 2649, 2654, 2662, 2672, 2674, 2677,
2689, 2691, 2693, 2703, 2707, 2730, 2738, 2741, 2748, 2749,
2750, 2753, 2759, 2761, 2763, 2765, 2768, 2784, 2786, 2790,
2800, 2801, 2817, 2818, 2821, 2831, 2835, 2858, 2866, 2869,
2876, 2877, 2878, 2879, 2880, 2881, 2887, 2891, 2893, 2902,
2903, 2908, 2911, 2914, 2918, 2928, 2929, 2930, 2946, 2947,
2949, 2958, 2962, 2969, 2972, 2974, 2979, 2984, 2990, 3006,
3008, 3009, 3014, 3018, 3021, 3024, 3031, 3046, 3056, 3059,
3065, 3066, 3073, 3077, 3086, 3090, 3114, 3125, 3133, 3134,
3137, 3142, 3146, 3157, 3160, 3168, 3170, 3174, 3192, 3199,
3202, 3205, 3214, 3218, 3242, 3253, 3260, 3261, 3262, 3263,
3264, 3270, 3271, 3274, 3276, 3285, 3294, 3296, 3298, 3302,
3313, 3330, 3333, 3342, 3346, 3389, 3390, 3393, 3398, 3402,
3405, 3406, 3415, 3424, 3426, 3430, 3440, 3449, 3450, 3458,
3461, 3482, 3507, 3517, 3520, 3530, 3535, 3538, 3542, 3544,
3570, 3572, 3585, 3633, 3634, 3636, 3647, 3648, 3654, 3655,
3663, 3664, 3674, 3713, 3716, 3719, 3722, 3725, 3732, 3737,
3745, 3749, 3751, 3754, 3757, 3761, 3762, 3764, 3771, 3773,
3776, 3782, 3784, 3792, 3804, 3840, 3841, 3844, 3859, 3860,
3861, 3864, 3866, 3872, 3882, 3892, 3893, 3894, 3895, 3896,
3897, 3898, 3899, 3900, 3901, 3902, 3904, 3913, 3953, 3967,
3968, 3973, 3974, 3976, 3981, 3993, 4030, 4038, 4039, 4046,
4048, 4053, 4057, 4096, 4139, 4141, 4145, 4146, 4152, 4153,
4155, 4157, 4159, 4160, 4170, 4176, 4182, 4184, 4186, 4190,
4193, 4194, 4197, 4199, 4206, 4209, 4213, 4226, 4227, 4229,
4231, 4237, 4238, 4239, 4240, 4250, 4253, 4254, 4256, 4295,
4301, 4304, 4347, 4348, 4349, 4682, 4688, 4696, 4698, 4704,
4746, 4752, 4786, 4792, 4800, 4802, 4808, 4824, 4882, 4888,
4957, 4960, 4969, 4992, 5008, 5024, 5120, 5121, 5741, 5743,
5760, 5761, 5787, 5788, 5792, 5867, 5870, 5888, 5902, 5906,
5920, 5938, 5941, 5952, 5970, 5984, 5998, 6002, 6016, 6068,
6070, 6071, 6078, 6086, 6087, 6089, 6100, 6103, 6104, 6107,
6108, 6109, 6112, 6128, 6144, 6150, 6151, 6155, 6158, 6160,
6176, 6211, 6212, 6272, 6313, 6314, 6320, 6400, 6432, 6435,
6439, 6441, 6448, 6450, 6451, 6457, 6464, 6468, 6470, 6480,
6512, 6528, 6576, 6593, 6600, 6608, 6618, 6622, 6656, 6679,
6681, 6686, 6688, 6741, 6742, 6743, 6744, 6752, 6753, 6754,
6755, 6757, 6765, 6771, 6783, 6784, 6800, 6816, 6823, 6824,
6912, 6916, 6917, 6964, 6965, 6966, 6971, 6972, 6973, 6978,
6979, 6981, 6992, 7002, 7009, 7019, 7028, 7040, 7042, 7043,
7073, 7074, 7078, 7080, 7082, 7083, 7084, 7086, 7088, 7098,
7142, 7143, 7144, 7146, 7149, 7150, 7151, 7154, 7164, 7168,
7204, 7212, 7220, 7222, 7227, 7232, 7245, 7248, 7258, 7288,
7294, 7360, 7376, 7379, 7380, 7393, 7394, 7401, 7405, 7406,
7410, 7412, 7413, 7424, 7468, 7531, 7544, 7545, 7579, 7616,
7676, 7680, 7830, 7838, 7936, 7944, 7952, 7960, 7968, 7976,
7984, 7992, 8000, 8008, 8016, 8025, 8027, 8029, 8031, 8033,
8040, 8048, 8064, 8072, 8080, 8088, 8096, 8104, 8112, 8118,
8120, 8124, 8125, 8126, 8127, 8130, 8134, 8136, 8140, 8141,
8144, 8150, 8152, 8157, 8160, 8168, 8173, 8178, 8182, 8184,
8188, 8189, 8192, 8203, 8208, 8214, 8216, 8217, 8218, 8219,
8221, 8222, 8223, 8224, 8232, 8233, 8234, 8239, 8240, 8249,
8250, 8251, 8255, 8257, 8260, 8261, 8262, 8263, 8274, 8275,
8276, 8277, 8287, 8288, 8298, 8304, 8305, 8308, 8314, 8317,
8318, 8319, 8320, 8330, 8333, 8334, 8336, 8352, 8400, 8413,
8417, 8418, 8421, 8448, 8450, 8451, 8455, 8456, 8458, 8459,
8462, 8464, 8467, 8468, 8469, 8470, 8472, 8473, 8478, 8484,
8485, 8486, 8487, 8488, 8489, 8490, 8494, 8495, 8496, 8500,
8501, 8505, 8506, 8508, 8510, 8512, 8517, 8519, 8522, 8523,
8524, 8526, 8527, 8528, 8544, 8579, 8581, 8585, 8592, 8597,
8602, 8604, 8608, 8609, 8611, 8612, 8614, 8615, 8622, 8623,
8654, 8656, 8658, 8659, 8660, 8661, 8692, 8960, 8968, 8972,
8992, 8994, 9001, 9002, 9003, 9084, 9085, 9115, 9140, 9180,
9186, 9216, 9280, 9312, 9372, 9450, 9472, 9655, 9656, 9665,
9666, 9720, 9728, 9839, 9840, 9985, 10088, 10089, 10090, 10091,
10092, 10093, 10094, 10095, 10096, 10097, 10098, 10099, 10100, 10101,
10102, 10132, 10176, 10181, 10182, 10183, 10214, 10215, 10216, 10217,
10218, 10219, 10220, 10221, 10222, 10223, 10224, 10240, 10496, 10627,
10628, 10629, 10630, 10631, 10632, 10633, 10634, 10635, 10636, 10637,
10638, 10639, 10640, 10641, 10642, 10643, 10644, 10645, 10646, 10647,
10648, 10649, 10712, 10713, 10714, 10715, 10716, 10748, 10749, 10750,
11008, 11056, 11077, 11079, 11088, 11264, 11312, 11360, 11363, 11365,
11367, 11374, 11377, 11378, 11380, 11381, 11383, 11388, 11390, 11393,
11394, 11492, 11493, 11499, 11503, 11506, 11513, 11517, 11518, 11520,
11559, 11565, 11568, 11631, 11632, 11647, 11648, 11680, 11688, 11696,
11704, 11712, 11720, 11728, 11736, 11744, 11776, 11778, 11779, 11780,
11781, 11782, 11785, 11786, 11787, 11788, 11789, 11790, 11799, 11800,
11802, 11803, 11804, 11805, 11806, 11808, 11809, 11810, 11811, 11812,
11813, 11814, 11815, 11816, 11817, 11818, 11823, 11824, 11834, 11904,
11931, 12032, 12272, 12288, 12289, 12292, 12293, 12294, 12295, 12296,
12297, 12298, 12299, 12300, 12301, 12302, 12303, 12304, 12305, 12306,
12308, 12309, 12310, 12311, 12312, 12313, 12314, 12315, 12316, 12317,
12318, 12320, 12321, 12330, 12334, 12336, 12337, 12342, 12344, 12347,
12348, 12349, 12350, 12353, 12441, 12443, 12445, 12447, 12448, 12449,
12539, 12540, 12543, 12549, 12593, 12688, 12690, 12694, 12704, 12736,
12784, 12800, 12832, 12842, 12872, 12880, 12881, 12896, 12928, 12938,
12977, 12992, 13056, 13312, 19893, 19904, 19968, 40908, 40960, 40981,
40982, 42128, 42192, 42232, 42238, 42240, 42508, 42509, 42512, 42528,
42538, 42560, 42606, 42607, 42608, 42611, 42612, 42622, 42623, 42624,
42655, 42656, 42726, 42736, 42738, 42752, 42775, 42784, 42786, 42800,
42802, 42864, 42865, 42873, 42878, 42888, 42889, 42891, 42896, 42912,
43000, 43002, 43003, 43010, 43011, 43014, 43015, 43019, 43020, 43043,
43045, 43047, 43048, 43056, 43062, 43064, 43065, 43072, 43124, 43136,
43138, 43188, 43204, 43214, 43216, 43232, 43250, 43256, 43259, 43264,
43274, 43302, 43310, 43312, 43335, 43346, 43359, 43360, 43392, 43395,
43396, 43443, 43444, 43446, 43450, 43452, 43453, 43457, 43471, 43472,
43486, 43520, 43561, 43567, 43569, 43571, 43573, 43584, 43587, 43588,
43596, 43597, 43600, 43612, 43616, 43632, 43633, 43639, 43642, 43643,
43648, 43696, 43697, 43698, 43701, 43703, 43705, 43710, 43712, 43713,
43714, 43739, 43741, 43742, 43744, 43755, 43756, 43758, 43760, 43762,
43763, 43765, 43766, 43777, 43785, 43793, 43808, 43816, 43968, 44003,
44005, 44006, 44008, 44009, 44011, 44012, 44013, 44016, 44032, 55203,
55216, 55243, 55296, 56191, 56319, 57343, 57344, 63743, 63744, 64112,
64256, 64275, 64285, 64286, 64287, 64297, 64298, 64312, 64318, 64320,
64323, 64326, 64434, 64467, 64830, 64831, 64848, 64914, 65008, 65020,
65021, 65024, 65040, 65047, 65048, 65049, 65056, 65072, 65073, 65075,
65077, 65078, 65079, 65080, 65081, 65082, 65083, 65084, 65085, 65086,
65087, 65088, 65089, 65090, 65091, 65092, 65093, 65095, 65096, 65097,
65101, 65104, 65108, 65112, 65113, 65114, 65115, 65116, 65117, 65118,
65119, 65122, 65123, 65124, 65128, 65129, 65130, 65136, 65142, 65279,
65281, 65284, 65285, 65288, 65289, 65290, 65291, 65292, 65293, 65294,
65296, 65306, 65308, 65311, 65313, 65339, 65340, 65341, 65342, 65343,
65344, 65345, 65371, 65372, 65373, 65374, 65375, 65376, 65377, 65378,
65379, 65380, 65382, 65392, 65393, 65438, 65440, 65474, 65482, 65490,
65498, 65504, 65506, 65507, 65508, 65509, 65512, 65513, 65517, 65529,
65532, 0, 13, 40, 60, 63, 80, 128, 256, 263,
311, 320, 373, 377, 394, 400, 464, 509, 640, 672,
768, 800, 816, 833, 834, 842, 896, 927, 928, 968,
976, 977, 1024, 1064, 1104, 1184, 2048, 2056, 2058, 2103,
2108, 2111, 2135, 2136, 2304, 2326, 2335, 2336, 2367, 2432,
2494, 2560, 2561, 2565, 2572, 2576, 2581, 2585, 2616, 2623,
2624, 2640, 2656, 2685, 2687, 2816, 2873, 2880, 2904, 2912,
2936, 3072, 3680, 4096, 4097, 4098, 4099, 4152, 4167, 4178,
4198, 4224, 4226, 4227, 4272, 4275, 4279, 4281, 4283, 4285,
4286, 4304, 4336, 4352, 4355, 4391, 4396, 4397, 4406, 4416,
4480, 4482, 4483, 4531, 4534, 4543, 4545, 4549, 4560, 5760,
5803, 5804, 5805, 5806, 5808, 5814, 5815, 5824, 8192, 9216,
9328, 12288, 26624, 28416, 28496, 28497, 28559, 28563, 45056, 53248,
53504, 53545, 53605, 53607, 53610, 53613, 53619, 53627, 53635, 53637,
53644, 53674, 53678, 53760, 53826, 53829, 54016, 54112, 54272, 54298,
54324, 54350, 54358, 54376, 54402, 54428, 54430, 54434, 54437, 54441,
54446, 54454, 54459, 54461, 54469, 54480, 54506, 54532, 54535, 54541,
54550, 54558, 54584, 54587, 54592, 54598, 54602, 54610, 54636, 54662,
54688, 54714, 54740, 54766, 54792, 54818, 54844, 54870, 54896, 54922,
54952, 54977, 54978, 55003, 55004, 55010, 55035, 55036, 55061, 55062,
55068, 55093, 55094, 55119, 55120, 55126, 55151, 55152, 55177, 55178,
55184, 55209, 55210, 55235, 55236, 55242, 55246, 60928, 60933, 60961,
60964, 60967, 60969, 60980, 60985, 60987, 60994, 60999, 61001, 61003,
61005, 61009, 61012, 61015, 61017, 61019, 61021, 61023, 61025, 61028,
61031, 61036, 61044, 61049, 61054, 61056, 61067, 61089, 61093, 61099,
61168, 61440, 61488, 61600, 61617, 61633, 61649, 61696, 61712, 61744,
61808, 61926, 61968, 62016, 62032, 62208, 62256, 62263, 62336, 62368,
62406, 62432, 62464, 62528, 62530, 62713, 62720, 62784, 62800, 62971,
63045, 63104, 63232, 0, 42710, 42752, 46900, 46912, 47133, 63488,
1, 32, 256, 0, 65533,
};
static u16 aFts5UnicodeData[] = {
1025, 61, 117, 55, 117, 54, 50, 53, 57, 53,
49, 85, 333, 85, 121, 85, 841, 54, 53, 50,
56, 48, 56, 837, 54, 57, 50, 57, 1057, 61,
53, 151, 58, 53, 56, 58, 39, 52, 57, 34,
58, 56, 58, 57, 79, 56, 37, 85, 56, 47,
39, 51, 111, 53, 745, 57, 233, 773, 57, 261,
1822, 37, 542, 37, 1534, 222, 69, 73, 37, 126,
126, 73, 69, 137, 37, 73, 37, 105, 101, 73,
37, 73, 37, 190, 158, 37, 126, 126, 73, 37,
126, 94, 37, 39, 94, 69, 135, 41, 40, 37,
41, 40, 37, 41, 40, 37, 542, 37, 606, 37,
41, 40, 37, 126, 73, 37, 1886, 197, 73, 37,
73, 69, 126, 105, 37, 286, 2181, 39, 869, 582,
152, 390, 472, 166, 248, 38, 56, 38, 568, 3596,
158, 38, 56, 94, 38, 101, 53, 88, 41, 53,
105, 41, 73, 37, 553, 297, 1125, 94, 37, 105,
101, 798, 133, 94, 57, 126, 94, 37, 1641, 1541,
1118, 58, 172, 75, 1790, 478, 37, 2846, 1225, 38,
213, 1253, 53, 49, 55, 1452, 49, 44, 53, 76,
53, 76, 53, 44, 871, 103, 85, 162, 121, 85,
55, 85, 90, 364, 53, 85, 1031, 38, 327, 684,
333, 149, 71, 44, 3175, 53, 39, 236, 34, 58,
204, 70, 76, 58, 140, 71, 333, 103, 90, 39,
469, 34, 39, 44, 967, 876, 2855, 364, 39, 333,
1063, 300, 70, 58, 117, 38, 711, 140, 38, 300,
38, 108, 38, 172, 501, 807, 108, 53, 39, 359,
876, 108, 42, 1735, 44, 42, 44, 39, 106, 268,
138, 44, 74, 39, 236, 327, 76, 85, 333, 53,
38, 199, 231, 44, 74, 263, 71, 711, 231, 39,
135, 44, 39, 106, 140, 74, 74, 44, 39, 42,
71, 103, 76, 333, 71, 87, 207, 58, 55, 76,
42, 199, 71, 711, 231, 71, 71, 71, 44, 106,
76, 76, 108, 44, 135, 39, 333, 76, 103, 44,
76, 42, 295, 103, 711, 231, 71, 167, 44, 39,
106, 172, 76, 42, 74, 44, 39, 71, 76, 333,
53, 55, 44, 74, 263, 71, 711, 231, 71, 167,
44, 39, 42, 44, 42, 140, 74, 74, 44, 44,
42, 71, 103, 76, 333, 58, 39, 207, 44, 39,
199, 103, 135, 71, 39, 71, 71, 103, 391, 74,
44, 74, 106, 106, 44, 39, 42, 333, 111, 218,
55, 58, 106, 263, 103, 743, 327, 167, 39, 108,
138, 108, 140, 76, 71, 71, 76, 333, 239, 58,
74, 263, 103, 743, 327, 167, 44, 39, 42, 44,
170, 44, 74, 74, 76, 74, 39, 71, 76, 333,
71, 74, 263, 103, 1319, 39, 106, 140, 106, 106,
44, 39, 42, 71, 76, 333, 207, 58, 199, 74,
583, 775, 295, 39, 231, 44, 106, 108, 44, 266,
74, 53, 1543, 44, 71, 236, 55, 199, 38, 268,
53, 333, 85, 71, 39, 71, 39, 39, 135, 231,
103, 39, 39, 71, 135, 44, 71, 204, 76, 39,
167, 38, 204, 333, 135, 39, 122, 501, 58, 53,
122, 76, 218, 333, 335, 58, 44, 58, 44, 58,
44, 54, 50, 54, 50, 74, 263, 1159, 460, 42,
172, 53, 76, 167, 364, 1164, 282, 44, 218, 90,
181, 154, 85, 1383, 74, 140, 42, 204, 42, 76,
74, 76, 39, 333, 213, 199, 74, 76, 135, 108,
39, 106, 71, 234, 103, 140, 423, 44, 74, 76,
202, 44, 39, 42, 333, 106, 44, 90, 1225, 41,
41, 1383, 53, 38, 10631, 135, 231, 39, 135, 1319,
135, 1063, 135, 231, 39, 135, 487, 1831, 135, 2151,
108, 309, 655, 519, 346, 2727, 49, 19847, 85, 551,
61, 839, 54, 50, 2407, 117, 110, 423, 135, 108,
583, 108, 85, 583, 76, 423, 103, 76, 1671, 76,
42, 236, 266, 44, 74, 364, 117, 38, 117, 55,
39, 44, 333, 335, 213, 49, 149, 108, 61, 333,
1127, 38, 1671, 1319, 44, 39, 2247, 935, 108, 138,
76, 106, 74, 44, 202, 108, 58, 85, 333, 967,
167, 1415, 554, 231, 74, 333, 47, 1114, 743, 76,
106, 85, 1703, 42, 44, 42, 236, 44, 42, 44,
74, 268, 202, 332, 44, 333, 333, 245, 38, 213,
140, 42, 1511, 44, 42, 172, 42, 44, 170, 44,
74, 231, 333, 245, 346, 300, 314, 76, 42, 967,
42, 140, 74, 76, 42, 44, 74, 71, 333, 1415,
44, 42, 76, 106, 44, 42, 108, 74, 149, 1159,
266, 268, 74, 76, 181, 333, 103, 333, 967, 198,
85, 277, 108, 53, 428, 42, 236, 135, 44, 135,
74, 44, 71, 1413, 2022, 421, 38, 1093, 1190, 1260,
140, 4830, 261, 3166, 261, 265, 197, 201, 261, 265,
261, 265, 197, 201, 261, 41, 41, 41, 94, 229,
265, 453, 261, 264, 261, 264, 261, 264, 165, 69,
137, 40, 56, 37, 120, 101, 69, 137, 40, 120,
133, 69, 137, 120, 261, 169, 120, 101, 69, 137,
40, 88, 381, 162, 209, 85, 52, 51, 54, 84,
51, 54, 52, 277, 59, 60, 162, 61, 309, 52,
51, 149, 80, 117, 57, 54, 50, 373, 57, 53,
48, 341, 61, 162, 194, 47, 38, 207, 121, 54,
50, 38, 335, 121, 54, 50, 422, 855, 428, 139,
44, 107, 396, 90, 41, 154, 41, 90, 37, 105,
69, 105, 37, 58, 41, 90, 57, 169, 218, 41,
58, 41, 58, 41, 58, 137, 58, 37, 137, 37,
135, 37, 90, 69, 73, 185, 94, 101, 58, 57,
90, 37, 58, 527, 1134, 94, 142, 47, 185, 186,
89, 154, 57, 90, 57, 90, 57, 250, 57, 1018,
89, 90, 57, 58, 57, 1018, 8601, 282, 153, 666,
89, 250, 54, 50, 2618, 57, 986, 825, 1306, 217,
602, 1274, 378, 1935, 2522, 719, 5882, 57, 314, 57,
1754, 281, 3578, 57, 4634, 3322, 54, 50, 54, 50,
54, 50, 54, 50, 54, 50, 54, 50, 54, 50,
975, 1434, 185, 54, 50, 1017, 54, 50, 54, 50,
54, 50, 54, 50, 54, 50, 537, 8218, 4217, 54,
50, 54, 50, 54, 50, 54, 50, 54, 50, 54,
50, 54, 50, 54, 50, 54, 50, 54, 50, 54,
50, 2041, 54, 50, 54, 50, 1049, 54, 50, 8281,
1562, 697, 90, 217, 346, 1513, 1509, 126, 73, 69,
254, 105, 37, 94, 37, 94, 165, 70, 105, 37,
3166, 37, 218, 158, 108, 94, 149, 47, 85, 1221,
37, 37, 1799, 38, 53, 44, 743, 231, 231, 231,
231, 231, 231, 231, 231, 1036, 85, 52, 51, 52,
51, 117, 52, 51, 53, 52, 51, 309, 49, 85,
49, 53, 52, 51, 85, 52, 51, 54, 50, 54,
50, 54, 50, 54, 50, 181, 38, 341, 81, 858,
2874, 6874, 410, 61, 117, 58, 38, 39, 46, 54,
50, 54, 50, 54, 50, 54, 50, 54, 50, 90,
54, 50, 54, 50, 54, 50, 54, 50, 49, 54,
82, 58, 302, 140, 74, 49, 166, 90, 110, 38,
39, 53, 90, 2759, 76, 88, 70, 39, 49, 2887,
53, 102, 39, 1319, 3015, 90, 143, 346, 871, 1178,
519, 1018, 335, 986, 271, 58, 495, 1050, 335, 1274,
495, 2042, 8218, 39, 39, 2074, 39, 39, 679, 38,
36583, 1786, 1287, 198, 85, 8583, 38, 117, 519, 333,
71, 1502, 39, 44, 107, 53, 332, 53, 38, 798,
44, 2247, 334, 76, 213, 760, 294, 88, 478, 69,
2014, 38, 261, 190, 350, 38, 88, 158, 158, 382,
70, 37, 231, 44, 103, 44, 135, 44, 743, 74,
76, 42, 154, 207, 90, 55, 58, 1671, 149, 74,
1607, 522, 44, 85, 333, 588, 199, 117, 39, 333,
903, 268, 85, 743, 364, 74, 53, 935, 108, 42,
1511, 44, 74, 140, 74, 44, 138, 437, 38, 333,
85, 1319, 204, 74, 76, 74, 76, 103, 44, 263,
44, 42, 333, 149, 519, 38, 199, 122, 39, 42,
1543, 44, 39, 108, 71, 76, 167, 76, 39, 44,
39, 71, 38, 85, 359, 42, 76, 74, 85, 39,
70, 42, 44, 199, 199, 199, 231, 231, 1127, 74,
44, 74, 44, 74, 53, 42, 44, 333, 39, 39,
743, 1575, 36, 68, 68, 36, 63, 63, 11719, 3399,
229, 165, 39, 44, 327, 57, 423, 167, 39, 71,
71, 3463, 536, 11623, 54, 50, 2055, 1735, 391, 55,
58, 524, 245, 54, 50, 53, 236, 53, 81, 80,
54, 50, 54, 50, 54, 50, 54, 50, 54, 50,
54, 50, 54, 50, 54, 50, 85, 54, 50, 149,
112, 117, 149, 49, 54, 50, 54, 50, 54, 50,
117, 57, 49, 121, 53, 55, 85, 167, 4327, 34,
117, 55, 117, 54, 50, 53, 57, 53, 49, 85,
333, 85, 121, 85, 841, 54, 53, 50, 56, 48,
56, 837, 54, 57, 50, 57, 54, 50, 53, 54,
50, 85, 327, 38, 1447, 70, 999, 199, 199, 199,
103, 87, 57, 56, 58, 87, 58, 153, 90, 98,
90, 391, 839, 615, 71, 487, 455, 3943, 117, 1455,
314, 1710, 143, 570, 47, 410, 1466, 44, 935, 1575,
999, 143, 551, 46, 263, 46, 967, 53, 1159, 263,
53, 174, 1289, 1285, 2503, 333, 199, 39, 1415, 71,
39, 743, 53, 271, 711, 207, 53, 839, 53, 1799,
71, 39, 108, 76, 140, 135, 103, 871, 108, 44,
271, 309, 935, 79, 53, 1735, 245, 711, 271, 615,
271, 2343, 1007, 42, 44, 42, 1703, 492, 245, 655,
333, 76, 42, 1447, 106, 140, 74, 76, 85, 34,
149, 807, 333, 108, 1159, 172, 42, 268, 333, 149,
76, 42, 1543, 106, 300, 74, 135, 149, 333, 1383,
44, 42, 44, 74, 204, 42, 44, 333, 28135, 3182,
149, 34279, 18215, 2215, 39, 1482, 140, 422, 71, 7898,
1274, 1946, 74, 108, 122, 202, 258, 268, 90, 236,
986, 140, 1562, 2138, 108, 58, 2810, 591, 841, 837,
841, 229, 581, 841, 837, 41, 73, 41, 73, 137,
265, 133, 37, 229, 357, 841, 837, 73, 137, 265,
233, 837, 73, 137, 169, 41, 233, 837, 841, 837,
841, 837, 841, 837, 841, 837, 841, 837, 841, 901,
809, 57, 805, 57, 197, 809, 57, 805, 57, 197,
809, 57, 805, 57, 197, 809, 57, 805, 57, 197,
809, 57, 805, 57, 197, 94, 1613, 135, 871, 71,
39, 39, 327, 135, 39, 39, 39, 39, 39, 39,
103, 71, 39, 39, 39, 39, 39, 39, 71, 39,
135, 231, 135, 135, 39, 327, 551, 103, 167, 551,
89, 1434, 3226, 506, 474, 506, 506, 367, 1018, 1946,
1402, 954, 1402, 314, 90, 1082, 218, 2266, 666, 1210,
186, 570, 2042, 58, 5850, 154, 2010, 154, 794, 2266,
378, 2266, 3738, 39, 39, 39, 39, 39, 39, 17351,
34, 3074, 7692, 63, 63,
};
static int sqlite3Fts5UnicodeCategory(u32 iCode) {
int iRes = -1;
int iHi;
int iLo;
int ret;
u16 iKey;
if( iCode>=(1<<20) ){
return 0;
}
iLo = aFts5UnicodeBlock[(iCode>>16)];
iHi = aFts5UnicodeBlock[1+(iCode>>16)];
iKey = (iCode & 0xFFFF);
while( iHi>iLo ){
int iTest = (iHi + iLo) / 2;
assert( iTest>=iLo && iTest<iHi );
if( iKey>=aFts5UnicodeMap[iTest] ){
iRes = iTest;
iLo = iTest+1;
}else{
iHi = iTest;
}
}
if( iRes<0 ) return 0;
if( iKey>=(aFts5UnicodeMap[iRes]+(aFts5UnicodeData[iRes]>>5)) ) return 0;
ret = aFts5UnicodeData[iRes] & 0x1F;
if( ret!=30 ) return ret;
return ((iKey - aFts5UnicodeMap[iRes]) & 0x01) ? 5 : 9;
}
static void sqlite3Fts5UnicodeAscii(u8 *aArray, u8 *aAscii){
int i = 0;
int iTbl = 0;
while( i<128 ){
int bToken = aArray[ aFts5UnicodeData[iTbl] & 0x1F ];
int n = (aFts5UnicodeData[iTbl] >> 5) + i;
for(; i<128 && i<n; i++){
aAscii[i] = (u8)bToken;
}
iTbl++;
}
aAscii[0] = 0; /* 0x00 is never a token character */
}
#line 1 "fts5_varint.c"
/*
** 2015 May 30
**
** The author disclaims copyright to this source code. In place of
** a legal notice, here is a blessing:
**
** May you do good and not evil.
** May you find forgiveness for yourself and forgive others.
** May you share freely, never taking more than you give.
**
******************************************************************************
**
** Routines for varint serialization and deserialization.
*/
/* #include "third_party/sqlite3/fts5Int.h" */
/*
** This is a copy of the sqlite3GetVarint32() routine from the SQLite core.
** Except, this version does handle the single byte case that the core
** version depends on being handled before its function is called.
*/
static int sqlite3Fts5GetVarint32(const unsigned char *p, u32 *v){
u32 a,b;
/* The 1-byte case. Overwhelmingly the most common. */
a = *p;
/* a: p0 (unmasked) */
if (!(a&0x80))
{
/* Values between 0 and 127 */
*v = a;
return 1;
}
/* The 2-byte case */
p++;
b = *p;
/* b: p1 (unmasked) */
if (!(b&0x80))
{
/* Values between 128 and 16383 */
a &= 0x7f;
a = a<<7;
*v = a | b;
return 2;
}
/* The 3-byte case */
p++;
a = a<<14;
a |= *p;
/* a: p0<<14 | p2 (unmasked) */
if (!(a&0x80))
{
/* Values between 16384 and 2097151 */
a &= (0x7f<<14)|(0x7f);
b &= 0x7f;
b = b<<7;
*v = a | b;
return 3;
}
/* A 32-bit varint is used to store size information in btrees.
** Objects are rarely larger than 2MiB limit of a 3-byte varint.
** A 3-byte varint is sufficient, for example, to record the size
** of a 1048569-byte BLOB or string.
**
** We only unroll the first 1-, 2-, and 3- byte cases. The very
** rare larger cases can be handled by the slower 64-bit varint
** routine.
*/
{
u64 v64;
u8 n;
p -= 2;
n = sqlite3Fts5GetVarint(p, &v64);
*v = ((u32)v64) & 0x7FFFFFFF;
assert( n>3 && n<=9 );
return n;
}
}
/*
** Bitmasks used by sqlite3GetVarint(). These precomputed constants
** are defined here rather than simply putting the constant expressions
** inline in order to work around bugs in the RVT compiler.
**
** SLOT_2_0 A mask for (0x7f<<14) | 0x7f
**
** SLOT_4_2_0 A mask for (0x7f<<28) | SLOT_2_0
*/
#define SLOT_2_0 0x001fc07f
#define SLOT_4_2_0 0xf01fc07f
/*
** Read a 64-bit variable-length integer from memory starting at p[0].
** Return the number of bytes read. The value is stored in *v.
*/
static u8 sqlite3Fts5GetVarint(const unsigned char *p, u64 *v){
u32 a,b,s;
a = *p;
/* a: p0 (unmasked) */
if (!(a&0x80))
{
*v = a;
return 1;
}
p++;
b = *p;
/* b: p1 (unmasked) */
if (!(b&0x80))
{
a &= 0x7f;
a = a<<7;
a |= b;
*v = a;
return 2;
}
/* Verify that constants are precomputed correctly */
assert( SLOT_2_0 == ((0x7f<<14) | (0x7f)) );
assert( SLOT_4_2_0 == ((0xfU<<28) | (0x7f<<14) | (0x7f)) );
p++;
a = a<<14;
a |= *p;
/* a: p0<<14 | p2 (unmasked) */
if (!(a&0x80))
{
a &= SLOT_2_0;
b &= 0x7f;
b = b<<7;
a |= b;
*v = a;
return 3;
}
/* CSE1 from below */
a &= SLOT_2_0;
p++;
b = b<<14;
b |= *p;
/* b: p1<<14 | p3 (unmasked) */
if (!(b&0x80))
{
b &= SLOT_2_0;
/* moved CSE1 up */
/* a &= (0x7f<<14)|(0x7f); */
a = a<<7;
a |= b;
*v = a;
return 4;
}
/* a: p0<<14 | p2 (masked) */
/* b: p1<<14 | p3 (unmasked) */
/* 1:save off p0<<21 | p1<<14 | p2<<7 | p3 (masked) */
/* moved CSE1 up */
/* a &= (0x7f<<14)|(0x7f); */
b &= SLOT_2_0;
s = a;
/* s: p0<<14 | p2 (masked) */
p++;
a = a<<14;
a |= *p;
/* a: p0<<28 | p2<<14 | p4 (unmasked) */
if (!(a&0x80))
{
/* we can skip these cause they were (effectively) done above in calc'ing s */
/* a &= (0x7f<<28)|(0x7f<<14)|(0x7f); */
/* b &= (0x7f<<14)|(0x7f); */
b = b<<7;
a |= b;
s = s>>18;
*v = ((u64)s)<<32 | a;
return 5;
}
/* 2:save off p0<<21 | p1<<14 | p2<<7 | p3 (masked) */
s = s<<7;
s |= b;
/* s: p0<<21 | p1<<14 | p2<<7 | p3 (masked) */
p++;
b = b<<14;
b |= *p;
/* b: p1<<28 | p3<<14 | p5 (unmasked) */
if (!(b&0x80))
{
/* we can skip this cause it was (effectively) done above in calc'ing s */
/* b &= (0x7f<<28)|(0x7f<<14)|(0x7f); */
a &= SLOT_2_0;
a = a<<7;
a |= b;
s = s>>18;
*v = ((u64)s)<<32 | a;
return 6;
}
p++;
a = a<<14;
a |= *p;
/* a: p2<<28 | p4<<14 | p6 (unmasked) */
if (!(a&0x80))
{
a &= SLOT_4_2_0;
b &= SLOT_2_0;
b = b<<7;
a |= b;
s = s>>11;
*v = ((u64)s)<<32 | a;
return 7;
}
/* CSE2 from below */
a &= SLOT_2_0;
p++;
b = b<<14;
b |= *p;
/* b: p3<<28 | p5<<14 | p7 (unmasked) */
if (!(b&0x80))
{
b &= SLOT_4_2_0;
/* moved CSE2 up */
/* a &= (0x7f<<14)|(0x7f); */
a = a<<7;
a |= b;
s = s>>4;
*v = ((u64)s)<<32 | a;
return 8;
}
p++;
a = a<<15;
a |= *p;
/* a: p4<<29 | p6<<15 | p8 (unmasked) */
/* moved CSE2 up */
/* a &= (0x7f<<29)|(0x7f<<15)|(0xff); */
b &= SLOT_2_0;
b = b<<8;
a |= b;
s = s<<4;
b = p[-4];
b &= 0x7f;
b = b>>3;
s |= b;
*v = ((u64)s)<<32 | a;
return 9;
}
/*
** The variable-length integer encoding is as follows:
**
** KEY:
** A = 0xxxxxxx 7 bits of data and one flag bit
** B = 1xxxxxxx 7 bits of data and one flag bit
** C = xxxxxxxx 8 bits of data
**
** 7 bits - A
** 14 bits - BA
** 21 bits - BBA
** 28 bits - BBBA
** 35 bits - BBBBA
** 42 bits - BBBBBA
** 49 bits - BBBBBBA
** 56 bits - BBBBBBBA
** 64 bits - BBBBBBBBC
*/
#ifdef SQLITE_NOINLINE
# define FTS5_NOINLINE SQLITE_NOINLINE
#else
# define FTS5_NOINLINE
#endif
/*
** Write a 64-bit variable-length integer to memory starting at p[0].
** The length of data write will be between 1 and 9 bytes. The number
** of bytes written is returned.
**
** A variable-length integer consists of the lower 7 bits of each byte
** for all bytes that have the 8th bit set and one byte with the 8th
** bit clear. Except, if we get to the 9th byte, it stores the full
** 8 bits and is the last byte.
*/
static int FTS5_NOINLINE fts5PutVarint64(unsigned char *p, u64 v){
int i, j, n;
u8 buf[10];
if( v & (((u64)0xff000000)<<32) ){
p[8] = (u8)v;
v >>= 8;
for(i=7; i>=0; i--){
p[i] = (u8)((v & 0x7f) | 0x80);
v >>= 7;
}
return 9;
}
n = 0;
do{
buf[n++] = (u8)((v & 0x7f) | 0x80);
v >>= 7;
}while( v!=0 );
buf[0] &= 0x7f;
assert( n<=9 );
for(i=0, j=n-1; j>=0; j--, i++){
p[i] = buf[j];
}
return n;
}
static int sqlite3Fts5PutVarint(unsigned char *p, u64 v){
if( v<=0x7f ){
p[0] = v&0x7f;
return 1;
}
if( v<=0x3fff ){
p[0] = ((v>>7)&0x7f)|0x80;
p[1] = v&0x7f;
return 2;
}
return fts5PutVarint64(p,v);
}
static int sqlite3Fts5GetVarintLen(u32 iVal){
#if 0
if( iVal<(1 << 7 ) ) return 1;
#endif
assert( iVal>=(1 << 7) );
if( iVal<(1 << 14) ) return 2;
if( iVal<(1 << 21) ) return 3;
if( iVal<(1 << 28) ) return 4;
return 5;
}
#line 1 "fts5_vocab.c"
/*
** 2015 May 08
**
** The author disclaims copyright to this source code. In place of
** a legal notice, here is a blessing:
**
** May you do good and not evil.
** May you find forgiveness for yourself and forgive others.
** May you share freely, never taking more than you give.
**
******************************************************************************
**
** This is an SQLite virtual table module implementing direct access to an
** existing FTS5 index. The module may create several different types of
** tables:
**
** col:
** CREATE TABLE vocab(term, col, doc, cnt, PRIMARY KEY(term, col));
**
** One row for each term/column combination. The value of $doc is set to
** the number of fts5 rows that contain at least one instance of term
** $term within column $col. Field $cnt is set to the total number of
** instances of term $term in column $col (in any row of the fts5 table).
**
** row:
** CREATE TABLE vocab(term, doc, cnt, PRIMARY KEY(term));
**
** One row for each term in the database. The value of $doc is set to
** the number of fts5 rows that contain at least one instance of term
** $term. Field $cnt is set to the total number of instances of term
** $term in the database.
**
** instance:
** CREATE TABLE vocab(term, doc, col, offset, PRIMARY KEY(<all-fields>));
**
** One row for each term instance in the database.
*/
/* #include "third_party/sqlite3/fts5Int.h" */
typedef struct Fts5VocabTable Fts5VocabTable;
typedef struct Fts5VocabCursor Fts5VocabCursor;
struct Fts5VocabTable {
sqlite3_vtab base;
char *zFts5Tbl; /* Name of fts5 table */
char *zFts5Db; /* Db containing fts5 table */
sqlite3 *db; /* Database handle */
Fts5Global *pGlobal; /* FTS5 global object for this database */
int eType; /* FTS5_VOCAB_COL, ROW or INSTANCE */
unsigned bBusy; /* True if busy */
};
struct Fts5VocabCursor {
sqlite3_vtab_cursor base;
sqlite3_stmt *pStmt; /* Statement holding lock on pIndex */
Fts5Table *pFts5; /* Associated FTS5 table */
int bEof; /* True if this cursor is at EOF */
Fts5IndexIter *pIter; /* Term/rowid iterator object */
int nLeTerm; /* Size of zLeTerm in bytes */
char *zLeTerm; /* (term <= $zLeTerm) paramater, or NULL */
/* These are used by 'col' tables only */
int iCol;
i64 *aCnt;
i64 *aDoc;
/* Output values used by all tables. */
i64 rowid; /* This table's current rowid value */
Fts5Buffer term; /* Current value of 'term' column */
/* Output values Used by 'instance' tables only */
i64 iInstPos;
int iInstOff;
};
#define FTS5_VOCAB_COL 0
#define FTS5_VOCAB_ROW 1
#define FTS5_VOCAB_INSTANCE 2
#define FTS5_VOCAB_COL_SCHEMA "term, col, doc, cnt"
#define FTS5_VOCAB_ROW_SCHEMA "term, doc, cnt"
#define FTS5_VOCAB_INST_SCHEMA "term, doc, col, offset"
/*
** Bits for the mask used as the idxNum value by xBestIndex/xFilter.
*/
#define FTS5_VOCAB_TERM_EQ 0x01
#define FTS5_VOCAB_TERM_GE 0x02
#define FTS5_VOCAB_TERM_LE 0x04
/*
** Translate a string containing an fts5vocab table type to an
** FTS5_VOCAB_XXX constant. If successful, set *peType to the output
** value and return SQLITE_OK. Otherwise, set *pzErr to an error message
** and return SQLITE_ERROR.
*/
static int fts5VocabTableType(const char *zType, char **pzErr, int *peType){
int rc = SQLITE_OK;
char *zCopy = sqlite3Fts5Strndup(&rc, zType, -1);
if( rc==SQLITE_OK ){
sqlite3Fts5Dequote(zCopy);
if( sqlite3_stricmp(zCopy, "col")==0 ){
*peType = FTS5_VOCAB_COL;
}else
if( sqlite3_stricmp(zCopy, "row")==0 ){
*peType = FTS5_VOCAB_ROW;
}else
if( sqlite3_stricmp(zCopy, "instance")==0 ){
*peType = FTS5_VOCAB_INSTANCE;
}else
{
*pzErr = sqlite3_mprintf("fts5vocab: unknown table type: %Q", zCopy);
rc = SQLITE_ERROR;
}
sqlite3_free(zCopy);
}
return rc;
}
/*
** The xDisconnect() virtual table method.
*/
static int fts5VocabDisconnectMethod(sqlite3_vtab *pVtab){
Fts5VocabTable *pTab = (Fts5VocabTable*)pVtab;
sqlite3_free(pTab);
return SQLITE_OK;
}
/*
** The xDestroy() virtual table method.
*/
static int fts5VocabDestroyMethod(sqlite3_vtab *pVtab){
Fts5VocabTable *pTab = (Fts5VocabTable*)pVtab;
sqlite3_free(pTab);
return SQLITE_OK;
}
/*
** This function is the implementation of both the xConnect and xCreate
** methods of the FTS3 virtual table.
**
** The argv[] array contains the following:
**
** argv[0] -> module name ("fts5vocab")
** argv[1] -> database name
** argv[2] -> table name
**
** then:
**
** argv[3] -> name of fts5 table
** argv[4] -> type of fts5vocab table
**
** or, for tables in the TEMP schema only.
**
** argv[3] -> name of fts5 tables database
** argv[4] -> name of fts5 table
** argv[5] -> type of fts5vocab table
*/
static int fts5VocabInitVtab(
sqlite3 *db, /* The SQLite database connection */
void *pAux, /* Pointer to Fts5Global object */
int argc, /* Number of elements in argv array */
const char * const *argv, /* xCreate/xConnect argument array */
sqlite3_vtab **ppVTab, /* Write the resulting vtab structure here */
char **pzErr /* Write any error message here */
){
const char *azSchema[] = {
"CREATE TABlE vocab(" FTS5_VOCAB_COL_SCHEMA ")",
"CREATE TABlE vocab(" FTS5_VOCAB_ROW_SCHEMA ")",
"CREATE TABlE vocab(" FTS5_VOCAB_INST_SCHEMA ")"
};
Fts5VocabTable *pRet = 0;
int rc = SQLITE_OK; /* Return code */
int bDb;
bDb = (argc==6 && strlen(argv[1])==4 && memcmp("temp", argv[1], 4)==0);
if( argc!=5 && bDb==0 ){
*pzErr = sqlite3_mprintf("wrong number of vtable arguments");
rc = SQLITE_ERROR;
}else{
int nByte; /* Bytes of space to allocate */
const char *zDb = bDb ? argv[3] : argv[1];
const char *zTab = bDb ? argv[4] : argv[3];
const char *zType = bDb ? argv[5] : argv[4];
int nDb = (int)strlen(zDb)+1;
int nTab = (int)strlen(zTab)+1;
int eType = 0;
rc = fts5VocabTableType(zType, pzErr, &eType);
if( rc==SQLITE_OK ){
assert( eType>=0 && eType<ArraySize(azSchema) );
rc = sqlite3_declare_vtab(db, azSchema[eType]);
}
nByte = sizeof(Fts5VocabTable) + nDb + nTab;
pRet = sqlite3Fts5MallocZero(&rc, nByte);
if( pRet ){
pRet->pGlobal = (Fts5Global*)pAux;
pRet->eType = eType;
pRet->db = db;
pRet->zFts5Tbl = (char*)&pRet[1];
pRet->zFts5Db = &pRet->zFts5Tbl[nTab];
memcpy(pRet->zFts5Tbl, zTab, nTab);
memcpy(pRet->zFts5Db, zDb, nDb);
sqlite3Fts5Dequote(pRet->zFts5Tbl);
sqlite3Fts5Dequote(pRet->zFts5Db);
}
}
*ppVTab = (sqlite3_vtab*)pRet;
return rc;
}
/*
** The xConnect() and xCreate() methods for the virtual table. All the
** work is done in function fts5VocabInitVtab().
*/
static int fts5VocabConnectMethod(
sqlite3 *db, /* Database connection */
void *pAux, /* Pointer to tokenizer hash table */
int argc, /* Number of elements in argv array */
const char * const *argv, /* xCreate/xConnect argument array */
sqlite3_vtab **ppVtab, /* OUT: New sqlite3_vtab object */
char **pzErr /* OUT: sqlite3_malloc'd error message */
){
return fts5VocabInitVtab(db, pAux, argc, argv, ppVtab, pzErr);
}
static int fts5VocabCreateMethod(
sqlite3 *db, /* Database connection */
void *pAux, /* Pointer to tokenizer hash table */
int argc, /* Number of elements in argv array */
const char * const *argv, /* xCreate/xConnect argument array */
sqlite3_vtab **ppVtab, /* OUT: New sqlite3_vtab object */
char **pzErr /* OUT: sqlite3_malloc'd error message */
){
return fts5VocabInitVtab(db, pAux, argc, argv, ppVtab, pzErr);
}
/*
** Implementation of the xBestIndex method.
**
** Only constraints of the form:
**
** term <= ?
** term == ?
** term >= ?
**
** are interpreted. Less-than and less-than-or-equal are treated
** identically, as are greater-than and greater-than-or-equal.
*/
static int fts5VocabBestIndexMethod(
sqlite3_vtab *pUnused,
sqlite3_index_info *pInfo
){
int i;
int iTermEq = -1;
int iTermGe = -1;
int iTermLe = -1;
int idxNum = 0;
int nArg = 0;
UNUSED_PARAM(pUnused);
for(i=0; i<pInfo->nConstraint; i++){
struct sqlite3_index_constraint *p = &pInfo->aConstraint[i];
if( p->usable==0 ) continue;
if( p->iColumn==0 ){ /* term column */
if( p->op==SQLITE_INDEX_CONSTRAINT_EQ ) iTermEq = i;
if( p->op==SQLITE_INDEX_CONSTRAINT_LE ) iTermLe = i;
if( p->op==SQLITE_INDEX_CONSTRAINT_LT ) iTermLe = i;
if( p->op==SQLITE_INDEX_CONSTRAINT_GE ) iTermGe = i;
if( p->op==SQLITE_INDEX_CONSTRAINT_GT ) iTermGe = i;
}
}
if( iTermEq>=0 ){
idxNum |= FTS5_VOCAB_TERM_EQ;
pInfo->aConstraintUsage[iTermEq].argvIndex = ++nArg;
pInfo->estimatedCost = 100;
}else{
pInfo->estimatedCost = 1000000;
if( iTermGe>=0 ){
idxNum |= FTS5_VOCAB_TERM_GE;
pInfo->aConstraintUsage[iTermGe].argvIndex = ++nArg;
pInfo->estimatedCost = pInfo->estimatedCost / 2;
}
if( iTermLe>=0 ){
idxNum |= FTS5_VOCAB_TERM_LE;
pInfo->aConstraintUsage[iTermLe].argvIndex = ++nArg;
pInfo->estimatedCost = pInfo->estimatedCost / 2;
}
}
/* This virtual table always delivers results in ascending order of
** the "term" column (column 0). So if the user has requested this
** specifically - "ORDER BY term" or "ORDER BY term ASC" - set the
** sqlite3_index_info.orderByConsumed flag to tell the core the results
** are already in sorted order. */
if( pInfo->nOrderBy==1
&& pInfo->aOrderBy[0].iColumn==0
&& pInfo->aOrderBy[0].desc==0
){
pInfo->orderByConsumed = 1;
}
pInfo->idxNum = idxNum;
return SQLITE_OK;
}
/*
** Implementation of xOpen method.
*/
static int fts5VocabOpenMethod(
sqlite3_vtab *pVTab,
sqlite3_vtab_cursor **ppCsr
){
Fts5VocabTable *pTab = (Fts5VocabTable*)pVTab;
Fts5Table *pFts5 = 0;
Fts5VocabCursor *pCsr = 0;
int rc = SQLITE_OK;
sqlite3_stmt *pStmt = 0;
char *zSql = 0;
if( pTab->bBusy ){
pVTab->zErrMsg = sqlite3_mprintf(
"recursive definition for %s.%s", pTab->zFts5Db, pTab->zFts5Tbl
);
return SQLITE_ERROR;
}
zSql = sqlite3Fts5Mprintf(&rc,
"SELECT t.%Q FROM %Q.%Q AS t WHERE t.%Q MATCH '*id'",
pTab->zFts5Tbl, pTab->zFts5Db, pTab->zFts5Tbl, pTab->zFts5Tbl
);
if( zSql ){
rc = sqlite3_prepare_v2(pTab->db, zSql, -1, &pStmt, 0);
}
sqlite3_free(zSql);
assert( rc==SQLITE_OK || pStmt==0 );
if( rc==SQLITE_ERROR ) rc = SQLITE_OK;
pTab->bBusy = 1;
if( pStmt && sqlite3_step(pStmt)==SQLITE_ROW ){
i64 iId = sqlite3_column_int64(pStmt, 0);
pFts5 = sqlite3Fts5TableFromCsrid(pTab->pGlobal, iId);
}
pTab->bBusy = 0;
if( rc==SQLITE_OK ){
if( pFts5==0 ){
rc = sqlite3_finalize(pStmt);
pStmt = 0;
if( rc==SQLITE_OK ){
pVTab->zErrMsg = sqlite3_mprintf(
"no such fts5 table: %s.%s", pTab->zFts5Db, pTab->zFts5Tbl
);
rc = SQLITE_ERROR;
}
}else{
rc = sqlite3Fts5FlushToDisk(pFts5);
}
}
if( rc==SQLITE_OK ){
int nByte = pFts5->pConfig->nCol * sizeof(i64)*2 + sizeof(Fts5VocabCursor);
pCsr = (Fts5VocabCursor*)sqlite3Fts5MallocZero(&rc, nByte);
}
if( pCsr ){
pCsr->pFts5 = pFts5;
pCsr->pStmt = pStmt;
pCsr->aCnt = (i64*)&pCsr[1];
pCsr->aDoc = &pCsr->aCnt[pFts5->pConfig->nCol];
}else{
sqlite3_finalize(pStmt);
}
*ppCsr = (sqlite3_vtab_cursor*)pCsr;
return rc;
}
static void fts5VocabResetCursor(Fts5VocabCursor *pCsr){
pCsr->rowid = 0;
sqlite3Fts5IterClose(pCsr->pIter);
pCsr->pIter = 0;
sqlite3_free(pCsr->zLeTerm);
pCsr->nLeTerm = -1;
pCsr->zLeTerm = 0;
pCsr->bEof = 0;
}
/*
** Close the cursor. For additional information see the documentation
** on the xClose method of the virtual table interface.
*/
static int fts5VocabCloseMethod(sqlite3_vtab_cursor *pCursor){
Fts5VocabCursor *pCsr = (Fts5VocabCursor*)pCursor;
fts5VocabResetCursor(pCsr);
sqlite3Fts5BufferFree(&pCsr->term);
sqlite3_finalize(pCsr->pStmt);
sqlite3_free(pCsr);
return SQLITE_OK;
}
static int fts5VocabInstanceNewTerm(Fts5VocabCursor *pCsr){
int rc = SQLITE_OK;
if( sqlite3Fts5IterEof(pCsr->pIter) ){
pCsr->bEof = 1;
}else{
const char *zTerm;
int nTerm;
zTerm = sqlite3Fts5IterTerm(pCsr->pIter, &nTerm);
if( pCsr->nLeTerm>=0 ){
int nCmp = MIN(nTerm, pCsr->nLeTerm);
int bCmp = memcmp(pCsr->zLeTerm, zTerm, nCmp);
if( bCmp<0 || (bCmp==0 && pCsr->nLeTerm<nTerm) ){
pCsr->bEof = 1;
}
}
sqlite3Fts5BufferSet(&rc, &pCsr->term, nTerm, (const u8*)zTerm);
}
return rc;
}
static int fts5VocabInstanceNext(Fts5VocabCursor *pCsr){
int eDetail = pCsr->pFts5->pConfig->eDetail;
int rc = SQLITE_OK;
Fts5IndexIter *pIter = pCsr->pIter;
i64 *pp = &pCsr->iInstPos;
int *po = &pCsr->iInstOff;
assert( sqlite3Fts5IterEof(pIter)==0 );
assert( pCsr->bEof==0 );
while( eDetail==FTS5_DETAIL_NONE
|| sqlite3Fts5PoslistNext64(pIter->pData, pIter->nData, po, pp)
){
pCsr->iInstPos = 0;
pCsr->iInstOff = 0;
rc = sqlite3Fts5IterNextScan(pCsr->pIter);
if( rc==SQLITE_OK ){
rc = fts5VocabInstanceNewTerm(pCsr);
if( pCsr->bEof || eDetail==FTS5_DETAIL_NONE ) break;
}
if( rc ){
pCsr->bEof = 1;
break;
}
}
return rc;
}
/*
** Advance the cursor to the next row in the table.
*/
static int fts5VocabNextMethod(sqlite3_vtab_cursor *pCursor){
Fts5VocabCursor *pCsr = (Fts5VocabCursor*)pCursor;
Fts5VocabTable *pTab = (Fts5VocabTable*)pCursor->pVtab;
int rc = SQLITE_OK;
int nCol = pCsr->pFts5->pConfig->nCol;
pCsr->rowid++;
if( pTab->eType==FTS5_VOCAB_INSTANCE ){
return fts5VocabInstanceNext(pCsr);
}
if( pTab->eType==FTS5_VOCAB_COL ){
for(pCsr->iCol++; pCsr->iCol<nCol; pCsr->iCol++){
if( pCsr->aDoc[pCsr->iCol] ) break;
}
}
if( pTab->eType!=FTS5_VOCAB_COL || pCsr->iCol>=nCol ){
if( sqlite3Fts5IterEof(pCsr->pIter) ){
pCsr->bEof = 1;
}else{
const char *zTerm;
int nTerm;
zTerm = sqlite3Fts5IterTerm(pCsr->pIter, &nTerm);
assert( nTerm>=0 );
if( pCsr->nLeTerm>=0 ){
int nCmp = MIN(nTerm, pCsr->nLeTerm);
int bCmp = memcmp(pCsr->zLeTerm, zTerm, nCmp);
if( bCmp<0 || (bCmp==0 && pCsr->nLeTerm<nTerm) ){
pCsr->bEof = 1;
return SQLITE_OK;
}
}
sqlite3Fts5BufferSet(&rc, &pCsr->term, nTerm, (const u8*)zTerm);
memset(pCsr->aCnt, 0, nCol * sizeof(i64));
memset(pCsr->aDoc, 0, nCol * sizeof(i64));
pCsr->iCol = 0;
assert( pTab->eType==FTS5_VOCAB_COL || pTab->eType==FTS5_VOCAB_ROW );
while( rc==SQLITE_OK ){
int eDetail = pCsr->pFts5->pConfig->eDetail;
const u8 *pPos; int nPos; /* Position list */
i64 iPos = 0; /* 64-bit position read from poslist */
int iOff = 0; /* Current offset within position list */
pPos = pCsr->pIter->pData;
nPos = pCsr->pIter->nData;
switch( pTab->eType ){
case FTS5_VOCAB_ROW:
if( eDetail==FTS5_DETAIL_FULL ){
while( 0==sqlite3Fts5PoslistNext64(pPos, nPos, &iOff, &iPos) ){
pCsr->aCnt[0]++;
}
}
pCsr->aDoc[0]++;
break;
case FTS5_VOCAB_COL:
if( eDetail==FTS5_DETAIL_FULL ){
int iCol = -1;
while( 0==sqlite3Fts5PoslistNext64(pPos, nPos, &iOff, &iPos) ){
int ii = FTS5_POS2COLUMN(iPos);
if( iCol!=ii ){
if( ii>=nCol ){
rc = FTS5_CORRUPT;
break;
}
pCsr->aDoc[ii]++;
iCol = ii;
}
pCsr->aCnt[ii]++;
}
}else if( eDetail==FTS5_DETAIL_COLUMNS ){
while( 0==sqlite3Fts5PoslistNext64(pPos, nPos, &iOff,&iPos) ){
assert_nc( iPos>=0 && iPos<nCol );
if( iPos>=nCol ){
rc = FTS5_CORRUPT;
break;
}
pCsr->aDoc[iPos]++;
}
}else{
assert( eDetail==FTS5_DETAIL_NONE );
pCsr->aDoc[0]++;
}
break;
default:
assert( pTab->eType==FTS5_VOCAB_INSTANCE );
break;
}
if( rc==SQLITE_OK ){
rc = sqlite3Fts5IterNextScan(pCsr->pIter);
}
if( pTab->eType==FTS5_VOCAB_INSTANCE ) break;
if( rc==SQLITE_OK ){
zTerm = sqlite3Fts5IterTerm(pCsr->pIter, &nTerm);
if( nTerm!=pCsr->term.n
|| (nTerm>0 && memcmp(zTerm, pCsr->term.p, nTerm))
){
break;
}
if( sqlite3Fts5IterEof(pCsr->pIter) ) break;
}
}
}
}
if( rc==SQLITE_OK && pCsr->bEof==0 && pTab->eType==FTS5_VOCAB_COL ){
for(/* noop */; pCsr->iCol<nCol && pCsr->aDoc[pCsr->iCol]==0; pCsr->iCol++);
if( pCsr->iCol==nCol ){
rc = FTS5_CORRUPT;
}
}
return rc;
}
/*
** This is the xFilter implementation for the virtual table.
*/
static int fts5VocabFilterMethod(
sqlite3_vtab_cursor *pCursor, /* The cursor used for this query */
int idxNum, /* Strategy index */
const char *zUnused, /* Unused */
int nUnused, /* Number of elements in apVal */
sqlite3_value **apVal /* Arguments for the indexing scheme */
){
Fts5VocabTable *pTab = (Fts5VocabTable*)pCursor->pVtab;
Fts5VocabCursor *pCsr = (Fts5VocabCursor*)pCursor;
int eType = pTab->eType;
int rc = SQLITE_OK;
int iVal = 0;
int f = FTS5INDEX_QUERY_SCAN;
const char *zTerm = 0;
int nTerm = 0;
sqlite3_value *pEq = 0;
sqlite3_value *pGe = 0;
sqlite3_value *pLe = 0;
UNUSED_PARAM2(zUnused, nUnused);
fts5VocabResetCursor(pCsr);
if( idxNum & FTS5_VOCAB_TERM_EQ ) pEq = apVal[iVal++];
if( idxNum & FTS5_VOCAB_TERM_GE ) pGe = apVal[iVal++];
if( idxNum & FTS5_VOCAB_TERM_LE ) pLe = apVal[iVal++];
if( pEq ){
zTerm = (const char *)sqlite3_value_text(pEq);
nTerm = sqlite3_value_bytes(pEq);
f = 0;
}else{
if( pGe ){
zTerm = (const char *)sqlite3_value_text(pGe);
nTerm = sqlite3_value_bytes(pGe);
}
if( pLe ){
const char *zCopy = (const char *)sqlite3_value_text(pLe);
if( zCopy==0 ) zCopy = "";
pCsr->nLeTerm = sqlite3_value_bytes(pLe);
pCsr->zLeTerm = sqlite3_malloc(pCsr->nLeTerm+1);
if( pCsr->zLeTerm==0 ){
rc = SQLITE_NOMEM;
}else{
memcpy(pCsr->zLeTerm, zCopy, pCsr->nLeTerm+1);
}
}
}
if( rc==SQLITE_OK ){
Fts5Index *pIndex = pCsr->pFts5->pIndex;
rc = sqlite3Fts5IndexQuery(pIndex, zTerm, nTerm, f, 0, &pCsr->pIter);
}
if( rc==SQLITE_OK && eType==FTS5_VOCAB_INSTANCE ){
rc = fts5VocabInstanceNewTerm(pCsr);
}
if( rc==SQLITE_OK && !pCsr->bEof
&& (eType!=FTS5_VOCAB_INSTANCE
|| pCsr->pFts5->pConfig->eDetail!=FTS5_DETAIL_NONE)
){
rc = fts5VocabNextMethod(pCursor);
}
return rc;
}
/*
** This is the xEof method of the virtual table. SQLite calls this
** routine to find out if it has reached the end of a result set.
*/
static int fts5VocabEofMethod(sqlite3_vtab_cursor *pCursor){
Fts5VocabCursor *pCsr = (Fts5VocabCursor*)pCursor;
return pCsr->bEof;
}
static int fts5VocabColumnMethod(
sqlite3_vtab_cursor *pCursor, /* Cursor to retrieve value from */
sqlite3_context *pCtx, /* Context for sqlite3_result_xxx() calls */
int iCol /* Index of column to read value from */
){
Fts5VocabCursor *pCsr = (Fts5VocabCursor*)pCursor;
int eDetail = pCsr->pFts5->pConfig->eDetail;
int eType = ((Fts5VocabTable*)(pCursor->pVtab))->eType;
i64 iVal = 0;
if( iCol==0 ){
sqlite3_result_text(
pCtx, (const char*)pCsr->term.p, pCsr->term.n, SQLITE_TRANSIENT
);
}else if( eType==FTS5_VOCAB_COL ){
assert( iCol==1 || iCol==2 || iCol==3 );
if( iCol==1 ){
if( eDetail!=FTS5_DETAIL_NONE ){
const char *z = pCsr->pFts5->pConfig->azCol[pCsr->iCol];
sqlite3_result_text(pCtx, z, -1, SQLITE_STATIC);
}
}else if( iCol==2 ){
iVal = pCsr->aDoc[pCsr->iCol];
}else{
iVal = pCsr->aCnt[pCsr->iCol];
}
}else if( eType==FTS5_VOCAB_ROW ){
assert( iCol==1 || iCol==2 );
if( iCol==1 ){
iVal = pCsr->aDoc[0];
}else{
iVal = pCsr->aCnt[0];
}
}else{
assert( eType==FTS5_VOCAB_INSTANCE );
switch( iCol ){
case 1:
sqlite3_result_int64(pCtx, pCsr->pIter->iRowid);
break;
case 2: {
int ii = -1;
if( eDetail==FTS5_DETAIL_FULL ){
ii = FTS5_POS2COLUMN(pCsr->iInstPos);
}else if( eDetail==FTS5_DETAIL_COLUMNS ){
ii = (int)pCsr->iInstPos;
}
if( ii>=0 && ii<pCsr->pFts5->pConfig->nCol ){
const char *z = pCsr->pFts5->pConfig->azCol[ii];
sqlite3_result_text(pCtx, z, -1, SQLITE_STATIC);
}
break;
}
default: {
assert( iCol==3 );
if( eDetail==FTS5_DETAIL_FULL ){
int ii = FTS5_POS2OFFSET(pCsr->iInstPos);
sqlite3_result_int(pCtx, ii);
}
break;
}
}
}
if( iVal>0 ) sqlite3_result_int64(pCtx, iVal);
return SQLITE_OK;
}
/*
** This is the xRowid method. The SQLite core calls this routine to
** retrieve the rowid for the current row of the result set. The
** rowid should be written to *pRowid.
*/
static int fts5VocabRowidMethod(
sqlite3_vtab_cursor *pCursor,
sqlite_int64 *pRowid
){
Fts5VocabCursor *pCsr = (Fts5VocabCursor*)pCursor;
*pRowid = pCsr->rowid;
return SQLITE_OK;
}
static int sqlite3Fts5VocabInit(Fts5Global *pGlobal, sqlite3 *db){
static const sqlite3_module fts5Vocab = {
/* iVersion */ 2,
/* xCreate */ fts5VocabCreateMethod,
/* xConnect */ fts5VocabConnectMethod,
/* xBestIndex */ fts5VocabBestIndexMethod,
/* xDisconnect */ fts5VocabDisconnectMethod,
/* xDestroy */ fts5VocabDestroyMethod,
/* xOpen */ fts5VocabOpenMethod,
/* xClose */ fts5VocabCloseMethod,
/* xFilter */ fts5VocabFilterMethod,
/* xNext */ fts5VocabNextMethod,
/* xEof */ fts5VocabEofMethod,
/* xColumn */ fts5VocabColumnMethod,
/* xRowid */ fts5VocabRowidMethod,
/* xUpdate */ 0,
/* xBegin */ 0,
/* xSync */ 0,
/* xCommit */ 0,
/* xRollback */ 0,
/* xFindFunction */ 0,
/* xRename */ 0,
/* xSavepoint */ 0,
/* xRelease */ 0,
/* xRollbackTo */ 0,
/* xShadowName */ 0
};
void *p = (void*)pGlobal;
return sqlite3_create_module_v2(db, "fts5vocab", &fts5Vocab, p, 0);
}
#endif /* !defined(SQLITE_CORE) || defined(SQLITE_ENABLE_FTS5) */
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