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AIXCC-C-Challenge / local-test-sqlite3-delta-01 /afc-sqlite3 /ext /fts3 /fts3.c

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	/*
	** 2006 Oct 10
	**
	** 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.
	*/

	/*
	** The code in this file is only compiled if:
	**
	** * The FTS3 module is being built as an extension
	** (in which case SQLITE_CORE is not defined), or
	**
	** * The FTS3 module is being built into the core of
	** SQLite (in which case SQLITE_ENABLE_FTS3 is defined).
	*/

	/* The full-text index is stored in a series of b+tree (-like)
	** structures called segments which map terms to doclists. The
	** structures are like b+trees in layout, but are constructed from the
	** bottom up in optimal fashion and are not updatable. Since trees
	** are built from the bottom up, things will be described from the
	** bottom up.
	**
	**
	** Varints **
	** The basic unit of encoding is a variable-length integer called a
	** varint. We encode variable-length integers in little-endian order
	** using seven bits * per byte as follows:
	**
	** KEY:
	** A = 0xxxxxxx 7 bits of data and one flag bit
	** B = 1xxxxxxx 7 bits of data and one flag bit
	**
	** 7 bits - A
	** 14 bits - BA
	** 21 bits - BBA
	** and so on.
	**
	** This is similar in concept to how sqlite encodes "varints" but
	** the encoding is not the same. SQLite varints are big-endian
	** are are limited to 9 bytes in length whereas FTS3 varints are
	** little-endian and can be up to 10 bytes in length (in theory).
	**
	** Example encodings:
	**
	** 1: 0x01
	** 127: 0x7f
	** 128: 0x81 0x00
	**
	**
	** Document lists **
	** A doclist (document list) holds a docid-sorted list of hits for a
	** given term. Doclists hold docids and associated token positions.
	** A docid is the unique integer identifier for a single document.
	** A position is the index of a word within the document. The first
	** word of the document has a position of 0.
	**
	** FTS3 used to optionally store character offsets using a compile-time
	** option. But that functionality is no longer supported.
	**
	** A doclist is stored like this:
	**
	** array {
	** varint docid; (delta from previous doclist)
	** array { (position list for column 0)
	** varint position; (2 more than the delta from previous position)
	** }
	** array {
	** varint POS_COLUMN; (marks start of position list for new column)
	** varint column; (index of new column)
	** array {
	** varint position; (2 more than the delta from previous position)
	** }
	** }
	** varint POS_END; (marks end of positions for this document.
	** }
	**
	** Here, array { X } means zero or more occurrences of X, adjacent in
	** memory. A "position" is an index of a token in the token stream
	** generated by the tokenizer. Note that POS_END and POS_COLUMN occur
	** in the same logical place as the position element, and act as sentinals
	** ending a position list array. POS_END is 0. POS_COLUMN is 1.
	** The positions numbers are not stored literally but rather as two more
	** than the difference from the prior position, or the just the position plus
	** 2 for the first position. Example:
	**
	** label: A B C D E F G H I J K
	** value: 123 5 9 1 1 14 35 0 234 72 0
	**
	** The 123 value is the first docid. For column zero in this document
	** there are two matches at positions 3 and 10 (5-2 and 9-2+3). The 1
	** at D signals the start of a new column; the 1 at E indicates that the
	** new column is column number 1. There are two positions at 12 and 45
	** (14-2 and 35-2+12). The 0 at H indicate the end-of-document. The
	** 234 at I is the delta to next docid (357). It has one position 70
	** (72-2) and then terminates with the 0 at K.
	**
	** A "position-list" is the list of positions for multiple columns for
	** a single docid. A "column-list" is the set of positions for a single
	** column. Hence, a position-list consists of one or more column-lists,
	** a document record consists of a docid followed by a position-list and
	** a doclist consists of one or more document records.
	**
	** A bare doclist omits the position information, becoming an
	** array of varint-encoded docids.
	**
	** Segment leaf nodes **
	** Segment leaf nodes store terms and doclists, ordered by term. Leaf
	** nodes are written using LeafWriter, and read using LeafReader (to
	** iterate through a single leaf node's data) and LeavesReader (to
	** iterate through a segment's entire leaf layer). Leaf nodes have
	** the format:
	**
	** varint iHeight; (height from leaf level, always 0)
	** varint nTerm; (length of first term)
	** char pTerm[nTerm]; (content of first term)
	** varint nDoclist; (length of term's associated doclist)
	** char pDoclist[nDoclist]; (content of doclist)
	** array {
	** (further terms are delta-encoded)
	** varint nPrefix; (length of prefix shared with previous term)
	** varint nSuffix; (length of unshared suffix)
	** char pTermSuffix[nSuffix];(unshared suffix of next term)
	** varint nDoclist; (length of term's associated doclist)
	** char pDoclist[nDoclist]; (content of doclist)
	** }
	**
	** Here, array { X } means zero or more occurrences of X, adjacent in
	** memory.
	**
	** Leaf nodes are broken into blocks which are stored contiguously in
	** the %_segments table in sorted order. This means that when the end
	** of a node is reached, the next term is in the node with the next
	** greater node id.
	**
	** New data is spilled to a new leaf node when the current node
	** exceeds LEAF_MAX bytes (default 2048). New data which itself is
	** larger than STANDALONE_MIN (default 1024) is placed in a standalone
	** node (a leaf node with a single term and doclist). The goal of
	** these settings is to pack together groups of small doclists while
	** making it efficient to directly access large doclists. The
	** assumption is that large doclists represent terms which are more
	** likely to be query targets.
	**
	** TODO(shess) It may be useful for blocking decisions to be more
	** dynamic. For instance, it may make more sense to have a 2.5k leaf
	** node rather than splitting into 2k and .5k nodes. My intuition is
	** that this might extend through 2x or 4x the pagesize.
	**
	**
	** Segment interior nodes **
	** Segment interior nodes store blockids for subtree nodes and terms
	** to describe what data is stored by the each subtree. Interior
	** nodes are written using InteriorWriter, and read using
	** InteriorReader. InteriorWriters are created as needed when
	** SegmentWriter creates new leaf nodes, or when an interior node
	** itself grows too big and must be split. The format of interior
	** nodes:
	**
	** varint iHeight; (height from leaf level, always >0)
	** varint iBlockid; (block id of node's leftmost subtree)
	** optional {
	** varint nTerm; (length of first term)
	** char pTerm[nTerm]; (content of first term)
	** array {
	** (further terms are delta-encoded)
	** varint nPrefix; (length of shared prefix with previous term)
	** varint nSuffix; (length of unshared suffix)
	** char pTermSuffix[nSuffix]; (unshared suffix of next term)
	** }
	** }
	**
	** Here, optional { X } means an optional element, while array { X }
	** means zero or more occurrences of X, adjacent in memory.
	**
	** An interior node encodes n terms separating n+1 subtrees. The
	** subtree blocks are contiguous, so only the first subtree's blockid
	** is encoded. The subtree at iBlockid will contain all terms less
	** than the first term encoded (or all terms if no term is encoded).
	** Otherwise, for terms greater than or equal to pTerm[i] but less
	** than pTerm[i+1], the subtree for that term will be rooted at
	** iBlockid+i. Interior nodes only store enough term data to
	** distinguish adjacent children (if the rightmost term of the left
	** child is "something", and the leftmost term of the right child is
	** "wicked", only "w" is stored).
	**
	** New data is spilled to a new interior node at the same height when
	** the current node exceeds INTERIOR_MAX bytes (default 2048).
	** INTERIOR_MIN_TERMS (default 7) keeps large terms from monopolizing
	** interior nodes and making the tree too skinny. The interior nodes
	** at a given height are naturally tracked by interior nodes at
	** height+1, and so on.
	**
	**
	** Segment directory **
	** The segment directory in table %_segdir stores meta-information for
	** merging and deleting segments, and also the root node of the
	** segment's tree.
	**
	** The root node is the top node of the segment's tree after encoding
	** the entire segment, restricted to ROOT_MAX bytes (default 1024).
	** This could be either a leaf node or an interior node. If the top
	** node requires more than ROOT_MAX bytes, it is flushed to %_segments
	** and a new root interior node is generated (which should always fit
	** within ROOT_MAX because it only needs space for 2 varints, the
	** height and the blockid of the previous root).
	**
	** The meta-information in the segment directory is:
	** level - segment level (see below)
	** idx - index within level
	** - (level,idx uniquely identify a segment)
	** start_block - first leaf node
	** leaves_end_block - last leaf node
	** end_block - last block (including interior nodes)
	** root - contents of root node
	**
	** If the root node is a leaf node, then start_block,
	** leaves_end_block, and end_block are all 0.
	**
	**
	** Segment merging **
	** To amortize update costs, segments are grouped into levels and
	** merged in batches. Each increase in level represents exponentially
	** more documents.
	**
	** New documents (actually, document updates) are tokenized and
	** written individually (using LeafWriter) to a level 0 segment, with
	** incrementing idx. When idx reaches MERGE_COUNT (default 16), all
	** level 0 segments are merged into a single level 1 segment. Level 1
	** is populated like level 0, and eventually MERGE_COUNT level 1
	** segments are merged to a single level 2 segment (representing
	** MERGE_COUNT^2 updates), and so on.
	**
	** A segment merge traverses all segments at a given level in
	** parallel, performing a straightforward sorted merge. Since segment
	** leaf nodes are written in to the %_segments table in order, this
	** merge traverses the underlying sqlite disk structures efficiently.
	** After the merge, all segment blocks from the merged level are
	** deleted.
	**
	** MERGE_COUNT controls how often we merge segments. 16 seems to be
	** somewhat of a sweet spot for insertion performance. 32 and 64 show
	** very similar performance numbers to 16 on insertion, though they're
	** a tiny bit slower (perhaps due to more overhead in merge-time
	** sorting). 8 is about 20% slower than 16, 4 about 50% slower than
	** 16, 2 about 66% slower than 16.
	**
	** At query time, high MERGE_COUNT increases the number of segments
	** which need to be scanned and merged. For instance, with 100k docs
	** inserted:
	**
	** MERGE_COUNT segments
	** 16 25
	** 8 12
	** 4 10
	** 2 6
	**
	** This appears to have only a moderate impact on queries for very
	** frequent terms (which are somewhat dominated by segment merge
	** costs), and infrequent and non-existent terms still seem to be fast
	** even with many segments.
	**
	** TODO(shess) That said, it would be nice to have a better query-side
	** argument for MERGE_COUNT of 16. Also, it is possible/likely that
	** optimizations to things like doclist merging will swing the sweet
	** spot around.
	**
	**
	**
	** Handling of deletions and updates **
	** Since we're using a segmented structure, with no docid-oriented
	** index into the term index, we clearly cannot simply update the term
	** index when a document is deleted or updated. For deletions, we
	** write an empty doclist (varint(docid) varint(POS_END)), for updates
	** we simply write the new doclist. Segment merges overwrite older
	** data for a particular docid with newer data, so deletes or updates
	** will eventually overtake the earlier data and knock it out. The
	** query logic likewise merges doclists so that newer data knocks out
	** older data.
	*/

	#include "fts3Int.h"
	#if !defined(SQLITE_CORE) \|\| defined(SQLITE_ENABLE_FTS3)

	#if defined(SQLITE_ENABLE_FTS3) && !defined(SQLITE_CORE)
	# define SQLITE_CORE 1
	#endif

	#include <assert.h>
	#include <stdlib.h>
	#include <stddef.h>
	#include <stdio.h>
	#include <string.h>
	#include <stdarg.h>

	#include "fts3.h"
	#ifndef SQLITE_CORE
	# include "sqlite3ext.h"
	SQLITE_EXTENSION_INIT1
	#endif

	typedef struct Fts3HashWrapper Fts3HashWrapper;
	struct Fts3HashWrapper {
	Fts3Hash hash; /* Hash table */
	int nRef; /* Number of pointers to this object */
	};

	static int fts3EvalNext(Fts3Cursor *pCsr);
	static int fts3EvalStart(Fts3Cursor *pCsr);
	static int fts3TermSegReaderCursor(
	Fts3Cursor , const char , int, int, Fts3MultiSegReader **);

	/*
	** 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 fts3 code are activated - conditions that are
	** only true if it is guaranteed that the fts3 database is not corrupt.
	*/
	#ifdef SQLITE_DEBUG
	int sqlite3_fts3_may_be_corrupt = 1;
	#endif

	/*
	** Write a 64-bit variable-length integer to memory starting at p[0].
	** The length of data written will be between 1 and FTS3_VARINT_MAX bytes.
	** The number of bytes written is returned.
	*/
	int sqlite3Fts3PutVarint(char *p, sqlite_int64 v){
	unsigned char q = (unsigned char ) p;
	sqlite_uint64 vu = v;
	do{
	*q++ = (unsigned char) ((vu & 0x7f) \| 0x80);
	vu >>= 7;
	}while( vu!=0 );
	q[-1] &= 0x7f; /* turn off high bit in final byte */
	assert( q - (unsigned char *)p <= FTS3_VARINT_MAX );
	return (int) (q - (unsigned char *)p);
	}

	#define GETVARINT_STEP(v, ptr, shift, mask1, mask2, var, ret) \
	v = (v & mask1) \| ( ((const unsigned char)(ptr++)) << shift ); \
	if( (v & mask2)==0 ){ var = v; return ret; }
	#define GETVARINT_INIT(v, ptr, shift, mask1, mask2, var, ret) \
	v = (*ptr++); \
	if( (v & mask2)==0 ){ var = v; return ret; }

	int sqlite3Fts3GetVarintU(const char pBuf, sqlite_uint64 v){
	const unsigned char p = (const unsigned char)pBuf;
	const unsigned char *pStart = p;
	u32 a;
	u64 b;
	int shift;

	GETVARINT_INIT(a, p, 0, 0x00, 0x80, *v, 1);
	GETVARINT_STEP(a, p, 7, 0x7F, 0x4000, *v, 2);
	GETVARINT_STEP(a, p, 14, 0x3FFF, 0x200000, *v, 3);
	GETVARINT_STEP(a, p, 21, 0x1FFFFF, 0x10000000, *v, 4);
	b = (a & 0x0FFFFFFF );

	for(shift=28; shift<=63; shift+=7){
	u64 c = *p++;
	b += (c&0x7F) << shift;
	if( (c & 0x80)==0 ) break;
	}
	*v = b;
	return (int)(p - pStart);
	}

	/*
	** Read a 64-bit variable-length integer from memory starting at p[0].
	** Return the number of bytes read, or 0 on error.
	** The value is stored in *v.
	*/
	int sqlite3Fts3GetVarint(const char pBuf, sqlite_int64 v){
	return sqlite3Fts3GetVarintU(pBuf, (sqlite3_uint64*)v);
	}

	/*
	** Read a 64-bit variable-length integer from memory starting at p[0] and
	** not extending past pEnd[-1].
	** Return the number of bytes read, or 0 on error.
	** The value is stored in *v.
	*/
	int sqlite3Fts3GetVarintBounded(
	const char *pBuf,
	const char *pEnd,
	sqlite_int64 *v
	){
	const unsigned char p = (const unsigned char)pBuf;
	const unsigned char *pStart = p;
	const unsigned char pX = (const unsigned char)pEnd;
	u64 b = 0;
	int shift;
	for(shift=0; shift<=63; shift+=7){
	u64 c = p<pX ? *p : 0;
	p++;
	b += (c&0x7F) << shift;
	if( (c & 0x80)==0 ) break;
	}
	*v = b;
	return (int)(p - pStart);
	}

	/*
	** Similar to sqlite3Fts3GetVarint(), except that the output is truncated to
	** a non-negative 32-bit integer before it is returned.
	*/
	int sqlite3Fts3GetVarint32(const char p, int pi){
	const unsigned char ptr = (const unsigned char)p;
	u32 a;

	#ifndef fts3GetVarint32
	GETVARINT_INIT(a, ptr, 0, 0x00, 0x80, *pi, 1);
	#else
	a = (*ptr++);
	assert( a & 0x80 );
	#endif

	GETVARINT_STEP(a, ptr, 7, 0x7F, 0x4000, *pi, 2);
	GETVARINT_STEP(a, ptr, 14, 0x3FFF, 0x200000, *pi, 3);
	GETVARINT_STEP(a, ptr, 21, 0x1FFFFF, 0x10000000, *pi, 4);
	a = (a & 0x0FFFFFFF );
	pi = (int)(a \| ((u32)(ptr & 0x07) << 28));
	assert( 0==(a & 0x80000000) );
	assert( *pi>=0 );
	return 5;
	}

	/*
	** Return the number of bytes required to encode v as a varint
	*/
	int sqlite3Fts3VarintLen(sqlite3_uint64 v){
	int i = 0;
	do{
	i++;
	v >>= 7;
	}while( v!=0 );
	return i;
	}

	/*
	** 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
	**
	*/
	void sqlite3Fts3Dequote(char *z){
	char quote; /* Quote character (if any ) */

	quote = z[0];
	if( quote=='[' \|\| quote=='\'' \|\| quote=='"' \|\| quote=='`' ){
	int iIn = 1; /* Index of next byte to read from input */
	int iOut = 0; /* Index of next byte to write to output */

	/* If the first byte was a '[', then the close-quote character is a ']' */
	if( quote=='[' ) quote = ']';

	while( z[iIn] ){
	if( z[iIn]==quote ){
	if( z[iIn+1]!=quote ) break;
	z[iOut++] = quote;
	iIn += 2;
	}else{
	z[iOut++] = z[iIn++];
	}
	}
	z[iOut] = '\0';
	}
	}

	/*
	** Read a single varint from the doclist at pp and advance pp to point
	** to the first byte past the end of the varint. Add the value of the varint
	** to *pVal.
	*/
	static void fts3GetDeltaVarint(char *pp, sqlite3_int64 pVal){
	sqlite3_int64 iVal;
	pp += sqlite3Fts3GetVarint(pp, &iVal);
	*pVal += iVal;
	}

	/*
	** When this function is called, *pp points to the first byte following a
	** varint that is part of a doclist (or position-list, or any other list
	** of varints). This function moves *pp to point to the start of that varint,
	** and sets *pVal by the varint value.
	**
	** Argument pStart points to the first byte of the doclist that the
	** varint is part of.
	*/
	static void fts3GetReverseVarint(
	char **pp,
	char *pStart,
	sqlite3_int64 *pVal
	){
	sqlite3_int64 iVal;
	char *p;

	/* Pointer p now points at the first byte past the varint we are
	** interested in. So, unless the doclist is corrupt, the 0x80 bit is
	** clear on character p[-1]. */
	for(p = (pp)-2; p>=pStart && p&0x80; p--);
	p++;
	*pp = p;

	sqlite3Fts3GetVarint(p, &iVal);
	*pVal = iVal;
	}

	/*
	** The xDisconnect() virtual table method.
	*/
	static int fts3DisconnectMethod(sqlite3_vtab *pVtab){
	Fts3Table p = (Fts3Table )pVtab;
	int i;

	assert( p->nPendingData==0 );
	assert( p->pSegments==0 );

	/* Free any prepared statements held */
	sqlite3_finalize(p->pSeekStmt);
	for(i=0; i<SizeofArray(p->aStmt); i++){
	sqlite3_finalize(p->aStmt[i]);
	}
	sqlite3_free(p->zSegmentsTbl);
	sqlite3_free(p->zReadExprlist);
	sqlite3_free(p->zWriteExprlist);
	sqlite3_free(p->zContentTbl);
	sqlite3_free(p->zLanguageid);

	/* Invoke the tokenizer destructor to free the tokenizer. */
	p->pTokenizer->pModule->xDestroy(p->pTokenizer);

	sqlite3_free(p);
	return SQLITE_OK;
	}

	/*
	** Write an error message into *pzErr
	*/
	void sqlite3Fts3ErrMsg(char *pzErr, const char zFormat, ...){
	va_list ap;
	sqlite3_free(*pzErr);
	va_start(ap, zFormat);
	*pzErr = sqlite3_vmprintf(zFormat, ap);
	va_end(ap);
	}

	/*
	** Construct one or more SQL statements from the format string given
	** and then evaluate those statements. The success code is written
	** into *pRc.
	**
	** If *pRc is initially non-zero then this routine is a no-op.
	*/
	static void fts3DbExec(
	int pRc, / Success code */
	sqlite3 db, / Database in which to run SQL */
	const char zFormat, / Format string for SQL */
	... /* Arguments to the format string */
	){
	va_list ap;
	char *zSql;
	if( *pRc ) return;
	va_start(ap, zFormat);
	zSql = sqlite3_vmprintf(zFormat, ap);
	va_end(ap);
	if( zSql==0 ){
	*pRc = SQLITE_NOMEM;
	}else{
	*pRc = sqlite3_exec(db, zSql, 0, 0, 0);
	sqlite3_free(zSql);
	}
	}

	/*
	** The xDestroy() virtual table method.
	*/
	static int fts3DestroyMethod(sqlite3_vtab *pVtab){
	Fts3Table p = (Fts3Table )pVtab;
	int rc = SQLITE_OK; /* Return code */
	const char zDb = p->zDb; / Name of database (e.g. "main", "temp") */
	sqlite3 db = p->db; / Database handle */

	/* Drop the shadow tables */
	fts3DbExec(&rc, db,
	"DROP TABLE IF EXISTS %Q.'%q_segments';"
	"DROP TABLE IF EXISTS %Q.'%q_segdir';"
	"DROP TABLE IF EXISTS %Q.'%q_docsize';"
	"DROP TABLE IF EXISTS %Q.'%q_stat';"
	"%s DROP TABLE IF EXISTS %Q.'%q_content';",
	zDb, p->zName,
	zDb, p->zName,
	zDb, p->zName,
	zDb, p->zName,
	(p->zContentTbl ? "--" : ""), zDb,p->zName
	);

	/* If everything has worked, invoke fts3DisconnectMethod() to free the
	** memory associated with the Fts3Table structure and return SQLITE_OK.
	** Otherwise, return an SQLite error code.
	*/
	return (rc==SQLITE_OK ? fts3DisconnectMethod(pVtab) : rc);
	}


	/*
	** Invoke sqlite3_declare_vtab() to declare the schema for the FTS3 table
	** passed as the first argument. This is done as part of the xConnect()
	** and xCreate() methods.
	**
	** If *pRc is non-zero when this function is called, it is a no-op.
	** Otherwise, if an error occurs, an SQLite error code is stored in *pRc
	** before returning.
	*/
	static void fts3DeclareVtab(int pRc, Fts3Table p){
	if( *pRc==SQLITE_OK ){
	int i; /* Iterator variable */
	int rc; /* Return code */
	char zSql; / SQL statement passed to declare_vtab() */
	char zCols; / List of user defined columns */
	const char *zLanguageid;

	zLanguageid = (p->zLanguageid ? p->zLanguageid : "__langid");
	sqlite3_vtab_config(p->db, SQLITE_VTAB_CONSTRAINT_SUPPORT, 1);
	sqlite3_vtab_config(p->db, SQLITE_VTAB_INNOCUOUS);

	/* Create a list of user columns for the virtual table */
	zCols = sqlite3_mprintf("%Q, ", p->azColumn[0]);
	for(i=1; zCols && i<p->nColumn; i++){
	zCols = sqlite3_mprintf("%z%Q, ", zCols, p->azColumn[i]);
	}

	/* Create the whole "CREATE TABLE" statement to pass to SQLite */
	zSql = sqlite3_mprintf(
	"CREATE TABLE x(%s %Q HIDDEN, docid HIDDEN, %Q HIDDEN)",
	zCols, p->zName, zLanguageid
	);
	if( !zCols \|\| !zSql ){
	rc = SQLITE_NOMEM;
	}else{
	rc = sqlite3_declare_vtab(p->db, zSql);
	}

	sqlite3_free(zSql);
	sqlite3_free(zCols);
	*pRc = rc;
	}
	}

	/*
	** Create the %_stat table if it does not already exist.
	*/
	void sqlite3Fts3CreateStatTable(int pRc, Fts3Table p){
	fts3DbExec(pRc, p->db,
	"CREATE TABLE IF NOT EXISTS %Q.'%q_stat'"
	"(id INTEGER PRIMARY KEY, value BLOB);",
	p->zDb, p->zName
	);
	if( (*pRc)==SQLITE_OK ) p->bHasStat = 1;
	}

	/*
	** Create the backing store tables (%_content, %_segments and %_segdir)
	** required by the FTS3 table passed as the only argument. This is done
	** as part of the vtab xCreate() method.
	**
	** If the p->bHasDocsize boolean is true (indicating that this is an
	** FTS4 table, not an FTS3 table) then also create the %_docsize and
	** %_stat tables required by FTS4.
	*/
	static int fts3CreateTables(Fts3Table *p){
	int rc = SQLITE_OK; /* Return code */
	int i; /* Iterator variable */
	sqlite3 db = p->db; / The database connection */

	if( p->zContentTbl==0 ){
	const char *zLanguageid = p->zLanguageid;
	char zContentCols; / Columns of %_content table */

	/* Create a list of user columns for the content table */
	zContentCols = sqlite3_mprintf("docid INTEGER PRIMARY KEY");
	for(i=0; zContentCols && i<p->nColumn; i++){
	char *z = p->azColumn[i];
	zContentCols = sqlite3_mprintf("%z, 'c%d%q'", zContentCols, i, z);
	}
	if( zLanguageid && zContentCols ){
	zContentCols = sqlite3_mprintf("%z, langid", zContentCols, zLanguageid);
	}
	if( zContentCols==0 ) rc = SQLITE_NOMEM;

	/* Create the content table */
	fts3DbExec(&rc, db,
	"CREATE TABLE %Q.'%q_content'(%s)",
	p->zDb, p->zName, zContentCols
	);
	sqlite3_free(zContentCols);
	}

	/* Create other tables */
	fts3DbExec(&rc, db,
	"CREATE TABLE %Q.'%q_segments'(blockid INTEGER PRIMARY KEY, block BLOB);",
	p->zDb, p->zName
	);
	fts3DbExec(&rc, db,
	"CREATE TABLE %Q.'%q_segdir'("
	"level INTEGER,"
	"idx INTEGER,"
	"start_block INTEGER,"
	"leaves_end_block INTEGER,"
	"end_block INTEGER,"
	"root BLOB,"
	"PRIMARY KEY(level, idx)"
	");",
	p->zDb, p->zName
	);
	if( p->bHasDocsize ){
	fts3DbExec(&rc, db,
	"CREATE TABLE %Q.'%q_docsize'(docid INTEGER PRIMARY KEY, size BLOB);",
	p->zDb, p->zName
	);
	}
	assert( p->bHasStat==p->bFts4 );
	if( p->bHasStat ){
	sqlite3Fts3CreateStatTable(&rc, p);
	}
	return rc;
	}

	/*
	** Store the current database page-size in bytes in p->nPgsz.
	**
	** If *pRc is non-zero when this function is called, it is a no-op.
	** Otherwise, if an error occurs, an SQLite error code is stored in *pRc
	** before returning.
	*/
	static void fts3DatabasePageSize(int pRc, Fts3Table p){
	if( *pRc==SQLITE_OK ){
	int rc; /* Return code */
	char zSql; / SQL text "PRAGMA %Q.page_size" */
	sqlite3_stmt pStmt; / Compiled "PRAGMA %Q.page_size" statement */

	zSql = sqlite3_mprintf("PRAGMA %Q.page_size", p->zDb);
	if( !zSql ){
	rc = SQLITE_NOMEM;
	}else{
	rc = sqlite3_prepare(p->db, zSql, -1, &pStmt, 0);
	if( rc==SQLITE_OK ){
	sqlite3_step(pStmt);
	p->nPgsz = sqlite3_column_int(pStmt, 0);
	rc = sqlite3_finalize(pStmt);
	}else if( rc==SQLITE_AUTH ){
	p->nPgsz = 1024;
	rc = SQLITE_OK;
	}
	}
	assert( p->nPgsz>0 \|\| rc!=SQLITE_OK );
	sqlite3_free(zSql);
	*pRc = rc;
	}
	}

	/*
	** "Special" FTS4 arguments are column specifications of the following form:
	**
	** <key> = <value>
	**
	** There may not be whitespace surrounding the "=" character. The <value>
	** term may be quoted, but the <key> may not.
	*/
	static int fts3IsSpecialColumn(
	const char *z,
	int *pnKey,
	char **pzValue
	){
	char *zValue;
	const char *zCsr = z;

	while( *zCsr!='=' ){
	if( *zCsr=='\0' ) return 0;
	zCsr++;
	}

	*pnKey = (int)(zCsr-z);
	zValue = sqlite3_mprintf("%s", &zCsr[1]);
	if( zValue ){
	sqlite3Fts3Dequote(zValue);
	}
	*pzValue = zValue;
	return 1;
	}

	/*
	** Append the output of a printf() style formatting to an existing string.
	*/
	static void fts3Appendf(
	int pRc, / IN/OUT: Error code */
	char *pz, / IN/OUT: Pointer to string buffer */
	const char zFormat, / Printf format string to append */
	... /* Arguments for printf format string */
	){
	if( *pRc==SQLITE_OK ){
	va_list ap;
	char *z;
	va_start(ap, zFormat);
	z = sqlite3_vmprintf(zFormat, ap);
	va_end(ap);
	if( z && *pz ){
	char z2 = sqlite3_mprintf("%s%s", pz, z);
	sqlite3_free(z);
	z = z2;
	}
	if( z==0 ) *pRc = SQLITE_NOMEM;
	sqlite3_free(*pz);
	*pz = z;
	}
	}

	/*
	** Return a copy of input string zInput enclosed in double-quotes (") and
	** with all double quote characters escaped. For example:
	**
	** fts3QuoteId("un \"zip\"") -> "un \"\"zip\"\""
	**
	** The pointer returned points to memory obtained from sqlite3_malloc(). It
	** is the callers responsibility to call sqlite3_free() to release this
	** memory.
	*/
	static char fts3QuoteId(char const zInput){
	sqlite3_int64 nRet;
	char *zRet;
	nRet = 2 + (int)strlen(zInput)*2 + 1;
	zRet = sqlite3_malloc64(nRet);
	if( zRet ){
	int i;
	char *z = zRet;
	*(z++) = '"';
	for(i=0; zInput[i]; i++){
	if( zInput[i]=='"' ) *(z++) = '"';
	*(z++) = zInput[i];
	}
	*(z++) = '"';
	*(z++) = '\0';
	}
	return zRet;
	}

	/*
	** Return a list of comma separated SQL expressions and a FROM clause that
	** could be used in a SELECT statement such as the following:
	**
	** SELECT <list of expressions> FROM %_content AS x ...
	**
	** to return the docid, followed by each column of text data in order
	** from left to write. If parameter zFunc is not NULL, then instead of
	** being returned directly each column of text data is passed to an SQL
	** function named zFunc first. For example, if zFunc is "unzip" and the
	** table has the three user-defined columns "a", "b", and "c", the following
	** string is returned:
	**
	** "docid, unzip(x.'a'), unzip(x.'b'), unzip(x.'c') FROM %_content AS x"
	**
	** The pointer returned points to a buffer allocated by sqlite3_malloc(). It
	** is the responsibility of the caller to eventually free it.
	**
	** If *pRc is not SQLITE_OK when this function is called, it is a no-op (and
	** a NULL pointer is returned). Otherwise, if an OOM error is encountered
	** by this function, NULL is returned and *pRc is set to SQLITE_NOMEM. If
	** no error occurs, *pRc is left unmodified.
	*/
	static char fts3ReadExprList(Fts3Table p, const char zFunc, int pRc){
	char *zRet = 0;
	char *zFree = 0;
	char *zFunction;
	int i;

	if( p->zContentTbl==0 ){
	if( !zFunc ){
	zFunction = "";
	}else{
	zFree = zFunction = fts3QuoteId(zFunc);
	}
	fts3Appendf(pRc, &zRet, "docid");
	for(i=0; i<p->nColumn; i++){
	fts3Appendf(pRc, &zRet, ",%s(x.'c%d%q')", zFunction, i, p->azColumn[i]);
	}
	if( p->zLanguageid ){
	fts3Appendf(pRc, &zRet, ", x.%Q", "langid");
	}
	sqlite3_free(zFree);
	}else{
	fts3Appendf(pRc, &zRet, "rowid");
	for(i=0; i<p->nColumn; i++){
	fts3Appendf(pRc, &zRet, ", x.'%q'", p->azColumn[i]);
	}
	if( p->zLanguageid ){
	fts3Appendf(pRc, &zRet, ", x.%Q", p->zLanguageid);
	}
	}
	fts3Appendf(pRc, &zRet, " FROM '%q'.'%q%s' AS x",
	p->zDb,
	(p->zContentTbl ? p->zContentTbl : p->zName),
	(p->zContentTbl ? "" : "_content")
	);
	return zRet;
	}

	/*
	** Return a list of N comma separated question marks, where N is the number
	** of columns in the %_content table (one for the docid plus one for each
	** user-defined text column).
	**
	** If argument zFunc is not NULL, then all but the first question mark
	** is preceded by zFunc and an open bracket, and followed by a closed
	** bracket. For example, if zFunc is "zip" and the FTS3 table has three
	** user-defined text columns, the following string is returned:
	**
	** "?, zip(?), zip(?), zip(?)"
	**
	** The pointer returned points to a buffer allocated by sqlite3_malloc(). It
	** is the responsibility of the caller to eventually free it.
	**
	** If *pRc is not SQLITE_OK when this function is called, it is a no-op (and
	** a NULL pointer is returned). Otherwise, if an OOM error is encountered
	** by this function, NULL is returned and *pRc is set to SQLITE_NOMEM. If
	** no error occurs, *pRc is left unmodified.
	*/
	static char fts3WriteExprList(Fts3Table p, const char zFunc, int pRc){
	char *zRet = 0;
	char *zFree = 0;
	char *zFunction;
	int i;

	if( !zFunc ){
	zFunction = "";
	}else{
	zFree = zFunction = fts3QuoteId(zFunc);
	}
	fts3Appendf(pRc, &zRet, "?");
	for(i=0; i<p->nColumn; i++){
	fts3Appendf(pRc, &zRet, ",%s(?)", zFunction);
	}
	if( p->zLanguageid ){
	fts3Appendf(pRc, &zRet, ", ?");
	}
	sqlite3_free(zFree);
	return zRet;
	}

	/*
	** Buffer z contains a positive integer value encoded as utf-8 text.
	** Decode this value and store it in *pnOut, returning the number of bytes
	** consumed. If an overflow error occurs return a negative value.
	*/
	int sqlite3Fts3ReadInt(const char z, int pnOut){
	u64 iVal = 0;
	int i;
	for(i=0; z[i]>='0' && z[i]<='9'; i++){
	iVal = iVal*10 + (z[i] - '0');
	if( iVal>0x7FFFFFFF ) return -1;
	}
	*pnOut = (int)iVal;
	return i;
	}

	/*
	** This function interprets the string at (*pp) as a non-negative integer
	** value. It reads the integer and sets *pnOut to the value read, then
	** sets *pp to point to the byte immediately following the last byte of
	** the integer value.
	**
	** Only decimal digits ('0'..'9') may be part of an integer value.
	**
	** If *pp does not being with a decimal digit SQLITE_ERROR is returned and
	** the output value undefined. Otherwise SQLITE_OK is returned.
	**
	** This function is used when parsing the "prefix=" FTS4 parameter.
	*/
	static int fts3GobbleInt(const char *pp, int pnOut){
	const int MAX_NPREFIX = 10000000;
	int nInt = 0; /* Output value */
	int nByte;
	nByte = sqlite3Fts3ReadInt(*pp, &nInt);
	if( nInt>MAX_NPREFIX ){
	nInt = 0;
	}
	if( nByte==0 ){
	return SQLITE_ERROR;
	}
	*pnOut = nInt;
	*pp += nByte;
	return SQLITE_OK;
	}

	/*
	** This function is called to allocate an array of Fts3Index structures
	** representing the indexes maintained by the current FTS table. FTS tables
	** always maintain the main "terms" index, but may also maintain one or
	** more "prefix" indexes, depending on the value of the "prefix=" parameter
	** (if any) specified as part of the CREATE VIRTUAL TABLE statement.
	**
	** Argument zParam is passed the value of the "prefix=" option if one was
	** specified, or NULL otherwise.
	**
	** If no error occurs, SQLITE_OK is returned and *apIndex set to point to
	** the allocated array. *pnIndex is set to the number of elements in the
	** array. If an error does occur, an SQLite error code is returned.
	**
	** Regardless of whether or not an error is returned, it is the responsibility
	** of the caller to call sqlite3_free() on the output array to free it.
	*/
	static int fts3PrefixParameter(
	const char zParam, / ABC in prefix=ABC parameter to parse */
	int pnIndex, / OUT: size of apIndex[] array /
	struct Fts3Index *apIndex / OUT: Array of indexes for this table */
	){
	struct Fts3Index aIndex; / Allocated array */
	int nIndex = 1; /* Number of entries in array */

	if( zParam && zParam[0] ){
	const char *p;
	nIndex++;
	for(p=zParam; *p; p++){
	if( *p==',' ) nIndex++;
	}
	}

	aIndex = sqlite3_malloc64(sizeof(struct Fts3Index) * nIndex);
	*apIndex = aIndex;
	if( !aIndex ){
	return SQLITE_NOMEM;
	}

	memset(aIndex, 0, sizeof(struct Fts3Index) * nIndex);
	if( zParam ){
	const char *p = zParam;
	int i;
	for(i=1; i<nIndex; i++){
	int nPrefix = 0;
	if( fts3GobbleInt(&p, &nPrefix) ) return SQLITE_ERROR;
	assert( nPrefix>=0 );
	if( nPrefix==0 ){
	nIndex--;
	i--;
	}else{
	aIndex[i].nPrefix = nPrefix;
	}
	p++;
	}
	}

	*pnIndex = nIndex;
	return SQLITE_OK;
	}

	/*
	** This function is called when initializing an FTS4 table that uses the
	** content=xxx option. It determines the number of and names of the columns
	** of the new FTS4 table.
	**
	** The third argument passed to this function is the value passed to the
	** config=xxx option (i.e. "xxx"). This function queries the database for
	** a table of that name. If found, the output variables are populated
	** as follows:
	**
	** *pnCol: Set to the number of columns table xxx has,
	**
	** *pnStr: Set to the total amount of space required to store a copy
	** of each columns name, including the nul-terminator.
	**
	** pazCol: Set to point to an array of pnCol strings. Each string is
	** the name of the corresponding column in table xxx. The array
	** and its contents are allocated using a single allocation. It
	** is the responsibility of the caller to free this allocation
	** by eventually passing the *pazCol value to sqlite3_free().
	**
	** If the table cannot be found, an error code is returned and the output
	** variables are undefined. Or, if an OOM is encountered, SQLITE_NOMEM is
	** returned (and the output variables are undefined).
	*/
	static int fts3ContentColumns(
	sqlite3 db, / Database handle */
	const char zDb, / Name of db (i.e. "main", "temp" etc.) */
	const char zTbl, / Name of content table */
	const char **pazCol, / OUT: Malloc'd array of column names */
	int pnCol, / OUT: Size of array pazCol /
	int pnStr, / OUT: Bytes of string content */
	char *pzErr / OUT: error message */
	){
	int rc = SQLITE_OK; /* Return code */
	char zSql; / "SELECT " statement on zTbl /
	sqlite3_stmt pStmt = 0; / Compiled version of zSql */

	zSql = sqlite3_mprintf("SELECT * FROM %Q.%Q", zDb, zTbl);
	if( !zSql ){
	rc = SQLITE_NOMEM;
	}else{
	rc = sqlite3_prepare(db, zSql, -1, &pStmt, 0);
	if( rc!=SQLITE_OK ){
	sqlite3Fts3ErrMsg(pzErr, "%s", sqlite3_errmsg(db));
	}
	}
	sqlite3_free(zSql);

	if( rc==SQLITE_OK ){
	const char *azCol; / Output array */
	sqlite3_int64 nStr = 0; /* Size of all column names (incl. 0x00) */
	int nCol; /* Number of table columns */
	int i; /* Used to iterate through columns */

	/* Loop through the returned columns. Set nStr to the number of bytes of
	** space required to store a copy of each column name, including the
	** nul-terminator byte. */
	nCol = sqlite3_column_count(pStmt);
	for(i=0; i<nCol; i++){
	const char *zCol = sqlite3_column_name(pStmt, i);
	nStr += strlen(zCol) + 1;
	}

	/* Allocate and populate the array to return. */
	azCol = (const char *)sqlite3_malloc64(sizeof(char ) * nCol + nStr);
	if( azCol==0 ){
	rc = SQLITE_NOMEM;
	}else{
	char p = (char )&azCol[nCol];
	for(i=0; i<nCol; i++){
	const char *zCol = sqlite3_column_name(pStmt, i);
	int n = (int)strlen(zCol)+1;
	memcpy(p, zCol, n);
	azCol[i] = p;
	p += n;
	}
	}
	sqlite3_finalize(pStmt);

	/* Set the output variables. */
	*pnCol = nCol;
	*pnStr = nStr;
	*pazCol = azCol;
	}

	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 ("fts3" or "fts4")
	** argv[1] -> database name
	** argv[2] -> table name
	** argv[...] -> "column name" and other module argument fields.
	*/
	static int fts3InitVtab(
	int isCreate, /* 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 */
	){
	Fts3Hash pHash = &((Fts3HashWrapper)pAux)->hash;
	Fts3Table p = 0; / Pointer to allocated vtab */
	int rc = SQLITE_OK; /* Return code */
	int i; /* Iterator variable */
	sqlite3_int64 nByte; /* Size of allocation used for p /
	int iCol; /* Column index */
	int nString = 0; /* Bytes required to hold all column names */
	int nCol = 0; /* Number of columns in the FTS table */
	char zCsr; / Space for holding column names */
	int nDb; /* Bytes required to hold database name */
	int nName; /* Bytes required to hold table name */
	int isFts4 = (argv[0][3]=='4'); /* True for FTS4, false for FTS3 */
	const char *aCol; / Array of column names */
	sqlite3_tokenizer pTokenizer = 0; / Tokenizer for this table */

	int nIndex = 0; /* Size of aIndex[] array */
	struct Fts3Index aIndex = 0; / Array of indexes for this table */

	/* The results of parsing supported FTS4 key=value options: */
	int bNoDocsize = 0; /* True to omit %_docsize table */
	int bDescIdx = 0; /* True to store descending indexes */
	char zPrefix = 0; / Prefix parameter value (or NULL) */
	char zCompress = 0; / compress=? parameter (or NULL) */
	char zUncompress = 0; / uncompress=? parameter (or NULL) */
	char zContent = 0; / content=? parameter (or NULL) */
	char zLanguageid = 0; / languageid=? parameter (or NULL) */
	char *azNotindexed = 0; / The set of notindexed= columns */
	int nNotindexed = 0; /* Size of azNotindexed[] array */

	assert( strlen(argv[0])==4 );
	assert( (sqlite3_strnicmp(argv[0], "fts4", 4)==0 && isFts4)
	\|\| (sqlite3_strnicmp(argv[0], "fts3", 4)==0 && !isFts4)
	);

	nDb = (int)strlen(argv[1]) + 1;
	nName = (int)strlen(argv[2]) + 1;

	nByte = sizeof(const char ) (argc-2);
	aCol = (const char **)sqlite3_malloc64(nByte);
	if( aCol ){
	memset((void*)aCol, 0, nByte);
	azNotindexed = (char **)sqlite3_malloc64(nByte);
	}
	if( azNotindexed ){
	memset(azNotindexed, 0, nByte);
	}
	if( !aCol \|\| !azNotindexed ){
	rc = SQLITE_NOMEM;
	goto fts3_init_out;
	}

	/* Loop through all of the arguments passed by the user to the FTS3/4
	** module (i.e. all the column names and special arguments). This loop
	** does the following:
	**
	** + Figures out the number of columns the FTSX table will have, and
	** the number of bytes of space that must be allocated to store copies
	** of the column names.
	**
	** + If there is a tokenizer specification included in the arguments,
	** initializes the tokenizer pTokenizer.
	*/
	for(i=3; rc==SQLITE_OK && i<argc; i++){
	char const *z = argv[i];
	int nKey;
	char *zVal;

	/* Check if this is a tokenizer specification */
	if( !pTokenizer
	&& strlen(z)>8
	&& 0==sqlite3_strnicmp(z, "tokenize", 8)
	&& 0==sqlite3Fts3IsIdChar(z[8])
	){
	rc = sqlite3Fts3InitTokenizer(pHash, &z[9], &pTokenizer, pzErr);
	}

	/* Check if it is an FTS4 special argument. */
	else if( isFts4 && fts3IsSpecialColumn(z, &nKey, &zVal) ){
	struct Fts4Option {
	const char *zOpt;
	int nOpt;
	} aFts4Opt[] = {
	{ "matchinfo", 9 }, /* 0 -> MATCHINFO */
	{ "prefix", 6 }, /* 1 -> PREFIX */
	{ "compress", 8 }, /* 2 -> COMPRESS */
	{ "uncompress", 10 }, /* 3 -> UNCOMPRESS */
	{ "order", 5 }, /* 4 -> ORDER */
	{ "content", 7 }, /* 5 -> CONTENT */
	{ "languageid", 10 }, /* 6 -> LANGUAGEID */
	{ "notindexed", 10 } /* 7 -> NOTINDEXED */
	};

	int iOpt;
	if( !zVal ){
	rc = SQLITE_NOMEM;
	}else{
	for(iOpt=0; iOpt<SizeofArray(aFts4Opt); iOpt++){
	struct Fts4Option *pOp = &aFts4Opt[iOpt];
	if( nKey==pOp->nOpt && !sqlite3_strnicmp(z, pOp->zOpt, pOp->nOpt) ){
	break;
	}
	}
	switch( iOpt ){
	case 0: /* MATCHINFO */
	if( strlen(zVal)!=4 \|\| sqlite3_strnicmp(zVal, "fts3", 4) ){
	sqlite3Fts3ErrMsg(pzErr, "unrecognized matchinfo: %s", zVal);
	rc = SQLITE_ERROR;
	}
	bNoDocsize = 1;
	break;

	case 1: /* PREFIX */
	sqlite3_free(zPrefix);
	zPrefix = zVal;
	zVal = 0;
	break;

	case 2: /* COMPRESS */
	sqlite3_free(zCompress);
	zCompress = zVal;
	zVal = 0;
	break;

	case 3: /* UNCOMPRESS */
	sqlite3_free(zUncompress);
	zUncompress = zVal;
	zVal = 0;
	break;

	case 4: /* ORDER */
	if( (strlen(zVal)!=3 \|\| sqlite3_strnicmp(zVal, "asc", 3))
	&& (strlen(zVal)!=4 \|\| sqlite3_strnicmp(zVal, "desc", 4))
	){
	sqlite3Fts3ErrMsg(pzErr, "unrecognized order: %s", zVal);
	rc = SQLITE_ERROR;
	}
	bDescIdx = (zVal[0]=='d' \|\| zVal[0]=='D');
	break;

	case 5: /* CONTENT */
	sqlite3_free(zContent);
	zContent = zVal;
	zVal = 0;
	break;

	case 6: /* LANGUAGEID */
	assert( iOpt==6 );
	sqlite3_free(zLanguageid);
	zLanguageid = zVal;
	zVal = 0;
	break;

	case 7: /* NOTINDEXED */
	azNotindexed[nNotindexed++] = zVal;
	zVal = 0;
	break;

	default:
	assert( iOpt==SizeofArray(aFts4Opt) );
	sqlite3Fts3ErrMsg(pzErr, "unrecognized parameter: %s", z);
	rc = SQLITE_ERROR;
	break;
	}
	sqlite3_free(zVal);
	}
	}

	/* Otherwise, the argument is a column name. */
	else {
	nString += (int)(strlen(z) + 1);
	aCol[nCol++] = z;
	}
	}

	/* If a content=xxx option was specified, the following:
	**
	** 1. Ignore any compress= and uncompress= options.
	**
	** 2. If no column names were specified as part of the CREATE VIRTUAL
	** TABLE statement, use all columns from the content table.
	*/
	if( rc==SQLITE_OK && zContent ){
	sqlite3_free(zCompress);
	sqlite3_free(zUncompress);
	zCompress = 0;
	zUncompress = 0;
	if( nCol==0 ){
	sqlite3_free((void*)aCol);
	aCol = 0;
	rc = fts3ContentColumns(db, argv[1], zContent,&aCol,&nCol,&nString,pzErr);

	/* If a languageid= option was specified, remove the language id
	** column from the aCol[] array. */
	if( rc==SQLITE_OK && zLanguageid ){
	int j;
	for(j=0; j<nCol; j++){
	if( sqlite3_stricmp(zLanguageid, aCol[j])==0 ){
	int k;
	for(k=j; k<nCol; k++) aCol[k] = aCol[k+1];
	nCol--;
	break;
	}
	}
	}
	}
	}
	if( rc!=SQLITE_OK ) goto fts3_init_out;

	if( nCol==0 ){
	assert( nString==0 );
	aCol[0] = "content";
	nString = 8;
	nCol = 1;
	}

	if( pTokenizer==0 ){
	rc = sqlite3Fts3InitTokenizer(pHash, "simple", &pTokenizer, pzErr);
	if( rc!=SQLITE_OK ) goto fts3_init_out;
	}
	assert( pTokenizer );

	rc = fts3PrefixParameter(zPrefix, &nIndex, &aIndex);
	if( rc==SQLITE_ERROR ){
	assert( zPrefix );
	sqlite3Fts3ErrMsg(pzErr, "error parsing prefix parameter: %s", zPrefix);
	}
	if( rc!=SQLITE_OK ) goto fts3_init_out;

	/* Allocate and populate the Fts3Table structure. */
	nByte = sizeof(Fts3Table) + /* Fts3Table */
	nCol * sizeof(char ) + / azColumn */
	nIndex * sizeof(struct Fts3Index) + /* aIndex */
	nCol * sizeof(u8) + /* abNotindexed */
	nName + /* zName */
	nDb + /* zDb */
	nString; /* Space for azColumn strings */
	p = (Fts3Table*)sqlite3_malloc64(nByte);
	if( p==0 ){
	rc = SQLITE_NOMEM;
	goto fts3_init_out;
	}
	memset(p, 0, nByte);
	p->db = db;
	p->nColumn = nCol;
	p->nPendingData = 0;
	p->azColumn = (char **)&p[1];
	p->pTokenizer = pTokenizer;
	p->nMaxPendingData = FTS3_MAX_PENDING_DATA;
	p->bHasDocsize = (isFts4 && bNoDocsize==0);
	p->bHasStat = (u8)isFts4;
	p->bFts4 = (u8)isFts4;
	p->bDescIdx = (u8)bDescIdx;
	p->nAutoincrmerge = 0xff; /* 0xff means setting unknown */
	p->zContentTbl = zContent;
	p->zLanguageid = zLanguageid;
	zContent = 0;
	zLanguageid = 0;
	TESTONLY( p->inTransaction = -1 );
	TESTONLY( p->mxSavepoint = -1 );

	p->aIndex = (struct Fts3Index *)&p->azColumn[nCol];
	memcpy(p->aIndex, aIndex, sizeof(struct Fts3Index) * nIndex);
	p->nIndex = nIndex;
	for(i=0; i<nIndex; i++){
	fts3HashInit(&p->aIndex[i].hPending, FTS3_HASH_STRING, 1);
	}
	p->abNotindexed = (u8 *)&p->aIndex[nIndex];

	/* Fill in the zName and zDb fields of the vtab structure. */
	zCsr = (char *)&p->abNotindexed[nCol];
	p->zName = zCsr;
	memcpy(zCsr, argv[2], nName);
	zCsr += nName;
	p->zDb = zCsr;
	memcpy(zCsr, argv[1], nDb);
	zCsr += nDb;

	/* Fill in the azColumn array */
	for(iCol=0; iCol<nCol; iCol++){
	char *z;
	int n = 0;
	z = (char *)sqlite3Fts3NextToken(aCol[iCol], &n);
	if( n>0 ){
	memcpy(zCsr, z, n);
	}
	zCsr[n] = '\0';
	sqlite3Fts3Dequote(zCsr);
	p->azColumn[iCol] = zCsr;
	zCsr += n+1;
	assert( zCsr <= &((char *)p)[nByte] );
	}

	/* Fill in the abNotindexed array */
	for(iCol=0; iCol<nCol; iCol++){
	int n = (int)strlen(p->azColumn[iCol]);
	for(i=0; i<nNotindexed; i++){
	char *zNot = azNotindexed[i];
	if( zNot && n==(int)strlen(zNot)
	&& 0==sqlite3_strnicmp(p->azColumn[iCol], zNot, n)
	){
	p->abNotindexed[iCol] = 1;
	sqlite3_free(zNot);
	azNotindexed[i] = 0;
	}
	}
	}
	for(i=0; i<nNotindexed; i++){
	if( azNotindexed[i] ){
	sqlite3Fts3ErrMsg(pzErr, "no such column: %s", azNotindexed[i]);
	rc = SQLITE_ERROR;
	}
	}

	if( rc==SQLITE_OK && (zCompress==0)!=(zUncompress==0) ){
	char const *zMiss = (zCompress==0 ? "compress" : "uncompress");
	rc = SQLITE_ERROR;
	sqlite3Fts3ErrMsg(pzErr, "missing %s parameter in fts4 constructor", zMiss);
	}
	p->zReadExprlist = fts3ReadExprList(p, zUncompress, &rc);
	p->zWriteExprlist = fts3WriteExprList(p, zCompress, &rc);
	if( rc!=SQLITE_OK ) goto fts3_init_out;

	/* If this is an xCreate call, create the underlying tables in the
	** database. TODO: For xConnect(), it could verify that said tables exist.
	*/
	if( isCreate ){
	rc = fts3CreateTables(p);
	}

	/* Check to see if a legacy fts3 table has been "upgraded" by the
	** addition of a %_stat table so that it can use incremental merge.
	*/
	if( !isFts4 && !isCreate ){
	p->bHasStat = 2;
	}

	/* Figure out the page-size for the database. This is required in order to
	** estimate the cost of loading large doclists from the database. */
	fts3DatabasePageSize(&rc, p);
	p->nNodeSize = p->nPgsz-35;

	#if defined(SQLITE_DEBUG)\|\|defined(SQLITE_TEST)
	p->nMergeCount = FTS3_MERGE_COUNT;
	#endif

	/* Declare the table schema to SQLite. */
	fts3DeclareVtab(&rc, p);

	fts3_init_out:
	sqlite3_free(zPrefix);
	sqlite3_free(aIndex);
	sqlite3_free(zCompress);
	sqlite3_free(zUncompress);
	sqlite3_free(zContent);
	sqlite3_free(zLanguageid);
	for(i=0; i<nNotindexed; i++) sqlite3_free(azNotindexed[i]);
	sqlite3_free((void *)aCol);
	sqlite3_free((void *)azNotindexed);
	if( rc!=SQLITE_OK ){
	if( p ){
	fts3DisconnectMethod((sqlite3_vtab *)p);
	}else if( pTokenizer ){
	pTokenizer->pModule->xDestroy(pTokenizer);
	}
	}else{
	assert( p->pSegments==0 );
	*ppVTab = &p->base;
	}
	return rc;
	}

	/*
	** The xConnect() and xCreate() methods for the virtual table. All the
	** work is done in function fts3InitVtab().
	*/
	static int fts3ConnectMethod(
	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 fts3InitVtab(0, db, pAux, argc, argv, ppVtab, pzErr);
	}
	static int fts3CreateMethod(
	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 fts3InitVtab(1, db, pAux, argc, argv, ppVtab, pzErr);
	}

	/*
	** Set the pIdxInfo->estimatedRows variable to nRow. Unless this
	** extension is currently being used by a version of SQLite too old to
	** support estimatedRows. In that case this function is a no-op.
	*/
	static void fts3SetEstimatedRows(sqlite3_index_info *pIdxInfo, i64 nRow){
	#if SQLITE_VERSION_NUMBER>=3008002
	if( sqlite3_libversion_number()>=3008002 ){
	pIdxInfo->estimatedRows = nRow;
	}
	#endif
	}

	/*
	** 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 fts3SetUniqueFlag(sqlite3_index_info *pIdxInfo){
	#if SQLITE_VERSION_NUMBER>=3008012
	if( sqlite3_libversion_number()>=3008012 ){
	pIdxInfo->idxFlags \|= SQLITE_INDEX_SCAN_UNIQUE;
	}
	#endif
	}

	/*
	** Implementation of the xBestIndex method for FTS3 tables. There
	** are three possible strategies, in order of preference:
	**
	** 1. Direct lookup by rowid or docid.
	** 2. Full-text search using a MATCH operator on a non-docid column.
	** 3. Linear scan of %_content table.
	*/
	static int fts3BestIndexMethod(sqlite3_vtab pVTab, sqlite3_index_info pInfo){
	Fts3Table p = (Fts3Table )pVTab;
	int i; /* Iterator variable */
	int iCons = -1; /* Index of constraint to use */

	int iLangidCons = -1; /* Index of langid=x constraint, if present */
	int iDocidGe = -1; /* Index of docid>=x constraint, if present */
	int iDocidLe = -1; /* Index of docid<=x constraint, if present */
	int iIdx;

	if( p->bLock ){
	return SQLITE_ERROR;
	}

	/* By default use a full table scan. This is an expensive option,
	** so search through the constraints to see if a more efficient
	** strategy is possible.
	*/
	pInfo->idxNum = FTS3_FULLSCAN_SEARCH;
	pInfo->estimatedCost = 5000000;
	for(i=0; i<pInfo->nConstraint; i++){
	int bDocid; /* True if this constraint is on docid */
	struct sqlite3_index_constraint *pCons = &pInfo->aConstraint[i];
	if( pCons->usable==0 ){
	if( pCons->op==SQLITE_INDEX_CONSTRAINT_MATCH ){
	/* There exists an unusable MATCH constraint. This means that if
	** the planner does elect to use the results of this call as part
	** of the overall query plan the user will see an "unable to use
	** function MATCH in the requested context" error. To discourage
	** this, return a very high cost here. */
	pInfo->idxNum = FTS3_FULLSCAN_SEARCH;
	pInfo->estimatedCost = 1e50;
	fts3SetEstimatedRows(pInfo, ((sqlite3_int64)1) << 50);
	return SQLITE_OK;
	}
	continue;
	}

	bDocid = (pCons->iColumn<0 \|\| pCons->iColumn==p->nColumn+1);

	/* A direct lookup on the rowid or docid column. Assign a cost of 1.0. */
	if( iCons<0 && pCons->op==SQLITE_INDEX_CONSTRAINT_EQ && bDocid ){
	pInfo->idxNum = FTS3_DOCID_SEARCH;
	pInfo->estimatedCost = 1.0;
	iCons = i;
	}

	/* A MATCH constraint. Use a full-text search.
	**
	** If there is more than one MATCH constraint available, use the first
	** one encountered. If there is both a MATCH constraint and a direct
	** rowid/docid lookup, prefer the MATCH strategy. This is done even
	** though the rowid/docid lookup is faster than a MATCH query, selecting
	** it would lead to an "unable to use function MATCH in the requested
	** context" error.
	*/
	if( pCons->op==SQLITE_INDEX_CONSTRAINT_MATCH
	&& pCons->iColumn>=0 && pCons->iColumn<=p->nColumn
	){
	pInfo->idxNum = FTS3_FULLTEXT_SEARCH + pCons->iColumn;
	pInfo->estimatedCost = 2.0;
	iCons = i;
	}

	/* Equality constraint on the langid column */
	if( pCons->op==SQLITE_INDEX_CONSTRAINT_EQ
	&& pCons->iColumn==p->nColumn + 2
	){
	iLangidCons = i;
	}

	if( bDocid ){
	switch( pCons->op ){
	case SQLITE_INDEX_CONSTRAINT_GE:
	case SQLITE_INDEX_CONSTRAINT_GT:
	iDocidGe = i;
	break;

	case SQLITE_INDEX_CONSTRAINT_LE:
	case SQLITE_INDEX_CONSTRAINT_LT:
	iDocidLe = i;
	break;
	}
	}
	}

	/* If using a docid=? or rowid=? strategy, set the UNIQUE flag. */
	if( pInfo->idxNum==FTS3_DOCID_SEARCH ) fts3SetUniqueFlag(pInfo);

	iIdx = 1;
	if( iCons>=0 ){
	pInfo->aConstraintUsage[iCons].argvIndex = iIdx++;
	pInfo->aConstraintUsage[iCons].omit = 1;
	}
	if( iLangidCons>=0 ){
	pInfo->idxNum \|= FTS3_HAVE_LANGID;
	pInfo->aConstraintUsage[iLangidCons].argvIndex = iIdx++;
	}
	if( iDocidGe>=0 ){
	pInfo->idxNum \|= FTS3_HAVE_DOCID_GE;
	pInfo->aConstraintUsage[iDocidGe].argvIndex = iIdx++;
	}
	if( iDocidLe>=0 ){
	pInfo->idxNum \|= FTS3_HAVE_DOCID_LE;
	pInfo->aConstraintUsage[iDocidLe].argvIndex = iIdx++;
	}

	/* Regardless of the strategy selected, FTS can deliver rows in rowid (or
	** docid) order. Both ascending and descending are possible.
	*/
	if( pInfo->nOrderBy==1 ){
	struct sqlite3_index_orderby *pOrder = &pInfo->aOrderBy[0];
	if( pOrder->iColumn<0 \|\| pOrder->iColumn==p->nColumn+1 ){
	if( pOrder->desc ){
	pInfo->idxStr = "DESC";
	}else{
	pInfo->idxStr = "ASC";
	}
	pInfo->orderByConsumed = 1;
	}
	}

	assert( p->pSegments==0 );
	return SQLITE_OK;
	}

	/*
	** Implementation of xOpen method.
	*/
	static int fts3OpenMethod(sqlite3_vtab pVTab, sqlite3_vtab_cursor *ppCsr){
	sqlite3_vtab_cursor pCsr; / Allocated cursor */

	UNUSED_PARAMETER(pVTab);

	/* Allocate a buffer large enough for an Fts3Cursor structure. If the
	** allocation succeeds, zero it and return SQLITE_OK. Otherwise,
	** if the allocation fails, return SQLITE_NOMEM.
	*/
	ppCsr = pCsr = (sqlite3_vtab_cursor )sqlite3_malloc(sizeof(Fts3Cursor));
	if( !pCsr ){
	return SQLITE_NOMEM;
	}
	memset(pCsr, 0, sizeof(Fts3Cursor));
	return SQLITE_OK;
	}

	/*
	** Finalize the statement handle at pCsr->pStmt.
	**
	** Or, if that statement handle is one created by fts3CursorSeekStmt(),
	** and the Fts3Table.pSeekStmt slot is currently NULL, save the statement
	** pointer there instead of finalizing it.
	*/
	static void fts3CursorFinalizeStmt(Fts3Cursor *pCsr){
	if( pCsr->bSeekStmt ){
	Fts3Table p = (Fts3Table )pCsr->base.pVtab;
	if( p->pSeekStmt==0 ){
	p->pSeekStmt = pCsr->pStmt;
	sqlite3_reset(pCsr->pStmt);
	pCsr->pStmt = 0;
	}
	pCsr->bSeekStmt = 0;
	}
	sqlite3_finalize(pCsr->pStmt);
	}

	/*
	** Free all resources currently held by the cursor passed as the only
	** argument.
	*/
	static void fts3ClearCursor(Fts3Cursor *pCsr){
	fts3CursorFinalizeStmt(pCsr);
	sqlite3Fts3FreeDeferredTokens(pCsr);
	sqlite3_free(pCsr->aDoclist);
	sqlite3Fts3MIBufferFree(pCsr->pMIBuffer);
	sqlite3Fts3ExprFree(pCsr->pExpr);
	memset(&(&pCsr->base)[1], 0, sizeof(Fts3Cursor)-sizeof(sqlite3_vtab_cursor));
	}

	/*
	** Close the cursor. For additional information see the documentation
	** on the xClose method of the virtual table interface.
	*/
	static int fts3CloseMethod(sqlite3_vtab_cursor *pCursor){
	Fts3Cursor pCsr = (Fts3Cursor )pCursor;
	assert( ((Fts3Table *)pCsr->base.pVtab)->pSegments==0 );
	fts3ClearCursor(pCsr);
	assert( ((Fts3Table *)pCsr->base.pVtab)->pSegments==0 );
	sqlite3_free(pCsr);
	return SQLITE_OK;
	}

	/*
	** If pCsr->pStmt has not been prepared (i.e. if pCsr->pStmt==0), then
	** compose and prepare an SQL statement of the form:
	**
	** "SELECT <columns> FROM %_content WHERE rowid = ?"
	**
	** (or the equivalent for a content=xxx table) and set pCsr->pStmt to
	** it. If an error occurs, return an SQLite error code.
	*/
	static int fts3CursorSeekStmt(Fts3Cursor *pCsr){
	int rc = SQLITE_OK;
	if( pCsr->pStmt==0 ){
	Fts3Table p = (Fts3Table )pCsr->base.pVtab;
	char *zSql;
	if( p->pSeekStmt ){
	pCsr->pStmt = p->pSeekStmt;
	p->pSeekStmt = 0;
	}else{
	zSql = sqlite3_mprintf("SELECT %s WHERE rowid = ?", p->zReadExprlist);
	if( !zSql ) return SQLITE_NOMEM;
	p->bLock++;
	rc = sqlite3_prepare_v3(
	p->db, zSql,-1,SQLITE_PREPARE_PERSISTENT,&pCsr->pStmt,0
	);
	p->bLock--;
	sqlite3_free(zSql);
	}
	if( rc==SQLITE_OK ) pCsr->bSeekStmt = 1;
	}
	return rc;
	}

	/*
	** Position the pCsr->pStmt statement so that it is on the row
	** of the %_content table that contains the last match. Return
	** SQLITE_OK on success.
	*/
	static int fts3CursorSeek(sqlite3_context pContext, Fts3Cursor pCsr){
	int rc = SQLITE_OK;
	if( pCsr->isRequireSeek ){
	rc = fts3CursorSeekStmt(pCsr);
	if( rc==SQLITE_OK ){
	Fts3Table pTab = (Fts3Table)pCsr->base.pVtab;
	pTab->bLock++;
	sqlite3_bind_int64(pCsr->pStmt, 1, pCsr->iPrevId);
	pCsr->isRequireSeek = 0;
	if( SQLITE_ROW==sqlite3_step(pCsr->pStmt) ){
	pTab->bLock--;
	return SQLITE_OK;
	}else{
	pTab->bLock--;
	rc = sqlite3_reset(pCsr->pStmt);
	if( rc==SQLITE_OK && ((Fts3Table *)pCsr->base.pVtab)->zContentTbl==0 ){
	/* If no row was found and no error has occurred, then the %_content
	** table is missing a row that is present in the full-text index.
	** The data structures are corrupt. */
	rc = FTS_CORRUPT_VTAB;
	pCsr->isEof = 1;
	}
	}
	}
	}

	if( rc!=SQLITE_OK && pContext ){
	sqlite3_result_error_code(pContext, rc);
	}
	return rc;
	}

	/*
	** This function is used to process a single interior node when searching
	** a b-tree for a term or term prefix. The node data is passed to this
	** function via the zNode/nNode parameters. The term to search for is
	** passed in zTerm/nTerm.
	**
	** If piFirst is not NULL, then this function sets *piFirst to the blockid
	** of the child node that heads the sub-tree that may contain the term.
	**
	** If piLast is not NULL, then *piLast is set to the right-most child node
	** that heads a sub-tree that may contain a term for which zTerm/nTerm is
	** a prefix.
	**
	** If an OOM error occurs, SQLITE_NOMEM is returned. Otherwise, SQLITE_OK.
	*/
	static int fts3ScanInteriorNode(
	const char zTerm, / Term to select leaves for */
	int nTerm, /* Size of term zTerm in bytes */
	const char zNode, / Buffer containing segment interior node */
	int nNode, /* Size of buffer at zNode */
	sqlite3_int64 piFirst, / OUT: Selected child node */
	sqlite3_int64 piLast / OUT: Selected child node */
	){
	int rc = SQLITE_OK; /* Return code */
	const char zCsr = zNode; / Cursor to iterate through node */
	const char zEnd = &zCsr[nNode];/ End of interior node buffer */
	char zBuffer = 0; / Buffer to load terms into */
	i64 nAlloc = 0; /* Size of allocated buffer */
	int isFirstTerm = 1; /* True when processing first term on page */
	u64 iChild; /* Block id of child node to descend to */
	int nBuffer = 0; /* Total term size */

	/* Skip over the 'height' varint that occurs at the start of every
	** interior node. Then load the blockid of the left-child of the b-tree
	** node into variable iChild.
	**
	** Even if the data structure on disk is corrupted, this (reading two
	** varints from the buffer) does not risk an overread. If zNode is a
	** root node, then the buffer comes from a SELECT statement. SQLite does
	** not make this guarantee explicitly, but in practice there are always
	** either more than 20 bytes of allocated space following the nNode bytes of
	** contents, or two zero bytes. Or, if the node is read from the %_segments
	** table, then there are always 20 bytes of zeroed padding following the
	** nNode bytes of content (see sqlite3Fts3ReadBlock() for details).
	*/
	zCsr += sqlite3Fts3GetVarintU(zCsr, &iChild);
	zCsr += sqlite3Fts3GetVarintU(zCsr, &iChild);
	if( zCsr>zEnd ){
	return FTS_CORRUPT_VTAB;
	}

	while( zCsr<zEnd && (piFirst \|\| piLast) ){
	int cmp; /* memcmp() result */
	int nSuffix; /* Size of term suffix */
	int nPrefix = 0; /* Size of term prefix */

	/* Load the next term on the node into zBuffer. Use realloc() to expand
	** the size of zBuffer if required. */
	if( !isFirstTerm ){
	zCsr += fts3GetVarint32(zCsr, &nPrefix);
	if( nPrefix>nBuffer ){
	rc = FTS_CORRUPT_VTAB;
	goto finish_scan;
	}
	}
	isFirstTerm = 0;
	zCsr += fts3GetVarint32(zCsr, &nSuffix);

	assert( nPrefix>=0 && nSuffix>=0 );
	if( nPrefix>zCsr-zNode \|\| nSuffix>zEnd-zCsr \|\| nSuffix==0 ){
	rc = FTS_CORRUPT_VTAB;
	goto finish_scan;
	}
	if( (i64)nPrefix+nSuffix>nAlloc ){
	char *zNew;
	nAlloc = ((i64)nPrefix+nSuffix) * 2;
	zNew = (char *)sqlite3_realloc64(zBuffer, nAlloc);
	if( !zNew ){
	rc = SQLITE_NOMEM;
	goto finish_scan;
	}
	zBuffer = zNew;
	}
	assert( zBuffer );
	memcpy(&zBuffer[nPrefix], zCsr, nSuffix);
	nBuffer = nPrefix + nSuffix;
	zCsr += nSuffix;

	/* Compare the term we are searching for with the term just loaded from
	** the interior node. If the specified term is greater than or equal
	** to the term from the interior node, then all terms on the sub-tree
	** headed by node iChild are smaller than zTerm. No need to search
	** iChild.
	**
	** If the interior node term is larger than the specified term, then
	** the tree headed by iChild may contain the specified term.
	*/
	cmp = memcmp(zTerm, zBuffer, (nBuffer>nTerm ? nTerm : nBuffer));
	if( piFirst && (cmp<0 \|\| (cmp==0 && nBuffer>nTerm)) ){
	*piFirst = (i64)iChild;
	piFirst = 0;
	}

	if( piLast && cmp<0 ){
	*piLast = (i64)iChild;
	piLast = 0;
	}

	iChild++;
	};

	if( piFirst ) *piFirst = (i64)iChild;
	if( piLast ) *piLast = (i64)iChild;

	finish_scan:
	sqlite3_free(zBuffer);
	return rc;
	}


	/*
	** The buffer pointed to by argument zNode (size nNode bytes) contains an
	** interior node of a b-tree segment. The zTerm buffer (size nTerm bytes)
	** contains a term. This function searches the sub-tree headed by the zNode
	** node for the range of leaf nodes that may contain the specified term
	** or terms for which the specified term is a prefix.
	**
	** If piLeaf is not NULL, then *piLeaf is set to the blockid of the
	** left-most leaf node in the tree that may contain the specified term.
	** If piLeaf2 is not NULL, then *piLeaf2 is set to the blockid of the
	** right-most leaf node that may contain a term for which the specified
	** term is a prefix.
	**
	** It is possible that the range of returned leaf nodes does not contain
	** the specified term or any terms for which it is a prefix. However, if the
	** segment does contain any such terms, they are stored within the identified
	** range. Because this function only inspects interior segment nodes (and
	** never loads leaf nodes into memory), it is not possible to be sure.
	**
	** If an error occurs, an error code other than SQLITE_OK is returned.
	*/
	static int fts3SelectLeaf(
	Fts3Table p, / Virtual table handle */
	const char zTerm, / Term to select leaves for */
	int nTerm, /* Size of term zTerm in bytes */
	const char zNode, / Buffer containing segment interior node */
	int nNode, /* Size of buffer at zNode */
	sqlite3_int64 piLeaf, / Selected leaf node */
	sqlite3_int64 piLeaf2 / Selected leaf node */
	){
	int rc = SQLITE_OK; /* Return code */
	int iHeight; /* Height of this node in tree */

	assert( piLeaf \|\| piLeaf2 );

	fts3GetVarint32(zNode, &iHeight);
	rc = fts3ScanInteriorNode(zTerm, nTerm, zNode, nNode, piLeaf, piLeaf2);
	assert_fts3_nc( !piLeaf2 \|\| !piLeaf \|\| rc!=SQLITE_OK \|\| (piLeaf<=piLeaf2) );

	if( rc==SQLITE_OK && iHeight>1 ){
	char zBlob = 0; / Blob read from %_segments table */
	int nBlob = 0; /* Size of zBlob in bytes */

	if( piLeaf && piLeaf2 && (piLeaf!=piLeaf2) ){
	rc = sqlite3Fts3ReadBlock(p, *piLeaf, &zBlob, &nBlob, 0);
	if( rc==SQLITE_OK ){
	rc = fts3SelectLeaf(p, zTerm, nTerm, zBlob, nBlob, piLeaf, 0);
	}
	sqlite3_free(zBlob);
	piLeaf = 0;
	zBlob = 0;
	}

	if( rc==SQLITE_OK ){
	rc = sqlite3Fts3ReadBlock(p, piLeaf?piLeaf:piLeaf2, &zBlob, &nBlob, 0);
	}
	if( rc==SQLITE_OK ){
	int iNewHeight = 0;
	fts3GetVarint32(zBlob, &iNewHeight);
	if( iNewHeight>=iHeight ){
	rc = FTS_CORRUPT_VTAB;
	}else{
	rc = fts3SelectLeaf(p, zTerm, nTerm, zBlob, nBlob, piLeaf, piLeaf2);
	}
	}
	sqlite3_free(zBlob);
	}

	return rc;
	}

	/*
	** This function is used to create delta-encoded serialized lists of FTS3
	** varints. Each call to this function appends a single varint to a list.
	*/
	static void fts3PutDeltaVarint(
	char *pp, / IN/OUT: Output pointer */
	sqlite3_int64 piPrev, / IN/OUT: Previous value written to list */
	sqlite3_int64 iVal /* Write this value to the list */
	){
	assert_fts3_nc( iVal-piPrev > 0 \|\| (piPrev==0 && iVal==0) );
	pp += sqlite3Fts3PutVarint(pp, iVal-*piPrev);
	*piPrev = iVal;
	}

	/*
	** When this function is called, *ppPoslist is assumed to point to the
	** start of a position-list. After it returns, *ppPoslist points to the
	** first byte after the position-list.
	**
	** A position list is list of positions (delta encoded) and columns for
	** a single document record of a doclist. So, in other words, this
	** routine advances *ppPoslist so that it points to the next docid in
	** the doclist, or to the first byte past the end of the doclist.
	**
	** If pp is not NULL, then the contents of the position list are copied
	** to pp. pp is set to point to the first byte past the last byte copied
	** before this function returns.
	*/
	static void fts3PoslistCopy(char pp, char ppPoslist){
	char pEnd = ppPoslist;
	char c = 0;

	/* The end of a position list is marked by a zero encoded as an FTS3
	** varint. A single POS_END (0) byte. Except, if the 0 byte is preceded by
	** a byte with the 0x80 bit set, then it is not a varint 0, but the tail
	** of some other, multi-byte, value.
	**
	** The following while-loop moves pEnd to point to the first byte that is not
	** immediately preceded by a byte with the 0x80 bit set. Then increments
	** pEnd once more so that it points to the byte immediately following the
	** last byte in the position-list.
	*/
	while( *pEnd \| c ){
	c = *pEnd++ & 0x80;
	testcase( c!=0 && (*pEnd)==0 );
	}
	pEnd++; /* Advance past the POS_END terminator byte */

	if( pp ){
	int n = (int)(pEnd - *ppPoslist);
	char p = pp;
	memcpy(p, *ppPoslist, n);
	p += n;
	*pp = p;
	}
	*ppPoslist = pEnd;
	}

	/*
	** When this function is called, *ppPoslist is assumed to point to the
	** start of a column-list. After it returns, *ppPoslist points to the
	** to the terminator (POS_COLUMN or POS_END) byte of the column-list.
	**
	** A column-list is list of delta-encoded positions for a single column
	** within a single document within a doclist.
	**
	** The column-list is terminated either by a POS_COLUMN varint (1) or
	** a POS_END varint (0). This routine leaves *ppPoslist pointing to
	** the POS_COLUMN or POS_END that terminates the column-list.
	**
	** If pp is not NULL, then the contents of the column-list are copied
	** to pp. pp is set to point to the first byte past the last byte copied
	** before this function returns. The POS_COLUMN or POS_END terminator
	** is not copied into *pp.
	*/
	static void fts3ColumnlistCopy(char pp, char ppPoslist){
	char pEnd = ppPoslist;
	char c = 0;

	/* A column-list is terminated by either a 0x01 or 0x00 byte that is
	** not part of a multi-byte varint.
	*/
	while( 0xFE & (*pEnd \| c) ){
	c = *pEnd++ & 0x80;
	testcase( c!=0 && ((*pEnd)&0xfe)==0 );
	}
	if( pp ){
	int n = (int)(pEnd - *ppPoslist);
	char p = pp;
	memcpy(p, *ppPoslist, n);
	p += n;
	*pp = p;
	}
	*ppPoslist = pEnd;
	}

	/*
	** Value used to signify the end of an position-list. This must be
	** as large or larger than any value that might appear on the
	** position-list, even a position list that has been corrupted.
	*/
	#define POSITION_LIST_END LARGEST_INT64

	/*
	** This function is used to help parse position-lists. When this function is
	** called, *pp may point to the start of the next varint in the position-list
	** being parsed, or it may point to 1 byte past the end of the position-list
	(in which case pp will be a terminator bytes POS_END (0) or
	** (1)).
	**
	** If pp points past the end of the current position-list, set pi to
	** POSITION_LIST_END and return. Otherwise, read the next varint from *pp,
	** increment the current value of pi by the value read, and set pp to
	** point to the next value before returning.
	**
	** Before calling this routine *pi must be initialized to the value of
	** the previous position, or zero if we are reading the first position
	** in the position-list. Because positions are delta-encoded, the value
	** of the previous position is needed in order to compute the value of
	** the next position.
	*/
	static void fts3ReadNextPos(
	char *pp, / IN/OUT: Pointer into position-list buffer */
	sqlite3_int64 pi / IN/OUT: Value read from position-list */
	){
	if( (**pp)&0xFE ){
	int iVal;
	pp += fts3GetVarint32((pp), &iVal);
	*pi += iVal;
	*pi -= 2;
	}else{
	*pi = POSITION_LIST_END;
	}
	}

	/*
	** If parameter iCol is not 0, write an POS_COLUMN (1) byte followed by
	** the value of iCol encoded as a varint to *pp. This will start a new
	** column list.
	**
	** Set *pp to point to the byte just after the last byte written before
	** returning (do not modify it if iCol==0). Return the total number of bytes
	** written (0 if iCol==0).
	*/
	static int fts3PutColNumber(char **pp, int iCol){
	int n = 0; /* Number of bytes written */
	if( iCol ){
	char p = pp; /* Output pointer */
	n = 1 + sqlite3Fts3PutVarint(&p[1], iCol);
	*p = 0x01;
	*pp = &p[n];
	}
	return n;
	}

	/*
	** Compute the union of two position lists. The output written
	** into pp contains all positions of both pp1 and *pp2 in sorted
	** order and with any duplicates removed. All pointers are
	** updated appropriately. The caller is responsible for insuring
	** that there is enough space in *pp to hold the complete output.
	*/
	static int fts3PoslistMerge(
	char *pp, / Output buffer */
	char *pp1, / Left input list */
	char *pp2 / Right input list */
	){
	char p = pp;
	char p1 = pp1;
	char p2 = pp2;

	while( p1 \|\| p2 ){
	int iCol1; /* The current column index in pp1 */
	int iCol2; /* The current column index in pp2 */

	if( *p1==POS_COLUMN ){
	fts3GetVarint32(&p1[1], &iCol1);
	if( iCol1==0 ) return FTS_CORRUPT_VTAB;
	}
	else if( *p1==POS_END ) iCol1 = 0x7fffffff;
	else iCol1 = 0;

	if( *p2==POS_COLUMN ){
	fts3GetVarint32(&p2[1], &iCol2);
	if( iCol2==0 ) return FTS_CORRUPT_VTAB;
	}
	else if( *p2==POS_END ) iCol2 = 0x7fffffff;
	else iCol2 = 0;

	if( iCol1==iCol2 ){
	sqlite3_int64 i1 = 0; /* Last position from pp1 */
	sqlite3_int64 i2 = 0; /* Last position from pp2 */
	sqlite3_int64 iPrev = 0;
	int n = fts3PutColNumber(&p, iCol1);
	p1 += n;
	p2 += n;

	/* At this point, both p1 and p2 point to the start of column-lists
	** for the same column (the column with index iCol1 and iCol2).
	** A column-list is a list of non-negative delta-encoded varints, each
	** incremented by 2 before being stored. Each list is terminated by a
	** POS_END (0) or POS_COLUMN (1). The following block merges the two lists
	** and writes the results to buffer p. p is left pointing to the byte
	** after the list written. No terminator (POS_END or POS_COLUMN) is
	** written to the output.
	*/
	fts3GetDeltaVarint(&p1, &i1);
	fts3GetDeltaVarint(&p2, &i2);
	if( i1<2 \|\| i2<2 ){
	break;
	}
	do {
	fts3PutDeltaVarint(&p, &iPrev, (i1<i2) ? i1 : i2);
	iPrev -= 2;
	if( i1==i2 ){
	fts3ReadNextPos(&p1, &i1);
	fts3ReadNextPos(&p2, &i2);
	}else if( i1<i2 ){
	fts3ReadNextPos(&p1, &i1);
	}else{
	fts3ReadNextPos(&p2, &i2);
	}
	}while( i1!=POSITION_LIST_END \|\| i2!=POSITION_LIST_END );
	}else if( iCol1<iCol2 ){
	p1 += fts3PutColNumber(&p, iCol1);
	fts3ColumnlistCopy(&p, &p1);
	}else{
	p2 += fts3PutColNumber(&p, iCol2);
	fts3ColumnlistCopy(&p, &p2);
	}
	}

	*p++ = POS_END;
	*pp = p;
	*pp1 = p1 + 1;
	*pp2 = p2 + 1;
	return SQLITE_OK;
	}

	/*
	** This function is used to merge two position lists into one. When it is
	** called, pp1 and pp2 must both point to position lists. A position-list is
	** the part of a doclist that follows each document id. For example, if a row
	** contains:
	**
	** 'a b c'\|'x y z'\|'a b b a'
	**
	** Then the position list for this row for token 'b' would consist of:
	**
	** 0x02 0x01 0x02 0x03 0x03 0x00
	**
	** When this function returns, both pp1 and pp2 are left pointing to the
	** byte following the 0x00 terminator of their respective position lists.
	**
	** If isSaveLeft is 0, an entry is added to the output position list for
	** each position in *pp2 for which there exists one or more positions in
	** pp1 so that (pos(pp2)>pos(pp1) && pos(pp2)-pos(*pp1)<=nToken). i.e.
	** when the pp1 token appears before the pp2 token, but not more than nToken
	** slots before it.
	**
	** e.g. nToken==1 searches for adjacent positions.
	*/
	static int fts3PoslistPhraseMerge(
	char *pp, / IN/OUT: Preallocated output buffer */
	int nToken, /* Maximum difference in token positions */
	int isSaveLeft, /* Save the left position */
	int isExact, /* If pp1 is exactly nTokens before pp2 */
	char *pp1, / IN/OUT: Left input list */
	char *pp2 / IN/OUT: Right input list */
	){
	char p = pp;
	char p1 = pp1;
	char p2 = pp2;
	int iCol1 = 0;
	int iCol2 = 0;

	/* Never set both isSaveLeft and isExact for the same invocation. */
	assert( isSaveLeft==0 \|\| isExact==0 );

	assert_fts3_nc( p!=0 && p1!=0 && p2!=0 );
	if( *p1==POS_COLUMN ){
	p1++;
	p1 += fts3GetVarint32(p1, &iCol1);
	/* iCol1==0 indicates corruption. Column 0 does not have a POS_COLUMN
	** entry, so this is actually end-of-doclist. */
	if( iCol1==0 ) return 0;
	}
	if( *p2==POS_COLUMN ){
	p2++;
	p2 += fts3GetVarint32(p2, &iCol2);
	/* As above, iCol2==0 indicates corruption. */
	if( iCol2==0 ) return 0;
	}

	while( 1 ){
	if( iCol1==iCol2 ){
	char *pSave = p;
	sqlite3_int64 iPrev = 0;
	sqlite3_int64 iPos1 = 0;
	sqlite3_int64 iPos2 = 0;

	if( iCol1 ){
	*p++ = POS_COLUMN;
	p += sqlite3Fts3PutVarint(p, iCol1);
	}

	fts3GetDeltaVarint(&p1, &iPos1); iPos1 -= 2;
	fts3GetDeltaVarint(&p2, &iPos2); iPos2 -= 2;
	if( iPos1<0 \|\| iPos2<0 ) break;

	while( 1 ){
	if( iPos2==iPos1+nToken
	\|\| (isExact==0 && iPos2>iPos1 && iPos2<=iPos1+nToken)
	){
	sqlite3_int64 iSave;
	iSave = isSaveLeft ? iPos1 : iPos2;
	fts3PutDeltaVarint(&p, &iPrev, iSave+2); iPrev -= 2;
	pSave = 0;
	assert( p );
	}
	if( (!isSaveLeft && iPos2<=(iPos1+nToken)) \|\| iPos2<=iPos1 ){
	if( (*p2&0xFE)==0 ) break;
	fts3GetDeltaVarint(&p2, &iPos2); iPos2 -= 2;
	}else{
	if( (*p1&0xFE)==0 ) break;
	fts3GetDeltaVarint(&p1, &iPos1); iPos1 -= 2;
	}
	}

	if( pSave ){
	assert( pp && p );
	p = pSave;
	}

	fts3ColumnlistCopy(0, &p1);
	fts3ColumnlistCopy(0, &p2);
	assert( (p1&0xFE)==0 && (p2&0xFE)==0 );
	if( 0==p1 \|\| 0==p2 ) break;

	p1++;
	p1 += fts3GetVarint32(p1, &iCol1);
	p2++;
	p2 += fts3GetVarint32(p2, &iCol2);
	}

	/* Advance pointer p1 or p2 (whichever corresponds to the smaller of
	** iCol1 and iCol2) so that it points to either the 0x00 that marks the
	** end of the position list, or the 0x01 that precedes the next
	** column-number in the position list.
	*/
	else if( iCol1<iCol2 ){
	fts3ColumnlistCopy(0, &p1);
	if( 0==*p1 ) break;
	p1++;
	p1 += fts3GetVarint32(p1, &iCol1);
	}else{
	fts3ColumnlistCopy(0, &p2);
	if( 0==*p2 ) break;
	p2++;
	p2 += fts3GetVarint32(p2, &iCol2);
	}
	}

	fts3PoslistCopy(0, &p2);
	fts3PoslistCopy(0, &p1);
	*pp1 = p1;
	*pp2 = p2;
	if( *pp==p ){
	return 0;
	}
	*p++ = 0x00;
	*pp = p;
	return 1;
	}

	/*
	** Merge two position-lists as required by the NEAR operator. The argument
	** position lists correspond to the left and right phrases of an expression
	** like:
	**
	** "phrase 1" NEAR "phrase number 2"
	**
	** Position list *pp1 corresponds to the left-hand side of the NEAR
	** expression and *pp2 to the right. As usual, the indexes in the position
	** lists are the offsets of the last token in each phrase (tokens "1" and "2"
	** in the example above).
	**
	** The output position list - written to pp - is a copy of pp2 with those
	** entries that are not sufficiently NEAR entries in *pp1 removed.
	*/
	static int fts3PoslistNearMerge(
	char *pp, / Output buffer */
	char aTmp, / Temporary buffer space */
	int nRight, /* Maximum difference in token positions */
	int nLeft, /* Maximum difference in token positions */
	char *pp1, / IN/OUT: Left input list */
	char *pp2 / IN/OUT: Right input list */
	){
	char p1 = pp1;
	char p2 = pp2;

	char *pTmp1 = aTmp;
	char *pTmp2;
	char *aTmp2;
	int res = 1;

	fts3PoslistPhraseMerge(&pTmp1, nRight, 0, 0, pp1, pp2);
	aTmp2 = pTmp2 = pTmp1;
	*pp1 = p1;
	*pp2 = p2;
	fts3PoslistPhraseMerge(&pTmp2, nLeft, 1, 0, pp2, pp1);
	if( pTmp1!=aTmp && pTmp2!=aTmp2 ){
	fts3PoslistMerge(pp, &aTmp, &aTmp2);
	}else if( pTmp1!=aTmp ){
	fts3PoslistCopy(pp, &aTmp);
	}else if( pTmp2!=aTmp2 ){
	fts3PoslistCopy(pp, &aTmp2);
	}else{
	res = 0;
	}

	return res;
	}

	/*
	** An instance of this function is used to merge together the (potentially
	** large number of) doclists for each term that matches a prefix query.
	** See function fts3TermSelectMerge() for details.
	*/
	typedef struct TermSelect TermSelect;
	struct TermSelect {
	char aaOutput[16]; / Malloc'd output buffers */
	int anOutput[16]; /* Size each output buffer in bytes */
	};

	/*
	** This function is used to read a single varint from a buffer. Parameter
	** pEnd points 1 byte past the end of the buffer. When this function is
	** called, if *pp points to pEnd or greater, then the end of the buffer
	** has been reached. In this case *pp is set to 0 and the function returns.
	**
	** If *pp does not point to or past pEnd, then a single varint is read
	** from pp. pp is then set to point 1 byte past the end of the read varint.
	**
	** If bDescIdx is false, the value read is added to *pVal before returning.
	** If it is true, the value read is subtracted from *pVal before this
	** function returns.
	*/
	static void fts3GetDeltaVarint3(
	char *pp, / IN/OUT: Point to read varint from */
	char pEnd, / End of buffer */
	int bDescIdx, /* True if docids are descending */
	sqlite3_int64 pVal / IN/OUT: Integer value */
	){
	if( *pp>=pEnd ){
	*pp = 0;
	}else{
	u64 iVal;
	pp += sqlite3Fts3GetVarintU(pp, &iVal);
	if( bDescIdx ){
	pVal = (i64)((u64)pVal - iVal);
	}else{
	pVal = (i64)((u64)pVal + iVal);
	}
	}
	}

	/*
	** This function is used to write a single varint to a buffer. The varint
	** is written to pp. Before returning, pp is set to point 1 byte past the
	** end of the value written.
	**
	** If *pbFirst is zero when this function is called, the value written to
	** the buffer is that of parameter iVal.
	**
	** If *pbFirst is non-zero when this function is called, then the value
	** written is either (iVal-piPrev) (if bDescIdx is zero) or (piPrev-iVal)
	** (if bDescIdx is non-zero).
	**
	** Before returning, this function always sets pbFirst to 1 and piPrev
	** to the value of parameter iVal.
	*/
	static void fts3PutDeltaVarint3(
	char *pp, / IN/OUT: Output pointer */
	int bDescIdx, /* True for descending docids */
	sqlite3_int64 piPrev, / IN/OUT: Previous value written to list */
	int pbFirst, / IN/OUT: True after first int written */
	sqlite3_int64 iVal /* Write this value to the list */
	){
	sqlite3_uint64 iWrite;
	if( bDescIdx==0 \|\| *pbFirst==0 ){
	assert_fts3_nc( pbFirst==0 \|\| iVal>=piPrev );
	iWrite = (u64)iVal - (u64)*piPrev;
	}else{
	assert_fts3_nc( *piPrev>=iVal );
	iWrite = (u64)*piPrev - (u64)iVal;
	}
	assert( pbFirst \|\| piPrev==0 );
	assert_fts3_nc( *pbFirst==0 \|\| iWrite>0 );
	pp += sqlite3Fts3PutVarint(pp, iWrite);
	*piPrev = iVal;
	*pbFirst = 1;
	}


	/*
	** This macro is used by various functions that merge doclists. The two
	** arguments are 64-bit docid values. If the value of the stack variable
	** bDescDoclist is 0 when this macro is invoked, then it returns (i1-i2).
	** Otherwise, (i2-i1).
	**
	** Using this makes it easier to write code that can merge doclists that are
	** sorted in either ascending or descending order.
	*/
	/* #define DOCID_CMP(i1, i2) ((bDescDoclist?-1:1) * (i64)((u64)i1-i2)) */
	#define DOCID_CMP(i1, i2) ((bDescDoclist?-1:1) * (i1>i2?1:((i1==i2)?0:-1)))

	/*
	** This function does an "OR" merge of two doclists (output contains all
	** positions contained in either argument doclist). If the docids in the
	** input doclists are sorted in ascending order, parameter bDescDoclist
	** should be false. If they are sorted in ascending order, it should be
	** passed a non-zero value.
	**
	** If no error occurs, *paOut is set to point at an sqlite3_malloc'd buffer
	** containing the output doclist and SQLITE_OK is returned. In this case
	** *pnOut is set to the number of bytes in the output doclist.
	**
	** If an error occurs, an SQLite error code is returned. The output values
	** are undefined in this case.
	*/
	static int fts3DoclistOrMerge(
	int bDescDoclist, /* True if arguments are desc */
	char a1, int n1, / First doclist */
	char a2, int n2, / Second doclist */
	char *paOut, int pnOut /* OUT: Malloc'd doclist */
	){
	int rc = SQLITE_OK;
	sqlite3_int64 i1 = 0;
	sqlite3_int64 i2 = 0;
	sqlite3_int64 iPrev = 0;
	char *pEnd1 = &a1[n1];
	char *pEnd2 = &a2[n2];
	char *p1 = a1;
	char *p2 = a2;
	char *p;
	char *aOut;
	int bFirstOut = 0;

	*paOut = 0;
	*pnOut = 0;

	/* Allocate space for the output. Both the input and output doclists
	** are delta encoded. If they are in ascending order (bDescDoclist==0),
	** then the first docid in each list is simply encoded as a varint. For
	** each subsequent docid, the varint stored is the difference between the
	** current and previous docid (a positive number - since the list is in
	** ascending order).
	**
	** The first docid written to the output is therefore encoded using the
	** same number of bytes as it is in whichever of the input lists it is
	** read from. And each subsequent docid read from the same input list
	** consumes either the same or less bytes as it did in the input (since
	** the difference between it and the previous value in the output must
	** be a positive value less than or equal to the delta value read from
	** the input list). The same argument applies to all but the first docid
	** read from the 'other' list. And to the contents of all position lists
	** that will be copied and merged from the input to the output.
	**
	** However, if the first docid copied to the output is a negative number,
	** then the encoding of the first docid from the 'other' input list may
	** be larger in the output than it was in the input (since the delta value
	** may be a larger positive integer than the actual docid).
	**
	** The space required to store the output is therefore the sum of the
	** sizes of the two inputs, plus enough space for exactly one of the input
	** docids to grow.
	**
	** A symetric argument may be made if the doclists are in descending
	** order.
	*/
	aOut = sqlite3_malloc64((i64)n1+n2+FTS3_VARINT_MAX-1+FTS3_BUFFER_PADDING);
	if( !aOut ) return SQLITE_NOMEM;

	p = aOut;
	fts3GetDeltaVarint3(&p1, pEnd1, 0, &i1);
	fts3GetDeltaVarint3(&p2, pEnd2, 0, &i2);
	while( p1 \|\| p2 ){
	sqlite3_int64 iDiff = DOCID_CMP(i1, i2);

	if( p2 && p1 && iDiff==0 ){
	fts3PutDeltaVarint3(&p, bDescDoclist, &iPrev, &bFirstOut, i1);
	rc = fts3PoslistMerge(&p, &p1, &p2);
	if( rc ) break;
	fts3GetDeltaVarint3(&p1, pEnd1, bDescDoclist, &i1);
	fts3GetDeltaVarint3(&p2, pEnd2, bDescDoclist, &i2);
	}else if( !p2 \|\| (p1 && iDiff<0) ){
	fts3PutDeltaVarint3(&p, bDescDoclist, &iPrev, &bFirstOut, i1);
	fts3PoslistCopy(&p, &p1);
	fts3GetDeltaVarint3(&p1, pEnd1, bDescDoclist, &i1);
	}else{
	fts3PutDeltaVarint3(&p, bDescDoclist, &iPrev, &bFirstOut, i2);
	fts3PoslistCopy(&p, &p2);
	fts3GetDeltaVarint3(&p2, pEnd2, bDescDoclist, &i2);
	}

	assert( (p-aOut)<=((p1?(p1-a1):n1)+(p2?(p2-a2):n2)+FTS3_VARINT_MAX-1) );
	}

	if( rc!=SQLITE_OK ){
	sqlite3_free(aOut);
	p = aOut = 0;
	}else{
	assert( (p-aOut)<=n1+n2+FTS3_VARINT_MAX-1 );
	memset(&aOut[(p-aOut)], 0, FTS3_BUFFER_PADDING);
	}
	*paOut = aOut;
	*pnOut = (int)(p-aOut);
	return rc;
	}

	/*
	** This function does a "phrase" merge of two doclists. In a phrase merge,
	** the output contains a copy of each position from the right-hand input
	** doclist for which there is a position in the left-hand input doclist
	** exactly nDist tokens before it.
	**
	** If the docids in the input doclists are sorted in ascending order,
	** parameter bDescDoclist should be false. If they are sorted in ascending
	** order, it should be passed a non-zero value.
	**
	** The right-hand input doclist is overwritten by this function.
	*/
	static int fts3DoclistPhraseMerge(
	int bDescDoclist, /* True if arguments are desc */
	int nDist, /* Distance from left to right (1=adjacent) */
	char aLeft, int nLeft, / Left doclist */
	char *paRight, int pnRight /* IN/OUT: Right/output doclist */
	){
	sqlite3_int64 i1 = 0;
	sqlite3_int64 i2 = 0;
	sqlite3_int64 iPrev = 0;
	char aRight = paRight;
	char *pEnd1 = &aLeft[nLeft];
	char pEnd2 = &aRight[pnRight];
	char *p1 = aLeft;
	char *p2 = aRight;
	char *p;
	int bFirstOut = 0;
	char *aOut;

	assert( nDist>0 );
	if( bDescDoclist ){
	aOut = sqlite3_malloc64((sqlite3_int64)*pnRight + FTS3_VARINT_MAX);
	if( aOut==0 ) return SQLITE_NOMEM;
	}else{
	aOut = aRight;
	}
	p = aOut;

	fts3GetDeltaVarint3(&p1, pEnd1, 0, &i1);
	fts3GetDeltaVarint3(&p2, pEnd2, 0, &i2);

	while( p1 && p2 ){
	sqlite3_int64 iDiff = DOCID_CMP(i1, i2);
	if( iDiff==0 ){
	char *pSave = p;
	sqlite3_int64 iPrevSave = iPrev;
	int bFirstOutSave = bFirstOut;

	fts3PutDeltaVarint3(&p, bDescDoclist, &iPrev, &bFirstOut, i1);
	if( 0==fts3PoslistPhraseMerge(&p, nDist, 0, 1, &p1, &p2) ){
	p = pSave;
	iPrev = iPrevSave;
	bFirstOut = bFirstOutSave;
	}
	fts3GetDeltaVarint3(&p1, pEnd1, bDescDoclist, &i1);
	fts3GetDeltaVarint3(&p2, pEnd2, bDescDoclist, &i2);
	}else if( iDiff<0 ){
	fts3PoslistCopy(0, &p1);
	fts3GetDeltaVarint3(&p1, pEnd1, bDescDoclist, &i1);
	}else{
	fts3PoslistCopy(0, &p2);
	fts3GetDeltaVarint3(&p2, pEnd2, bDescDoclist, &i2);
	}
	}

	*pnRight = (int)(p - aOut);
	if( bDescDoclist ){
	sqlite3_free(aRight);
	*paRight = aOut;
	}

	return SQLITE_OK;
	}

	/*
	** Argument pList points to a position list nList bytes in size. This
	** function checks to see if the position list contains any entries for
	** a token in position 0 (of any column). If so, it writes argument iDelta
	** to the output buffer pOut, followed by a position list consisting only
	** of the entries from pList at position 0, and terminated by an 0x00 byte.
	** The value returned is the number of bytes written to pOut (if any).
	*/
	int sqlite3Fts3FirstFilter(
	sqlite3_int64 iDelta, /* Varint that may be written to pOut */
	char pList, / Position list (no 0x00 term) */
	int nList, /* Size of pList in bytes */
	char pOut / Write output here */
	){
	int nOut = 0;
	int bWritten = 0; /* True once iDelta has been written */
	char *p = pList;
	char *pEnd = &pList[nList];

	if( *p!=0x01 ){
	if( *p==0x02 ){
	nOut += sqlite3Fts3PutVarint(&pOut[nOut], iDelta);
	pOut[nOut++] = 0x02;
	bWritten = 1;
	}
	fts3ColumnlistCopy(0, &p);
	}

	while( p<pEnd ){
	sqlite3_int64 iCol;
	p++;
	p += sqlite3Fts3GetVarint(p, &iCol);
	if( *p==0x02 ){
	if( bWritten==0 ){
	nOut += sqlite3Fts3PutVarint(&pOut[nOut], iDelta);
	bWritten = 1;
	}
	pOut[nOut++] = 0x01;
	nOut += sqlite3Fts3PutVarint(&pOut[nOut], iCol);
	pOut[nOut++] = 0x02;
	}
	fts3ColumnlistCopy(0, &p);
	}
	if( bWritten ){
	pOut[nOut++] = 0x00;
	}

	return nOut;
	}


	/*
	** Merge all doclists in the TermSelect.aaOutput[] array into a single
	** doclist stored in TermSelect.aaOutput[0]. If successful, delete all
	** other doclists (except the aaOutput[0] one) and return SQLITE_OK.
	**
	** If an OOM error occurs, return SQLITE_NOMEM. In this case it is
	** the responsibility of the caller to free any doclists left in the
	** TermSelect.aaOutput[] array.
	*/
	static int fts3TermSelectFinishMerge(Fts3Table p, TermSelect pTS){
	char *aOut = 0;
	int nOut = 0;
	int i;

	/* Loop through the doclists in the aaOutput[] array. Merge them all
	** into a single doclist.
	*/
	for(i=0; i<SizeofArray(pTS->aaOutput); i++){
	if( pTS->aaOutput[i] ){
	if( !aOut ){
	aOut = pTS->aaOutput[i];
	nOut = pTS->anOutput[i];
	pTS->aaOutput[i] = 0;
	}else{
	int nNew;
	char *aNew;

	int rc = fts3DoclistOrMerge(p->bDescIdx,
	pTS->aaOutput[i], pTS->anOutput[i], aOut, nOut, &aNew, &nNew
	);
	if( rc!=SQLITE_OK ){
	sqlite3_free(aOut);
	return rc;
	}

	sqlite3_free(pTS->aaOutput[i]);
	sqlite3_free(aOut);
	pTS->aaOutput[i] = 0;
	aOut = aNew;
	nOut = nNew;
	}
	}
	}

	pTS->aaOutput[0] = aOut;
	pTS->anOutput[0] = nOut;
	return SQLITE_OK;
	}

	/*
	** Merge the doclist aDoclist/nDoclist into the TermSelect object passed
	** as the first argument. The merge is an "OR" merge (see function
	** fts3DoclistOrMerge() for details).
	**
	** This function is called with the doclist for each term that matches
	** a queried prefix. It merges all these doclists into one, the doclist
	** for the specified prefix. Since there can be a very large number of
	** doclists to merge, the merging is done pair-wise using the TermSelect
	** object.
	**
	** This function returns SQLITE_OK if the merge is successful, or an
	** SQLite error code (SQLITE_NOMEM) if an error occurs.
	*/
	static int fts3TermSelectMerge(
	Fts3Table p, / FTS table handle */
	TermSelect pTS, / TermSelect object to merge into */
	char aDoclist, / Pointer to doclist */
	int nDoclist /* Size of aDoclist in bytes */
	){
	if( pTS->aaOutput[0]==0 ){
	/* If this is the first term selected, copy the doclist to the output
	** buffer using memcpy().
	**
	** Add FTS3_VARINT_MAX bytes of unused space to the end of the
	** allocation. This is so as to ensure that the buffer is big enough
	** to hold the current doclist AND'd with any other doclist. If the
	** doclists are stored in order=ASC order, this padding would not be
	** required (since the size of [doclistA AND doclistB] is always less
	** than or equal to the size of [doclistA] in that case). But this is
	** not true for order=DESC. For example, a doclist containing (1, -1)
	** may be smaller than (-1), as in the first example the -1 may be stored
	** as a single-byte delta, whereas in the second it must be stored as a
	** FTS3_VARINT_MAX byte varint.
	**
	** Similar padding is added in the fts3DoclistOrMerge() function.
	*/
	pTS->aaOutput[0] = sqlite3_malloc64((i64)nDoclist + FTS3_VARINT_MAX + 1);
	pTS->anOutput[0] = nDoclist;
	if( pTS->aaOutput[0] ){
	memcpy(pTS->aaOutput[0], aDoclist, nDoclist);
	memset(&pTS->aaOutput[0][nDoclist], 0, FTS3_VARINT_MAX);
	}else{
	return SQLITE_NOMEM;
	}
	}else{
	char *aMerge = aDoclist;
	int nMerge = nDoclist;
	int iOut;

	for(iOut=0; iOut<SizeofArray(pTS->aaOutput); iOut++){
	if( pTS->aaOutput[iOut]==0 ){
	assert( iOut>0 );
	pTS->aaOutput[iOut] = aMerge;
	pTS->anOutput[iOut] = nMerge;
	break;
	}else{
	char *aNew;
	int nNew;

	int rc = fts3DoclistOrMerge(p->bDescIdx, aMerge, nMerge,
	pTS->aaOutput[iOut], pTS->anOutput[iOut], &aNew, &nNew
	);
	if( rc!=SQLITE_OK ){
	if( aMerge!=aDoclist ) sqlite3_free(aMerge);
	return rc;
	}

	if( aMerge!=aDoclist ) sqlite3_free(aMerge);
	sqlite3_free(pTS->aaOutput[iOut]);
	pTS->aaOutput[iOut] = 0;

	aMerge = aNew;
	nMerge = nNew;
	if( (iOut+1)==SizeofArray(pTS->aaOutput) ){
	pTS->aaOutput[iOut] = aMerge;
	pTS->anOutput[iOut] = nMerge;
	}
	}
	}
	}
	return SQLITE_OK;
	}

	/*
	** Append SegReader object pNew to the end of the pCsr->apSegment[] array.
	*/
	static int fts3SegReaderCursorAppend(
	Fts3MultiSegReader *pCsr,
	Fts3SegReader *pNew
	){
	if( (pCsr->nSegment%16)==0 ){
	Fts3SegReader **apNew;
	sqlite3_int64 nByte = (pCsr->nSegment + 16)sizeof(Fts3SegReader);
	apNew = (Fts3SegReader **)sqlite3_realloc64(pCsr->apSegment, nByte);
	if( !apNew ){
	sqlite3Fts3SegReaderFree(pNew);
	return SQLITE_NOMEM;
	}
	pCsr->apSegment = apNew;
	}
	pCsr->apSegment[pCsr->nSegment++] = pNew;
	return SQLITE_OK;
	}

	/*
	** Add seg-reader objects to the Fts3MultiSegReader object passed as the
	** 8th argument.
	**
	** This function returns SQLITE_OK if successful, or an SQLite error code
	** otherwise.
	*/
	static int fts3SegReaderCursor(
	Fts3Table p, / FTS3 table handle */
	int iLangid, /* Language id */
	int iIndex, /* Index to search (from 0 to p->nIndex-1) */
	int iLevel, /* Level of segments to scan */
	const char zTerm, / Term to query for */
	int nTerm, /* Size of zTerm in bytes */
	int isPrefix, /* True for a prefix search */
	int isScan, /* True to scan from zTerm to EOF */
	Fts3MultiSegReader pCsr / Cursor object to populate */
	){
	int rc = SQLITE_OK; /* Error code */
	sqlite3_stmt pStmt = 0; / Statement to iterate through segments */
	int rc2; /* Result of sqlite3_reset() */

	/* If iLevel is less than 0 and this is not a scan, include a seg-reader
	** for the pending-terms. If this is a scan, then this call must be being
	** made by an fts4aux module, not an FTS table. In this case calling
	** Fts3SegReaderPending might segfault, as the data structures used by
	** fts4aux are not completely populated. So it's easiest to filter these
	** calls out here. */
	if( iLevel<0 && p->aIndex && p->iPrevLangid==iLangid ){
	Fts3SegReader *pSeg = 0;
	rc = sqlite3Fts3SegReaderPending(p, iIndex, zTerm, nTerm, isPrefix\|\|isScan, &pSeg);
	if( rc==SQLITE_OK && pSeg ){
	rc = fts3SegReaderCursorAppend(pCsr, pSeg);
	}
	}

	if( iLevel!=FTS3_SEGCURSOR_PENDING ){
	if( rc==SQLITE_OK ){
	rc = sqlite3Fts3AllSegdirs(p, iLangid, iIndex, iLevel, &pStmt);
	}

	while( rc==SQLITE_OK && SQLITE_ROW==(rc = sqlite3_step(pStmt)) ){
	Fts3SegReader *pSeg = 0;

	/* Read the values returned by the SELECT into local variables. */
	sqlite3_int64 iStartBlock = sqlite3_column_int64(pStmt, 1);
	sqlite3_int64 iLeavesEndBlock = sqlite3_column_int64(pStmt, 2);
	sqlite3_int64 iEndBlock = sqlite3_column_int64(pStmt, 3);
	int nRoot = sqlite3_column_bytes(pStmt, 4);
	char const *zRoot = sqlite3_column_blob(pStmt, 4);

	/* If zTerm is not NULL, and this segment is not stored entirely on its
	** root node, the range of leaves scanned can be reduced. Do this. */
	if( iStartBlock && zTerm && zRoot ){
	sqlite3_int64 *pi = (isPrefix ? &iLeavesEndBlock : 0);
	rc = fts3SelectLeaf(p, zTerm, nTerm, zRoot, nRoot, &iStartBlock, pi);
	if( rc!=SQLITE_OK ) goto finished;
	if( isPrefix==0 && isScan==0 ) iLeavesEndBlock = iStartBlock;
	}

	rc = sqlite3Fts3SegReaderNew(pCsr->nSegment+1,
	(isPrefix==0 && isScan==0),
	iStartBlock, iLeavesEndBlock,
	iEndBlock, zRoot, nRoot, &pSeg
	);
	if( rc!=SQLITE_OK ) goto finished;
	rc = fts3SegReaderCursorAppend(pCsr, pSeg);
	}
	}

	finished:
	rc2 = sqlite3_reset(pStmt);
	if( rc==SQLITE_DONE ) rc = rc2;

	return rc;
	}

	/*
	** Set up a cursor object for iterating through a full-text index or a
	** single level therein.
	*/
	int sqlite3Fts3SegReaderCursor(
	Fts3Table p, / FTS3 table handle */
	int iLangid, /* Language-id to search */
	int iIndex, /* Index to search (from 0 to p->nIndex-1) */
	int iLevel, /* Level of segments to scan */
	const char zTerm, / Term to query for */
	int nTerm, /* Size of zTerm in bytes */
	int isPrefix, /* True for a prefix search */
	int isScan, /* True to scan from zTerm to EOF */
	Fts3MultiSegReader pCsr / Cursor object to populate */
	){
	assert( iIndex>=0 && iIndex<p->nIndex );
	assert( iLevel==FTS3_SEGCURSOR_ALL
	\|\| iLevel==FTS3_SEGCURSOR_PENDING
	\|\| iLevel>=0
	);
	assert( iLevel<FTS3_SEGDIR_MAXLEVEL );
	assert( FTS3_SEGCURSOR_ALL<0 && FTS3_SEGCURSOR_PENDING<0 );
	assert( isPrefix==0 \|\| isScan==0 );

	memset(pCsr, 0, sizeof(Fts3MultiSegReader));
	return fts3SegReaderCursor(
	p, iLangid, iIndex, iLevel, zTerm, nTerm, isPrefix, isScan, pCsr
	);
	}

	/*
	** In addition to its current configuration, have the Fts3MultiSegReader
	** passed as the 4th argument also scan the doclist for term zTerm/nTerm.
	**
	** SQLITE_OK is returned if no error occurs, otherwise an SQLite error code.
	*/
	static int fts3SegReaderCursorAddZero(
	Fts3Table p, / FTS virtual table handle */
	int iLangid,
	const char zTerm, / Term to scan doclist of */
	int nTerm, /* Number of bytes in zTerm */
	Fts3MultiSegReader pCsr / Fts3MultiSegReader to modify */
	){
	return fts3SegReaderCursor(p,
	iLangid, 0, FTS3_SEGCURSOR_ALL, zTerm, nTerm, 0, 0,pCsr
	);
	}

	/*
	** Open an Fts3MultiSegReader to scan the doclist for term zTerm/nTerm. Or,
	** if isPrefix is true, to scan the doclist for all terms for which
	** zTerm/nTerm is a prefix. If successful, return SQLITE_OK and write
	** a pointer to the new Fts3MultiSegReader to *ppSegcsr. Otherwise, return
	** an SQLite error code.
	**
	** It is the responsibility of the caller to free this object by eventually
	** passing it to fts3SegReaderCursorFree()
	**
	** SQLITE_OK is returned if no error occurs, otherwise an SQLite error code.
	** Output parameter *ppSegcsr is set to 0 if an error occurs.
	*/
	static int fts3TermSegReaderCursor(
	Fts3Cursor pCsr, / Virtual table cursor handle */
	const char zTerm, / Term to query for */
	int nTerm, /* Size of zTerm in bytes */
	int isPrefix, /* True for a prefix search */
	Fts3MultiSegReader *ppSegcsr / OUT: Allocated seg-reader cursor */
	){
	Fts3MultiSegReader pSegcsr; / Object to allocate and return */
	int rc = SQLITE_NOMEM; /* Return code */

	pSegcsr = sqlite3_malloc(sizeof(Fts3MultiSegReader));
	if( pSegcsr ){
	int i;
	int bFound = 0; /* True once an index has been found */
	Fts3Table p = (Fts3Table )pCsr->base.pVtab;

	if( isPrefix ){
	for(i=1; bFound==0 && i<p->nIndex; i++){
	if( p->aIndex[i].nPrefix==nTerm ){
	bFound = 1;
	rc = sqlite3Fts3SegReaderCursor(p, pCsr->iLangid,
	i, FTS3_SEGCURSOR_ALL, zTerm, nTerm, 0, 0, pSegcsr
	);
	pSegcsr->bLookup = 1;
	}
	}

	for(i=1; bFound==0 && i<p->nIndex; i++){
	if( p->aIndex[i].nPrefix==nTerm+1 ){
	bFound = 1;
	rc = sqlite3Fts3SegReaderCursor(p, pCsr->iLangid,
	i, FTS3_SEGCURSOR_ALL, zTerm, nTerm, 1, 0, pSegcsr
	);
	if( rc==SQLITE_OK ){
	rc = fts3SegReaderCursorAddZero(
	p, pCsr->iLangid, zTerm, nTerm, pSegcsr
	);
	}
	}
	}
	}

	if( bFound==0 ){
	rc = sqlite3Fts3SegReaderCursor(p, pCsr->iLangid,
	0, FTS3_SEGCURSOR_ALL, zTerm, nTerm, isPrefix, 0, pSegcsr
	);
	pSegcsr->bLookup = !isPrefix;
	}
	}

	*ppSegcsr = pSegcsr;
	return rc;
	}

	/*
	** Free an Fts3MultiSegReader allocated by fts3TermSegReaderCursor().
	*/
	static void fts3SegReaderCursorFree(Fts3MultiSegReader *pSegcsr){
	sqlite3Fts3SegReaderFinish(pSegcsr);
	sqlite3_free(pSegcsr);
	}

	/*
	** This function retrieves the doclist for the specified term (or term
	** prefix) from the database.
	*/
	static int fts3TermSelect(
	Fts3Table p, / Virtual table handle */
	Fts3PhraseToken pTok, / Token to query for */
	int iColumn, /* Column to query (or -ve for all columns) */
	int pnOut, / OUT: Size of buffer at ppOut /
	char *ppOut / OUT: Malloced result buffer */
	){
	int rc; /* Return code */
	Fts3MultiSegReader pSegcsr; / Seg-reader cursor for this term */
	TermSelect tsc; /* Object for pair-wise doclist merging */
	Fts3SegFilter filter; /* Segment term filter configuration */

	pSegcsr = pTok->pSegcsr;
	memset(&tsc, 0, sizeof(TermSelect));

	filter.flags = FTS3_SEGMENT_IGNORE_EMPTY \| FTS3_SEGMENT_REQUIRE_POS
	\| (pTok->isPrefix ? FTS3_SEGMENT_PREFIX : 0)
	\| (pTok->bFirst ? FTS3_SEGMENT_FIRST : 0)
	\| (iColumn<p->nColumn ? FTS3_SEGMENT_COLUMN_FILTER : 0);
	filter.iCol = iColumn;
	filter.zTerm = pTok->z;
	filter.nTerm = pTok->n;

	rc = sqlite3Fts3SegReaderStart(p, pSegcsr, &filter);
	while( SQLITE_OK==rc
	&& SQLITE_ROW==(rc = sqlite3Fts3SegReaderStep(p, pSegcsr))
	){
	rc = fts3TermSelectMerge(p, &tsc, pSegcsr->aDoclist, pSegcsr->nDoclist);
	}

	if( rc==SQLITE_OK ){
	rc = fts3TermSelectFinishMerge(p, &tsc);
	}
	if( rc==SQLITE_OK ){
	*ppOut = tsc.aaOutput[0];
	*pnOut = tsc.anOutput[0];
	}else{
	int i;
	for(i=0; i<SizeofArray(tsc.aaOutput); i++){
	sqlite3_free(tsc.aaOutput[i]);
	}
	}

	fts3SegReaderCursorFree(pSegcsr);
	pTok->pSegcsr = 0;
	return rc;
	}

	/*
	** This function counts the total number of docids in the doclist stored
	** in buffer aList[], size nList bytes.
	**
	** If the isPoslist argument is true, then it is assumed that the doclist
	** contains a position-list following each docid. Otherwise, it is assumed
	** that the doclist is simply a list of docids stored as delta encoded
	** varints.
	*/
	static int fts3DoclistCountDocids(char *aList, int nList){
	int nDoc = 0; /* Return value */
	if( aList ){
	char aEnd = &aList[nList]; / Pointer to one byte after EOF */
	char p = aList; / Cursor */
	while( p<aEnd ){
	nDoc++;
	while( (p++)&0x80 ); / Skip docid varint */
	fts3PoslistCopy(0, &p); /* Skip over position list */
	}
	}

	return nDoc;
	}

	/*
	** Advance the cursor to the next row in the %_content table that
	** matches the search criteria. For a MATCH search, this will be
	** the next row that matches. For a full-table scan, this will be
	** simply the next row in the %_content table. For a docid lookup,
	** this routine simply sets the EOF flag.
	**
	** Return SQLITE_OK if nothing goes wrong. SQLITE_OK is returned
	** even if we reach end-of-file. The fts3EofMethod() will be called
	** subsequently to determine whether or not an EOF was hit.
	*/
	static int fts3NextMethod(sqlite3_vtab_cursor *pCursor){
	int rc;
	Fts3Cursor pCsr = (Fts3Cursor )pCursor;
	if( pCsr->eSearch==FTS3_DOCID_SEARCH \|\| pCsr->eSearch==FTS3_FULLSCAN_SEARCH ){
	Fts3Table pTab = (Fts3Table)pCursor->pVtab;
	pTab->bLock++;
	if( SQLITE_ROW!=sqlite3_step(pCsr->pStmt) ){
	pCsr->isEof = 1;
	rc = sqlite3_reset(pCsr->pStmt);
	}else{
	pCsr->iPrevId = sqlite3_column_int64(pCsr->pStmt, 0);
	rc = SQLITE_OK;
	}
	pTab->bLock--;
	}else{
	rc = fts3EvalNext((Fts3Cursor *)pCursor);
	}
	assert( ((Fts3Table *)pCsr->base.pVtab)->pSegments==0 );
	return rc;
	}

	/*
	** If the numeric type of argument pVal is "integer", then return it
	** converted to a 64-bit signed integer. Otherwise, return a copy of
	** the second parameter, iDefault.
	*/
	static sqlite3_int64 fts3DocidRange(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.
	**
	** If idxNum==FTS3_FULLSCAN_SEARCH then do a full table scan against
	** the %_content table.
	**
	** If idxNum==FTS3_DOCID_SEARCH then do a docid lookup for a single entry
	** in the %_content table.
	**
	** If idxNum>=FTS3_FULLTEXT_SEARCH then use the full text index. The
	** column on the left-hand side of the MATCH operator is column
	** number idxNum-FTS3_FULLTEXT_SEARCH, 0 indexed. argv[0] is the right-hand
	** side of the MATCH operator.
	*/
	static int fts3FilterMethod(
	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 */
	){
	int rc = SQLITE_OK;
	char zSql; / SQL statement used to access %_content */
	int eSearch;
	Fts3Table p = (Fts3Table )pCursor->pVtab;
	Fts3Cursor pCsr = (Fts3Cursor )pCursor;

	sqlite3_value pCons = 0; / The MATCH or rowid constraint, if any */
	sqlite3_value pLangid = 0; / The "langid = ?" constraint, if any */
	sqlite3_value pDocidGe = 0; / The "docid >= ?" constraint, if any */
	sqlite3_value pDocidLe = 0; / The "docid <= ?" constraint, if any */
	int iIdx;

	UNUSED_PARAMETER(idxStr);
	UNUSED_PARAMETER(nVal);

	if( p->bLock ){
	return SQLITE_ERROR;
	}

	eSearch = (idxNum & 0x0000FFFF);
	assert( eSearch>=0 && eSearch<=(FTS3_FULLTEXT_SEARCH+p->nColumn) );
	assert( p->pSegments==0 );

	/* Collect arguments into local variables */
	iIdx = 0;
	if( eSearch!=FTS3_FULLSCAN_SEARCH ) pCons = apVal[iIdx++];
	if( idxNum & FTS3_HAVE_LANGID ) pLangid = apVal[iIdx++];
	if( idxNum & FTS3_HAVE_DOCID_GE ) pDocidGe = apVal[iIdx++];
	if( idxNum & FTS3_HAVE_DOCID_LE ) pDocidLe = apVal[iIdx++];
	assert( iIdx==nVal );

	/* In case the cursor has been used before, clear it now. */
	fts3ClearCursor(pCsr);

	/* Set the lower and upper bounds on docids to return */
	pCsr->iMinDocid = fts3DocidRange(pDocidGe, SMALLEST_INT64);
	pCsr->iMaxDocid = fts3DocidRange(pDocidLe, LARGEST_INT64);

	if( idxStr ){
	pCsr->bDesc = (idxStr[0]=='D');
	}else{
	pCsr->bDesc = p->bDescIdx;
	}
	pCsr->eSearch = (i16)eSearch;

	if( eSearch!=FTS3_DOCID_SEARCH && eSearch!=FTS3_FULLSCAN_SEARCH ){
	int iCol = eSearch-FTS3_FULLTEXT_SEARCH;
	const char zQuery = (const char )sqlite3_value_text(pCons);

	if( zQuery==0 && sqlite3_value_type(pCons)!=SQLITE_NULL ){
	return SQLITE_NOMEM;
	}

	pCsr->iLangid = 0;
	if( pLangid ) pCsr->iLangid = sqlite3_value_int(pLangid);

	assert( p->base.zErrMsg==0 );
	rc = sqlite3Fts3ExprParse(p->pTokenizer, pCsr->iLangid,
	p->azColumn, p->bFts4, p->nColumn, iCol, zQuery, -1, &pCsr->pExpr,
	&p->base.zErrMsg
	);
	if( rc!=SQLITE_OK ){
	return rc;
	}

	rc = fts3EvalStart(pCsr);
	sqlite3Fts3SegmentsClose(p);
	if( rc!=SQLITE_OK ) return rc;
	pCsr->pNextId = pCsr->aDoclist;
	pCsr->iPrevId = 0;
	}

	/* Compile a SELECT statement for this cursor. For a full-table-scan, the
	** statement loops through all rows of the %_content table. For a
	** full-text query or docid lookup, the statement retrieves a single
	** row by docid.
	*/
	if( eSearch==FTS3_FULLSCAN_SEARCH ){
	if( pDocidGe \|\| pDocidLe ){
	zSql = sqlite3_mprintf(
	"SELECT %s WHERE rowid BETWEEN %lld AND %lld ORDER BY rowid %s",
	p->zReadExprlist, pCsr->iMinDocid, pCsr->iMaxDocid,
	(pCsr->bDesc ? "DESC" : "ASC")
	);
	}else{
	zSql = sqlite3_mprintf("SELECT %s ORDER BY rowid %s",
	p->zReadExprlist, (pCsr->bDesc ? "DESC" : "ASC")
	);
	}
	if( zSql ){
	p->bLock++;
	rc = sqlite3_prepare_v3(
	p->db,zSql,-1,SQLITE_PREPARE_PERSISTENT,&pCsr->pStmt,0
	);
	p->bLock--;
	sqlite3_free(zSql);
	}else{
	rc = SQLITE_NOMEM;
	}
	}else if( eSearch==FTS3_DOCID_SEARCH ){
	rc = fts3CursorSeekStmt(pCsr);
	if( rc==SQLITE_OK ){
	rc = sqlite3_bind_value(pCsr->pStmt, 1, pCons);
	}
	}
	if( rc!=SQLITE_OK ) return rc;

	return fts3NextMethod(pCursor);
	}

	/*
	** 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 fts3EofMethod(sqlite3_vtab_cursor *pCursor){
	Fts3Cursor pCsr = (Fts3Cursor)pCursor;
	if( pCsr->isEof ){
	fts3ClearCursor(pCsr);
	pCsr->isEof = 1;
	}
	return pCsr->isEof;
	}

	/*
	** This is the xRowid method. The SQLite core calls this routine to
	** retrieve the rowid for the current row of the result set. fts3
	** exposes %_content.docid as the rowid for the virtual table. The
	** rowid should be written to *pRowid.
	*/
	static int fts3RowidMethod(sqlite3_vtab_cursor pCursor, sqlite_int64 pRowid){
	Fts3Cursor pCsr = (Fts3Cursor ) pCursor;
	*pRowid = pCsr->iPrevId;
	return SQLITE_OK;
	}

	/*
	** This is the xColumn method, called by SQLite to request a value from
	** the row that the supplied cursor currently points to.
	**
	** If:
	**
	** (iCol < p->nColumn) -> The value of the iCol'th user column.
	** (iCol == p->nColumn) -> Magic column with the same name as the table.
	** (iCol == p->nColumn+1) -> Docid column
	** (iCol == p->nColumn+2) -> Langid column
	*/
	static int fts3ColumnMethod(
	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 */
	){
	int rc = SQLITE_OK; /* Return Code */
	Fts3Cursor pCsr = (Fts3Cursor ) pCursor;
	Fts3Table p = (Fts3Table )pCursor->pVtab;

	/* The column value supplied by SQLite must be in range. */
	assert( iCol>=0 && iCol<=p->nColumn+2 );

	switch( iCol-p->nColumn ){
	case 0:
	/* The special 'table-name' column */
	sqlite3_result_pointer(pCtx, pCsr, "fts3cursor", 0);
	break;

	case 1:
	/* The docid column */
	sqlite3_result_int64(pCtx, pCsr->iPrevId);
	break;

	case 2:
	if( pCsr->pExpr ){
	sqlite3_result_int64(pCtx, pCsr->iLangid);
	break;
	}else if( p->zLanguageid==0 ){
	sqlite3_result_int(pCtx, 0);
	break;
	}else{
	iCol = p->nColumn;
	/* no break */ deliberate_fall_through
	}

	default:
	/* A user column. Or, if this is a full-table scan, possibly the
	** language-id column. Seek the cursor. */
	rc = fts3CursorSeek(0, pCsr);
	if( rc==SQLITE_OK && sqlite3_data_count(pCsr->pStmt)-1>iCol ){
	sqlite3_result_value(pCtx, sqlite3_column_value(pCsr->pStmt, iCol+1));
	}
	break;
	}

	assert( ((Fts3Table *)pCsr->base.pVtab)->pSegments==0 );
	return 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.
	*/
	static int fts3UpdateMethod(
	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 */
	){
	return sqlite3Fts3UpdateMethod(pVtab, nArg, apVal, pRowid);
	}

	/*
	** Implementation of xSync() method. Flush the contents of the pending-terms
	** hash-table to the database.
	*/
	static int fts3SyncMethod(sqlite3_vtab *pVtab){

	/* Following an incremental-merge operation, assuming that the input
	** segments are not completely consumed (the usual case), they are updated
	** in place to remove the entries that have already been merged. This
	** involves updating the leaf block that contains the smallest unmerged
	** entry and each block (if any) between the leaf and the root node. So
	** if the height of the input segment b-trees is N, and input segments
	** are merged eight at a time, updating the input segments at the end
	** of an incremental-merge requires writing (8*(1+N)) blocks. N is usually
	** small - often between 0 and 2. So the overhead of the incremental
	** merge is somewhere between 8 and 24 blocks. To avoid this overhead
	** dwarfing the actual productive work accomplished, the incremental merge
	** is only attempted if it will write at least 64 leaf blocks. Hence
	** nMinMerge.
	**
	** Of course, updating the input segments also involves deleting a bunch
	** of blocks from the segments table. But this is not considered overhead
	** as it would also be required by a crisis-merge that used the same input
	** segments.
	*/
	const u32 nMinMerge = 64; /* Minimum amount of incr-merge work to do */

	Fts3Table p = (Fts3Table)pVtab;
	int rc;
	i64 iLastRowid = sqlite3_last_insert_rowid(p->db);

	rc = sqlite3Fts3PendingTermsFlush(p);
	if( rc==SQLITE_OK
	&& p->nLeafAdd>(nMinMerge/16)
	&& p->nAutoincrmerge && p->nAutoincrmerge!=0xff
	){
	int mxLevel = 0; /* Maximum relative level value in db */
	int A; /* Incr-merge parameter A */

	rc = sqlite3Fts3MaxLevel(p, &mxLevel);
	assert( rc==SQLITE_OK \|\| mxLevel==0 );
	A = p->nLeafAdd * mxLevel;
	A += (A/2);
	if( A>(int)nMinMerge ) rc = sqlite3Fts3Incrmerge(p, A, p->nAutoincrmerge);
	}
	sqlite3Fts3SegmentsClose(p);
	sqlite3_set_last_insert_rowid(p->db, iLastRowid);
	return rc;
	}

	/*
	** If it is currently unknown whether or not the FTS table has an %_stat
	** table (if p->bHasStat==2), attempt to determine this (set p->bHasStat
	** to 0 or 1). Return SQLITE_OK if successful, or an SQLite error code
	** if an error occurs.
	*/
	static int fts3SetHasStat(Fts3Table *p){
	int rc = SQLITE_OK;
	if( p->bHasStat==2 ){
	char *zTbl = sqlite3_mprintf("%s_stat", p->zName);
	if( zTbl ){
	int res = sqlite3_table_column_metadata(p->db, p->zDb, zTbl, 0,0,0,0,0,0);
	sqlite3_free(zTbl);
	p->bHasStat = (res==SQLITE_OK);
	}else{
	rc = SQLITE_NOMEM;
	}
	}
	return rc;
	}

	/*
	** Implementation of xBegin() method.
	*/
	static int fts3BeginMethod(sqlite3_vtab *pVtab){
	Fts3Table p = (Fts3Table)pVtab;
	int rc;
	UNUSED_PARAMETER(pVtab);
	assert( p->pSegments==0 );
	assert( p->nPendingData==0 );
	assert( p->inTransaction!=1 );
	p->nLeafAdd = 0;
	rc = fts3SetHasStat(p);
	#ifdef SQLITE_DEBUG
	if( rc==SQLITE_OK ){
	p->inTransaction = 1;
	p->mxSavepoint = -1;
	}
	#endif
	return rc;
	}

	/*
	** 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 fts3SyncMethod().
	*/
	static int fts3CommitMethod(sqlite3_vtab *pVtab){
	TESTONLY( Fts3Table p = (Fts3Table)pVtab );
	UNUSED_PARAMETER(pVtab);
	assert( p->nPendingData==0 );
	assert( p->inTransaction!=0 );
	assert( p->pSegments==0 );
	TESTONLY( p->inTransaction = 0 );
	TESTONLY( p->mxSavepoint = -1; );
	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 fts3RollbackMethod(sqlite3_vtab *pVtab){
	Fts3Table p = (Fts3Table)pVtab;
	sqlite3Fts3PendingTermsClear(p);
	assert( p->inTransaction!=0 );
	TESTONLY( p->inTransaction = 0 );
	TESTONLY( p->mxSavepoint = -1; );
	return SQLITE_OK;
	}

	/*
	** When called, *ppPoslist must point to the byte immediately following the
	** end of a position-list. i.e. ( (*ppPoslist)[-1]==POS_END ). This function
	** moves *ppPoslist so that it instead points to the first byte of the
	** same position list.
	*/
	static void fts3ReversePoslist(char pStart, char *ppPoslist){
	char p = &(ppPoslist)[-2];
	char c = 0;

	/* Skip backwards passed any trailing 0x00 bytes added by NearTrim() */
	while( p>pStart && (c=*p--)==0 );

	/* Search backwards for a varint with value zero (the end of the previous
	** poslist). This is an 0x00 byte preceded by some byte that does not
	** have the 0x80 bit set. */
	while( p>pStart && (*p & 0x80) \| c ){
	c = *p--;
	}
	assert( p==pStart \|\| c==0 );

	/* At this point p points to that preceding byte without the 0x80 bit
	** set. So to find the start of the poslist, skip forward 2 bytes then
	** over a varint.
	**
	** Normally. The other case is that p==pStart and the poslist to return
	** is the first in the doclist. In this case do not skip forward 2 bytes.
	** The second part of the if condition (c==0 && *ppPoslist>&p[2])
	** is required for cases where the first byte of a doclist and the
	** doclist is empty. For example, if the first docid is 10, a doclist
	** that begins with:
	**
	** 0x0A 0x00 <next docid delta varint>
	*/
	if( p>pStart \|\| (c==0 && *ppPoslist>&p[2]) ){ p = &p[2]; }
	while( *p++&0x80 );
	*ppPoslist = p;
	}

	/*
	** Helper function used by the implementation of the overloaded snippet(),
	** offsets() and optimize() SQL functions.
	**
	** If the value passed as the third argument is a blob of size
	** sizeof(Fts3Cursor*), then the blob contents are copied to the
	** output variable *ppCsr and SQLITE_OK is returned. Otherwise, an error
	** message is written to context pContext and SQLITE_ERROR returned. The
	** string passed via zFunc is used as part of the error message.
	*/
	static int fts3FunctionArg(
	sqlite3_context pContext, / SQL function call context */
	const char zFunc, / Function name */
	sqlite3_value pVal, / argv[0] passed to function */
	Fts3Cursor *ppCsr / OUT: Store cursor handle here */
	){
	int rc;
	ppCsr = (Fts3Cursor)sqlite3_value_pointer(pVal, "fts3cursor");
	if( (*ppCsr)!=0 ){
	rc = SQLITE_OK;
	}else{
	char *zErr = sqlite3_mprintf("illegal first argument to %s", zFunc);
	sqlite3_result_error(pContext, zErr, -1);
	sqlite3_free(zErr);
	rc = SQLITE_ERROR;
	}
	return rc;
	}

	/*
	** Implementation of the snippet() function for FTS3
	*/
	static void fts3SnippetFunc(
	sqlite3_context pContext, / SQLite function call context */
	int nVal, /* Size of apVal[] array */
	sqlite3_value *apVal / Array of arguments */
	){
	Fts3Cursor pCsr; / Cursor handle passed through apVal[0] */
	const char *zStart = "<b>";
	const char *zEnd = "</b>";
	const char *zEllipsis = "<b>...</b>";
	int iCol = -1;
	int nToken = 15; /* Default number of tokens in snippet */

	/* There must be at least one argument passed to this function (otherwise
	** the non-overloaded version would have been called instead of this one).
	*/
	assert( nVal>=1 );

	if( nVal>6 ){
	sqlite3_result_error(pContext,
	"wrong number of arguments to function snippet()", -1);
	return;
	}
	if( fts3FunctionArg(pContext, "snippet", apVal[0], &pCsr) ) return;

	switch( nVal ){
	case 6: nToken = sqlite3_value_int(apVal[5]);
	/* no break */ deliberate_fall_through
	case 5: iCol = sqlite3_value_int(apVal[4]);
	/* no break */ deliberate_fall_through
	case 4: zEllipsis = (const char*)sqlite3_value_text(apVal[3]);
	/* no break */ deliberate_fall_through
	case 3: zEnd = (const char*)sqlite3_value_text(apVal[2]);
	/* no break */ deliberate_fall_through
	case 2: zStart = (const char*)sqlite3_value_text(apVal[1]);
	}
	if( !zEllipsis \|\| !zEnd \|\| !zStart ){
	sqlite3_result_error_nomem(pContext);
	}else if( nToken==0 ){
	sqlite3_result_text(pContext, "", -1, SQLITE_STATIC);
	}else if( SQLITE_OK==fts3CursorSeek(pContext, pCsr) ){
	sqlite3Fts3Snippet(pContext, pCsr, zStart, zEnd, zEllipsis, iCol, nToken);
	}
	}

	/*
	** Implementation of the offsets() function for FTS3
	*/
	static void fts3OffsetsFunc(
	sqlite3_context pContext, / SQLite function call context */
	int nVal, /* Size of argument array */
	sqlite3_value *apVal / Array of arguments */
	){
	Fts3Cursor pCsr; / Cursor handle passed through apVal[0] */

	UNUSED_PARAMETER(nVal);

	assert( nVal==1 );
	if( fts3FunctionArg(pContext, "offsets", apVal[0], &pCsr) ) return;
	assert( pCsr );
	if( SQLITE_OK==fts3CursorSeek(pContext, pCsr) ){
	sqlite3Fts3Offsets(pContext, pCsr);
	}
	}

	/*
	** Implementation of the special optimize() function for FTS3. This
	** function merges all segments in the database to a single segment.
	** Example usage is:
	**
	** SELECT optimize(t) FROM t LIMIT 1;
	**
	** where 't' is the name of an FTS3 table.
	*/
	static void fts3OptimizeFunc(
	sqlite3_context pContext, / SQLite function call context */
	int nVal, /* Size of argument array */
	sqlite3_value *apVal / Array of arguments */
	){
	int rc; /* Return code */
	Fts3Table p; / Virtual table handle */
	Fts3Cursor pCursor; / Cursor handle passed through apVal[0] */

	UNUSED_PARAMETER(nVal);

	assert( nVal==1 );
	if( fts3FunctionArg(pContext, "optimize", apVal[0], &pCursor) ) return;
	p = (Fts3Table *)pCursor->base.pVtab;
	assert( p );

	rc = sqlite3Fts3Optimize(p);

	switch( rc ){
	case SQLITE_OK:
	sqlite3_result_text(pContext, "Index optimized", -1, SQLITE_STATIC);
	break;
	case SQLITE_DONE:
	sqlite3_result_text(pContext, "Index already optimal", -1, SQLITE_STATIC);
	break;
	default:
	sqlite3_result_error_code(pContext, rc);
	break;
	}
	}

	/*
	** Implementation of the matchinfo() function for FTS3
	*/
	static void fts3MatchinfoFunc(
	sqlite3_context pContext, / SQLite function call context */
	int nVal, /* Size of argument array */
	sqlite3_value *apVal / Array of arguments */
	){
	Fts3Cursor pCsr; / Cursor handle passed through apVal[0] */
	assert( nVal==1 \|\| nVal==2 );
	if( SQLITE_OK==fts3FunctionArg(pContext, "matchinfo", apVal[0], &pCsr) ){
	const char *zArg = 0;
	if( nVal>1 ){
	zArg = (const char *)sqlite3_value_text(apVal[1]);
	}
	sqlite3Fts3Matchinfo(pContext, pCsr, zArg);
	}
	}

	/*
	** This routine implements the xFindFunction method for the FTS3
	** virtual table.
	*/
	static int fts3FindFunctionMethod(
	sqlite3_vtab pVtab, / Virtual table handle */
	int nArg, /* Number of SQL function arguments */
	const char zName, / Name of SQL function */
	void (*pxFunc)(sqlite3_context,int,sqlite3_value*), / OUT: Result */
	void *ppArg / Unused */
	){
	struct Overloaded {
	const char *zName;
	void (xFunc)(sqlite3_context,int,sqlite3_value**);
	} aOverload[] = {
	{ "snippet", fts3SnippetFunc },
	{ "offsets", fts3OffsetsFunc },
	{ "optimize", fts3OptimizeFunc },
	{ "matchinfo", fts3MatchinfoFunc },
	};
	int i; /* Iterator variable */

	UNUSED_PARAMETER(pVtab);
	UNUSED_PARAMETER(nArg);
	UNUSED_PARAMETER(ppArg);

	for(i=0; i<SizeofArray(aOverload); i++){
	if( strcmp(zName, aOverload[i].zName)==0 ){
	*pxFunc = aOverload[i].xFunc;
	return 1;
	}
	}

	/* No function of the specified name was found. Return 0. */
	return 0;
	}

	/*
	** Implementation of FTS3 xRename method. Rename an fts3 table.
	*/
	static int fts3RenameMethod(
	sqlite3_vtab pVtab, / Virtual table handle */
	const char zName / New name of table */
	){
	Fts3Table p = (Fts3Table )pVtab;
	sqlite3 db = p->db; / Database connection */
	int rc; /* Return Code */

	/* At this point it must be known if the %_stat table exists or not.
	** So bHasStat may not be 2. */
	rc = fts3SetHasStat(p);

	/* As it happens, the pending terms table is always empty here. This is
	** because an "ALTER TABLE RENAME TABLE" statement inside a transaction
	** always opens a savepoint transaction. And the xSavepoint() method
	** flushes the pending terms table. But leave the (no-op) call to
	** PendingTermsFlush() in in case that changes.
	*/
	assert( p->nPendingData==0 );
	if( rc==SQLITE_OK ){
	rc = sqlite3Fts3PendingTermsFlush(p);
	}

	p->bIgnoreSavepoint = 1;

	if( p->zContentTbl==0 ){
	fts3DbExec(&rc, db,
	"ALTER TABLE %Q.'%q_content' RENAME TO '%q_content';",
	p->zDb, p->zName, zName
	);
	}

	if( p->bHasDocsize ){
	fts3DbExec(&rc, db,
	"ALTER TABLE %Q.'%q_docsize' RENAME TO '%q_docsize';",
	p->zDb, p->zName, zName
	);
	}
	if( p->bHasStat ){
	fts3DbExec(&rc, db,
	"ALTER TABLE %Q.'%q_stat' RENAME TO '%q_stat';",
	p->zDb, p->zName, zName
	);
	}
	fts3DbExec(&rc, db,
	"ALTER TABLE %Q.'%q_segments' RENAME TO '%q_segments';",
	p->zDb, p->zName, zName
	);
	fts3DbExec(&rc, db,
	"ALTER TABLE %Q.'%q_segdir' RENAME TO '%q_segdir';",
	p->zDb, p->zName, zName
	);

	p->bIgnoreSavepoint = 0;
	return rc;
	}

	/*
	** The xSavepoint() method.
	**
	** Flush the contents of the pending-terms table to disk.
	*/
	static int fts3SavepointMethod(sqlite3_vtab *pVtab, int iSavepoint){
	int rc = SQLITE_OK;
	Fts3Table pTab = (Fts3Table)pVtab;
	assert( pTab->inTransaction );
	assert( pTab->mxSavepoint<=iSavepoint );
	TESTONLY( pTab->mxSavepoint = iSavepoint );

	if( pTab->bIgnoreSavepoint==0 ){
	if( fts3HashCount(&pTab->aIndex[0].hPending)>0 ){
	char *zSql = sqlite3_mprintf("INSERT INTO %Q.%Q(%Q) VALUES('flush')",
	pTab->zDb, pTab->zName, pTab->zName
	);
	if( zSql ){
	pTab->bIgnoreSavepoint = 1;
	rc = sqlite3_exec(pTab->db, zSql, 0, 0, 0);
	pTab->bIgnoreSavepoint = 0;
	sqlite3_free(zSql);
	}else{
	rc = SQLITE_NOMEM;
	}
	}
	if( rc==SQLITE_OK ){
	pTab->iSavepoint = iSavepoint+1;
	}
	}
	return rc;
	}

	/*
	** The xRelease() method.
	**
	** This is a no-op.
	*/
	static int fts3ReleaseMethod(sqlite3_vtab *pVtab, int iSavepoint){
	Fts3Table pTab = (Fts3Table)pVtab;
	assert( pTab->inTransaction );
	assert( pTab->mxSavepoint >= iSavepoint );
	TESTONLY( pTab->mxSavepoint = iSavepoint-1 );
	pTab->iSavepoint = iSavepoint;
	return SQLITE_OK;
	}

	/*
	** The xRollbackTo() method.
	**
	** Discard the contents of the pending terms table.
	*/
	static int fts3RollbackToMethod(sqlite3_vtab *pVtab, int iSavepoint){
	Fts3Table pTab = (Fts3Table)pVtab;
	UNUSED_PARAMETER(iSavepoint);
	assert( pTab->inTransaction );
	TESTONLY( pTab->mxSavepoint = iSavepoint );
	if( (iSavepoint+1)<=pTab->iSavepoint ){
	sqlite3Fts3PendingTermsClear(pTab);
	}
	return SQLITE_OK;
	}

	/*
	** Return true if zName is the extension on one of the shadow tables used
	** by this module.
	*/
	static int fts3ShadowName(const char *zName){
	static const char *azName[] = {
	"content", "docsize", "segdir", "segments", "stat",
	};
	unsigned int i;
	for(i=0; i<sizeof(azName)/sizeof(azName[0]); i++){
	if( sqlite3_stricmp(zName, azName[i])==0 ) return 1;
	}
	return 0;
	}

	/*
	** Implementation of the xIntegrity() method on the FTS3/FTS4 virtual
	** table.
	*/
	static int fts3IntegrityMethod(
	sqlite3_vtab pVtab, / The virtual table to be checked */
	const char zSchema, / Name of schema in which pVtab lives */
	const char zTabname, / Name of the pVTab table */
	int isQuick, /* True if this is a quick_check */
	char *pzErr / Write error message here */
	){
	Fts3Table p = (Fts3Table)pVtab;
	int rc = SQLITE_OK;
	int bOk = 0;

	UNUSED_PARAMETER(isQuick);
	rc = sqlite3Fts3IntegrityCheck(p, &bOk);
	assert( rc!=SQLITE_CORRUPT_VTAB );
	if( rc==SQLITE_ERROR \|\| (rc&0xFF)==SQLITE_CORRUPT ){
	*pzErr = sqlite3_mprintf("unable to validate the inverted index for"
	" FTS%d table %s.%s: %s",
	p->bFts4 ? 4 : 3, zSchema, zTabname, sqlite3_errstr(rc));
	if( *pzErr ) rc = SQLITE_OK;
	}else if( rc==SQLITE_OK && bOk==0 ){
	*pzErr = sqlite3_mprintf("malformed inverted index for FTS%d table %s.%s",
	p->bFts4 ? 4 : 3, zSchema, zTabname);
	if( *pzErr==0 ) rc = SQLITE_NOMEM;
	}
	sqlite3Fts3SegmentsClose(p);
	return rc;
	}



	static const sqlite3_module fts3Module = {
	/* iVersion */ 4,
	/* xCreate */ fts3CreateMethod,
	/* xConnect */ fts3ConnectMethod,
	/* xBestIndex */ fts3BestIndexMethod,
	/* xDisconnect */ fts3DisconnectMethod,
	/* xDestroy */ fts3DestroyMethod,
	/* xOpen */ fts3OpenMethod,
	/* xClose */ fts3CloseMethod,
	/* xFilter */ fts3FilterMethod,
	/* xNext */ fts3NextMethod,
	/* xEof */ fts3EofMethod,
	/* xColumn */ fts3ColumnMethod,
	/* xRowid */ fts3RowidMethod,
	/* xUpdate */ fts3UpdateMethod,
	/* xBegin */ fts3BeginMethod,
	/* xSync */ fts3SyncMethod,
	/* xCommit */ fts3CommitMethod,
	/* xRollback */ fts3RollbackMethod,
	/* xFindFunction */ fts3FindFunctionMethod,
	/* xRename */ fts3RenameMethod,
	/* xSavepoint */ fts3SavepointMethod,
	/* xRelease */ fts3ReleaseMethod,
	/* xRollbackTo */ fts3RollbackToMethod,
	/* xShadowName */ fts3ShadowName,
	/* xIntegrity */ fts3IntegrityMethod,
	};

	/*
	** This function is registered as the module destructor (called when an
	** FTS3 enabled database connection is closed). It frees the memory
	** allocated for the tokenizer hash table.
	*/
	static void hashDestroy(void *p){
	Fts3HashWrapper pHash = (Fts3HashWrapper )p;
	pHash->nRef--;
	if( pHash->nRef<=0 ){
	sqlite3Fts3HashClear(&pHash->hash);
	sqlite3_free(pHash);
	}
	}

	/*
	** The fts3 built-in tokenizers - "simple", "porter" and "icu"- are
	** implemented in files fts3_tokenizer1.c, fts3_porter.c and fts3_icu.c
	** respectively. The following three forward declarations are for functions
	** declared in these files used to retrieve the respective implementations.
	**
	** Calling sqlite3Fts3SimpleTokenizerModule() sets the value pointed
	** to by the argument to point to the "simple" tokenizer implementation.
	** And so on.
	*/
	void sqlite3Fts3SimpleTokenizerModule(sqlite3_tokenizer_module const**ppModule);
	void sqlite3Fts3PorterTokenizerModule(sqlite3_tokenizer_module const**ppModule);
	#ifndef SQLITE_DISABLE_FTS3_UNICODE
	void sqlite3Fts3UnicodeTokenizer(sqlite3_tokenizer_module const**ppModule);
	#endif
	#ifdef SQLITE_ENABLE_ICU
	void sqlite3Fts3IcuTokenizerModule(sqlite3_tokenizer_module const**ppModule);
	#endif

	/*
	** Initialize the fts3 extension. If this extension is built as part
	** of the sqlite library, then this function is called directly by
	** SQLite. If fts3 is built as a dynamically loadable extension, this
	** function is called by the sqlite3_extension_init() entry point.
	*/
	int sqlite3Fts3Init(sqlite3 *db){
	int rc = SQLITE_OK;
	Fts3HashWrapper *pHash = 0;
	const sqlite3_tokenizer_module *pSimple = 0;
	const sqlite3_tokenizer_module *pPorter = 0;
	#ifndef SQLITE_DISABLE_FTS3_UNICODE
	const sqlite3_tokenizer_module *pUnicode = 0;
	#endif

	#ifdef SQLITE_ENABLE_ICU
	const sqlite3_tokenizer_module *pIcu = 0;
	sqlite3Fts3IcuTokenizerModule(&pIcu);
	#endif

	#ifndef SQLITE_DISABLE_FTS3_UNICODE
	sqlite3Fts3UnicodeTokenizer(&pUnicode);
	#endif

	#ifdef SQLITE_TEST
	rc = sqlite3Fts3InitTerm(db);
	if( rc!=SQLITE_OK ) return rc;
	#endif

	rc = sqlite3Fts3InitAux(db);
	if( rc!=SQLITE_OK ) return rc;

	sqlite3Fts3SimpleTokenizerModule(&pSimple);
	sqlite3Fts3PorterTokenizerModule(&pPorter);

	/* Allocate and initialize the hash-table used to store tokenizers. */
	pHash = sqlite3_malloc(sizeof(Fts3HashWrapper));
	if( !pHash ){
	rc = SQLITE_NOMEM;
	}else{
	sqlite3Fts3HashInit(&pHash->hash, FTS3_HASH_STRING, 1);
	pHash->nRef = 0;
	}

	/* Load the built-in tokenizers into the hash table */
	if( rc==SQLITE_OK ){
	if( sqlite3Fts3HashInsert(&pHash->hash, "simple", 7, (void *)pSimple)
	\|\| sqlite3Fts3HashInsert(&pHash->hash, "porter", 7, (void *)pPorter)

	#ifndef SQLITE_DISABLE_FTS3_UNICODE
	\|\| sqlite3Fts3HashInsert(&pHash->hash, "unicode61", 10, (void *)pUnicode)
	#endif
	#ifdef SQLITE_ENABLE_ICU
	\|\| (pIcu && sqlite3Fts3HashInsert(&pHash->hash, "icu", 4, (void *)pIcu))
	#endif
	){
	rc = SQLITE_NOMEM;
	}
	}

	#ifdef SQLITE_TEST
	if( rc==SQLITE_OK ){
	rc = sqlite3Fts3ExprInitTestInterface(db, &pHash->hash);
	}
	#endif

	/* Create the virtual table wrapper around the hash-table and overload
	** the four scalar functions. If this is successful, register the
	** module with sqlite.
	*/
	if( SQLITE_OK==rc
	&& SQLITE_OK==(rc=sqlite3Fts3InitHashTable(db,&pHash->hash,"fts3_tokenizer"))
	&& SQLITE_OK==(rc = sqlite3_overload_function(db, "snippet", -1))
	&& SQLITE_OK==(rc = sqlite3_overload_function(db, "offsets", 1))
	&& SQLITE_OK==(rc = sqlite3_overload_function(db, "matchinfo", 1))
	&& SQLITE_OK==(rc = sqlite3_overload_function(db, "matchinfo", 2))
	&& SQLITE_OK==(rc = sqlite3_overload_function(db, "optimize", 1))
	){
	pHash->nRef++;
	rc = sqlite3_create_module_v2(
	db, "fts3", &fts3Module, (void *)pHash, hashDestroy
	);
	if( rc==SQLITE_OK ){
	pHash->nRef++;
	rc = sqlite3_create_module_v2(
	db, "fts4", &fts3Module, (void *)pHash, hashDestroy
	);
	}
	if( rc==SQLITE_OK ){
	pHash->nRef++;
	rc = sqlite3Fts3InitTok(db, (void *)pHash, hashDestroy);
	}
	return rc;
	}


	/* An error has occurred. Delete the hash table and return the error code. */
	assert( rc!=SQLITE_OK );
	if( pHash ){
	sqlite3Fts3HashClear(&pHash->hash);
	sqlite3_free(pHash);
	}
	return rc;
	}

	/*
	** Allocate an Fts3MultiSegReader for each token in the expression headed
	** by pExpr.
	**
	** An Fts3SegReader object is a cursor that can seek or scan a range of
	** entries within a single segment b-tree. An Fts3MultiSegReader uses multiple
	** Fts3SegReader objects internally to provide an interface to seek or scan
	** within the union of all segments of a b-tree. Hence the name.
	**
	** If the allocated Fts3MultiSegReader just seeks to a single entry in a
	** segment b-tree (if the term is not a prefix or it is a prefix for which
	** there exists prefix b-tree of the right length) then it may be traversed
	** and merged incrementally. Otherwise, it has to be merged into an in-memory
	** doclist and then traversed.
	*/
	static void fts3EvalAllocateReaders(
	Fts3Cursor pCsr, / FTS cursor handle */
	Fts3Expr pExpr, / Allocate readers for this expression */
	int pnToken, / OUT: Total number of tokens in phrase. */
	int pnOr, / OUT: Total number of OR nodes in expr. */
	int pRc / IN/OUT: Error code */
	){
	if( pExpr && SQLITE_OK==*pRc ){
	if( pExpr->eType==FTSQUERY_PHRASE ){
	int i;
	int nToken = pExpr->pPhrase->nToken;
	*pnToken += nToken;
	for(i=0; i<nToken; i++){
	Fts3PhraseToken *pToken = &pExpr->pPhrase->aToken[i];
	int rc = fts3TermSegReaderCursor(pCsr,
	pToken->z, pToken->n, pToken->isPrefix, &pToken->pSegcsr
	);
	if( rc!=SQLITE_OK ){
	*pRc = rc;
	return;
	}
	}
	assert( pExpr->pPhrase->iDoclistToken==0 );
	pExpr->pPhrase->iDoclistToken = -1;
	}else{
	*pnOr += (pExpr->eType==FTSQUERY_OR);
	fts3EvalAllocateReaders(pCsr, pExpr->pLeft, pnToken, pnOr, pRc);
	fts3EvalAllocateReaders(pCsr, pExpr->pRight, pnToken, pnOr, pRc);
	}
	}
	}

	/*
	** Arguments pList/nList contain the doclist for token iToken of phrase p.
	** It is merged into the main doclist stored in p->doclist.aAll/nAll.
	**
	** This function assumes that pList points to a buffer allocated using
	** sqlite3_malloc(). This function takes responsibility for eventually
	** freeing the buffer.
	**
	** SQLITE_OK is returned if successful, or SQLITE_NOMEM if an error occurs.
	*/
	static int fts3EvalPhraseMergeToken(
	Fts3Table pTab, / FTS Table pointer */
	Fts3Phrase p, / Phrase to merge pList/nList into */
	int iToken, /* Token pList/nList corresponds to */
	char pList, / Pointer to doclist */
	int nList /* Number of bytes in pList */
	){
	int rc = SQLITE_OK;
	assert( iToken!=p->iDoclistToken );

	if( pList==0 ){
	sqlite3_free(p->doclist.aAll);
	p->doclist.aAll = 0;
	p->doclist.nAll = 0;
	}

	else if( p->iDoclistToken<0 ){
	p->doclist.aAll = pList;
	p->doclist.nAll = nList;
	}

	else if( p->doclist.aAll==0 ){
	sqlite3_free(pList);
	}

	else {
	char *pLeft;
	char *pRight;
	int nLeft;
	int nRight;
	int nDiff;

	if( p->iDoclistToken<iToken ){
	pLeft = p->doclist.aAll;
	nLeft = p->doclist.nAll;
	pRight = pList;
	nRight = nList;
	nDiff = iToken - p->iDoclistToken;
	}else{
	pRight = p->doclist.aAll;
	nRight = p->doclist.nAll;
	pLeft = pList;
	nLeft = nList;
	nDiff = p->iDoclistToken - iToken;
	}

	rc = fts3DoclistPhraseMerge(
	pTab->bDescIdx, nDiff, pLeft, nLeft, &pRight, &nRight
	);
	sqlite3_free(pLeft);
	p->doclist.aAll = pRight;
	p->doclist.nAll = nRight;
	}

	if( iToken>p->iDoclistToken ) p->iDoclistToken = iToken;
	return rc;
	}

	/*
	** Load the doclist for phrase p into p->doclist.aAll/nAll. The loaded doclist
	** does not take deferred tokens into account.
	**
	** SQLITE_OK is returned if no error occurs, otherwise an SQLite error code.
	*/
	static int fts3EvalPhraseLoad(
	Fts3Cursor pCsr, / FTS Cursor handle */
	Fts3Phrase p / Phrase object */
	){
	Fts3Table pTab = (Fts3Table )pCsr->base.pVtab;
	int iToken;
	int rc = SQLITE_OK;

	for(iToken=0; rc==SQLITE_OK && iToken<p->nToken; iToken++){
	Fts3PhraseToken *pToken = &p->aToken[iToken];
	assert( pToken->pDeferred==0 \|\| pToken->pSegcsr==0 );

	if( pToken->pSegcsr ){
	int nThis = 0;
	char *pThis = 0;
	rc = fts3TermSelect(pTab, pToken, p->iColumn, &nThis, &pThis);
	if( rc==SQLITE_OK ){
	rc = fts3EvalPhraseMergeToken(pTab, p, iToken, pThis, nThis);
	}
	}
	assert( pToken->pSegcsr==0 );
	}

	return rc;
	}

	#ifndef SQLITE_DISABLE_FTS4_DEFERRED
	/*
	** This function is called on each phrase after the position lists for
	** any deferred tokens have been loaded into memory. It updates the phrases
	** current position list to include only those positions that are really
	** instances of the phrase (after considering deferred tokens). If this
	** means that the phrase does not appear in the current row, doclist.pList
	** and doclist.nList are both zeroed.
	**
	** SQLITE_OK is returned if no error occurs, otherwise an SQLite error code.
	*/
	static int fts3EvalDeferredPhrase(Fts3Cursor pCsr, Fts3Phrase pPhrase){
	int iToken; /* Used to iterate through phrase tokens */
	char aPoslist = 0; / Position list for deferred tokens */
	int nPoslist = 0; /* Number of bytes in aPoslist */
	int iPrev = -1; /* Token number of previous deferred token */
	char *aFree = (pPhrase->doclist.bFreeList ? pPhrase->doclist.pList : 0);

	for(iToken=0; iToken<pPhrase->nToken; iToken++){
	Fts3PhraseToken *pToken = &pPhrase->aToken[iToken];
	Fts3DeferredToken *pDeferred = pToken->pDeferred;

	if( pDeferred ){
	char *pList;
	int nList;
	int rc = sqlite3Fts3DeferredTokenList(pDeferred, &pList, &nList);
	if( rc!=SQLITE_OK ) return rc;

	if( pList==0 ){
	sqlite3_free(aPoslist);
	sqlite3_free(aFree);
	pPhrase->doclist.pList = 0;
	pPhrase->doclist.nList = 0;
	return SQLITE_OK;

	}else if( aPoslist==0 ){
	aPoslist = pList;
	nPoslist = nList;

	}else{
	char *aOut = pList;
	char *p1 = aPoslist;
	char *p2 = aOut;

	assert( iPrev>=0 );
	fts3PoslistPhraseMerge(&aOut, iToken-iPrev, 0, 1, &p1, &p2);
	sqlite3_free(aPoslist);
	aPoslist = pList;
	nPoslist = (int)(aOut - aPoslist);
	if( nPoslist==0 ){
	sqlite3_free(aPoslist);
	sqlite3_free(aFree);
	pPhrase->doclist.pList = 0;
	pPhrase->doclist.nList = 0;
	return SQLITE_OK;
	}
	}
	iPrev = iToken;
	}
	}

	if( iPrev>=0 ){
	int nMaxUndeferred = pPhrase->iDoclistToken;
	if( nMaxUndeferred<0 ){
	pPhrase->doclist.pList = aPoslist;
	pPhrase->doclist.nList = nPoslist;
	pPhrase->doclist.iDocid = pCsr->iPrevId;
	pPhrase->doclist.bFreeList = 1;
	}else{
	int nDistance;
	char *p1;
	char *p2;
	char *aOut;

	if( nMaxUndeferred>iPrev ){
	p1 = aPoslist;
	p2 = pPhrase->doclist.pList;
	nDistance = nMaxUndeferred - iPrev;
	}else{
	p1 = pPhrase->doclist.pList;
	p2 = aPoslist;
	nDistance = iPrev - nMaxUndeferred;
	}

	aOut = (char *)sqlite3Fts3MallocZero(nPoslist+FTS3_BUFFER_PADDING);
	if( !aOut ){
	sqlite3_free(aPoslist);
	return SQLITE_NOMEM;
	}

	pPhrase->doclist.pList = aOut;
	assert( p1 && p2 );
	if( fts3PoslistPhraseMerge(&aOut, nDistance, 0, 1, &p1, &p2) ){
	pPhrase->doclist.bFreeList = 1;
	pPhrase->doclist.nList = (int)(aOut - pPhrase->doclist.pList);
	}else{
	sqlite3_free(aOut);
	pPhrase->doclist.pList = 0;
	pPhrase->doclist.nList = 0;
	}
	sqlite3_free(aPoslist);
	}
	}

	if( pPhrase->doclist.pList!=aFree ) sqlite3_free(aFree);
	return SQLITE_OK;
	}
	#endif /* SQLITE_DISABLE_FTS4_DEFERRED */

	/*
	** Maximum number of tokens a phrase may have to be considered for the
	** incremental doclists strategy.
	*/
	#define MAX_INCR_PHRASE_TOKENS 4

	/*
	** This function is called for each Fts3Phrase in a full-text query
	** expression to initialize the mechanism for returning rows. Once this
	** function has been called successfully on an Fts3Phrase, it may be
	** used with fts3EvalPhraseNext() to iterate through the matching docids.
	**
	** If parameter bOptOk is true, then the phrase may (or may not) use the
	** incremental loading strategy. Otherwise, the entire doclist is loaded into
	** memory within this call.
	**
	** SQLITE_OK is returned if no error occurs, otherwise an SQLite error code.
	*/
	static int fts3EvalPhraseStart(Fts3Cursor pCsr, int bOptOk, Fts3Phrase p){
	Fts3Table pTab = (Fts3Table )pCsr->base.pVtab;
	int rc = SQLITE_OK; /* Error code */
	int i;

	/* Determine if doclists may be loaded from disk incrementally. This is
	** possible if the bOptOk argument is true, the FTS doclists will be
	** scanned in forward order, and the phrase consists of
	** MAX_INCR_PHRASE_TOKENS or fewer tokens, none of which are are "^first"
	** tokens or prefix tokens that cannot use a prefix-index. */
	int bHaveIncr = 0;
	int bIncrOk = (bOptOk
	&& pCsr->bDesc==pTab->bDescIdx
	&& p->nToken<=MAX_INCR_PHRASE_TOKENS && p->nToken>0
	#if defined(SQLITE_DEBUG) \|\| defined(SQLITE_TEST)
	&& pTab->bNoIncrDoclist==0
	#endif
	);
	for(i=0; bIncrOk==1 && i<p->nToken; i++){
	Fts3PhraseToken *pToken = &p->aToken[i];
	if( pToken->bFirst \|\| (pToken->pSegcsr!=0 && !pToken->pSegcsr->bLookup) ){
	bIncrOk = 0;
	}
	if( pToken->pSegcsr ) bHaveIncr = 1;
	}

	if( bIncrOk && bHaveIncr ){
	/* Use the incremental approach. */
	int iCol = (p->iColumn >= pTab->nColumn ? -1 : p->iColumn);
	for(i=0; rc==SQLITE_OK && i<p->nToken; i++){
	Fts3PhraseToken *pToken = &p->aToken[i];
	Fts3MultiSegReader *pSegcsr = pToken->pSegcsr;
	if( pSegcsr ){
	rc = sqlite3Fts3MsrIncrStart(pTab, pSegcsr, iCol, pToken->z, pToken->n);
	}
	}
	p->bIncr = 1;
	}else{
	/* Load the full doclist for the phrase into memory. */
	rc = fts3EvalPhraseLoad(pCsr, p);
	p->bIncr = 0;
	}

	assert( rc!=SQLITE_OK \|\| p->nToken<1 \|\| p->aToken[0].pSegcsr==0 \|\| p->bIncr );
	return rc;
	}

	/*
	** This function is used to iterate backwards (from the end to start)
	** through doclists. It is used by this module to iterate through phrase
	** doclists in reverse and by the fts3_write.c module to iterate through
	** pending-terms lists when writing to databases with "order=desc".
	**
	** The doclist may be sorted in ascending (parameter bDescIdx==0) or
	** descending (parameter bDescIdx==1) order of docid. Regardless, this
	** function iterates from the end of the doclist to the beginning.
	*/
	void sqlite3Fts3DoclistPrev(
	int bDescIdx, /* True if the doclist is desc */
	char aDoclist, / Pointer to entire doclist */
	int nDoclist, /* Length of aDoclist in bytes */
	char *ppIter, / IN/OUT: Iterator pointer */
	sqlite3_int64 piDocid, / IN/OUT: Docid pointer */
	int pnList, / OUT: List length pointer */
	u8 pbEof / OUT: End-of-file flag */
	){
	char p = ppIter;

	assert( nDoclist>0 );
	assert( *pbEof==0 );
	assert_fts3_nc( p \|\| *piDocid==0 );
	assert( !p \|\| (p>aDoclist && p<&aDoclist[nDoclist]) );

	if( p==0 ){
	sqlite3_int64 iDocid = 0;
	char *pNext = 0;
	char *pDocid = aDoclist;
	char *pEnd = &aDoclist[nDoclist];
	int iMul = 1;

	while( pDocid<pEnd ){
	sqlite3_int64 iDelta;
	pDocid += sqlite3Fts3GetVarint(pDocid, &iDelta);
	iDocid += (iMul * iDelta);
	pNext = pDocid;
	fts3PoslistCopy(0, &pDocid);
	while( pDocid<pEnd && *pDocid==0 ) pDocid++;
	iMul = (bDescIdx ? -1 : 1);
	}

	*pnList = (int)(pEnd - pNext);
	*ppIter = pNext;
	*piDocid = iDocid;
	}else{
	int iMul = (bDescIdx ? -1 : 1);
	sqlite3_int64 iDelta;
	fts3GetReverseVarint(&p, aDoclist, &iDelta);
	piDocid -= (iMul iDelta);

	if( p==aDoclist ){
	*pbEof = 1;
	}else{
	char *pSave = p;
	fts3ReversePoslist(aDoclist, &p);
	*pnList = (int)(pSave - p);
	}
	*ppIter = p;
	}
	}

	/*
	** Iterate forwards through a doclist.
	*/
	void sqlite3Fts3DoclistNext(
	int bDescIdx, /* True if the doclist is desc */
	char aDoclist, / Pointer to entire doclist */
	int nDoclist, /* Length of aDoclist in bytes */
	char *ppIter, / IN/OUT: Iterator pointer */
	sqlite3_int64 piDocid, / IN/OUT: Docid pointer */
	u8 pbEof / OUT: End-of-file flag */
	){
	char p = ppIter;

	assert( nDoclist>0 );
	assert( *pbEof==0 );
	assert_fts3_nc( p \|\| *piDocid==0 );
	assert( !p \|\| (p>=aDoclist && p<=&aDoclist[nDoclist]) );

	if( p==0 ){
	p = aDoclist;
	p += sqlite3Fts3GetVarint(p, piDocid);
	}else{
	fts3PoslistCopy(0, &p);
	while( p<&aDoclist[nDoclist] && *p==0 ) p++;
	if( p>=&aDoclist[nDoclist] ){
	*pbEof = 1;
	}else{
	sqlite3_int64 iVar;
	p += sqlite3Fts3GetVarint(p, &iVar);
	piDocid += ((bDescIdx ? -1 : 1) iVar);
	}
	}

	*ppIter = p;
	}

	/*
	** Advance the iterator pDL to the next entry in pDL->aAll/nAll. Set *pbEof
	** to true if EOF is reached.
	*/
	static void fts3EvalDlPhraseNext(
	Fts3Table *pTab,
	Fts3Doclist *pDL,
	u8 *pbEof
	){
	char pIter; / Used to iterate through aAll */
	char pEnd; / 1 byte past end of aAll */

	if( pDL->pNextDocid ){
	pIter = pDL->pNextDocid;
	assert( pDL->aAll!=0 \|\| pIter==0 );
	}else{
	pIter = pDL->aAll;
	}

	if( pIter==0 \|\| pIter>=(pEnd = pDL->aAll + pDL->nAll) ){
	/* We have already reached the end of this doclist. EOF. */
	*pbEof = 1;
	}else{
	sqlite3_int64 iDelta;
	pIter += sqlite3Fts3GetVarint(pIter, &iDelta);
	if( pTab->bDescIdx==0 \|\| pDL->pNextDocid==0 ){
	pDL->iDocid += iDelta;
	}else{
	pDL->iDocid -= iDelta;
	}
	pDL->pList = pIter;
	fts3PoslistCopy(0, &pIter);
	pDL->nList = (int)(pIter - pDL->pList);

	/* pIter now points just past the 0x00 that terminates the position-
	** list for document pDL->iDocid. However, if this position-list was
	** edited in place by fts3EvalNearTrim(), then pIter may not actually
	** point to the start of the next docid value. The following line deals
	** with this case by advancing pIter past the zero-padding added by
	** fts3EvalNearTrim(). */
	while( pIter<pEnd && *pIter==0 ) pIter++;

	pDL->pNextDocid = pIter;
	assert( pIter>=&pDL->aAll[pDL->nAll] \|\| *pIter );
	*pbEof = 0;
	}
	}

	/*
	** Helper type used by fts3EvalIncrPhraseNext() and incrPhraseTokenNext().
	*/
	typedef struct TokenDoclist TokenDoclist;
	struct TokenDoclist {
	int bIgnore;
	sqlite3_int64 iDocid;
	char *pList;
	int nList;
	};

	/*
	** Token pToken is an incrementally loaded token that is part of a
	** multi-token phrase. Advance it to the next matching document in the
	** database and populate output variable *p with the details of the new
	** entry. Or, if the iterator has reached EOF, set *pbEof to true.
	**
	** If an error occurs, return an SQLite error code. Otherwise, return
	** SQLITE_OK.
	*/
	static int incrPhraseTokenNext(
	Fts3Table pTab, / Virtual table handle */
	Fts3Phrase pPhrase, / Phrase to advance token of */
	int iToken, /* Specific token to advance */
	TokenDoclist p, / OUT: Docid and doclist for new entry */
	u8 pbEof / OUT: True if iterator is at EOF */
	){
	int rc = SQLITE_OK;

	if( pPhrase->iDoclistToken==iToken ){
	assert( p->bIgnore==0 );
	assert( pPhrase->aToken[iToken].pSegcsr==0 );
	fts3EvalDlPhraseNext(pTab, &pPhrase->doclist, pbEof);
	p->pList = pPhrase->doclist.pList;
	p->nList = pPhrase->doclist.nList;
	p->iDocid = pPhrase->doclist.iDocid;
	}else{
	Fts3PhraseToken *pToken = &pPhrase->aToken[iToken];
	assert( pToken->pDeferred==0 );
	assert( pToken->pSegcsr \|\| pPhrase->iDoclistToken>=0 );
	if( pToken->pSegcsr ){
	assert( p->bIgnore==0 );
	rc = sqlite3Fts3MsrIncrNext(
	pTab, pToken->pSegcsr, &p->iDocid, &p->pList, &p->nList
	);
	if( p->pList==0 ) *pbEof = 1;
	}else{
	p->bIgnore = 1;
	}
	}

	return rc;
	}


	/*
	** The phrase iterator passed as the second argument:
	**
	** * features at least one token that uses an incremental doclist, and
	**
	** * does not contain any deferred tokens.
	**
	** Advance it to the next matching documnent in the database and populate
	** the Fts3Doclist.pList and nList fields.
	**
	** If there is no "next" entry and no error occurs, then *pbEof is set to
	** 1 before returning. Otherwise, if no error occurs and the iterator is
	** successfully advanced, *pbEof is set to 0.
	**
	** If an error occurs, return an SQLite error code. Otherwise, return
	** SQLITE_OK.
	*/
	static int fts3EvalIncrPhraseNext(
	Fts3Cursor pCsr, / FTS Cursor handle */
	Fts3Phrase p, / Phrase object to advance to next docid */
	u8 pbEof / OUT: Set to 1 if EOF */
	){
	int rc = SQLITE_OK;
	Fts3Doclist *pDL = &p->doclist;
	Fts3Table pTab = (Fts3Table )pCsr->base.pVtab;
	u8 bEof = 0;

	/* This is only called if it is guaranteed that the phrase has at least
	** one incremental token. In which case the bIncr flag is set. */
	assert( p->bIncr==1 );

	if( p->nToken==1 ){
	rc = sqlite3Fts3MsrIncrNext(pTab, p->aToken[0].pSegcsr,
	&pDL->iDocid, &pDL->pList, &pDL->nList
	);
	if( pDL->pList==0 ) bEof = 1;
	}else{
	int bDescDoclist = pCsr->bDesc;
	struct TokenDoclist a[MAX_INCR_PHRASE_TOKENS];

	memset(a, 0, sizeof(a));
	assert( p->nToken<=MAX_INCR_PHRASE_TOKENS );
	assert( p->iDoclistToken<MAX_INCR_PHRASE_TOKENS );

	while( bEof==0 ){
	int bMaxSet = 0;
	sqlite3_int64 iMax = 0; /* Largest docid for all iterators */
	int i; /* Used to iterate through tokens */

	/* Advance the iterator for each token in the phrase once. */
	for(i=0; rc==SQLITE_OK && i<p->nToken && bEof==0; i++){
	rc = incrPhraseTokenNext(pTab, p, i, &a[i], &bEof);
	if( a[i].bIgnore==0 && (bMaxSet==0 \|\| DOCID_CMP(iMax, a[i].iDocid)<0) ){
	iMax = a[i].iDocid;
	bMaxSet = 1;
	}
	}
	assert( rc!=SQLITE_OK \|\| (p->nToken>=1 && a[p->nToken-1].bIgnore==0) );
	assert( rc!=SQLITE_OK \|\| bMaxSet );

	/* Keep advancing iterators until they all point to the same document */
	for(i=0; i<p->nToken; i++){
	while( rc==SQLITE_OK && bEof==0
	&& a[i].bIgnore==0 && DOCID_CMP(a[i].iDocid, iMax)<0
	){
	rc = incrPhraseTokenNext(pTab, p, i, &a[i], &bEof);
	if( DOCID_CMP(a[i].iDocid, iMax)>0 ){
	iMax = a[i].iDocid;
	i = 0;
	}
	}
	}

	/* Check if the current entries really are a phrase match */
	if( bEof==0 ){
	int nList = 0;
	int nByte = a[p->nToken-1].nList;
	char *aDoclist = sqlite3_malloc64((i64)nByte+FTS3_BUFFER_PADDING);
	if( !aDoclist ) return SQLITE_NOMEM;
	memcpy(aDoclist, a[p->nToken-1].pList, nByte+1);
	memset(&aDoclist[nByte], 0, FTS3_BUFFER_PADDING);

	for(i=0; i<(p->nToken-1); i++){
	if( a[i].bIgnore==0 ){
	char *pL = a[i].pList;
	char *pR = aDoclist;
	char *pOut = aDoclist;
	int nDist = p->nToken-1-i;
	int res = fts3PoslistPhraseMerge(&pOut, nDist, 0, 1, &pL, &pR);
	if( res==0 ) break;
	nList = (int)(pOut - aDoclist);
	}
	}
	if( i==(p->nToken-1) ){
	pDL->iDocid = iMax;
	pDL->pList = aDoclist;
	pDL->nList = nList;
	pDL->bFreeList = 1;
	break;
	}
	sqlite3_free(aDoclist);
	}
	}
	}

	*pbEof = bEof;
	return rc;
	}

	/*
	** Attempt to move the phrase iterator to point to the next matching docid.
	** If an error occurs, return an SQLite error code. Otherwise, return
	** SQLITE_OK.
	**
	** If there is no "next" entry and no error occurs, then *pbEof is set to
	** 1 before returning. Otherwise, if no error occurs and the iterator is
	** successfully advanced, *pbEof is set to 0.
	*/
	static int fts3EvalPhraseNext(
	Fts3Cursor pCsr, / FTS Cursor handle */
	Fts3Phrase p, / Phrase object to advance to next docid */
	u8 pbEof / OUT: Set to 1 if EOF */
	){
	int rc = SQLITE_OK;
	Fts3Doclist *pDL = &p->doclist;
	Fts3Table pTab = (Fts3Table )pCsr->base.pVtab;

	if( p->bIncr ){
	rc = fts3EvalIncrPhraseNext(pCsr, p, pbEof);
	}else if( pCsr->bDesc!=pTab->bDescIdx && pDL->nAll ){
	sqlite3Fts3DoclistPrev(pTab->bDescIdx, pDL->aAll, pDL->nAll,
	&pDL->pNextDocid, &pDL->iDocid, &pDL->nList, pbEof
	);
	pDL->pList = pDL->pNextDocid;
	}else{
	fts3EvalDlPhraseNext(pTab, pDL, pbEof);
	}

	return rc;
	}

	/*
	**
	** If *pRc is not SQLITE_OK when this function is called, it is a no-op.
	** Otherwise, fts3EvalPhraseStart() is called on all phrases within the
	** expression. Also the Fts3Expr.bDeferred variable is set to true for any
	** expressions for which all descendent tokens are deferred.
	**
	** If parameter bOptOk is zero, then it is guaranteed that the
	** Fts3Phrase.doclist.aAll/nAll variables contain the entire doclist for
	** each phrase in the expression (subject to deferred token processing).
	** Or, if bOptOk is non-zero, then one or more tokens within the expression
	** may be loaded incrementally, meaning doclist.aAll/nAll is not available.
	**
	** If an error occurs within this function, *pRc is set to an SQLite error
	** code before returning.
	*/
	static void fts3EvalStartReaders(
	Fts3Cursor pCsr, / FTS Cursor handle */
	Fts3Expr pExpr, / Expression to initialize phrases in */
	int pRc / IN/OUT: Error code */
	){
	if( pExpr && SQLITE_OK==*pRc ){
	if( pExpr->eType==FTSQUERY_PHRASE ){
	int nToken = pExpr->pPhrase->nToken;
	if( nToken ){
	int i;
	for(i=0; i<nToken; i++){
	if( pExpr->pPhrase->aToken[i].pDeferred==0 ) break;
	}
	pExpr->bDeferred = (i==nToken);
	}
	*pRc = fts3EvalPhraseStart(pCsr, 1, pExpr->pPhrase);
	}else{
	fts3EvalStartReaders(pCsr, pExpr->pLeft, pRc);
	fts3EvalStartReaders(pCsr, pExpr->pRight, pRc);
	pExpr->bDeferred = (pExpr->pLeft->bDeferred && pExpr->pRight->bDeferred);
	}
	}
	}

	/*
	** An array of the following structures is assembled as part of the process
	** of selecting tokens to defer before the query starts executing (as part
	** of the xFilter() method). There is one element in the array for each
	** token in the FTS expression.
	**
	** Tokens are divided into AND/NEAR clusters. All tokens in a cluster belong
	** to phrases that are connected only by AND and NEAR operators (not OR or
	** NOT). When determining tokens to defer, each AND/NEAR cluster is considered
	** separately. The root of a tokens AND/NEAR cluster is stored in
	** Fts3TokenAndCost.pRoot.
	*/
	typedef struct Fts3TokenAndCost Fts3TokenAndCost;
	struct Fts3TokenAndCost {
	Fts3Phrase pPhrase; / The phrase the token belongs to */
	int iToken; /* Position of token in phrase */
	Fts3PhraseToken pToken; / The token itself */
	Fts3Expr pRoot; / Root of NEAR/AND cluster */
	int nOvfl; /* Number of overflow pages to load doclist */
	int iCol; /* The column the token must match */
	};

	/*
	** This function is used to populate an allocated Fts3TokenAndCost array.
	**
	** If *pRc is not SQLITE_OK when this function is called, it is a no-op.
	** Otherwise, if an error occurs during execution, *pRc is set to an
	** SQLite error code.
	*/
	static void fts3EvalTokenCosts(
	Fts3Cursor pCsr, / FTS Cursor handle */
	Fts3Expr pRoot, / Root of current AND/NEAR cluster */
	Fts3Expr pExpr, / Expression to consider */
	Fts3TokenAndCost *ppTC, / Write new entries to (ppTC)++ */
	Fts3Expr **ppOr, / Write new OR root to (ppOr)++ */
	int pRc / IN/OUT: Error code */
	){
	if( *pRc==SQLITE_OK ){
	if( pExpr->eType==FTSQUERY_PHRASE ){
	Fts3Phrase *pPhrase = pExpr->pPhrase;
	int i;
	for(i=0; *pRc==SQLITE_OK && i<pPhrase->nToken; i++){
	Fts3TokenAndCost pTC = (ppTC)++;
	pTC->pPhrase = pPhrase;
	pTC->iToken = i;
	pTC->pRoot = pRoot;
	pTC->pToken = &pPhrase->aToken[i];
	pTC->iCol = pPhrase->iColumn;
	*pRc = sqlite3Fts3MsrOvfl(pCsr, pTC->pToken->pSegcsr, &pTC->nOvfl);
	}
	}else if( pExpr->eType!=FTSQUERY_NOT ){
	assert( pExpr->eType==FTSQUERY_OR
	\|\| pExpr->eType==FTSQUERY_AND
	\|\| pExpr->eType==FTSQUERY_NEAR
	);
	assert( pExpr->pLeft && pExpr->pRight );
	if( pExpr->eType==FTSQUERY_OR ){
	pRoot = pExpr->pLeft;
	**ppOr = pRoot;
	(*ppOr)++;
	}
	fts3EvalTokenCosts(pCsr, pRoot, pExpr->pLeft, ppTC, ppOr, pRc);
	if( pExpr->eType==FTSQUERY_OR ){
	pRoot = pExpr->pRight;
	**ppOr = pRoot;
	(*ppOr)++;
	}
	fts3EvalTokenCosts(pCsr, pRoot, pExpr->pRight, ppTC, ppOr, pRc);
	}
	}
	}

	/*
	** Determine the average document (row) size in pages. If successful,
	** write this value to *pnPage and return SQLITE_OK. Otherwise, return
	** an SQLite error code.
	**
	** The average document size in pages is calculated by first calculating
	** determining the average size in bytes, B. If B is less than the amount
	** of data that will fit on a single leaf page of an intkey table in
	** this database, then the average docsize is 1. Otherwise, it is 1 plus
	** the number of overflow pages consumed by a record B bytes in size.
	*/
	static int fts3EvalAverageDocsize(Fts3Cursor pCsr, int pnPage){
	int rc = SQLITE_OK;
	if( pCsr->nRowAvg==0 ){
	/* The average document size, which is required to calculate the cost
	** of each doclist, has not yet been determined. Read the required
	** data from the %_stat table to calculate it.
	**
	** Entry 0 of the %_stat table is a blob containing (nCol+1) FTS3
	** varints, where nCol is the number of columns in the FTS3 table.
	** The first varint is the number of documents currently stored in
	** the table. The following nCol varints contain the total amount of
	** data stored in all rows of each column of the table, from left
	** to right.
	*/
	Fts3Table p = (Fts3Table)pCsr->base.pVtab;
	sqlite3_stmt *pStmt;
	sqlite3_int64 nDoc = 0;
	sqlite3_int64 nByte = 0;
	const char *pEnd;
	const char *a;

	rc = sqlite3Fts3SelectDoctotal(p, &pStmt);
	if( rc!=SQLITE_OK ) return rc;
	a = sqlite3_column_blob(pStmt, 0);
	testcase( a==0 ); /* If %_stat.value set to X'' */
	if( a ){
	pEnd = &a[sqlite3_column_bytes(pStmt, 0)];
	a += sqlite3Fts3GetVarintBounded(a, pEnd, &nDoc);
	while( a<pEnd ){
	a += sqlite3Fts3GetVarintBounded(a, pEnd, &nByte);
	}
	}
	if( nDoc==0 \|\| nByte==0 ){
	sqlite3_reset(pStmt);
	return FTS_CORRUPT_VTAB;
	}

	pCsr->nDoc = nDoc;
	pCsr->nRowAvg = (int)(((nByte / nDoc) + p->nPgsz) / p->nPgsz);
	assert( pCsr->nRowAvg>0 );
	rc = sqlite3_reset(pStmt);
	}

	*pnPage = pCsr->nRowAvg;
	return rc;
	}

	/*
	** This function is called to select the tokens (if any) that will be
	** deferred. The array aTC[] has already been populated when this is
	** called.
	**
	** This function is called once for each AND/NEAR cluster in the
	** expression. Each invocation determines which tokens to defer within
	** the cluster with root node pRoot. See comments above the definition
	** of struct Fts3TokenAndCost for more details.
	**
	** If no error occurs, SQLITE_OK is returned and sqlite3Fts3DeferToken()
	** called on each token to defer. Otherwise, an SQLite error code is
	** returned.
	*/
	static int fts3EvalSelectDeferred(
	Fts3Cursor pCsr, / FTS Cursor handle */
	Fts3Expr pRoot, / Consider tokens with this root node */
	Fts3TokenAndCost aTC, / Array of expression tokens and costs */
	int nTC /* Number of entries in aTC[] */
	){
	Fts3Table pTab = (Fts3Table )pCsr->base.pVtab;
	int nDocSize = 0; /* Number of pages per doc loaded */
	int rc = SQLITE_OK; /* Return code */
	int ii; /* Iterator variable for various purposes */
	int nOvfl = 0; /* Total overflow pages used by doclists */
	int nToken = 0; /* Total number of tokens in cluster */

	int nMinEst = 0; /* The minimum count for any phrase so far. */
	int nLoad4 = 1; /* (Phrases that will be loaded)^4. */

	/* Tokens are never deferred for FTS tables created using the content=xxx
	** option. The reason being that it is not guaranteed that the content
	** table actually contains the same data as the index. To prevent this from
	** causing any problems, the deferred token optimization is completely
	** disabled for content=xxx tables. */
	if( pTab->zContentTbl ){
	return SQLITE_OK;
	}

	/* Count the tokens in this AND/NEAR cluster. If none of the doclists
	** associated with the tokens spill onto overflow pages, or if there is
	** only 1 token, exit early. No tokens to defer in this case. */
	for(ii=0; ii<nTC; ii++){
	if( aTC[ii].pRoot==pRoot ){
	nOvfl += aTC[ii].nOvfl;
	nToken++;
	}
	}
	if( nOvfl==0 \|\| nToken<2 ) return SQLITE_OK;

	/* Obtain the average docsize (in pages). */
	rc = fts3EvalAverageDocsize(pCsr, &nDocSize);
	assert( rc!=SQLITE_OK \|\| nDocSize>0 );


	/* Iterate through all tokens in this AND/NEAR cluster, in ascending order
	** of the number of overflow pages that will be loaded by the pager layer
	** to retrieve the entire doclist for the token from the full-text index.
	** Load the doclists for tokens that are either:
	**
	** a. The cheapest token in the entire query (i.e. the one visited by the
	** first iteration of this loop), or
	**
	** b. Part of a multi-token phrase.
	**
	** After each token doclist is loaded, merge it with the others from the
	** same phrase and count the number of documents that the merged doclist
	** contains. Set variable "nMinEst" to the smallest number of documents in
	** any phrase doclist for which 1 or more token doclists have been loaded.
	** Let nOther be the number of other phrases for which it is certain that
	** one or more tokens will not be deferred.
	**
	** Then, for each token, defer it if loading the doclist would result in
	** loading N or more overflow pages into memory, where N is computed as:
	**
	** (nMinEst + 4^nOther - 1) / (4^nOther)
	*/
	for(ii=0; ii<nToken && rc==SQLITE_OK; ii++){
	int iTC; /* Used to iterate through aTC[] array. */
	Fts3TokenAndCost pTC = 0; / Set to cheapest remaining token. */

	/* Set pTC to point to the cheapest remaining token. */
	for(iTC=0; iTC<nTC; iTC++){
	if( aTC[iTC].pToken && aTC[iTC].pRoot==pRoot
	&& (!pTC \|\| aTC[iTC].nOvfl<pTC->nOvfl)
	){
	pTC = &aTC[iTC];
	}
	}
	assert( pTC );

	if( ii && pTC->nOvfl>=((nMinEst+(nLoad4/4)-1)/(nLoad4/4))*nDocSize ){
	/* The number of overflow pages to load for this (and therefore all
	** subsequent) tokens is greater than the estimated number of pages
	** that will be loaded if all subsequent tokens are deferred.
	*/
	Fts3PhraseToken *pToken = pTC->pToken;
	rc = sqlite3Fts3DeferToken(pCsr, pToken, pTC->iCol);
	fts3SegReaderCursorFree(pToken->pSegcsr);
	pToken->pSegcsr = 0;
	}else{
	/* Set nLoad4 to the value of (4^nOther) for the next iteration of the
	** for-loop. Except, limit the value to 2^24 to prevent it from
	** overflowing the 32-bit integer it is stored in. */
	if( ii<12 ) nLoad4 = nLoad4*4;

	if( ii==0 \|\| (pTC->pPhrase->nToken>1 && ii!=nToken-1) ){
	/* Either this is the cheapest token in the entire query, or it is
	** part of a multi-token phrase. Either way, the entire doclist will
	** (eventually) be loaded into memory. It may as well be now. */
	Fts3PhraseToken *pToken = pTC->pToken;
	int nList = 0;
	char *pList = 0;
	rc = fts3TermSelect(pTab, pToken, pTC->iCol, &nList, &pList);
	assert( rc==SQLITE_OK \|\| pList==0 );
	if( rc==SQLITE_OK ){
	rc = fts3EvalPhraseMergeToken(
	pTab, pTC->pPhrase, pTC->iToken,pList,nList
	);
	}
	if( rc==SQLITE_OK ){
	int nCount;
	nCount = fts3DoclistCountDocids(
	pTC->pPhrase->doclist.aAll, pTC->pPhrase->doclist.nAll
	);
	if( ii==0 \|\| nCount<nMinEst ) nMinEst = nCount;
	}
	}
	}
	pTC->pToken = 0;
	}

	return rc;
	}

	/*
	** This function is called from within the xFilter method. It initializes
	** the full-text query currently stored in pCsr->pExpr. To iterate through
	** the results of a query, the caller does:
	**
	** fts3EvalStart(pCsr);
	** while( 1 ){
	** fts3EvalNext(pCsr);
	** if( pCsr->bEof ) break;
	** ... return row pCsr->iPrevId to the caller ...
	** }
	*/
	static int fts3EvalStart(Fts3Cursor *pCsr){
	Fts3Table pTab = (Fts3Table )pCsr->base.pVtab;
	int rc = SQLITE_OK;
	int nToken = 0;
	int nOr = 0;

	/* Allocate a MultiSegReader for each token in the expression. */
	fts3EvalAllocateReaders(pCsr, pCsr->pExpr, &nToken, &nOr, &rc);

	/* Determine which, if any, tokens in the expression should be deferred. */
	#ifndef SQLITE_DISABLE_FTS4_DEFERRED
	if( rc==SQLITE_OK && nToken>1 && pTab->bFts4 ){
	Fts3TokenAndCost *aTC;
	aTC = (Fts3TokenAndCost *)sqlite3_malloc64(
	sizeof(Fts3TokenAndCost) * nToken
	+ sizeof(Fts3Expr ) nOr * 2
	);

	if( !aTC ){
	rc = SQLITE_NOMEM;
	}else{
	Fts3Expr apOr = (Fts3Expr )&aTC[nToken];
	int ii;
	Fts3TokenAndCost *pTC = aTC;
	Fts3Expr **ppOr = apOr;

	fts3EvalTokenCosts(pCsr, 0, pCsr->pExpr, &pTC, &ppOr, &rc);
	nToken = (int)(pTC-aTC);
	nOr = (int)(ppOr-apOr);

	if( rc==SQLITE_OK ){
	rc = fts3EvalSelectDeferred(pCsr, 0, aTC, nToken);
	for(ii=0; rc==SQLITE_OK && ii<nOr; ii++){
	rc = fts3EvalSelectDeferred(pCsr, apOr[ii], aTC, nToken);
	}
	}

	sqlite3_free(aTC);
	}
	}
	#endif

	fts3EvalStartReaders(pCsr, pCsr->pExpr, &rc);
	return rc;
	}

	/*
	** Invalidate the current position list for phrase pPhrase.
	*/
	static void fts3EvalInvalidatePoslist(Fts3Phrase *pPhrase){
	if( pPhrase->doclist.bFreeList ){
	sqlite3_free(pPhrase->doclist.pList);
	}
	pPhrase->doclist.pList = 0;
	pPhrase->doclist.nList = 0;
	pPhrase->doclist.bFreeList = 0;
	}

	/*
	** This function is called to edit the position list associated with
	** the phrase object passed as the fifth argument according to a NEAR
	** condition. For example:
	**
	** abc NEAR/5 "def ghi"
	**
	** Parameter nNear is passed the NEAR distance of the expression (5 in
	** the example above). When this function is called, *paPoslist points to
	** the position list, and *pnToken is the number of phrase tokens in the
	** phrase on the other side of the NEAR operator to pPhrase. For example,
	** if pPhrase refers to the "def ghi" phrase, then *paPoslist points to
	** the position list associated with phrase "abc".
	**
	** All positions in the pPhrase position list that are not sufficiently
	** close to a position in the *paPoslist position list are removed. If this
	** leaves 0 positions, zero is returned. Otherwise, non-zero.
	**
	** Before returning, *paPoslist is set to point to the position lsit
	** associated with pPhrase. And *pnToken is set to the number of tokens in
	** pPhrase.
	*/
	static int fts3EvalNearTrim(
	int nNear, /* NEAR distance. As in "NEAR/nNear". */
	char aTmp, / Temporary space to use */
	char *paPoslist, / IN/OUT: Position list */
	int pnToken, / IN/OUT: Tokens in phrase of paPoslist /
	Fts3Phrase pPhrase / The phrase object to trim the doclist of */
	){
	int nParam1 = nNear + pPhrase->nToken;
	int nParam2 = nNear + *pnToken;
	int nNew;
	char *p2;
	char *pOut;
	int res;

	assert( pPhrase->doclist.pList );

	p2 = pOut = pPhrase->doclist.pList;
	res = fts3PoslistNearMerge(
	&pOut, aTmp, nParam1, nParam2, paPoslist, &p2
	);
	if( res ){
	nNew = (int)(pOut - pPhrase->doclist.pList) - 1;
	assert_fts3_nc( nNew<=pPhrase->doclist.nList && nNew>0 );
	if( nNew>=0 && nNew<=pPhrase->doclist.nList ){
	assert( pPhrase->doclist.pList[nNew]=='\0' );
	memset(&pPhrase->doclist.pList[nNew], 0, pPhrase->doclist.nList - nNew);
	pPhrase->doclist.nList = nNew;
	}
	*paPoslist = pPhrase->doclist.pList;
	*pnToken = pPhrase->nToken;
	}

	return res;
	}

	/*
	** This function is a no-op if *pRc is other than SQLITE_OK when it is called.
	** Otherwise, it advances the expression passed as the second argument to
	** point to the next matching row in the database. Expressions iterate through
	** matching rows in docid order. Ascending order if Fts3Cursor.bDesc is zero,
	** or descending if it is non-zero.
	**
	** If an error occurs, *pRc is set to an SQLite error code. Otherwise, if
	** successful, the following variables in pExpr are set:
	**
	** Fts3Expr.bEof (non-zero if EOF - there is no next row)
	** Fts3Expr.iDocid (valid if bEof==0. The docid of the next row)
	**
	** If the expression is of type FTSQUERY_PHRASE, and the expression is not
	** at EOF, then the following variables are populated with the position list
	** for the phrase for the visited row:
	**
	** FTs3Expr.pPhrase->doclist.nList (length of pList in bytes)
	** FTs3Expr.pPhrase->doclist.pList (pointer to position list)
	**
	** It says above that this function advances the expression to the next
	** matching row. This is usually true, but there are the following exceptions:
	**
	** 1. Deferred tokens are not taken into account. If a phrase consists
	** entirely of deferred tokens, it is assumed to match every row in
	** the db. In this case the position-list is not populated at all.
	**
	** Or, if a phrase contains one or more deferred tokens and one or
	** more non-deferred tokens, then the expression is advanced to the
	** next possible match, considering only non-deferred tokens. In other
	** words, if the phrase is "A B C", and "B" is deferred, the expression
	** is advanced to the next row that contains an instance of "A * C",
	** where "*" may match any single token. The position list in this case
	** is populated as for "A * C" before returning.
	**
	** 2. NEAR is treated as AND. If the expression is "x NEAR y", it is
	** advanced to point to the next row that matches "x AND y".
	**
	** See sqlite3Fts3EvalTestDeferred() for details on testing if a row is
	** really a match, taking into account deferred tokens and NEAR operators.
	*/
	static void fts3EvalNextRow(
	Fts3Cursor pCsr, / FTS Cursor handle */
	Fts3Expr pExpr, / Expr. to advance to next matching row */
	int pRc / IN/OUT: Error code */
	){
	if( *pRc==SQLITE_OK && pExpr->bEof==0 ){
	int bDescDoclist = pCsr->bDesc; /* Used by DOCID_CMP() macro */
	pExpr->bStart = 1;

	switch( pExpr->eType ){
	case FTSQUERY_NEAR:
	case FTSQUERY_AND: {
	Fts3Expr *pLeft = pExpr->pLeft;
	Fts3Expr *pRight = pExpr->pRight;
	assert( !pLeft->bDeferred \|\| !pRight->bDeferred );

	if( pLeft->bDeferred ){
	/* LHS is entirely deferred. So we assume it matches every row.
	** Advance the RHS iterator to find the next row visited. */
	fts3EvalNextRow(pCsr, pRight, pRc);
	pExpr->iDocid = pRight->iDocid;
	pExpr->bEof = pRight->bEof;
	}else if( pRight->bDeferred ){
	/* RHS is entirely deferred. So we assume it matches every row.
	** Advance the LHS iterator to find the next row visited. */
	fts3EvalNextRow(pCsr, pLeft, pRc);
	pExpr->iDocid = pLeft->iDocid;
	pExpr->bEof = pLeft->bEof;
	}else{
	/* Neither the RHS or LHS are deferred. */
	fts3EvalNextRow(pCsr, pLeft, pRc);
	fts3EvalNextRow(pCsr, pRight, pRc);
	while( !pLeft->bEof && !pRight->bEof && *pRc==SQLITE_OK ){
	sqlite3_int64 iDiff = DOCID_CMP(pLeft->iDocid, pRight->iDocid);
	if( iDiff==0 ) break;
	if( iDiff<0 ){
	fts3EvalNextRow(pCsr, pLeft, pRc);
	}else{
	fts3EvalNextRow(pCsr, pRight, pRc);
	}
	}
	pExpr->iDocid = pLeft->iDocid;
	pExpr->bEof = (pLeft->bEof \|\| pRight->bEof);
	if( pExpr->eType==FTSQUERY_NEAR && pExpr->bEof ){
	assert( pRight->eType==FTSQUERY_PHRASE );
	if( pRight->pPhrase->doclist.aAll ){
	Fts3Doclist *pDl = &pRight->pPhrase->doclist;
	while( *pRc==SQLITE_OK && pRight->bEof==0 ){
	memset(pDl->pList, 0, pDl->nList);
	fts3EvalNextRow(pCsr, pRight, pRc);
	}
	}
	if( pLeft->pPhrase && pLeft->pPhrase->doclist.aAll ){
	Fts3Doclist *pDl = &pLeft->pPhrase->doclist;
	while( *pRc==SQLITE_OK && pLeft->bEof==0 ){
	memset(pDl->pList, 0, pDl->nList);
	fts3EvalNextRow(pCsr, pLeft, pRc);
	}
	}
	pRight->bEof = pLeft->bEof = 1;
	}
	}
	break;
	}

	case FTSQUERY_OR: {
	Fts3Expr *pLeft = pExpr->pLeft;
	Fts3Expr *pRight = pExpr->pRight;
	sqlite3_int64 iCmp = DOCID_CMP(pLeft->iDocid, pRight->iDocid);

	assert_fts3_nc( pLeft->bStart \|\| pLeft->iDocid==pRight->iDocid );
	assert_fts3_nc( pRight->bStart \|\| pLeft->iDocid==pRight->iDocid );

	if( pRight->bEof \|\| (pLeft->bEof==0 && iCmp<0) ){
	fts3EvalNextRow(pCsr, pLeft, pRc);
	}else if( pLeft->bEof \|\| iCmp>0 ){
	fts3EvalNextRow(pCsr, pRight, pRc);
	}else{
	fts3EvalNextRow(pCsr, pLeft, pRc);
	fts3EvalNextRow(pCsr, pRight, pRc);
	}

	pExpr->bEof = (pLeft->bEof && pRight->bEof);
	iCmp = DOCID_CMP(pLeft->iDocid, pRight->iDocid);
	if( pRight->bEof \|\| (pLeft->bEof==0 && iCmp<0) ){
	pExpr->iDocid = pLeft->iDocid;
	}else{
	pExpr->iDocid = pRight->iDocid;
	}

	break;
	}

	case FTSQUERY_NOT: {
	Fts3Expr *pLeft = pExpr->pLeft;
	Fts3Expr *pRight = pExpr->pRight;

	if( pRight->bStart==0 ){
	fts3EvalNextRow(pCsr, pRight, pRc);
	assert( *pRc!=SQLITE_OK \|\| pRight->bStart );
	}

	fts3EvalNextRow(pCsr, pLeft, pRc);
	if( pLeft->bEof==0 ){
	while( !*pRc
	&& !pRight->bEof
	&& DOCID_CMP(pLeft->iDocid, pRight->iDocid)>0
	){
	fts3EvalNextRow(pCsr, pRight, pRc);
	}
	}
	pExpr->iDocid = pLeft->iDocid;
	pExpr->bEof = pLeft->bEof;
	break;
	}

	default: {
	Fts3Phrase *pPhrase = pExpr->pPhrase;
	fts3EvalInvalidatePoslist(pPhrase);
	*pRc = fts3EvalPhraseNext(pCsr, pPhrase, &pExpr->bEof);
	pExpr->iDocid = pPhrase->doclist.iDocid;
	break;
	}
	}
	}
	}

	/*
	** If *pRc is not SQLITE_OK, or if pExpr is not the root node of a NEAR
	** cluster, then this function returns 1 immediately.
	**
	** Otherwise, it checks if the current row really does match the NEAR
	** expression, using the data currently stored in the position lists
	** (Fts3Expr->pPhrase.doclist.pList/nList) for each phrase in the expression.
	**
	** If the current row is a match, the position list associated with each
	** phrase in the NEAR expression is edited in place to contain only those
	** phrase instances sufficiently close to their peers to satisfy all NEAR
	** constraints. In this case it returns 1. If the NEAR expression does not
	** match the current row, 0 is returned. The position lists may or may not
	** be edited if 0 is returned.
	*/
	static int fts3EvalNearTest(Fts3Expr pExpr, int pRc){
	int res = 1;

	/* The following block runs if pExpr is the root of a NEAR query.
	** For example, the query:
	**
	** "w" NEAR "x" NEAR "y" NEAR "z"
	**
	** which is represented in tree form as:
	**
	** \|
	** +--NEAR--+ <-- root of NEAR query
	** \| \|
	** +--NEAR--+ "z"
	** \| \|
	** +--NEAR--+ "y"
	** \| \|
	** "w" "x"
	**
	** The right-hand child of a NEAR node is always a phrase. The
	** left-hand child may be either a phrase or a NEAR node. There are
	** no exceptions to this - it's the way the parser in fts3_expr.c works.
	*/
	if( *pRc==SQLITE_OK
	&& pExpr->eType==FTSQUERY_NEAR
	&& (pExpr->pParent==0 \|\| pExpr->pParent->eType!=FTSQUERY_NEAR)
	){
	Fts3Expr *p;
	sqlite3_int64 nTmp = 0; /* Bytes of temp space */
	char aTmp; / Temp space for PoslistNearMerge() */

	/* Allocate temporary working space. */
	for(p=pExpr; p->pLeft; p=p->pLeft){
	assert( p->pRight->pPhrase->doclist.nList>0 );
	nTmp += p->pRight->pPhrase->doclist.nList;
	}
	nTmp += p->pPhrase->doclist.nList;
	aTmp = sqlite3_malloc64(nTmp*2 + FTS3_VARINT_MAX);
	if( !aTmp ){
	*pRc = SQLITE_NOMEM;
	res = 0;
	}else{
	char *aPoslist = p->pPhrase->doclist.pList;
	int nToken = p->pPhrase->nToken;

	for(p=p->pParent;res && p && p->eType==FTSQUERY_NEAR; p=p->pParent){
	Fts3Phrase *pPhrase = p->pRight->pPhrase;
	int nNear = p->nNear;
	res = fts3EvalNearTrim(nNear, aTmp, &aPoslist, &nToken, pPhrase);
	}

	aPoslist = pExpr->pRight->pPhrase->doclist.pList;
	nToken = pExpr->pRight->pPhrase->nToken;
	for(p=pExpr->pLeft; p && res; p=p->pLeft){
	int nNear;
	Fts3Phrase *pPhrase;
	assert( p->pParent && p->pParent->pLeft==p );
	nNear = p->pParent->nNear;
	pPhrase = (
	p->eType==FTSQUERY_NEAR ? p->pRight->pPhrase : p->pPhrase
	);
	res = fts3EvalNearTrim(nNear, aTmp, &aPoslist, &nToken, pPhrase);
	}
	}

	sqlite3_free(aTmp);
	}

	return res;
	}

	/*
	** This function is a helper function for sqlite3Fts3EvalTestDeferred().
	** Assuming no error occurs or has occurred, It returns non-zero if the
	** expression passed as the second argument matches the row that pCsr
	** currently points to, or zero if it does not.
	**
	** If *pRc is not SQLITE_OK when this function is called, it is a no-op.
	** If an error occurs during execution of this function, *pRc is set to
	** the appropriate SQLite error code. In this case the returned value is
	** undefined.
	*/
	static int fts3EvalTestExpr(
	Fts3Cursor pCsr, / FTS cursor handle */
	Fts3Expr pExpr, / Expr to test. May or may not be root. */
	int pRc / IN/OUT: Error code */
	){
	int bHit = 1; /* Return value */
	if( *pRc==SQLITE_OK ){
	switch( pExpr->eType ){
	case FTSQUERY_NEAR:
	case FTSQUERY_AND:
	bHit = (
	fts3EvalTestExpr(pCsr, pExpr->pLeft, pRc)
	&& fts3EvalTestExpr(pCsr, pExpr->pRight, pRc)
	&& fts3EvalNearTest(pExpr, pRc)
	);

	/* If the NEAR expression does not match any rows, zero the doclist for
	** all phrases involved in the NEAR. This is because the snippet(),
	** offsets() and matchinfo() functions are not supposed to recognize
	** any instances of phrases that are part of unmatched NEAR queries.
	** For example if this expression:
	**
	** ... MATCH 'a OR (b NEAR c)'
	**
	** is matched against a row containing:
	**
	** 'a b d e'
	**
	** then any snippet() should ony highlight the "a" term, not the "b"
	** (as "b" is part of a non-matching NEAR clause).
	*/
	if( bHit==0
	&& pExpr->eType==FTSQUERY_NEAR
	&& (pExpr->pParent==0 \|\| pExpr->pParent->eType!=FTSQUERY_NEAR)
	){
	Fts3Expr *p;
	for(p=pExpr; p->pPhrase==0; p=p->pLeft){
	if( p->pRight->iDocid==pCsr->iPrevId ){
	fts3EvalInvalidatePoslist(p->pRight->pPhrase);
	}
	}
	if( p->iDocid==pCsr->iPrevId ){
	fts3EvalInvalidatePoslist(p->pPhrase);
	}
	}

	break;

	case FTSQUERY_OR: {
	int bHit1 = fts3EvalTestExpr(pCsr, pExpr->pLeft, pRc);
	int bHit2 = fts3EvalTestExpr(pCsr, pExpr->pRight, pRc);
	bHit = bHit1 \|\| bHit2;
	break;
	}

	case FTSQUERY_NOT:
	bHit = (
	fts3EvalTestExpr(pCsr, pExpr->pLeft, pRc)
	&& !fts3EvalTestExpr(pCsr, pExpr->pRight, pRc)
	);
	break;

	default: {
	#ifndef SQLITE_DISABLE_FTS4_DEFERRED
	if( pCsr->pDeferred && (pExpr->bDeferred \|\| (
	pExpr->iDocid==pCsr->iPrevId && pExpr->pPhrase->doclist.pList
	))){
	Fts3Phrase *pPhrase = pExpr->pPhrase;
	if( pExpr->bDeferred ){
	fts3EvalInvalidatePoslist(pPhrase);
	}
	*pRc = fts3EvalDeferredPhrase(pCsr, pPhrase);
	bHit = (pPhrase->doclist.pList!=0);
	pExpr->iDocid = pCsr->iPrevId;
	}else
	#endif
	{
	bHit = (
	pExpr->bEof==0 && pExpr->iDocid==pCsr->iPrevId
	&& pExpr->pPhrase->doclist.nList>0
	);
	}
	break;
	}
	}
	}
	return bHit;
	}

	/*
	** This function is called as the second part of each xNext operation when
	** iterating through the results of a full-text query. At this point the
	** cursor points to a row that matches the query expression, with the
	** following caveats:
	**
	** * Up until this point, "NEAR" operators in the expression have been
	** treated as "AND".
	**
	** * Deferred tokens have not yet been considered.
	**
	** If *pRc is not SQLITE_OK when this function is called, it immediately
	** returns 0. Otherwise, it tests whether or not after considering NEAR
	** operators and deferred tokens the current row is still a match for the
	** expression. It returns 1 if both of the following are true:
	**
	** 1. *pRc is SQLITE_OK when this function returns, and
	**
	** 2. After scanning the current FTS table row for the deferred tokens,
	** it is determined that the row does not match the query.
	**
	** Or, if no error occurs and it seems the current row does match the FTS
	** query, return 0.
	*/
	int sqlite3Fts3EvalTestDeferred(Fts3Cursor pCsr, int pRc){
	int rc = *pRc;
	int bMiss = 0;
	if( rc==SQLITE_OK ){

	/* If there are one or more deferred tokens, load the current row into
	** memory and scan it to determine the position list for each deferred
	** token. Then, see if this row is really a match, considering deferred
	** tokens and NEAR operators (neither of which were taken into account
	** earlier, by fts3EvalNextRow()).
	*/
	if( pCsr->pDeferred ){
	rc = fts3CursorSeek(0, pCsr);
	if( rc==SQLITE_OK ){
	rc = sqlite3Fts3CacheDeferredDoclists(pCsr);
	}
	}
	bMiss = (0==fts3EvalTestExpr(pCsr, pCsr->pExpr, &rc));

	/* Free the position-lists accumulated for each deferred token above. */
	sqlite3Fts3FreeDeferredDoclists(pCsr);
	*pRc = rc;
	}
	return (rc==SQLITE_OK && bMiss);
	}

	/*
	** Advance to the next document that matches the FTS expression in
	** Fts3Cursor.pExpr.
	*/
	static int fts3EvalNext(Fts3Cursor *pCsr){
	int rc = SQLITE_OK; /* Return Code */
	Fts3Expr *pExpr = pCsr->pExpr;
	assert( pCsr->isEof==0 );
	if( pExpr==0 ){
	pCsr->isEof = 1;
	}else{
	do {
	if( pCsr->isRequireSeek==0 ){
	sqlite3_reset(pCsr->pStmt);
	}
	assert( sqlite3_data_count(pCsr->pStmt)==0 );
	fts3EvalNextRow(pCsr, pExpr, &rc);
	pCsr->isEof = pExpr->bEof;
	pCsr->isRequireSeek = 1;
	pCsr->isMatchinfoNeeded = 1;
	pCsr->iPrevId = pExpr->iDocid;
	}while( pCsr->isEof==0 && sqlite3Fts3EvalTestDeferred(pCsr, &rc) );
	}

	/* Check if the cursor is past the end of the docid range specified
	** by Fts3Cursor.iMinDocid/iMaxDocid. If so, set the EOF flag. */
	if( rc==SQLITE_OK && (
	(pCsr->bDesc==0 && pCsr->iPrevId>pCsr->iMaxDocid)
	\|\| (pCsr->bDesc!=0 && pCsr->iPrevId<pCsr->iMinDocid)
	)){
	pCsr->isEof = 1;
	}

	return rc;
	}

	/*
	** Restart interation for expression pExpr so that the next call to
	** fts3EvalNext() visits the first row. Do not allow incremental
	** loading or merging of phrase doclists for this iteration.
	**
	** If *pRc is other than SQLITE_OK when this function is called, it is
	** a no-op. If an error occurs within this function, *pRc is set to an
	** SQLite error code before returning.
	*/
	static void fts3EvalRestart(
	Fts3Cursor *pCsr,
	Fts3Expr *pExpr,
	int *pRc
	){
	if( pExpr && *pRc==SQLITE_OK ){
	Fts3Phrase *pPhrase = pExpr->pPhrase;

	if( pPhrase ){
	fts3EvalInvalidatePoslist(pPhrase);
	if( pPhrase->bIncr ){
	int i;
	for(i=0; i<pPhrase->nToken; i++){
	Fts3PhraseToken *pToken = &pPhrase->aToken[i];
	assert( pToken->pDeferred==0 );
	if( pToken->pSegcsr ){
	sqlite3Fts3MsrIncrRestart(pToken->pSegcsr);
	}
	}
	*pRc = fts3EvalPhraseStart(pCsr, 0, pPhrase);
	}
	pPhrase->doclist.pNextDocid = 0;
	pPhrase->doclist.iDocid = 0;
	pPhrase->pOrPoslist = 0;
	}

	pExpr->iDocid = 0;
	pExpr->bEof = 0;
	pExpr->bStart = 0;

	fts3EvalRestart(pCsr, pExpr->pLeft, pRc);
	fts3EvalRestart(pCsr, pExpr->pRight, pRc);
	}
	}

	/*
	** After allocating the Fts3Expr.aMI[] array for each phrase in the
	** expression rooted at pExpr, the cursor iterates through all rows matched
	** by pExpr, calling this function for each row. This function increments
	** the values in Fts3Expr.aMI[] according to the position-list currently
	** found in Fts3Expr.pPhrase->doclist.pList for each of the phrase
	** expression nodes.
	*/
	static void fts3EvalUpdateCounts(Fts3Expr *pExpr, int nCol){
	if( pExpr ){
	Fts3Phrase *pPhrase = pExpr->pPhrase;
	if( pPhrase && pPhrase->doclist.pList ){
	int iCol = 0;
	char *p = pPhrase->doclist.pList;

	do{
	u8 c = 0;
	int iCnt = 0;
	while( 0xFE & (*p \| c) ){
	if( (c&0x80)==0 ) iCnt++;
	c = *p++ & 0x80;
	}

	/* aMI[iCol*3 + 1] = Number of occurrences
	** aMI[iCol*3 + 2] = Number of rows containing at least one instance
	*/
	pExpr->aMI[iCol*3 + 1] += iCnt;
	pExpr->aMI[iCol*3 + 2] += (iCnt>0);
	if( *p==0x00 ) break;
	p++;
	p += fts3GetVarint32(p, &iCol);
	}while( iCol<nCol );
	}

	fts3EvalUpdateCounts(pExpr->pLeft, nCol);
	fts3EvalUpdateCounts(pExpr->pRight, nCol);
	}
	}

	/*
	** This is an sqlite3Fts3ExprIterate() callback. If the Fts3Expr.aMI[] array
	** has not yet been allocated, allocate and zero it. Otherwise, just zero
	** it.
	*/
	static int fts3AllocateMSI(Fts3Expr pExpr, int iPhrase, void pCtx){
	Fts3Table pTab = (Fts3Table)pCtx;
	UNUSED_PARAMETER(iPhrase);
	if( pExpr->aMI==0 ){
	pExpr->aMI = (u32 )sqlite3_malloc64(pTab->nColumn 3 * sizeof(u32));
	if( pExpr->aMI==0 ) return SQLITE_NOMEM;
	}
	memset(pExpr->aMI, 0, pTab->nColumn * 3 * sizeof(u32));
	return SQLITE_OK;
	}

	/*
	** Expression pExpr must be of type FTSQUERY_PHRASE.
	**
	** If it is not already allocated and populated, this function allocates and
	** populates the Fts3Expr.aMI[] array for expression pExpr. If pExpr is part
	** of a NEAR expression, then it also allocates and populates the same array
	** for all other phrases that are part of the NEAR expression.
	**
	** SQLITE_OK is returned if the aMI[] array is successfully allocated and
	** populated. Otherwise, if an error occurs, an SQLite error code is returned.
	*/
	static int fts3EvalGatherStats(
	Fts3Cursor pCsr, / Cursor object */
	Fts3Expr pExpr / FTSQUERY_PHRASE expression */
	){
	int rc = SQLITE_OK; /* Return code */

	assert( pExpr->eType==FTSQUERY_PHRASE );
	if( pExpr->aMI==0 ){
	Fts3Table pTab = (Fts3Table )pCsr->base.pVtab;
	Fts3Expr pRoot; / Root of NEAR expression */

	sqlite3_int64 iPrevId = pCsr->iPrevId;
	sqlite3_int64 iDocid;
	u8 bEof;

	/* Find the root of the NEAR expression */
	pRoot = pExpr;
	while( pRoot->pParent
	&& (pRoot->pParent->eType==FTSQUERY_NEAR \|\| pRoot->bDeferred)
	){
	pRoot = pRoot->pParent;
	}
	iDocid = pRoot->iDocid;
	bEof = pRoot->bEof;
	assert( pRoot->bStart );

	/* Allocate space for the aMSI[] array of each FTSQUERY_PHRASE node */
	rc = sqlite3Fts3ExprIterate(pRoot, fts3AllocateMSI, (void*)pTab);
	if( rc!=SQLITE_OK ) return rc;
	fts3EvalRestart(pCsr, pRoot, &rc);

	while( pCsr->isEof==0 && rc==SQLITE_OK ){

	do {
	/* Ensure the %_content statement is reset. */
	if( pCsr->isRequireSeek==0 ) sqlite3_reset(pCsr->pStmt);
	assert( sqlite3_data_count(pCsr->pStmt)==0 );

	/* Advance to the next document */
	fts3EvalNextRow(pCsr, pRoot, &rc);
	pCsr->isEof = pRoot->bEof;
	pCsr->isRequireSeek = 1;
	pCsr->isMatchinfoNeeded = 1;
	pCsr->iPrevId = pRoot->iDocid;
	}while( pCsr->isEof==0
	&& pRoot->eType==FTSQUERY_NEAR
	&& sqlite3Fts3EvalTestDeferred(pCsr, &rc)
	);

	if( rc==SQLITE_OK && pCsr->isEof==0 ){
	fts3EvalUpdateCounts(pRoot, pTab->nColumn);
	}
	}

	pCsr->isEof = 0;
	pCsr->iPrevId = iPrevId;

	if( bEof ){
	pRoot->bEof = bEof;
	}else{
	/* Caution: pRoot may iterate through docids in ascending or descending
	** order. For this reason, even though it seems more defensive, the
	** do loop can not be written:
	**
	** do {...} while( pRoot->iDocid<iDocid && rc==SQLITE_OK );
	*/
	fts3EvalRestart(pCsr, pRoot, &rc);
	do {
	fts3EvalNextRow(pCsr, pRoot, &rc);
	assert_fts3_nc( pRoot->bEof==0 );
	if( pRoot->bEof ) rc = FTS_CORRUPT_VTAB;
	}while( pRoot->iDocid!=iDocid && rc==SQLITE_OK );
	}
	}
	return rc;
	}

	/*
	** This function is used by the matchinfo() module to query a phrase
	** expression node for the following information:
	**
	** 1. The total number of occurrences of the phrase in each column of
	** the FTS table (considering all rows), and
	**
	** 2. For each column, the number of rows in the table for which the
	** column contains at least one instance of the phrase.
	**
	** If no error occurs, SQLITE_OK is returned and the values for each column
	** written into the array aiOut as follows:
	**
	** aiOut[iCol*3 + 1] = Number of occurrences
	** aiOut[iCol*3 + 2] = Number of rows containing at least one instance
	**
	** Caveats:
	**
	** * If a phrase consists entirely of deferred tokens, then all output
	** values are set to the number of documents in the table. In other
	** words we assume that very common tokens occur exactly once in each
	** column of each row of the table.
	**
	** * If a phrase contains some deferred tokens (and some non-deferred
	** tokens), count the potential occurrence identified by considering
	** the non-deferred tokens instead of actual phrase occurrences.
	**
	** * If the phrase is part of a NEAR expression, then only phrase instances
	** that meet the NEAR constraint are included in the counts.
	*/
	int sqlite3Fts3EvalPhraseStats(
	Fts3Cursor pCsr, / FTS cursor handle */
	Fts3Expr pExpr, / Phrase expression */
	u32 aiOut / Array to write results into (see above) */
	){
	Fts3Table pTab = (Fts3Table )pCsr->base.pVtab;
	int rc = SQLITE_OK;
	int iCol;

	if( pExpr->bDeferred && pExpr->pParent->eType!=FTSQUERY_NEAR ){
	assert( pCsr->nDoc>0 );
	for(iCol=0; iCol<pTab->nColumn; iCol++){
	aiOut[iCol*3 + 1] = (u32)pCsr->nDoc;
	aiOut[iCol*3 + 2] = (u32)pCsr->nDoc;
	}
	}else{
	rc = fts3EvalGatherStats(pCsr, pExpr);
	if( rc==SQLITE_OK ){
	assert( pExpr->aMI );
	for(iCol=0; iCol<pTab->nColumn; iCol++){
	aiOut[iCol3 + 1] = pExpr->aMI[iCol3 + 1];
	aiOut[iCol3 + 2] = pExpr->aMI[iCol3 + 2];
	}
	}
	}

	return rc;
	}

	/*
	** The expression pExpr passed as the second argument to this function
	** must be of type FTSQUERY_PHRASE.
	**
	** The returned value is either NULL or a pointer to a buffer containing
	** a position-list indicating the occurrences of the phrase in column iCol
	** of the current row.
	**
	** More specifically, the returned buffer contains 1 varint for each
	** occurrence of the phrase in the column, stored using the normal (delta+2)
	** compression and is terminated by either an 0x01 or 0x00 byte. For example,
	** if the requested column contains "a b X c d X X" and the position-list
	** for 'X' is requested, the buffer returned may contain:
	**
	** 0x04 0x05 0x03 0x01 or 0x04 0x05 0x03 0x00
	**
	** This function works regardless of whether or not the phrase is deferred,
	** incremental, or neither.
	*/
	int sqlite3Fts3EvalPhrasePoslist(
	Fts3Cursor pCsr, / FTS3 cursor object */
	Fts3Expr pExpr, / Phrase to return doclist for */
	int iCol, /* Column to return position list for */
	char *ppOut / OUT: Pointer to position list */
	){
	Fts3Phrase *pPhrase = pExpr->pPhrase;
	Fts3Table pTab = (Fts3Table )pCsr->base.pVtab;
	char *pIter;
	int iThis;
	sqlite3_int64 iDocid;

	/* If this phrase is applies specifically to some column other than
	** column iCol, return a NULL pointer. */
	*ppOut = 0;
	assert( iCol>=0 && iCol<pTab->nColumn );
	if( (pPhrase->iColumn<pTab->nColumn && pPhrase->iColumn!=iCol) ){
	return SQLITE_OK;
	}

	iDocid = pExpr->iDocid;
	pIter = pPhrase->doclist.pList;
	if( iDocid!=pCsr->iPrevId \|\| pExpr->bEof ){
	int rc = SQLITE_OK;
	int bDescDoclist = pTab->bDescIdx; /* For DOCID_CMP macro */
	int bOr = 0;
	u8 bTreeEof = 0;
	Fts3Expr p; / Used to iterate from pExpr to root */
	Fts3Expr pNear; / Most senior NEAR ancestor (or pExpr) */
	Fts3Expr pRun; / Closest non-deferred ancestor of pNear */
	int bMatch;

	/* Check if this phrase descends from an OR expression node. If not,
	** return NULL. Otherwise, the entry that corresponds to docid
	** pCsr->iPrevId may lie earlier in the doclist buffer. Or, if the
	** tree that the node is part of has been marked as EOF, but the node
	** itself is not EOF, then it may point to an earlier entry. */
	pNear = pExpr;
	for(p=pExpr->pParent; p; p=p->pParent){
	if( p->eType==FTSQUERY_OR ) bOr = 1;
	if( p->eType==FTSQUERY_NEAR ) pNear = p;
	if( p->bEof ) bTreeEof = 1;
	}
	if( bOr==0 ) return SQLITE_OK;
	pRun = pNear;
	while( pRun->bDeferred ){
	assert( pRun->pParent );
	pRun = pRun->pParent;
	}

	/* This is the descendent of an OR node. In this case we cannot use
	** an incremental phrase. Load the entire doclist for the phrase
	** into memory in this case. */
	if( pPhrase->bIncr ){
	int bEofSave = pRun->bEof;
	fts3EvalRestart(pCsr, pRun, &rc);
	while( rc==SQLITE_OK && !pRun->bEof ){
	fts3EvalNextRow(pCsr, pRun, &rc);
	if( bEofSave==0 && pRun->iDocid==iDocid ) break;
	}
	assert( rc!=SQLITE_OK \|\| pPhrase->bIncr==0 );
	if( rc==SQLITE_OK && pRun->bEof!=bEofSave ){
	rc = FTS_CORRUPT_VTAB;
	}
	}
	if( bTreeEof ){
	while( rc==SQLITE_OK && !pRun->bEof ){
	fts3EvalNextRow(pCsr, pRun, &rc);
	}
	}
	if( rc!=SQLITE_OK ) return rc;

	bMatch = 1;
	for(p=pNear; p; p=p->pLeft){
	u8 bEof = 0;
	Fts3Expr *pTest = p;
	Fts3Phrase *pPh;
	assert( pTest->eType==FTSQUERY_NEAR \|\| pTest->eType==FTSQUERY_PHRASE );
	if( pTest->eType==FTSQUERY_NEAR ) pTest = pTest->pRight;
	assert( pTest->eType==FTSQUERY_PHRASE );
	pPh = pTest->pPhrase;

	pIter = pPh->pOrPoslist;
	iDocid = pPh->iOrDocid;
	if( pCsr->bDesc==bDescDoclist ){
	bEof = !pPh->doclist.nAll \|\|
	(pIter >= (pPh->doclist.aAll + pPh->doclist.nAll));
	while( (pIter==0 \|\| DOCID_CMP(iDocid, pCsr->iPrevId)<0 ) && bEof==0 ){
	sqlite3Fts3DoclistNext(
	bDescDoclist, pPh->doclist.aAll, pPh->doclist.nAll,
	&pIter, &iDocid, &bEof
	);
	}
	}else{
	bEof = !pPh->doclist.nAll \|\| (pIter && pIter<=pPh->doclist.aAll);
	while( (pIter==0 \|\| DOCID_CMP(iDocid, pCsr->iPrevId)>0 ) && bEof==0 ){
	int dummy;
	sqlite3Fts3DoclistPrev(
	bDescDoclist, pPh->doclist.aAll, pPh->doclist.nAll,
	&pIter, &iDocid, &dummy, &bEof
	);
	}
	}
	pPh->pOrPoslist = pIter;
	pPh->iOrDocid = iDocid;
	if( bEof \|\| iDocid!=pCsr->iPrevId ) bMatch = 0;
	}

	if( bMatch ){
	pIter = pPhrase->pOrPoslist;
	}else{
	pIter = 0;
	}
	}
	if( pIter==0 ) return SQLITE_OK;

	if( *pIter==0x01 ){
	pIter++;
	pIter += fts3GetVarint32(pIter, &iThis);
	}else{
	iThis = 0;
	}
	while( iThis<iCol ){
	fts3ColumnlistCopy(0, &pIter);
	if( *pIter==0x00 ) return SQLITE_OK;
	pIter++;
	pIter += fts3GetVarint32(pIter, &iThis);
	}
	if( *pIter==0x00 ){
	pIter = 0;
	}

	*ppOut = ((iCol==iThis)?pIter:0);
	return SQLITE_OK;
	}

	/*
	** Free all components of the Fts3Phrase structure that were allocated by
	** the eval module. Specifically, this means to free:
	**
	** * the contents of pPhrase->doclist, and
	** * any Fts3MultiSegReader objects held by phrase tokens.
	*/
	void sqlite3Fts3EvalPhraseCleanup(Fts3Phrase *pPhrase){
	if( pPhrase ){
	int i;
	sqlite3_free(pPhrase->doclist.aAll);
	fts3EvalInvalidatePoslist(pPhrase);
	memset(&pPhrase->doclist, 0, sizeof(Fts3Doclist));
	for(i=0; i<pPhrase->nToken; i++){
	fts3SegReaderCursorFree(pPhrase->aToken[i].pSegcsr);
	pPhrase->aToken[i].pSegcsr = 0;
	}
	}
	}


	/*
	** Return SQLITE_CORRUPT_VTAB.
	*/
	#ifdef SQLITE_DEBUG
	int sqlite3Fts3Corrupt(){
	return SQLITE_CORRUPT_VTAB;
	}
	#endif

	#if !defined(SQLITE_CORE)
	/*
	** Initialize API pointer table, if required.
	*/
	#ifdef _WIN32
	__declspec(dllexport)
	#endif
	int sqlite3_fts3_init(
	sqlite3 *db,
	char **pzErrMsg,
	const sqlite3_api_routines *pApi
	){
	SQLITE_EXTENSION_INIT2(pApi)
	return sqlite3Fts3Init(db);
	}
	#endif

	#endif