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

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	/*
	** 2001 September 15
	**
	** 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 file contains code for implementations of the r-tree and r*-tree
	** algorithms packaged as an SQLite virtual table module.
	*/

	/*
	** Database Format of R-Tree Tables
	** --------------------------------
	**
	** The data structure for a single virtual r-tree table is stored in three
	** native SQLite tables declared as follows. In each case, the '%' character
	** in the table name is replaced with the user-supplied name of the r-tree
	** table.
	**
	** CREATE TABLE %_node(nodeno INTEGER PRIMARY KEY, data BLOB)
	** CREATE TABLE %_parent(nodeno INTEGER PRIMARY KEY, parentnode INTEGER)
	** CREATE TABLE %_rowid(rowid INTEGER PRIMARY KEY, nodeno INTEGER, ...)
	**
	** The data for each node of the r-tree structure is stored in the %_node
	** table. For each node that is not the root node of the r-tree, there is
	** an entry in the %_parent table associating the node with its parent.
	** And for each row of data in the table, there is an entry in the %_rowid
	** table that maps from the entries rowid to the id of the node that it
	** is stored on. If the r-tree contains auxiliary columns, those are stored
	** on the end of the %_rowid table.
	**
	** The root node of an r-tree always exists, even if the r-tree table is
	** empty. The nodeno of the root node is always 1. All other nodes in the
	** table must be the same size as the root node. The content of each node
	** is formatted as follows:
	**
	** 1. If the node is the root node (node 1), then the first 2 bytes
	** of the node contain the tree depth as a big-endian integer.
	** For non-root nodes, the first 2 bytes are left unused.
	**
	** 2. The next 2 bytes contain the number of entries currently
	** stored in the node.
	**
	** 3. The remainder of the node contains the node entries. Each entry
	** consists of a single 8-byte integer followed by an even number
	** of 4-byte coordinates. For leaf nodes the integer is the rowid
	** of a record. For internal nodes it is the node number of a
	** child page.
	*/

	#if !defined(SQLITE_CORE) \
	\|\| (defined(SQLITE_ENABLE_RTREE) && !defined(SQLITE_OMIT_VIRTUALTABLE))

	#ifndef SQLITE_CORE
	#include "sqlite3ext.h"
	SQLITE_EXTENSION_INIT1
	#else
	#include "sqlite3.h"
	#endif
	int sqlite3GetToken(const unsigned char,int); /* In the SQLite core */

	/*
	** If building separately, we will need some setup that is normally
	** found in sqliteInt.h
	*/
	#if !defined(SQLITE_AMALGAMATION)
	#include "sqlite3rtree.h"
	typedef sqlite3_int64 i64;
	typedef sqlite3_uint64 u64;
	typedef unsigned char u8;
	typedef unsigned short u16;
	typedef unsigned int u32;
	#if !defined(NDEBUG) && !defined(SQLITE_DEBUG)
	# define NDEBUG 1
	#endif
	#if defined(NDEBUG) && defined(SQLITE_DEBUG)
	# undef NDEBUG
	#endif
	#if defined(SQLITE_COVERAGE_TEST) \|\| defined(SQLITE_MUTATION_TEST)
	# define SQLITE_OMIT_AUXILIARY_SAFETY_CHECKS 1
	#endif
	#if defined(SQLITE_OMIT_AUXILIARY_SAFETY_CHECKS)
	# define ALWAYS(X) (1)
	# define NEVER(X) (0)
	#elif !defined(NDEBUG)
	# define ALWAYS(X) ((X)?1:(assert(0),0))
	# define NEVER(X) ((X)?(assert(0),1):0)
	#else
	# define ALWAYS(X) (X)
	# define NEVER(X) (X)
	#endif
	#endif /* !defined(SQLITE_AMALGAMATION) */

	/* Macro to check for 4-byte alignment. Only used inside of assert() */
	#ifdef SQLITE_DEBUG
	# define FOUR_BYTE_ALIGNED(X) ((((char)(X) - (char)0) & 3)==0)
	#endif

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

	/* The following macro is used to suppress compiler warnings.
	*/
	#ifndef UNUSED_PARAMETER
	# define UNUSED_PARAMETER(x) (void)(x)
	#endif

	typedef struct Rtree Rtree;
	typedef struct RtreeCursor RtreeCursor;
	typedef struct RtreeNode RtreeNode;
	typedef struct RtreeCell RtreeCell;
	typedef struct RtreeConstraint RtreeConstraint;
	typedef struct RtreeMatchArg RtreeMatchArg;
	typedef struct RtreeGeomCallback RtreeGeomCallback;
	typedef union RtreeCoord RtreeCoord;
	typedef struct RtreeSearchPoint RtreeSearchPoint;

	/* The rtree may have between 1 and RTREE_MAX_DIMENSIONS dimensions. */
	#define RTREE_MAX_DIMENSIONS 5

	/* Maximum number of auxiliary columns */
	#define RTREE_MAX_AUX_COLUMN 100

	/* Size of hash table Rtree.aHash. This hash table is not expected to
	** ever contain very many entries, so a fixed number of buckets is
	** used.
	*/
	#define HASHSIZE 97

	/* The xBestIndex method of this virtual table requires an estimate of
	** the number of rows in the virtual table to calculate the costs of
	** various strategies. If possible, this estimate is loaded from the
	** sqlite_stat1 table (with RTREE_MIN_ROWEST as a hard-coded minimum).
	** Otherwise, if no sqlite_stat1 entry is available, use
	** RTREE_DEFAULT_ROWEST.
	*/
	#define RTREE_DEFAULT_ROWEST 1048576
	#define RTREE_MIN_ROWEST 100

	/*
	** An rtree virtual-table object.
	*/
	struct Rtree {
	sqlite3_vtab base; /* Base class. Must be first */
	sqlite3 db; / Host database connection */
	int iNodeSize; /* Size in bytes of each node in the node table */
	u8 nDim; /* Number of dimensions */
	u8 nDim2; /* Twice the number of dimensions */
	u8 eCoordType; /* RTREE_COORD_REAL32 or RTREE_COORD_INT32 */
	u8 nBytesPerCell; /* Bytes consumed per cell */
	u8 inWrTrans; /* True if inside write transaction */
	u8 nAux; /* # of auxiliary columns in %_rowid */
	#ifdef SQLITE_ENABLE_GEOPOLY
	u8 nAuxNotNull; /* Number of initial not-null aux columns */
	#endif
	#ifdef SQLITE_DEBUG
	u8 bCorrupt; /* Shadow table corruption detected */
	#endif
	int iDepth; /* Current depth of the r-tree structure */
	char zDb; / Name of database containing r-tree table */
	char zName; / Name of r-tree table */
	char zNodeName; / Name of the %_node table */
	u32 nBusy; /* Current number of users of this structure */
	i64 nRowEst; /* Estimated number of rows in this table */
	u32 nCursor; /* Number of open cursors */
	u32 nNodeRef; /* Number RtreeNodes with positive nRef */
	char zReadAuxSql; / SQL for statement to read aux data */

	/* List of nodes removed during a CondenseTree operation. List is
	** linked together via the pointer normally used for hash chains -
	** RtreeNode.pNext. RtreeNode.iNode stores the depth of the sub-tree
	** headed by the node (leaf nodes have RtreeNode.iNode==0).
	*/
	RtreeNode *pDeleted;

	/* Blob I/O on xxx_node */
	sqlite3_blob *pNodeBlob;

	/* Statements to read/write/delete a record from xxx_node */
	sqlite3_stmt *pWriteNode;
	sqlite3_stmt *pDeleteNode;

	/* Statements to read/write/delete a record from xxx_rowid */
	sqlite3_stmt *pReadRowid;
	sqlite3_stmt *pWriteRowid;
	sqlite3_stmt *pDeleteRowid;

	/* Statements to read/write/delete a record from xxx_parent */
	sqlite3_stmt *pReadParent;
	sqlite3_stmt *pWriteParent;
	sqlite3_stmt *pDeleteParent;

	/* Statement for writing to the "aux:" fields, if there are any */
	sqlite3_stmt *pWriteAux;

	RtreeNode aHash[HASHSIZE]; / Hash table of in-memory nodes. */
	};

	/* Possible values for Rtree.eCoordType: */
	#define RTREE_COORD_REAL32 0
	#define RTREE_COORD_INT32 1

	/*
	** If SQLITE_RTREE_INT_ONLY is defined, then this virtual table will
	** only deal with integer coordinates. No floating point operations
	** will be done.
	*/
	#ifdef SQLITE_RTREE_INT_ONLY
	typedef sqlite3_int64 RtreeDValue; /* High accuracy coordinate */
	typedef int RtreeValue; /* Low accuracy coordinate */
	# define RTREE_ZERO 0
	#else
	typedef double RtreeDValue; /* High accuracy coordinate */
	typedef float RtreeValue; /* Low accuracy coordinate */
	# define RTREE_ZERO 0.0
	#endif

	/*
	** Set the Rtree.bCorrupt flag
	*/
	#ifdef SQLITE_DEBUG
	# define RTREE_IS_CORRUPT(X) ((X)->bCorrupt = 1)
	#else
	# define RTREE_IS_CORRUPT(X)
	#endif

	/*
	** When doing a search of an r-tree, instances of the following structure
	** record intermediate results from the tree walk.
	**
	** The id is always a node-id. For iLevel>=1 the id is the node-id of
	** the node that the RtreeSearchPoint represents. When iLevel==0, however,
	** the id is of the parent node and the cell that RtreeSearchPoint
	** represents is the iCell-th entry in the parent node.
	*/
	struct RtreeSearchPoint {
	RtreeDValue rScore; /* The score for this node. Smallest goes first. */
	sqlite3_int64 id; /* Node ID */
	u8 iLevel; /* 0=entries. 1=leaf node. 2+ for higher */
	u8 eWithin; /* PARTLY_WITHIN or FULLY_WITHIN */
	u8 iCell; /* Cell index within the node */
	};

	/*
	** The minimum number of cells allowed for a node is a third of the
	** maximum. In Gutman's notation:
	**
	** m = M/3
	**
	** If an R*-tree "Reinsert" operation is required, the same number of
	** cells are removed from the overfull node and reinserted into the tree.
	*/
	#define RTREE_MINCELLS(p) ((((p)->iNodeSize-4)/(p)->nBytesPerCell)/3)
	#define RTREE_REINSERT(p) RTREE_MINCELLS(p)
	#define RTREE_MAXCELLS 51

	/*
	** The smallest possible node-size is (512-64)==448 bytes. And the largest
	** supported cell size is 48 bytes (8 byte rowid + ten 4 byte coordinates).
	** Therefore all non-root nodes must contain at least 3 entries. Since
	** 3^40 is greater than 2^64, an r-tree structure always has a depth of
	** 40 or less.
	*/
	#define RTREE_MAX_DEPTH 40


	/*
	** Number of entries in the cursor RtreeNode cache. The first entry is
	** used to cache the RtreeNode for RtreeCursor.sPoint. The remaining
	** entries cache the RtreeNode for the first elements of the priority queue.
	*/
	#define RTREE_CACHE_SZ 5

	/*
	** An rtree cursor object.
	*/
	struct RtreeCursor {
	sqlite3_vtab_cursor base; /* Base class. Must be first */
	u8 atEOF; /* True if at end of search */
	u8 bPoint; /* True if sPoint is valid */
	u8 bAuxValid; /* True if pReadAux is valid */
	int iStrategy; /* Copy of idxNum search parameter */
	int nConstraint; /* Number of entries in aConstraint */
	RtreeConstraint aConstraint; / Search constraints. */
	int nPointAlloc; /* Number of slots allocated for aPoint[] */
	int nPoint; /* Number of slots used in aPoint[] */
	int mxLevel; /* iLevel value for root of the tree */
	RtreeSearchPoint aPoint; / Priority queue for search points */
	sqlite3_stmt pReadAux; / Statement to read aux-data */
	RtreeSearchPoint sPoint; /* Cached next search point */
	RtreeNode aNode[RTREE_CACHE_SZ]; / Rtree node cache */
	u32 anQueue[RTREE_MAX_DEPTH+1]; /* Number of queued entries by iLevel */
	};

	/* Return the Rtree of a RtreeCursor */
	#define RTREE_OF_CURSOR(X) ((Rtree*)((X)->base.pVtab))

	/*
	** A coordinate can be either a floating point number or a integer. All
	** coordinates within a single R-Tree are always of the same time.
	*/
	union RtreeCoord {
	RtreeValue f; /* Floating point value */
	int i; /* Integer value */
	u32 u; /* Unsigned for byte-order conversions */
	};

	/*
	** The argument is an RtreeCoord. Return the value stored within the RtreeCoord
	** formatted as a RtreeDValue (double or int64). This macro assumes that local
	** variable pRtree points to the Rtree structure associated with the
	** RtreeCoord.
	*/
	#ifdef SQLITE_RTREE_INT_ONLY
	# define DCOORD(coord) ((RtreeDValue)coord.i)
	#else
	# define DCOORD(coord) ( \
	(pRtree->eCoordType==RTREE_COORD_REAL32) ? \
	((double)coord.f) : \
	((double)coord.i) \
	)
	#endif

	/*
	** A search constraint.
	*/
	struct RtreeConstraint {
	int iCoord; /* Index of constrained coordinate */
	int op; /* Constraining operation */
	union {
	RtreeDValue rValue; /* Constraint value. */
	int (xGeom)(sqlite3_rtree_geometry,int,RtreeDValue,int);
	int (xQueryFunc)(sqlite3_rtree_query_info);
	} u;
	sqlite3_rtree_query_info pInfo; / xGeom and xQueryFunc argument */
	};

	/* Possible values for RtreeConstraint.op */
	#define RTREE_EQ 0x41 /* A */
	#define RTREE_LE 0x42 /* B */
	#define RTREE_LT 0x43 /* C */
	#define RTREE_GE 0x44 /* D */
	#define RTREE_GT 0x45 /* E */
	#define RTREE_MATCH 0x46 /* F: Old-style sqlite3_rtree_geometry_callback() */
	#define RTREE_QUERY 0x47 /* G: New-style sqlite3_rtree_query_callback() */

	/* Special operators available only on cursors. Needs to be consecutive
	** with the normal values above, but must be less than RTREE_MATCH. These
	** are used in the cursor for contraints such as x=NULL (RTREE_FALSE) or
	** x<'xyz' (RTREE_TRUE) */
	#define RTREE_TRUE 0x3f /* ? */
	#define RTREE_FALSE 0x40 /* @ */

	/*
	** An rtree structure node.
	*/
	struct RtreeNode {
	RtreeNode pParent; / Parent node */
	i64 iNode; /* The node number */
	int nRef; /* Number of references to this node */
	int isDirty; /* True if the node needs to be written to disk */
	u8 zData; / Content of the node, as should be on disk */
	RtreeNode pNext; / Next node in this hash collision chain */
	};

	/* Return the number of cells in a node */
	#define NCELL(pNode) readInt16(&(pNode)->zData[2])

	/*
	** A single cell from a node, deserialized
	*/
	struct RtreeCell {
	i64 iRowid; /* Node or entry ID */
	RtreeCoord aCoord[RTREE_MAX_DIMENSIONS2]; / Bounding box coordinates */
	};


	/*
	** This object becomes the sqlite3_user_data() for the SQL functions
	** that are created by sqlite3_rtree_geometry_callback() and
	** sqlite3_rtree_query_callback() and which appear on the right of MATCH
	** operators in order to constrain a search.
	**
	** xGeom and xQueryFunc are the callback functions. Exactly one of
	** xGeom and xQueryFunc fields is non-NULL, depending on whether the
	** SQL function was created using sqlite3_rtree_geometry_callback() or
	** sqlite3_rtree_query_callback().
	**
	** This object is deleted automatically by the destructor mechanism in
	** sqlite3_create_function_v2().
	*/
	struct RtreeGeomCallback {
	int (xGeom)(sqlite3_rtree_geometry, int, RtreeDValue, int);
	int (xQueryFunc)(sqlite3_rtree_query_info);
	void (xDestructor)(void);
	void *pContext;
	};

	/*
	** An instance of this structure (in the form of a BLOB) is returned by
	** the SQL functions that sqlite3_rtree_geometry_callback() and
	** sqlite3_rtree_query_callback() create, and is read as the right-hand
	** operand to the MATCH operator of an R-Tree.
	*/
	struct RtreeMatchArg {
	u32 iSize; /* Size of this object */
	RtreeGeomCallback cb; /* Info about the callback functions */
	int nParam; /* Number of parameters to the SQL function */
	sqlite3_value *apSqlParam; / Original SQL parameter values */
	RtreeDValue aParam[1]; /* Values for parameters to the SQL function */
	};

	#ifndef MAX
	# define MAX(x,y) ((x) < (y) ? (y) : (x))
	#endif
	#ifndef MIN
	# define MIN(x,y) ((x) > (y) ? (y) : (x))
	#endif

	/* What version of GCC is being used. 0 means GCC is not being used .
	** Note that the GCC_VERSION macro will also be set correctly when using
	** clang, since clang works hard to be gcc compatible. So the gcc
	** optimizations will also work when compiling with clang.
	*/
	#ifndef GCC_VERSION
	#if defined(__GNUC__) && !defined(SQLITE_DISABLE_INTRINSIC)
	# define GCC_VERSION (__GNUC__1000000+__GNUC_MINOR__1000+__GNUC_PATCHLEVEL__)
	#else
	# define GCC_VERSION 0
	#endif
	#endif

	/* The testcase() macro should already be defined in the amalgamation. If
	** it is not, make it a no-op.
	*/
	#ifndef SQLITE_AMALGAMATION
	# if defined(SQLITE_COVERAGE_TEST) \|\| defined(SQLITE_DEBUG)
	unsigned int sqlite3RtreeTestcase = 0;
	# define testcase(X) if( X ){ sqlite3RtreeTestcase += __LINE__; }
	# else
	# define testcase(X)
	# endif
	#endif

	/*
	** Make sure that the compiler intrinsics we desire are enabled when
	** compiling with an appropriate version of MSVC unless prevented by
	** the SQLITE_DISABLE_INTRINSIC define.
	*/
	#if !defined(SQLITE_DISABLE_INTRINSIC)
	# if defined(_MSC_VER) && _MSC_VER>=1400
	# if !defined(_WIN32_WCE)
	# include <intrin.h>
	# pragma intrinsic(_byteswap_ulong)
	# pragma intrinsic(_byteswap_uint64)
	# else
	# include <cmnintrin.h>
	# endif
	# endif
	#endif

	/*
	** Macros to determine whether the machine is big or little endian,
	** and whether or not that determination is run-time or compile-time.
	**
	** For best performance, an attempt is made to guess at the byte-order
	** using C-preprocessor macros. If that is unsuccessful, or if
	** -DSQLITE_RUNTIME_BYTEORDER=1 is set, then byte-order is determined
	** at run-time.
	*/
	#ifndef SQLITE_BYTEORDER /* Replicate changes at tag-20230904a */
	# if defined(__BYTE_ORDER__) && __BYTE_ORDER__==__ORDER_BIG_ENDIAN__
	# define SQLITE_BYTEORDER 4321
	# elif defined(__BYTE_ORDER__) && __BYTE_ORDER__==__ORDER_LITTLE_ENDIAN__
	# define SQLITE_BYTEORDER 1234
	# elif defined(__BIG_ENDIAN__) && __BIG_ENDIAN__==1
	# define SQLITE_BYTEORDER 4321
	# elif defined(i386) \|\| defined(__i386__) \|\| defined(_M_IX86) \|\| \
	defined(__x86_64) \|\| defined(__x86_64__) \|\| defined(_M_X64) \|\| \
	defined(_M_AMD64) \|\| defined(_M_ARM) \|\| defined(__x86) \|\| \
	defined(__ARMEL__) \|\| defined(__AARCH64EL__) \|\| defined(_M_ARM64)
	# define SQLITE_BYTEORDER 1234
	# elif defined(sparc) \|\| defined(__ARMEB__) \|\| defined(__AARCH64EB__)
	# define SQLITE_BYTEORDER 4321
	# else
	# define SQLITE_BYTEORDER 0
	# endif
	#endif


	/* What version of MSVC is being used. 0 means MSVC is not being used */
	#ifndef MSVC_VERSION
	#if defined(_MSC_VER) && !defined(SQLITE_DISABLE_INTRINSIC)
	# define MSVC_VERSION _MSC_VER
	#else
	# define MSVC_VERSION 0
	#endif
	#endif

	/*
	** Functions to deserialize a 16 bit integer, 32 bit real number and
	** 64 bit integer. The deserialized value is returned.
	*/
	static int readInt16(u8 *p){
	return (p[0]<<8) + p[1];
	}
	static void readCoord(u8 p, RtreeCoord pCoord){
	assert( FOUR_BYTE_ALIGNED(p) );
	#if SQLITE_BYTEORDER==1234 && MSVC_VERSION>=1300
	pCoord->u = _byteswap_ulong((u32)p);
	#elif SQLITE_BYTEORDER==1234 && GCC_VERSION>=4003000
	pCoord->u = __builtin_bswap32((u32)p);
	#elif SQLITE_BYTEORDER==4321
	pCoord->u = (u32)p;
	#else
	pCoord->u = (
	(((u32)p[0]) << 24) +
	(((u32)p[1]) << 16) +
	(((u32)p[2]) << 8) +
	(((u32)p[3]) << 0)
	);
	#endif
	}
	static i64 readInt64(u8 *p){
	#if SQLITE_BYTEORDER==1234 && MSVC_VERSION>=1300
	u64 x;
	memcpy(&x, p, 8);
	return (i64)_byteswap_uint64(x);
	#elif SQLITE_BYTEORDER==1234 && GCC_VERSION>=4003000
	u64 x;
	memcpy(&x, p, 8);
	return (i64)__builtin_bswap64(x);
	#elif SQLITE_BYTEORDER==4321
	i64 x;
	memcpy(&x, p, 8);
	return x;
	#else
	return (i64)(
	(((u64)p[0]) << 56) +
	(((u64)p[1]) << 48) +
	(((u64)p[2]) << 40) +
	(((u64)p[3]) << 32) +
	(((u64)p[4]) << 24) +
	(((u64)p[5]) << 16) +
	(((u64)p[6]) << 8) +
	(((u64)p[7]) << 0)
	);
	#endif
	}

	/*
	** Functions to serialize a 16 bit integer, 32 bit real number and
	** 64 bit integer. The value returned is the number of bytes written
	** to the argument buffer (always 2, 4 and 8 respectively).
	*/
	static void writeInt16(u8 *p, int i){
	p[0] = (i>> 8)&0xFF;
	p[1] = (i>> 0)&0xFF;
	}
	static int writeCoord(u8 p, RtreeCoord pCoord){
	u32 i;
	assert( FOUR_BYTE_ALIGNED(p) );
	assert( sizeof(RtreeCoord)==4 );
	assert( sizeof(u32)==4 );
	#if SQLITE_BYTEORDER==1234 && GCC_VERSION>=4003000
	i = __builtin_bswap32(pCoord->u);
	memcpy(p, &i, 4);
	#elif SQLITE_BYTEORDER==1234 && MSVC_VERSION>=1300
	i = _byteswap_ulong(pCoord->u);
	memcpy(p, &i, 4);
	#elif SQLITE_BYTEORDER==4321
	i = pCoord->u;
	memcpy(p, &i, 4);
	#else
	i = pCoord->u;
	p[0] = (i>>24)&0xFF;
	p[1] = (i>>16)&0xFF;
	p[2] = (i>> 8)&0xFF;
	p[3] = (i>> 0)&0xFF;
	#endif
	return 4;
	}
	static int writeInt64(u8 *p, i64 i){
	#if SQLITE_BYTEORDER==1234 && GCC_VERSION>=4003000
	i = (i64)__builtin_bswap64((u64)i);
	memcpy(p, &i, 8);
	#elif SQLITE_BYTEORDER==1234 && MSVC_VERSION>=1300
	i = (i64)_byteswap_uint64((u64)i);
	memcpy(p, &i, 8);
	#elif SQLITE_BYTEORDER==4321
	memcpy(p, &i, 8);
	#else
	p[0] = (i>>56)&0xFF;
	p[1] = (i>>48)&0xFF;
	p[2] = (i>>40)&0xFF;
	p[3] = (i>>32)&0xFF;
	p[4] = (i>>24)&0xFF;
	p[5] = (i>>16)&0xFF;
	p[6] = (i>> 8)&0xFF;
	p[7] = (i>> 0)&0xFF;
	#endif
	return 8;
	}

	/*
	** Increment the reference count of node p.
	*/
	static void nodeReference(RtreeNode *p){
	if( p ){
	assert( p->nRef>0 );
	p->nRef++;
	}
	}

	/*
	** Clear the content of node p (set all bytes to 0x00).
	*/
	static void nodeZero(Rtree pRtree, RtreeNode p){
	memset(&p->zData[2], 0, pRtree->iNodeSize-2);
	p->isDirty = 1;
	}

	/*
	** Given a node number iNode, return the corresponding key to use
	** in the Rtree.aHash table.
	*/
	static unsigned int nodeHash(i64 iNode){
	return ((unsigned)iNode) % HASHSIZE;
	}

	/*
	** Search the node hash table for node iNode. If found, return a pointer
	** to it. Otherwise, return 0.
	*/
	static RtreeNode nodeHashLookup(Rtree pRtree, i64 iNode){
	RtreeNode *p;
	for(p=pRtree->aHash[nodeHash(iNode)]; p && p->iNode!=iNode; p=p->pNext);
	return p;
	}

	/*
	** Add node pNode to the node hash table.
	*/
	static void nodeHashInsert(Rtree pRtree, RtreeNode pNode){
	int iHash;
	assert( pNode->pNext==0 );
	iHash = nodeHash(pNode->iNode);
	pNode->pNext = pRtree->aHash[iHash];
	pRtree->aHash[iHash] = pNode;
	}

	/*
	** Remove node pNode from the node hash table.
	*/
	static void nodeHashDelete(Rtree pRtree, RtreeNode pNode){
	RtreeNode **pp;
	if( pNode->iNode!=0 ){
	pp = &pRtree->aHash[nodeHash(pNode->iNode)];
	for( ; (pp)!=pNode; pp = &(pp)->pNext){ assert(*pp); }
	*pp = pNode->pNext;
	pNode->pNext = 0;
	}
	}

	/*
	** Allocate and return new r-tree node. Initially, (RtreeNode.iNode==0),
	** indicating that node has not yet been assigned a node number. It is
	** assigned a node number when nodeWrite() is called to write the
	** node contents out to the database.
	*/
	static RtreeNode nodeNew(Rtree pRtree, RtreeNode *pParent){
	RtreeNode *pNode;
	pNode = (RtreeNode *)sqlite3_malloc64(sizeof(RtreeNode) + pRtree->iNodeSize);
	if( pNode ){
	memset(pNode, 0, sizeof(RtreeNode) + pRtree->iNodeSize);
	pNode->zData = (u8 *)&pNode[1];
	pNode->nRef = 1;
	pRtree->nNodeRef++;
	pNode->pParent = pParent;
	pNode->isDirty = 1;
	nodeReference(pParent);
	}
	return pNode;
	}

	/*
	** Clear the Rtree.pNodeBlob object
	*/
	static void nodeBlobReset(Rtree *pRtree){
	sqlite3_blob *pBlob = pRtree->pNodeBlob;
	pRtree->pNodeBlob = 0;
	sqlite3_blob_close(pBlob);
	}

	/*
	** Obtain a reference to an r-tree node.
	*/
	static int nodeAcquire(
	Rtree pRtree, / R-tree structure */
	i64 iNode, /* Node number to load */
	RtreeNode pParent, / Either the parent node or NULL */
	RtreeNode *ppNode / OUT: Acquired node */
	){
	int rc = SQLITE_OK;
	RtreeNode *pNode = 0;

	/* Check if the requested node is already in the hash table. If so,
	** increase its reference count and return it.
	*/
	if( (pNode = nodeHashLookup(pRtree, iNode))!=0 ){
	if( pParent && ALWAYS(pParent!=pNode->pParent) ){
	RTREE_IS_CORRUPT(pRtree);
	return SQLITE_CORRUPT_VTAB;
	}
	pNode->nRef++;
	*ppNode = pNode;
	return SQLITE_OK;
	}

	if( pRtree->pNodeBlob ){
	sqlite3_blob *pBlob = pRtree->pNodeBlob;
	pRtree->pNodeBlob = 0;
	rc = sqlite3_blob_reopen(pBlob, iNode);
	pRtree->pNodeBlob = pBlob;
	if( rc ){
	nodeBlobReset(pRtree);
	if( rc==SQLITE_NOMEM ) return SQLITE_NOMEM;
	}
	}
	if( pRtree->pNodeBlob==0 ){
	rc = sqlite3_blob_open(pRtree->db, pRtree->zDb, pRtree->zNodeName,
	"data", iNode, 0,
	&pRtree->pNodeBlob);
	}
	if( rc ){
	*ppNode = 0;
	/* If unable to open an sqlite3_blob on the desired row, that can only
	** be because the shadow tables hold erroneous data. */
	if( rc==SQLITE_ERROR ){
	rc = SQLITE_CORRUPT_VTAB;
	RTREE_IS_CORRUPT(pRtree);
	}
	}else if( pRtree->iNodeSize==sqlite3_blob_bytes(pRtree->pNodeBlob) ){
	pNode = (RtreeNode *)sqlite3_malloc64(sizeof(RtreeNode)+pRtree->iNodeSize);
	if( !pNode ){
	rc = SQLITE_NOMEM;
	}else{
	pNode->pParent = pParent;
	pNode->zData = (u8 *)&pNode[1];
	pNode->nRef = 1;
	pRtree->nNodeRef++;
	pNode->iNode = iNode;
	pNode->isDirty = 0;
	pNode->pNext = 0;
	rc = sqlite3_blob_read(pRtree->pNodeBlob, pNode->zData,
	pRtree->iNodeSize, 0);
	}
	}

	/* If the root node was just loaded, set pRtree->iDepth to the height
	** of the r-tree structure. A height of zero means all data is stored on
	** the root node. A height of one means the children of the root node
	** are the leaves, and so on. If the depth as specified on the root node
	** is greater than RTREE_MAX_DEPTH, the r-tree structure must be corrupt.
	*/
	if( rc==SQLITE_OK && pNode && iNode==1 ){
	pRtree->iDepth = readInt16(pNode->zData);
	if( pRtree->iDepth>RTREE_MAX_DEPTH ){
	rc = SQLITE_CORRUPT_VTAB;
	RTREE_IS_CORRUPT(pRtree);
	}
	}

	/* If no error has occurred so far, check if the "number of entries"
	** field on the node is too large. If so, set the return code to
	** SQLITE_CORRUPT_VTAB.
	*/
	if( pNode && rc==SQLITE_OK ){
	if( NCELL(pNode)>((pRtree->iNodeSize-4)/pRtree->nBytesPerCell) ){
	rc = SQLITE_CORRUPT_VTAB;
	RTREE_IS_CORRUPT(pRtree);
	}
	}

	if( rc==SQLITE_OK ){
	if( pNode!=0 ){
	nodeReference(pParent);
	nodeHashInsert(pRtree, pNode);
	}else{
	rc = SQLITE_CORRUPT_VTAB;
	RTREE_IS_CORRUPT(pRtree);
	}
	*ppNode = pNode;
	}else{
	nodeBlobReset(pRtree);
	if( pNode ){
	pRtree->nNodeRef--;
	sqlite3_free(pNode);
	}
	*ppNode = 0;
	}

	return rc;
	}

	/*
	** Overwrite cell iCell of node pNode with the contents of pCell.
	*/
	static void nodeOverwriteCell(
	Rtree pRtree, / The overall R-Tree */
	RtreeNode pNode, / The node into which the cell is to be written */
	RtreeCell pCell, / The cell to write */
	int iCell /* Index into pNode into which pCell is written */
	){
	int ii;
	u8 p = &pNode->zData[4 + pRtree->nBytesPerCelliCell];
	p += writeInt64(p, pCell->iRowid);
	for(ii=0; ii<pRtree->nDim2; ii++){
	p += writeCoord(p, &pCell->aCoord[ii]);
	}
	pNode->isDirty = 1;
	}

	/*
	** Remove the cell with index iCell from node pNode.
	*/
	static void nodeDeleteCell(Rtree pRtree, RtreeNode pNode, int iCell){
	u8 pDst = &pNode->zData[4 + pRtree->nBytesPerCelliCell];
	u8 *pSrc = &pDst[pRtree->nBytesPerCell];
	int nByte = (NCELL(pNode) - iCell - 1) * pRtree->nBytesPerCell;
	memmove(pDst, pSrc, nByte);
	writeInt16(&pNode->zData[2], NCELL(pNode)-1);
	pNode->isDirty = 1;
	}

	/*
	** Insert the contents of cell pCell into node pNode. If the insert
	** is successful, return SQLITE_OK.
	**
	** If there is not enough free space in pNode, return SQLITE_FULL.
	*/
	static int nodeInsertCell(
	Rtree pRtree, / The overall R-Tree */
	RtreeNode pNode, / Write new cell into this node */
	RtreeCell pCell / The cell to be inserted */
	){
	int nCell; /* Current number of cells in pNode */
	int nMaxCell; /* Maximum number of cells for pNode */

	nMaxCell = (pRtree->iNodeSize-4)/pRtree->nBytesPerCell;
	nCell = NCELL(pNode);

	assert( nCell<=nMaxCell );
	if( nCell<nMaxCell ){
	nodeOverwriteCell(pRtree, pNode, pCell, nCell);
	writeInt16(&pNode->zData[2], nCell+1);
	pNode->isDirty = 1;
	}

	return (nCell==nMaxCell);
	}

	/*
	** If the node is dirty, write it out to the database.
	*/
	static int nodeWrite(Rtree pRtree, RtreeNode pNode){
	int rc = SQLITE_OK;
	if( pNode->isDirty ){
	sqlite3_stmt *p = pRtree->pWriteNode;
	if( pNode->iNode ){
	sqlite3_bind_int64(p, 1, pNode->iNode);
	}else{
	sqlite3_bind_null(p, 1);
	}
	sqlite3_bind_blob(p, 2, pNode->zData, pRtree->iNodeSize, SQLITE_STATIC);
	sqlite3_step(p);
	pNode->isDirty = 0;
	rc = sqlite3_reset(p);
	sqlite3_bind_null(p, 2);
	if( pNode->iNode==0 && rc==SQLITE_OK ){
	pNode->iNode = sqlite3_last_insert_rowid(pRtree->db);
	nodeHashInsert(pRtree, pNode);
	}
	}
	return rc;
	}

	/*
	** Release a reference to a node. If the node is dirty and the reference
	** count drops to zero, the node data is written to the database.
	*/
	static int nodeRelease(Rtree pRtree, RtreeNode pNode){
	int rc = SQLITE_OK;
	if( pNode ){
	assert( pNode->nRef>0 );
	assert( pRtree->nNodeRef>0 );
	pNode->nRef--;
	if( pNode->nRef==0 ){
	pRtree->nNodeRef--;
	if( pNode->iNode==1 ){
	pRtree->iDepth = -1;
	}
	if( pNode->pParent ){
	rc = nodeRelease(pRtree, pNode->pParent);
	}
	if( rc==SQLITE_OK ){
	rc = nodeWrite(pRtree, pNode);
	}
	nodeHashDelete(pRtree, pNode);
	sqlite3_free(pNode);
	}
	}
	return rc;
	}

	/*
	** Return the 64-bit integer value associated with cell iCell of
	** node pNode. If pNode is a leaf node, this is a rowid. If it is
	** an internal node, then the 64-bit integer is a child page number.
	*/
	static i64 nodeGetRowid(
	Rtree pRtree, / The overall R-Tree */
	RtreeNode pNode, / The node from which to extract the ID */
	int iCell /* The cell index from which to extract the ID */
	){
	assert( iCell<NCELL(pNode) );
	return readInt64(&pNode->zData[4 + pRtree->nBytesPerCell*iCell]);
	}

	/*
	** Return coordinate iCoord from cell iCell in node pNode.
	*/
	static void nodeGetCoord(
	Rtree pRtree, / The overall R-Tree */
	RtreeNode pNode, / The node from which to extract a coordinate */
	int iCell, /* The index of the cell within the node */
	int iCoord, /* Which coordinate to extract */
	RtreeCoord pCoord / OUT: Space to write result to */
	){
	assert( iCell<NCELL(pNode) );
	readCoord(&pNode->zData[12 + pRtree->nBytesPerCelliCell + 4iCoord], pCoord);
	}

	/*
	** Deserialize cell iCell of node pNode. Populate the structure pointed
	** to by pCell with the results.
	*/
	static void nodeGetCell(
	Rtree pRtree, / The overall R-Tree */
	RtreeNode pNode, / The node containing the cell to be read */
	int iCell, /* Index of the cell within the node */
	RtreeCell pCell / OUT: Write the cell contents here */
	){
	u8 *pData;
	RtreeCoord *pCoord;
	int ii = 0;
	pCell->iRowid = nodeGetRowid(pRtree, pNode, iCell);
	pData = pNode->zData + (12 + pRtree->nBytesPerCell*iCell);
	pCoord = pCell->aCoord;
	do{
	readCoord(pData, &pCoord[ii]);
	readCoord(pData+4, &pCoord[ii+1]);
	pData += 8;
	ii += 2;
	}while( ii<pRtree->nDim2 );
	}


	/* Forward declaration for the function that does the work of
	** the virtual table module xCreate() and xConnect() methods.
	*/
	static int rtreeInit(
	sqlite3 , void , int, const char const, sqlite3_vtab , char , int
	);

	/*
	** Rtree virtual table module xCreate method.
	*/
	static int rtreeCreate(
	sqlite3 *db,
	void *pAux,
	int argc, const char constargv,
	sqlite3_vtab **ppVtab,
	char **pzErr
	){
	return rtreeInit(db, pAux, argc, argv, ppVtab, pzErr, 1);
	}

	/*
	** Rtree virtual table module xConnect method.
	*/
	static int rtreeConnect(
	sqlite3 *db,
	void *pAux,
	int argc, const char constargv,
	sqlite3_vtab **ppVtab,
	char **pzErr
	){
	return rtreeInit(db, pAux, argc, argv, ppVtab, pzErr, 0);
	}

	/*
	** Increment the r-tree reference count.
	*/
	static void rtreeReference(Rtree *pRtree){
	pRtree->nBusy++;
	}

	/*
	** Decrement the r-tree reference count. When the reference count reaches
	** zero the structure is deleted.
	*/
	static void rtreeRelease(Rtree *pRtree){
	pRtree->nBusy--;
	if( pRtree->nBusy==0 ){
	pRtree->inWrTrans = 0;
	assert( pRtree->nCursor==0 );
	nodeBlobReset(pRtree);
	assert( pRtree->nNodeRef==0 \|\| pRtree->bCorrupt );
	sqlite3_finalize(pRtree->pWriteNode);
	sqlite3_finalize(pRtree->pDeleteNode);
	sqlite3_finalize(pRtree->pReadRowid);
	sqlite3_finalize(pRtree->pWriteRowid);
	sqlite3_finalize(pRtree->pDeleteRowid);
	sqlite3_finalize(pRtree->pReadParent);
	sqlite3_finalize(pRtree->pWriteParent);
	sqlite3_finalize(pRtree->pDeleteParent);
	sqlite3_finalize(pRtree->pWriteAux);
	sqlite3_free(pRtree->zReadAuxSql);
	sqlite3_free(pRtree);
	}
	}

	/*
	** Rtree virtual table module xDisconnect method.
	*/
	static int rtreeDisconnect(sqlite3_vtab *pVtab){
	rtreeRelease((Rtree *)pVtab);
	return SQLITE_OK;
	}

	/*
	** Rtree virtual table module xDestroy method.
	*/
	static int rtreeDestroy(sqlite3_vtab *pVtab){
	Rtree pRtree = (Rtree )pVtab;
	int rc;
	char *zCreate = sqlite3_mprintf(
	"DROP TABLE '%q'.'%q_node';"
	"DROP TABLE '%q'.'%q_rowid';"
	"DROP TABLE '%q'.'%q_parent';",
	pRtree->zDb, pRtree->zName,
	pRtree->zDb, pRtree->zName,
	pRtree->zDb, pRtree->zName
	);
	if( !zCreate ){
	rc = SQLITE_NOMEM;
	}else{
	nodeBlobReset(pRtree);
	rc = sqlite3_exec(pRtree->db, zCreate, 0, 0, 0);
	sqlite3_free(zCreate);
	}
	if( rc==SQLITE_OK ){
	rtreeRelease(pRtree);
	}

	return rc;
	}

	/*
	** Rtree virtual table module xOpen method.
	*/
	static int rtreeOpen(sqlite3_vtab pVTab, sqlite3_vtab_cursor *ppCursor){
	int rc = SQLITE_NOMEM;
	Rtree pRtree = (Rtree )pVTab;
	RtreeCursor *pCsr;

	pCsr = (RtreeCursor *)sqlite3_malloc64(sizeof(RtreeCursor));
	if( pCsr ){
	memset(pCsr, 0, sizeof(RtreeCursor));
	pCsr->base.pVtab = pVTab;
	rc = SQLITE_OK;
	pRtree->nCursor++;
	}
	ppCursor = (sqlite3_vtab_cursor )pCsr;

	return rc;
	}


	/*
	** Reset a cursor back to its initial state.
	*/
	static void resetCursor(RtreeCursor *pCsr){
	Rtree pRtree = (Rtree )(pCsr->base.pVtab);
	int ii;
	sqlite3_stmt *pStmt;
	if( pCsr->aConstraint ){
	int i; /* Used to iterate through constraint array */
	for(i=0; i<pCsr->nConstraint; i++){
	sqlite3_rtree_query_info *pInfo = pCsr->aConstraint[i].pInfo;
	if( pInfo ){
	if( pInfo->xDelUser ) pInfo->xDelUser(pInfo->pUser);
	sqlite3_free(pInfo);
	}
	}
	sqlite3_free(pCsr->aConstraint);
	pCsr->aConstraint = 0;
	}
	for(ii=0; ii<RTREE_CACHE_SZ; ii++) nodeRelease(pRtree, pCsr->aNode[ii]);
	sqlite3_free(pCsr->aPoint);
	pStmt = pCsr->pReadAux;
	memset(pCsr, 0, sizeof(RtreeCursor));
	pCsr->base.pVtab = (sqlite3_vtab*)pRtree;
	pCsr->pReadAux = pStmt;

	}

	/*
	** Rtree virtual table module xClose method.
	*/
	static int rtreeClose(sqlite3_vtab_cursor *cur){
	Rtree pRtree = (Rtree )(cur->pVtab);
	RtreeCursor pCsr = (RtreeCursor )cur;
	assert( pRtree->nCursor>0 );
	resetCursor(pCsr);
	sqlite3_finalize(pCsr->pReadAux);
	sqlite3_free(pCsr);
	pRtree->nCursor--;
	if( pRtree->nCursor==0 && pRtree->inWrTrans==0 ){
	nodeBlobReset(pRtree);
	}
	return SQLITE_OK;
	}

	/*
	** Rtree virtual table module xEof method.
	**
	** Return non-zero if the cursor does not currently point to a valid
	** record (i.e if the scan has finished), or zero otherwise.
	*/
	static int rtreeEof(sqlite3_vtab_cursor *cur){
	RtreeCursor pCsr = (RtreeCursor )cur;
	return pCsr->atEOF;
	}

	/*
	** Convert raw bits from the on-disk RTree record into a coordinate value.
	** The on-disk format is big-endian and needs to be converted for little-
	** endian platforms. The on-disk record stores integer coordinates if
	** eInt is true and it stores 32-bit floating point records if eInt is
	** false. a[] is the four bytes of the on-disk record to be decoded.
	** Store the results in "r".
	**
	** There are five versions of this macro. The last one is generic. The
	** other four are various architectures-specific optimizations.
	*/
	#if SQLITE_BYTEORDER==1234 && MSVC_VERSION>=1300
	#define RTREE_DECODE_COORD(eInt, a, r) { \
	RtreeCoord c; /* Coordinate decoded */ \
	c.u = _byteswap_ulong((u32)a); \
	r = eInt ? (sqlite3_rtree_dbl)c.i : (sqlite3_rtree_dbl)c.f; \
	}
	#elif SQLITE_BYTEORDER==1234 && GCC_VERSION>=4003000
	#define RTREE_DECODE_COORD(eInt, a, r) { \
	RtreeCoord c; /* Coordinate decoded */ \
	c.u = __builtin_bswap32((u32)a); \
	r = eInt ? (sqlite3_rtree_dbl)c.i : (sqlite3_rtree_dbl)c.f; \
	}
	#elif SQLITE_BYTEORDER==1234
	#define RTREE_DECODE_COORD(eInt, a, r) { \
	RtreeCoord c; /* Coordinate decoded */ \
	memcpy(&c.u,a,4); \
	c.u = ((c.u>>24)&0xff)\|((c.u>>8)&0xff00)\| \
	((c.u&0xff)<<24)\|((c.u&0xff00)<<8); \
	r = eInt ? (sqlite3_rtree_dbl)c.i : (sqlite3_rtree_dbl)c.f; \
	}
	#elif SQLITE_BYTEORDER==4321
	#define RTREE_DECODE_COORD(eInt, a, r) { \
	RtreeCoord c; /* Coordinate decoded */ \
	memcpy(&c.u,a,4); \
	r = eInt ? (sqlite3_rtree_dbl)c.i : (sqlite3_rtree_dbl)c.f; \
	}
	#else
	#define RTREE_DECODE_COORD(eInt, a, r) { \
	RtreeCoord c; /* Coordinate decoded */ \
	c.u = ((u32)a[0]<<24) + ((u32)a[1]<<16) \
	+((u32)a[2]<<8) + a[3]; \
	r = eInt ? (sqlite3_rtree_dbl)c.i : (sqlite3_rtree_dbl)c.f; \
	}
	#endif

	/*
	** Check the RTree node or entry given by pCellData and p against the MATCH
	** constraint pConstraint.
	*/
	static int rtreeCallbackConstraint(
	RtreeConstraint pConstraint, / The constraint to test */
	int eInt, /* True if RTree holding integer coordinates */
	u8 pCellData, / Raw cell content */
	RtreeSearchPoint pSearch, / Container of this cell */
	sqlite3_rtree_dbl prScore, / OUT: score for the cell */
	int peWithin / OUT: visibility of the cell */
	){
	sqlite3_rtree_query_info pInfo = pConstraint->pInfo; / Callback info */
	int nCoord = pInfo->nCoord; /* No. of coordinates */
	int rc; /* Callback return code */
	RtreeCoord c; /* Translator union */
	sqlite3_rtree_dbl aCoord[RTREE_MAX_DIMENSIONS2]; / Decoded coordinates */

	assert( pConstraint->op==RTREE_MATCH \|\| pConstraint->op==RTREE_QUERY );
	assert( nCoord==2 \|\| nCoord==4 \|\| nCoord==6 \|\| nCoord==8 \|\| nCoord==10 );

	if( pConstraint->op==RTREE_QUERY && pSearch->iLevel==1 ){
	pInfo->iRowid = readInt64(pCellData);
	}
	pCellData += 8;
	#ifndef SQLITE_RTREE_INT_ONLY
	if( eInt==0 ){
	switch( nCoord ){
	case 10: readCoord(pCellData+36, &c); aCoord[9] = c.f;
	readCoord(pCellData+32, &c); aCoord[8] = c.f;
	case 8: readCoord(pCellData+28, &c); aCoord[7] = c.f;
	readCoord(pCellData+24, &c); aCoord[6] = c.f;
	case 6: readCoord(pCellData+20, &c); aCoord[5] = c.f;
	readCoord(pCellData+16, &c); aCoord[4] = c.f;
	case 4: readCoord(pCellData+12, &c); aCoord[3] = c.f;
	readCoord(pCellData+8, &c); aCoord[2] = c.f;
	default: readCoord(pCellData+4, &c); aCoord[1] = c.f;
	readCoord(pCellData, &c); aCoord[0] = c.f;
	}
	}else
	#endif
	{
	switch( nCoord ){
	case 10: readCoord(pCellData+36, &c); aCoord[9] = c.i;
	readCoord(pCellData+32, &c); aCoord[8] = c.i;
	case 8: readCoord(pCellData+28, &c); aCoord[7] = c.i;
	readCoord(pCellData+24, &c); aCoord[6] = c.i;
	case 6: readCoord(pCellData+20, &c); aCoord[5] = c.i;
	readCoord(pCellData+16, &c); aCoord[4] = c.i;
	case 4: readCoord(pCellData+12, &c); aCoord[3] = c.i;
	readCoord(pCellData+8, &c); aCoord[2] = c.i;
	default: readCoord(pCellData+4, &c); aCoord[1] = c.i;
	readCoord(pCellData, &c); aCoord[0] = c.i;
	}
	}
	if( pConstraint->op==RTREE_MATCH ){
	int eWithin = 0;
	rc = pConstraint->u.xGeom((sqlite3_rtree_geometry*)pInfo,
	nCoord, aCoord, &eWithin);
	if( eWithin==0 ) *peWithin = NOT_WITHIN;
	*prScore = RTREE_ZERO;
	}else{
	pInfo->aCoord = aCoord;
	pInfo->iLevel = pSearch->iLevel - 1;
	pInfo->rScore = pInfo->rParentScore = pSearch->rScore;
	pInfo->eWithin = pInfo->eParentWithin = pSearch->eWithin;
	rc = pConstraint->u.xQueryFunc(pInfo);
	if( pInfo->eWithin<peWithin ) peWithin = pInfo->eWithin;
	if( pInfo->rScore<prScore \|\| prScore<RTREE_ZERO ){
	*prScore = pInfo->rScore;
	}
	}
	return rc;
	}

	/*
	** Check the internal RTree node given by pCellData against constraint p.
	** If this constraint cannot be satisfied by any child within the node,
	** set *peWithin to NOT_WITHIN.
	*/
	static void rtreeNonleafConstraint(
	RtreeConstraint p, / The constraint to test */
	int eInt, /* True if RTree holds integer coordinates */
	u8 pCellData, / Raw cell content as appears on disk */
	int peWithin / Adjust downward, as appropriate */
	){
	sqlite3_rtree_dbl val; /* Coordinate value convert to a double */

	/* p->iCoord might point to either a lower or upper bound coordinate
	** in a coordinate pair. But make pCellData point to the lower bound.
	*/
	pCellData += 8 + 4*(p->iCoord&0xfe);

	assert(p->op==RTREE_LE \|\| p->op==RTREE_LT \|\| p->op==RTREE_GE
	\|\| p->op==RTREE_GT \|\| p->op==RTREE_EQ \|\| p->op==RTREE_TRUE
	\|\| p->op==RTREE_FALSE );
	assert( FOUR_BYTE_ALIGNED(pCellData) );
	switch( p->op ){
	case RTREE_TRUE: return; /* Always satisfied */
	case RTREE_FALSE: break; /* Never satisfied */
	case RTREE_EQ:
	RTREE_DECODE_COORD(eInt, pCellData, val);
	/* val now holds the lower bound of the coordinate pair */
	if( p->u.rValue>=val ){
	pCellData += 4;
	RTREE_DECODE_COORD(eInt, pCellData, val);
	/* val now holds the upper bound of the coordinate pair */
	if( p->u.rValue<=val ) return;
	}
	break;
	case RTREE_LE:
	case RTREE_LT:
	RTREE_DECODE_COORD(eInt, pCellData, val);
	/* val now holds the lower bound of the coordinate pair */
	if( p->u.rValue>=val ) return;
	break;

	default:
	pCellData += 4;
	RTREE_DECODE_COORD(eInt, pCellData, val);
	/* val now holds the upper bound of the coordinate pair */
	if( p->u.rValue<=val ) return;
	break;
	}
	*peWithin = NOT_WITHIN;
	}

	/*
	** Check the leaf RTree cell given by pCellData against constraint p.
	** If this constraint is not satisfied, set *peWithin to NOT_WITHIN.
	** If the constraint is satisfied, leave *peWithin unchanged.
	**
	** The constraint is of the form: xN op $val
	**
	** The op is given by p->op. The xN is p->iCoord-th coordinate in
	** pCellData. $val is given by p->u.rValue.
	*/
	static void rtreeLeafConstraint(
	RtreeConstraint p, / The constraint to test */
	int eInt, /* True if RTree holds integer coordinates */
	u8 pCellData, / Raw cell content as appears on disk */
	int peWithin / Adjust downward, as appropriate */
	){
	RtreeDValue xN; /* Coordinate value converted to a double */

	assert(p->op==RTREE_LE \|\| p->op==RTREE_LT \|\| p->op==RTREE_GE
	\|\| p->op==RTREE_GT \|\| p->op==RTREE_EQ \|\| p->op==RTREE_TRUE
	\|\| p->op==RTREE_FALSE );
	pCellData += 8 + p->iCoord*4;
	assert( FOUR_BYTE_ALIGNED(pCellData) );
	RTREE_DECODE_COORD(eInt, pCellData, xN);
	switch( p->op ){
	case RTREE_TRUE: return; /* Always satisfied */
	case RTREE_FALSE: break; /* Never satisfied */
	case RTREE_LE: if( xN <= p->u.rValue ) return; break;
	case RTREE_LT: if( xN < p->u.rValue ) return; break;
	case RTREE_GE: if( xN >= p->u.rValue ) return; break;
	case RTREE_GT: if( xN > p->u.rValue ) return; break;
	default: if( xN == p->u.rValue ) return; break;
	}
	*peWithin = NOT_WITHIN;
	}

	/*
	** One of the cells in node pNode is guaranteed to have a 64-bit
	** integer value equal to iRowid. Return the index of this cell.
	*/
	static int nodeRowidIndex(
	Rtree *pRtree,
	RtreeNode *pNode,
	i64 iRowid,
	int *piIndex
	){
	int ii;
	int nCell = NCELL(pNode);
	assert( nCell<200 );
	for(ii=0; ii<nCell; ii++){
	if( nodeGetRowid(pRtree, pNode, ii)==iRowid ){
	*piIndex = ii;
	return SQLITE_OK;
	}
	}
	RTREE_IS_CORRUPT(pRtree);
	return SQLITE_CORRUPT_VTAB;
	}

	/*
	** Return the index of the cell containing a pointer to node pNode
	** in its parent. If pNode is the root node, return -1.
	*/
	static int nodeParentIndex(Rtree pRtree, RtreeNode pNode, int *piIndex){
	RtreeNode *pParent = pNode->pParent;
	if( ALWAYS(pParent) ){
	return nodeRowidIndex(pRtree, pParent, pNode->iNode, piIndex);
	}else{
	*piIndex = -1;
	return SQLITE_OK;
	}
	}

	/*
	** Compare two search points. Return negative, zero, or positive if the first
	** is less than, equal to, or greater than the second.
	**
	** The rScore is the primary key. Smaller rScore values come first.
	** If the rScore is a tie, then use iLevel as the tie breaker with smaller
	** iLevel values coming first. In this way, if rScore is the same for all
	** SearchPoints, then iLevel becomes the deciding factor and the result
	** is a depth-first search, which is the desired default behavior.
	*/
	static int rtreeSearchPointCompare(
	const RtreeSearchPoint *pA,
	const RtreeSearchPoint *pB
	){
	if( pA->rScore<pB->rScore ) return -1;
	if( pA->rScore>pB->rScore ) return +1;
	if( pA->iLevel<pB->iLevel ) return -1;
	if( pA->iLevel>pB->iLevel ) return +1;
	return 0;
	}

	/*
	** Interchange two search points in a cursor.
	*/
	static void rtreeSearchPointSwap(RtreeCursor *p, int i, int j){
	RtreeSearchPoint t = p->aPoint[i];
	assert( i<j );
	p->aPoint[i] = p->aPoint[j];
	p->aPoint[j] = t;
	i++; j++;
	if( i<RTREE_CACHE_SZ ){
	if( j>=RTREE_CACHE_SZ ){
	nodeRelease(RTREE_OF_CURSOR(p), p->aNode[i]);
	p->aNode[i] = 0;
	}else{
	RtreeNode *pTemp = p->aNode[i];
	p->aNode[i] = p->aNode[j];
	p->aNode[j] = pTemp;
	}
	}
	}

	/*
	** Return the search point with the lowest current score.
	*/
	static RtreeSearchPoint rtreeSearchPointFirst(RtreeCursor pCur){
	return pCur->bPoint ? &pCur->sPoint : pCur->nPoint ? pCur->aPoint : 0;
	}

	/*
	** Get the RtreeNode for the search point with the lowest score.
	*/
	static RtreeNode rtreeNodeOfFirstSearchPoint(RtreeCursor pCur, int *pRC){
	sqlite3_int64 id;
	int ii = 1 - pCur->bPoint;
	assert( ii==0 \|\| ii==1 );
	assert( pCur->bPoint \|\| pCur->nPoint );
	if( pCur->aNode[ii]==0 ){
	assert( pRC!=0 );
	id = ii ? pCur->aPoint[0].id : pCur->sPoint.id;
	*pRC = nodeAcquire(RTREE_OF_CURSOR(pCur), id, 0, &pCur->aNode[ii]);
	}
	return pCur->aNode[ii];
	}

	/*
	** Push a new element onto the priority queue
	*/
	static RtreeSearchPoint *rtreeEnqueue(
	RtreeCursor pCur, / The cursor */
	RtreeDValue rScore, /* Score for the new search point */
	u8 iLevel /* Level for the new search point */
	){
	int i, j;
	RtreeSearchPoint *pNew;
	if( pCur->nPoint>=pCur->nPointAlloc ){
	int nNew = pCur->nPointAlloc*2 + 8;
	pNew = sqlite3_realloc64(pCur->aPoint, nNew*sizeof(pCur->aPoint[0]));
	if( pNew==0 ) return 0;
	pCur->aPoint = pNew;
	pCur->nPointAlloc = nNew;
	}
	i = pCur->nPoint++;
	pNew = pCur->aPoint + i;
	pNew->rScore = rScore;
	pNew->iLevel = iLevel;
	assert( iLevel<=RTREE_MAX_DEPTH );
	while( i>0 ){
	RtreeSearchPoint *pParent;
	j = (i-1)/2;
	pParent = pCur->aPoint + j;
	if( rtreeSearchPointCompare(pNew, pParent)>=0 ) break;
	rtreeSearchPointSwap(pCur, j, i);
	i = j;
	pNew = pParent;
	}
	return pNew;
	}

	/*
	** Allocate a new RtreeSearchPoint and return a pointer to it. Return
	** NULL if malloc fails.
	*/
	static RtreeSearchPoint *rtreeSearchPointNew(
	RtreeCursor pCur, / The cursor */
	RtreeDValue rScore, /* Score for the new search point */
	u8 iLevel /* Level for the new search point */
	){
	RtreeSearchPoint pNew, pFirst;
	pFirst = rtreeSearchPointFirst(pCur);
	pCur->anQueue[iLevel]++;
	if( pFirst==0
	\|\| pFirst->rScore>rScore
	\|\| (pFirst->rScore==rScore && pFirst->iLevel>iLevel)
	){
	if( pCur->bPoint ){
	int ii;
	pNew = rtreeEnqueue(pCur, rScore, iLevel);
	if( pNew==0 ) return 0;
	ii = (int)(pNew - pCur->aPoint) + 1;
	assert( ii==1 );
	if( ALWAYS(ii<RTREE_CACHE_SZ) ){
	assert( pCur->aNode[ii]==0 );
	pCur->aNode[ii] = pCur->aNode[0];
	}else{
	nodeRelease(RTREE_OF_CURSOR(pCur), pCur->aNode[0]);
	}
	pCur->aNode[0] = 0;
	*pNew = pCur->sPoint;
	}
	pCur->sPoint.rScore = rScore;
	pCur->sPoint.iLevel = iLevel;
	pCur->bPoint = 1;
	return &pCur->sPoint;
	}else{
	return rtreeEnqueue(pCur, rScore, iLevel);
	}
	}

	#if 0
	/* Tracing routines for the RtreeSearchPoint queue */
	static void tracePoint(RtreeSearchPoint p, int idx, RtreeCursor pCur){
	if( idx<0 ){ printf(" s"); }else{ printf("%2d", idx); }
	printf(" %d.%05lld.%02d %g %d",
	p->iLevel, p->id, p->iCell, p->rScore, p->eWithin
	);
	idx++;
	if( idx<RTREE_CACHE_SZ ){
	printf(" %p\n", pCur->aNode[idx]);
	}else{
	printf("\n");
	}
	}
	static void traceQueue(RtreeCursor pCur, const char zPrefix){
	int ii;
	printf("=== %9s ", zPrefix);
	if( pCur->bPoint ){
	tracePoint(&pCur->sPoint, -1, pCur);
	}
	for(ii=0; ii<pCur->nPoint; ii++){
	if( ii>0 \|\| pCur->bPoint ) printf(" ");
	tracePoint(&pCur->aPoint[ii], ii, pCur);
	}
	}
	# define RTREE_QUEUE_TRACE(A,B) traceQueue(A,B)
	#else
	# define RTREE_QUEUE_TRACE(A,B) /* no-op */
	#endif

	/* Remove the search point with the lowest current score.
	*/
	static void rtreeSearchPointPop(RtreeCursor *p){
	int i, j, k, n;
	i = 1 - p->bPoint;
	assert( i==0 \|\| i==1 );
	if( p->aNode[i] ){
	nodeRelease(RTREE_OF_CURSOR(p), p->aNode[i]);
	p->aNode[i] = 0;
	}
	if( p->bPoint ){
	p->anQueue[p->sPoint.iLevel]--;
	p->bPoint = 0;
	}else if( ALWAYS(p->nPoint) ){
	p->anQueue[p->aPoint[0].iLevel]--;
	n = --p->nPoint;
	p->aPoint[0] = p->aPoint[n];
	if( n<RTREE_CACHE_SZ-1 ){
	p->aNode[1] = p->aNode[n+1];
	p->aNode[n+1] = 0;
	}
	i = 0;
	while( (j = i*2+1)<n ){
	k = j+1;
	if( k<n && rtreeSearchPointCompare(&p->aPoint[k], &p->aPoint[j])<0 ){
	if( rtreeSearchPointCompare(&p->aPoint[k], &p->aPoint[i])<0 ){
	rtreeSearchPointSwap(p, i, k);
	i = k;
	}else{
	break;
	}
	}else{
	if( rtreeSearchPointCompare(&p->aPoint[j], &p->aPoint[i])<0 ){
	rtreeSearchPointSwap(p, i, j);
	i = j;
	}else{
	break;
	}
	}
	}
	}
	}


	/*
	** Continue the search on cursor pCur until the front of the queue
	** contains an entry suitable for returning as a result-set row,
	** or until the RtreeSearchPoint queue is empty, indicating that the
	** query has completed.
	*/
	static int rtreeStepToLeaf(RtreeCursor *pCur){
	RtreeSearchPoint *p;
	Rtree *pRtree = RTREE_OF_CURSOR(pCur);
	RtreeNode *pNode;
	int eWithin;
	int rc = SQLITE_OK;
	int nCell;
	int nConstraint = pCur->nConstraint;
	int ii;
	int eInt;
	RtreeSearchPoint x;

	eInt = pRtree->eCoordType==RTREE_COORD_INT32;
	while( (p = rtreeSearchPointFirst(pCur))!=0 && p->iLevel>0 ){
	u8 *pCellData;
	pNode = rtreeNodeOfFirstSearchPoint(pCur, &rc);
	if( rc ) return rc;
	nCell = NCELL(pNode);
	assert( nCell<200 );
	pCellData = pNode->zData + (4+pRtree->nBytesPerCell*p->iCell);
	while( p->iCell<nCell ){
	sqlite3_rtree_dbl rScore = (sqlite3_rtree_dbl)-1;
	eWithin = FULLY_WITHIN;
	for(ii=0; ii<nConstraint; ii++){
	RtreeConstraint *pConstraint = pCur->aConstraint + ii;
	if( pConstraint->op>=RTREE_MATCH ){
	rc = rtreeCallbackConstraint(pConstraint, eInt, pCellData, p,
	&rScore, &eWithin);
	if( rc ) return rc;
	}else if( p->iLevel==1 ){
	rtreeLeafConstraint(pConstraint, eInt, pCellData, &eWithin);
	}else{
	rtreeNonleafConstraint(pConstraint, eInt, pCellData, &eWithin);
	}
	if( eWithin==NOT_WITHIN ){
	p->iCell++;
	pCellData += pRtree->nBytesPerCell;
	break;
	}
	}
	if( eWithin==NOT_WITHIN ) continue;
	p->iCell++;
	x.iLevel = p->iLevel - 1;
	if( x.iLevel ){
	x.id = readInt64(pCellData);
	for(ii=0; ii<pCur->nPoint; ii++){
	if( pCur->aPoint[ii].id==x.id ){
	RTREE_IS_CORRUPT(pRtree);
	return SQLITE_CORRUPT_VTAB;
	}
	}
	x.iCell = 0;
	}else{
	x.id = p->id;
	x.iCell = p->iCell - 1;
	}
	if( p->iCell>=nCell ){
	RTREE_QUEUE_TRACE(pCur, "POP-S:");
	rtreeSearchPointPop(pCur);
	}
	if( rScore<RTREE_ZERO ) rScore = RTREE_ZERO;
	p = rtreeSearchPointNew(pCur, rScore, x.iLevel);
	if( p==0 ) return SQLITE_NOMEM;
	p->eWithin = (u8)eWithin;
	p->id = x.id;
	p->iCell = x.iCell;
	RTREE_QUEUE_TRACE(pCur, "PUSH-S:");
	break;
	}
	if( p->iCell>=nCell ){
	RTREE_QUEUE_TRACE(pCur, "POP-Se:");
	rtreeSearchPointPop(pCur);
	}
	}
	pCur->atEOF = p==0;
	return SQLITE_OK;
	}

	/*
	** Rtree virtual table module xNext method.
	*/
	static int rtreeNext(sqlite3_vtab_cursor *pVtabCursor){
	RtreeCursor pCsr = (RtreeCursor )pVtabCursor;
	int rc = SQLITE_OK;

	/* Move to the next entry that matches the configured constraints. */
	RTREE_QUEUE_TRACE(pCsr, "POP-Nx:");
	if( pCsr->bAuxValid ){
	pCsr->bAuxValid = 0;
	sqlite3_reset(pCsr->pReadAux);
	}
	rtreeSearchPointPop(pCsr);
	rc = rtreeStepToLeaf(pCsr);
	return rc;
	}

	/*
	** Rtree virtual table module xRowid method.
	*/
	static int rtreeRowid(sqlite3_vtab_cursor pVtabCursor, sqlite_int64 pRowid){
	RtreeCursor pCsr = (RtreeCursor )pVtabCursor;
	RtreeSearchPoint *p = rtreeSearchPointFirst(pCsr);
	int rc = SQLITE_OK;
	RtreeNode *pNode = rtreeNodeOfFirstSearchPoint(pCsr, &rc);
	if( rc==SQLITE_OK && ALWAYS(p) ){
	if( p->iCell>=NCELL(pNode) ){
	rc = SQLITE_ABORT;
	}else{
	*pRowid = nodeGetRowid(RTREE_OF_CURSOR(pCsr), pNode, p->iCell);
	}
	}
	return rc;
	}

	/*
	** Rtree virtual table module xColumn method.
	*/
	static int rtreeColumn(sqlite3_vtab_cursor cur, sqlite3_context ctx, int i){
	Rtree pRtree = (Rtree )cur->pVtab;
	RtreeCursor pCsr = (RtreeCursor )cur;
	RtreeSearchPoint *p = rtreeSearchPointFirst(pCsr);
	RtreeCoord c;
	int rc = SQLITE_OK;
	RtreeNode *pNode = rtreeNodeOfFirstSearchPoint(pCsr, &rc);

	if( rc ) return rc;
	if( NEVER(p==0) ) return SQLITE_OK;
	if( p->iCell>=NCELL(pNode) ) return SQLITE_ABORT;
	if( i==0 ){
	sqlite3_result_int64(ctx, nodeGetRowid(pRtree, pNode, p->iCell));
	}else if( i<=pRtree->nDim2 ){
	nodeGetCoord(pRtree, pNode, p->iCell, i-1, &c);
	#ifndef SQLITE_RTREE_INT_ONLY
	if( pRtree->eCoordType==RTREE_COORD_REAL32 ){
	sqlite3_result_double(ctx, c.f);
	}else
	#endif
	{
	assert( pRtree->eCoordType==RTREE_COORD_INT32 );
	sqlite3_result_int(ctx, c.i);
	}
	}else{
	if( !pCsr->bAuxValid ){
	if( pCsr->pReadAux==0 ){
	rc = sqlite3_prepare_v3(pRtree->db, pRtree->zReadAuxSql, -1, 0,
	&pCsr->pReadAux, 0);
	if( rc ) return rc;
	}
	sqlite3_bind_int64(pCsr->pReadAux, 1,
	nodeGetRowid(pRtree, pNode, p->iCell));
	rc = sqlite3_step(pCsr->pReadAux);
	if( rc==SQLITE_ROW ){
	pCsr->bAuxValid = 1;
	}else{
	sqlite3_reset(pCsr->pReadAux);
	if( rc==SQLITE_DONE ) rc = SQLITE_OK;
	return rc;
	}
	}
	sqlite3_result_value(ctx,
	sqlite3_column_value(pCsr->pReadAux, i - pRtree->nDim2 + 1));
	}
	return SQLITE_OK;
	}

	/*
	** Use nodeAcquire() to obtain the leaf node containing the record with
	** rowid iRowid. If successful, set *ppLeaf to point to the node and
	** return SQLITE_OK. If there is no such record in the table, set
	** ppLeaf to 0 and return SQLITE_OK. If an error occurs, set ppLeaf
	** to zero and return an SQLite error code.
	*/
	static int findLeafNode(
	Rtree pRtree, / RTree to search */
	i64 iRowid, /* The rowid searching for */
	RtreeNode *ppLeaf, / Write the node here */
	sqlite3_int64 piNode / Write the node-id here */
	){
	int rc;
	*ppLeaf = 0;
	sqlite3_bind_int64(pRtree->pReadRowid, 1, iRowid);
	if( sqlite3_step(pRtree->pReadRowid)==SQLITE_ROW ){
	i64 iNode = sqlite3_column_int64(pRtree->pReadRowid, 0);
	if( piNode ) *piNode = iNode;
	rc = nodeAcquire(pRtree, iNode, 0, ppLeaf);
	sqlite3_reset(pRtree->pReadRowid);
	}else{
	rc = sqlite3_reset(pRtree->pReadRowid);
	}
	return rc;
	}

	/*
	** This function is called to configure the RtreeConstraint object passed
	** as the second argument for a MATCH constraint. The value passed as the
	** first argument to this function is the right-hand operand to the MATCH
	** operator.
	*/
	static int deserializeGeometry(sqlite3_value pValue, RtreeConstraint pCons){
	RtreeMatchArg pBlob, pSrc; /* BLOB returned by geometry function */
	sqlite3_rtree_query_info pInfo; / Callback information */

	pSrc = sqlite3_value_pointer(pValue, "RtreeMatchArg");
	if( pSrc==0 ) return SQLITE_ERROR;
	pInfo = (sqlite3_rtree_query_info*)
	sqlite3_malloc64( sizeof(*pInfo)+pSrc->iSize );
	if( !pInfo ) return SQLITE_NOMEM;
	memset(pInfo, 0, sizeof(*pInfo));
	pBlob = (RtreeMatchArg*)&pInfo[1];
	memcpy(pBlob, pSrc, pSrc->iSize);
	pInfo->pContext = pBlob->cb.pContext;
	pInfo->nParam = pBlob->nParam;
	pInfo->aParam = pBlob->aParam;
	pInfo->apSqlParam = pBlob->apSqlParam;

	if( pBlob->cb.xGeom ){
	pCons->u.xGeom = pBlob->cb.xGeom;
	}else{
	pCons->op = RTREE_QUERY;
	pCons->u.xQueryFunc = pBlob->cb.xQueryFunc;
	}
	pCons->pInfo = pInfo;
	return SQLITE_OK;
	}

	int sqlite3IntFloatCompare(i64,double);

	/*
	** Rtree virtual table module xFilter method.
	*/
	static int rtreeFilter(
	sqlite3_vtab_cursor *pVtabCursor,
	int idxNum, const char *idxStr,
	int argc, sqlite3_value **argv
	){
	Rtree pRtree = (Rtree )pVtabCursor->pVtab;
	RtreeCursor pCsr = (RtreeCursor )pVtabCursor;
	RtreeNode *pRoot = 0;
	int ii;
	int rc = SQLITE_OK;
	int iCell = 0;

	rtreeReference(pRtree);

	/* Reset the cursor to the same state as rtreeOpen() leaves it in. */
	resetCursor(pCsr);

	pCsr->iStrategy = idxNum;
	if( idxNum==1 ){
	/* Special case - lookup by rowid. */
	RtreeNode pLeaf; / Leaf on which the required cell resides */
	RtreeSearchPoint p; / Search point for the leaf */
	i64 iRowid = sqlite3_value_int64(argv[0]);
	i64 iNode = 0;
	int eType = sqlite3_value_numeric_type(argv[0]);
	if( eType==SQLITE_INTEGER
	\|\| (eType==SQLITE_FLOAT
	&& 0==sqlite3IntFloatCompare(iRowid,sqlite3_value_double(argv[0])))
	){
	rc = findLeafNode(pRtree, iRowid, &pLeaf, &iNode);
	}else{
	rc = SQLITE_OK;
	pLeaf = 0;
	}
	if( rc==SQLITE_OK && pLeaf!=0 ){
	p = rtreeSearchPointNew(pCsr, RTREE_ZERO, 0);
	assert( p!=0 ); /* Always returns pCsr->sPoint */
	pCsr->aNode[0] = pLeaf;
	p->id = iNode;
	p->eWithin = PARTLY_WITHIN;
	rc = nodeRowidIndex(pRtree, pLeaf, iRowid, &iCell);
	p->iCell = (u8)iCell;
	RTREE_QUEUE_TRACE(pCsr, "PUSH-F1:");
	}else{
	pCsr->atEOF = 1;
	}
	}else{
	/* Normal case - r-tree scan. Set up the RtreeCursor.aConstraint array
	** with the configured constraints.
	*/
	rc = nodeAcquire(pRtree, 1, 0, &pRoot);
	if( rc==SQLITE_OK && argc>0 ){
	pCsr->aConstraint = sqlite3_malloc64(sizeof(RtreeConstraint)*argc);
	pCsr->nConstraint = argc;
	if( !pCsr->aConstraint ){
	rc = SQLITE_NOMEM;
	}else{
	memset(pCsr->aConstraint, 0, sizeof(RtreeConstraint)*argc);
	memset(pCsr->anQueue, 0, sizeof(u32)*(pRtree->iDepth + 1));
	assert( (idxStr==0 && argc==0)
	\|\| (idxStr && (int)strlen(idxStr)==argc*2) );
	for(ii=0; ii<argc; ii++){
	RtreeConstraint *p = &pCsr->aConstraint[ii];
	int eType = sqlite3_value_numeric_type(argv[ii]);
	p->op = idxStr[ii*2];
	p->iCoord = idxStr[ii*2+1]-'0';
	if( p->op>=RTREE_MATCH ){
	/* A MATCH operator. The right-hand-side must be a blob that
	** can be cast into an RtreeMatchArg object. One created using
	** an sqlite3_rtree_geometry_callback() SQL user function.
	*/
	rc = deserializeGeometry(argv[ii], p);
	if( rc!=SQLITE_OK ){
	break;
	}
	p->pInfo->nCoord = pRtree->nDim2;
	p->pInfo->anQueue = pCsr->anQueue;
	p->pInfo->mxLevel = pRtree->iDepth + 1;
	}else if( eType==SQLITE_INTEGER ){
	sqlite3_int64 iVal = sqlite3_value_int64(argv[ii]);
	#ifdef SQLITE_RTREE_INT_ONLY
	p->u.rValue = iVal;
	#else
	p->u.rValue = (double)iVal;
	if( iVal>=((sqlite3_int64)1)<<48
	\|\| iVal<=-(((sqlite3_int64)1)<<48)
	){
	if( p->op==RTREE_LT ) p->op = RTREE_LE;
	if( p->op==RTREE_GT ) p->op = RTREE_GE;
	}
	#endif
	}else if( eType==SQLITE_FLOAT ){
	#ifdef SQLITE_RTREE_INT_ONLY
	p->u.rValue = sqlite3_value_int64(argv[ii]);
	#else
	p->u.rValue = sqlite3_value_double(argv[ii]);
	#endif
	}else{
	p->u.rValue = RTREE_ZERO;
	if( eType==SQLITE_NULL ){
	p->op = RTREE_FALSE;
	}else if( p->op==RTREE_LT \|\| p->op==RTREE_LE ){
	p->op = RTREE_TRUE;
	}else{
	p->op = RTREE_FALSE;
	}
	}
	}
	}
	}
	if( rc==SQLITE_OK ){
	RtreeSearchPoint *pNew;
	assert( pCsr->bPoint==0 ); /* Due to the resetCursor() call above */
	pNew = rtreeSearchPointNew(pCsr, RTREE_ZERO, (u8)(pRtree->iDepth+1));
	if( NEVER(pNew==0) ){ /* Because pCsr->bPoint was FALSE */
	return SQLITE_NOMEM;
	}
	pNew->id = 1;
	pNew->iCell = 0;
	pNew->eWithin = PARTLY_WITHIN;
	assert( pCsr->bPoint==1 );
	pCsr->aNode[0] = pRoot;
	pRoot = 0;
	RTREE_QUEUE_TRACE(pCsr, "PUSH-Fm:");
	rc = rtreeStepToLeaf(pCsr);
	}
	}

	nodeRelease(pRtree, pRoot);
	rtreeRelease(pRtree);
	return rc;
	}

	/*
	** Rtree virtual table module xBestIndex method. There are three
	** table scan strategies to choose from (in order from most to
	** least desirable):
	**
	** idxNum idxStr Strategy
	** ------------------------------------------------
	** 1 Unused Direct lookup by rowid.
	** 2 See below R-tree query or full-table scan.
	** ------------------------------------------------
	**
	** If strategy 1 is used, then idxStr is not meaningful. If strategy
	** 2 is used, idxStr is formatted to contain 2 bytes for each
	** constraint used. The first two bytes of idxStr correspond to
	** the constraint in sqlite3_index_info.aConstraintUsage[] with
	** (argvIndex==1) etc.
	**
	** The first of each pair of bytes in idxStr identifies the constraint
	** operator as follows:
	**
	** Operator Byte Value
	** ----------------------
	** = 0x41 ('A')
	** <= 0x42 ('B')
	** < 0x43 ('C')
	** >= 0x44 ('D')
	** > 0x45 ('E')
	** MATCH 0x46 ('F')
	** ----------------------
	**
	** The second of each pair of bytes identifies the coordinate column
	** to which the constraint applies. The leftmost coordinate column
	** is 'a', the second from the left 'b' etc.
	*/
	static int rtreeBestIndex(sqlite3_vtab tab, sqlite3_index_info pIdxInfo){
	Rtree pRtree = (Rtree)tab;
	int rc = SQLITE_OK;
	int ii;
	int bMatch = 0; /* True if there exists a MATCH constraint */
	i64 nRow; /* Estimated rows returned by this scan */

	int iIdx = 0;
	char zIdxStr[RTREE_MAX_DIMENSIONS*8+1];
	memset(zIdxStr, 0, sizeof(zIdxStr));

	/* Check if there exists a MATCH constraint - even an unusable one. If there
	** is, do not consider the lookup-by-rowid plan as using such a plan would
	** require the VDBE to evaluate the MATCH constraint, which is not currently
	** possible. */
	for(ii=0; ii<pIdxInfo->nConstraint; ii++){
	if( pIdxInfo->aConstraint[ii].op==SQLITE_INDEX_CONSTRAINT_MATCH ){
	bMatch = 1;
	}
	}

	assert( pIdxInfo->idxStr==0 );
	for(ii=0; ii<pIdxInfo->nConstraint && iIdx<(int)(sizeof(zIdxStr)-1); ii++){
	struct sqlite3_index_constraint *p = &pIdxInfo->aConstraint[ii];

	if( bMatch==0 && p->usable
	&& p->iColumn<=0 && p->op==SQLITE_INDEX_CONSTRAINT_EQ
	){
	/* We have an equality constraint on the rowid. Use strategy 1. */
	int jj;
	for(jj=0; jj<ii; jj++){
	pIdxInfo->aConstraintUsage[jj].argvIndex = 0;
	pIdxInfo->aConstraintUsage[jj].omit = 0;
	}
	pIdxInfo->idxNum = 1;
	pIdxInfo->aConstraintUsage[ii].argvIndex = 1;
	pIdxInfo->aConstraintUsage[jj].omit = 1;

	/* This strategy involves a two rowid lookups on an B-Tree structures
	** and then a linear search of an R-Tree node. This should be
	** considered almost as quick as a direct rowid lookup (for which
	** sqlite uses an internal cost of 0.0). It is expected to return
	** a single row.
	*/
	pIdxInfo->estimatedCost = 30.0;
	pIdxInfo->estimatedRows = 1;
	pIdxInfo->idxFlags = SQLITE_INDEX_SCAN_UNIQUE;
	return SQLITE_OK;
	}

	if( p->usable
	&& ((p->iColumn>0 && p->iColumn<=pRtree->nDim2)
	\|\| p->op==SQLITE_INDEX_CONSTRAINT_MATCH)
	){
	u8 op;
	u8 doOmit = 1;
	switch( p->op ){
	case SQLITE_INDEX_CONSTRAINT_EQ: op = RTREE_EQ; doOmit = 0; break;
	case SQLITE_INDEX_CONSTRAINT_GT: op = RTREE_GT; doOmit = 0; break;
	case SQLITE_INDEX_CONSTRAINT_LE: op = RTREE_LE; break;
	case SQLITE_INDEX_CONSTRAINT_LT: op = RTREE_LT; doOmit = 0; break;
	case SQLITE_INDEX_CONSTRAINT_GE: op = RTREE_GE; break;
	case SQLITE_INDEX_CONSTRAINT_MATCH: op = RTREE_MATCH; break;
	default: op = 0; break;
	}
	if( op ){
	zIdxStr[iIdx++] = op;
	zIdxStr[iIdx++] = (char)(p->iColumn - 1 + '0');
	pIdxInfo->aConstraintUsage[ii].argvIndex = (iIdx/2);
	pIdxInfo->aConstraintUsage[ii].omit = doOmit;
	}
	}
	}

	pIdxInfo->idxNum = 2;
	pIdxInfo->needToFreeIdxStr = 1;
	if( iIdx>0 ){
	pIdxInfo->idxStr = sqlite3_malloc( iIdx+1 );
	if( pIdxInfo->idxStr==0 ){
	return SQLITE_NOMEM;
	}
	memcpy(pIdxInfo->idxStr, zIdxStr, iIdx+1);
	}

	nRow = pRtree->nRowEst >> (iIdx/2);
	pIdxInfo->estimatedCost = (double)6.0 * (double)nRow;
	pIdxInfo->estimatedRows = nRow;

	return rc;
	}

	/*
	** Return the N-dimensional volumn of the cell stored in *p.
	*/
	static RtreeDValue cellArea(Rtree pRtree, RtreeCell p){
	RtreeDValue area = (RtreeDValue)1;
	assert( pRtree->nDim>=1 && pRtree->nDim<=5 );
	#ifndef SQLITE_RTREE_INT_ONLY
	if( pRtree->eCoordType==RTREE_COORD_REAL32 ){
	switch( pRtree->nDim ){
	case 5: area = p->aCoord[9].f - p->aCoord[8].f;
	case 4: area *= p->aCoord[7].f - p->aCoord[6].f;
	case 3: area *= p->aCoord[5].f - p->aCoord[4].f;
	case 2: area *= p->aCoord[3].f - p->aCoord[2].f;
	default: area *= p->aCoord[1].f - p->aCoord[0].f;
	}
	}else
	#endif
	{
	switch( pRtree->nDim ){
	case 5: area = (i64)p->aCoord[9].i - (i64)p->aCoord[8].i;
	case 4: area *= (i64)p->aCoord[7].i - (i64)p->aCoord[6].i;
	case 3: area *= (i64)p->aCoord[5].i - (i64)p->aCoord[4].i;
	case 2: area *= (i64)p->aCoord[3].i - (i64)p->aCoord[2].i;
	default: area *= (i64)p->aCoord[1].i - (i64)p->aCoord[0].i;
	}
	}
	return area;
	}

	/*
	** Return the margin length of cell p. The margin length is the sum
	** of the objects size in each dimension.
	*/
	static RtreeDValue cellMargin(Rtree pRtree, RtreeCell p){
	RtreeDValue margin = 0;
	int ii = pRtree->nDim2 - 2;
	do{
	margin += (DCOORD(p->aCoord[ii+1]) - DCOORD(p->aCoord[ii]));
	ii -= 2;
	}while( ii>=0 );
	return margin;
	}

	/*
	** Store the union of cells p1 and p2 in p1.
	*/
	static void cellUnion(Rtree pRtree, RtreeCell p1, RtreeCell *p2){
	int ii = 0;
	if( pRtree->eCoordType==RTREE_COORD_REAL32 ){
	do{
	p1->aCoord[ii].f = MIN(p1->aCoord[ii].f, p2->aCoord[ii].f);
	p1->aCoord[ii+1].f = MAX(p1->aCoord[ii+1].f, p2->aCoord[ii+1].f);
	ii += 2;
	}while( ii<pRtree->nDim2 );
	}else{
	do{
	p1->aCoord[ii].i = MIN(p1->aCoord[ii].i, p2->aCoord[ii].i);
	p1->aCoord[ii+1].i = MAX(p1->aCoord[ii+1].i, p2->aCoord[ii+1].i);
	ii += 2;
	}while( ii<pRtree->nDim2 );
	}
	}

	/*
	** Return true if the area covered by p2 is a subset of the area covered
	** by p1. False otherwise.
	*/
	static int cellContains(Rtree pRtree, RtreeCell p1, RtreeCell *p2){
	int ii;
	if( pRtree->eCoordType==RTREE_COORD_INT32 ){
	for(ii=0; ii<pRtree->nDim2; ii+=2){
	RtreeCoord *a1 = &p1->aCoord[ii];
	RtreeCoord *a2 = &p2->aCoord[ii];
	if( a2[0].i<a1[0].i \|\| a2[1].i>a1[1].i ) return 0;
	}
	}else{
	for(ii=0; ii<pRtree->nDim2; ii+=2){
	RtreeCoord *a1 = &p1->aCoord[ii];
	RtreeCoord *a2 = &p2->aCoord[ii];
	if( a2[0].f<a1[0].f \|\| a2[1].f>a1[1].f ) return 0;
	}
	}
	return 1;
	}

	static RtreeDValue cellOverlap(
	Rtree *pRtree,
	RtreeCell *p,
	RtreeCell *aCell,
	int nCell
	){
	int ii;
	RtreeDValue overlap = RTREE_ZERO;
	for(ii=0; ii<nCell; ii++){
	int jj;
	RtreeDValue o = (RtreeDValue)1;
	for(jj=0; jj<pRtree->nDim2; jj+=2){
	RtreeDValue x1, x2;
	x1 = MAX(DCOORD(p->aCoord[jj]), DCOORD(aCell[ii].aCoord[jj]));
	x2 = MIN(DCOORD(p->aCoord[jj+1]), DCOORD(aCell[ii].aCoord[jj+1]));
	if( x2<x1 ){
	o = (RtreeDValue)0;
	break;
	}else{
	o = o * (x2-x1);
	}
	}
	overlap += o;
	}
	return overlap;
	}


	/*
	** This function implements the ChooseLeaf algorithm from Gutman[84].
	** ChooseSubTree in r*tree terminology.
	*/
	static int ChooseLeaf(
	Rtree pRtree, / Rtree table */
	RtreeCell pCell, / Cell to insert into rtree */
	int iHeight, /* Height of sub-tree rooted at pCell */
	RtreeNode *ppLeaf / OUT: Selected leaf page */
	){
	int rc;
	int ii;
	RtreeNode *pNode = 0;
	rc = nodeAcquire(pRtree, 1, 0, &pNode);

	for(ii=0; rc==SQLITE_OK && ii<(pRtree->iDepth-iHeight); ii++){
	int iCell;
	sqlite3_int64 iBest = 0;
	int bFound = 0;
	RtreeDValue fMinGrowth = RTREE_ZERO;
	RtreeDValue fMinArea = RTREE_ZERO;
	int nCell = NCELL(pNode);
	RtreeNode *pChild = 0;

	/* First check to see if there is are any cells in pNode that completely
	** contains pCell. If two or more cells in pNode completely contain pCell
	** then pick the smallest.
	*/
	for(iCell=0; iCell<nCell; iCell++){
	RtreeCell cell;
	nodeGetCell(pRtree, pNode, iCell, &cell);
	if( cellContains(pRtree, &cell, pCell) ){
	RtreeDValue area = cellArea(pRtree, &cell);
	if( bFound==0 \|\| area<fMinArea ){
	iBest = cell.iRowid;
	fMinArea = area;
	bFound = 1;
	}
	}
	}
	if( !bFound ){
	/* No cells of pNode will completely contain pCell. So pick the
	** cell of pNode that grows by the least amount when pCell is added.
	** Break ties by selecting the smaller cell.
	*/
	for(iCell=0; iCell<nCell; iCell++){
	RtreeCell cell;
	RtreeDValue growth;
	RtreeDValue area;
	nodeGetCell(pRtree, pNode, iCell, &cell);
	area = cellArea(pRtree, &cell);
	cellUnion(pRtree, &cell, pCell);
	growth = cellArea(pRtree, &cell)-area;
	if( iCell==0
	\|\| growth<fMinGrowth
	\|\| (growth==fMinGrowth && area<fMinArea)
	){
	fMinGrowth = growth;
	fMinArea = area;
	iBest = cell.iRowid;
	}
	}
	}

	rc = nodeAcquire(pRtree, iBest, pNode, &pChild);
	nodeRelease(pRtree, pNode);
	pNode = pChild;
	}

	*ppLeaf = pNode;
	return rc;
	}

	/*
	** A cell with the same content as pCell has just been inserted into
	** the node pNode. This function updates the bounding box cells in
	** all ancestor elements.
	*/
	static int AdjustTree(
	Rtree pRtree, / Rtree table */
	RtreeNode pNode, / Adjust ancestry of this node. */
	RtreeCell pCell / This cell was just inserted */
	){
	RtreeNode *p = pNode;
	int cnt = 0;
	int rc;
	while( p->pParent ){
	RtreeNode *pParent = p->pParent;
	RtreeCell cell;
	int iCell;

	cnt++;
	if( NEVER(cnt>100) ){
	RTREE_IS_CORRUPT(pRtree);
	return SQLITE_CORRUPT_VTAB;
	}
	rc = nodeParentIndex(pRtree, p, &iCell);
	if( NEVER(rc!=SQLITE_OK) ){
	RTREE_IS_CORRUPT(pRtree);
	return SQLITE_CORRUPT_VTAB;
	}

	nodeGetCell(pRtree, pParent, iCell, &cell);
	if( !cellContains(pRtree, &cell, pCell) ){
	cellUnion(pRtree, &cell, pCell);
	nodeOverwriteCell(pRtree, pParent, &cell, iCell);
	}

	p = pParent;
	}
	return SQLITE_OK;
	}

	/*
	** Write mapping (iRowid->iNode) to the <rtree>_rowid table.
	*/
	static int rowidWrite(Rtree *pRtree, sqlite3_int64 iRowid, sqlite3_int64 iNode){
	sqlite3_bind_int64(pRtree->pWriteRowid, 1, iRowid);
	sqlite3_bind_int64(pRtree->pWriteRowid, 2, iNode);
	sqlite3_step(pRtree->pWriteRowid);
	return sqlite3_reset(pRtree->pWriteRowid);
	}

	/*
	** Write mapping (iNode->iPar) to the <rtree>_parent table.
	*/
	static int parentWrite(Rtree *pRtree, sqlite3_int64 iNode, sqlite3_int64 iPar){
	sqlite3_bind_int64(pRtree->pWriteParent, 1, iNode);
	sqlite3_bind_int64(pRtree->pWriteParent, 2, iPar);
	sqlite3_step(pRtree->pWriteParent);
	return sqlite3_reset(pRtree->pWriteParent);
	}

	static int rtreeInsertCell(Rtree , RtreeNode , RtreeCell *, int);



	/*
	** Arguments aIdx, aCell and aSpare all point to arrays of size
	** nIdx. The aIdx array contains the set of integers from 0 to
	** (nIdx-1) in no particular order. This function sorts the values
	** in aIdx according to dimension iDim of the cells in aCell. The
	** minimum value of dimension iDim is considered first, the
	** maximum used to break ties.
	**
	** The aSpare array is used as temporary working space by the
	** sorting algorithm.
	*/
	static void SortByDimension(
	Rtree *pRtree,
	int *aIdx,
	int nIdx,
	int iDim,
	RtreeCell *aCell,
	int *aSpare
	){
	if( nIdx>1 ){

	int iLeft = 0;
	int iRight = 0;

	int nLeft = nIdx/2;
	int nRight = nIdx-nLeft;
	int *aLeft = aIdx;
	int *aRight = &aIdx[nLeft];

	SortByDimension(pRtree, aLeft, nLeft, iDim, aCell, aSpare);
	SortByDimension(pRtree, aRight, nRight, iDim, aCell, aSpare);

	memcpy(aSpare, aLeft, sizeof(int)*nLeft);
	aLeft = aSpare;
	while( iLeft<nLeft \|\| iRight<nRight ){
	RtreeDValue xleft1 = DCOORD(aCell[aLeft[iLeft]].aCoord[iDim*2]);
	RtreeDValue xleft2 = DCOORD(aCell[aLeft[iLeft]].aCoord[iDim*2+1]);
	RtreeDValue xright1 = DCOORD(aCell[aRight[iRight]].aCoord[iDim*2]);
	RtreeDValue xright2 = DCOORD(aCell[aRight[iRight]].aCoord[iDim*2+1]);
	if( (iLeft!=nLeft) && ((iRight==nRight)
	\|\| (xleft1<xright1)
	\|\| (xleft1==xright1 && xleft2<xright2)
	)){
	aIdx[iLeft+iRight] = aLeft[iLeft];
	iLeft++;
	}else{
	aIdx[iLeft+iRight] = aRight[iRight];
	iRight++;
	}
	}

	#if 0
	/* Check that the sort worked */
	{
	int jj;
	for(jj=1; jj<nIdx; jj++){
	RtreeDValue xleft1 = aCell[aIdx[jj-1]].aCoord[iDim*2];
	RtreeDValue xleft2 = aCell[aIdx[jj-1]].aCoord[iDim*2+1];
	RtreeDValue xright1 = aCell[aIdx[jj]].aCoord[iDim*2];
	RtreeDValue xright2 = aCell[aIdx[jj]].aCoord[iDim*2+1];
	assert( xleft1<=xright1 && (xleft1<xright1 \|\| xleft2<=xright2) );
	}
	}
	#endif
	}
	}

	/*
	** Implementation of the R*-tree variant of SplitNode from Beckman[1990].
	*/
	static int splitNodeStartree(
	Rtree *pRtree,
	RtreeCell *aCell,
	int nCell,
	RtreeNode *pLeft,
	RtreeNode *pRight,
	RtreeCell *pBboxLeft,
	RtreeCell *pBboxRight
	){
	int **aaSorted;
	int *aSpare;
	int ii;

	int iBestDim = 0;
	int iBestSplit = 0;
	RtreeDValue fBestMargin = RTREE_ZERO;

	sqlite3_int64 nByte = (pRtree->nDim+1)(sizeof(int)+nCell*sizeof(int));

	aaSorted = (int **)sqlite3_malloc64(nByte);
	if( !aaSorted ){
	return SQLITE_NOMEM;
	}

	aSpare = &((int )&aaSorted[pRtree->nDim])[pRtree->nDimnCell];
	memset(aaSorted, 0, nByte);
	for(ii=0; ii<pRtree->nDim; ii++){
	int jj;
	aaSorted[ii] = &((int )&aaSorted[pRtree->nDim])[iinCell];
	for(jj=0; jj<nCell; jj++){
	aaSorted[ii][jj] = jj;
	}
	SortByDimension(pRtree, aaSorted[ii], nCell, ii, aCell, aSpare);
	}

	for(ii=0; ii<pRtree->nDim; ii++){
	RtreeDValue margin = RTREE_ZERO;
	RtreeDValue fBestOverlap = RTREE_ZERO;
	RtreeDValue fBestArea = RTREE_ZERO;
	int iBestLeft = 0;
	int nLeft;

	for(
	nLeft=RTREE_MINCELLS(pRtree);
	nLeft<=(nCell-RTREE_MINCELLS(pRtree));
	nLeft++
	){
	RtreeCell left;
	RtreeCell right;
	int kk;
	RtreeDValue overlap;
	RtreeDValue area;

	memcpy(&left, &aCell[aaSorted[ii][0]], sizeof(RtreeCell));
	memcpy(&right, &aCell[aaSorted[ii][nCell-1]], sizeof(RtreeCell));
	for(kk=1; kk<(nCell-1); kk++){
	if( kk<nLeft ){
	cellUnion(pRtree, &left, &aCell[aaSorted[ii][kk]]);
	}else{
	cellUnion(pRtree, &right, &aCell[aaSorted[ii][kk]]);
	}
	}
	margin += cellMargin(pRtree, &left);
	margin += cellMargin(pRtree, &right);
	overlap = cellOverlap(pRtree, &left, &right, 1);
	area = cellArea(pRtree, &left) + cellArea(pRtree, &right);
	if( (nLeft==RTREE_MINCELLS(pRtree))
	\|\| (overlap<fBestOverlap)
	\|\| (overlap==fBestOverlap && area<fBestArea)
	){
	iBestLeft = nLeft;
	fBestOverlap = overlap;
	fBestArea = area;
	}
	}

	if( ii==0 \|\| margin<fBestMargin ){
	iBestDim = ii;
	fBestMargin = margin;
	iBestSplit = iBestLeft;
	}
	}

	memcpy(pBboxLeft, &aCell[aaSorted[iBestDim][0]], sizeof(RtreeCell));
	memcpy(pBboxRight, &aCell[aaSorted[iBestDim][iBestSplit]], sizeof(RtreeCell));
	for(ii=0; ii<nCell; ii++){
	RtreeNode *pTarget = (ii<iBestSplit)?pLeft:pRight;
	RtreeCell *pBbox = (ii<iBestSplit)?pBboxLeft:pBboxRight;
	RtreeCell *pCell = &aCell[aaSorted[iBestDim][ii]];
	nodeInsertCell(pRtree, pTarget, pCell);
	cellUnion(pRtree, pBbox, pCell);
	}

	sqlite3_free(aaSorted);
	return SQLITE_OK;
	}


	static int updateMapping(
	Rtree *pRtree,
	i64 iRowid,
	RtreeNode *pNode,
	int iHeight
	){
	int (xSetMapping)(Rtree , sqlite3_int64, sqlite3_int64);
	xSetMapping = ((iHeight==0)?rowidWrite:parentWrite);
	if( iHeight>0 ){
	RtreeNode *pChild = nodeHashLookup(pRtree, iRowid);
	RtreeNode *p;
	for(p=pNode; p; p=p->pParent){
	if( p==pChild ) return SQLITE_CORRUPT_VTAB;
	}
	if( pChild ){
	nodeRelease(pRtree, pChild->pParent);
	nodeReference(pNode);
	pChild->pParent = pNode;
	}
	}
	if( NEVER(pNode==0) ) return SQLITE_ERROR;
	return xSetMapping(pRtree, iRowid, pNode->iNode);
	}

	static int SplitNode(
	Rtree *pRtree,
	RtreeNode *pNode,
	RtreeCell *pCell,
	int iHeight
	){
	int i;
	int newCellIsRight = 0;

	int rc = SQLITE_OK;
	int nCell = NCELL(pNode);
	RtreeCell *aCell;
	int *aiUsed;

	RtreeNode *pLeft = 0;
	RtreeNode *pRight = 0;

	RtreeCell leftbbox;
	RtreeCell rightbbox;

	/* Allocate an array and populate it with a copy of pCell and
	** all cells from node pLeft. Then zero the original node.
	*/
	aCell = sqlite3_malloc64((sizeof(RtreeCell)+sizeof(int))*(nCell+1));
	if( !aCell ){
	rc = SQLITE_NOMEM;
	goto splitnode_out;
	}
	aiUsed = (int *)&aCell[nCell+1];
	memset(aiUsed, 0, sizeof(int)*(nCell+1));
	for(i=0; i<nCell; i++){
	nodeGetCell(pRtree, pNode, i, &aCell[i]);
	}
	nodeZero(pRtree, pNode);
	memcpy(&aCell[nCell], pCell, sizeof(RtreeCell));
	nCell++;

	if( pNode->iNode==1 ){
	pRight = nodeNew(pRtree, pNode);
	pLeft = nodeNew(pRtree, pNode);
	pRtree->iDepth++;
	pNode->isDirty = 1;
	writeInt16(pNode->zData, pRtree->iDepth);
	}else{
	pLeft = pNode;
	pRight = nodeNew(pRtree, pLeft->pParent);
	pLeft->nRef++;
	}

	if( !pLeft \|\| !pRight ){
	rc = SQLITE_NOMEM;
	goto splitnode_out;
	}

	memset(pLeft->zData, 0, pRtree->iNodeSize);
	memset(pRight->zData, 0, pRtree->iNodeSize);

	rc = splitNodeStartree(pRtree, aCell, nCell, pLeft, pRight,
	&leftbbox, &rightbbox);
	if( rc!=SQLITE_OK ){
	goto splitnode_out;
	}

	/* Ensure both child nodes have node numbers assigned to them by calling
	** nodeWrite(). Node pRight always needs a node number, as it was created
	** by nodeNew() above. But node pLeft sometimes already has a node number.
	** In this case avoid the all to nodeWrite().
	*/
	if( SQLITE_OK!=(rc = nodeWrite(pRtree, pRight))
	\|\| (0==pLeft->iNode && SQLITE_OK!=(rc = nodeWrite(pRtree, pLeft)))
	){
	goto splitnode_out;
	}

	rightbbox.iRowid = pRight->iNode;
	leftbbox.iRowid = pLeft->iNode;

	if( pNode->iNode==1 ){
	rc = rtreeInsertCell(pRtree, pLeft->pParent, &leftbbox, iHeight+1);
	if( rc!=SQLITE_OK ){
	goto splitnode_out;
	}
	}else{
	RtreeNode *pParent = pLeft->pParent;
	int iCell;
	rc = nodeParentIndex(pRtree, pLeft, &iCell);
	if( ALWAYS(rc==SQLITE_OK) ){
	nodeOverwriteCell(pRtree, pParent, &leftbbox, iCell);
	rc = AdjustTree(pRtree, pParent, &leftbbox);
	assert( rc==SQLITE_OK );
	}
	if( NEVER(rc!=SQLITE_OK) ){
	goto splitnode_out;
	}
	}
	if( (rc = rtreeInsertCell(pRtree, pRight->pParent, &rightbbox, iHeight+1)) ){
	goto splitnode_out;
	}

	for(i=0; i<NCELL(pRight); i++){
	i64 iRowid = nodeGetRowid(pRtree, pRight, i);
	rc = updateMapping(pRtree, iRowid, pRight, iHeight);
	if( iRowid==pCell->iRowid ){
	newCellIsRight = 1;
	}
	if( rc!=SQLITE_OK ){
	goto splitnode_out;
	}
	}
	if( pNode->iNode==1 ){
	for(i=0; i<NCELL(pLeft); i++){
	i64 iRowid = nodeGetRowid(pRtree, pLeft, i);
	rc = updateMapping(pRtree, iRowid, pLeft, iHeight);
	if( rc!=SQLITE_OK ){
	goto splitnode_out;
	}
	}
	}else if( newCellIsRight==0 ){
	rc = updateMapping(pRtree, pCell->iRowid, pLeft, iHeight);
	}

	if( rc==SQLITE_OK ){
	rc = nodeRelease(pRtree, pRight);
	pRight = 0;
	}
	if( rc==SQLITE_OK ){
	rc = nodeRelease(pRtree, pLeft);
	pLeft = 0;
	}

	splitnode_out:
	nodeRelease(pRtree, pRight);
	nodeRelease(pRtree, pLeft);
	sqlite3_free(aCell);
	return rc;
	}

	/*
	** If node pLeaf is not the root of the r-tree and its pParent pointer is
	** still NULL, load all ancestor nodes of pLeaf into memory and populate
	** the pLeaf->pParent chain all the way up to the root node.
	**
	** This operation is required when a row is deleted (or updated - an update
	** is implemented as a delete followed by an insert). SQLite provides the
	** rowid of the row to delete, which can be used to find the leaf on which
	** the entry resides (argument pLeaf). Once the leaf is located, this
	** function is called to determine its ancestry.
	*/
	static int fixLeafParent(Rtree pRtree, RtreeNode pLeaf){
	int rc = SQLITE_OK;
	RtreeNode *pChild = pLeaf;
	while( rc==SQLITE_OK && pChild->iNode!=1 && pChild->pParent==0 ){
	int rc2 = SQLITE_OK; /* sqlite3_reset() return code */
	sqlite3_bind_int64(pRtree->pReadParent, 1, pChild->iNode);
	rc = sqlite3_step(pRtree->pReadParent);
	if( rc==SQLITE_ROW ){
	RtreeNode pTest; / Used to test for reference loops */
	i64 iNode; /* Node number of parent node */

	/* Before setting pChild->pParent, test that we are not creating a
	** loop of references (as we would if, say, pChild==pParent). We don't
	** want to do this as it leads to a memory leak when trying to delete
	** the referenced counted node structures.
	*/
	iNode = sqlite3_column_int64(pRtree->pReadParent, 0);
	for(pTest=pLeaf; pTest && pTest->iNode!=iNode; pTest=pTest->pParent);
	if( pTest==0 ){
	rc2 = nodeAcquire(pRtree, iNode, 0, &pChild->pParent);
	}
	}
	rc = sqlite3_reset(pRtree->pReadParent);
	if( rc==SQLITE_OK ) rc = rc2;
	if( rc==SQLITE_OK && !pChild->pParent ){
	RTREE_IS_CORRUPT(pRtree);
	rc = SQLITE_CORRUPT_VTAB;
	}
	pChild = pChild->pParent;
	}
	return rc;
	}

	static int deleteCell(Rtree , RtreeNode , int, int);

	static int removeNode(Rtree pRtree, RtreeNode pNode, int iHeight){
	int rc;
	int rc2;
	RtreeNode *pParent = 0;
	int iCell;

	assert( pNode->nRef==1 );

	/* Remove the entry in the parent cell. */
	rc = nodeParentIndex(pRtree, pNode, &iCell);
	if( rc==SQLITE_OK ){
	pParent = pNode->pParent;
	pNode->pParent = 0;
	rc = deleteCell(pRtree, pParent, iCell, iHeight+1);
	testcase( rc!=SQLITE_OK );
	}
	rc2 = nodeRelease(pRtree, pParent);
	if( rc==SQLITE_OK ){
	rc = rc2;
	}
	if( rc!=SQLITE_OK ){
	return rc;
	}

	/* Remove the xxx_node entry. */
	sqlite3_bind_int64(pRtree->pDeleteNode, 1, pNode->iNode);
	sqlite3_step(pRtree->pDeleteNode);
	if( SQLITE_OK!=(rc = sqlite3_reset(pRtree->pDeleteNode)) ){
	return rc;
	}

	/* Remove the xxx_parent entry. */
	sqlite3_bind_int64(pRtree->pDeleteParent, 1, pNode->iNode);
	sqlite3_step(pRtree->pDeleteParent);
	if( SQLITE_OK!=(rc = sqlite3_reset(pRtree->pDeleteParent)) ){
	return rc;
	}

	/* Remove the node from the in-memory hash table and link it into
	** the Rtree.pDeleted list. Its contents will be re-inserted later on.
	*/
	nodeHashDelete(pRtree, pNode);
	pNode->iNode = iHeight;
	pNode->pNext = pRtree->pDeleted;
	pNode->nRef++;
	pRtree->pDeleted = pNode;

	return SQLITE_OK;
	}

	static int fixBoundingBox(Rtree pRtree, RtreeNode pNode){
	RtreeNode *pParent = pNode->pParent;
	int rc = SQLITE_OK;
	if( pParent ){
	int ii;
	int nCell = NCELL(pNode);
	RtreeCell box; /* Bounding box for pNode */
	nodeGetCell(pRtree, pNode, 0, &box);
	for(ii=1; ii<nCell; ii++){
	RtreeCell cell;
	nodeGetCell(pRtree, pNode, ii, &cell);
	cellUnion(pRtree, &box, &cell);
	}
	box.iRowid = pNode->iNode;
	rc = nodeParentIndex(pRtree, pNode, &ii);
	if( rc==SQLITE_OK ){
	nodeOverwriteCell(pRtree, pParent, &box, ii);
	rc = fixBoundingBox(pRtree, pParent);
	}
	}
	return rc;
	}

	/*
	** Delete the cell at index iCell of node pNode. After removing the
	** cell, adjust the r-tree data structure if required.
	*/
	static int deleteCell(Rtree pRtree, RtreeNode pNode, int iCell, int iHeight){
	RtreeNode *pParent;
	int rc;

	if( SQLITE_OK!=(rc = fixLeafParent(pRtree, pNode)) ){
	return rc;
	}

	/* Remove the cell from the node. This call just moves bytes around
	** the in-memory node image, so it cannot fail.
	*/
	nodeDeleteCell(pRtree, pNode, iCell);

	/* If the node is not the tree root and now has less than the minimum
	** number of cells, remove it from the tree. Otherwise, update the
	** cell in the parent node so that it tightly contains the updated
	** node.
	*/
	pParent = pNode->pParent;
	assert( pParent \|\| pNode->iNode==1 );
	if( pParent ){
	if( NCELL(pNode)<RTREE_MINCELLS(pRtree) ){
	rc = removeNode(pRtree, pNode, iHeight);
	}else{
	rc = fixBoundingBox(pRtree, pNode);
	}
	}

	return rc;
	}

	/*
	** Insert cell pCell into node pNode. Node pNode is the head of a
	** subtree iHeight high (leaf nodes have iHeight==0).
	*/
	static int rtreeInsertCell(
	Rtree *pRtree,
	RtreeNode *pNode,
	RtreeCell *pCell,
	int iHeight
	){
	int rc = SQLITE_OK;
	if( iHeight>0 ){
	RtreeNode *pChild = nodeHashLookup(pRtree, pCell->iRowid);
	if( pChild ){
	nodeRelease(pRtree, pChild->pParent);
	nodeReference(pNode);
	pChild->pParent = pNode;
	}
	}
	if( nodeInsertCell(pRtree, pNode, pCell) ){
	rc = SplitNode(pRtree, pNode, pCell, iHeight);
	}else{
	rc = AdjustTree(pRtree, pNode, pCell);
	if( ALWAYS(rc==SQLITE_OK) ){
	if( iHeight==0 ){
	rc = rowidWrite(pRtree, pCell->iRowid, pNode->iNode);
	}else{
	rc = parentWrite(pRtree, pCell->iRowid, pNode->iNode);
	}
	}
	}
	return rc;
	}

	static int reinsertNodeContent(Rtree pRtree, RtreeNode pNode){
	int ii;
	int rc = SQLITE_OK;
	int nCell = NCELL(pNode);

	for(ii=0; rc==SQLITE_OK && ii<nCell; ii++){
	RtreeNode *pInsert;
	RtreeCell cell;
	nodeGetCell(pRtree, pNode, ii, &cell);

	/* Find a node to store this cell in. pNode->iNode currently contains
	** the height of the sub-tree headed by the cell.
	*/
	rc = ChooseLeaf(pRtree, &cell, (int)pNode->iNode, &pInsert);
	if( rc==SQLITE_OK ){
	int rc2;
	rc = rtreeInsertCell(pRtree, pInsert, &cell, (int)pNode->iNode);
	rc2 = nodeRelease(pRtree, pInsert);
	if( rc==SQLITE_OK ){
	rc = rc2;
	}
	}
	}
	return rc;
	}

	/*
	** Select a currently unused rowid for a new r-tree record.
	*/
	static int rtreeNewRowid(Rtree pRtree, i64 piRowid){
	int rc;
	sqlite3_bind_null(pRtree->pWriteRowid, 1);
	sqlite3_bind_null(pRtree->pWriteRowid, 2);
	sqlite3_step(pRtree->pWriteRowid);
	rc = sqlite3_reset(pRtree->pWriteRowid);
	*piRowid = sqlite3_last_insert_rowid(pRtree->db);
	return rc;
	}

	/*
	** Remove the entry with rowid=iDelete from the r-tree structure.
	*/
	static int rtreeDeleteRowid(Rtree *pRtree, sqlite3_int64 iDelete){
	int rc; /* Return code */
	RtreeNode pLeaf = 0; / Leaf node containing record iDelete */
	int iCell; /* Index of iDelete cell in pLeaf */
	RtreeNode pRoot = 0; / Root node of rtree structure */


	/* Obtain a reference to the root node to initialize Rtree.iDepth */
	rc = nodeAcquire(pRtree, 1, 0, &pRoot);

	/* Obtain a reference to the leaf node that contains the entry
	** about to be deleted.
	*/
	if( rc==SQLITE_OK ){
	rc = findLeafNode(pRtree, iDelete, &pLeaf, 0);
	}

	#ifdef CORRUPT_DB
	assert( pLeaf!=0 \|\| rc!=SQLITE_OK \|\| CORRUPT_DB );
	#endif

	/* Delete the cell in question from the leaf node. */
	if( rc==SQLITE_OK && pLeaf ){
	int rc2;
	rc = nodeRowidIndex(pRtree, pLeaf, iDelete, &iCell);
	if( rc==SQLITE_OK ){
	rc = deleteCell(pRtree, pLeaf, iCell, 0);
	}
	rc2 = nodeRelease(pRtree, pLeaf);
	if( rc==SQLITE_OK ){
	rc = rc2;
	}
	}

	/* Delete the corresponding entry in the <rtree>_rowid table. */
	if( rc==SQLITE_OK ){
	sqlite3_bind_int64(pRtree->pDeleteRowid, 1, iDelete);
	sqlite3_step(pRtree->pDeleteRowid);
	rc = sqlite3_reset(pRtree->pDeleteRowid);
	}

	/* Check if the root node now has exactly one child. If so, remove
	** it, schedule the contents of the child for reinsertion and
	** reduce the tree height by one.
	**
	** This is equivalent to copying the contents of the child into
	** the root node (the operation that Gutman's paper says to perform
	** in this scenario).
	*/
	if( rc==SQLITE_OK && pRtree->iDepth>0 && NCELL(pRoot)==1 ){
	int rc2;
	RtreeNode *pChild = 0;
	i64 iChild = nodeGetRowid(pRtree, pRoot, 0);
	rc = nodeAcquire(pRtree, iChild, pRoot, &pChild); /* tag-20210916a */
	if( rc==SQLITE_OK ){
	rc = removeNode(pRtree, pChild, pRtree->iDepth-1);
	}
	rc2 = nodeRelease(pRtree, pChild);
	if( rc==SQLITE_OK ) rc = rc2;
	if( rc==SQLITE_OK ){
	pRtree->iDepth--;
	writeInt16(pRoot->zData, pRtree->iDepth);
	pRoot->isDirty = 1;
	}
	}

	/* Re-insert the contents of any underfull nodes removed from the tree. */
	for(pLeaf=pRtree->pDeleted; pLeaf; pLeaf=pRtree->pDeleted){
	if( rc==SQLITE_OK ){
	rc = reinsertNodeContent(pRtree, pLeaf);
	}
	pRtree->pDeleted = pLeaf->pNext;
	pRtree->nNodeRef--;
	sqlite3_free(pLeaf);
	}

	/* Release the reference to the root node. */
	if( rc==SQLITE_OK ){
	rc = nodeRelease(pRtree, pRoot);
	}else{
	nodeRelease(pRtree, pRoot);
	}

	return rc;
	}

	/*
	** Rounding constants for float->double conversion.
	*/
	#define RNDTOWARDS (1.0 - 1.0/8388608.0) /* Round towards zero */
	#define RNDAWAY (1.0 + 1.0/8388608.0) /* Round away from zero */

	#if !defined(SQLITE_RTREE_INT_ONLY)
	/*
	** Convert an sqlite3_value into an RtreeValue (presumably a float)
	** while taking care to round toward negative or positive, respectively.
	*/
	static RtreeValue rtreeValueDown(sqlite3_value *v){
	double d = sqlite3_value_double(v);
	float f = (float)d;
	if( f>d ){
	f = (float)(d*(d<0 ? RNDAWAY : RNDTOWARDS));
	}
	return f;
	}
	static RtreeValue rtreeValueUp(sqlite3_value *v){
	double d = sqlite3_value_double(v);
	float f = (float)d;
	if( f<d ){
	f = (float)(d*(d<0 ? RNDTOWARDS : RNDAWAY));
	}
	return f;
	}
	#endif /* !defined(SQLITE_RTREE_INT_ONLY) */

	/*
	** A constraint has failed while inserting a row into an rtree table.
	** Assuming no OOM error occurs, this function sets the error message
	** (at pRtree->base.zErrMsg) to an appropriate value and returns
	** SQLITE_CONSTRAINT.
	**
	** Parameter iCol is the index of the leftmost column involved in the
	** constraint failure. If it is 0, then the constraint that failed is
	** the unique constraint on the id column. Otherwise, it is the rtree
	** (c1<=c2) constraint on columns iCol and iCol+1 that has failed.
	**
	** If an OOM occurs, SQLITE_NOMEM is returned instead of SQLITE_CONSTRAINT.
	*/
	static int rtreeConstraintError(Rtree *pRtree, int iCol){
	sqlite3_stmt *pStmt = 0;
	char *zSql;
	int rc;

	assert( iCol==0 \|\| iCol%2 );
	zSql = sqlite3_mprintf("SELECT * FROM %Q.%Q", pRtree->zDb, pRtree->zName);
	if( zSql ){
	rc = sqlite3_prepare_v2(pRtree->db, zSql, -1, &pStmt, 0);
	}else{
	rc = SQLITE_NOMEM;
	}
	sqlite3_free(zSql);

	if( rc==SQLITE_OK ){
	if( iCol==0 ){
	const char *zCol = sqlite3_column_name(pStmt, 0);
	pRtree->base.zErrMsg = sqlite3_mprintf(
	"UNIQUE constraint failed: %s.%s", pRtree->zName, zCol
	);
	}else{
	const char *zCol1 = sqlite3_column_name(pStmt, iCol);
	const char *zCol2 = sqlite3_column_name(pStmt, iCol+1);
	pRtree->base.zErrMsg = sqlite3_mprintf(
	"rtree constraint failed: %s.(%s<=%s)", pRtree->zName, zCol1, zCol2
	);
	}
	}

	sqlite3_finalize(pStmt);
	return (rc==SQLITE_OK ? SQLITE_CONSTRAINT : rc);
	}



	/*
	** The xUpdate method for rtree module virtual tables.
	*/
	static int rtreeUpdate(
	sqlite3_vtab *pVtab,
	int nData,
	sqlite3_value **aData,
	sqlite_int64 *pRowid
	){
	Rtree pRtree = (Rtree )pVtab;
	int rc = SQLITE_OK;
	RtreeCell cell; /* New cell to insert if nData>1 */
	int bHaveRowid = 0; /* Set to 1 after new rowid is determined */

	if( pRtree->nNodeRef ){
	/* Unable to write to the btree while another cursor is reading from it,
	** since the write might do a rebalance which would disrupt the read
	** cursor. */
	return SQLITE_LOCKED_VTAB;
	}
	rtreeReference(pRtree);
	assert(nData>=1);

	memset(&cell, 0, sizeof(cell));

	/* Constraint handling. A write operation on an r-tree table may return
	** SQLITE_CONSTRAINT for two reasons:
	**
	** 1. A duplicate rowid value, or
	** 2. The supplied data violates the "x2>=x1" constraint.
	**
	** In the first case, if the conflict-handling mode is REPLACE, then
	** the conflicting row can be removed before proceeding. In the second
	** case, SQLITE_CONSTRAINT must be returned regardless of the
	** conflict-handling mode specified by the user.
	*/
	if( nData>1 ){
	int ii;
	int nn = nData - 4;

	if( nn > pRtree->nDim2 ) nn = pRtree->nDim2;
	/* Populate the cell.aCoord[] array. The first coordinate is aData[3].
	**
	** NB: nData can only be less than nDim*2+3 if the rtree is mis-declared
	** with "column" that are interpreted as table constraints.
	** Example: CREATE VIRTUAL TABLE bad USING rtree(x,y,CHECK(y>5));
	** This problem was discovered after years of use, so we silently ignore
	** these kinds of misdeclared tables to avoid breaking any legacy.
	*/

	#ifndef SQLITE_RTREE_INT_ONLY
	if( pRtree->eCoordType==RTREE_COORD_REAL32 ){
	for(ii=0; ii<nn; ii+=2){
	cell.aCoord[ii].f = rtreeValueDown(aData[ii+3]);
	cell.aCoord[ii+1].f = rtreeValueUp(aData[ii+4]);
	if( cell.aCoord[ii].f>cell.aCoord[ii+1].f ){
	rc = rtreeConstraintError(pRtree, ii+1);
	goto constraint;
	}
	}
	}else
	#endif
	{
	for(ii=0; ii<nn; ii+=2){
	cell.aCoord[ii].i = sqlite3_value_int(aData[ii+3]);
	cell.aCoord[ii+1].i = sqlite3_value_int(aData[ii+4]);
	if( cell.aCoord[ii].i>cell.aCoord[ii+1].i ){
	rc = rtreeConstraintError(pRtree, ii+1);
	goto constraint;
	}
	}
	}

	/* If a rowid value was supplied, check if it is already present in
	** the table. If so, the constraint has failed. */
	if( sqlite3_value_type(aData[2])!=SQLITE_NULL ){
	cell.iRowid = sqlite3_value_int64(aData[2]);
	if( sqlite3_value_type(aData[0])==SQLITE_NULL
	\|\| sqlite3_value_int64(aData[0])!=cell.iRowid
	){
	int steprc;
	sqlite3_bind_int64(pRtree->pReadRowid, 1, cell.iRowid);
	steprc = sqlite3_step(pRtree->pReadRowid);
	rc = sqlite3_reset(pRtree->pReadRowid);
	if( SQLITE_ROW==steprc ){
	if( sqlite3_vtab_on_conflict(pRtree->db)==SQLITE_REPLACE ){
	rc = rtreeDeleteRowid(pRtree, cell.iRowid);
	}else{
	rc = rtreeConstraintError(pRtree, 0);
	goto constraint;
	}
	}
	}
	bHaveRowid = 1;
	}
	}

	/* If aData[0] is not an SQL NULL value, it is the rowid of a
	** record to delete from the r-tree table. The following block does
	** just that.
	*/
	if( sqlite3_value_type(aData[0])!=SQLITE_NULL ){
	rc = rtreeDeleteRowid(pRtree, sqlite3_value_int64(aData[0]));
	}

	/* If the aData[] array contains more than one element, elements
	** (aData[2]..aData[argc-1]) contain a new record to insert into
	** the r-tree structure.
	*/
	if( rc==SQLITE_OK && nData>1 ){
	/* Insert the new record into the r-tree */
	RtreeNode *pLeaf = 0;

	/* Figure out the rowid of the new row. */
	if( bHaveRowid==0 ){
	rc = rtreeNewRowid(pRtree, &cell.iRowid);
	}
	*pRowid = cell.iRowid;

	if( rc==SQLITE_OK ){
	rc = ChooseLeaf(pRtree, &cell, 0, &pLeaf);
	}
	if( rc==SQLITE_OK ){
	int rc2;
	rc = rtreeInsertCell(pRtree, pLeaf, &cell, 0);
	rc2 = nodeRelease(pRtree, pLeaf);
	if( rc==SQLITE_OK ){
	rc = rc2;
	}
	}
	if( rc==SQLITE_OK && pRtree->nAux ){
	sqlite3_stmt *pUp = pRtree->pWriteAux;
	int jj;
	sqlite3_bind_int64(pUp, 1, *pRowid);
	for(jj=0; jj<pRtree->nAux; jj++){
	sqlite3_bind_value(pUp, jj+2, aData[pRtree->nDim2+3+jj]);
	}
	sqlite3_step(pUp);
	rc = sqlite3_reset(pUp);
	}
	}

	constraint:
	rtreeRelease(pRtree);
	return rc;
	}

	/*
	** Called when a transaction starts.
	*/
	static int rtreeBeginTransaction(sqlite3_vtab *pVtab){
	Rtree pRtree = (Rtree )pVtab;
	assert( pRtree->inWrTrans==0 );
	pRtree->inWrTrans = 1;
	return SQLITE_OK;
	}

	/*
	** Called when a transaction completes (either by COMMIT or ROLLBACK).
	** The sqlite3_blob object should be released at this point.
	*/
	static int rtreeEndTransaction(sqlite3_vtab *pVtab){
	Rtree pRtree = (Rtree )pVtab;
	pRtree->inWrTrans = 0;
	nodeBlobReset(pRtree);
	return SQLITE_OK;
	}
	static int rtreeRollback(sqlite3_vtab *pVtab){
	return rtreeEndTransaction(pVtab);
	}

	/*
	** The xRename method for rtree module virtual tables.
	*/
	static int rtreeRename(sqlite3_vtab pVtab, const char zNewName){
	Rtree pRtree = (Rtree )pVtab;
	int rc = SQLITE_NOMEM;
	char *zSql = sqlite3_mprintf(
	"ALTER TABLE %Q.'%q_node' RENAME TO \"%w_node\";"
	"ALTER TABLE %Q.'%q_parent' RENAME TO \"%w_parent\";"
	"ALTER TABLE %Q.'%q_rowid' RENAME TO \"%w_rowid\";"
	, pRtree->zDb, pRtree->zName, zNewName
	, pRtree->zDb, pRtree->zName, zNewName
	, pRtree->zDb, pRtree->zName, zNewName
	);
	if( zSql ){
	nodeBlobReset(pRtree);
	rc = sqlite3_exec(pRtree->db, zSql, 0, 0, 0);
	sqlite3_free(zSql);
	}
	return rc;
	}

	/*
	** The xSavepoint method.
	**
	** This module does not need to do anything to support savepoints. However,
	** it uses this hook to close any open blob handle. This is done because a
	** DROP TABLE command - which fortunately always opens a savepoint - cannot
	** succeed if there are any open blob handles. i.e. if the blob handle were
	** not closed here, the following would fail:
	**
	** BEGIN;
	** INSERT INTO rtree...
	** DROP TABLE <tablename>; -- Would fail with SQLITE_LOCKED
	** COMMIT;
	*/
	static int rtreeSavepoint(sqlite3_vtab *pVtab, int iSavepoint){
	Rtree pRtree = (Rtree )pVtab;
	u8 iwt = pRtree->inWrTrans;
	UNUSED_PARAMETER(iSavepoint);
	pRtree->inWrTrans = 0;
	nodeBlobReset(pRtree);
	pRtree->inWrTrans = iwt;
	return SQLITE_OK;
	}

	/*
	** This function populates the pRtree->nRowEst variable with an estimate
	** of the number of rows in the virtual table. If possible, this is based
	** on sqlite_stat1 data. Otherwise, use RTREE_DEFAULT_ROWEST.
	*/
	static int rtreeQueryStat1(sqlite3 db, Rtree pRtree){
	const char *zFmt = "SELECT stat FROM %Q.sqlite_stat1 WHERE tbl = '%q_rowid'";
	char *zSql;
	sqlite3_stmt *p;
	int rc;
	i64 nRow = RTREE_MIN_ROWEST;

	rc = sqlite3_table_column_metadata(
	db, pRtree->zDb, "sqlite_stat1",0,0,0,0,0,0
	);
	if( rc!=SQLITE_OK ){
	pRtree->nRowEst = RTREE_DEFAULT_ROWEST;
	return rc==SQLITE_ERROR ? SQLITE_OK : rc;
	}
	zSql = sqlite3_mprintf(zFmt, pRtree->zDb, pRtree->zName);
	if( zSql==0 ){
	rc = SQLITE_NOMEM;
	}else{
	rc = sqlite3_prepare_v2(db, zSql, -1, &p, 0);
	if( rc==SQLITE_OK ){
	if( sqlite3_step(p)==SQLITE_ROW ) nRow = sqlite3_column_int64(p, 0);
	rc = sqlite3_finalize(p);
	}
	sqlite3_free(zSql);
	}
	pRtree->nRowEst = MAX(nRow, RTREE_MIN_ROWEST);
	return rc;
	}


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

	/* Forward declaration */
	static int rtreeIntegrity(sqlite3_vtab, const char, const char, int, char*);

	static sqlite3_module rtreeModule = {
	4, /* iVersion */
	rtreeCreate, /* xCreate - create a table */
	rtreeConnect, /* xConnect - connect to an existing table */
	rtreeBestIndex, /* xBestIndex - Determine search strategy */
	rtreeDisconnect, /* xDisconnect - Disconnect from a table */
	rtreeDestroy, /* xDestroy - Drop a table */
	rtreeOpen, /* xOpen - open a cursor */
	rtreeClose, /* xClose - close a cursor */
	rtreeFilter, /* xFilter - configure scan constraints */
	rtreeNext, /* xNext - advance a cursor */
	rtreeEof, /* xEof */
	rtreeColumn, /* xColumn - read data */
	rtreeRowid, /* xRowid - read data */
	rtreeUpdate, /* xUpdate - write data */
	rtreeBeginTransaction, /* xBegin - begin transaction */
	rtreeEndTransaction, /* xSync - sync transaction */
	rtreeEndTransaction, /* xCommit - commit transaction */
	rtreeRollback, /* xRollback - rollback transaction */
	0, /* xFindFunction - function overloading */
	rtreeRename, /* xRename - rename the table */
	rtreeSavepoint, /* xSavepoint */
	0, /* xRelease */
	0, /* xRollbackTo */
	rtreeShadowName, /* xShadowName */
	rtreeIntegrity /* xIntegrity */
	};

	static int rtreeSqlInit(
	Rtree *pRtree,
	sqlite3 *db,
	const char *zDb,
	const char *zPrefix,
	int isCreate
	){
	int rc = SQLITE_OK;

	#define N_STATEMENT 8
	static const char *azSql[N_STATEMENT] = {
	/* Write the xxx_node table */
	"INSERT OR REPLACE INTO '%q'.'%q_node' VALUES(?1, ?2)",
	"DELETE FROM '%q'.'%q_node' WHERE nodeno = ?1",

	/* Read and write the xxx_rowid table */
	"SELECT nodeno FROM '%q'.'%q_rowid' WHERE rowid = ?1",
	"INSERT OR REPLACE INTO '%q'.'%q_rowid' VALUES(?1, ?2)",
	"DELETE FROM '%q'.'%q_rowid' WHERE rowid = ?1",

	/* Read and write the xxx_parent table */
	"SELECT parentnode FROM '%q'.'%q_parent' WHERE nodeno = ?1",
	"INSERT OR REPLACE INTO '%q'.'%q_parent' VALUES(?1, ?2)",
	"DELETE FROM '%q'.'%q_parent' WHERE nodeno = ?1"
	};
	sqlite3_stmt **appStmt[N_STATEMENT];
	int i;
	const int f = SQLITE_PREPARE_PERSISTENT\|SQLITE_PREPARE_NO_VTAB;

	pRtree->db = db;

	if( isCreate ){
	char *zCreate;
	sqlite3_str *p = sqlite3_str_new(db);
	int ii;
	sqlite3_str_appendf(p,
	"CREATE TABLE \"%w\".\"%w_rowid\"(rowid INTEGER PRIMARY KEY,nodeno",
	zDb, zPrefix);
	for(ii=0; ii<pRtree->nAux; ii++){
	sqlite3_str_appendf(p,",a%d",ii);
	}
	sqlite3_str_appendf(p,
	");CREATE TABLE \"%w\".\"%w_node\"(nodeno INTEGER PRIMARY KEY,data);",
	zDb, zPrefix);
	sqlite3_str_appendf(p,
	"CREATE TABLE \"%w\".\"%w_parent\"(nodeno INTEGER PRIMARY KEY,parentnode);",
	zDb, zPrefix);
	sqlite3_str_appendf(p,
	"INSERT INTO \"%w\".\"%w_node\"VALUES(1,zeroblob(%d))",
	zDb, zPrefix, pRtree->iNodeSize);
	zCreate = sqlite3_str_finish(p);
	if( !zCreate ){
	return SQLITE_NOMEM;
	}
	rc = sqlite3_exec(db, zCreate, 0, 0, 0);
	sqlite3_free(zCreate);
	if( rc!=SQLITE_OK ){
	return rc;
	}
	}

	appStmt[0] = &pRtree->pWriteNode;
	appStmt[1] = &pRtree->pDeleteNode;
	appStmt[2] = &pRtree->pReadRowid;
	appStmt[3] = &pRtree->pWriteRowid;
	appStmt[4] = &pRtree->pDeleteRowid;
	appStmt[5] = &pRtree->pReadParent;
	appStmt[6] = &pRtree->pWriteParent;
	appStmt[7] = &pRtree->pDeleteParent;

	rc = rtreeQueryStat1(db, pRtree);
	for(i=0; i<N_STATEMENT && rc==SQLITE_OK; i++){
	char *zSql;
	const char *zFormat;
	if( i!=3 \|\| pRtree->nAux==0 ){
	zFormat = azSql[i];
	}else {
	/* An UPSERT is very slightly slower than REPLACE, but it is needed
	** if there are auxiliary columns */
	zFormat = "INSERT INTO\"%w\".\"%w_rowid\"(rowid,nodeno)VALUES(?1,?2)"
	"ON CONFLICT(rowid)DO UPDATE SET nodeno=excluded.nodeno";
	}
	zSql = sqlite3_mprintf(zFormat, zDb, zPrefix);
	if( zSql ){
	rc = sqlite3_prepare_v3(db, zSql, -1, f, appStmt[i], 0);
	}else{
	rc = SQLITE_NOMEM;
	}
	sqlite3_free(zSql);
	}
	if( pRtree->nAux && rc!=SQLITE_NOMEM ){
	pRtree->zReadAuxSql = sqlite3_mprintf(
	"SELECT * FROM \"%w\".\"%w_rowid\" WHERE rowid=?1",
	zDb, zPrefix);
	if( pRtree->zReadAuxSql==0 ){
	rc = SQLITE_NOMEM;
	}else{
	sqlite3_str *p = sqlite3_str_new(db);
	int ii;
	char *zSql;
	sqlite3_str_appendf(p, "UPDATE \"%w\".\"%w_rowid\"SET ", zDb, zPrefix);
	for(ii=0; ii<pRtree->nAux; ii++){
	if( ii ) sqlite3_str_append(p, ",", 1);
	#ifdef SQLITE_ENABLE_GEOPOLY
	if( ii<pRtree->nAuxNotNull ){
	sqlite3_str_appendf(p,"a%d=coalesce(?%d,a%d)",ii,ii+2,ii);
	}else
	#endif
	{
	sqlite3_str_appendf(p,"a%d=?%d",ii,ii+2);
	}
	}
	sqlite3_str_appendf(p, " WHERE rowid=?1");
	zSql = sqlite3_str_finish(p);
	if( zSql==0 ){
	rc = SQLITE_NOMEM;
	}else{
	rc = sqlite3_prepare_v3(db, zSql, -1, f, &pRtree->pWriteAux, 0);
	sqlite3_free(zSql);
	}
	}
	}

	return rc;
	}

	/*
	** The second argument to this function contains the text of an SQL statement
	** that returns a single integer value. The statement is compiled and executed
	** using database connection db. If successful, the integer value returned
	** is written to *piVal and SQLITE_OK returned. Otherwise, an SQLite error
	** code is returned and the value of *piVal after returning is not defined.
	*/
	static int getIntFromStmt(sqlite3 db, const char zSql, int *piVal){
	int rc = SQLITE_NOMEM;
	if( zSql ){
	sqlite3_stmt *pStmt = 0;
	rc = sqlite3_prepare_v2(db, zSql, -1, &pStmt, 0);
	if( rc==SQLITE_OK ){
	if( SQLITE_ROW==sqlite3_step(pStmt) ){
	*piVal = sqlite3_column_int(pStmt, 0);
	}
	rc = sqlite3_finalize(pStmt);
	}
	}
	return rc;
	}

	/*
	** This function is called from within the xConnect() or xCreate() method to
	** determine the node-size used by the rtree table being created or connected
	** to. If successful, pRtree->iNodeSize is populated and SQLITE_OK returned.
	** Otherwise, an SQLite error code is returned.
	**
	** If this function is being called as part of an xConnect(), then the rtree
	** table already exists. In this case the node-size is determined by inspecting
	** the root node of the tree.
	**
	** Otherwise, for an xCreate(), use 64 bytes less than the database page-size.
	** This ensures that each node is stored on a single database page. If the
	** database page-size is so large that more than RTREE_MAXCELLS entries
	** would fit in a single node, use a smaller node-size.
	*/
	static int getNodeSize(
	sqlite3 db, / Database handle */
	Rtree pRtree, / Rtree handle */
	int isCreate, /* True for xCreate, false for xConnect */
	char *pzErr / OUT: Error message, if any */
	){
	int rc;
	char *zSql;
	if( isCreate ){
	int iPageSize = 0;
	zSql = sqlite3_mprintf("PRAGMA %Q.page_size", pRtree->zDb);
	rc = getIntFromStmt(db, zSql, &iPageSize);
	if( rc==SQLITE_OK ){
	pRtree->iNodeSize = iPageSize-64;
	if( (4+pRtree->nBytesPerCell*RTREE_MAXCELLS)<pRtree->iNodeSize ){
	pRtree->iNodeSize = 4+pRtree->nBytesPerCell*RTREE_MAXCELLS;
	}
	}else{
	*pzErr = sqlite3_mprintf("%s", sqlite3_errmsg(db));
	}
	}else{
	zSql = sqlite3_mprintf(
	"SELECT length(data) FROM '%q'.'%q_node' WHERE nodeno = 1",
	pRtree->zDb, pRtree->zName
	);
	rc = getIntFromStmt(db, zSql, &pRtree->iNodeSize);
	if( rc!=SQLITE_OK ){
	*pzErr = sqlite3_mprintf("%s", sqlite3_errmsg(db));
	}else if( pRtree->iNodeSize<(512-64) ){
	rc = SQLITE_CORRUPT_VTAB;
	RTREE_IS_CORRUPT(pRtree);
	*pzErr = sqlite3_mprintf("undersize RTree blobs in \"%q_node\"",
	pRtree->zName);
	}
	}

	sqlite3_free(zSql);
	return rc;
	}

	/*
	** Return the length of a token
	*/
	static int rtreeTokenLength(const char *z){
	int dummy = 0;
	return sqlite3GetToken((const unsigned char*)z,&dummy);
	}

	/*
	** This function is the implementation of both the xConnect and xCreate
	** methods of the r-tree virtual table.
	**
	** argv[0] -> module name
	** argv[1] -> database name
	** argv[2] -> table name
	** argv[...] -> column names...
	*/
	static int rtreeInit(
	sqlite3 db, / Database connection */
	void pAux, / One of the RTREE_COORD_* constants */
	int argc, const char constargv, /* Parameters to CREATE TABLE statement */
	sqlite3_vtab *ppVtab, / OUT: New virtual table */
	char *pzErr, / OUT: Error message, if any */
	int isCreate /* True for xCreate, false for xConnect */
	){
	int rc = SQLITE_OK;
	Rtree *pRtree;
	int nDb; /* Length of string argv[1] */
	int nName; /* Length of string argv[2] */
	int eCoordType = (pAux ? RTREE_COORD_INT32 : RTREE_COORD_REAL32);
	sqlite3_str *pSql;
	char *zSql;
	int ii = 4;
	int iErr;

	const char *aErrMsg[] = {
	0, /* 0 */
	"Wrong number of columns for an rtree table", /* 1 */
	"Too few columns for an rtree table", /* 2 */
	"Too many columns for an rtree table", /* 3 */
	"Auxiliary rtree columns must be last" /* 4 */
	};

	assert( RTREE_MAX_AUX_COLUMN<256 ); /* Aux columns counted by a u8 */
	if( argc<6 \|\| argc>RTREE_MAX_AUX_COLUMN+3 ){
	*pzErr = sqlite3_mprintf("%s", aErrMsg[2 + (argc>=6)]);
	return SQLITE_ERROR;
	}

	sqlite3_vtab_config(db, SQLITE_VTAB_CONSTRAINT_SUPPORT, 1);
	sqlite3_vtab_config(db, SQLITE_VTAB_INNOCUOUS);


	/* Allocate the sqlite3_vtab structure */
	nDb = (int)strlen(argv[1]);
	nName = (int)strlen(argv[2]);
	pRtree = (Rtree )sqlite3_malloc64(sizeof(Rtree)+nDb+nName2+8);
	if( !pRtree ){
	return SQLITE_NOMEM;
	}
	memset(pRtree, 0, sizeof(Rtree)+nDb+nName*2+8);
	pRtree->nBusy = 1;
	pRtree->base.pModule = &rtreeModule;
	pRtree->zDb = (char *)&pRtree[1];
	pRtree->zName = &pRtree->zDb[nDb+1];
	pRtree->zNodeName = &pRtree->zName[nName+1];
	pRtree->eCoordType = (u8)eCoordType;
	memcpy(pRtree->zDb, argv[1], nDb);
	memcpy(pRtree->zName, argv[2], nName);
	memcpy(pRtree->zNodeName, argv[2], nName);
	memcpy(&pRtree->zNodeName[nName], "_node", 6);


	/* Create/Connect to the underlying relational database schema. If
	** that is successful, call sqlite3_declare_vtab() to configure
	** the r-tree table schema.
	*/
	pSql = sqlite3_str_new(db);
	sqlite3_str_appendf(pSql, "CREATE TABLE x(%.*s INT",
	rtreeTokenLength(argv[3]), argv[3]);
	for(ii=4; ii<argc; ii++){
	const char *zArg = argv[ii];
	if( zArg[0]=='+' ){
	pRtree->nAux++;
	sqlite3_str_appendf(pSql, ",%.*s", rtreeTokenLength(zArg+1), zArg+1);
	}else if( pRtree->nAux>0 ){
	break;
	}else{
	static const char azFormat[] = {",%.s REAL", ",%.*s INT"};
	pRtree->nDim2++;
	sqlite3_str_appendf(pSql, azFormat[eCoordType],
	rtreeTokenLength(zArg), zArg);
	}
	}
	sqlite3_str_appendf(pSql, ");");
	zSql = sqlite3_str_finish(pSql);
	if( !zSql ){
	rc = SQLITE_NOMEM;
	}else if( ii<argc ){
	*pzErr = sqlite3_mprintf("%s", aErrMsg[4]);
	rc = SQLITE_ERROR;
	}else if( SQLITE_OK!=(rc = sqlite3_declare_vtab(db, zSql)) ){
	*pzErr = sqlite3_mprintf("%s", sqlite3_errmsg(db));
	}
	sqlite3_free(zSql);
	if( rc ) goto rtreeInit_fail;
	pRtree->nDim = pRtree->nDim2/2;
	if( pRtree->nDim<1 ){
	iErr = 2;
	}else if( pRtree->nDim2>RTREE_MAX_DIMENSIONS*2 ){
	iErr = 3;
	}else if( pRtree->nDim2 % 2 ){
	iErr = 1;
	}else{
	iErr = 0;
	}
	if( iErr ){
	*pzErr = sqlite3_mprintf("%s", aErrMsg[iErr]);
	goto rtreeInit_fail;
	}
	pRtree->nBytesPerCell = 8 + pRtree->nDim2*4;

	/* Figure out the node size to use. */
	rc = getNodeSize(db, pRtree, isCreate, pzErr);
	if( rc ) goto rtreeInit_fail;
	rc = rtreeSqlInit(pRtree, db, argv[1], argv[2], isCreate);
	if( rc ){
	*pzErr = sqlite3_mprintf("%s", sqlite3_errmsg(db));
	goto rtreeInit_fail;
	}

	ppVtab = (sqlite3_vtab )pRtree;
	return SQLITE_OK;

	rtreeInit_fail:
	if( rc==SQLITE_OK ) rc = SQLITE_ERROR;
	assert( *ppVtab==0 );
	assert( pRtree->nBusy==1 );
	rtreeRelease(pRtree);
	return rc;
	}


	/*
	** Implementation of a scalar function that decodes r-tree nodes to
	** human readable strings. This can be used for debugging and analysis.
	**
	** The scalar function takes two arguments: (1) the number of dimensions
	** to the rtree (between 1 and 5, inclusive) and (2) a blob of data containing
	** an r-tree node. For a two-dimensional r-tree structure called "rt", to
	** deserialize all nodes, a statement like:
	**
	** SELECT rtreenode(2, data) FROM rt_node;
	**
	** The human readable string takes the form of a Tcl list with one
	** entry for each cell in the r-tree node. Each entry is itself a
	** list, containing the 8-byte rowid/pageno followed by the
	** <num-dimension>*2 coordinates.
	*/
	static void rtreenode(sqlite3_context ctx, int nArg, sqlite3_value *apArg){
	RtreeNode node;
	Rtree tree;
	int ii;
	int nData;
	int errCode;
	sqlite3_str *pOut;

	UNUSED_PARAMETER(nArg);
	memset(&node, 0, sizeof(RtreeNode));
	memset(&tree, 0, sizeof(Rtree));
	tree.nDim = (u8)sqlite3_value_int(apArg[0]);
	if( tree.nDim<1 \|\| tree.nDim>5 ) return;
	tree.nDim2 = tree.nDim*2;
	tree.nBytesPerCell = 8 + 8 * tree.nDim;
	node.zData = (u8 *)sqlite3_value_blob(apArg[1]);
	if( node.zData==0 ) return;
	nData = sqlite3_value_bytes(apArg[1]);
	if( nData<4 ) return;
	if( nData<NCELL(&node)*tree.nBytesPerCell ) return;

	pOut = sqlite3_str_new(0);
	for(ii=0; ii<NCELL(&node); ii++){
	RtreeCell cell;
	int jj;

	nodeGetCell(&tree, &node, ii, &cell);
	if( ii>0 ) sqlite3_str_append(pOut, " ", 1);
	sqlite3_str_appendf(pOut, "{%lld", cell.iRowid);
	for(jj=0; jj<tree.nDim2; jj++){
	#ifndef SQLITE_RTREE_INT_ONLY
	sqlite3_str_appendf(pOut, " %g", (double)cell.aCoord[jj].f);
	#else
	sqlite3_str_appendf(pOut, " %d", cell.aCoord[jj].i);
	#endif
	}
	sqlite3_str_append(pOut, "}", 1);
	}
	errCode = sqlite3_str_errcode(pOut);
	sqlite3_result_text(ctx, sqlite3_str_finish(pOut), -1, sqlite3_free);
	sqlite3_result_error_code(ctx, errCode);
	}

	/* This routine implements an SQL function that returns the "depth" parameter
	** from the front of a blob that is an r-tree node. For example:
	**
	** SELECT rtreedepth(data) FROM rt_node WHERE nodeno=1;
	**
	** The depth value is 0 for all nodes other than the root node, and the root
	** node always has nodeno=1, so the example above is the primary use for this
	** routine. This routine is intended for testing and analysis only.
	*/
	static void rtreedepth(sqlite3_context ctx, int nArg, sqlite3_value *apArg){
	UNUSED_PARAMETER(nArg);
	if( sqlite3_value_type(apArg[0])!=SQLITE_BLOB
	\|\| sqlite3_value_bytes(apArg[0])<2

	){
	sqlite3_result_error(ctx, "Invalid argument to rtreedepth()", -1);
	}else{
	u8 zBlob = (u8 )sqlite3_value_blob(apArg[0]);
	if( zBlob ){
	sqlite3_result_int(ctx, readInt16(zBlob));
	}else{
	sqlite3_result_error_nomem(ctx);
	}
	}
	}

	/*
	** Context object passed between the various routines that make up the
	** implementation of integrity-check function rtreecheck().
	*/
	typedef struct RtreeCheck RtreeCheck;
	struct RtreeCheck {
	sqlite3 db; / Database handle */
	const char zDb; / Database containing rtree table */
	const char zTab; / Name of rtree table */
	int bInt; /* True for rtree_i32 table */
	int nDim; /* Number of dimensions for this rtree tbl */
	sqlite3_stmt pGetNode; / Statement used to retrieve nodes */
	sqlite3_stmt aCheckMapping[2]; / Statements to query %_parent/%_rowid */
	int nLeaf; /* Number of leaf cells in table */
	int nNonLeaf; /* Number of non-leaf cells in table */
	int rc; /* Return code */
	char zReport; / Message to report */
	int nErr; /* Number of lines in zReport */
	};

	#define RTREE_CHECK_MAX_ERROR 100

	/*
	** Reset SQL statement pStmt. If the sqlite3_reset() call returns an error,
	** and RtreeCheck.rc==SQLITE_OK, set RtreeCheck.rc to the error code.
	*/
	static void rtreeCheckReset(RtreeCheck pCheck, sqlite3_stmt pStmt){
	int rc = sqlite3_reset(pStmt);
	if( pCheck->rc==SQLITE_OK ) pCheck->rc = rc;
	}

	/*
	** The second and subsequent arguments to this function are a format string
	** and printf style arguments. This function formats the string and attempts
	** to compile it as an SQL statement.
	**
	** If successful, a pointer to the new SQL statement is returned. Otherwise,
	** NULL is returned and an error code left in RtreeCheck.rc.
	*/
	static sqlite3_stmt *rtreeCheckPrepare(
	RtreeCheck pCheck, / RtreeCheck object */
	const char zFmt, ... / Format string and trailing args */
	){
	va_list ap;
	char *z;
	sqlite3_stmt *pRet = 0;

	va_start(ap, zFmt);
	z = sqlite3_vmprintf(zFmt, ap);

	if( pCheck->rc==SQLITE_OK ){
	if( z==0 ){
	pCheck->rc = SQLITE_NOMEM;
	}else{
	pCheck->rc = sqlite3_prepare_v2(pCheck->db, z, -1, &pRet, 0);
	}
	}

	sqlite3_free(z);
	va_end(ap);
	return pRet;
	}

	/*
	** The second and subsequent arguments to this function are a printf()
	** style format string and arguments. This function formats the string and
	** appends it to the report being accumuated in pCheck.
	*/
	static void rtreeCheckAppendMsg(RtreeCheck pCheck, const char zFmt, ...){
	va_list ap;
	va_start(ap, zFmt);
	if( pCheck->rc==SQLITE_OK && pCheck->nErr<RTREE_CHECK_MAX_ERROR ){
	char *z = sqlite3_vmprintf(zFmt, ap);
	if( z==0 ){
	pCheck->rc = SQLITE_NOMEM;
	}else{
	pCheck->zReport = sqlite3_mprintf("%z%s%z",
	pCheck->zReport, (pCheck->zReport ? "\n" : ""), z
	);
	if( pCheck->zReport==0 ){
	pCheck->rc = SQLITE_NOMEM;
	}
	}
	pCheck->nErr++;
	}
	va_end(ap);
	}

	/*
	** This function is a no-op if there is already an error code stored
	** in the RtreeCheck object indicated by the first argument. NULL is
	** returned in this case.
	**
	** Otherwise, the contents of rtree table node iNode are loaded from
	** the database and copied into a buffer obtained from sqlite3_malloc().
	** If no error occurs, a pointer to the buffer is returned and (*pnNode)
	** is set to the size of the buffer in bytes.
	**
	** Or, if an error does occur, NULL is returned and an error code left
	** in the RtreeCheck object. The final value of *pnNode is undefined in
	** this case.
	*/
	static u8 rtreeCheckGetNode(RtreeCheck pCheck, i64 iNode, int *pnNode){
	u8 pRet = 0; / Return value */

	if( pCheck->rc==SQLITE_OK && pCheck->pGetNode==0 ){
	pCheck->pGetNode = rtreeCheckPrepare(pCheck,
	"SELECT data FROM %Q.'%q_node' WHERE nodeno=?",
	pCheck->zDb, pCheck->zTab
	);
	}

	if( pCheck->rc==SQLITE_OK ){
	sqlite3_bind_int64(pCheck->pGetNode, 1, iNode);
	if( sqlite3_step(pCheck->pGetNode)==SQLITE_ROW ){
	int nNode = sqlite3_column_bytes(pCheck->pGetNode, 0);
	const u8 pNode = (const u8)sqlite3_column_blob(pCheck->pGetNode, 0);
	pRet = sqlite3_malloc64(nNode);
	if( pRet==0 ){
	pCheck->rc = SQLITE_NOMEM;
	}else{
	memcpy(pRet, pNode, nNode);
	*pnNode = nNode;
	}
	}
	rtreeCheckReset(pCheck, pCheck->pGetNode);
	if( pCheck->rc==SQLITE_OK && pRet==0 ){
	rtreeCheckAppendMsg(pCheck, "Node %lld missing from database", iNode);
	}
	}

	return pRet;
	}

	/*
	** This function is used to check that the %_parent (if bLeaf==0) or %_rowid
	** (if bLeaf==1) table contains a specified entry. The schemas of the
	** two tables are:
	**
	** CREATE TABLE %_parent(nodeno INTEGER PRIMARY KEY, parentnode INTEGER)
	** CREATE TABLE %_rowid(rowid INTEGER PRIMARY KEY, nodeno INTEGER, ...)
	**
	** In both cases, this function checks that there exists an entry with
	** IPK value iKey and the second column set to iVal.
	**
	*/
	static void rtreeCheckMapping(
	RtreeCheck pCheck, / RtreeCheck object */
	int bLeaf, /* True for a leaf cell, false for interior */
	i64 iKey, /* Key for mapping */
	i64 iVal /* Expected value for mapping */
	){
	int rc;
	sqlite3_stmt *pStmt;
	const char *azSql[2] = {
	"SELECT parentnode FROM %Q.'%q_parent' WHERE nodeno=?1",
	"SELECT nodeno FROM %Q.'%q_rowid' WHERE rowid=?1"
	};

	assert( bLeaf==0 \|\| bLeaf==1 );
	if( pCheck->aCheckMapping[bLeaf]==0 ){
	pCheck->aCheckMapping[bLeaf] = rtreeCheckPrepare(pCheck,
	azSql[bLeaf], pCheck->zDb, pCheck->zTab
	);
	}
	if( pCheck->rc!=SQLITE_OK ) return;

	pStmt = pCheck->aCheckMapping[bLeaf];
	sqlite3_bind_int64(pStmt, 1, iKey);
	rc = sqlite3_step(pStmt);
	if( rc==SQLITE_DONE ){
	rtreeCheckAppendMsg(pCheck, "Mapping (%lld -> %lld) missing from %s table",
	iKey, iVal, (bLeaf ? "%_rowid" : "%_parent")
	);
	}else if( rc==SQLITE_ROW ){
	i64 ii = sqlite3_column_int64(pStmt, 0);
	if( ii!=iVal ){
	rtreeCheckAppendMsg(pCheck,
	"Found (%lld -> %lld) in %s table, expected (%lld -> %lld)",
	iKey, ii, (bLeaf ? "%_rowid" : "%_parent"), iKey, iVal
	);
	}
	}
	rtreeCheckReset(pCheck, pStmt);
	}

	/*
	** Argument pCell points to an array of coordinates stored on an rtree page.
	** This function checks that the coordinates are internally consistent (no
	** x1>x2 conditions) and adds an error message to the RtreeCheck object
	** if they are not.
	**
	** Additionally, if pParent is not NULL, then it is assumed to point to
	** the array of coordinates on the parent page that bound the page
	** containing pCell. In this case it is also verified that the two
	** sets of coordinates are mutually consistent and an error message added
	** to the RtreeCheck object if they are not.
	*/
	static void rtreeCheckCellCoord(
	RtreeCheck *pCheck,
	i64 iNode, /* Node id to use in error messages */
	int iCell, /* Cell number to use in error messages */
	u8 pCell, / Pointer to cell coordinates */
	u8 pParent / Pointer to parent coordinates */
	){
	RtreeCoord c1, c2;
	RtreeCoord p1, p2;
	int i;

	for(i=0; i<pCheck->nDim; i++){
	readCoord(&pCell[42i], &c1);
	readCoord(&pCell[4(2i + 1)], &c2);

	/* printf("%e, %e\n", c1.u.f, c2.u.f); */
	if( pCheck->bInt ? c1.i>c2.i : c1.f>c2.f ){
	rtreeCheckAppendMsg(pCheck,
	"Dimension %d of cell %d on node %lld is corrupt", i, iCell, iNode
	);
	}

	if( pParent ){
	readCoord(&pParent[42i], &p1);
	readCoord(&pParent[4(2i + 1)], &p2);

	if( (pCheck->bInt ? c1.i<p1.i : c1.f<p1.f)
	\|\| (pCheck->bInt ? c2.i>p2.i : c2.f>p2.f)
	){
	rtreeCheckAppendMsg(pCheck,
	"Dimension %d of cell %d on node %lld is corrupt relative to parent"
	, i, iCell, iNode
	);
	}
	}
	}
	}

	/*
	** Run rtreecheck() checks on node iNode, which is at depth iDepth within
	** the r-tree structure. Argument aParent points to the array of coordinates
	** that bound node iNode on the parent node.
	**
	** If any problems are discovered, an error message is appended to the
	** report accumulated in the RtreeCheck object.
	*/
	static void rtreeCheckNode(
	RtreeCheck *pCheck,
	int iDepth, /* Depth of iNode (0==leaf) */
	u8 aParent, / Buffer containing parent coords */
	i64 iNode /* Node to check */
	){
	u8 *aNode = 0;
	int nNode = 0;

	assert( iNode==1 \|\| aParent!=0 );
	assert( pCheck->nDim>0 );

	aNode = rtreeCheckGetNode(pCheck, iNode, &nNode);
	if( aNode ){
	if( nNode<4 ){
	rtreeCheckAppendMsg(pCheck,
	"Node %lld is too small (%d bytes)", iNode, nNode
	);
	}else{
	int nCell; /* Number of cells on page */
	int i; /* Used to iterate through cells */
	if( aParent==0 ){
	iDepth = readInt16(aNode);
	if( iDepth>RTREE_MAX_DEPTH ){
	rtreeCheckAppendMsg(pCheck, "Rtree depth out of range (%d)", iDepth);
	sqlite3_free(aNode);
	return;
	}
	}
	nCell = readInt16(&aNode[2]);
	if( (4 + nCell(8 + pCheck->nDim2*4))>nNode ){
	rtreeCheckAppendMsg(pCheck,
	"Node %lld is too small for cell count of %d (%d bytes)",
	iNode, nCell, nNode
	);
	}else{
	for(i=0; i<nCell; i++){
	u8 pCell = &aNode[4 + i(8 + pCheck->nDim24)];
	i64 iVal = readInt64(pCell);
	rtreeCheckCellCoord(pCheck, iNode, i, &pCell[8], aParent);

	if( iDepth>0 ){
	rtreeCheckMapping(pCheck, 0, iVal, iNode);
	rtreeCheckNode(pCheck, iDepth-1, &pCell[8], iVal);
	pCheck->nNonLeaf++;
	}else{
	rtreeCheckMapping(pCheck, 1, iVal, iNode);
	pCheck->nLeaf++;
	}
	}
	}
	}
	sqlite3_free(aNode);
	}
	}

	/*
	** The second argument to this function must be either "_rowid" or
	** "_parent". This function checks that the number of entries in the
	** %_rowid or %_parent table is exactly nExpect. If not, it adds
	** an error message to the report in the RtreeCheck object indicated
	** by the first argument.
	*/
	static void rtreeCheckCount(RtreeCheck pCheck, const char zTbl, i64 nExpect){
	if( pCheck->rc==SQLITE_OK ){
	sqlite3_stmt *pCount;
	pCount = rtreeCheckPrepare(pCheck, "SELECT count(*) FROM %Q.'%q%s'",
	pCheck->zDb, pCheck->zTab, zTbl
	);
	if( pCount ){
	if( sqlite3_step(pCount)==SQLITE_ROW ){
	i64 nActual = sqlite3_column_int64(pCount, 0);
	if( nActual!=nExpect ){
	rtreeCheckAppendMsg(pCheck, "Wrong number of entries in %%%s table"
	" - expected %lld, actual %lld" , zTbl, nExpect, nActual
	);
	}
	}
	pCheck->rc = sqlite3_finalize(pCount);
	}
	}
	}

	/*
	** This function does the bulk of the work for the rtree integrity-check.
	** It is called by rtreecheck(), which is the SQL function implementation.
	*/
	static int rtreeCheckTable(
	sqlite3 db, / Database handle to access db through */
	const char zDb, / Name of db ("main", "temp" etc.) */
	const char zTab, / Name of rtree table to check */
	char *pzReport / OUT: sqlite3_malloc'd report text */
	){
	RtreeCheck check; /* Common context for various routines */
	sqlite3_stmt pStmt = 0; / Used to find column count of rtree table */
	int nAux = 0; /* Number of extra columns. */

	/* Initialize the context object */
	memset(&check, 0, sizeof(check));
	check.db = db;
	check.zDb = zDb;
	check.zTab = zTab;

	/* Find the number of auxiliary columns */
	pStmt = rtreeCheckPrepare(&check, "SELECT * FROM %Q.'%q_rowid'", zDb, zTab);
	if( pStmt ){
	nAux = sqlite3_column_count(pStmt) - 2;
	sqlite3_finalize(pStmt);
	}else
	if( check.rc!=SQLITE_NOMEM ){
	check.rc = SQLITE_OK;
	}

	/* Find number of dimensions in the rtree table. */
	pStmt = rtreeCheckPrepare(&check, "SELECT * FROM %Q.%Q", zDb, zTab);
	if( pStmt ){
	int rc;
	check.nDim = (sqlite3_column_count(pStmt) - 1 - nAux) / 2;
	if( check.nDim<1 ){
	rtreeCheckAppendMsg(&check, "Schema corrupt or not an rtree");
	}else if( SQLITE_ROW==sqlite3_step(pStmt) ){
	check.bInt = (sqlite3_column_type(pStmt, 1)==SQLITE_INTEGER);
	}
	rc = sqlite3_finalize(pStmt);
	if( rc!=SQLITE_CORRUPT ) check.rc = rc;
	}

	/* Do the actual integrity-check */
	if( check.nDim>=1 ){
	if( check.rc==SQLITE_OK ){
	rtreeCheckNode(&check, 0, 0, 1);
	}
	rtreeCheckCount(&check, "_rowid", check.nLeaf);
	rtreeCheckCount(&check, "_parent", check.nNonLeaf);
	}

	/* Finalize SQL statements used by the integrity-check */
	sqlite3_finalize(check.pGetNode);
	sqlite3_finalize(check.aCheckMapping[0]);
	sqlite3_finalize(check.aCheckMapping[1]);

	*pzReport = check.zReport;
	return check.rc;
	}

	/*
	** Implementation of the xIntegrity method for Rtree.
	*/
	static int rtreeIntegrity(
	sqlite3_vtab pVtab, / The virtual table to check */
	const char zSchema, / Schema in which the virtual table lives */
	const char zName, / Name of the virtual table */
	int isQuick, /* True for a quick_check */
	char *pzErr / Write results here */
	){
	Rtree pRtree = (Rtree)pVtab;
	int rc;
	assert( pzErr!=0 && *pzErr==0 );
	UNUSED_PARAMETER(zSchema);
	UNUSED_PARAMETER(zName);
	UNUSED_PARAMETER(isQuick);
	rc = rtreeCheckTable(pRtree->db, pRtree->zDb, pRtree->zName, pzErr);
	if( rc==SQLITE_OK && *pzErr ){
	*pzErr = sqlite3_mprintf("In RTree %s.%s:\n%z",
	pRtree->zDb, pRtree->zName, *pzErr);
	if( (*pzErr)==0 ) rc = SQLITE_NOMEM;
	}
	return rc;
	}

	/*
	** Usage:
	**
	** rtreecheck(<rtree-table>);
	** rtreecheck(<database>, <rtree-table>);
	**
	** Invoking this SQL function runs an integrity-check on the named rtree
	** table. The integrity-check verifies the following:
	**
	** 1. For each cell in the r-tree structure (%_node table), that:
	**
	** a) for each dimension, (coord1 <= coord2).
	**
	** b) unless the cell is on the root node, that the cell is bounded
	** by the parent cell on the parent node.
	**
	** c) for leaf nodes, that there is an entry in the %_rowid
	** table corresponding to the cell's rowid value that
	** points to the correct node.
	**
	** d) for cells on non-leaf nodes, that there is an entry in the
	** %_parent table mapping from the cell's child node to the
	** node that it resides on.
	**
	** 2. That there are the same number of entries in the %_rowid table
	** as there are leaf cells in the r-tree structure, and that there
	** is a leaf cell that corresponds to each entry in the %_rowid table.
	**
	** 3. That there are the same number of entries in the %_parent table
	** as there are non-leaf cells in the r-tree structure, and that
	** there is a non-leaf cell that corresponds to each entry in the
	** %_parent table.
	*/
	static void rtreecheck(
	sqlite3_context *ctx,
	int nArg,
	sqlite3_value **apArg
	){
	if( nArg!=1 && nArg!=2 ){
	sqlite3_result_error(ctx,
	"wrong number of arguments to function rtreecheck()", -1
	);
	}else{
	int rc;
	char *zReport = 0;
	const char zDb = (const char)sqlite3_value_text(apArg[0]);
	const char *zTab;
	if( nArg==1 ){
	zTab = zDb;
	zDb = "main";
	}else{
	zTab = (const char*)sqlite3_value_text(apArg[1]);
	}
	rc = rtreeCheckTable(sqlite3_context_db_handle(ctx), zDb, zTab, &zReport);
	if( rc==SQLITE_OK ){
	sqlite3_result_text(ctx, zReport ? zReport : "ok", -1, SQLITE_TRANSIENT);
	}else{
	sqlite3_result_error_code(ctx, rc);
	}
	sqlite3_free(zReport);
	}
	}

	/* Conditionally include the geopoly code */
	#ifdef SQLITE_ENABLE_GEOPOLY
	# include "geopoly.c"
	#endif

	/*
	** Register the r-tree module with database handle db. This creates the
	** virtual table module "rtree" and the debugging/analysis scalar
	** function "rtreenode".
	*/
	int sqlite3RtreeInit(sqlite3 *db){
	const int utf8 = SQLITE_UTF8;
	int rc;

	rc = sqlite3_create_function(db, "rtreenode", 2, utf8, 0, rtreenode, 0, 0);
	if( rc==SQLITE_OK ){
	rc = sqlite3_create_function(db, "rtreedepth", 1, utf8, 0,rtreedepth, 0, 0);
	}
	if( rc==SQLITE_OK ){
	rc = sqlite3_create_function(db, "rtreecheck", -1, utf8, 0,rtreecheck, 0,0);
	}
	if( rc==SQLITE_OK ){
	#ifdef SQLITE_RTREE_INT_ONLY
	void c = (void )RTREE_COORD_INT32;
	#else
	void c = (void )RTREE_COORD_REAL32;
	#endif
	rc = sqlite3_create_module_v2(db, "rtree", &rtreeModule, c, 0);
	}
	if( rc==SQLITE_OK ){
	void c = (void )RTREE_COORD_INT32;
	rc = sqlite3_create_module_v2(db, "rtree_i32", &rtreeModule, c, 0);
	}
	#ifdef SQLITE_ENABLE_GEOPOLY
	if( rc==SQLITE_OK ){
	rc = sqlite3_geopoly_init(db);
	}
	#endif

	return rc;
	}

	/*
	** This routine deletes the RtreeGeomCallback object that was attached
	** one of the SQL functions create by sqlite3_rtree_geometry_callback()
	** or sqlite3_rtree_query_callback(). In other words, this routine is the
	** destructor for an RtreeGeomCallback objecct. This routine is called when
	** the corresponding SQL function is deleted.
	*/
	static void rtreeFreeCallback(void *p){
	RtreeGeomCallback pInfo = (RtreeGeomCallback)p;
	if( pInfo->xDestructor ) pInfo->xDestructor(pInfo->pContext);
	sqlite3_free(p);
	}

	/*
	** This routine frees the BLOB that is returned by geomCallback().
	*/
	static void rtreeMatchArgFree(void *pArg){
	int i;
	RtreeMatchArg p = (RtreeMatchArg)pArg;
	for(i=0; i<p->nParam; i++){
	sqlite3_value_free(p->apSqlParam[i]);
	}
	sqlite3_free(p);
	}

	/*
	** Each call to sqlite3_rtree_geometry_callback() or
	** sqlite3_rtree_query_callback() creates an ordinary SQLite
	** scalar function that is implemented by this routine.
	**
	** All this function does is construct an RtreeMatchArg object that
	** contains the geometry-checking callback routines and a list of
	** parameters to this function, then return that RtreeMatchArg object
	** as a BLOB.
	**
	** The R-Tree MATCH operator will read the returned BLOB, deserialize
	** the RtreeMatchArg object, and use the RtreeMatchArg object to figure
	** out which elements of the R-Tree should be returned by the query.
	*/
	static void geomCallback(sqlite3_context ctx, int nArg, sqlite3_value *aArg){
	RtreeGeomCallback pGeomCtx = (RtreeGeomCallback )sqlite3_user_data(ctx);
	RtreeMatchArg *pBlob;
	sqlite3_int64 nBlob;
	int memErr = 0;

	nBlob = sizeof(RtreeMatchArg) + (nArg-1)*sizeof(RtreeDValue)
	+ nArgsizeof(sqlite3_value);
	pBlob = (RtreeMatchArg *)sqlite3_malloc64(nBlob);
	if( !pBlob ){
	sqlite3_result_error_nomem(ctx);
	}else{
	int i;
	pBlob->iSize = nBlob;
	pBlob->cb = pGeomCtx[0];
	pBlob->apSqlParam = (sqlite3_value**)&pBlob->aParam[nArg];
	pBlob->nParam = nArg;
	for(i=0; i<nArg; i++){
	pBlob->apSqlParam[i] = sqlite3_value_dup(aArg[i]);
	if( pBlob->apSqlParam[i]==0 ) memErr = 1;
	#ifdef SQLITE_RTREE_INT_ONLY
	pBlob->aParam[i] = sqlite3_value_int64(aArg[i]);
	#else
	pBlob->aParam[i] = sqlite3_value_double(aArg[i]);
	#endif
	}
	if( memErr ){
	sqlite3_result_error_nomem(ctx);
	rtreeMatchArgFree(pBlob);
	}else{
	sqlite3_result_pointer(ctx, pBlob, "RtreeMatchArg", rtreeMatchArgFree);
	}
	}
	}

	/*
	** Register a new geometry function for use with the r-tree MATCH operator.
	*/
	int sqlite3_rtree_geometry_callback(
	sqlite3 db, / Register SQL function on this connection */
	const char zGeom, / Name of the new SQL function */
	int (xGeom)(sqlite3_rtree_geometry,int,RtreeDValue,int), /* Callback */
	void pContext / Extra data associated with the callback */
	){
	RtreeGeomCallback pGeomCtx; / Context object for new user-function */

	/* Allocate and populate the context object. */
	pGeomCtx = (RtreeGeomCallback *)sqlite3_malloc(sizeof(RtreeGeomCallback));
	if( !pGeomCtx ) return SQLITE_NOMEM;
	pGeomCtx->xGeom = xGeom;
	pGeomCtx->xQueryFunc = 0;
	pGeomCtx->xDestructor = 0;
	pGeomCtx->pContext = pContext;
	return sqlite3_create_function_v2(db, zGeom, -1, SQLITE_ANY,
	(void *)pGeomCtx, geomCallback, 0, 0, rtreeFreeCallback
	);
	}

	/*
	** Register a new 2nd-generation geometry function for use with the
	** r-tree MATCH operator.
	*/
	int sqlite3_rtree_query_callback(
	sqlite3 db, / Register SQL function on this connection */
	const char zQueryFunc, / Name of new SQL function */
	int (xQueryFunc)(sqlite3_rtree_query_info), /* Callback */
	void pContext, / Extra data passed into the callback */
	void (xDestructor)(void) /* Destructor for the extra data */
	){
	RtreeGeomCallback pGeomCtx; / Context object for new user-function */

	/* Allocate and populate the context object. */
	pGeomCtx = (RtreeGeomCallback *)sqlite3_malloc(sizeof(RtreeGeomCallback));
	if( !pGeomCtx ){
	if( xDestructor ) xDestructor(pContext);
	return SQLITE_NOMEM;
	}
	pGeomCtx->xGeom = 0;
	pGeomCtx->xQueryFunc = xQueryFunc;
	pGeomCtx->xDestructor = xDestructor;
	pGeomCtx->pContext = pContext;
	return sqlite3_create_function_v2(db, zQueryFunc, -1, SQLITE_ANY,
	(void *)pGeomCtx, geomCallback, 0, 0, rtreeFreeCallback
	);
	}

	#ifndef SQLITE_CORE
	#ifdef _WIN32
	__declspec(dllexport)
	#endif
	int sqlite3_rtree_init(
	sqlite3 *db,
	char **pzErrMsg,
	const sqlite3_api_routines *pApi
	){
	SQLITE_EXTENSION_INIT2(pApi)
	return sqlite3RtreeInit(db);
	}
	#endif

	#endif