};
+/*************************************************************************
+** The following three functions, found below:
+**
+** rbuDeltaGetInt()
+** rbuDeltaChecksum()
+** rbuDeltaApply()
+**
+** are lifted from the fossil source code (http://fossil-scm.org). They
+** are used to implement the scalar SQL function rbu_fossil_delta().
+*/
+
+/*
+** Read bytes from *pz and convert them into a positive integer. When
+** finished, leave *pz pointing to the first character past the end of
+** the integer. The *pLen parameter holds the length of the string
+** in *pz and is decremented once for each character in the integer.
+*/
+static unsigned int rbuDeltaGetInt(const char **pz, int *pLen){
+ static const signed char zValue[] = {
+ -1, -1, -1, -1, -1, -1, -1, -1, -1, -1, -1, -1, -1, -1, -1, -1,
+ -1, -1, -1, -1, -1, -1, -1, -1, -1, -1, -1, -1, -1, -1, -1, -1,
+ -1, -1, -1, -1, -1, -1, -1, -1, -1, -1, -1, -1, -1, -1, -1, -1,
+ 0, 1, 2, 3, 4, 5, 6, 7, 8, 9, -1, -1, -1, -1, -1, -1,
+ -1, 10, 11, 12, 13, 14, 15, 16, 17, 18, 19, 20, 21, 22, 23, 24,
+ 25, 26, 27, 28, 29, 30, 31, 32, 33, 34, 35, -1, -1, -1, -1, 36,
+ -1, 37, 38, 39, 40, 41, 42, 43, 44, 45, 46, 47, 48, 49, 50, 51,
+ 52, 53, 54, 55, 56, 57, 58, 59, 60, 61, 62, -1, -1, -1, 63, -1,
+ };
+ unsigned int v = 0;
+ int c;
+ unsigned char *z = (unsigned char*)*pz;
+ unsigned char *zStart = z;
+ while( (c = zValue[0x7f&*(z++)])>=0 ){
+ v = (v<<6) + c;
+ }
+ z--;
+ *pLen -= z - zStart;
+ *pz = (char*)z;
+ return v;
+}
+
+/*
+** Compute a 32-bit checksum on the N-byte buffer. Return the result.
+*/
+static unsigned int rbuDeltaChecksum(const char *zIn, size_t N){
+ const unsigned char *z = (const unsigned char *)zIn;
+ unsigned sum0 = 0;
+ unsigned sum1 = 0;
+ unsigned sum2 = 0;
+ unsigned sum3 = 0;
+ while(N >= 16){
+ sum0 += ((unsigned)z[0] + z[4] + z[8] + z[12]);
+ sum1 += ((unsigned)z[1] + z[5] + z[9] + z[13]);
+ sum2 += ((unsigned)z[2] + z[6] + z[10]+ z[14]);
+ sum3 += ((unsigned)z[3] + z[7] + z[11]+ z[15]);
+ z += 16;
+ N -= 16;
+ }
+ while(N >= 4){
+ sum0 += z[0];
+ sum1 += z[1];
+ sum2 += z[2];
+ sum3 += z[3];
+ z += 4;
+ N -= 4;
+ }
+ sum3 += (sum2 << 8) + (sum1 << 16) + (sum0 << 24);
+ switch(N){
+ case 3: sum3 += (z[2] << 8);
+ case 2: sum3 += (z[1] << 16);
+ case 1: sum3 += (z[0] << 24);
+ default: ;
+ }
+ return sum3;
+}
+
+/*
+** Apply a delta.
+**
+** The output buffer should be big enough to hold the whole output
+** file and a NUL terminator at the end. The delta_output_size()
+** routine will determine this size for you.
+**
+** The delta string should be null-terminated. But the delta string
+** may contain embedded NUL characters (if the input and output are
+** binary files) so we also have to pass in the length of the delta in
+** the lenDelta parameter.
+**
+** This function returns the size of the output file in bytes (excluding
+** the final NUL terminator character). Except, if the delta string is
+** malformed or intended for use with a source file other than zSrc,
+** then this routine returns -1.
+**
+** Refer to the delta_create() documentation above for a description
+** of the delta file format.
+*/
+static int rbuDeltaApply(
+ const char *zSrc, /* The source or pattern file */
+ int lenSrc, /* Length of the source file */
+ const char *zDelta, /* Delta to apply to the pattern */
+ int lenDelta, /* Length of the delta */
+ char *zOut /* Write the output into this preallocated buffer */
+){
+ unsigned int limit;
+ unsigned int total = 0;
+#ifndef FOSSIL_OMIT_DELTA_CKSUM_TEST
+ char *zOrigOut = zOut;
+#endif
+
+ limit = rbuDeltaGetInt(&zDelta, &lenDelta);
+ if( *zDelta!='\n' ){
+ /* ERROR: size integer not terminated by "\n" */
+ return -1;
+ }
+ zDelta++; lenDelta--;
+ while( *zDelta && lenDelta>0 ){
+ unsigned int cnt, ofst;
+ cnt = rbuDeltaGetInt(&zDelta, &lenDelta);
+ switch( zDelta[0] ){
+ case '@': {
+ zDelta++; lenDelta--;
+ ofst = rbuDeltaGetInt(&zDelta, &lenDelta);
+ if( lenDelta>0 && zDelta[0]!=',' ){
+ /* ERROR: copy command not terminated by ',' */
+ return -1;
+ }
+ zDelta++; lenDelta--;
+ total += cnt;
+ if( total>limit ){
+ /* ERROR: copy exceeds output file size */
+ return -1;
+ }
+ if( ofst+cnt > lenSrc ){
+ /* ERROR: copy extends past end of input */
+ return -1;
+ }
+ memcpy(zOut, &zSrc[ofst], cnt);
+ zOut += cnt;
+ break;
+ }
+ case ':': {
+ zDelta++; lenDelta--;
+ total += cnt;
+ if( total>limit ){
+ /* ERROR: insert command gives an output larger than predicted */
+ return -1;
+ }
+ if( cnt>lenDelta ){
+ /* ERROR: insert count exceeds size of delta */
+ return -1;
+ }
+ memcpy(zOut, zDelta, cnt);
+ zOut += cnt;
+ zDelta += cnt;
+ lenDelta -= cnt;
+ break;
+ }
+ case ';': {
+ zDelta++; lenDelta--;
+ zOut[0] = 0;
+#ifndef FOSSIL_OMIT_DELTA_CKSUM_TEST
+ if( cnt!=rbuDeltaChecksum(zOrigOut, total) ){
+ /* ERROR: bad checksum */
+ return -1;
+ }
+#endif
+ if( total!=limit ){
+ /* ERROR: generated size does not match predicted size */
+ return -1;
+ }
+ return total;
+ }
+ default: {
+ /* ERROR: unknown delta operator */
+ return -1;
+ }
+ }
+ }
+ /* ERROR: unterminated delta */
+ return -1;
+}
+
+static int rbuDeltaOutputSize(const char *zDelta, int lenDelta){
+ int size;
+ size = rbuDeltaGetInt(&zDelta, &lenDelta);
+ if( *zDelta!='\n' ){
+ /* ERROR: size integer not terminated by "\n" */
+ return -1;
+ }
+ return size;
+}
+
+/*
+** End of code taken from fossil.
+*************************************************************************/
+
+/*
+** Implementation of SQL scalar function rbu_fossil_delta().
+**
+** This function applies a fossil delta patch to a blob. Exactly two
+** arguments must be passed to this function. The first is the blob to
+** patch and the second the patch to apply. If no error occurs, this
+** function returns the patched blob.
+*/
+static void rbuFossilDeltaFunc(
+ sqlite3_context *context,
+ int argc,
+ sqlite3_value **argv
+){
+ const char *aDelta;
+ int nDelta;
+ const char *aOrig;
+ int nOrig;
+
+ int nOut;
+ int nOut2;
+ char *aOut;
+
+ assert( argc==2 );
+
+ nOrig = sqlite3_value_bytes(argv[0]);
+ aOrig = (const char*)sqlite3_value_blob(argv[0]);
+ nDelta = sqlite3_value_bytes(argv[1]);
+ aDelta = (const char*)sqlite3_value_blob(argv[1]);
+
+ /* Figure out the size of the output */
+ nOut = rbuDeltaOutputSize(aDelta, nDelta);
+ if( nOut<0 ){
+ sqlite3_result_error(context, "corrupt fossil delta", -1);
+ return;
+ }
+
+ aOut = sqlite3_malloc(nOut+1);
+ if( aOut==0 ){
+ sqlite3_result_error_nomem(context);
+ }else{
+ int nOut2 = rbuDeltaApply(aOrig, nOrig, aDelta, nDelta, aOut);
+ if( nOut2!=nOut ){
+ sqlite3_result_error(context, "corrupt fossil delta", -1);
+ }else{
+ sqlite3_result_blob(context, aOut, nOut, sqlite3_free);
+ }
+ }
+}
+
+
/*
** Prepare the SQL statement in buffer zSql against database handle db.
** If successful, set *ppStmt to point to the new statement and return
);
zSep = ", ";
}
- if( c=='d' ){
+ else if( c=='d' ){
zList = rbuMPrintf(p, "%z%s\"%w\"=rbu_delta(\"%w\", ?%d)",
zList, zSep, pIter->azTblCol[i], pIter->azTblCol[i], i+1
);
zSep = ", ";
}
+ else if( c=='f' ){
+ zList = rbuMPrintf(p, "%z%s\"%w\"=rbu_fossil_delta(\"%w\", ?%d)",
+ zList, zSep, pIter->azTblCol[i], pIter->azTblCol[i], i+1
+ );
+ zSep = ", ";
+ }
}
}
}
);
}
+ if( p->rc==SQLITE_OK ){
+ p->rc = sqlite3_create_function(p->dbMain,
+ "rbu_fossil_delta", 2, SQLITE_UTF8, 0, rbuFossilDeltaFunc, 0, 0
+ );
+ }
+
if( p->rc==SQLITE_OK ){
p->rc = sqlite3_create_function(p->dbRbu,
"rbu_target_name", 1, SQLITE_UTF8, (void*)p, rbuTargetNameFunc, 0, 0
for(i=0; p->rc==SQLITE_OK && i<pIter->nCol; i++){
char c = zMask[pIter->aiSrcOrder[i]];
pVal = sqlite3_column_value(pIter->pSelect, i);
- if( pIter->abTblPk[i] || c=='x' || c=='d' ){
+ if( pIter->abTblPk[i] || c!='.' ){
p->rc = sqlite3_bind_value(pUpdate, i+1, pVal);
}
}
#include <stdarg.h>
#include <ctype.h>
#include <string.h>
+#include <assert.h>
#include "sqlite3.h"
/*
sqlite3_finalize(pStmt);
}
+/**************************************************************************
+** The following code is copied from fossil. It is used to generate the
+** fossil delta blobs sometimes used in RBU update records.
+*/
+
+typedef unsigned short u16;
+typedef unsigned int u32;
+typedef unsigned char u8;
+
+/*
+** The width of a hash window in bytes. The algorithm only works if this
+** is a power of 2.
+*/
+#define NHASH 16
+
+/*
+** The current state of the rolling hash.
+**
+** z[] holds the values that have been hashed. z[] is a circular buffer.
+** z[i] is the first entry and z[(i+NHASH-1)%NHASH] is the last entry of
+** the window.
+**
+** Hash.a is the sum of all elements of hash.z[]. Hash.b is a weighted
+** sum. Hash.b is z[i]*NHASH + z[i+1]*(NHASH-1) + ... + z[i+NHASH-1]*1.
+** (Each index for z[] should be module NHASH, of course. The %NHASH operator
+** is omitted in the prior expression for brevity.)
+*/
+typedef struct hash hash;
+struct hash {
+ u16 a, b; /* Hash values */
+ u16 i; /* Start of the hash window */
+ char z[NHASH]; /* The values that have been hashed */
+};
+
+/*
+** Initialize the rolling hash using the first NHASH characters of z[]
+*/
+static void hash_init(hash *pHash, const char *z){
+ u16 a, b, i;
+ a = b = 0;
+ for(i=0; i<NHASH; i++){
+ a += z[i];
+ b += (NHASH-i)*z[i];
+ pHash->z[i] = z[i];
+ }
+ pHash->a = a & 0xffff;
+ pHash->b = b & 0xffff;
+ pHash->i = 0;
+}
+
+/*
+** Advance the rolling hash by a single character "c"
+*/
+static void hash_next(hash *pHash, int c){
+ u16 old = pHash->z[pHash->i];
+ pHash->z[pHash->i] = c;
+ pHash->i = (pHash->i+1)&(NHASH-1);
+ pHash->a = pHash->a - old + c;
+ pHash->b = pHash->b - NHASH*old + pHash->a;
+}
+
+/*
+** Return a 32-bit hash value
+*/
+static u32 hash_32bit(hash *pHash){
+ return (pHash->a & 0xffff) | (((u32)(pHash->b & 0xffff))<<16);
+}
+
+/*
+** Write an base-64 integer into the given buffer.
+*/
+static void putInt(unsigned int v, char **pz){
+ static const char zDigits[] =
+ "0123456789ABCDEFGHIJKLMNOPQRSTUVWXYZ_abcdefghijklmnopqrstuvwxyz~";
+ /* 123456789 123456789 123456789 123456789 123456789 123456789 123 */
+ int i, j;
+ char zBuf[20];
+ if( v==0 ){
+ *(*pz)++ = '0';
+ return;
+ }
+ for(i=0; v>0; i++, v>>=6){
+ zBuf[i] = zDigits[v&0x3f];
+ }
+ for(j=i-1; j>=0; j--){
+ *(*pz)++ = zBuf[j];
+ }
+}
+
+/*
+** Read bytes from *pz and convert them into a positive integer. When
+** finished, leave *pz pointing to the first character past the end of
+** the integer. The *pLen parameter holds the length of the string
+** in *pz and is decremented once for each character in the integer.
+*/
+static unsigned int getInt(const char **pz, int *pLen){
+ static const signed char zValue[] = {
+ -1, -1, -1, -1, -1, -1, -1, -1, -1, -1, -1, -1, -1, -1, -1, -1,
+ -1, -1, -1, -1, -1, -1, -1, -1, -1, -1, -1, -1, -1, -1, -1, -1,
+ -1, -1, -1, -1, -1, -1, -1, -1, -1, -1, -1, -1, -1, -1, -1, -1,
+ 0, 1, 2, 3, 4, 5, 6, 7, 8, 9, -1, -1, -1, -1, -1, -1,
+ -1, 10, 11, 12, 13, 14, 15, 16, 17, 18, 19, 20, 21, 22, 23, 24,
+ 25, 26, 27, 28, 29, 30, 31, 32, 33, 34, 35, -1, -1, -1, -1, 36,
+ -1, 37, 38, 39, 40, 41, 42, 43, 44, 45, 46, 47, 48, 49, 50, 51,
+ 52, 53, 54, 55, 56, 57, 58, 59, 60, 61, 62, -1, -1, -1, 63, -1,
+ };
+ unsigned int v = 0;
+ int c;
+ unsigned char *z = (unsigned char*)*pz;
+ unsigned char *zStart = z;
+ while( (c = zValue[0x7f&*(z++)])>=0 ){
+ v = (v<<6) + c;
+ }
+ z--;
+ *pLen -= z - zStart;
+ *pz = (char*)z;
+ return v;
+}
+
+/*
+** Return the number digits in the base-64 representation of a positive integer
+*/
+static int digit_count(int v){
+ unsigned int i, x;
+ for(i=1, x=64; v>=x; i++, x <<= 6){}
+ return i;
+}
+
+/*
+** Compute a 32-bit checksum on the N-byte buffer. Return the result.
+*/
+static unsigned int checksum(const char *zIn, size_t N){
+ const unsigned char *z = (const unsigned char *)zIn;
+ unsigned sum0 = 0;
+ unsigned sum1 = 0;
+ unsigned sum2 = 0;
+ unsigned sum3 = 0;
+ while(N >= 16){
+ sum0 += ((unsigned)z[0] + z[4] + z[8] + z[12]);
+ sum1 += ((unsigned)z[1] + z[5] + z[9] + z[13]);
+ sum2 += ((unsigned)z[2] + z[6] + z[10]+ z[14]);
+ sum3 += ((unsigned)z[3] + z[7] + z[11]+ z[15]);
+ z += 16;
+ N -= 16;
+ }
+ while(N >= 4){
+ sum0 += z[0];
+ sum1 += z[1];
+ sum2 += z[2];
+ sum3 += z[3];
+ z += 4;
+ N -= 4;
+ }
+ sum3 += (sum2 << 8) + (sum1 << 16) + (sum0 << 24);
+ switch(N){
+ case 3: sum3 += (z[2] << 8);
+ case 2: sum3 += (z[1] << 16);
+ case 1: sum3 += (z[0] << 24);
+ default: ;
+ }
+ return sum3;
+}
+
+/*
+** Create a new delta.
+**
+** The delta is written into a preallocated buffer, zDelta, which
+** should be at least 60 bytes longer than the target file, zOut.
+** The delta string will be NUL-terminated, but it might also contain
+** embedded NUL characters if either the zSrc or zOut files are
+** binary. This function returns the length of the delta string
+** in bytes, excluding the final NUL terminator character.
+**
+** Output Format:
+**
+** The delta begins with a base64 number followed by a newline. This
+** number is the number of bytes in the TARGET file. Thus, given a
+** delta file z, a program can compute the size of the output file
+** simply by reading the first line and decoding the base-64 number
+** found there. The delta_output_size() routine does exactly this.
+**
+** After the initial size number, the delta consists of a series of
+** literal text segments and commands to copy from the SOURCE file.
+** A copy command looks like this:
+**
+** NNN@MMM,
+**
+** where NNN is the number of bytes to be copied and MMM is the offset
+** into the source file of the first byte (both base-64). If NNN is 0
+** it means copy the rest of the input file. Literal text is like this:
+**
+** NNN:TTTTT
+**
+** where NNN is the number of bytes of text (base-64) and TTTTT is the text.
+**
+** The last term is of the form
+**
+** NNN;
+**
+** In this case, NNN is a 32-bit bigendian checksum of the output file
+** that can be used to verify that the delta applied correctly. All
+** numbers are in base-64.
+**
+** Pure text files generate a pure text delta. Binary files generate a
+** delta that may contain some binary data.
+**
+** Algorithm:
+**
+** The encoder first builds a hash table to help it find matching
+** patterns in the source file. 16-byte chunks of the source file
+** sampled at evenly spaced intervals are used to populate the hash
+** table.
+**
+** Next we begin scanning the target file using a sliding 16-byte
+** window. The hash of the 16-byte window in the target is used to
+** search for a matching section in the source file. When a match
+** is found, a copy command is added to the delta. An effort is
+** made to extend the matching section to regions that come before
+** and after the 16-byte hash window. A copy command is only issued
+** if the result would use less space that just quoting the text
+** literally. Literal text is added to the delta for sections that
+** do not match or which can not be encoded efficiently using copy
+** commands.
+*/
+static int rbuDeltaCreate(
+ const char *zSrc, /* The source or pattern file */
+ unsigned int lenSrc, /* Length of the source file */
+ const char *zOut, /* The target file */
+ unsigned int lenOut, /* Length of the target file */
+ char *zDelta /* Write the delta into this buffer */
+){
+ int i, base;
+ char *zOrigDelta = zDelta;
+ hash h;
+ int nHash; /* Number of hash table entries */
+ int *landmark; /* Primary hash table */
+ int *collide; /* Collision chain */
+ int lastRead = -1; /* Last byte of zSrc read by a COPY command */
+
+ /* Add the target file size to the beginning of the delta
+ */
+ putInt(lenOut, &zDelta);
+ *(zDelta++) = '\n';
+
+ /* If the source file is very small, it means that we have no
+ ** chance of ever doing a copy command. Just output a single
+ ** literal segment for the entire target and exit.
+ */
+ if( lenSrc<=NHASH ){
+ putInt(lenOut, &zDelta);
+ *(zDelta++) = ':';
+ memcpy(zDelta, zOut, lenOut);
+ zDelta += lenOut;
+ putInt(checksum(zOut, lenOut), &zDelta);
+ *(zDelta++) = ';';
+ return zDelta - zOrigDelta;
+ }
+
+ /* Compute the hash table used to locate matching sections in the
+ ** source file.
+ */
+ nHash = lenSrc/NHASH;
+ collide = sqlite3_malloc( nHash*2*sizeof(int) );
+ landmark = &collide[nHash];
+ memset(landmark, -1, nHash*sizeof(int));
+ memset(collide, -1, nHash*sizeof(int));
+ for(i=0; i<lenSrc-NHASH; i+=NHASH){
+ int hv;
+ hash_init(&h, &zSrc[i]);
+ hv = hash_32bit(&h) % nHash;
+ collide[i/NHASH] = landmark[hv];
+ landmark[hv] = i/NHASH;
+ }
+
+ /* Begin scanning the target file and generating copy commands and
+ ** literal sections of the delta.
+ */
+ base = 0; /* We have already generated everything before zOut[base] */
+ while( base+NHASH<lenOut ){
+ int iSrc, iBlock;
+ unsigned int bestCnt, bestOfst=0, bestLitsz=0;
+ hash_init(&h, &zOut[base]);
+ i = 0; /* Trying to match a landmark against zOut[base+i] */
+ bestCnt = 0;
+ while( 1 ){
+ int hv;
+ int limit = 250;
+
+ hv = hash_32bit(&h) % nHash;
+ iBlock = landmark[hv];
+ while( iBlock>=0 && (limit--)>0 ){
+ /*
+ ** The hash window has identified a potential match against
+ ** landmark block iBlock. But we need to investigate further.
+ **
+ ** Look for a region in zOut that matches zSrc. Anchor the search
+ ** at zSrc[iSrc] and zOut[base+i]. Do not include anything prior to
+ ** zOut[base] or after zOut[outLen] nor anything after zSrc[srcLen].
+ **
+ ** Set cnt equal to the length of the match and set ofst so that
+ ** zSrc[ofst] is the first element of the match. litsz is the number
+ ** of characters between zOut[base] and the beginning of the match.
+ ** sz will be the overhead (in bytes) needed to encode the copy
+ ** command. Only generate copy command if the overhead of the
+ ** copy command is less than the amount of literal text to be copied.
+ */
+ int cnt, ofst, litsz;
+ int j, k, x, y;
+ int sz;
+
+ /* Beginning at iSrc, match forwards as far as we can. j counts
+ ** the number of characters that match */
+ iSrc = iBlock*NHASH;
+ for(j=0, x=iSrc, y=base+i; x<lenSrc && y<lenOut; j++, x++, y++){
+ if( zSrc[x]!=zOut[y] ) break;
+ }
+ j--;
+
+ /* Beginning at iSrc-1, match backwards as far as we can. k counts
+ ** the number of characters that match */
+ for(k=1; k<iSrc && k<=i; k++){
+ if( zSrc[iSrc-k]!=zOut[base+i-k] ) break;
+ }
+ k--;
+
+ /* Compute the offset and size of the matching region */
+ ofst = iSrc-k;
+ cnt = j+k+1;
+ litsz = i-k; /* Number of bytes of literal text before the copy */
+ /* sz will hold the number of bytes needed to encode the "insert"
+ ** command and the copy command, not counting the "insert" text */
+ sz = digit_count(i-k)+digit_count(cnt)+digit_count(ofst)+3;
+ if( cnt>=sz && cnt>bestCnt ){
+ /* Remember this match only if it is the best so far and it
+ ** does not increase the file size */
+ bestCnt = cnt;
+ bestOfst = iSrc-k;
+ bestLitsz = litsz;
+ }
+
+ /* Check the next matching block */
+ iBlock = collide[iBlock];
+ }
+
+ /* We have a copy command that does not cause the delta to be larger
+ ** than a literal insert. So add the copy command to the delta.
+ */
+ if( bestCnt>0 ){
+ if( bestLitsz>0 ){
+ /* Add an insert command before the copy */
+ putInt(bestLitsz,&zDelta);
+ *(zDelta++) = ':';
+ memcpy(zDelta, &zOut[base], bestLitsz);
+ zDelta += bestLitsz;
+ base += bestLitsz;
+ }
+ base += bestCnt;
+ putInt(bestCnt, &zDelta);
+ *(zDelta++) = '@';
+ putInt(bestOfst, &zDelta);
+ *(zDelta++) = ',';
+ if( bestOfst + bestCnt -1 > lastRead ){
+ lastRead = bestOfst + bestCnt - 1;
+ }
+ bestCnt = 0;
+ break;
+ }
+
+ /* If we reach this point, it means no match is found so far */
+ if( base+i+NHASH>=lenOut ){
+ /* We have reached the end of the file and have not found any
+ ** matches. Do an "insert" for everything that does not match */
+ putInt(lenOut-base, &zDelta);
+ *(zDelta++) = ':';
+ memcpy(zDelta, &zOut[base], lenOut-base);
+ zDelta += lenOut-base;
+ base = lenOut;
+ break;
+ }
+
+ /* Advance the hash by one character. Keep looking for a match */
+ hash_next(&h, zOut[base+i+NHASH]);
+ i++;
+ }
+ }
+ /* Output a final "insert" record to get all the text at the end of
+ ** the file that does not match anything in the source file.
+ */
+ if( base<lenOut ){
+ putInt(lenOut-base, &zDelta);
+ *(zDelta++) = ':';
+ memcpy(zDelta, &zOut[base], lenOut-base);
+ zDelta += lenOut-base;
+ }
+ /* Output the final checksum record. */
+ putInt(checksum(zOut, lenOut), &zDelta);
+ *(zDelta++) = ';';
+ sqlite3_free(collide);
+ return zDelta - zOrigDelta;
+}
+
+/*
+** End of code copied from fossil.
+**************************************************************************/
+
static void strPrintfArray(
Str *pStr, /* String object to append to */
const char *zSep, /* Separator string */
/* First the newly inserted rows: **/
strPrintf(pSql, "SELECT ");
strPrintfArray(pSql, ", ", "%s", azCol, -1);
- strPrintf(pSql, ", 0"); /* Set ota_control to 0 for an insert */
+ strPrintf(pSql, ", 0, "); /* Set ota_control to 0 for an insert */
+ strPrintfArray(pSql, ", ", "NULL", azCol, -1);
strPrintf(pSql, " FROM aux.%Q AS n WHERE NOT EXISTS (\n", zTab);
strPrintf(pSql, " SELECT 1 FROM ", zTab);
strPrintf(pSql, " main.%Q AS o WHERE ", zTab);
strPrintf(pSql, ", ");
strPrintfArray(pSql, ", ", "NULL", &azCol[nPK], -1);
}
- strPrintf(pSql, ", 1"); /* Set ota_control to 1 for a delete */
+ strPrintf(pSql, ", 1, "); /* Set ota_control to 1 for a delete */
+ strPrintfArray(pSql, ", ", "NULL", azCol, -1);
strPrintf(pSql, " FROM main.%Q AS n WHERE NOT EXISTS (\n", zTab);
strPrintf(pSql, " SELECT 1 FROM ", zTab);
strPrintf(pSql, " aux.%Q AS o WHERE ", zTab);
strPrintfArray(pSql, " ||\n",
" CASE WHEN n.%s IS o.%s THEN '.' ELSE 'x' END", &azCol[nPK], -1
);
- strPrintf(pSql, "\nAS ota_control");
+ strPrintf(pSql, "\nAS ota_control, ");
+ strPrintfArray(pSql, ", ", "NULL", azCol, nPK);
+ strPrintf(pSql, ",\n");
+ strPrintfArray(pSql, " ,\n",
+ " CASE WHEN n.%s IS o.%s THEN NULL ELSE o.%s END", &azCol[nPK], -1
+ );
strPrintf(pSql, "\nFROM main.%Q AS o, aux.%Q AS n\nWHERE ", zTab, zTab);
strPrintfArray(pSql, " AND ", "(n.%Q IS o.%Q)", azCol, nPK);
if( azCol==0 ){
runtimeError("table %s has no usable PK columns", zTab);
}
+ for(nCol=0; azCol[nCol]; nCol++);
/* Build and output the CREATE TABLE statement for the data_xxx table */
strPrintf(&ct, "CREATE TABLE IF NOT EXISTS 'data_%q'(", zTab);
strPrintfArray(&ct, ", ", "%s", &azCol[bOtaRowid], -1);
strPrintf(&ct, ", rbu_control);");
-
/* Get the SQL for the query to retrieve data from the two databases */
getRbudiffQuery(zTab, azCol, nPK, bOtaRowid, &sql);
strPrintf(&insert, ", rbu_control) VALUES(");
pStmt = db_prepare("%s", sql.z);
- nCol = sqlite3_column_count(pStmt);
+
while( sqlite3_step(pStmt)==SQLITE_ROW ){
+
+ /* If this is the first row output, print out the CREATE TABLE
+ ** statement first. And then set ct.z to NULL so that it is not
+ ** printed again. */
if( ct.z ){
fprintf(out, "%s\n", ct.z);
strFree(&ct);
}
+ /* Output the first part of the INSERT statement */
fprintf(out, "%s", insert.z);
- for(i=0; i<nCol; i++){
- if( i>0 ) fprintf(out, ", ");
- printQuoted(out, sqlite3_column_value(pStmt, i));
+
+ if( sqlite3_column_type(pStmt, nCol)==SQLITE_INTEGER ){
+ for(i=0; i<=nCol; i++){
+ if( i>0 ) fprintf(out, ", ");
+ printQuoted(out, sqlite3_column_value(pStmt, i));
+ }
+ }else{
+ char *zOtaControl;
+ int nOtaControl = sqlite3_column_bytes(pStmt, nCol);
+
+ zOtaControl = (char*)sqlite3_malloc(nOtaControl);
+ memcpy(zOtaControl, sqlite3_column_text(pStmt, nCol), nOtaControl+1);
+
+ for(i=0; i<nCol; i++){
+ int bDone = 0;
+ if( i>=nPK
+ && sqlite3_column_type(pStmt, i)==SQLITE_BLOB
+ && sqlite3_column_type(pStmt, nCol+1+i)==SQLITE_BLOB
+ ){
+ const char *aSrc = sqlite3_column_blob(pStmt, nCol+1+i);
+ int nSrc = sqlite3_column_bytes(pStmt, nCol+1+i);
+ const char *aFinal = sqlite3_column_blob(pStmt, i);
+ int nFinal = sqlite3_column_bytes(pStmt, i);
+ char *aDelta;
+ int nDelta;
+
+ aDelta = sqlite3_malloc(nFinal + 60);
+ nDelta = rbuDeltaCreate(aSrc, nSrc, aFinal, nFinal, aDelta);
+ if( nDelta<nFinal ){
+ int j;
+ fprintf(out, "x'");
+ for(j=0; j<nDelta; j++) fprintf(out, "%02x", (u8)aDelta[j]);
+ fprintf(out, "'");
+ zOtaControl[i-bOtaRowid] = 'f';
+ bDone = 1;
+ }
+ sqlite3_free(aDelta);
+ }
+
+ if( bDone==0 ){
+ printQuoted(out, sqlite3_column_value(pStmt, i));
+ }
+ fprintf(out, ", ");
+ }
+ fprintf(out, "'%s'", zOtaControl);
+ sqlite3_free(zOtaControl);
}
+
+ /* And the closing bracket of the insert statement */
fprintf(out, ");\n");
}
projects / thirdparty / sqlite.git / commitdiff
