In the 'swarmvtabfault' test module, make sure to close the database handle prior...
[sqlite.git] / tool / sqldiff.c
blobb31489bfd7d318eedbdb824cac29ead629b3f6a9
1 /*
2 ** 2015-04-06
3 **
4 ** The author disclaims copyright to this source code. In place of
5 ** a legal notice, here is a blessing:
6 **
7 ** May you do good and not evil.
8 ** May you find forgiveness for yourself and forgive others.
9 ** May you share freely, never taking more than you give.
11 *************************************************************************
13 ** This is a utility program that computes the differences in content
14 ** between two SQLite databases.
16 ** To compile, simply link against SQLite.
18 ** See the showHelp() routine below for a brief description of how to
19 ** run the utility.
21 #include <stdio.h>
22 #include <stdlib.h>
23 #include <stdarg.h>
24 #include <ctype.h>
25 #include <string.h>
26 #include <assert.h>
27 #include "sqlite3.h"
30 ** All global variables are gathered into the "g" singleton.
32 struct GlobalVars {
33 const char *zArgv0; /* Name of program */
34 int bSchemaOnly; /* Only show schema differences */
35 int bSchemaPK; /* Use the schema-defined PK, not the true PK */
36 int bHandleVtab; /* Handle fts3, fts4, fts5 and rtree vtabs */
37 unsigned fDebug; /* Debug flags */
38 sqlite3 *db; /* The database connection */
39 } g;
42 ** Allowed values for g.fDebug
44 #define DEBUG_COLUMN_NAMES 0x000001
45 #define DEBUG_DIFF_SQL 0x000002
48 ** Dynamic string object
50 typedef struct Str Str;
51 struct Str {
52 char *z; /* Text of the string */
53 int nAlloc; /* Bytes allocated in z[] */
54 int nUsed; /* Bytes actually used in z[] */
58 ** Initialize a Str object
60 static void strInit(Str *p){
61 p->z = 0;
62 p->nAlloc = 0;
63 p->nUsed = 0;
67 ** Print an error resulting from faulting command-line arguments and
68 ** abort the program.
70 static void cmdlineError(const char *zFormat, ...){
71 va_list ap;
72 fprintf(stderr, "%s: ", g.zArgv0);
73 va_start(ap, zFormat);
74 vfprintf(stderr, zFormat, ap);
75 va_end(ap);
76 fprintf(stderr, "\n\"%s --help\" for more help\n", g.zArgv0);
77 exit(1);
81 ** Print an error message for an error that occurs at runtime, then
82 ** abort the program.
84 static void runtimeError(const char *zFormat, ...){
85 va_list ap;
86 fprintf(stderr, "%s: ", g.zArgv0);
87 va_start(ap, zFormat);
88 vfprintf(stderr, zFormat, ap);
89 va_end(ap);
90 fprintf(stderr, "\n");
91 exit(1);
95 ** Free all memory held by a Str object
97 static void strFree(Str *p){
98 sqlite3_free(p->z);
99 strInit(p);
103 ** Add formatted text to the end of a Str object
105 static void strPrintf(Str *p, const char *zFormat, ...){
106 int nNew;
107 for(;;){
108 if( p->z ){
109 va_list ap;
110 va_start(ap, zFormat);
111 sqlite3_vsnprintf(p->nAlloc-p->nUsed, p->z+p->nUsed, zFormat, ap);
112 va_end(ap);
113 nNew = (int)strlen(p->z + p->nUsed);
114 }else{
115 nNew = p->nAlloc;
117 if( p->nUsed+nNew < p->nAlloc-1 ){
118 p->nUsed += nNew;
119 break;
121 p->nAlloc = p->nAlloc*2 + 1000;
122 p->z = sqlite3_realloc(p->z, p->nAlloc);
123 if( p->z==0 ) runtimeError("out of memory");
129 /* Safely quote an SQL identifier. Use the minimum amount of transformation
130 ** necessary to allow the string to be used with %s.
132 ** Space to hold the returned string is obtained from sqlite3_malloc(). The
133 ** caller is responsible for ensuring this space is freed when no longer
134 ** needed.
136 static char *safeId(const char *zId){
137 /* All SQLite keywords, in alphabetical order */
138 static const char *azKeywords[] = {
139 "ABORT", "ACTION", "ADD", "AFTER", "ALL", "ALTER", "ANALYZE", "AND", "AS",
140 "ASC", "ATTACH", "AUTOINCREMENT", "BEFORE", "BEGIN", "BETWEEN", "BY",
141 "CASCADE", "CASE", "CAST", "CHECK", "COLLATE", "COLUMN", "COMMIT",
142 "CONFLICT", "CONSTRAINT", "CREATE", "CROSS", "CURRENT_DATE",
143 "CURRENT_TIME", "CURRENT_TIMESTAMP", "DATABASE", "DEFAULT", "DEFERRABLE",
144 "DEFERRED", "DELETE", "DESC", "DETACH", "DISTINCT", "DROP", "EACH",
145 "ELSE", "END", "ESCAPE", "EXCEPT", "EXCLUSIVE", "EXISTS", "EXPLAIN",
146 "FAIL", "FOR", "FOREIGN", "FROM", "FULL", "GLOB", "GROUP", "HAVING", "IF",
147 "IGNORE", "IMMEDIATE", "IN", "INDEX", "INDEXED", "INITIALLY", "INNER",
148 "INSERT", "INSTEAD", "INTERSECT", "INTO", "IS", "ISNULL", "JOIN", "KEY",
149 "LEFT", "LIKE", "LIMIT", "MATCH", "NATURAL", "NO", "NOT", "NOTNULL",
150 "NULL", "OF", "OFFSET", "ON", "OR", "ORDER", "OUTER", "PLAN", "PRAGMA",
151 "PRIMARY", "QUERY", "RAISE", "RECURSIVE", "REFERENCES", "REGEXP",
152 "REINDEX", "RELEASE", "RENAME", "REPLACE", "RESTRICT", "RIGHT",
153 "ROLLBACK", "ROW", "SAVEPOINT", "SELECT", "SET", "TABLE", "TEMP",
154 "TEMPORARY", "THEN", "TO", "TRANSACTION", "TRIGGER", "UNION", "UNIQUE",
155 "UPDATE", "USING", "VACUUM", "VALUES", "VIEW", "VIRTUAL", "WHEN", "WHERE",
156 "WITH", "WITHOUT",
158 int lwr, upr, mid, c, i, x;
159 if( zId[0]==0 ) return sqlite3_mprintf("\"\"");
160 for(i=x=0; (c = zId[i])!=0; i++){
161 if( !isalpha(c) && c!='_' ){
162 if( i>0 && isdigit(c) ){
163 x++;
164 }else{
165 return sqlite3_mprintf("\"%w\"", zId);
169 if( x ) return sqlite3_mprintf("%s", zId);
170 lwr = 0;
171 upr = sizeof(azKeywords)/sizeof(azKeywords[0]) - 1;
172 while( lwr<=upr ){
173 mid = (lwr+upr)/2;
174 c = sqlite3_stricmp(azKeywords[mid], zId);
175 if( c==0 ) return sqlite3_mprintf("\"%w\"", zId);
176 if( c<0 ){
177 lwr = mid+1;
178 }else{
179 upr = mid-1;
182 return sqlite3_mprintf("%s", zId);
186 ** Prepare a new SQL statement. Print an error and abort if anything
187 ** goes wrong.
189 static sqlite3_stmt *db_vprepare(const char *zFormat, va_list ap){
190 char *zSql;
191 int rc;
192 sqlite3_stmt *pStmt;
194 zSql = sqlite3_vmprintf(zFormat, ap);
195 if( zSql==0 ) runtimeError("out of memory");
196 rc = sqlite3_prepare_v2(g.db, zSql, -1, &pStmt, 0);
197 if( rc ){
198 runtimeError("SQL statement error: %s\n\"%s\"", sqlite3_errmsg(g.db),
199 zSql);
201 sqlite3_free(zSql);
202 return pStmt;
204 static sqlite3_stmt *db_prepare(const char *zFormat, ...){
205 va_list ap;
206 sqlite3_stmt *pStmt;
207 va_start(ap, zFormat);
208 pStmt = db_vprepare(zFormat, ap);
209 va_end(ap);
210 return pStmt;
214 ** Free a list of strings
216 static void namelistFree(char **az){
217 if( az ){
218 int i;
219 for(i=0; az[i]; i++) sqlite3_free(az[i]);
220 sqlite3_free(az);
225 ** Return a list of column names for the table zDb.zTab. Space to
226 ** hold the list is obtained from sqlite3_malloc() and should released
227 ** using namelistFree() when no longer needed.
229 ** Primary key columns are listed first, followed by data columns.
230 ** The number of columns in the primary key is returned in *pnPkey.
232 ** Normally, the "primary key" in the previous sentence is the true
233 ** primary key - the rowid or INTEGER PRIMARY KEY for ordinary tables
234 ** or the declared PRIMARY KEY for WITHOUT ROWID tables. However, if
235 ** the g.bSchemaPK flag is set, then the schema-defined PRIMARY KEY is
236 ** used in all cases. In that case, entries that have NULL values in
237 ** any of their primary key fields will be excluded from the analysis.
239 ** If the primary key for a table is the rowid but rowid is inaccessible,
240 ** then this routine returns a NULL pointer.
242 ** Examples:
243 ** CREATE TABLE t1(a INT UNIQUE, b INTEGER, c TEXT, PRIMARY KEY(c));
244 ** *pnPKey = 1;
245 ** az = { "rowid", "a", "b", "c", 0 } // Normal case
246 ** az = { "c", "a", "b", 0 } // g.bSchemaPK==1
248 ** CREATE TABLE t2(a INT UNIQUE, b INTEGER, c TEXT, PRIMARY KEY(b));
249 ** *pnPKey = 1;
250 ** az = { "b", "a", "c", 0 }
252 ** CREATE TABLE t3(x,y,z,PRIMARY KEY(y,z));
253 ** *pnPKey = 1 // Normal case
254 ** az = { "rowid", "x", "y", "z", 0 } // Normal case
255 ** *pnPKey = 2 // g.bSchemaPK==1
256 ** az = { "y", "x", "z", 0 } // g.bSchemaPK==1
258 ** CREATE TABLE t4(x,y,z,PRIMARY KEY(y,z)) WITHOUT ROWID;
259 ** *pnPKey = 2
260 ** az = { "y", "z", "x", 0 }
262 ** CREATE TABLE t5(rowid,_rowid_,oid);
263 ** az = 0 // The rowid is not accessible
265 static char **columnNames(
266 const char *zDb, /* Database ("main" or "aux") to query */
267 const char *zTab, /* Name of table to return details of */
268 int *pnPKey, /* OUT: Number of PK columns */
269 int *pbRowid /* OUT: True if PK is an implicit rowid */
271 char **az = 0; /* List of column names to be returned */
272 int naz = 0; /* Number of entries in az[] */
273 sqlite3_stmt *pStmt; /* SQL statement being run */
274 char *zPkIdxName = 0; /* Name of the PRIMARY KEY index */
275 int truePk = 0; /* PRAGMA table_info indentifies the PK to use */
276 int nPK = 0; /* Number of PRIMARY KEY columns */
277 int i, j; /* Loop counters */
279 if( g.bSchemaPK==0 ){
280 /* Normal case: Figure out what the true primary key is for the table.
281 ** * For WITHOUT ROWID tables, the true primary key is the same as
282 ** the schema PRIMARY KEY, which is guaranteed to be present.
283 ** * For rowid tables with an INTEGER PRIMARY KEY, the true primary
284 ** key is the INTEGER PRIMARY KEY.
285 ** * For all other rowid tables, the rowid is the true primary key.
287 pStmt = db_prepare("PRAGMA %s.index_list=%Q", zDb, zTab);
288 while( SQLITE_ROW==sqlite3_step(pStmt) ){
289 if( sqlite3_stricmp((const char*)sqlite3_column_text(pStmt,3),"pk")==0 ){
290 zPkIdxName = sqlite3_mprintf("%s", sqlite3_column_text(pStmt, 1));
291 break;
294 sqlite3_finalize(pStmt);
295 if( zPkIdxName ){
296 int nKey = 0;
297 int nCol = 0;
298 truePk = 0;
299 pStmt = db_prepare("PRAGMA %s.index_xinfo=%Q", zDb, zPkIdxName);
300 while( SQLITE_ROW==sqlite3_step(pStmt) ){
301 nCol++;
302 if( sqlite3_column_int(pStmt,5) ){ nKey++; continue; }
303 if( sqlite3_column_int(pStmt,1)>=0 ) truePk = 1;
305 if( nCol==nKey ) truePk = 1;
306 if( truePk ){
307 nPK = nKey;
308 }else{
309 nPK = 1;
311 sqlite3_finalize(pStmt);
312 sqlite3_free(zPkIdxName);
313 }else{
314 truePk = 1;
315 nPK = 1;
317 pStmt = db_prepare("PRAGMA %s.table_info=%Q", zDb, zTab);
318 }else{
319 /* The g.bSchemaPK==1 case: Use whatever primary key is declared
320 ** in the schema. The "rowid" will still be used as the primary key
321 ** if the table definition does not contain a PRIMARY KEY.
323 nPK = 0;
324 pStmt = db_prepare("PRAGMA %s.table_info=%Q", zDb, zTab);
325 while( SQLITE_ROW==sqlite3_step(pStmt) ){
326 if( sqlite3_column_int(pStmt,5)>0 ) nPK++;
328 sqlite3_reset(pStmt);
329 if( nPK==0 ) nPK = 1;
330 truePk = 1;
332 *pnPKey = nPK;
333 naz = nPK;
334 az = sqlite3_malloc( sizeof(char*)*(nPK+1) );
335 if( az==0 ) runtimeError("out of memory");
336 memset(az, 0, sizeof(char*)*(nPK+1));
337 while( SQLITE_ROW==sqlite3_step(pStmt) ){
338 int iPKey;
339 if( truePk && (iPKey = sqlite3_column_int(pStmt,5))>0 ){
340 az[iPKey-1] = safeId((char*)sqlite3_column_text(pStmt,1));
341 }else{
342 az = sqlite3_realloc(az, sizeof(char*)*(naz+2) );
343 if( az==0 ) runtimeError("out of memory");
344 az[naz++] = safeId((char*)sqlite3_column_text(pStmt,1));
347 sqlite3_finalize(pStmt);
348 if( az ) az[naz] = 0;
350 /* If it is non-NULL, set *pbRowid to indicate whether or not the PK of
351 ** this table is an implicit rowid (*pbRowid==1) or not (*pbRowid==0). */
352 if( pbRowid ) *pbRowid = (az[0]==0);
354 /* If this table has an implicit rowid for a PK, figure out how to refer
355 ** to it. There are three options - "rowid", "_rowid_" and "oid". Any
356 ** of these will work, unless the table has an explicit column of the
357 ** same name. */
358 if( az[0]==0 ){
359 const char *azRowid[] = { "rowid", "_rowid_", "oid" };
360 for(i=0; i<sizeof(azRowid)/sizeof(azRowid[0]); i++){
361 for(j=1; j<naz; j++){
362 if( sqlite3_stricmp(az[j], azRowid[i])==0 ) break;
364 if( j>=naz ){
365 az[0] = sqlite3_mprintf("%s", azRowid[i]);
366 break;
369 if( az[0]==0 ){
370 for(i=1; i<naz; i++) sqlite3_free(az[i]);
371 sqlite3_free(az);
372 az = 0;
375 return az;
379 ** Print the sqlite3_value X as an SQL literal.
381 static void printQuoted(FILE *out, sqlite3_value *X){
382 switch( sqlite3_value_type(X) ){
383 case SQLITE_FLOAT: {
384 double r1;
385 char zBuf[50];
386 r1 = sqlite3_value_double(X);
387 sqlite3_snprintf(sizeof(zBuf), zBuf, "%!.15g", r1);
388 fprintf(out, "%s", zBuf);
389 break;
391 case SQLITE_INTEGER: {
392 fprintf(out, "%lld", sqlite3_value_int64(X));
393 break;
395 case SQLITE_BLOB: {
396 const unsigned char *zBlob = sqlite3_value_blob(X);
397 int nBlob = sqlite3_value_bytes(X);
398 if( zBlob ){
399 int i;
400 fprintf(out, "x'");
401 for(i=0; i<nBlob; i++){
402 fprintf(out, "%02x", zBlob[i]);
404 fprintf(out, "'");
405 }else{
406 /* Could be an OOM, could be a zero-byte blob */
407 fprintf(out, "X''");
409 break;
411 case SQLITE_TEXT: {
412 const unsigned char *zArg = sqlite3_value_text(X);
413 int i, j;
415 if( zArg==0 ){
416 fprintf(out, "NULL");
417 }else{
418 fprintf(out, "'");
419 for(i=j=0; zArg[i]; i++){
420 if( zArg[i]=='\'' ){
421 fprintf(out, "%.*s'", i-j+1, &zArg[j]);
422 j = i+1;
425 fprintf(out, "%s'", &zArg[j]);
427 break;
429 case SQLITE_NULL: {
430 fprintf(out, "NULL");
431 break;
437 ** Output SQL that will recreate the aux.zTab table.
439 static void dump_table(const char *zTab, FILE *out){
440 char *zId = safeId(zTab); /* Name of the table */
441 char **az = 0; /* List of columns */
442 int nPk; /* Number of true primary key columns */
443 int nCol; /* Number of data columns */
444 int i; /* Loop counter */
445 sqlite3_stmt *pStmt; /* SQL statement */
446 const char *zSep; /* Separator string */
447 Str ins; /* Beginning of the INSERT statement */
449 pStmt = db_prepare("SELECT sql FROM aux.sqlite_master WHERE name=%Q", zTab);
450 if( SQLITE_ROW==sqlite3_step(pStmt) ){
451 fprintf(out, "%s;\n", sqlite3_column_text(pStmt,0));
453 sqlite3_finalize(pStmt);
454 if( !g.bSchemaOnly ){
455 az = columnNames("aux", zTab, &nPk, 0);
456 strInit(&ins);
457 if( az==0 ){
458 pStmt = db_prepare("SELECT * FROM aux.%s", zId);
459 strPrintf(&ins,"INSERT INTO %s VALUES", zId);
460 }else{
461 Str sql;
462 strInit(&sql);
463 zSep = "SELECT";
464 for(i=0; az[i]; i++){
465 strPrintf(&sql, "%s %s", zSep, az[i]);
466 zSep = ",";
468 strPrintf(&sql," FROM aux.%s", zId);
469 zSep = " ORDER BY";
470 for(i=1; i<=nPk; i++){
471 strPrintf(&sql, "%s %d", zSep, i);
472 zSep = ",";
474 pStmt = db_prepare("%s", sql.z);
475 strFree(&sql);
476 strPrintf(&ins, "INSERT INTO %s", zId);
477 zSep = "(";
478 for(i=0; az[i]; i++){
479 strPrintf(&ins, "%s%s", zSep, az[i]);
480 zSep = ",";
482 strPrintf(&ins,") VALUES");
483 namelistFree(az);
485 nCol = sqlite3_column_count(pStmt);
486 while( SQLITE_ROW==sqlite3_step(pStmt) ){
487 fprintf(out, "%s",ins.z);
488 zSep = "(";
489 for(i=0; i<nCol; i++){
490 fprintf(out, "%s",zSep);
491 printQuoted(out, sqlite3_column_value(pStmt,i));
492 zSep = ",";
494 fprintf(out, ");\n");
496 sqlite3_finalize(pStmt);
497 strFree(&ins);
498 } /* endif !g.bSchemaOnly */
499 pStmt = db_prepare("SELECT sql FROM aux.sqlite_master"
500 " WHERE type='index' AND tbl_name=%Q AND sql IS NOT NULL",
501 zTab);
502 while( SQLITE_ROW==sqlite3_step(pStmt) ){
503 fprintf(out, "%s;\n", sqlite3_column_text(pStmt,0));
505 sqlite3_finalize(pStmt);
510 ** Compute all differences for a single table.
512 static void diff_one_table(const char *zTab, FILE *out){
513 char *zId = safeId(zTab); /* Name of table (translated for us in SQL) */
514 char **az = 0; /* Columns in main */
515 char **az2 = 0; /* Columns in aux */
516 int nPk; /* Primary key columns in main */
517 int nPk2; /* Primary key columns in aux */
518 int n = 0; /* Number of columns in main */
519 int n2; /* Number of columns in aux */
520 int nQ; /* Number of output columns in the diff query */
521 int i; /* Loop counter */
522 const char *zSep; /* Separator string */
523 Str sql; /* Comparison query */
524 sqlite3_stmt *pStmt; /* Query statement to do the diff */
526 strInit(&sql);
527 if( g.fDebug==DEBUG_COLUMN_NAMES ){
528 /* Simply run columnNames() on all tables of the origin
529 ** database and show the results. This is used for testing
530 ** and debugging of the columnNames() function.
532 az = columnNames("aux",zTab, &nPk, 0);
533 if( az==0 ){
534 printf("Rowid not accessible for %s\n", zId);
535 }else{
536 printf("%s:", zId);
537 for(i=0; az[i]; i++){
538 printf(" %s", az[i]);
539 if( i+1==nPk ) printf(" *");
541 printf("\n");
543 goto end_diff_one_table;
547 if( sqlite3_table_column_metadata(g.db,"aux",zTab,0,0,0,0,0,0) ){
548 if( !sqlite3_table_column_metadata(g.db,"main",zTab,0,0,0,0,0,0) ){
549 /* Table missing from second database. */
550 fprintf(out, "DROP TABLE %s;\n", zId);
552 goto end_diff_one_table;
555 if( sqlite3_table_column_metadata(g.db,"main",zTab,0,0,0,0,0,0) ){
556 /* Table missing from source */
557 dump_table(zTab, out);
558 goto end_diff_one_table;
561 az = columnNames("main", zTab, &nPk, 0);
562 az2 = columnNames("aux", zTab, &nPk2, 0);
563 if( az && az2 ){
564 for(n=0; az[n] && az2[n]; n++){
565 if( sqlite3_stricmp(az[n],az2[n])!=0 ) break;
568 if( az==0
569 || az2==0
570 || nPk!=nPk2
571 || az[n]
573 /* Schema mismatch */
574 fprintf(out, "DROP TABLE %s; -- due to schema mismatch\n", zId);
575 dump_table(zTab, out);
576 goto end_diff_one_table;
579 /* Build the comparison query */
580 for(n2=n; az2[n2]; n2++){
581 fprintf(out, "ALTER TABLE %s ADD COLUMN %s;\n", zId, safeId(az2[n2]));
583 nQ = nPk2+1+2*(n2-nPk2);
584 if( n2>nPk2 ){
585 zSep = "SELECT ";
586 for(i=0; i<nPk; i++){
587 strPrintf(&sql, "%sB.%s", zSep, az[i]);
588 zSep = ", ";
590 strPrintf(&sql, ", 1%s -- changed row\n", nPk==n ? "" : ",");
591 while( az[i] ){
592 strPrintf(&sql, " A.%s IS NOT B.%s, B.%s%s\n",
593 az[i], az2[i], az2[i], az2[i+1]==0 ? "" : ",");
594 i++;
596 while( az2[i] ){
597 strPrintf(&sql, " B.%s IS NOT NULL, B.%s%s\n",
598 az2[i], az2[i], az2[i+1]==0 ? "" : ",");
599 i++;
601 strPrintf(&sql, " FROM main.%s A, aux.%s B\n", zId, zId);
602 zSep = " WHERE";
603 for(i=0; i<nPk; i++){
604 strPrintf(&sql, "%s A.%s=B.%s", zSep, az[i], az[i]);
605 zSep = " AND";
607 zSep = "\n AND (";
608 while( az[i] ){
609 strPrintf(&sql, "%sA.%s IS NOT B.%s%s\n",
610 zSep, az[i], az2[i], az2[i+1]==0 ? ")" : "");
611 zSep = " OR ";
612 i++;
614 while( az2[i] ){
615 strPrintf(&sql, "%sB.%s IS NOT NULL%s\n",
616 zSep, az2[i], az2[i+1]==0 ? ")" : "");
617 zSep = " OR ";
618 i++;
620 strPrintf(&sql, " UNION ALL\n");
622 zSep = "SELECT ";
623 for(i=0; i<nPk; i++){
624 strPrintf(&sql, "%sA.%s", zSep, az[i]);
625 zSep = ", ";
627 strPrintf(&sql, ", 2%s -- deleted row\n", nPk==n ? "" : ",");
628 while( az2[i] ){
629 strPrintf(&sql, " NULL, NULL%s\n", i==n2-1 ? "" : ",");
630 i++;
632 strPrintf(&sql, " FROM main.%s A\n", zId);
633 strPrintf(&sql, " WHERE NOT EXISTS(SELECT 1 FROM aux.%s B\n", zId);
634 zSep = " WHERE";
635 for(i=0; i<nPk; i++){
636 strPrintf(&sql, "%s A.%s=B.%s", zSep, az[i], az[i]);
637 zSep = " AND";
639 strPrintf(&sql, ")\n");
640 zSep = " UNION ALL\nSELECT ";
641 for(i=0; i<nPk; i++){
642 strPrintf(&sql, "%sB.%s", zSep, az[i]);
643 zSep = ", ";
645 strPrintf(&sql, ", 3%s -- inserted row\n", nPk==n ? "" : ",");
646 while( az2[i] ){
647 strPrintf(&sql, " 1, B.%s%s\n", az2[i], az2[i+1]==0 ? "" : ",");
648 i++;
650 strPrintf(&sql, " FROM aux.%s B\n", zId);
651 strPrintf(&sql, " WHERE NOT EXISTS(SELECT 1 FROM main.%s A\n", zId);
652 zSep = " WHERE";
653 for(i=0; i<nPk; i++){
654 strPrintf(&sql, "%s A.%s=B.%s", zSep, az[i], az[i]);
655 zSep = " AND";
657 strPrintf(&sql, ")\n ORDER BY");
658 zSep = " ";
659 for(i=1; i<=nPk; i++){
660 strPrintf(&sql, "%s%d", zSep, i);
661 zSep = ", ";
663 strPrintf(&sql, ";\n");
665 if( g.fDebug & DEBUG_DIFF_SQL ){
666 printf("SQL for %s:\n%s\n", zId, sql.z);
667 goto end_diff_one_table;
670 /* Drop indexes that are missing in the destination */
671 pStmt = db_prepare(
672 "SELECT name FROM main.sqlite_master"
673 " WHERE type='index' AND tbl_name=%Q"
674 " AND sql IS NOT NULL"
675 " AND sql NOT IN (SELECT sql FROM aux.sqlite_master"
676 " WHERE type='index' AND tbl_name=%Q"
677 " AND sql IS NOT NULL)",
678 zTab, zTab);
679 while( SQLITE_ROW==sqlite3_step(pStmt) ){
680 char *z = safeId((const char*)sqlite3_column_text(pStmt,0));
681 fprintf(out, "DROP INDEX %s;\n", z);
682 sqlite3_free(z);
684 sqlite3_finalize(pStmt);
686 /* Run the query and output differences */
687 if( !g.bSchemaOnly ){
688 pStmt = db_prepare("%s", sql.z);
689 while( SQLITE_ROW==sqlite3_step(pStmt) ){
690 int iType = sqlite3_column_int(pStmt, nPk);
691 if( iType==1 || iType==2 ){
692 if( iType==1 ){ /* Change the content of a row */
693 fprintf(out, "UPDATE %s", zId);
694 zSep = " SET";
695 for(i=nPk+1; i<nQ; i+=2){
696 if( sqlite3_column_int(pStmt,i)==0 ) continue;
697 fprintf(out, "%s %s=", zSep, az2[(i+nPk-1)/2]);
698 zSep = ",";
699 printQuoted(out, sqlite3_column_value(pStmt,i+1));
701 }else{ /* Delete a row */
702 fprintf(out, "DELETE FROM %s", zId);
704 zSep = " WHERE";
705 for(i=0; i<nPk; i++){
706 fprintf(out, "%s %s=", zSep, az2[i]);
707 printQuoted(out, sqlite3_column_value(pStmt,i));
708 zSep = " AND";
710 fprintf(out, ";\n");
711 }else{ /* Insert a row */
712 fprintf(out, "INSERT INTO %s(%s", zId, az2[0]);
713 for(i=1; az2[i]; i++) fprintf(out, ",%s", az2[i]);
714 fprintf(out, ") VALUES");
715 zSep = "(";
716 for(i=0; i<nPk2; i++){
717 fprintf(out, "%s", zSep);
718 zSep = ",";
719 printQuoted(out, sqlite3_column_value(pStmt,i));
721 for(i=nPk2+2; i<nQ; i+=2){
722 fprintf(out, ",");
723 printQuoted(out, sqlite3_column_value(pStmt,i));
725 fprintf(out, ");\n");
728 sqlite3_finalize(pStmt);
729 } /* endif !g.bSchemaOnly */
731 /* Create indexes that are missing in the source */
732 pStmt = db_prepare(
733 "SELECT sql FROM aux.sqlite_master"
734 " WHERE type='index' AND tbl_name=%Q"
735 " AND sql IS NOT NULL"
736 " AND sql NOT IN (SELECT sql FROM main.sqlite_master"
737 " WHERE type='index' AND tbl_name=%Q"
738 " AND sql IS NOT NULL)",
739 zTab, zTab);
740 while( SQLITE_ROW==sqlite3_step(pStmt) ){
741 fprintf(out, "%s;\n", sqlite3_column_text(pStmt,0));
743 sqlite3_finalize(pStmt);
745 end_diff_one_table:
746 strFree(&sql);
747 sqlite3_free(zId);
748 namelistFree(az);
749 namelistFree(az2);
750 return;
754 ** Check that table zTab exists and has the same schema in both the "main"
755 ** and "aux" databases currently opened by the global db handle. If they
756 ** do not, output an error message on stderr and exit(1). Otherwise, if
757 ** the schemas do match, return control to the caller.
759 static void checkSchemasMatch(const char *zTab){
760 sqlite3_stmt *pStmt = db_prepare(
761 "SELECT A.sql=B.sql FROM main.sqlite_master A, aux.sqlite_master B"
762 " WHERE A.name=%Q AND B.name=%Q", zTab, zTab
764 if( SQLITE_ROW==sqlite3_step(pStmt) ){
765 if( sqlite3_column_int(pStmt,0)==0 ){
766 runtimeError("schema changes for table %s", safeId(zTab));
768 }else{
769 runtimeError("table %s missing from one or both databases", safeId(zTab));
771 sqlite3_finalize(pStmt);
774 /**************************************************************************
775 ** The following code is copied from fossil. It is used to generate the
776 ** fossil delta blobs sometimes used in RBU update records.
779 typedef unsigned short u16;
780 typedef unsigned int u32;
781 typedef unsigned char u8;
784 ** The width of a hash window in bytes. The algorithm only works if this
785 ** is a power of 2.
787 #define NHASH 16
790 ** The current state of the rolling hash.
792 ** z[] holds the values that have been hashed. z[] is a circular buffer.
793 ** z[i] is the first entry and z[(i+NHASH-1)%NHASH] is the last entry of
794 ** the window.
796 ** Hash.a is the sum of all elements of hash.z[]. Hash.b is a weighted
797 ** sum. Hash.b is z[i]*NHASH + z[i+1]*(NHASH-1) + ... + z[i+NHASH-1]*1.
798 ** (Each index for z[] should be module NHASH, of course. The %NHASH operator
799 ** is omitted in the prior expression for brevity.)
801 typedef struct hash hash;
802 struct hash {
803 u16 a, b; /* Hash values */
804 u16 i; /* Start of the hash window */
805 char z[NHASH]; /* The values that have been hashed */
809 ** Initialize the rolling hash using the first NHASH characters of z[]
811 static void hash_init(hash *pHash, const char *z){
812 u16 a, b, i;
813 a = b = 0;
814 for(i=0; i<NHASH; i++){
815 a += z[i];
816 b += (NHASH-i)*z[i];
817 pHash->z[i] = z[i];
819 pHash->a = a & 0xffff;
820 pHash->b = b & 0xffff;
821 pHash->i = 0;
825 ** Advance the rolling hash by a single character "c"
827 static void hash_next(hash *pHash, int c){
828 u16 old = pHash->z[pHash->i];
829 pHash->z[pHash->i] = (char)c;
830 pHash->i = (pHash->i+1)&(NHASH-1);
831 pHash->a = pHash->a - old + (char)c;
832 pHash->b = pHash->b - NHASH*old + pHash->a;
836 ** Return a 32-bit hash value
838 static u32 hash_32bit(hash *pHash){
839 return (pHash->a & 0xffff) | (((u32)(pHash->b & 0xffff))<<16);
843 ** Write an base-64 integer into the given buffer.
845 static void putInt(unsigned int v, char **pz){
846 static const char zDigits[] =
847 "0123456789ABCDEFGHIJKLMNOPQRSTUVWXYZ_abcdefghijklmnopqrstuvwxyz~";
848 /* 123456789 123456789 123456789 123456789 123456789 123456789 123 */
849 int i, j;
850 char zBuf[20];
851 if( v==0 ){
852 *(*pz)++ = '0';
853 return;
855 for(i=0; v>0; i++, v>>=6){
856 zBuf[i] = zDigits[v&0x3f];
858 for(j=i-1; j>=0; j--){
859 *(*pz)++ = zBuf[j];
864 ** Return the number digits in the base-64 representation of a positive integer
866 static int digit_count(int v){
867 unsigned int i, x;
868 for(i=1, x=64; (unsigned int)v>=x; i++, x <<= 6){}
869 return i;
873 ** Compute a 32-bit checksum on the N-byte buffer. Return the result.
875 static unsigned int checksum(const char *zIn, size_t N){
876 const unsigned char *z = (const unsigned char *)zIn;
877 unsigned sum0 = 0;
878 unsigned sum1 = 0;
879 unsigned sum2 = 0;
880 unsigned sum3 = 0;
881 while(N >= 16){
882 sum0 += ((unsigned)z[0] + z[4] + z[8] + z[12]);
883 sum1 += ((unsigned)z[1] + z[5] + z[9] + z[13]);
884 sum2 += ((unsigned)z[2] + z[6] + z[10]+ z[14]);
885 sum3 += ((unsigned)z[3] + z[7] + z[11]+ z[15]);
886 z += 16;
887 N -= 16;
889 while(N >= 4){
890 sum0 += z[0];
891 sum1 += z[1];
892 sum2 += z[2];
893 sum3 += z[3];
894 z += 4;
895 N -= 4;
897 sum3 += (sum2 << 8) + (sum1 << 16) + (sum0 << 24);
898 switch(N){
899 case 3: sum3 += (z[2] << 8);
900 case 2: sum3 += (z[1] << 16);
901 case 1: sum3 += (z[0] << 24);
902 default: ;
904 return sum3;
908 ** Create a new delta.
910 ** The delta is written into a preallocated buffer, zDelta, which
911 ** should be at least 60 bytes longer than the target file, zOut.
912 ** The delta string will be NUL-terminated, but it might also contain
913 ** embedded NUL characters if either the zSrc or zOut files are
914 ** binary. This function returns the length of the delta string
915 ** in bytes, excluding the final NUL terminator character.
917 ** Output Format:
919 ** The delta begins with a base64 number followed by a newline. This
920 ** number is the number of bytes in the TARGET file. Thus, given a
921 ** delta file z, a program can compute the size of the output file
922 ** simply by reading the first line and decoding the base-64 number
923 ** found there. The delta_output_size() routine does exactly this.
925 ** After the initial size number, the delta consists of a series of
926 ** literal text segments and commands to copy from the SOURCE file.
927 ** A copy command looks like this:
929 ** NNN@MMM,
931 ** where NNN is the number of bytes to be copied and MMM is the offset
932 ** into the source file of the first byte (both base-64). If NNN is 0
933 ** it means copy the rest of the input file. Literal text is like this:
935 ** NNN:TTTTT
937 ** where NNN is the number of bytes of text (base-64) and TTTTT is the text.
939 ** The last term is of the form
941 ** NNN;
943 ** In this case, NNN is a 32-bit bigendian checksum of the output file
944 ** that can be used to verify that the delta applied correctly. All
945 ** numbers are in base-64.
947 ** Pure text files generate a pure text delta. Binary files generate a
948 ** delta that may contain some binary data.
950 ** Algorithm:
952 ** The encoder first builds a hash table to help it find matching
953 ** patterns in the source file. 16-byte chunks of the source file
954 ** sampled at evenly spaced intervals are used to populate the hash
955 ** table.
957 ** Next we begin scanning the target file using a sliding 16-byte
958 ** window. The hash of the 16-byte window in the target is used to
959 ** search for a matching section in the source file. When a match
960 ** is found, a copy command is added to the delta. An effort is
961 ** made to extend the matching section to regions that come before
962 ** and after the 16-byte hash window. A copy command is only issued
963 ** if the result would use less space that just quoting the text
964 ** literally. Literal text is added to the delta for sections that
965 ** do not match or which can not be encoded efficiently using copy
966 ** commands.
968 static int rbuDeltaCreate(
969 const char *zSrc, /* The source or pattern file */
970 unsigned int lenSrc, /* Length of the source file */
971 const char *zOut, /* The target file */
972 unsigned int lenOut, /* Length of the target file */
973 char *zDelta /* Write the delta into this buffer */
975 unsigned int i, base;
976 char *zOrigDelta = zDelta;
977 hash h;
978 int nHash; /* Number of hash table entries */
979 int *landmark; /* Primary hash table */
980 int *collide; /* Collision chain */
981 int lastRead = -1; /* Last byte of zSrc read by a COPY command */
983 /* Add the target file size to the beginning of the delta
985 putInt(lenOut, &zDelta);
986 *(zDelta++) = '\n';
988 /* If the source file is very small, it means that we have no
989 ** chance of ever doing a copy command. Just output a single
990 ** literal segment for the entire target and exit.
992 if( lenSrc<=NHASH ){
993 putInt(lenOut, &zDelta);
994 *(zDelta++) = ':';
995 memcpy(zDelta, zOut, lenOut);
996 zDelta += lenOut;
997 putInt(checksum(zOut, lenOut), &zDelta);
998 *(zDelta++) = ';';
999 return (int)(zDelta - zOrigDelta);
1002 /* Compute the hash table used to locate matching sections in the
1003 ** source file.
1005 nHash = lenSrc/NHASH;
1006 collide = sqlite3_malloc( nHash*2*sizeof(int) );
1007 landmark = &collide[nHash];
1008 memset(landmark, -1, nHash*sizeof(int));
1009 memset(collide, -1, nHash*sizeof(int));
1010 for(i=0; i<lenSrc-NHASH; i+=NHASH){
1011 int hv;
1012 hash_init(&h, &zSrc[i]);
1013 hv = hash_32bit(&h) % nHash;
1014 collide[i/NHASH] = landmark[hv];
1015 landmark[hv] = i/NHASH;
1018 /* Begin scanning the target file and generating copy commands and
1019 ** literal sections of the delta.
1021 base = 0; /* We have already generated everything before zOut[base] */
1022 while( base+NHASH<lenOut ){
1023 int iSrc, iBlock;
1024 int bestCnt, bestOfst=0, bestLitsz=0;
1025 hash_init(&h, &zOut[base]);
1026 i = 0; /* Trying to match a landmark against zOut[base+i] */
1027 bestCnt = 0;
1028 while( 1 ){
1029 int hv;
1030 int limit = 250;
1032 hv = hash_32bit(&h) % nHash;
1033 iBlock = landmark[hv];
1034 while( iBlock>=0 && (limit--)>0 ){
1036 ** The hash window has identified a potential match against
1037 ** landmark block iBlock. But we need to investigate further.
1039 ** Look for a region in zOut that matches zSrc. Anchor the search
1040 ** at zSrc[iSrc] and zOut[base+i]. Do not include anything prior to
1041 ** zOut[base] or after zOut[outLen] nor anything after zSrc[srcLen].
1043 ** Set cnt equal to the length of the match and set ofst so that
1044 ** zSrc[ofst] is the first element of the match. litsz is the number
1045 ** of characters between zOut[base] and the beginning of the match.
1046 ** sz will be the overhead (in bytes) needed to encode the copy
1047 ** command. Only generate copy command if the overhead of the
1048 ** copy command is less than the amount of literal text to be copied.
1050 int cnt, ofst, litsz;
1051 int j, k, x, y;
1052 int sz;
1054 /* Beginning at iSrc, match forwards as far as we can. j counts
1055 ** the number of characters that match */
1056 iSrc = iBlock*NHASH;
1057 for(
1058 j=0, x=iSrc, y=base+i;
1059 (unsigned int)x<lenSrc && (unsigned int)y<lenOut;
1060 j++, x++, y++
1062 if( zSrc[x]!=zOut[y] ) break;
1064 j--;
1066 /* Beginning at iSrc-1, match backwards as far as we can. k counts
1067 ** the number of characters that match */
1068 for(k=1; k<iSrc && (unsigned int)k<=i; k++){
1069 if( zSrc[iSrc-k]!=zOut[base+i-k] ) break;
1071 k--;
1073 /* Compute the offset and size of the matching region */
1074 ofst = iSrc-k;
1075 cnt = j+k+1;
1076 litsz = i-k; /* Number of bytes of literal text before the copy */
1077 /* sz will hold the number of bytes needed to encode the "insert"
1078 ** command and the copy command, not counting the "insert" text */
1079 sz = digit_count(i-k)+digit_count(cnt)+digit_count(ofst)+3;
1080 if( cnt>=sz && cnt>bestCnt ){
1081 /* Remember this match only if it is the best so far and it
1082 ** does not increase the file size */
1083 bestCnt = cnt;
1084 bestOfst = iSrc-k;
1085 bestLitsz = litsz;
1088 /* Check the next matching block */
1089 iBlock = collide[iBlock];
1092 /* We have a copy command that does not cause the delta to be larger
1093 ** than a literal insert. So add the copy command to the delta.
1095 if( bestCnt>0 ){
1096 if( bestLitsz>0 ){
1097 /* Add an insert command before the copy */
1098 putInt(bestLitsz,&zDelta);
1099 *(zDelta++) = ':';
1100 memcpy(zDelta, &zOut[base], bestLitsz);
1101 zDelta += bestLitsz;
1102 base += bestLitsz;
1104 base += bestCnt;
1105 putInt(bestCnt, &zDelta);
1106 *(zDelta++) = '@';
1107 putInt(bestOfst, &zDelta);
1108 *(zDelta++) = ',';
1109 if( bestOfst + bestCnt -1 > lastRead ){
1110 lastRead = bestOfst + bestCnt - 1;
1112 bestCnt = 0;
1113 break;
1116 /* If we reach this point, it means no match is found so far */
1117 if( base+i+NHASH>=lenOut ){
1118 /* We have reached the end of the file and have not found any
1119 ** matches. Do an "insert" for everything that does not match */
1120 putInt(lenOut-base, &zDelta);
1121 *(zDelta++) = ':';
1122 memcpy(zDelta, &zOut[base], lenOut-base);
1123 zDelta += lenOut-base;
1124 base = lenOut;
1125 break;
1128 /* Advance the hash by one character. Keep looking for a match */
1129 hash_next(&h, zOut[base+i+NHASH]);
1130 i++;
1133 /* Output a final "insert" record to get all the text at the end of
1134 ** the file that does not match anything in the source file.
1136 if( base<lenOut ){
1137 putInt(lenOut-base, &zDelta);
1138 *(zDelta++) = ':';
1139 memcpy(zDelta, &zOut[base], lenOut-base);
1140 zDelta += lenOut-base;
1142 /* Output the final checksum record. */
1143 putInt(checksum(zOut, lenOut), &zDelta);
1144 *(zDelta++) = ';';
1145 sqlite3_free(collide);
1146 return (int)(zDelta - zOrigDelta);
1150 ** End of code copied from fossil.
1151 **************************************************************************/
1153 static void strPrintfArray(
1154 Str *pStr, /* String object to append to */
1155 const char *zSep, /* Separator string */
1156 const char *zFmt, /* Format for each entry */
1157 char **az, int n /* Array of strings & its size (or -1) */
1159 int i;
1160 for(i=0; az[i] && (i<n || n<0); i++){
1161 if( i!=0 ) strPrintf(pStr, "%s", zSep);
1162 strPrintf(pStr, zFmt, az[i], az[i], az[i]);
1166 static void getRbudiffQuery(
1167 const char *zTab,
1168 char **azCol,
1169 int nPK,
1170 int bOtaRowid,
1171 Str *pSql
1173 int i;
1175 /* First the newly inserted rows: **/
1176 strPrintf(pSql, "SELECT ");
1177 strPrintfArray(pSql, ", ", "%s", azCol, -1);
1178 strPrintf(pSql, ", 0, "); /* Set ota_control to 0 for an insert */
1179 strPrintfArray(pSql, ", ", "NULL", azCol, -1);
1180 strPrintf(pSql, " FROM aux.%Q AS n WHERE NOT EXISTS (\n", zTab);
1181 strPrintf(pSql, " SELECT 1 FROM ", zTab);
1182 strPrintf(pSql, " main.%Q AS o WHERE ", zTab);
1183 strPrintfArray(pSql, " AND ", "(n.%Q = o.%Q)", azCol, nPK);
1184 strPrintf(pSql, "\n) AND ");
1185 strPrintfArray(pSql, " AND ", "(n.%Q IS NOT NULL)", azCol, nPK);
1187 /* Deleted rows: */
1188 strPrintf(pSql, "\nUNION ALL\nSELECT ");
1189 strPrintfArray(pSql, ", ", "%s", azCol, nPK);
1190 if( azCol[nPK] ){
1191 strPrintf(pSql, ", ");
1192 strPrintfArray(pSql, ", ", "NULL", &azCol[nPK], -1);
1194 strPrintf(pSql, ", 1, "); /* Set ota_control to 1 for a delete */
1195 strPrintfArray(pSql, ", ", "NULL", azCol, -1);
1196 strPrintf(pSql, " FROM main.%Q AS n WHERE NOT EXISTS (\n", zTab);
1197 strPrintf(pSql, " SELECT 1 FROM ", zTab);
1198 strPrintf(pSql, " aux.%Q AS o WHERE ", zTab);
1199 strPrintfArray(pSql, " AND ", "(n.%Q = o.%Q)", azCol, nPK);
1200 strPrintf(pSql, "\n) AND ");
1201 strPrintfArray(pSql, " AND ", "(n.%Q IS NOT NULL)", azCol, nPK);
1203 /* Updated rows. If all table columns are part of the primary key, there
1204 ** can be no updates. In this case this part of the compound SELECT can
1205 ** be omitted altogether. */
1206 if( azCol[nPK] ){
1207 strPrintf(pSql, "\nUNION ALL\nSELECT ");
1208 strPrintfArray(pSql, ", ", "n.%s", azCol, nPK);
1209 strPrintf(pSql, ",\n");
1210 strPrintfArray(pSql, " ,\n",
1211 " CASE WHEN n.%s IS o.%s THEN NULL ELSE n.%s END", &azCol[nPK], -1
1214 if( bOtaRowid==0 ){
1215 strPrintf(pSql, ", '");
1216 strPrintfArray(pSql, "", ".", azCol, nPK);
1217 strPrintf(pSql, "' ||\n");
1218 }else{
1219 strPrintf(pSql, ",\n");
1221 strPrintfArray(pSql, " ||\n",
1222 " CASE WHEN n.%s IS o.%s THEN '.' ELSE 'x' END", &azCol[nPK], -1
1224 strPrintf(pSql, "\nAS ota_control, ");
1225 strPrintfArray(pSql, ", ", "NULL", azCol, nPK);
1226 strPrintf(pSql, ",\n");
1227 strPrintfArray(pSql, " ,\n",
1228 " CASE WHEN n.%s IS o.%s THEN NULL ELSE o.%s END", &azCol[nPK], -1
1231 strPrintf(pSql, "\nFROM main.%Q AS o, aux.%Q AS n\nWHERE ", zTab, zTab);
1232 strPrintfArray(pSql, " AND ", "(n.%Q = o.%Q)", azCol, nPK);
1233 strPrintf(pSql, " AND ota_control LIKE '%%x%%'");
1236 /* Now add an ORDER BY clause to sort everything by PK. */
1237 strPrintf(pSql, "\nORDER BY ");
1238 for(i=1; i<=nPK; i++) strPrintf(pSql, "%s%d", ((i>1)?", ":""), i);
1241 static void rbudiff_one_table(const char *zTab, FILE *out){
1242 int bOtaRowid; /* True to use an ota_rowid column */
1243 int nPK; /* Number of primary key columns in table */
1244 char **azCol; /* NULL terminated array of col names */
1245 int i;
1246 int nCol;
1247 Str ct = {0, 0, 0}; /* The "CREATE TABLE data_xxx" statement */
1248 Str sql = {0, 0, 0}; /* Query to find differences */
1249 Str insert = {0, 0, 0}; /* First part of output INSERT statement */
1250 sqlite3_stmt *pStmt = 0;
1251 int nRow = 0; /* Total rows in data_xxx table */
1253 /* --rbu mode must use real primary keys. */
1254 g.bSchemaPK = 1;
1256 /* Check that the schemas of the two tables match. Exit early otherwise. */
1257 checkSchemasMatch(zTab);
1259 /* Grab the column names and PK details for the table(s). If no usable PK
1260 ** columns are found, bail out early. */
1261 azCol = columnNames("main", zTab, &nPK, &bOtaRowid);
1262 if( azCol==0 ){
1263 runtimeError("table %s has no usable PK columns", zTab);
1265 for(nCol=0; azCol[nCol]; nCol++);
1267 /* Build and output the CREATE TABLE statement for the data_xxx table */
1268 strPrintf(&ct, "CREATE TABLE IF NOT EXISTS 'data_%q'(", zTab);
1269 if( bOtaRowid ) strPrintf(&ct, "rbu_rowid, ");
1270 strPrintfArray(&ct, ", ", "%s", &azCol[bOtaRowid], -1);
1271 strPrintf(&ct, ", rbu_control);");
1273 /* Get the SQL for the query to retrieve data from the two databases */
1274 getRbudiffQuery(zTab, azCol, nPK, bOtaRowid, &sql);
1276 /* Build the first part of the INSERT statement output for each row
1277 ** in the data_xxx table. */
1278 strPrintf(&insert, "INSERT INTO 'data_%q' (", zTab);
1279 if( bOtaRowid ) strPrintf(&insert, "rbu_rowid, ");
1280 strPrintfArray(&insert, ", ", "%s", &azCol[bOtaRowid], -1);
1281 strPrintf(&insert, ", rbu_control) VALUES(");
1283 pStmt = db_prepare("%s", sql.z);
1285 while( sqlite3_step(pStmt)==SQLITE_ROW ){
1287 /* If this is the first row output, print out the CREATE TABLE
1288 ** statement first. And then set ct.z to NULL so that it is not
1289 ** printed again. */
1290 if( ct.z ){
1291 fprintf(out, "%s\n", ct.z);
1292 strFree(&ct);
1295 /* Output the first part of the INSERT statement */
1296 fprintf(out, "%s", insert.z);
1297 nRow++;
1299 if( sqlite3_column_type(pStmt, nCol)==SQLITE_INTEGER ){
1300 for(i=0; i<=nCol; i++){
1301 if( i>0 ) fprintf(out, ", ");
1302 printQuoted(out, sqlite3_column_value(pStmt, i));
1304 }else{
1305 char *zOtaControl;
1306 int nOtaControl = sqlite3_column_bytes(pStmt, nCol);
1308 zOtaControl = (char*)sqlite3_malloc(nOtaControl+1);
1309 memcpy(zOtaControl, sqlite3_column_text(pStmt, nCol), nOtaControl+1);
1311 for(i=0; i<nCol; i++){
1312 int bDone = 0;
1313 if( i>=nPK
1314 && sqlite3_column_type(pStmt, i)==SQLITE_BLOB
1315 && sqlite3_column_type(pStmt, nCol+1+i)==SQLITE_BLOB
1317 const char *aSrc = sqlite3_column_blob(pStmt, nCol+1+i);
1318 int nSrc = sqlite3_column_bytes(pStmt, nCol+1+i);
1319 const char *aFinal = sqlite3_column_blob(pStmt, i);
1320 int nFinal = sqlite3_column_bytes(pStmt, i);
1321 char *aDelta;
1322 int nDelta;
1324 aDelta = sqlite3_malloc(nFinal + 60);
1325 nDelta = rbuDeltaCreate(aSrc, nSrc, aFinal, nFinal, aDelta);
1326 if( nDelta<nFinal ){
1327 int j;
1328 fprintf(out, "x'");
1329 for(j=0; j<nDelta; j++) fprintf(out, "%02x", (u8)aDelta[j]);
1330 fprintf(out, "'");
1331 zOtaControl[i-bOtaRowid] = 'f';
1332 bDone = 1;
1334 sqlite3_free(aDelta);
1337 if( bDone==0 ){
1338 printQuoted(out, sqlite3_column_value(pStmt, i));
1340 fprintf(out, ", ");
1342 fprintf(out, "'%s'", zOtaControl);
1343 sqlite3_free(zOtaControl);
1346 /* And the closing bracket of the insert statement */
1347 fprintf(out, ");\n");
1350 sqlite3_finalize(pStmt);
1351 if( nRow>0 ){
1352 Str cnt = {0, 0, 0};
1353 strPrintf(&cnt, "INSERT INTO rbu_count VALUES('data_%q', %d);", zTab, nRow);
1354 fprintf(out, "%s\n", cnt.z);
1355 strFree(&cnt);
1358 strFree(&ct);
1359 strFree(&sql);
1360 strFree(&insert);
1364 ** Display a summary of differences between two versions of the same
1365 ** table table.
1367 ** * Number of rows changed
1368 ** * Number of rows added
1369 ** * Number of rows deleted
1370 ** * Number of identical rows
1372 static void summarize_one_table(const char *zTab, FILE *out){
1373 char *zId = safeId(zTab); /* Name of table (translated for us in SQL) */
1374 char **az = 0; /* Columns in main */
1375 char **az2 = 0; /* Columns in aux */
1376 int nPk; /* Primary key columns in main */
1377 int nPk2; /* Primary key columns in aux */
1378 int n = 0; /* Number of columns in main */
1379 int n2; /* Number of columns in aux */
1380 int i; /* Loop counter */
1381 const char *zSep; /* Separator string */
1382 Str sql; /* Comparison query */
1383 sqlite3_stmt *pStmt; /* Query statement to do the diff */
1384 sqlite3_int64 nUpdate; /* Number of updated rows */
1385 sqlite3_int64 nUnchanged; /* Number of unmodified rows */
1386 sqlite3_int64 nDelete; /* Number of deleted rows */
1387 sqlite3_int64 nInsert; /* Number of inserted rows */
1389 strInit(&sql);
1390 if( sqlite3_table_column_metadata(g.db,"aux",zTab,0,0,0,0,0,0) ){
1391 if( !sqlite3_table_column_metadata(g.db,"main",zTab,0,0,0,0,0,0) ){
1392 /* Table missing from second database. */
1393 fprintf(out, "%s: missing from second database\n", zTab);
1395 goto end_summarize_one_table;
1398 if( sqlite3_table_column_metadata(g.db,"main",zTab,0,0,0,0,0,0) ){
1399 /* Table missing from source */
1400 fprintf(out, "%s: missing from first database\n", zTab);
1401 goto end_summarize_one_table;
1404 az = columnNames("main", zTab, &nPk, 0);
1405 az2 = columnNames("aux", zTab, &nPk2, 0);
1406 if( az && az2 ){
1407 for(n=0; az[n]; n++){
1408 if( sqlite3_stricmp(az[n],az2[n])!=0 ) break;
1411 if( az==0
1412 || az2==0
1413 || nPk!=nPk2
1414 || az[n]
1416 /* Schema mismatch */
1417 fprintf(out, "%s: incompatible schema\n", zTab);
1418 goto end_summarize_one_table;
1421 /* Build the comparison query */
1422 for(n2=n; az[n2]; n2++){}
1423 strPrintf(&sql, "SELECT 1, count(*)");
1424 if( n2==nPk2 ){
1425 strPrintf(&sql, ", 0\n");
1426 }else{
1427 zSep = ", sum(";
1428 for(i=nPk; az[i]; i++){
1429 strPrintf(&sql, "%sA.%s IS NOT B.%s", zSep, az[i], az[i]);
1430 zSep = " OR ";
1432 strPrintf(&sql, ")\n");
1434 strPrintf(&sql, " FROM main.%s A, aux.%s B\n", zId, zId);
1435 zSep = " WHERE";
1436 for(i=0; i<nPk; i++){
1437 strPrintf(&sql, "%s A.%s=B.%s", zSep, az[i], az[i]);
1438 zSep = " AND";
1440 strPrintf(&sql, " UNION ALL\n");
1441 strPrintf(&sql, "SELECT 2, count(*), 0\n");
1442 strPrintf(&sql, " FROM main.%s A\n", zId);
1443 strPrintf(&sql, " WHERE NOT EXISTS(SELECT 1 FROM aux.%s B ", zId);
1444 zSep = "WHERE";
1445 for(i=0; i<nPk; i++){
1446 strPrintf(&sql, "%s A.%s=B.%s", zSep, az[i], az[i]);
1447 zSep = " AND";
1449 strPrintf(&sql, ")\n");
1450 strPrintf(&sql, " UNION ALL\n");
1451 strPrintf(&sql, "SELECT 3, count(*), 0\n");
1452 strPrintf(&sql, " FROM aux.%s B\n", zId);
1453 strPrintf(&sql, " WHERE NOT EXISTS(SELECT 1 FROM main.%s A ", zId);
1454 zSep = "WHERE";
1455 for(i=0; i<nPk; i++){
1456 strPrintf(&sql, "%s A.%s=B.%s", zSep, az[i], az[i]);
1457 zSep = " AND";
1459 strPrintf(&sql, ")\n ORDER BY 1;\n");
1461 if( (g.fDebug & DEBUG_DIFF_SQL)!=0 ){
1462 printf("SQL for %s:\n%s\n", zId, sql.z);
1463 goto end_summarize_one_table;
1466 /* Run the query and output difference summary */
1467 pStmt = db_prepare("%s", sql.z);
1468 nUpdate = 0;
1469 nInsert = 0;
1470 nDelete = 0;
1471 nUnchanged = 0;
1472 while( SQLITE_ROW==sqlite3_step(pStmt) ){
1473 switch( sqlite3_column_int(pStmt,0) ){
1474 case 1:
1475 nUpdate = sqlite3_column_int64(pStmt,2);
1476 nUnchanged = sqlite3_column_int64(pStmt,1) - nUpdate;
1477 break;
1478 case 2:
1479 nDelete = sqlite3_column_int64(pStmt,1);
1480 break;
1481 case 3:
1482 nInsert = sqlite3_column_int64(pStmt,1);
1483 break;
1486 sqlite3_finalize(pStmt);
1487 fprintf(out, "%s: %lld changes, %lld inserts, %lld deletes, %lld unchanged\n",
1488 zTab, nUpdate, nInsert, nDelete, nUnchanged);
1490 end_summarize_one_table:
1491 strFree(&sql);
1492 sqlite3_free(zId);
1493 namelistFree(az);
1494 namelistFree(az2);
1495 return;
1499 ** Write a 64-bit signed integer as a varint onto out
1501 static void putsVarint(FILE *out, sqlite3_uint64 v){
1502 int i, n;
1503 unsigned char p[12];
1504 if( v & (((sqlite3_uint64)0xff000000)<<32) ){
1505 p[8] = (unsigned char)v;
1506 v >>= 8;
1507 for(i=7; i>=0; i--){
1508 p[i] = (unsigned char)((v & 0x7f) | 0x80);
1509 v >>= 7;
1511 fwrite(p, 8, 1, out);
1512 }else{
1513 n = 9;
1515 p[n--] = (unsigned char)((v & 0x7f) | 0x80);
1516 v >>= 7;
1517 }while( v!=0 );
1518 p[9] &= 0x7f;
1519 fwrite(p+n+1, 9-n, 1, out);
1524 ** Write an SQLite value onto out.
1526 static void putValue(FILE *out, sqlite3_value *pVal){
1527 int iDType = sqlite3_value_type(pVal);
1528 sqlite3_int64 iX;
1529 double rX;
1530 sqlite3_uint64 uX;
1531 int j;
1533 putc(iDType, out);
1534 switch( iDType ){
1535 case SQLITE_INTEGER:
1536 iX = sqlite3_value_int64(pVal);
1537 memcpy(&uX, &iX, 8);
1538 for(j=56; j>=0; j-=8) putc((uX>>j)&0xff, out);
1539 break;
1540 case SQLITE_FLOAT:
1541 rX = sqlite3_value_double(pVal);
1542 memcpy(&uX, &rX, 8);
1543 for(j=56; j>=0; j-=8) putc((uX>>j)&0xff, out);
1544 break;
1545 case SQLITE_TEXT:
1546 iX = sqlite3_value_bytes(pVal);
1547 putsVarint(out, (sqlite3_uint64)iX);
1548 fwrite(sqlite3_value_text(pVal),1,(size_t)iX,out);
1549 break;
1550 case SQLITE_BLOB:
1551 iX = sqlite3_value_bytes(pVal);
1552 putsVarint(out, (sqlite3_uint64)iX);
1553 fwrite(sqlite3_value_blob(pVal),1,(size_t)iX,out);
1554 break;
1555 case SQLITE_NULL:
1556 break;
1561 ** Generate a CHANGESET for all differences from main.zTab to aux.zTab.
1563 static void changeset_one_table(const char *zTab, FILE *out){
1564 sqlite3_stmt *pStmt; /* SQL statment */
1565 char *zId = safeId(zTab); /* Escaped name of the table */
1566 char **azCol = 0; /* List of escaped column names */
1567 int nCol = 0; /* Number of columns */
1568 int *aiFlg = 0; /* 0 if column is not part of PK */
1569 int *aiPk = 0; /* Column numbers for each PK column */
1570 int nPk = 0; /* Number of PRIMARY KEY columns */
1571 Str sql; /* SQL for the diff query */
1572 int i, k; /* Loop counters */
1573 const char *zSep; /* List separator */
1575 /* Check that the schemas of the two tables match. Exit early otherwise. */
1576 checkSchemasMatch(zTab);
1578 pStmt = db_prepare("PRAGMA main.table_info=%Q", zTab);
1579 while( SQLITE_ROW==sqlite3_step(pStmt) ){
1580 nCol++;
1581 azCol = sqlite3_realloc(azCol, sizeof(char*)*nCol);
1582 if( azCol==0 ) runtimeError("out of memory");
1583 aiFlg = sqlite3_realloc(aiFlg, sizeof(int)*nCol);
1584 if( aiFlg==0 ) runtimeError("out of memory");
1585 azCol[nCol-1] = safeId((const char*)sqlite3_column_text(pStmt,1));
1586 aiFlg[nCol-1] = i = sqlite3_column_int(pStmt,5);
1587 if( i>0 ){
1588 if( i>nPk ){
1589 nPk = i;
1590 aiPk = sqlite3_realloc(aiPk, sizeof(int)*nPk);
1591 if( aiPk==0 ) runtimeError("out of memory");
1593 aiPk[i-1] = nCol-1;
1596 sqlite3_finalize(pStmt);
1597 if( nPk==0 ) goto end_changeset_one_table;
1598 strInit(&sql);
1599 if( nCol>nPk ){
1600 strPrintf(&sql, "SELECT %d", SQLITE_UPDATE);
1601 for(i=0; i<nCol; i++){
1602 if( aiFlg[i] ){
1603 strPrintf(&sql, ",\n A.%s", azCol[i]);
1604 }else{
1605 strPrintf(&sql, ",\n A.%s IS NOT B.%s, A.%s, B.%s",
1606 azCol[i], azCol[i], azCol[i], azCol[i]);
1609 strPrintf(&sql,"\n FROM main.%s A, aux.%s B\n", zId, zId);
1610 zSep = " WHERE";
1611 for(i=0; i<nPk; i++){
1612 strPrintf(&sql, "%s A.%s=B.%s", zSep, azCol[aiPk[i]], azCol[aiPk[i]]);
1613 zSep = " AND";
1615 zSep = "\n AND (";
1616 for(i=0; i<nCol; i++){
1617 if( aiFlg[i] ) continue;
1618 strPrintf(&sql, "%sA.%s IS NOT B.%s", zSep, azCol[i], azCol[i]);
1619 zSep = " OR\n ";
1621 strPrintf(&sql,")\n UNION ALL\n");
1623 strPrintf(&sql, "SELECT %d", SQLITE_DELETE);
1624 for(i=0; i<nCol; i++){
1625 if( aiFlg[i] ){
1626 strPrintf(&sql, ",\n A.%s", azCol[i]);
1627 }else{
1628 strPrintf(&sql, ",\n 1, A.%s, NULL", azCol[i]);
1631 strPrintf(&sql, "\n FROM main.%s A\n", zId);
1632 strPrintf(&sql, " WHERE NOT EXISTS(SELECT 1 FROM aux.%s B\n", zId);
1633 zSep = " WHERE";
1634 for(i=0; i<nPk; i++){
1635 strPrintf(&sql, "%s A.%s=B.%s", zSep, azCol[aiPk[i]], azCol[aiPk[i]]);
1636 zSep = " AND";
1638 strPrintf(&sql, ")\n UNION ALL\n");
1639 strPrintf(&sql, "SELECT %d", SQLITE_INSERT);
1640 for(i=0; i<nCol; i++){
1641 if( aiFlg[i] ){
1642 strPrintf(&sql, ",\n B.%s", azCol[i]);
1643 }else{
1644 strPrintf(&sql, ",\n 1, NULL, B.%s", azCol[i]);
1647 strPrintf(&sql, "\n FROM aux.%s B\n", zId);
1648 strPrintf(&sql, " WHERE NOT EXISTS(SELECT 1 FROM main.%s A\n", zId);
1649 zSep = " WHERE";
1650 for(i=0; i<nPk; i++){
1651 strPrintf(&sql, "%s A.%s=B.%s", zSep, azCol[aiPk[i]], azCol[aiPk[i]]);
1652 zSep = " AND";
1654 strPrintf(&sql, ")\n");
1655 strPrintf(&sql, " ORDER BY");
1656 zSep = " ";
1657 for(i=0; i<nPk; i++){
1658 strPrintf(&sql, "%s %d", zSep, aiPk[i]+2);
1659 zSep = ",";
1661 strPrintf(&sql, ";\n");
1663 if( g.fDebug & DEBUG_DIFF_SQL ){
1664 printf("SQL for %s:\n%s\n", zId, sql.z);
1665 goto end_changeset_one_table;
1668 putc('T', out);
1669 putsVarint(out, (sqlite3_uint64)nCol);
1670 for(i=0; i<nCol; i++) putc(aiFlg[i], out);
1671 fwrite(zTab, 1, strlen(zTab), out);
1672 putc(0, out);
1674 pStmt = db_prepare("%s", sql.z);
1675 while( SQLITE_ROW==sqlite3_step(pStmt) ){
1676 int iType = sqlite3_column_int(pStmt,0);
1677 putc(iType, out);
1678 putc(0, out);
1679 switch( sqlite3_column_int(pStmt,0) ){
1680 case SQLITE_UPDATE: {
1681 for(k=1, i=0; i<nCol; i++){
1682 if( aiFlg[i] ){
1683 putValue(out, sqlite3_column_value(pStmt,k));
1684 k++;
1685 }else if( sqlite3_column_int(pStmt,k) ){
1686 putValue(out, sqlite3_column_value(pStmt,k+1));
1687 k += 3;
1688 }else{
1689 putc(0, out);
1690 k += 3;
1693 for(k=1, i=0; i<nCol; i++){
1694 if( aiFlg[i] ){
1695 putc(0, out);
1696 k++;
1697 }else if( sqlite3_column_int(pStmt,k) ){
1698 putValue(out, sqlite3_column_value(pStmt,k+2));
1699 k += 3;
1700 }else{
1701 putc(0, out);
1702 k += 3;
1705 break;
1707 case SQLITE_INSERT: {
1708 for(k=1, i=0; i<nCol; i++){
1709 if( aiFlg[i] ){
1710 putValue(out, sqlite3_column_value(pStmt,k));
1711 k++;
1712 }else{
1713 putValue(out, sqlite3_column_value(pStmt,k+2));
1714 k += 3;
1717 break;
1719 case SQLITE_DELETE: {
1720 for(k=1, i=0; i<nCol; i++){
1721 if( aiFlg[i] ){
1722 putValue(out, sqlite3_column_value(pStmt,k));
1723 k++;
1724 }else{
1725 putValue(out, sqlite3_column_value(pStmt,k+1));
1726 k += 3;
1729 break;
1733 sqlite3_finalize(pStmt);
1735 end_changeset_one_table:
1736 while( nCol>0 ) sqlite3_free(azCol[--nCol]);
1737 sqlite3_free(azCol);
1738 sqlite3_free(aiPk);
1739 sqlite3_free(zId);
1743 ** Extract the next SQL keyword or quoted string from buffer zIn and copy it
1744 ** (or a prefix of it if it will not fit) into buffer zBuf, size nBuf bytes.
1745 ** Return a pointer to the character within zIn immediately following
1746 ** the token or quoted string just extracted.
1748 const char *gobble_token(const char *zIn, char *zBuf, int nBuf){
1749 const char *p = zIn;
1750 char *pOut = zBuf;
1751 char *pEnd = &pOut[nBuf-1];
1752 char q = 0; /* quote character, if any */
1754 if( p==0 ) return 0;
1755 while( *p==' ' ) p++;
1756 switch( *p ){
1757 case '"': q = '"'; break;
1758 case '\'': q = '\''; break;
1759 case '`': q = '`'; break;
1760 case '[': q = ']'; break;
1763 if( q ){
1764 p++;
1765 while( *p && pOut<pEnd ){
1766 if( *p==q ){
1767 p++;
1768 if( *p!=q ) break;
1770 if( pOut<pEnd ) *pOut++ = *p;
1771 p++;
1773 }else{
1774 while( *p && *p!=' ' && *p!='(' ){
1775 if( pOut<pEnd ) *pOut++ = *p;
1776 p++;
1780 *pOut = '\0';
1781 return p;
1785 ** This function is the implementation of SQL scalar function "module_name":
1787 ** module_name(SQL)
1789 ** The only argument should be an SQL statement of the type that may appear
1790 ** in the sqlite_master table. If the statement is a "CREATE VIRTUAL TABLE"
1791 ** statement, then the value returned is the name of the module that it
1792 ** uses. Otherwise, if the statement is not a CVT, NULL is returned.
1794 static void module_name_func(
1795 sqlite3_context *pCtx,
1796 int nVal, sqlite3_value **apVal
1798 const char *zSql;
1799 char zToken[32];
1801 assert( nVal==1 );
1802 zSql = (const char*)sqlite3_value_text(apVal[0]);
1804 zSql = gobble_token(zSql, zToken, sizeof(zToken));
1805 if( zSql==0 || sqlite3_stricmp(zToken, "create") ) return;
1806 zSql = gobble_token(zSql, zToken, sizeof(zToken));
1807 if( zSql==0 || sqlite3_stricmp(zToken, "virtual") ) return;
1808 zSql = gobble_token(zSql, zToken, sizeof(zToken));
1809 if( zSql==0 || sqlite3_stricmp(zToken, "table") ) return;
1810 zSql = gobble_token(zSql, zToken, sizeof(zToken));
1811 if( zSql==0 ) return;
1812 zSql = gobble_token(zSql, zToken, sizeof(zToken));
1813 if( zSql==0 || sqlite3_stricmp(zToken, "using") ) return;
1814 zSql = gobble_token(zSql, zToken, sizeof(zToken));
1816 sqlite3_result_text(pCtx, zToken, -1, SQLITE_TRANSIENT);
1820 ** Return the text of an SQL statement that itself returns the list of
1821 ** tables to process within the database.
1823 const char *all_tables_sql(){
1824 if( g.bHandleVtab ){
1825 int rc;
1827 rc = sqlite3_exec(g.db,
1828 "CREATE TEMP TABLE tblmap(module COLLATE nocase, postfix);"
1829 "INSERT INTO temp.tblmap VALUES"
1830 "('fts3', '_content'), ('fts3', '_segments'), ('fts3', '_segdir'),"
1832 "('fts4', '_content'), ('fts4', '_segments'), ('fts4', '_segdir'),"
1833 "('fts4', '_docsize'), ('fts4', '_stat'),"
1835 "('fts5', '_data'), ('fts5', '_idx'), ('fts5', '_content'),"
1836 "('fts5', '_docsize'), ('fts5', '_config'),"
1838 "('rtree', '_node'), ('rtree', '_rowid'), ('rtree', '_parent');"
1839 , 0, 0, 0
1841 assert( rc==SQLITE_OK );
1843 rc = sqlite3_create_function(
1844 g.db, "module_name", 1, SQLITE_UTF8, 0, module_name_func, 0, 0
1846 assert( rc==SQLITE_OK );
1848 return
1849 "SELECT name FROM main.sqlite_master\n"
1850 " WHERE type='table' AND (\n"
1851 " module_name(sql) IS NULL OR \n"
1852 " module_name(sql) IN (SELECT module FROM temp.tblmap)\n"
1853 " ) AND name NOT IN (\n"
1854 " SELECT a.name || b.postfix \n"
1855 "FROM main.sqlite_master AS a, temp.tblmap AS b \n"
1856 "WHERE module_name(a.sql) = b.module\n"
1857 " )\n"
1858 "UNION \n"
1859 "SELECT name FROM aux.sqlite_master\n"
1860 " WHERE type='table' AND (\n"
1861 " module_name(sql) IS NULL OR \n"
1862 " module_name(sql) IN (SELECT module FROM temp.tblmap)\n"
1863 " ) AND name NOT IN (\n"
1864 " SELECT a.name || b.postfix \n"
1865 "FROM aux.sqlite_master AS a, temp.tblmap AS b \n"
1866 "WHERE module_name(a.sql) = b.module\n"
1867 " )\n"
1868 " ORDER BY name";
1869 }else{
1870 return
1871 "SELECT name FROM main.sqlite_master\n"
1872 " WHERE type='table' AND sql NOT LIKE 'CREATE VIRTUAL%%'\n"
1873 " UNION\n"
1874 "SELECT name FROM aux.sqlite_master\n"
1875 " WHERE type='table' AND sql NOT LIKE 'CREATE VIRTUAL%%'\n"
1876 " ORDER BY name";
1881 ** Print sketchy documentation for this utility program
1883 static void showHelp(void){
1884 printf("Usage: %s [options] DB1 DB2\n", g.zArgv0);
1885 printf(
1886 "Output SQL text that would transform DB1 into DB2.\n"
1887 "Options:\n"
1888 " --changeset FILE Write a CHANGESET into FILE\n"
1889 " -L|--lib LIBRARY Load an SQLite extension library\n"
1890 " --primarykey Use schema-defined PRIMARY KEYs\n"
1891 " --rbu Output SQL to create/populate RBU table(s)\n"
1892 " --schema Show only differences in the schema\n"
1893 " --summary Show only a summary of the differences\n"
1894 " --table TAB Show only differences in table TAB\n"
1895 " --transaction Show SQL output inside a transaction\n"
1896 " --vtab Handle fts3, fts4, fts5 and rtree tables\n"
1900 int main(int argc, char **argv){
1901 const char *zDb1 = 0;
1902 const char *zDb2 = 0;
1903 int i;
1904 int rc;
1905 char *zErrMsg = 0;
1906 char *zSql;
1907 sqlite3_stmt *pStmt;
1908 char *zTab = 0;
1909 FILE *out = stdout;
1910 void (*xDiff)(const char*,FILE*) = diff_one_table;
1911 #ifndef SQLITE_OMIT_LOAD_EXTENSION
1912 int nExt = 0;
1913 char **azExt = 0;
1914 #endif
1915 int useTransaction = 0;
1916 int neverUseTransaction = 0;
1918 g.zArgv0 = argv[0];
1919 sqlite3_config(SQLITE_CONFIG_SINGLETHREAD);
1920 for(i=1; i<argc; i++){
1921 const char *z = argv[i];
1922 if( z[0]=='-' ){
1923 z++;
1924 if( z[0]=='-' ) z++;
1925 if( strcmp(z,"changeset")==0 ){
1926 if( i==argc-1 ) cmdlineError("missing argument to %s", argv[i]);
1927 out = fopen(argv[++i], "wb");
1928 if( out==0 ) cmdlineError("cannot open: %s", argv[i]);
1929 xDiff = changeset_one_table;
1930 neverUseTransaction = 1;
1931 }else
1932 if( strcmp(z,"debug")==0 ){
1933 if( i==argc-1 ) cmdlineError("missing argument to %s", argv[i]);
1934 g.fDebug = strtol(argv[++i], 0, 0);
1935 }else
1936 if( strcmp(z,"help")==0 ){
1937 showHelp();
1938 return 0;
1939 }else
1940 #ifndef SQLITE_OMIT_LOAD_EXTENSION
1941 if( strcmp(z,"lib")==0 || strcmp(z,"L")==0 ){
1942 if( i==argc-1 ) cmdlineError("missing argument to %s", argv[i]);
1943 azExt = realloc(azExt, sizeof(azExt[0])*(nExt+1));
1944 if( azExt==0 ) cmdlineError("out of memory");
1945 azExt[nExt++] = argv[++i];
1946 }else
1947 #endif
1948 if( strcmp(z,"primarykey")==0 ){
1949 g.bSchemaPK = 1;
1950 }else
1951 if( strcmp(z,"rbu")==0 ){
1952 xDiff = rbudiff_one_table;
1953 }else
1954 if( strcmp(z,"schema")==0 ){
1955 g.bSchemaOnly = 1;
1956 }else
1957 if( strcmp(z,"summary")==0 ){
1958 xDiff = summarize_one_table;
1959 }else
1960 if( strcmp(z,"table")==0 ){
1961 if( i==argc-1 ) cmdlineError("missing argument to %s", argv[i]);
1962 zTab = argv[++i];
1963 }else
1964 if( strcmp(z,"transaction")==0 ){
1965 useTransaction = 1;
1966 }else
1967 if( strcmp(z,"vtab")==0 ){
1968 g.bHandleVtab = 1;
1969 }else
1971 cmdlineError("unknown option: %s", argv[i]);
1973 }else if( zDb1==0 ){
1974 zDb1 = argv[i];
1975 }else if( zDb2==0 ){
1976 zDb2 = argv[i];
1977 }else{
1978 cmdlineError("unknown argument: %s", argv[i]);
1981 if( zDb2==0 ){
1982 cmdlineError("two database arguments required");
1984 rc = sqlite3_open(zDb1, &g.db);
1985 if( rc ){
1986 cmdlineError("cannot open database file \"%s\"", zDb1);
1988 rc = sqlite3_exec(g.db, "SELECT * FROM sqlite_master", 0, 0, &zErrMsg);
1989 if( rc || zErrMsg ){
1990 cmdlineError("\"%s\" does not appear to be a valid SQLite database", zDb1);
1992 #ifndef SQLITE_OMIT_LOAD_EXTENSION
1993 sqlite3_enable_load_extension(g.db, 1);
1994 for(i=0; i<nExt; i++){
1995 rc = sqlite3_load_extension(g.db, azExt[i], 0, &zErrMsg);
1996 if( rc || zErrMsg ){
1997 cmdlineError("error loading %s: %s", azExt[i], zErrMsg);
2000 free(azExt);
2001 #endif
2002 zSql = sqlite3_mprintf("ATTACH %Q as aux;", zDb2);
2003 rc = sqlite3_exec(g.db, zSql, 0, 0, &zErrMsg);
2004 if( rc || zErrMsg ){
2005 cmdlineError("cannot attach database \"%s\"", zDb2);
2007 rc = sqlite3_exec(g.db, "SELECT * FROM aux.sqlite_master", 0, 0, &zErrMsg);
2008 if( rc || zErrMsg ){
2009 cmdlineError("\"%s\" does not appear to be a valid SQLite database", zDb2);
2012 if( neverUseTransaction ) useTransaction = 0;
2013 if( useTransaction ) fprintf(out, "BEGIN TRANSACTION;\n");
2014 if( xDiff==rbudiff_one_table ){
2015 fprintf(out, "CREATE TABLE IF NOT EXISTS rbu_count"
2016 "(tbl TEXT PRIMARY KEY COLLATE NOCASE, cnt INTEGER) "
2017 "WITHOUT ROWID;\n"
2020 if( zTab ){
2021 xDiff(zTab, out);
2022 }else{
2023 /* Handle tables one by one */
2024 pStmt = db_prepare("%s", all_tables_sql() );
2025 while( SQLITE_ROW==sqlite3_step(pStmt) ){
2026 xDiff((const char*)sqlite3_column_text(pStmt,0), out);
2028 sqlite3_finalize(pStmt);
2030 if( useTransaction ) printf("COMMIT;\n");
2032 /* TBD: Handle trigger differences */
2033 /* TBD: Handle view differences */
2034 sqlite3_close(g.db);
2035 return 0;