src/tool/showwal.c - chromium/src/third_party/sqlite - Git at Google

 /*
 ** A utility for printing content from a write-ahead log file.
 */
 #include <stdio.h>
 #include <ctype.h>
 #include <sys/types.h>
 #include <sys/stat.h>
 #include <fcntl.h>

 #define ISDIGIT(X)  isdigit((unsigned char)(X))
 #define ISPRINT(X)  isprint((unsigned char)(X))

 #if !defined(_MSC_VER)
 #include <unistd.h>
 #else
 #include <io.h>
 #endif

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


 static int pagesize = 1024;     /* Size of a database page */
 static int fd = -1;             /* File descriptor for reading the WAL file */
 static int mxFrame = 0;         /* Last frame */
 static int perLine = 16;        /* HEX elements to print per line */

 typedef long long int i64;      /* Datatype for 64-bit integers */

 /* Information for computing the checksum */
 typedef struct Cksum Cksum;
 struct Cksum {
   int bSwap;           /* True to do byte swapping on 32-bit words */
   unsigned s0, s1;     /* Current checksum value */
 };

 /*
 ** extract a 32-bit big-endian integer
 */
 static unsigned int getInt32(const unsigned char *a){
   unsigned int x = (a[0]<<24) + (a[1]<<16) + (a[2]<<8) + a[3];
   return x;
 }

 /*
 ** Swap bytes on a 32-bit unsigned integer
 */
 static unsigned int swab32(unsigned int x){
   return (((x)&0x000000FF)<<24) + (((x)&0x0000FF00)<<8)
          + (((x)&0x00FF0000)>>8)  + (((x)&0xFF000000)>>24);
 }

 /* Extend the checksum.  Reinitialize the checksum if bInit is true.
 */
 static void extendCksum(
   Cksum *pCksum,
   unsigned char *aData,
   unsigned int nByte,
   int bInit
 ){
   unsigned int *a32;
   if( bInit ){
     int a = 0;
     *((char*)&a) = 1;
     if( a==1 ){
       /* Host is little-endian */
       pCksum->bSwap = getInt32(aData)!=0x377f0682;
     }else{
       /* Host is big-endian */
       pCksum->bSwap = getInt32(aData)!=0x377f0683;
     }
     pCksum->s0 = 0;
     pCksum->s1 = 0;
   }
   a32 = (unsigned int*)aData;
   while( nByte>0 ){
     unsigned int x0 = a32[0];
     unsigned int x1 = a32[1];
     if( pCksum->bSwap ){
       x0 = swab32(x0);
       x1 = swab32(x1);
     }
     pCksum->s0 += x0 + pCksum->s1;
     pCksum->s1 += x1 + pCksum->s0;
     nByte -= 8;
     a32 += 2;
   }
 }

 /*
 ** Convert the var-int format into i64.  Return the number of bytes
 ** in the var-int.  Write the var-int value into *pVal.
 */
 static int decodeVarint(const unsigned char *z, i64 *pVal){
   i64 v = 0;
   int i;
   for(i=0; i<8; i++){
     v = (v<<7) + (z[i]&0x7f);
     if( (z[i]&0x80)==0 ){ *pVal = v; return i+1; }
   }
   v = (v<<8) + (z[i]&0xff);
   *pVal = v;
   return 9;
 }

 /* Report an out-of-memory error and die.
 */
 static void out_of_memory(void){
   fprintf(stderr,"Out of memory...\n");
   exit(1);
 }

 /*
 ** Read content from the file.
 **
 ** Space to hold the content is obtained from malloc() and needs to be
 ** freed by the caller.
 */
 static unsigned char *getContent(int ofst, int nByte){
   unsigned char *aData;
   aData = malloc(nByte);
   if( aData==0 ) out_of_memory();
   lseek(fd, ofst, SEEK_SET);
   read(fd, aData, nByte);
   return aData;
 }

 /*
 ** Print a range of bytes as hex and as ascii.
 */
 static void print_byte_range(
   int ofst,              /* First byte in the range of bytes to print */
   int nByte,             /* Number of bytes to print */
   unsigned char *aData,  /* Content to print */
   int printOfst          /* Add this amount to the index on the left column */
 ){
   int i, j;
   const char *zOfstFmt;

   if( ((printOfst+nByte)&~0xfff)==0 ){
     zOfstFmt = " %03x: ";
   }else if( ((printOfst+nByte)&~0xffff)==0 ){
     zOfstFmt = " %04x: ";
   }else if( ((printOfst+nByte)&~0xfffff)==0 ){
     zOfstFmt = " %05x: ";
   }else if( ((printOfst+nByte)&~0xffffff)==0 ){
     zOfstFmt = " %06x: ";
   }else{
     zOfstFmt = " %08x: ";
   }

   for(i=0; i<nByte; i += perLine){
     fprintf(stdout, zOfstFmt, i+printOfst);
     for(j=0; j<perLine; j++){
       if( i+j>nByte ){
         fprintf(stdout, "   ");
       }else{
         fprintf(stdout,"%02x ", aData[i+j]);
       }
     }
     for(j=0; j<perLine; j++){
       if( i+j>nByte ){
         fprintf(stdout, " ");
       }else{
         fprintf(stdout,"%c", ISPRINT(aData[i+j]) ? aData[i+j] : '.');
       }
     }
     fprintf(stdout,"\n");
   }
 }

 /* Print a line of decode output showing a 4-byte integer.
 */
 static void print_decode_line(
   unsigned char *aData,      /* Content being decoded */
   int ofst, int nByte,       /* Start and size of decode */
   int asHex,                 /* If true, output value as hex */
   const char *zMsg           /* Message to append */
 ){
   int i, j;
   int val = aData[ofst];
   char zBuf[100];
   sprintf(zBuf, " %03x: %02x", ofst, aData[ofst]);
   i = (int)strlen(zBuf);
   for(j=1; j<4; j++){
     if( j>=nByte ){
       sprintf(&zBuf[i], "   ");
     }else{
       sprintf(&zBuf[i], " %02x", aData[ofst+j]);
       val = val*256 + aData[ofst+j];
     }
     i += (int)strlen(&zBuf[i]);
   }
   if( asHex ){
     sprintf(&zBuf[i], "  0x%08x", val);
   }else{
     sprintf(&zBuf[i], "   %9d", val);
   }
   printf("%s  %s\n", zBuf, zMsg);
 }

 /*
 ** Print an entire page of content as hex
 */
 static void print_frame(int iFrame){
   int iStart;
   unsigned char *aData;
   iStart = 32 + (iFrame-1)*(pagesize+24);
   fprintf(stdout, "Frame %d:   (offsets 0x%x..0x%x)\n",
           iFrame, iStart, iStart+pagesize+24);
   aData = getContent(iStart, pagesize+24);
   print_decode_line(aData, 0, 4, 0, "Page number");
   print_decode_line(aData, 4, 4, 0, "DB size, or 0 for non-commit");
   print_decode_line(aData, 8, 4, 1, "Salt-1");
   print_decode_line(aData,12, 4, 1, "Salt-2");
   print_decode_line(aData,16, 4, 1, "Checksum-1");
   print_decode_line(aData,20, 4, 1, "Checksum-2");
   print_byte_range(iStart+24, pagesize, aData+24, 0);
   free(aData);
 }

 /*
 ** Summarize a single frame on a single line.
 */
 static void print_oneline_frame(int iFrame, Cksum *pCksum){
   int iStart;
   unsigned char *aData;
   unsigned int s0, s1;
   iStart = 32 + (iFrame-1)*(pagesize+24);
   aData = getContent(iStart, 24);
   extendCksum(pCksum, aData, 8, 0);
   extendCksum(pCksum, getContent(iStart+24, pagesize), pagesize, 0);
   s0 = getInt32(aData+16);
   s1 = getInt32(aData+20);
   fprintf(stdout, "Frame %4d: %6d %6d 0x%08x,%08x 0x%08x,%08x %s\n",
           iFrame,
           getInt32(aData),
           getInt32(aData+4),
           getInt32(aData+8),
           getInt32(aData+12),
           s0,
           s1,
           (s0==pCksum->s0 && s1==pCksum->s1) ? "" : "cksum-fail"
   );

   /* Reset the checksum so that a single frame checksum failure will not
   ** cause all subsequent frames to also show a failure. */
   pCksum->s0 = s0;
   pCksum->s1 = s1;
   free(aData);
 }

 /*
 ** Decode the WAL header.
 */
 static void print_wal_header(Cksum *pCksum){
   unsigned char *aData;
   aData = getContent(0, 32);
   if( pCksum ){
     extendCksum(pCksum, aData, 24, 1);
     printf("Checksum byte order: %s\n", pCksum->bSwap ? "swapped" : "native");
   }
   printf("WAL Header:\n");
   print_decode_line(aData, 0, 4,1,"Magic.  0x377f0682 (le) or 0x377f0683 (be)");
   print_decode_line(aData, 4, 4, 0, "File format");
   print_decode_line(aData, 8, 4, 0, "Database page size");
   print_decode_line(aData, 12,4, 0, "Checkpoint sequence number");
   print_decode_line(aData, 16,4, 1, "Salt-1");
   print_decode_line(aData, 20,4, 1, "Salt-2");
   print_decode_line(aData, 24,4, 1, "Checksum-1");
   print_decode_line(aData, 28,4, 1, "Checksum-2");
   if( pCksum ){
     if( pCksum->s0!=getInt32(aData+24) ){
       printf("**** cksum-1 mismatch: 0x%08x\n", pCksum->s0);
     }
     if( pCksum->s1!=getInt32(aData+28) ){
       printf("**** cksum-2 mismatch: 0x%08x\n", pCksum->s1);
     }
   }
   free(aData);
 }
 /*
 ** Describe cell content.
 */
 static i64 describeContent(
   unsigned char *a,       /* Cell content */
   i64 nLocal,             /* Bytes in a[] */
   char *zDesc             /* Write description here */
 ){
   int nDesc = 0;
   int n, j;
   i64 i, x, v;
   const unsigned char *pData;
   const unsigned char *pLimit;
   char sep = ' ';

   pLimit = &a[nLocal];
   n = decodeVarint(a, &x);
   pData = &a[x];
   a += n;
   i = x - n;
   while( i>0 && pData<=pLimit ){
     n = decodeVarint(a, &x);
     a += n;
     i -= n;
     nLocal -= n;
     zDesc[0] = sep;
     sep = ',';
     nDesc++;
     zDesc++;
     if( x==0 ){
       sprintf(zDesc, "*");     /* NULL is a "*" */
     }else if( x>=1 && x<=6 ){
       v = (signed char)pData[0];
       pData++;
       switch( x ){
         case 6:  v = (v<<16) + (pData[0]<<8) + pData[1];  pData += 2;
         case 5:  v = (v<<16) + (pData[0]<<8) + pData[1];  pData += 2;
         case 4:  v = (v<<8) + pData[0];  pData++;
         case 3:  v = (v<<8) + pData[0];  pData++;
         case 2:  v = (v<<8) + pData[0];  pData++;
       }
       sprintf(zDesc, "%lld", v);
     }else if( x==7 ){
       sprintf(zDesc, "real");
       pData += 8;
     }else if( x==8 ){
       sprintf(zDesc, "0");
     }else if( x==9 ){
       sprintf(zDesc, "1");
     }else if( x>=12 ){
       i64 size = (x-12)/2;
       if( (x&1)==0 ){
         sprintf(zDesc, "blob(%lld)", size);
       }else{
         sprintf(zDesc, "txt(%lld)", size);
       }
       pData += size;
     }
     j = (int)strlen(zDesc);
     zDesc += j;
     nDesc += j;
   }
   return nDesc;
 }

 /*
 ** Compute the local payload size given the total payload size and
 ** the page size.
 */
 static i64 localPayload(i64 nPayload, char cType){
   i64 maxLocal;
   i64 minLocal;
   i64 surplus;
   i64 nLocal;
   if( cType==13 ){
     /* Table leaf */
     maxLocal = pagesize-35;
     minLocal = (pagesize-12)*32/255-23;
   }else{
     maxLocal = (pagesize-12)*64/255-23;
     minLocal = (pagesize-12)*32/255-23;
   }
   if( nPayload>maxLocal ){
     surplus = minLocal + (nPayload-minLocal)%(pagesize-4);
     if( surplus<=maxLocal ){
       nLocal = surplus;
     }else{
       nLocal = minLocal;
     }
   }else{
     nLocal = nPayload;
   }
   return nLocal;
 }

 /*
 ** Create a description for a single cell.
 **
 ** The return value is the local cell size.
 */
 static i64 describeCell(
   unsigned char cType,    /* Page type */
   unsigned char *a,       /* Cell content */
   int showCellContent,    /* Show cell content if true */
   char **pzDesc           /* Store description here */
 ){
   int i;
   i64 nDesc = 0;
   int n = 0;
   int leftChild;
   i64 nPayload;
   i64 rowid;
   i64 nLocal;
   static char zDesc[1000];
   i = 0;
   if( cType<=5 ){
     leftChild = ((a[0]*256 + a[1])*256 + a[2])*256 + a[3];
     a += 4;
     n += 4;
     sprintf(zDesc, "lx: %d ", leftChild);
     nDesc = strlen(zDesc);
   }
   if( cType!=5 ){
     i = decodeVarint(a, &nPayload);
     a += i;
     n += i;
     sprintf(&zDesc[nDesc], "n: %lld ", nPayload);
     nDesc += strlen(&zDesc[nDesc]);
     nLocal = localPayload(nPayload, cType);
   }else{
     nPayload = nLocal = 0;
   }
   if( cType==5 || cType==13 ){
     i = decodeVarint(a, &rowid);
     a += i;
     n += i;
     sprintf(&zDesc[nDesc], "r: %lld ", rowid);
     nDesc += strlen(&zDesc[nDesc]);
   }
   if( nLocal<nPayload ){
     int ovfl;
     unsigned char *b = &a[nLocal];
     ovfl = ((b[0]*256 + b[1])*256 + b[2])*256 + b[3];
     sprintf(&zDesc[nDesc], "ov: %d ", ovfl);
     nDesc += strlen(&zDesc[nDesc]);
     n += 4;
   }
   if( showCellContent && cType!=5 ){
     nDesc += describeContent(a, nLocal, &zDesc[nDesc-1]);
   }
   *pzDesc = zDesc;
   return nLocal+n;
 }

 /*
 ** Decode a btree page
 */
 static void decode_btree_page(
   unsigned char *a,   /* Content of the btree page to be decoded */
   int pgno,           /* Page number */
   int hdrSize,        /* Size of the page1-header in bytes */
   const char *zArgs   /* Flags to control formatting */
 ){
   const char *zType = "unknown";
   int nCell;
   int i, j;
   int iCellPtr;
   int showCellContent = 0;
   int showMap = 0;
   char *zMap = 0;
   switch( a[0] ){
     case 2:  zType = "index interior node";  break;
     case 5:  zType = "table interior node";  break;
     case 10: zType = "index leaf";           break;
     case 13: zType = "table leaf";           break;
   }
   while( zArgs[0] ){
     switch( zArgs[0] ){
       case 'c': showCellContent = 1;  break;
       case 'm': showMap = 1;          break;
     }
     zArgs++;
   }
   printf("Decode of btree page %d:\n", pgno);
   print_decode_line(a, 0, 1, 0, zType);
   print_decode_line(a, 1, 2, 0, "Offset to first freeblock");
   print_decode_line(a, 3, 2, 0, "Number of cells on this page");
   nCell = a[3]*256 + a[4];
   print_decode_line(a, 5, 2, 0, "Offset to cell content area");
   print_decode_line(a, 7, 1, 0, "Fragmented byte count");
   if( a[0]==2 || a[0]==5 ){
     print_decode_line(a, 8, 4, 0, "Right child");
     iCellPtr = 12;
   }else{
     iCellPtr = 8;
   }
   if( nCell>0 ){
     printf(" key: lx=left-child n=payload-size r=rowid\n");
   }
   if( showMap ){
     zMap = malloc(pagesize);
     memset(zMap, '.', pagesize);
     memset(zMap, '1', hdrSize);
     memset(&zMap[hdrSize], 'H', iCellPtr);
     memset(&zMap[hdrSize+iCellPtr], 'P', 2*nCell);
   }
   for(i=0; i<nCell; i++){
     int cofst = iCellPtr + i*2;
     char *zDesc;
     i64 n;

     cofst = a[cofst]*256 + a[cofst+1];
     n = describeCell(a[0], &a[cofst-hdrSize], showCellContent, &zDesc);
     if( showMap ){
       char zBuf[30];
       memset(&zMap[cofst], '*', (size_t)n);
       zMap[cofst] = '[';
       zMap[cofst+n-1] = ']';
       sprintf(zBuf, "%d", i);
       j = (int)strlen(zBuf);
       if( j<=n-2 ) memcpy(&zMap[cofst+1], zBuf, j);
     }
     printf(" %03x: cell[%d] %s\n", cofst, i, zDesc);
   }
   if( showMap ){
     for(i=0; i<pagesize; i+=64){
       printf(" %03x: %.64s\n", i, &zMap[i]);
     }
     free(zMap);
   }
 }

 int main(int argc, char **argv){
   struct stat sbuf;
   unsigned char zPgSz[4];
   if( argc<2 ){
     fprintf(stderr,"Usage: %s FILENAME ?PAGE? ...\n", argv[0]);
     exit(1);
   }
   fd = open(argv[1], O_RDONLY);
   if( fd<0 ){
     fprintf(stderr,"%s: can't open %s\n", argv[0], argv[1]);
     exit(1);
   }
   zPgSz[0] = 0;
   zPgSz[1] = 0;
   lseek(fd, 8, SEEK_SET);
   read(fd, zPgSz, 4);
   pagesize = zPgSz[1]*65536 + zPgSz[2]*256 + zPgSz[3];
   if( pagesize==0 ) pagesize = 1024;
   printf("Pagesize: %d\n", pagesize);
   fstat(fd, &sbuf);
   if( sbuf.st_size<32 ){
     printf("file too small to be a WAL\n");
     return 0;
   }
   mxFrame = (sbuf.st_size - 32)/(pagesize + 24);
   printf("Available pages: 1..%d\n", mxFrame);
   if( argc==2 ){
     int i;
     Cksum x;
     print_wal_header(&x);
     for(i=1; i<=mxFrame; i++){
       print_oneline_frame(i, &x);
     }
   }else{
     int i;
     for(i=2; i<argc; i++){
       int iStart, iEnd;
       char *zLeft;
       if( strcmp(argv[i], "header")==0 ){
         print_wal_header(0);
         continue;
       }
       if( !ISDIGIT(argv[i][0]) ){
         fprintf(stderr, "%s: unknown option: [%s]\n", argv[0], argv[i]);
         continue;
       }
       iStart = strtol(argv[i], &zLeft, 0);
       if( zLeft && strcmp(zLeft,"..end")==0 ){
         iEnd = mxFrame;
       }else if( zLeft && zLeft[0]=='.' && zLeft[1]=='.' ){
         iEnd = strtol(&zLeft[2], 0, 0);
       }else if( zLeft && zLeft[0]=='b' ){
         int ofst, nByte, hdrSize;
         unsigned char *a;
         if( iStart==1 ){
           hdrSize = 100;
           ofst = hdrSize = 100;
           nByte = pagesize-100;
         }else{
           hdrSize = 0;
           ofst = (iStart-1)*pagesize;
           nByte = pagesize;
         }
         ofst = 32 + hdrSize + (iStart-1)*(pagesize+24) + 24;
         a = getContent(ofst, nByte);
         decode_btree_page(a, iStart, hdrSize, zLeft+1);
         free(a);
         continue;
       }else{
         iEnd = iStart;
       }
       if( iStart<1 || iEnd<iStart || iEnd>mxFrame ){
         fprintf(stderr,
           "Page argument should be LOWER?..UPPER?.  Range 1 to %d\n",
           mxFrame);
         exit(1);
       }
       while( iStart<=iEnd ){
         print_frame(iStart);
         iStart++;
       }
     }
   }
   close(fd);
   return 0;
 }
	/*
	** A utility for printing content from a write-ahead log file.
	*/
	#include <stdio.h>
	#include <ctype.h>
	#include <sys/types.h>
	#include <sys/stat.h>
	#include <fcntl.h>

	#define ISDIGIT(X) isdigit((unsigned char)(X))
	#define ISPRINT(X) isprint((unsigned char)(X))

	#if !defined(_MSC_VER)
	#include <unistd.h>
	#else
	#include <io.h>
	#endif

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


	static int pagesize = 1024; /* Size of a database page */
	static int fd = -1; /* File descriptor for reading the WAL file */
	static int mxFrame = 0; /* Last frame */
	static int perLine = 16; /* HEX elements to print per line */

	typedef long long int i64; /* Datatype for 64-bit integers */

	/* Information for computing the checksum */
	typedef struct Cksum Cksum;
	struct Cksum {
	int bSwap; /* True to do byte swapping on 32-bit words */
	unsigned s0, s1; /* Current checksum value */
	};

	/*
	** extract a 32-bit big-endian integer
	*/
	static unsigned int getInt32(const unsigned char *a){
	unsigned int x = (a[0]<<24) + (a[1]<<16) + (a[2]<<8) + a[3];
	return x;
	}

	/*
	** Swap bytes on a 32-bit unsigned integer
	*/
	static unsigned int swab32(unsigned int x){
	return (((x)&0x000000FF)<<24) + (((x)&0x0000FF00)<<8)
	+ (((x)&0x00FF0000)>>8) + (((x)&0xFF000000)>>24);
	}

	/* Extend the checksum. Reinitialize the checksum if bInit is true.
	*/
	static void extendCksum(
	Cksum *pCksum,
	unsigned char *aData,
	unsigned int nByte,
	int bInit
	){
	unsigned int *a32;
	if( bInit ){
	int a = 0;
	((char)&a) = 1;
	if( a==1 ){
	/* Host is little-endian */
	pCksum->bSwap = getInt32(aData)!=0x377f0682;
	}else{
	/* Host is big-endian */
	pCksum->bSwap = getInt32(aData)!=0x377f0683;
	}
	pCksum->s0 = 0;
	pCksum->s1 = 0;
	}
	a32 = (unsigned int*)aData;
	while( nByte>0 ){
	unsigned int x0 = a32[0];
	unsigned int x1 = a32[1];
	if( pCksum->bSwap ){
	x0 = swab32(x0);
	x1 = swab32(x1);
	}
	pCksum->s0 += x0 + pCksum->s1;
	pCksum->s1 += x1 + pCksum->s0;
	nByte -= 8;
	a32 += 2;
	}
	}

	/*
	** Convert the var-int format into i64. Return the number of bytes
	** in the var-int. Write the var-int value into *pVal.
	*/
	static int decodeVarint(const unsigned char z, i64 pVal){
	i64 v = 0;
	int i;
	for(i=0; i<8; i++){
	v = (v<<7) + (z[i]&0x7f);
	if( (z[i]&0x80)==0 ){ *pVal = v; return i+1; }
	}
	v = (v<<8) + (z[i]&0xff);
	*pVal = v;
	return 9;
	}

	/* Report an out-of-memory error and die.
	*/
	static void out_of_memory(void){
	fprintf(stderr,"Out of memory...\n");
	exit(1);
	}

	/*
	** Read content from the file.
	**
	** Space to hold the content is obtained from malloc() and needs to be
	** freed by the caller.
	*/
	static unsigned char *getContent(int ofst, int nByte){
	unsigned char *aData;
	aData = malloc(nByte);
	if( aData==0 ) out_of_memory();
	lseek(fd, ofst, SEEK_SET);
	read(fd, aData, nByte);
	return aData;
	}

	/*
	** Print a range of bytes as hex and as ascii.
	*/
	static void print_byte_range(
	int ofst, /* First byte in the range of bytes to print */
	int nByte, /* Number of bytes to print */
	unsigned char aData, / Content to print */
	int printOfst /* Add this amount to the index on the left column */
	){
	int i, j;
	const char *zOfstFmt;

	if( ((printOfst+nByte)&~0xfff)==0 ){
	zOfstFmt = " %03x: ";
	}else if( ((printOfst+nByte)&~0xffff)==0 ){
	zOfstFmt = " %04x: ";
	}else if( ((printOfst+nByte)&~0xfffff)==0 ){
	zOfstFmt = " %05x: ";
	}else if( ((printOfst+nByte)&~0xffffff)==0 ){
	zOfstFmt = " %06x: ";
	}else{
	zOfstFmt = " %08x: ";
	}

	for(i=0; i<nByte; i += perLine){
	fprintf(stdout, zOfstFmt, i+printOfst);
	for(j=0; j<perLine; j++){
	if( i+j>nByte ){
	fprintf(stdout, " ");
	}else{
	fprintf(stdout,"%02x ", aData[i+j]);
	}
	}
	for(j=0; j<perLine; j++){
	if( i+j>nByte ){
	fprintf(stdout, " ");
	}else{
	fprintf(stdout,"%c", ISPRINT(aData[i+j]) ? aData[i+j] : '.');
	}
	}
	fprintf(stdout,"\n");
	}
	}

	/* Print a line of decode output showing a 4-byte integer.
	*/
	static void print_decode_line(
	unsigned char aData, / Content being decoded */
	int ofst, int nByte, /* Start and size of decode */
	int asHex, /* If true, output value as hex */
	const char zMsg / Message to append */
	){
	int i, j;
	int val = aData[ofst];
	char zBuf[100];
	sprintf(zBuf, " %03x: %02x", ofst, aData[ofst]);
	i = (int)strlen(zBuf);
	for(j=1; j<4; j++){
	if( j>=nByte ){
	sprintf(&zBuf[i], " ");
	}else{
	sprintf(&zBuf[i], " %02x", aData[ofst+j]);
	val = val*256 + aData[ofst+j];
	}
	i += (int)strlen(&zBuf[i]);
	}
	if( asHex ){
	sprintf(&zBuf[i], " 0x%08x", val);
	}else{
	sprintf(&zBuf[i], " %9d", val);
	}
	printf("%s %s\n", zBuf, zMsg);
	}

	/*
	** Print an entire page of content as hex
	*/
	static void print_frame(int iFrame){
	int iStart;
	unsigned char *aData;
	iStart = 32 + (iFrame-1)*(pagesize+24);
	fprintf(stdout, "Frame %d: (offsets 0x%x..0x%x)\n",
	iFrame, iStart, iStart+pagesize+24);
	aData = getContent(iStart, pagesize+24);
	print_decode_line(aData, 0, 4, 0, "Page number");
	print_decode_line(aData, 4, 4, 0, "DB size, or 0 for non-commit");
	print_decode_line(aData, 8, 4, 1, "Salt-1");
	print_decode_line(aData,12, 4, 1, "Salt-2");
	print_decode_line(aData,16, 4, 1, "Checksum-1");
	print_decode_line(aData,20, 4, 1, "Checksum-2");
	print_byte_range(iStart+24, pagesize, aData+24, 0);
	free(aData);
	}

	/*
	** Summarize a single frame on a single line.
	*/
	static void print_oneline_frame(int iFrame, Cksum *pCksum){
	int iStart;
	unsigned char *aData;
	unsigned int s0, s1;
	iStart = 32 + (iFrame-1)*(pagesize+24);
	aData = getContent(iStart, 24);
	extendCksum(pCksum, aData, 8, 0);
	extendCksum(pCksum, getContent(iStart+24, pagesize), pagesize, 0);
	s0 = getInt32(aData+16);
	s1 = getInt32(aData+20);
	fprintf(stdout, "Frame %4d: %6d %6d 0x%08x,%08x 0x%08x,%08x %s\n",
	iFrame,
	getInt32(aData),
	getInt32(aData+4),
	getInt32(aData+8),
	getInt32(aData+12),
	s0,
	s1,
	(s0==pCksum->s0 && s1==pCksum->s1) ? "" : "cksum-fail"
	);

	/* Reset the checksum so that a single frame checksum failure will not
	** cause all subsequent frames to also show a failure. */
	pCksum->s0 = s0;
	pCksum->s1 = s1;
	free(aData);
	}

	/*
	** Decode the WAL header.
	*/
	static void print_wal_header(Cksum *pCksum){
	unsigned char *aData;
	aData = getContent(0, 32);
	if( pCksum ){
	extendCksum(pCksum, aData, 24, 1);
	printf("Checksum byte order: %s\n", pCksum->bSwap ? "swapped" : "native");
	}
	printf("WAL Header:\n");
	print_decode_line(aData, 0, 4,1,"Magic. 0x377f0682 (le) or 0x377f0683 (be)");
	print_decode_line(aData, 4, 4, 0, "File format");
	print_decode_line(aData, 8, 4, 0, "Database page size");
	print_decode_line(aData, 12,4, 0, "Checkpoint sequence number");
	print_decode_line(aData, 16,4, 1, "Salt-1");
	print_decode_line(aData, 20,4, 1, "Salt-2");
	print_decode_line(aData, 24,4, 1, "Checksum-1");
	print_decode_line(aData, 28,4, 1, "Checksum-2");
	if( pCksum ){
	if( pCksum->s0!=getInt32(aData+24) ){
	printf("**** cksum-1 mismatch: 0x%08x\n", pCksum->s0);
	}
	if( pCksum->s1!=getInt32(aData+28) ){
	printf("**** cksum-2 mismatch: 0x%08x\n", pCksum->s1);
	}
	}
	free(aData);
	}
	/*
	** Describe cell content.
	*/
	static i64 describeContent(
	unsigned char a, / Cell content */
	i64 nLocal, /* Bytes in a[] */
	char zDesc / Write description here */
	){
	int nDesc = 0;
	int n, j;
	i64 i, x, v;
	const unsigned char *pData;
	const unsigned char *pLimit;
	char sep = ' ';

	pLimit = &a[nLocal];
	n = decodeVarint(a, &x);
	pData = &a[x];
	a += n;
	i = x - n;
	while( i>0 && pData<=pLimit ){
	n = decodeVarint(a, &x);
	a += n;
	i -= n;
	nLocal -= n;
	zDesc[0] = sep;
	sep = ',';
	nDesc++;
	zDesc++;
	if( x==0 ){
	sprintf(zDesc, ""); / NULL is a "" /
	}else if( x>=1 && x<=6 ){
	v = (signed char)pData[0];
	pData++;
	switch( x ){
	case 6: v = (v<<16) + (pData[0]<<8) + pData[1]; pData += 2;
	case 5: v = (v<<16) + (pData[0]<<8) + pData[1]; pData += 2;
	case 4: v = (v<<8) + pData[0]; pData++;
	case 3: v = (v<<8) + pData[0]; pData++;
	case 2: v = (v<<8) + pData[0]; pData++;
	}
	sprintf(zDesc, "%lld", v);
	}else if( x==7 ){
	sprintf(zDesc, "real");
	pData += 8;
	}else if( x==8 ){
	sprintf(zDesc, "0");
	}else if( x==9 ){
	sprintf(zDesc, "1");
	}else if( x>=12 ){
	i64 size = (x-12)/2;
	if( (x&1)==0 ){
	sprintf(zDesc, "blob(%lld)", size);
	}else{
	sprintf(zDesc, "txt(%lld)", size);
	}
	pData += size;
	}
	j = (int)strlen(zDesc);
	zDesc += j;
	nDesc += j;
	}
	return nDesc;
	}

	/*
	** Compute the local payload size given the total payload size and
	** the page size.
	*/
	static i64 localPayload(i64 nPayload, char cType){
	i64 maxLocal;
	i64 minLocal;
	i64 surplus;
	i64 nLocal;
	if( cType==13 ){
	/* Table leaf */
	maxLocal = pagesize-35;
	minLocal = (pagesize-12)*32/255-23;
	}else{
	maxLocal = (pagesize-12)*64/255-23;
	minLocal = (pagesize-12)*32/255-23;
	}
	if( nPayload>maxLocal ){
	surplus = minLocal + (nPayload-minLocal)%(pagesize-4);
	if( surplus<=maxLocal ){
	nLocal = surplus;
	}else{
	nLocal = minLocal;
	}
	}else{
	nLocal = nPayload;
	}
	return nLocal;
	}

	/*
	** Create a description for a single cell.
	**
	** The return value is the local cell size.
	*/
	static i64 describeCell(
	unsigned char cType, /* Page type */
	unsigned char a, / Cell content */
	int showCellContent, /* Show cell content if true */
	char *pzDesc / Store description here */
	){
	int i;
	i64 nDesc = 0;
	int n = 0;
	int leftChild;
	i64 nPayload;
	i64 rowid;
	i64 nLocal;
	static char zDesc[1000];
	i = 0;
	if( cType<=5 ){
	leftChild = ((a[0]256 + a[1])256 + a[2])*256 + a[3];
	a += 4;
	n += 4;
	sprintf(zDesc, "lx: %d ", leftChild);
	nDesc = strlen(zDesc);
	}
	if( cType!=5 ){
	i = decodeVarint(a, &nPayload);
	a += i;
	n += i;
	sprintf(&zDesc[nDesc], "n: %lld ", nPayload);
	nDesc += strlen(&zDesc[nDesc]);
	nLocal = localPayload(nPayload, cType);
	}else{
	nPayload = nLocal = 0;
	}
	if( cType==5 \|\| cType==13 ){
	i = decodeVarint(a, &rowid);
	a += i;
	n += i;
	sprintf(&zDesc[nDesc], "r: %lld ", rowid);
	nDesc += strlen(&zDesc[nDesc]);
	}
	if( nLocal<nPayload ){
	int ovfl;
	unsigned char *b = &a[nLocal];
	ovfl = ((b[0]256 + b[1])256 + b[2])*256 + b[3];
	sprintf(&zDesc[nDesc], "ov: %d ", ovfl);
	nDesc += strlen(&zDesc[nDesc]);
	n += 4;
	}
	if( showCellContent && cType!=5 ){
	nDesc += describeContent(a, nLocal, &zDesc[nDesc-1]);
	}
	*pzDesc = zDesc;
	return nLocal+n;
	}

	/*
	** Decode a btree page
	*/
	static void decode_btree_page(
	unsigned char a, / Content of the btree page to be decoded */
	int pgno, /* Page number */
	int hdrSize, /* Size of the page1-header in bytes */
	const char zArgs / Flags to control formatting */
	){
	const char *zType = "unknown";
	int nCell;
	int i, j;
	int iCellPtr;
	int showCellContent = 0;
	int showMap = 0;
	char *zMap = 0;
	switch( a[0] ){
	case 2: zType = "index interior node"; break;
	case 5: zType = "table interior node"; break;
	case 10: zType = "index leaf"; break;
	case 13: zType = "table leaf"; break;
	}
	while( zArgs[0] ){
	switch( zArgs[0] ){
	case 'c': showCellContent = 1; break;
	case 'm': showMap = 1; break;
	}
	zArgs++;
	}
	printf("Decode of btree page %d:\n", pgno);
	print_decode_line(a, 0, 1, 0, zType);
	print_decode_line(a, 1, 2, 0, "Offset to first freeblock");
	print_decode_line(a, 3, 2, 0, "Number of cells on this page");
	nCell = a[3]*256 + a[4];
	print_decode_line(a, 5, 2, 0, "Offset to cell content area");
	print_decode_line(a, 7, 1, 0, "Fragmented byte count");
	if( a[0]==2 \|\| a[0]==5 ){
	print_decode_line(a, 8, 4, 0, "Right child");
	iCellPtr = 12;
	}else{
	iCellPtr = 8;
	}
	if( nCell>0 ){
	printf(" key: lx=left-child n=payload-size r=rowid\n");
	}
	if( showMap ){
	zMap = malloc(pagesize);
	memset(zMap, '.', pagesize);
	memset(zMap, '1', hdrSize);
	memset(&zMap[hdrSize], 'H', iCellPtr);
	memset(&zMap[hdrSize+iCellPtr], 'P', 2*nCell);
	}
	for(i=0; i<nCell; i++){
	int cofst = iCellPtr + i*2;
	char *zDesc;
	i64 n;

	cofst = a[cofst]*256 + a[cofst+1];
	n = describeCell(a[0], &a[cofst-hdrSize], showCellContent, &zDesc);
	if( showMap ){
	char zBuf[30];
	memset(&zMap[cofst], '*', (size_t)n);
	zMap[cofst] = '[';
	zMap[cofst+n-1] = ']';
	sprintf(zBuf, "%d", i);
	j = (int)strlen(zBuf);
	if( j<=n-2 ) memcpy(&zMap[cofst+1], zBuf, j);
	}
	printf(" %03x: cell[%d] %s\n", cofst, i, zDesc);
	}
	if( showMap ){
	for(i=0; i<pagesize; i+=64){
	printf(" %03x: %.64s\n", i, &zMap[i]);
	}
	free(zMap);
	}
	}

	int main(int argc, char **argv){
	struct stat sbuf;
	unsigned char zPgSz[4];
	if( argc<2 ){
	fprintf(stderr,"Usage: %s FILENAME ?PAGE? ...\n", argv[0]);
	exit(1);
	}
	fd = open(argv[1], O_RDONLY);
	if( fd<0 ){
	fprintf(stderr,"%s: can't open %s\n", argv[0], argv[1]);
	exit(1);
	}
	zPgSz[0] = 0;
	zPgSz[1] = 0;
	lseek(fd, 8, SEEK_SET);
	read(fd, zPgSz, 4);
	pagesize = zPgSz[1]65536 + zPgSz[2]256 + zPgSz[3];
	if( pagesize==0 ) pagesize = 1024;
	printf("Pagesize: %d\n", pagesize);
	fstat(fd, &sbuf);
	if( sbuf.st_size<32 ){
	printf("file too small to be a WAL\n");
	return 0;
	}
	mxFrame = (sbuf.st_size - 32)/(pagesize + 24);
	printf("Available pages: 1..%d\n", mxFrame);
	if( argc==2 ){
	int i;
	Cksum x;
	print_wal_header(&x);
	for(i=1; i<=mxFrame; i++){
	print_oneline_frame(i, &x);
	}
	}else{
	int i;
	for(i=2; i<argc; i++){
	int iStart, iEnd;
	char *zLeft;
	if( strcmp(argv[i], "header")==0 ){
	print_wal_header(0);
	continue;
	}
	if( !ISDIGIT(argv[i][0]) ){
	fprintf(stderr, "%s: unknown option: [%s]\n", argv[0], argv[i]);
	continue;
	}
	iStart = strtol(argv[i], &zLeft, 0);
	if( zLeft && strcmp(zLeft,"..end")==0 ){
	iEnd = mxFrame;
	}else if( zLeft && zLeft[0]=='.' && zLeft[1]=='.' ){
	iEnd = strtol(&zLeft[2], 0, 0);
	}else if( zLeft && zLeft[0]=='b' ){
	int ofst, nByte, hdrSize;
	unsigned char *a;
	if( iStart==1 ){
	hdrSize = 100;
	ofst = hdrSize = 100;
	nByte = pagesize-100;
	}else{
	hdrSize = 0;
	ofst = (iStart-1)*pagesize;
	nByte = pagesize;
	}
	ofst = 32 + hdrSize + (iStart-1)*(pagesize+24) + 24;
	a = getContent(ofst, nByte);
	decode_btree_page(a, iStart, hdrSize, zLeft+1);
	free(a);
	continue;
	}else{
	iEnd = iStart;
	}
	if( iStart<1 \|\| iEnd<iStart \|\| iEnd>mxFrame ){
	fprintf(stderr,
	"Page argument should be LOWER?..UPPER?. Range 1 to %d\n",
	mxFrame);
	exit(1);
	}
	while( iStart<=iEnd ){
	print_frame(iStart);
	iStart++;
	}
	}
	}
	close(fd);
	return 0;
	}