/* ** 2024-09-10 ** ** The author disclaims copyright to this source code. In place of ** a legal notice, here is a blessing: ** ** May you do good and not evil. ** May you find forgiveness for yourself and forgive others. ** May you share freely, never taking more than you give. ** ************************************************************************* ** ** This is a utility program that makes a copy of a live SQLite database ** using a bandwidth-efficient protocol, similar to "rsync". */ #include #include #include #include #include #include "sqlite3.h" static const char zUsage[] = "sqlite3-rsync ORIGIN REPLICA ?OPTIONS?\n" "\n" "One of ORIGIN or REPLICA is a pathname to a database on the local\n" "machine and the other is of the form \"USER@HOST:PATH\" describing\n" "a database on a remote machine. This utility makes REPLICA into a\n" "copy of ORIGIN\n" "\n" "OPTIONS:\n" "\n" " --exe PATH Name of the sqlite3-rsync program on the remote side\n" " --help Show this help screen\n" " --ssh PATH Name of the SSH program used to reach the remote side\n" " -v Verbose. Multiple v's for increasing output\n" " --version Show detailed version information\n" ; typedef unsigned char u8; /* Context for the run */ typedef struct SQLiteRsync SQLiteRsync; struct SQLiteRsync { const char *zOrigin; /* Name of the origin */ const char *zReplica; /* Name of the replica */ const char *zErrFile; /* Append error messages to this file */ FILE *pOut; /* Transmit to the other side */ FILE *pIn; /* Receive from the other side */ FILE *pLog; /* Duplicate output here if not NULL */ sqlite3 *db; /* Database connection */ int nErr; /* Number of errors encountered */ int nWrErr; /* Number of failed attempts to write on the pipe */ u8 eVerbose; /* Bigger for more output. 0 means none. */ u8 bCommCheck; /* True to debug the communication protocol */ u8 isRemote; /* On the remote side of a connection */ u8 isReplica; /* True if running on the replica side */ u8 iProtocol; /* Protocol version number */ sqlite3_uint64 nOut; /* Bytes transmitted */ sqlite3_uint64 nIn; /* Bytes received */ unsigned int nPage; /* Total number of pages in the database */ unsigned int szPage; /* Database page size */ unsigned int nHashSent; /* Hashes sent (replica to origin) */ unsigned int nPageSent; /* Page contents sent (origin to replica) */ }; /* The version number of the protocol. Sent in the *_BEGIN message ** to verify that both sides speak the same dialect. */ #define PROTOCOL_VERSION 1 /* Magic numbers to identify particular messages sent over the wire. */ #define ORIGIN_BEGIN 0x41 /* Initial message */ #define ORIGIN_END 0x42 /* Time to quit */ #define ORIGIN_ERROR 0x43 /* Error message from the remote */ #define ORIGIN_PAGE 0x44 /* New page data */ #define ORIGIN_TXN 0x45 /* Transaction commit */ #define ORIGIN_MSG 0x46 /* Informational message */ #define REPLICA_BEGIN 0x61 /* Welcome message */ #define REPLICA_ERROR 0x62 /* Error. Report and quit. */ #define REPLICA_END 0x63 /* Replica wants to stop */ #define REPLICA_HASH 0x64 /* One or more pages hashes to report */ #define REPLICA_READY 0x65 /* Read to receive page content */ #define REPLICA_MSG 0x66 /* Informational message */ /**************************************************************************** ** Beginning of the popen2() implementation copied from Fossil ************* ****************************************************************************/ #ifdef _WIN32 #include #include /* ** Print a fatal error and quit. */ static void win32_fatal_error(const char *zMsg){ fprintf(stderr, "%s", zMsg); exit(1); } extern int _open_osfhandle(intptr_t,int); #else #include #include #include #endif /* ** The following macros are used to cast pointers to integers and ** integers to pointers. The way you do this varies from one compiler ** to the next, so we have developed the following set of #if statements ** to generate appropriate macros for a wide range of compilers. ** ** The correct "ANSI" way to do this is to use the intptr_t type. ** Unfortunately, that typedef is not available on all compilers, or ** if it is available, it requires an #include of specific headers ** that vary from one machine to the next. ** ** This code is copied out of SQLite. */ #if defined(__PTRDIFF_TYPE__) /* This case should work for GCC */ # define INT_TO_PTR(X) ((void*)(__PTRDIFF_TYPE__)(X)) # define PTR_TO_INT(X) ((int)(__PTRDIFF_TYPE__)(X)) #elif !defined(__GNUC__) /* Works for compilers other than LLVM */ # define INT_TO_PTR(X) ((void*)&((char*)0)[X]) # define PTR_TO_INT(X) ((int)(((char*)X)-(char*)0)) #elif defined(HAVE_STDINT_H) /* Use this case if we have ANSI headers */ # define INT_TO_PTR(X) ((void*)(intptr_t)(X)) # define PTR_TO_INT(X) ((int)(intptr_t)(X)) #else /* Generates a warning - but it always works */ # define INT_TO_PTR(X) ((void*)(X)) # define PTR_TO_INT(X) ((int)(X)) #endif /* Register SQL functions provided by ext/misc/sha1.c */ extern int sqlite3_sha_init( sqlite3 *db, char **pzErrMsg, const sqlite3_api_routines *pApi ); #ifdef _WIN32 /* ** On windows, create a child process and specify the stdin, stdout, ** and stderr channels for that process to use. ** ** Return the number of errors. */ static int win32_create_child_process( wchar_t *zCmd, /* The command that the child process will run */ HANDLE hIn, /* Standard input */ HANDLE hOut, /* Standard output */ HANDLE hErr, /* Standard error */ DWORD *pChildPid /* OUT: Child process handle */ ){ STARTUPINFOW si; PROCESS_INFORMATION pi; BOOL rc; memset(&si, 0, sizeof(si)); si.cb = sizeof(si); si.dwFlags = STARTF_USESTDHANDLES; SetHandleInformation(hIn, HANDLE_FLAG_INHERIT, TRUE); si.hStdInput = hIn; SetHandleInformation(hOut, HANDLE_FLAG_INHERIT, TRUE); si.hStdOutput = hOut; SetHandleInformation(hErr, HANDLE_FLAG_INHERIT, TRUE); si.hStdError = hErr; rc = CreateProcessW( NULL, /* Application Name */ zCmd, /* Command-line */ NULL, /* Process attributes */ NULL, /* Thread attributes */ TRUE, /* Inherit Handles */ 0, /* Create flags */ NULL, /* Environment */ NULL, /* Current directory */ &si, /* Startup Info */ &pi /* Process Info */ ); if( rc ){ CloseHandle( pi.hProcess ); CloseHandle( pi.hThread ); *pChildPid = pi.dwProcessId; }else{ win32_fatal_error("cannot create child process"); } return rc!=0; } void *win32_utf8_to_unicode(const char *zUtf8){ int nByte = MultiByteToWideChar(CP_UTF8, 0, zUtf8, -1, 0, 0); wchar_t *zUnicode = malloc( nByte*2 ); MultiByteToWideChar(CP_UTF8, 0, zUtf8, -1, zUnicode, nByte); return zUnicode; } #endif /* ** Create a child process running shell command "zCmd". *ppOut is ** a FILE that becomes the standard input of the child process. ** (The caller writes to *ppOut in order to send text to the child.) ** *ppIn is stdout from the child process. (The caller ** reads from *ppIn in order to receive input from the child.) ** Note that *ppIn is an unbuffered file descriptor, not a FILE. ** The process ID of the child is written into *pChildPid. ** ** Return the number of errors. */ static int popen2( const char *zCmd, /* Command to run in the child process */ FILE **ppIn, /* Read from child using this file descriptor */ FILE **ppOut, /* Write to child using this file descriptor */ int *pChildPid, /* PID of the child process */ int bDirect /* 0: run zCmd as a shell cmd. 1: run directly */ ){ #ifdef _WIN32 HANDLE hStdinRd, hStdinWr, hStdoutRd, hStdoutWr, hStderr; SECURITY_ATTRIBUTES saAttr; DWORD childPid = 0; int fd; saAttr.nLength = sizeof(saAttr); saAttr.bInheritHandle = TRUE; saAttr.lpSecurityDescriptor = NULL; hStderr = GetStdHandle(STD_ERROR_HANDLE); if( !CreatePipe(&hStdoutRd, &hStdoutWr, &saAttr, 4096) ){ win32_fatal_error("cannot create pipe for stdout"); } SetHandleInformation( hStdoutRd, HANDLE_FLAG_INHERIT, FALSE); if( !CreatePipe(&hStdinRd, &hStdinWr, &saAttr, 4096) ){ win32_fatal_error("cannot create pipe for stdin"); } SetHandleInformation( hStdinWr, HANDLE_FLAG_INHERIT, FALSE); win32_create_child_process(win32_utf8_to_unicode(zCmd), hStdinRd, hStdoutWr, hStderr,&childPid); *pChildPid = childPid; fd = _open_osfhandle(PTR_TO_INT(hStdoutRd), 0); *ppIn = fdopen(fd, "r"); fd = _open_osfhandle(PTR_TO_INT(hStdinWr), 0); *ppOut = _fdopen(fd, "w"); CloseHandle(hStdinRd); CloseHandle(hStdoutWr); return 0; #else int pin[2], pout[2]; *ppIn = 0; *ppOut = 0; *pChildPid = 0; if( pipe(pin)<0 ){ return 1; } if( pipe(pout)<0 ){ close(pin[0]); close(pin[1]); return 1; } *pChildPid = fork(); if( *pChildPid<0 ){ close(pin[0]); close(pin[1]); close(pout[0]); close(pout[1]); *pChildPid = 0; return 1; } signal(SIGPIPE,SIG_IGN); if( *pChildPid==0 ){ int fd; /* This is the child process */ close(0); fd = dup(pout[0]); if( fd!=0 ) { fprintf(stderr,"popen2() failed to open file descriptor 0"); exit(1); } close(pout[0]); close(pout[1]); close(1); fd = dup(pin[1]); if( fd!=1 ){ fprintf(stderr,"popen() failed to open file descriptor 1"); exit(1); } close(pin[0]); close(pin[1]); if( bDirect ){ execl(zCmd, zCmd, (char*)0); }else{ execl("/bin/sh", "/bin/sh", "-c", zCmd, (char*)0); } return 1; }else{ /* This is the parent process */ close(pin[1]); *ppIn = fdopen(pin[0], "r"); close(pout[0]); *ppOut = fdopen(pout[1], "w"); return 0; } #endif } /* ** Close the connection to a child process previously created using ** popen2(). */ static void pclose2(FILE *pIn, FILE *pOut, int childPid){ #ifdef _WIN32 /* Not implemented, yet */ fclose(pIn); fclose(pOut); #else fclose(pIn); fclose(pOut); while( waitpid(0, 0, WNOHANG)>0 ) {} #endif } /***************************************************************************** ** End of the popen2() implementation copied from Fossil ********************* *****************************************************************************/ /***************************************************************************** ** Beginning of the append_escaped_arg() routine, adapted from the Fossil ** ** subroutine nameed blob_append_escaped_arg() ** *****************************************************************************/ /* ** ASCII (for reference): ** x0 x1 x2 x3 x4 x5 x6 x7 x8 x9 xa xb xc xd xe xf ** 0x ^` ^a ^b ^c ^d ^e ^f ^g \b \t \n () \f \r ^n ^o ** 1x ^p ^q ^r ^s ^t ^u ^v ^w ^x ^y ^z ^{ ^| ^} ^~ ^ ** 2x () ! " # $ % & ' ( ) * + , - . / ** 3x 0 1 2 3 4 5 6 7 8 9 : ; < = > ? ** 4x @ A B C D E F G H I J K L M N O ** 5x P Q R S T U V W X Y Z [ \ ] ^ _ ** 6x ` a b c d e f g h i j k l m n o ** 7x p q r s t u v w x y z { | } ~ ^_ */ /* ** Meanings for bytes in a filename: ** ** 0 Ordinary character. No encoding required ** 1 Needs to be escaped ** 2 Illegal character. Do not allow in a filename ** 3 First byte of a 2-byte UTF-8 ** 4 First byte of a 3-byte UTF-8 ** 5 First byte of a 4-byte UTF-8 */ static const char aSafeChar[256] = { #ifdef _WIN32 /* Windows ** Prohibit: all control characters, including tab, \r and \n. ** Escape: (space) " # $ % & ' ( ) * ; < > ? [ ] ^ ` { | } */ /* x0 x1 x2 x3 x4 x5 x6 x7 x8 x9 xa xb xc xd xe xf */ 2, 2, 2, 2, 2, 2, 2, 2, 2, 2, 2, 2, 2, 2, 2, 2, /* 0x */ 2, 2, 2, 2, 2, 2, 2, 2, 2, 2, 2, 2, 2, 2, 2, 2, /* 1x */ 1, 0, 1, 1, 1, 1, 1, 1, 1, 1, 1, 0, 0, 0, 0, 0, /* 2x */ 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 1, 1, 0, 1, 1, /* 3x */ 1, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, /* 4x */ 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 1, 0, 1, 1, 0, /* 5x */ 1, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, /* 6x */ 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 1, 1, 1, 0, 1, /* 7x */ #else /* Unix ** Prohibit: all control characters, including tab, \r and \n ** Escape: (space) ! " # $ % & ' ( ) * ; < > ? [ \ ] ^ ` { | } */ /* x0 x1 x2 x3 x4 x5 x6 x7 x8 x9 xa xb xc xd xe xf */ 2, 2, 2, 2, 2, 2, 2, 2, 2, 2, 2, 2, 2, 2, 2, 2, /* 0x */ 2, 2, 2, 2, 2, 2, 2, 2, 2, 2, 2, 2, 2, 2, 2, 2, /* 1x */ 1, 1, 1, 1, 1, 1, 1, 1, 1, 1, 1, 0, 0, 0, 0, 0, /* 2x */ 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 1, 1, 0, 1, 1, /* 3x */ 1, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, /* 4x */ 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 1, 1, 1, 1, 0, /* 5x */ 1, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, /* 6x */ 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 1, 1, 1, 0, 1, /* 7x */ #endif /* all bytes 0x80 through 0xbf are unescaped, being secondary ** bytes to UTF8 characters. Bytes 0xc0 through 0xff are the ** first byte of a UTF8 character and do get escaped */ 2, 2, 2, 2, 2, 2, 2, 2, 2, 2, 2, 2, 2, 2, 2, 2, /* 8x */ 2, 2, 2, 2, 2, 2, 2, 2, 2, 2, 2, 2, 2, 2, 2, 2, /* 9x */ 2, 2, 2, 2, 2, 2, 2, 2, 2, 2, 2, 2, 2, 2, 2, 2, /* ax */ 2, 2, 2, 2, 2, 2, 2, 2, 2, 2, 2, 2, 2, 2, 2, 2, /* bx */ 3, 3, 3, 3, 3, 3, 3, 3, 3, 3, 3, 3, 3, 3, 3, 3, /* cx */ 3, 3, 3, 3, 3, 3, 3, 3, 3, 3, 3, 3, 3, 3, 3, 3, /* dx */ 4, 4, 4, 4, 4, 4, 4, 4, 4, 4, 4, 4, 4, 4, 4, 4, /* ex */ 5, 5, 5, 5, 5, 5, 5, 5, 5, 5, 5, 5, 5, 5, 5, 5 /* fx */ }; /* ** pStr is a shell command under construction. This routine safely ** appends filename argument zIn. It returns 0 on success or non-zero ** on any error. ** ** The argument is escaped if it contains white space or other characters ** that need to be escaped for the shell. If zIn contains characters ** that cannot be safely escaped, then throw a fatal error. ** ** If the isFilename argument is true, then the argument is expected ** to be a filename. As shell commands commonly have command-line ** options that begin with "-" and since we do not want an attacker ** to be able to invoke these switches using filenames that begin ** with "-", if zIn begins with "-", prepend an additional "./" ** (or ".\\" on Windows). */ int append_escaped_arg(sqlite3_str *pStr, const char *zIn, int isFilename){ int i; unsigned char c; int needEscape = 0; int n = sqlite3_str_length(pStr); char *z = sqlite3_str_value(pStr); /* Look for illegal byte-sequences and byte-sequences that require ** escaping. No control-characters are allowed. All spaces and ** non-ASCII unicode characters and some punctuation characters require ** escaping. */ for(i=0; (c = (unsigned char)zIn[i])!=0; i++){ if( aSafeChar[c] ){ unsigned char x = aSafeChar[c]; needEscape = 1; if( x==2 ){ /* Bad ASCII character */ return 1; }else if( x>2 ){ if( (zIn[i+1]&0xc0)!=0x80 || (x>=4 && (zIn[i+2]&0xc0)!=0x80) || (x==5 && (zIn[i+3]&0xc0)!=0x80) ){ /* Bad UTF8 character */ return 1; } i += x-2; } } } /* Separate from the previous argument by a space */ if( n>0 && !isspace(z[n-1]) ){ sqlite3_str_appendchar(pStr, 1, ' '); } /* Check for characters that need quoting */ if( !needEscape ){ if( isFilename && zIn[0]=='-' ){ sqlite3_str_appendchar(pStr, 1, '.'); #if defined(_WIN32) sqlite3_str_appendchar(pStr, 1, '\\'); #else sqlite3_str_appendchar(pStr, 1, '/'); #endif } sqlite3_str_appendall(pStr, zIn); }else{ #if defined(_WIN32) /* Quoting strategy for windows: ** Put the entire name inside of "...". Any " characters within ** the name get doubled. */ sqlite3_str_appendchar(pStr, 1, '"'); if( isFilename && zIn[0]=='-' ){ sqlite3_str_appendchar(pStr, 1, '.'); sqlite3_str_appendchar(pStr, 1, '\\'); }else if( zIn[0]=='/' ){ sqlite3_str_appendchar(pStr, 1, '.'); } for(i=0; (c = (unsigned char)zIn[i])!=0; i++){ sqlite3_str_appendchar(pStr, 1, (char)c); if( c=='"' ) sqlite3_str_appendchar(pStr, 1, '"'); if( c=='\\' ) sqlite3_str_appendchar(pStr, 1, '\\'); if( c=='%' && isFilename ) sqlite3_str_append(pStr, "%cd:~,%", 7); } sqlite3_str_appendchar(pStr, 1, '"'); #else /* Quoting strategy for unix: ** If the name does not contain ', then surround the whole thing ** with '...'. If there is one or more ' characters within the ** name, then put \ before each special character. */ if( strchr(zIn,'\'') ){ if( isFilename && zIn[0]=='-' ){ sqlite3_str_appendchar(pStr, 1, '.'); sqlite3_str_appendchar(pStr, 1, '/'); } for(i=0; (c = (unsigned char)zIn[i])!=0; i++){ if( aSafeChar[c] && aSafeChar[c]!=2 ){ sqlite3_str_appendchar(pStr, 1, '\\'); } sqlite3_str_appendchar(pStr, 1, (char)c); } }else{ sqlite3_str_appendchar(pStr, 1, '\''); if( isFilename && zIn[0]=='-' ){ sqlite3_str_appendchar(pStr, 1, '.'); sqlite3_str_appendchar(pStr, 1, '/'); } sqlite3_str_appendall(pStr, zIn); sqlite3_str_appendchar(pStr, 1, '\''); } #endif } return 0; } /***************************************************************************** ** End of the append_escaped_arg() routine, adapted from the Fossil ** *****************************************************************************/ /***************************************************************************** ** The Hash Engine ** ** This is basically SHA3, though with a 160-bit hash, and reducing the ** number of rounds in the KeccakF1600 step function from 24 to 6. */ /* ** Macros to determine whether the machine is big or little endian, ** and whether or not that determination is run-time or compile-time. ** ** For best performance, an attempt is made to guess at the byte-order ** using C-preprocessor macros. If that is unsuccessful, or if ** -DHash_BYTEORDER=0 is set, then byte-order is determined ** at run-time. */ #ifndef Hash_BYTEORDER # if defined(i386) || defined(__i386__) || defined(_M_IX86) || \ defined(__x86_64) || defined(__x86_64__) || defined(_M_X64) || \ defined(_M_AMD64) || defined(_M_ARM) || defined(__x86) || \ defined(__arm__) # define Hash_BYTEORDER 1234 # elif defined(sparc) || defined(__ppc__) # define Hash_BYTEORDER 4321 # else # define Hash_BYTEORDER 0 # endif #endif typedef sqlite3_uint64 u64; /* ** State structure for a Hash hash in progress */ typedef struct HashContext HashContext; struct HashContext { union { u64 s[25]; /* Keccak state. 5x5 lines of 64 bits each */ unsigned char x[1600]; /* ... or 1600 bytes */ } u; unsigned nRate; /* Bytes of input accepted per Keccak iteration */ unsigned nLoaded; /* Input bytes loaded into u.x[] so far this cycle */ unsigned ixMask; /* Insert next input into u.x[nLoaded^ixMask]. */ unsigned iSize; /* 224, 256, 358, or 512 */ }; /* ** A single step of the Keccak mixing function for a 1600-bit state */ static void KeccakF1600Step(HashContext *p){ int i; u64 b0, b1, b2, b3, b4; u64 c0, c1, c2, c3, c4; u64 d0, d1, d2, d3, d4; static const u64 RC[] = { 0x0000000000000001ULL, 0x0000000000008082ULL, 0x800000000000808aULL, 0x8000000080008000ULL, 0x000000000000808bULL, 0x0000000080000001ULL, 0x8000000080008081ULL, 0x8000000000008009ULL, 0x000000000000008aULL, 0x0000000000000088ULL, 0x0000000080008009ULL, 0x000000008000000aULL, 0x000000008000808bULL, 0x800000000000008bULL, 0x8000000000008089ULL, 0x8000000000008003ULL, 0x8000000000008002ULL, 0x8000000000000080ULL, 0x000000000000800aULL, 0x800000008000000aULL, 0x8000000080008081ULL, 0x8000000000008080ULL, 0x0000000080000001ULL, 0x8000000080008008ULL }; # define a00 (p->u.s[0]) # define a01 (p->u.s[1]) # define a02 (p->u.s[2]) # define a03 (p->u.s[3]) # define a04 (p->u.s[4]) # define a10 (p->u.s[5]) # define a11 (p->u.s[6]) # define a12 (p->u.s[7]) # define a13 (p->u.s[8]) # define a14 (p->u.s[9]) # define a20 (p->u.s[10]) # define a21 (p->u.s[11]) # define a22 (p->u.s[12]) # define a23 (p->u.s[13]) # define a24 (p->u.s[14]) # define a30 (p->u.s[15]) # define a31 (p->u.s[16]) # define a32 (p->u.s[17]) # define a33 (p->u.s[18]) # define a34 (p->u.s[19]) # define a40 (p->u.s[20]) # define a41 (p->u.s[21]) # define a42 (p->u.s[22]) # define a43 (p->u.s[23]) # define a44 (p->u.s[24]) # define ROL64(a,x) ((a<>(64-x))) /* v---- Number of rounds. SHA3 has 24 here. */ for(i=0; i<6; i++){ c0 = a00^a10^a20^a30^a40; c1 = a01^a11^a21^a31^a41; c2 = a02^a12^a22^a32^a42; c3 = a03^a13^a23^a33^a43; c4 = a04^a14^a24^a34^a44; d0 = c4^ROL64(c1, 1); d1 = c0^ROL64(c2, 1); d2 = c1^ROL64(c3, 1); d3 = c2^ROL64(c4, 1); d4 = c3^ROL64(c0, 1); b0 = (a00^d0); b1 = ROL64((a11^d1), 44); b2 = ROL64((a22^d2), 43); b3 = ROL64((a33^d3), 21); b4 = ROL64((a44^d4), 14); a00 = b0 ^((~b1)& b2 ); a00 ^= RC[i]; a11 = b1 ^((~b2)& b3 ); a22 = b2 ^((~b3)& b4 ); a33 = b3 ^((~b4)& b0 ); a44 = b4 ^((~b0)& b1 ); b2 = ROL64((a20^d0), 3); b3 = ROL64((a31^d1), 45); b4 = ROL64((a42^d2), 61); b0 = ROL64((a03^d3), 28); b1 = ROL64((a14^d4), 20); a20 = b0 ^((~b1)& b2 ); a31 = b1 ^((~b2)& b3 ); a42 = b2 ^((~b3)& b4 ); a03 = b3 ^((~b4)& b0 ); a14 = b4 ^((~b0)& b1 ); b4 = ROL64((a40^d0), 18); b0 = ROL64((a01^d1), 1); b1 = ROL64((a12^d2), 6); b2 = ROL64((a23^d3), 25); b3 = ROL64((a34^d4), 8); a40 = b0 ^((~b1)& b2 ); a01 = b1 ^((~b2)& b3 ); a12 = b2 ^((~b3)& b4 ); a23 = b3 ^((~b4)& b0 ); a34 = b4 ^((~b0)& b1 ); b1 = ROL64((a10^d0), 36); b2 = ROL64((a21^d1), 10); b3 = ROL64((a32^d2), 15); b4 = ROL64((a43^d3), 56); b0 = ROL64((a04^d4), 27); a10 = b0 ^((~b1)& b2 ); a21 = b1 ^((~b2)& b3 ); a32 = b2 ^((~b3)& b4 ); a43 = b3 ^((~b4)& b0 ); a04 = b4 ^((~b0)& b1 ); b3 = ROL64((a30^d0), 41); b4 = ROL64((a41^d1), 2); b0 = ROL64((a02^d2), 62); b1 = ROL64((a13^d3), 55); b2 = ROL64((a24^d4), 39); a30 = b0 ^((~b1)& b2 ); a41 = b1 ^((~b2)& b3 ); a02 = b2 ^((~b3)& b4 ); a13 = b3 ^((~b4)& b0 ); a24 = b4 ^((~b0)& b1 ); } } /* ** Initialize a new hash. iSize determines the size of the hash ** in bits and should be one of 224, 256, 384, or 512. Or iSize ** can be zero to use the default hash size of 256 bits. */ static void HashInit(HashContext *p, int iSize){ memset(p, 0, sizeof(*p)); p->iSize = iSize; if( iSize>=128 && iSize<=512 ){ p->nRate = (1600 - ((iSize + 31)&~31)*2)/8; }else{ p->nRate = (1600 - 2*256)/8; } #if Hash_BYTEORDER==1234 /* Known to be little-endian at compile-time. No-op */ #elif Hash_BYTEORDER==4321 p->ixMask = 7; /* Big-endian */ #else { static unsigned int one = 1; if( 1==*(unsigned char*)&one ){ /* Little endian. No byte swapping. */ p->ixMask = 0; }else{ /* Big endian. Byte swap. */ p->ixMask = 7; } } #endif } /* ** Make consecutive calls to the HashUpdate function to add new content ** to the hash */ static void HashUpdate( HashContext *p, const unsigned char *aData, unsigned int nData ){ unsigned int i = 0; if( aData==0 ) return; #if Hash_BYTEORDER==1234 if( (p->nLoaded % 8)==0 && ((aData - (const unsigned char*)0)&7)==0 ){ for(; i+7u.s[p->nLoaded/8] ^= *(u64*)&aData[i]; p->nLoaded += 8; if( p->nLoaded>=p->nRate ){ KeccakF1600Step(p); p->nLoaded = 0; } } } #endif for(; iu.x[p->nLoaded] ^= aData[i]; #elif Hash_BYTEORDER==4321 p->u.x[p->nLoaded^0x07] ^= aData[i]; #else p->u.x[p->nLoaded^p->ixMask] ^= aData[i]; #endif p->nLoaded++; if( p->nLoaded==p->nRate ){ KeccakF1600Step(p); p->nLoaded = 0; } } } /* ** After all content has been added, invoke HashFinal() to compute ** the final hash. The function returns a pointer to the binary ** hash value. */ static unsigned char *HashFinal(HashContext *p){ unsigned int i; if( p->nLoaded==p->nRate-1 ){ const unsigned char c1 = 0x86; HashUpdate(p, &c1, 1); }else{ const unsigned char c2 = 0x06; const unsigned char c3 = 0x80; HashUpdate(p, &c2, 1); p->nLoaded = p->nRate - 1; HashUpdate(p, &c3, 1); } for(i=0; inRate; i++){ p->u.x[i+p->nRate] = p->u.x[i^p->ixMask]; } return &p->u.x[p->nRate]; } /* ** Implementation of the hash(X) function. ** ** Return a 160-bit BLOB which is the hash of X. */ static void hashFunc( sqlite3_context *context, int argc, sqlite3_value **argv ){ HashContext cx; int eType = sqlite3_value_type(argv[0]); int nByte = sqlite3_value_bytes(argv[0]); if( eType==SQLITE_NULL ) return; HashInit(&cx, 160); if( eType==SQLITE_BLOB ){ HashUpdate(&cx, sqlite3_value_blob(argv[0]), nByte); }else{ HashUpdate(&cx, sqlite3_value_text(argv[0]), nByte); } sqlite3_result_blob(context, HashFinal(&cx), 160/8, SQLITE_TRANSIENT); } /* Register the hash function */ static int hashRegister(sqlite3 *db){ return sqlite3_create_function(db, "hash", 1, SQLITE_UTF8 | SQLITE_INNOCUOUS | SQLITE_DETERMINISTIC, 0, hashFunc, 0, 0); } /* End of the hashing logic *****************************************************************************/ /* ** Return the tail of a file pathname. The tail is the last component ** of the path. For example, the tail of "/a/b/c.d" is "c.d". */ const char *file_tail(const char *z){ const char *zTail = z; if( !zTail ) return 0; while( z[0] ){ if( z[0]=='/' ) zTail = &z[1]; z++; } return zTail; } /* ** Append error message text to the error file, if an error file is ** specified. In any case, increment the error count. */ static void logError(SQLiteRsync *p, const char *zFormat, ...){ if( p->zErrFile ){ FILE *pErr = fopen(p->zErrFile, "a"); if( pErr ){ va_list ap; va_start(ap, zFormat); vfprintf(pErr, zFormat, ap); va_end(ap); fclose(pErr); } } p->nErr++; } /* Read a single big-endian 32-bit unsigned integer from the input ** stream. Return 0 on success and 1 if there are any errors. */ static int readUint32(SQLiteRsync *p, unsigned int *pU){ unsigned char buf[4]; if( fread(buf, sizeof(buf), 1, p->pIn)==1 ){ *pU = (buf[0]<<24) | (buf[1]<<16) | (buf[2]<<8) | buf[3]; p->nIn += 4; return 0; }else{ logError(p, "failed to read a 32-bit integer\n"); return 1; } } /* Write a single big-endian 32-bit unsigned integer to the output stream. ** Return 0 on success and 1 if there are any errors. */ static int writeUint32(SQLiteRsync *p, unsigned int x){ unsigned char buf[4]; buf[3] = x & 0xff; x >>= 8; buf[2] = x & 0xff; x >>= 8; buf[1] = x & 0xff; x >>= 8; buf[0] = x; if( p->pLog ) fwrite(buf, sizeof(buf), 1, p->pLog); if( fwrite(buf, sizeof(buf), 1, p->pOut)!=1 ){ logError(p, "failed to write 32-bit integer 0x%x\n", x); p->nWrErr++; return 1; } p->nOut += 4; return 0; } /* Read a single byte from the wire. */ int readByte(SQLiteRsync *p){ int c = fgetc(p->pIn); if( c!=EOF ) p->nIn++; return c; } /* Write a single byte into the wire. */ void writeByte(SQLiteRsync *p, int c){ if( p->pLog ) fputc(c, p->pLog); fputc(c, p->pOut); p->nOut++; } /* Read a power of two encoded as a single byte. */ int readPow2(SQLiteRsync *p){ int x = readByte(p); if( x<0 || x>=32 ){ logError(p, "read invalid page size %d\n", x); return 0; } return 1<1; n++){ c /= 2; } writeByte(p, n); } /* Read an array of bytes from the wire. */ void readBytes(SQLiteRsync *p, int nByte, void *pData){ if( fread(pData, 1, nByte, p->pIn)==nByte ){ p->nIn += nByte; }else{ logError(p, "failed to read %d bytes\n", nByte); } } /* Write an array of bytes onto the wire. */ void writeBytes(SQLiteRsync *p, int nByte, const void *pData){ if( p->pLog ) fwrite(pData, 1, nByte, p->pLog); if( fwrite(pData, 1, nByte, p->pOut)==nByte ){ p->nOut += nByte; }else{ logError(p, "failed to write %d bytes\n", nByte); p->nWrErr++; } } /* Report an error. ** ** If this happens on the remote side, we send back a *_ERROR ** message. On the local side, the error message goes to stderr. */ static void reportError(SQLiteRsync *p, const char *zFormat, ...){ va_list ap; char *zMsg; unsigned int nMsg; va_start(ap, zFormat); zMsg = sqlite3_vmprintf(zFormat, ap); va_end(ap); nMsg = zMsg ? (unsigned int)strlen(zMsg) : 0; if( p->isRemote ){ if( p->isReplica ){ putc(REPLICA_ERROR, p->pOut); }else{ putc(ORIGIN_ERROR, p->pOut); } writeUint32(p, nMsg); writeBytes(p, nMsg, zMsg); fflush(p->pOut); }else{ fprintf(stderr, "%s\n", zMsg); } logError(p, "%s\n", zMsg); sqlite3_free(zMsg); } /* Send an informational message. ** ** If this happens on the remote side, we send back a *_MSG ** message. On the local side, the message goes to stdout. */ static void infoMsg(SQLiteRsync *p, const char *zFormat, ...){ va_list ap; char *zMsg; unsigned int nMsg; va_start(ap, zFormat); zMsg = sqlite3_vmprintf(zFormat, ap); va_end(ap); nMsg = zMsg ? (unsigned int)strlen(zMsg) : 0; if( p->isRemote ){ if( p->isReplica ){ putc(REPLICA_MSG, p->pOut); }else{ putc(ORIGIN_MSG, p->pOut); } writeUint32(p, nMsg); writeBytes(p, nMsg, zMsg); fflush(p->pOut); }else{ printf("%s\n", zMsg); } sqlite3_free(zMsg); } /* Receive and report an error message coming from the other side. */ static void readAndDisplayMessage(SQLiteRsync *p, int c){ unsigned int n = 0; char *zMsg; const char *zPrefix; if( c==ORIGIN_ERROR || c==REPLICA_ERROR ){ zPrefix = "ERROR: "; }else{ zPrefix = ""; } readUint32(p, &n); if( n==0 ){ fprintf(stderr,"ERROR: unknown (possibly out-of-memory)\n"); }else{ zMsg = sqlite3_malloc64( n+1 ); if( zMsg==0 ){ fprintf(stderr, "ERROR: out-of-memory\n"); return; } memset(zMsg, 0, n+1); readBytes(p, n, zMsg); fprintf(stderr,"%s%s\n", zPrefix, zMsg); if( zPrefix[0] ) logError(p, "%s%s\n", zPrefix, zMsg); sqlite3_free(zMsg); } } /* Construct a new prepared statement. Report an error and return NULL ** if anything goes wrong. */ static sqlite3_stmt *prepareStmtVA( SQLiteRsync *p, char *zFormat, va_list ap ){ sqlite3_stmt *pStmt = 0; char *zSql; char *zToFree = 0; int rc; if( strchr(zFormat,'%') ){ zSql = sqlite3_vmprintf(zFormat, ap); if( zSql==0 ){ reportError(p, "out-of-memory"); return 0; }else{ zToFree = zSql; } }else{ zSql = zFormat; } rc = sqlite3_prepare_v2(p->db, zSql, -1, &pStmt, 0); if( rc || pStmt==0 ){ reportError(p, "unable to prepare SQL [%s]: %s", zSql, sqlite3_errmsg(p->db)); sqlite3_finalize(pStmt); pStmt = 0; } if( zToFree ) sqlite3_free(zToFree); return pStmt; } static sqlite3_stmt *prepareStmt( SQLiteRsync *p, char *zFormat, ... ){ sqlite3_stmt *pStmt; va_list ap; va_start(ap, zFormat); pStmt = prepareStmtVA(p, zFormat, ap); va_end(ap); return pStmt; } /* Run a single SQL statement */ static void runSql(SQLiteRsync *p, char *zSql, ...){ sqlite3_stmt *pStmt; va_list ap; va_start(ap, zSql); pStmt = prepareStmtVA(p, zSql, ap); va_end(ap); if( pStmt ){ int rc = sqlite3_step(pStmt); if( rc==SQLITE_ROW ) rc = sqlite3_step(pStmt); if( rc!=SQLITE_OK && rc!=SQLITE_DONE ){ reportError(p, "SQL statement [%s] failed: %s", zSql, sqlite3_errmsg(p->db)); } sqlite3_finalize(pStmt); } } /* Run an SQL statement that returns a single unsigned 32-bit integer result */ static int runSqlReturnUInt( SQLiteRsync *p, unsigned int *pRes, char *zSql, ... ){ sqlite3_stmt *pStmt; int res = 0; va_list ap; va_start(ap, zSql); pStmt = prepareStmtVA(p, zSql, ap); va_end(ap); if( pStmt==0 ){ res = 1; }else{ int rc = sqlite3_step(pStmt); if( rc==SQLITE_ROW ){ *pRes = (unsigned int)(sqlite3_column_int64(pStmt, 0)&0xffffffff); }else{ reportError(p, "SQL statement [%s] failed: %s", zSql, sqlite3_errmsg(p->db)); res = 1; } sqlite3_finalize(pStmt); } return res; } /* Run an SQL statement that returns a single TEXT value that is no more ** than 99 bytes in length. */ static int runSqlReturnText( SQLiteRsync *p, char *pRes, char *zSql, ... ){ sqlite3_stmt *pStmt; int res = 0; va_list ap; va_start(ap, zSql); pStmt = prepareStmtVA(p, zSql, ap); va_end(ap); pRes[0] = 0; if( pStmt==0 ){ res = 1; }else{ int rc = sqlite3_step(pStmt); if( rc==SQLITE_ROW ){ const unsigned char *a = sqlite3_column_text(pStmt, 0); int n; if( a==0 ){ pRes[0] = 0; }else{ n = sqlite3_column_bytes(pStmt, 0); if( n>99 ) n = 99; memcpy(pRes, a, n); pRes[n] = 0; } }else{ reportError(p, "SQL statement [%s] failed: %s", zSql, sqlite3_errmsg(p->db)); res = 1; } sqlite3_finalize(pStmt); } return res; } /* Close the database connection associated with p */ static void closeDb(SQLiteRsync *p){ if( p->db ){ sqlite3_close(p->db); p->db = 0; } } /* ** Run the origin-side protocol. ** ** Begin by sending the ORIGIN_BEGIN message with two arguments, ** nPage, and szPage. Then enter a loop responding to message from ** the replica: ** ** REPLICA_ERROR size text ** ** Report an error from the replica and quit ** ** REPLICA_END ** ** The replica is terminating. Stop processing now. ** ** REPLICA_HASH hash ** ** The argument is the 20-byte SHA1 hash for the next page ** page hashes appear in sequential order with no gaps. ** ** REPLICA_READY ** ** The replica has sent all the hashes that it intends to send. ** This side (the origin) can now start responding with page ** content for pages that do not have a matching hash. */ static void originSide(SQLiteRsync *p){ int rc = 0; int c = 0; unsigned int nPage = 0; unsigned int iPage = 0; unsigned int lockBytePage = 0; unsigned int szPg = 0; sqlite3_stmt *pCkHash = 0; char buf[200]; p->isReplica = 0; if( p->bCommCheck ){ infoMsg(p, "origin zOrigin=%Q zReplica=%Q isRemote=%d protocol=%d", p->zOrigin, p->zReplica, p->isRemote, PROTOCOL_VERSION); writeByte(p, ORIGIN_END); fflush(p->pOut); }else{ /* Open the ORIGIN database. */ rc = sqlite3_open_v2(p->zOrigin, &p->db, SQLITE_OPEN_READWRITE, 0); if( rc ){ reportError(p, "cannot open origin \"%s\": %s", p->zOrigin, sqlite3_errmsg(p->db)); closeDb(p); return; } hashRegister(p->db); runSql(p, "BEGIN"); runSqlReturnText(p, buf, "PRAGMA journal_mode"); if( sqlite3_stricmp(buf,"wal")!=0 ){ reportError(p, "Origin database is not in WAL mode"); } runSqlReturnUInt(p, &nPage, "PRAGMA page_count"); runSqlReturnUInt(p, &szPg, "PRAGMA page_size"); if( p->nErr==0 ){ /* Send the ORIGIN_BEGIN message */ writeByte(p, ORIGIN_BEGIN); writeByte(p, PROTOCOL_VERSION); writePow2(p, szPg); writeUint32(p, nPage); fflush(p->pOut); p->nPage = nPage; p->szPage = szPg; p->iProtocol = PROTOCOL_VERSION; lockBytePage = (1<<30)/szPg + 1; } } /* Respond to message from the replica */ while( p->nErr<=p->nWrErr && (c = readByte(p))!=EOF && c!=REPLICA_END ){ switch( c ){ case REPLICA_BEGIN: { /* This message is only sent if the replica received an origin-protocol ** that is larger than what it knows about. The replica sends back ** a counter-proposal of an earlier protocol which the origin can ** accept by resending a new ORIGIN_BEGIN. */ p->iProtocol = readByte(p); writeByte(p, ORIGIN_BEGIN); writeByte(p, p->iProtocol); writePow2(p, p->szPage); writeUint32(p, p->nPage); break; } case REPLICA_MSG: case REPLICA_ERROR: { readAndDisplayMessage(p, c); break; } case REPLICA_HASH: { if( pCkHash==0 ){ runSql(p, "CREATE TEMP TABLE badHash(pgno INTEGER PRIMARY KEY)"); pCkHash = prepareStmt(p, "INSERT INTO badHash SELECT pgno FROM sqlite_dbpage('main')" " WHERE pgno=?1 AND hash(data)!=?2" ); if( pCkHash==0 ) break; } p->nHashSent++; iPage++; sqlite3_bind_int64(pCkHash, 1, iPage); readBytes(p, 20, buf); sqlite3_bind_blob(pCkHash, 2, buf, 20, SQLITE_STATIC); rc = sqlite3_step(pCkHash); if( rc!=SQLITE_DONE ){ reportError(p, "SQL statement [%s] failed: %s", sqlite3_sql(pCkHash), sqlite3_errmsg(p->db)); } sqlite3_reset(pCkHash); break; } case REPLICA_READY: { sqlite3_stmt *pStmt; sqlite3_finalize(pCkHash); pCkHash = 0; if( iPage+1nPage ){ runSql(p, "WITH RECURSIVE c(n) AS" " (VALUES(%d) UNION ALL SELECT n+1 FROM c WHERE n<%d)" " INSERT INTO badHash SELECT n FROM c", iPage+1, p->nPage); } runSql(p, "DELETE FROM badHash WHERE pgno=%d", lockBytePage); pStmt = prepareStmt(p, "SELECT pgno, data" " FROM badHash JOIN sqlite_dbpage('main') USING(pgno)"); if( pStmt==0 ) break; while( sqlite3_step(pStmt)==SQLITE_ROW && p->nErr==0 && p->nWrErr==0 ){ unsigned int pgno = (unsigned int)sqlite3_column_int64(pStmt,0); const void *pContent = sqlite3_column_blob(pStmt, 1); writeByte(p, ORIGIN_PAGE); writeUint32(p, pgno); writeBytes(p, szPg, pContent); p->nPageSent++; } sqlite3_finalize(pStmt); writeByte(p, ORIGIN_TXN); writeUint32(p, nPage); writeByte(p, ORIGIN_END); fflush(p->pOut); break; } default: { reportError(p, "Unknown message 0x%02x %lld bytes into conversation", c, p->nIn); break; } } } if( pCkHash ) sqlite3_finalize(pCkHash); closeDb(p); } /* ** Run the replica-side protocol. The protocol is passive in the sense ** that it only response to message from the origin side. ** ** ORIGIN_BEGIN idProtocol szPage nPage ** ** The origin is reporting the protocol version number, the size of ** each page in the origin database (sent as a single-byte power-of-2), ** and the number of pages in the origin database. ** This procedure checks compatibility, and if everything is ok, ** it starts sending hashes of pages already present back to the origin. ** ** ORIGIN_ERROR size text ** ** Report the received error and quit. ** ** ORIGIN_PAGE pgno content ** ** Update the content of the given page. ** ** ORIGIN_TXN pgno ** ** Close the update transaction. The total database size is pgno ** pages. ** ** ORIGIN_END ** ** Expect no more transmissions from the origin. */ static void replicaSide(SQLiteRsync *p){ int c; sqlite3_stmt *pIns = 0; unsigned int szOPage = 0; char buf[65536]; p->isReplica = 1; if( p->bCommCheck ){ infoMsg(p, "replica zOrigin=%Q zReplica=%Q isRemote=%d protocol=%d", p->zOrigin, p->zReplica, p->isRemote, PROTOCOL_VERSION); writeByte(p, REPLICA_END); fflush(p->pOut); } /* Respond to message from the origin. The origin will initiate the ** the conversation with an ORIGIN_BEGIN message. */ while( p->nErr<=p->nWrErr && (c = readByte(p))!=EOF && c!=ORIGIN_END ){ switch( c ){ case ORIGIN_MSG: case ORIGIN_ERROR: { readAndDisplayMessage(p, c); break; } case ORIGIN_BEGIN: { unsigned int nOPage = 0; unsigned int nRPage = 0, szRPage = 0; int rc = 0; sqlite3_stmt *pStmt = 0; closeDb(p); p->iProtocol = readByte(p); szOPage = readPow2(p); readUint32(p, &nOPage); if( p->nErr ) break; if( p->iProtocol>PROTOCOL_VERSION ){ /* If the protocol version on the origin side is larger, send back ** a REPLICA_BEGIN message with the protocol version number of the ** replica side. This gives the origin an opportunity to resend ** a new ORIGIN_BEGIN with a reduced protocol version. */ writeByte(p, REPLICA_BEGIN); writeByte(p, PROTOCOL_VERSION); break; } p->nPage = nOPage; p->szPage = szOPage; rc = sqlite3_open(":memory:", &p->db); if( rc ){ reportError(p, "cannot open in-memory database: %s", sqlite3_errmsg(p->db)); closeDb(p); break; } runSql(p, "ATTACH %Q AS 'replica'", p->zReplica); if( p->nErr ){ closeDb(p); break; } hashRegister(p->db); if( runSqlReturnUInt(p, &nRPage, "PRAGMA replica.page_count") ){ break; } if( nRPage==0 ){ runSql(p, "PRAGMA replica.page_size=%u", szOPage); runSql(p, "PRAGMA replica.journal_mode=WAL"); runSql(p, "SELECT * FROM replica.sqlite_schema"); } runSql(p, "BEGIN IMMEDIATE"); runSqlReturnText(p, buf, "PRAGMA replica.journal_mode"); if( strcmp(buf, "wal")!=0 ){ reportError(p, "replica is not in WAL mode"); break; } runSqlReturnUInt(p, &nRPage, "PRAGMA replica.page_count"); runSqlReturnUInt(p, &szRPage, "PRAGMA replica.page_size"); if( szRPage!=szOPage ){ reportError(p, "page size mismatch; origin is %d bytes and " "replica is %d bytes", szOPage, szRPage); break; } pStmt = prepareStmt(p, "SELECT hash(data) FROM sqlite_dbpage('replica')" " WHERE pgno<=min(%d,%d)" " ORDER BY pgno", nRPage, nOPage); while( sqlite3_step(pStmt)==SQLITE_ROW && p->nErr==0 && p->nWrErr==0 ){ const unsigned char *a = sqlite3_column_blob(pStmt, 0); writeByte(p, REPLICA_HASH); writeBytes(p, 20, a); p->nHashSent++; } sqlite3_finalize(pStmt); writeByte(p, REPLICA_READY); fflush(p->pOut); runSql(p, "PRAGMA writable_schema=ON"); break; } case ORIGIN_TXN: { unsigned int nOPage = 0; readUint32(p, &nOPage); if( pIns==0 ){ /* Nothing has changed */ runSql(p, "COMMIT"); }else if( p->nErr ){ runSql(p, "ROLLBACK"); }else{ if( nOPage<0xffffffff ){ int rc; sqlite3_bind_int64(pIns, 1, nOPage+1); sqlite3_bind_null(pIns, 2); rc = sqlite3_step(pIns); if( rc!=SQLITE_DONE ){ reportError(p, "SQL statement [%s] failed (pgno=%u, data=NULL): %s", sqlite3_sql(pIns), nOPage, sqlite3_errmsg(p->db)); } sqlite3_reset(pIns); } p->nPage = nOPage; runSql(p, "COMMIT"); } break; } case ORIGIN_PAGE: { unsigned int pgno = 0; int rc; readUint32(p, &pgno); if( p->nErr ) break; if( pIns==0 ){ pIns = prepareStmt(p, "INSERT INTO sqlite_dbpage(pgno,data,schema)VALUES(?1,?2,'replica')" ); if( pIns==0 ) break; } readBytes(p, szOPage, buf); if( p->nErr ) break; p->nPageSent++; sqlite3_bind_int64(pIns, 1, pgno); sqlite3_bind_blob(pIns, 2, buf, szOPage, SQLITE_STATIC); rc = sqlite3_step(pIns); if( rc!=SQLITE_DONE ){ reportError(p, "SQL statement [%s] failed (pgno=%u): %s", sqlite3_sql(pIns), pgno, sqlite3_errmsg(p->db)); } sqlite3_reset(pIns); break; } default: { reportError(p, "Unknown message 0x%02x %lld bytes into conversation", c, p->nIn); break; } } } if( pIns ) sqlite3_finalize(pIns); closeDb(p); } /* ** The argument might be -vvv...vv with any number of "v"s. Return ** the number of "v"s. Return 0 if the argument is not a -vvv...v. */ static int numVs(const char *z){ int n = 0; if( z[0]!='-' ) return 0; z++; if( z[0]=='-' ) z++; while( z[0]=='v' ){ n++; z++; } if( z[0]==0 ) return n; return 0; } /* ** Get the argument to an --option. Throw an error and die if no argument ** is available. */ static const char *cmdline_option_value(int argc, const char * const*argv, int i){ if( i==argc ){ fprintf(stderr,"%s: Error: missing argument to %s\n", argv[0], argv[argc-1]); exit(1); } return argv[i]; } /* ** Return the current time in milliseconds since the Julian epoch. */ sqlite3_int64 currentTime(void){ sqlite3_int64 now = 0; sqlite3_vfs *pVfs = sqlite3_vfs_find(0); if( pVfs && pVfs->iVersion>=2 && pVfs->xCurrentTimeInt64!=0 ){ pVfs->xCurrentTimeInt64(pVfs, &now); } return now; } /* ** Input string zIn might be in any of these formats: ** ** (1) PATH ** (2) HOST:PATH ** (3) USER@HOST:PATH ** ** For format 1, return NULL. For formats 2 and 3, return ** a pointer to the ':' character that separates the hostname ** from the path. */ static char *hostSeparator(const char *zIn){ char *zPath = strchr(zIn, ':'); if( zPath==0 ) return 0; #ifdef _WIN32 if( isalpha(zIn[0]) && zIn[1]==':' && (zIn[2]=='/' || zIn[2]=='\\') ){ return 0; } #endif while( zIn=2 ) printf("%s\n", zCmd); if( popen2(zCmd, &ctx.pIn, &ctx.pOut, &childPid, 0) ){ fprintf(stderr, "Could not start auxiliary process: %s\n", zCmd); return 1; } replicaSide(&ctx); }else if( (zDiv = hostSeparator(ctx.zReplica))!=0 ){ /* Local ORIGIN and remote REPLICA */ sqlite3_str *pStr = sqlite3_str_new(0); append_escaped_arg(pStr, zSsh, 1); sqlite3_str_appendf(pStr, " -e none"); *(zDiv++) = 0; append_escaped_arg(pStr, ctx.zReplica, 0); append_escaped_arg(pStr, zExe, 1); append_escaped_arg(pStr, "--replica", 0); if( ctx.bCommCheck ){ append_escaped_arg(pStr, "--commcheck", 0); if( ctx.eVerbose==0 ) ctx.eVerbose = 1; } if( zRemoteErrFile ){ append_escaped_arg(pStr, "--errorfile", 0); append_escaped_arg(pStr, zRemoteErrFile, 1); } append_escaped_arg(pStr, file_tail(ctx.zOrigin), 1); append_escaped_arg(pStr, zDiv, 1); zCmd = sqlite3_str_finish(pStr); if( ctx.eVerbose>=2 ) printf("%s\n", zCmd); if( popen2(zCmd, &ctx.pIn, &ctx.pOut, &childPid, 0) ){ fprintf(stderr, "Could not start auxiliary process: %s\n", zCmd); return 1; } originSide(&ctx); }else{ /* Local ORIGIN and REPLICA */ sqlite3_str *pStr = sqlite3_str_new(0); append_escaped_arg(pStr, argv[0], 1); append_escaped_arg(pStr, "--replica", 0); if( ctx.bCommCheck ){ append_escaped_arg(pStr, "--commcheck", 0); } if( zRemoteErrFile ){ append_escaped_arg(pStr, "--errorfile", 0); append_escaped_arg(pStr, zRemoteErrFile, 1); } append_escaped_arg(pStr, ctx.zOrigin, 1); append_escaped_arg(pStr, ctx.zReplica, 1); zCmd = sqlite3_str_finish(pStr); if( ctx.eVerbose>=2 ) printf("%s\n", zCmd); if( popen2(zCmd, &ctx.pIn, &ctx.pOut, &childPid, 0) ){ fprintf(stderr, "Could not start auxiliary process: %s\n", zCmd); return 1; } originSide(&ctx); } pclose2(ctx.pIn, ctx.pOut, childPid); if( ctx.pLog ) fclose(ctx.pLog); tmEnd = currentTime(); tmElapse = tmEnd - tmStart; /* Elapse time in milliseconds */ if( ctx.nErr ){ printf("Databases were not synced due to errors\n"); } if( ctx.eVerbose>=1 ){ char *zMsg; sqlite3_int64 szTotal = (sqlite3_int64)ctx.nPage*(sqlite3_int64)ctx.szPage; sqlite3_int64 nIO = ctx.nOut +ctx.nIn; zMsg = sqlite3_mprintf("sent %,lld bytes, received %,lld bytes", ctx.nOut, ctx.nIn); printf("%s", zMsg); sqlite3_free(zMsg); if( tmElapse>0 ){ zMsg = sqlite3_mprintf(", %,.2f bytes/sec", 1000.0*(double)nIO/(double)tmElapse); printf("%s\n", zMsg); sqlite3_free(zMsg); }else{ printf("\n"); } if( ctx.nErr==0 ){ if( nIO<=szTotal && nIO>0 ){ zMsg = sqlite3_mprintf("total size %,lld speedup is %.2f", szTotal, (double)szTotal/(double)nIO); }else{ zMsg = sqlite3_mprintf("total size %,lld", szTotal); } printf("%s\n", zMsg); sqlite3_free(zMsg); } } sqlite3_free(zCmd); if( pIn!=0 && pOut!=0 ){ pclose2(pIn, pOut, childPid); } return ctx.nErr; }