/* * Copyright (c) 2009-2011, Salvatore Sanfilippo * Copyright (c) 2010-2014, Pieter Noordhuis * Copyright (c) 2015, Matt Stancliff , * Jan-Erik Rediger * * All rights reserved. * * Redistribution and use in source and binary forms, with or without * modification, are permitted provided that the following conditions are met: * * * Redistributions of source code must retain the above copyright notice, * this list of conditions and the following disclaimer. * * Redistributions in binary form must reproduce the above copyright * notice, this list of conditions and the following disclaimer in the * documentation and/or other materials provided with the distribution. * * Neither the name of Redis nor the names of its contributors may be used * to endorse or promote products derived from this software without * specific prior written permission. * * THIS SOFTWARE IS PROVIDED BY THE COPYRIGHT HOLDERS AND CONTRIBUTORS "AS IS" * AND ANY EXPRESS OR IMPLIED WARRANTIES, INCLUDING, BUT NOT LIMITED TO, THE * IMPLIED WARRANTIES OF MERCHANTABILITY AND FITNESS FOR A PARTICULAR PURPOSE * ARE DISCLAIMED. IN NO EVENT SHALL THE COPYRIGHT OWNER OR CONTRIBUTORS BE * LIABLE FOR ANY DIRECT, INDIRECT, INCIDENTAL, SPECIAL, EXEMPLARY, OR * CONSEQUENTIAL DAMAGES (INCLUDING, BUT NOT LIMITED TO, PROCUREMENT OF * SUBSTITUTE GOODS OR SERVICES; LOSS OF USE, DATA, OR PROFITS; OR BUSINESS * INTERRUPTION) HOWEVER CAUSED AND ON ANY THEORY OF LIABILITY, WHETHER IN * CONTRACT, STRICT LIABILITY, OR TORT (INCLUDING NEGLIGENCE OR OTHERWISE) * ARISING IN ANY WAY OUT OF THE USE OF THIS SOFTWARE, EVEN IF ADVISED OF THE * POSSIBILITY OF SUCH DAMAGE. */ #include "fmacros.h" #include #include #include #include #include #include "hiredis.h" #include "net.h" #include "sds.h" #include "async.h" #include "win32.h" static redisContextFuncs redisContextDefaultFuncs = { .free_privdata = NULL, .async_read = redisAsyncRead, .async_write = redisAsyncWrite, .read = redisNetRead, .write = redisNetWrite }; static redisReply *createReplyObject(int type); static void *createStringObject(const redisReadTask *task, char *str, size_t len); static void *createArrayObject(const redisReadTask *task, size_t elements); static void *createIntegerObject(const redisReadTask *task, long long value); static void *createDoubleObject(const redisReadTask *task, double value, char *str, size_t len); static void *createNilObject(const redisReadTask *task); static void *createBoolObject(const redisReadTask *task, int bval); /* Default set of functions to build the reply. Keep in mind that such a * function returning NULL is interpreted as OOM. */ static redisReplyObjectFunctions defaultFunctions = { createStringObject, createArrayObject, createIntegerObject, createDoubleObject, createNilObject, createBoolObject, freeReplyObject }; /* Create a reply object */ static redisReply *createReplyObject(int type) { redisReply *r = calloc(1,sizeof(*r)); if (r == NULL) return NULL; r->type = type; return r; } /* Free a reply object */ void freeReplyObject(void *reply) { redisReply *r = reply; size_t j; if (r == NULL) return; switch(r->type) { case REDIS_REPLY_INTEGER: break; /* Nothing to free */ case REDIS_REPLY_ARRAY: case REDIS_REPLY_MAP: case REDIS_REPLY_SET: if (r->element != NULL) { for (j = 0; j < r->elements; j++) freeReplyObject(r->element[j]); free(r->element); } break; case REDIS_REPLY_ERROR: case REDIS_REPLY_STATUS: case REDIS_REPLY_STRING: case REDIS_REPLY_DOUBLE: case REDIS_REPLY_VERB: free(r->str); break; } free(r); } static void *createStringObject(const redisReadTask *task, char *str, size_t len) { redisReply *r, *parent; char *buf; r = createReplyObject(task->type); if (r == NULL) return NULL; assert(task->type == REDIS_REPLY_ERROR || task->type == REDIS_REPLY_STATUS || task->type == REDIS_REPLY_STRING || task->type == REDIS_REPLY_VERB); /* Copy string value */ if (task->type == REDIS_REPLY_VERB) { buf = malloc(len-4+1); /* Skip 4 bytes of verbatim type header. */ if (buf == NULL) { freeReplyObject(r); return NULL; } memcpy(r->vtype,str,3); r->vtype[3] = '\0'; memcpy(buf,str+4,len-4); buf[len-4] = '\0'; r->len = len - 4; } else { buf = malloc(len+1); if (buf == NULL) { freeReplyObject(r); return NULL; } memcpy(buf,str,len); buf[len] = '\0'; r->len = len; } r->str = buf; if (task->parent) { parent = task->parent->obj; assert(parent->type == REDIS_REPLY_ARRAY || parent->type == REDIS_REPLY_MAP || parent->type == REDIS_REPLY_SET); parent->element[task->idx] = r; } return r; } static void *createArrayObject(const redisReadTask *task, size_t elements) { redisReply *r, *parent; r = createReplyObject(task->type); if (r == NULL) return NULL; if (elements > 0) { r->element = calloc(elements,sizeof(redisReply*)); if (r->element == NULL) { freeReplyObject(r); return NULL; } } r->elements = elements; if (task->parent) { parent = task->parent->obj; assert(parent->type == REDIS_REPLY_ARRAY || parent->type == REDIS_REPLY_MAP || parent->type == REDIS_REPLY_SET); parent->element[task->idx] = r; } return r; } static void *createIntegerObject(const redisReadTask *task, long long value) { redisReply *r, *parent; r = createReplyObject(REDIS_REPLY_INTEGER); if (r == NULL) return NULL; r->integer = value; if (task->parent) { parent = task->parent->obj; assert(parent->type == REDIS_REPLY_ARRAY || parent->type == REDIS_REPLY_MAP || parent->type == REDIS_REPLY_SET); parent->element[task->idx] = r; } return r; } static void *createDoubleObject(const redisReadTask *task, double value, char *str, size_t len) { redisReply *r, *parent; r = createReplyObject(REDIS_REPLY_DOUBLE); if (r == NULL) return NULL; r->dval = value; r->str = malloc(len+1); if (r->str == NULL) { freeReplyObject(r); return NULL; } /* The double reply also has the original protocol string representing a * double as a null terminated string. This way the caller does not need * to format back for string conversion, especially since Redis does efforts * to make the string more human readable avoiding the calssical double * decimal string conversion artifacts. */ memcpy(r->str, str, len); r->str[len] = '\0'; if (task->parent) { parent = task->parent->obj; assert(parent->type == REDIS_REPLY_ARRAY || parent->type == REDIS_REPLY_MAP || parent->type == REDIS_REPLY_SET); parent->element[task->idx] = r; } return r; } static void *createNilObject(const redisReadTask *task) { redisReply *r, *parent; r = createReplyObject(REDIS_REPLY_NIL); if (r == NULL) return NULL; if (task->parent) { parent = task->parent->obj; assert(parent->type == REDIS_REPLY_ARRAY || parent->type == REDIS_REPLY_MAP || parent->type == REDIS_REPLY_SET); parent->element[task->idx] = r; } return r; } static void *createBoolObject(const redisReadTask *task, int bval) { redisReply *r, *parent; r = createReplyObject(REDIS_REPLY_BOOL); if (r == NULL) return NULL; r->integer = bval != 0; if (task->parent) { parent = task->parent->obj; assert(parent->type == REDIS_REPLY_ARRAY || parent->type == REDIS_REPLY_MAP || parent->type == REDIS_REPLY_SET); parent->element[task->idx] = r; } return r; } /* Return the number of digits of 'v' when converted to string in radix 10. * Implementation borrowed from link in redis/src/util.c:string2ll(). */ static uint32_t countDigits(uint64_t v) { uint32_t result = 1; for (;;) { if (v < 10) return result; if (v < 100) return result + 1; if (v < 1000) return result + 2; if (v < 10000) return result + 3; v /= 10000U; result += 4; } } /* Helper that calculates the bulk length given a certain string length. */ static size_t bulklen(size_t len) { return 1+countDigits(len)+2+len+2; } int redisvFormatCommand(char **target, const char *format, va_list ap) { const char *c = format; char *cmd = NULL; /* final command */ int pos; /* position in final command */ sds curarg, newarg; /* current argument */ int touched = 0; /* was the current argument touched? */ char **curargv = NULL, **newargv = NULL; int argc = 0; int totlen = 0; int error_type = 0; /* 0 = no error; -1 = memory error; -2 = format error */ int j; /* Abort if there is not target to set */ if (target == NULL) return -1; /* Build the command string accordingly to protocol */ curarg = sdsempty(); if (curarg == NULL) return -1; while(*c != '\0') { if (*c != '%' || c[1] == '\0') { if (*c == ' ') { if (touched) { newargv = realloc(curargv,sizeof(char*)*(argc+1)); if (newargv == NULL) goto memory_err; curargv = newargv; curargv[argc++] = curarg; totlen += bulklen(sdslen(curarg)); /* curarg is put in argv so it can be overwritten. */ curarg = sdsempty(); if (curarg == NULL) goto memory_err; touched = 0; } } else { newarg = sdscatlen(curarg,c,1); if (newarg == NULL) goto memory_err; curarg = newarg; touched = 1; } } else { char *arg; size_t size; /* Set newarg so it can be checked even if it is not touched. */ newarg = curarg; switch(c[1]) { case 's': arg = va_arg(ap,char*); size = strlen(arg); if (size > 0) newarg = sdscatlen(curarg,arg,size); break; case 'b': arg = va_arg(ap,char*); size = va_arg(ap,size_t); if (size > 0) newarg = sdscatlen(curarg,arg,size); break; case '%': newarg = sdscat(curarg,"%"); break; default: /* Try to detect printf format */ { static const char intfmts[] = "diouxX"; static const char flags[] = "#0-+ "; char _format[16]; const char *_p = c+1; size_t _l = 0; va_list _cpy; /* Flags */ while (*_p != '\0' && strchr(flags,*_p) != NULL) _p++; /* Field width */ while (*_p != '\0' && isdigit(*_p)) _p++; /* Precision */ if (*_p == '.') { _p++; while (*_p != '\0' && isdigit(*_p)) _p++; } /* Copy va_list before consuming with va_arg */ va_copy(_cpy,ap); /* Integer conversion (without modifiers) */ if (strchr(intfmts,*_p) != NULL) { va_arg(ap,int); goto fmt_valid; } /* Double conversion (without modifiers) */ if (strchr("eEfFgGaA",*_p) != NULL) { va_arg(ap,double); goto fmt_valid; } /* Size: char */ if (_p[0] == 'h' && _p[1] == 'h') { _p += 2; if (*_p != '\0' && strchr(intfmts,*_p) != NULL) { va_arg(ap,int); /* char gets promoted to int */ goto fmt_valid; } goto fmt_invalid; } /* Size: short */ if (_p[0] == 'h') { _p += 1; if (*_p != '\0' && strchr(intfmts,*_p) != NULL) { va_arg(ap,int); /* short gets promoted to int */ goto fmt_valid; } goto fmt_invalid; } /* Size: long long */ if (_p[0] == 'l' && _p[1] == 'l') { _p += 2; if (*_p != '\0' && strchr(intfmts,*_p) != NULL) { va_arg(ap,long long); goto fmt_valid; } goto fmt_invalid; } /* Size: long */ if (_p[0] == 'l') { _p += 1; if (*_p != '\0' && strchr(intfmts,*_p) != NULL) { va_arg(ap,long); goto fmt_valid; } goto fmt_invalid; } fmt_invalid: va_end(_cpy); goto format_err; fmt_valid: _l = (_p+1)-c; if (_l < sizeof(_format)-2) { memcpy(_format,c,_l); _format[_l] = '\0'; newarg = sdscatvprintf(curarg,_format,_cpy); /* Update current position (note: outer blocks * increment c twice so compensate here) */ c = _p-1; } va_end(_cpy); break; } } if (newarg == NULL) goto memory_err; curarg = newarg; touched = 1; c++; } c++; } /* Add the last argument if needed */ if (touched) { newargv = realloc(curargv,sizeof(char*)*(argc+1)); if (newargv == NULL) goto memory_err; curargv = newargv; curargv[argc++] = curarg; totlen += bulklen(sdslen(curarg)); } else { sdsfree(curarg); } /* Clear curarg because it was put in curargv or was free'd. */ curarg = NULL; /* Add bytes needed to hold multi bulk count */ totlen += 1+countDigits(argc)+2; /* Build the command at protocol level */ cmd = malloc(totlen+1); if (cmd == NULL) goto memory_err; pos = sprintf(cmd,"*%d\r\n",argc); for (j = 0; j < argc; j++) { pos += sprintf(cmd+pos,"$%zu\r\n",sdslen(curargv[j])); memcpy(cmd+pos,curargv[j],sdslen(curargv[j])); pos += sdslen(curargv[j]); sdsfree(curargv[j]); cmd[pos++] = '\r'; cmd[pos++] = '\n'; } assert(pos == totlen); cmd[pos] = '\0'; free(curargv); *target = cmd; return totlen; format_err: error_type = -2; goto cleanup; memory_err: error_type = -1; goto cleanup; cleanup: if (curargv) { while(argc--) sdsfree(curargv[argc]); free(curargv); } sdsfree(curarg); free(cmd); return error_type; } /* Format a command according to the Redis protocol. This function * takes a format similar to printf: * * %s represents a C null terminated string you want to interpolate * %b represents a binary safe string * * When using %b you need to provide both the pointer to the string * and the length in bytes as a size_t. Examples: * * len = redisFormatCommand(target, "GET %s", mykey); * len = redisFormatCommand(target, "SET %s %b", mykey, myval, myvallen); */ int redisFormatCommand(char **target, const char *format, ...) { va_list ap; int len; va_start(ap,format); len = redisvFormatCommand(target,format,ap); va_end(ap); /* The API says "-1" means bad result, but we now also return "-2" in some * cases. Force the return value to always be -1. */ if (len < 0) len = -1; return len; } /* Format a command according to the Redis protocol using an sds string and * sdscatfmt for the processing of arguments. This function takes the * number of arguments, an array with arguments and an array with their * lengths. If the latter is set to NULL, strlen will be used to compute the * argument lengths. */ int redisFormatSdsCommandArgv(sds *target, int argc, const char **argv, const size_t *argvlen) { sds cmd; unsigned long long totlen; int j; size_t len; /* Abort on a NULL target */ if (target == NULL) return -1; /* Calculate our total size */ totlen = 1+countDigits(argc)+2; for (j = 0; j < argc; j++) { len = argvlen ? argvlen[j] : strlen(argv[j]); totlen += bulklen(len); } /* Use an SDS string for command construction */ cmd = sdsempty(); if (cmd == NULL) return -1; /* We already know how much storage we need */ cmd = sdsMakeRoomFor(cmd, totlen); if (cmd == NULL) return -1; /* Construct command */ cmd = sdscatfmt(cmd, "*%i\r\n", argc); for (j=0; j < argc; j++) { len = argvlen ? argvlen[j] : strlen(argv[j]); cmd = sdscatfmt(cmd, "$%u\r\n", len); cmd = sdscatlen(cmd, argv[j], len); cmd = sdscatlen(cmd, "\r\n", sizeof("\r\n")-1); } assert(sdslen(cmd)==totlen); *target = cmd; return totlen; } void redisFreeSdsCommand(sds cmd) { sdsfree(cmd); } /* Format a command according to the Redis protocol. This function takes the * number of arguments, an array with arguments and an array with their * lengths. If the latter is set to NULL, strlen will be used to compute the * argument lengths. */ int redisFormatCommandArgv(char **target, int argc, const char **argv, const size_t *argvlen) { char *cmd = NULL; /* final command */ int pos; /* position in final command */ size_t len; int totlen, j; /* Abort on a NULL target */ if (target == NULL) return -1; /* Calculate number of bytes needed for the command */ totlen = 1+countDigits(argc)+2; for (j = 0; j < argc; j++) { len = argvlen ? argvlen[j] : strlen(argv[j]); totlen += bulklen(len); } /* Build the command at protocol level */ cmd = malloc(totlen+1); if (cmd == NULL) return -1; pos = sprintf(cmd,"*%d\r\n",argc); for (j = 0; j < argc; j++) { len = argvlen ? argvlen[j] : strlen(argv[j]); pos += sprintf(cmd+pos,"$%zu\r\n",len); memcpy(cmd+pos,argv[j],len); pos += len; cmd[pos++] = '\r'; cmd[pos++] = '\n'; } assert(pos == totlen); cmd[pos] = '\0'; *target = cmd; return totlen; } void redisFreeCommand(char *cmd) { free(cmd); } void __redisSetError(redisContext *c, int type, const char *str) { size_t len; c->err = type; if (str != NULL) { len = strlen(str); len = len < (sizeof(c->errstr)-1) ? len : (sizeof(c->errstr)-1); memcpy(c->errstr,str,len); c->errstr[len] = '\0'; } else { /* Only REDIS_ERR_IO may lack a description! */ assert(type == REDIS_ERR_IO); strerror_r(errno, c->errstr, sizeof(c->errstr)); } } redisReader *redisReaderCreate(void) { return redisReaderCreateWithFunctions(&defaultFunctions); } static redisContext *redisContextInit(const redisOptions *options) { redisContext *c; c = calloc(1, sizeof(*c)); if (c == NULL) return NULL; c->funcs = &redisContextDefaultFuncs; c->obuf = sdsempty(); c->reader = redisReaderCreate(); c->fd = REDIS_INVALID_FD; if (c->obuf == NULL || c->reader == NULL) { redisFree(c); return NULL; } (void)options; /* options are used in other functions */ return c; } void redisFree(redisContext *c) { if (c == NULL) return; redisNetClose(c); sdsfree(c->obuf); redisReaderFree(c->reader); free(c->tcp.host); free(c->tcp.source_addr); free(c->unix_sock.path); free(c->timeout); free(c->saddr); if (c->funcs->free_privdata) { c->funcs->free_privdata(c->privdata); } memset(c, 0xff, sizeof(*c)); free(c); } redisFD redisFreeKeepFd(redisContext *c) { redisFD fd = c->fd; c->fd = REDIS_INVALID_FD; redisFree(c); return fd; } int redisReconnect(redisContext *c) { c->err = 0; memset(c->errstr, '\0', strlen(c->errstr)); if (c->privdata && c->funcs->free_privdata) { c->funcs->free_privdata(c->privdata); c->privdata = NULL; } redisNetClose(c); sdsfree(c->obuf); redisReaderFree(c->reader); c->obuf = sdsempty(); c->reader = redisReaderCreate(); if (c->connection_type == REDIS_CONN_TCP) { return redisContextConnectBindTcp(c, c->tcp.host, c->tcp.port, c->timeout, c->tcp.source_addr); } else if (c->connection_type == REDIS_CONN_UNIX) { return redisContextConnectUnix(c, c->unix_sock.path, c->timeout); } else { /* Something bad happened here and shouldn't have. There isn't enough information in the context to reconnect. */ __redisSetError(c,REDIS_ERR_OTHER,"Not enough information to reconnect"); } return REDIS_ERR; } redisContext *redisConnectWithOptions(const redisOptions *options) { redisContext *c = redisContextInit(options); if (c == NULL) { return NULL; } if (!(options->options & REDIS_OPT_NONBLOCK)) { c->flags |= REDIS_BLOCK; } if (options->options & REDIS_OPT_REUSEADDR) { c->flags |= REDIS_REUSEADDR; } if (options->options & REDIS_OPT_NOAUTOFREE) { c->flags |= REDIS_NO_AUTO_FREE; } if (options->type == REDIS_CONN_TCP) { redisContextConnectBindTcp(c, options->endpoint.tcp.ip, options->endpoint.tcp.port, options->timeout, options->endpoint.tcp.source_addr); } else if (options->type == REDIS_CONN_UNIX) { redisContextConnectUnix(c, options->endpoint.unix_socket, options->timeout); } else if (options->type == REDIS_CONN_USERFD) { c->fd = options->endpoint.fd; c->flags |= REDIS_CONNECTED; } else { // Unknown type - FIXME - FREE return NULL; } if (options->timeout != NULL && (c->flags & REDIS_BLOCK) && c->fd != REDIS_INVALID_FD) { redisContextSetTimeout(c, *options->timeout); } return c; } /* Connect to a Redis instance. On error the field error in the returned * context will be set to the return value of the error function. * When no set of reply functions is given, the default set will be used. */ redisContext *redisConnect(const char *ip, int port) { redisOptions options = {0}; REDIS_OPTIONS_SET_TCP(&options, ip, port); return redisConnectWithOptions(&options); } redisContext *redisConnectWithTimeout(const char *ip, int port, const struct timeval tv) { redisOptions options = {0}; REDIS_OPTIONS_SET_TCP(&options, ip, port); options.timeout = &tv; return redisConnectWithOptions(&options); } redisContext *redisConnectNonBlock(const char *ip, int port) { redisOptions options = {0}; REDIS_OPTIONS_SET_TCP(&options, ip, port); options.options |= REDIS_OPT_NONBLOCK; return redisConnectWithOptions(&options); } redisContext *redisConnectBindNonBlock(const char *ip, int port, const char *source_addr) { redisOptions options = {0}; REDIS_OPTIONS_SET_TCP(&options, ip, port); options.endpoint.tcp.source_addr = source_addr; options.options |= REDIS_OPT_NONBLOCK; return redisConnectWithOptions(&options); } redisContext *redisConnectBindNonBlockWithReuse(const char *ip, int port, const char *source_addr) { redisOptions options = {0}; REDIS_OPTIONS_SET_TCP(&options, ip, port); options.endpoint.tcp.source_addr = source_addr; options.options |= REDIS_OPT_NONBLOCK|REDIS_OPT_REUSEADDR; return redisConnectWithOptions(&options); } redisContext *redisConnectUnix(const char *path) { redisOptions options = {0}; REDIS_OPTIONS_SET_UNIX(&options, path); return redisConnectWithOptions(&options); } redisContext *redisConnectUnixWithTimeout(const char *path, const struct timeval tv) { redisOptions options = {0}; REDIS_OPTIONS_SET_UNIX(&options, path); options.timeout = &tv; return redisConnectWithOptions(&options); } redisContext *redisConnectUnixNonBlock(const char *path) { redisOptions options = {0}; REDIS_OPTIONS_SET_UNIX(&options, path); options.options |= REDIS_OPT_NONBLOCK; return redisConnectWithOptions(&options); } redisContext *redisConnectFd(redisFD fd) { redisOptions options = {0}; options.type = REDIS_CONN_USERFD; options.endpoint.fd = fd; return redisConnectWithOptions(&options); } /* Set read/write timeout on a blocking socket. */ int redisSetTimeout(redisContext *c, const struct timeval tv) { if (c->flags & REDIS_BLOCK) return redisContextSetTimeout(c,tv); return REDIS_ERR; } /* Enable connection KeepAlive. */ int redisEnableKeepAlive(redisContext *c) { if (redisKeepAlive(c, REDIS_KEEPALIVE_INTERVAL) != REDIS_OK) return REDIS_ERR; return REDIS_OK; } /* Use this function to handle a read event on the descriptor. It will try * and read some bytes from the socket and feed them to the reply parser. * * After this function is called, you may use redisGetReplyFromReader to * see if there is a reply available. */ int redisBufferRead(redisContext *c) { char buf[1024*16]; int nread; /* Return early when the context has seen an error. */ if (c->err) return REDIS_ERR; nread = c->funcs->read(c, buf, sizeof(buf)); if (nread > 0) { if (redisReaderFeed(c->reader, buf, nread) != REDIS_OK) { __redisSetError(c, c->reader->err, c->reader->errstr); return REDIS_ERR; } else { } } else if (nread < 0) { return REDIS_ERR; } return REDIS_OK; } /* Write the output buffer to the socket. * * Returns REDIS_OK when the buffer is empty, or (a part of) the buffer was * successfully written to the socket. When the buffer is empty after the * write operation, "done" is set to 1 (if given). * * Returns REDIS_ERR if an error occurred trying to write and sets * c->errstr to hold the appropriate error string. */ int redisBufferWrite(redisContext *c, int *done) { /* Return early when the context has seen an error. */ if (c->err) return REDIS_ERR; if (sdslen(c->obuf) > 0) { int nwritten = c->funcs->write(c); if (nwritten < 0) { return REDIS_ERR; } else if (nwritten > 0) { if (nwritten == (signed)sdslen(c->obuf)) { sdsfree(c->obuf); c->obuf = sdsempty(); } else { sdsrange(c->obuf,nwritten,-1); } } } if (done != NULL) *done = (sdslen(c->obuf) == 0); return REDIS_OK; } /* Internal helper function to try and get a reply from the reader, * or set an error in the context otherwise. */ int redisGetReplyFromReader(redisContext *c, void **reply) { if (redisReaderGetReply(c->reader,reply) == REDIS_ERR) { __redisSetError(c,c->reader->err,c->reader->errstr); return REDIS_ERR; } return REDIS_OK; } int redisGetReply(redisContext *c, void **reply) { int wdone = 0; void *aux = NULL; /* Try to read pending replies */ if (redisGetReplyFromReader(c,&aux) == REDIS_ERR) return REDIS_ERR; /* For the blocking context, flush output buffer and read reply */ if (aux == NULL && c->flags & REDIS_BLOCK) { /* Write until done */ do { if (redisBufferWrite(c,&wdone) == REDIS_ERR) return REDIS_ERR; } while (!wdone); /* Read until there is a reply */ do { if (redisBufferRead(c) == REDIS_ERR) return REDIS_ERR; if (redisGetReplyFromReader(c,&aux) == REDIS_ERR) return REDIS_ERR; } while (aux == NULL); } /* Set reply or free it if we were passed NULL */ if (reply != NULL) { *reply = aux; } else { freeReplyObject(aux); } return REDIS_OK; } /* Helper function for the redisAppendCommand* family of functions. * * Write a formatted command to the output buffer. When this family * is used, you need to call redisGetReply yourself to retrieve * the reply (or replies in pub/sub). */ int __redisAppendCommand(redisContext *c, const char *cmd, size_t len) { sds newbuf; newbuf = sdscatlen(c->obuf,cmd,len); if (newbuf == NULL) { __redisSetError(c,REDIS_ERR_OOM,"Out of memory"); return REDIS_ERR; } c->obuf = newbuf; return REDIS_OK; } int redisAppendFormattedCommand(redisContext *c, const char *cmd, size_t len) { if (__redisAppendCommand(c, cmd, len) != REDIS_OK) { return REDIS_ERR; } return REDIS_OK; } int redisvAppendCommand(redisContext *c, const char *format, va_list ap) { char *cmd; int len; len = redisvFormatCommand(&cmd,format,ap); if (len == -1) { __redisSetError(c,REDIS_ERR_OOM,"Out of memory"); return REDIS_ERR; } else if (len == -2) { __redisSetError(c,REDIS_ERR_OTHER,"Invalid format string"); return REDIS_ERR; } if (__redisAppendCommand(c,cmd,len) != REDIS_OK) { free(cmd); return REDIS_ERR; } free(cmd); return REDIS_OK; } int redisAppendCommand(redisContext *c, const char *format, ...) { va_list ap; int ret; va_start(ap,format); ret = redisvAppendCommand(c,format,ap); va_end(ap); return ret; } int redisAppendCommandArgv(redisContext *c, int argc, const char **argv, const size_t *argvlen) { sds cmd; int len; len = redisFormatSdsCommandArgv(&cmd,argc,argv,argvlen); if (len == -1) { __redisSetError(c,REDIS_ERR_OOM,"Out of memory"); return REDIS_ERR; } if (__redisAppendCommand(c,cmd,len) != REDIS_OK) { sdsfree(cmd); return REDIS_ERR; } sdsfree(cmd); return REDIS_OK; } /* Helper function for the redisCommand* family of functions. * * Write a formatted command to the output buffer. If the given context is * blocking, immediately read the reply into the "reply" pointer. When the * context is non-blocking, the "reply" pointer will not be used and the * command is simply appended to the write buffer. * * Returns the reply when a reply was successfully retrieved. Returns NULL * otherwise. When NULL is returned in a blocking context, the error field * in the context will be set. */ static void *__redisBlockForReply(redisContext *c) { void *reply; if (c->flags & REDIS_BLOCK) { if (redisGetReply(c,&reply) != REDIS_OK) return NULL; return reply; } return NULL; } void *redisvCommand(redisContext *c, const char *format, va_list ap) { if (redisvAppendCommand(c,format,ap) != REDIS_OK) return NULL; return __redisBlockForReply(c); } void *redisCommand(redisContext *c, const char *format, ...) { va_list ap; va_start(ap,format); void *reply = redisvCommand(c,format,ap); va_end(ap); return reply; } void *redisCommandArgv(redisContext *c, int argc, const char **argv, const size_t *argvlen) { if (redisAppendCommandArgv(c,argc,argv,argvlen) != REDIS_OK) return NULL; return __redisBlockForReply(c); }