#include "fmacros.h" #include "sockcompat.h" #include #include #include #ifndef _WIN32 #include #include #endif #include #include #include #include #include #include "hiredis.h" #include "async.h" #include "adapters/poll.h" #ifdef HIREDIS_TEST_SSL #include "hiredis_ssl.h" #endif #ifdef HIREDIS_TEST_ASYNC #include "adapters/libevent.h" #include #endif #include "net.h" #include "win32.h" enum connection_type { CONN_TCP, CONN_UNIX, CONN_FD, CONN_SSL }; struct config { enum connection_type type; struct { const char *host; int port; struct timeval timeout; } tcp; struct { const char *path; } unix_sock; struct { const char *host; int port; const char *ca_cert; const char *cert; const char *key; } ssl; }; struct privdata { int dtor_counter; }; struct pushCounters { int nil; int str; }; static int insecure_calloc_calls; #ifdef HIREDIS_TEST_SSL redisSSLContext *_ssl_ctx = NULL; #endif /* The following lines make up our testing "framework" :) */ static int tests = 0, fails = 0, skips = 0; #define test(_s) { printf("#%02d ", ++tests); printf(_s); } #define test_cond(_c) if(_c) printf("\033[0;32mPASSED\033[0;0m\n"); else {printf("\033[0;31mFAILED\033[0;0m\n"); fails++;} #define test_skipped() { printf("\033[01;33mSKIPPED\033[0;0m\n"); skips++; } static void millisleep(int ms) { #if _MSC_VER Sleep(ms); #else usleep(ms*1000); #endif } static long long usec(void) { #ifndef _MSC_VER struct timeval tv; gettimeofday(&tv,NULL); return (((long long)tv.tv_sec)*1000000)+tv.tv_usec; #else FILETIME ft; GetSystemTimeAsFileTime(&ft); return (((long long)ft.dwHighDateTime << 32) | ft.dwLowDateTime) / 10; #endif } /* The assert() calls below have side effects, so we need assert() * even if we are compiling without asserts (-DNDEBUG). */ #ifdef NDEBUG #undef assert #define assert(e) (void)(e) #endif /* Helper to extract Redis version information. Aborts on any failure. */ #define REDIS_VERSION_FIELD "redis_version:" void get_redis_version(redisContext *c, int *majorptr, int *minorptr) { redisReply *reply; char *eptr, *s, *e; int major, minor; reply = redisCommand(c, "INFO"); if (reply == NULL || c->err || reply->type != REDIS_REPLY_STRING) goto abort; if ((s = strstr(reply->str, REDIS_VERSION_FIELD)) == NULL) goto abort; s += strlen(REDIS_VERSION_FIELD); /* We need a field terminator and at least 'x.y.z' (5) bytes of data */ if ((e = strstr(s, "\r\n")) == NULL || (e - s) < 5) goto abort; /* Extract version info */ major = strtol(s, &eptr, 10); if (*eptr != '.') goto abort; minor = strtol(eptr+1, NULL, 10); /* Push info the caller wants */ if (majorptr) *majorptr = major; if (minorptr) *minorptr = minor; freeReplyObject(reply); return; abort: freeReplyObject(reply); fprintf(stderr, "Error: Cannot determine Redis version, aborting\n"); exit(1); } static redisContext *select_database(redisContext *c) { redisReply *reply; /* Switch to DB 9 for testing, now that we know we can chat. */ reply = redisCommand(c,"SELECT 9"); assert(reply != NULL); freeReplyObject(reply); /* Make sure the DB is emtpy */ reply = redisCommand(c,"DBSIZE"); assert(reply != NULL); if (reply->type == REDIS_REPLY_INTEGER && reply->integer == 0) { /* Awesome, DB 9 is empty and we can continue. */ freeReplyObject(reply); } else { printf("Database #9 is not empty, test can not continue\n"); exit(1); } return c; } /* Switch protocol */ static void send_hello(redisContext *c, int version) { redisReply *reply; int expected; reply = redisCommand(c, "HELLO %d", version); expected = version == 3 ? REDIS_REPLY_MAP : REDIS_REPLY_ARRAY; assert(reply != NULL && reply->type == expected); freeReplyObject(reply); } /* Togggle client tracking */ static void send_client_tracking(redisContext *c, const char *str) { redisReply *reply; reply = redisCommand(c, "CLIENT TRACKING %s", str); assert(reply != NULL && reply->type == REDIS_REPLY_STATUS); freeReplyObject(reply); } static int disconnect(redisContext *c, int keep_fd) { redisReply *reply; /* Make sure we're on DB 9. */ reply = redisCommand(c,"SELECT 9"); assert(reply != NULL); freeReplyObject(reply); reply = redisCommand(c,"FLUSHDB"); assert(reply != NULL); freeReplyObject(reply); /* Free the context as well, but keep the fd if requested. */ if (keep_fd) return redisFreeKeepFd(c); redisFree(c); return -1; } static void do_ssl_handshake(redisContext *c) { #ifdef HIREDIS_TEST_SSL redisInitiateSSLWithContext(c, _ssl_ctx); if (c->err) { printf("SSL error: %s\n", c->errstr); redisFree(c); exit(1); } #else (void) c; #endif } static redisContext *do_connect(struct config config) { redisContext *c = NULL; if (config.type == CONN_TCP) { c = redisConnect(config.tcp.host, config.tcp.port); } else if (config.type == CONN_SSL) { c = redisConnect(config.ssl.host, config.ssl.port); } else if (config.type == CONN_UNIX) { c = redisConnectUnix(config.unix_sock.path); } else if (config.type == CONN_FD) { /* Create a dummy connection just to get an fd to inherit */ redisContext *dummy_ctx = redisConnectUnix(config.unix_sock.path); if (dummy_ctx) { int fd = disconnect(dummy_ctx, 1); printf("Connecting to inherited fd %d\n", fd); c = redisConnectFd(fd); } } else { assert(NULL); } if (c == NULL) { printf("Connection error: can't allocate redis context\n"); exit(1); } else if (c->err) { printf("Connection error: %s\n", c->errstr); redisFree(c); exit(1); } if (config.type == CONN_SSL) { do_ssl_handshake(c); } return select_database(c); } static void do_reconnect(redisContext *c, struct config config) { redisReconnect(c); if (config.type == CONN_SSL) { do_ssl_handshake(c); } } static void test_format_commands(void) { char *cmd; int len; test("Format command without interpolation: "); len = redisFormatCommand(&cmd,"SET foo bar"); test_cond(strncmp(cmd,"*3\r\n$3\r\nSET\r\n$3\r\nfoo\r\n$3\r\nbar\r\n",len) == 0 && len == 4+4+(3+2)+4+(3+2)+4+(3+2)); hi_free(cmd); test("Format command with %%s string interpolation: "); len = redisFormatCommand(&cmd,"SET %s %s","foo","bar"); test_cond(strncmp(cmd,"*3\r\n$3\r\nSET\r\n$3\r\nfoo\r\n$3\r\nbar\r\n",len) == 0 && len == 4+4+(3+2)+4+(3+2)+4+(3+2)); hi_free(cmd); test("Format command with %%s and an empty string: "); len = redisFormatCommand(&cmd,"SET %s %s","foo",""); test_cond(strncmp(cmd,"*3\r\n$3\r\nSET\r\n$3\r\nfoo\r\n$0\r\n\r\n",len) == 0 && len == 4+4+(3+2)+4+(3+2)+4+(0+2)); hi_free(cmd); test("Format command with an empty string in between proper interpolations: "); len = redisFormatCommand(&cmd,"SET %s %s","","foo"); test_cond(strncmp(cmd,"*3\r\n$3\r\nSET\r\n$0\r\n\r\n$3\r\nfoo\r\n",len) == 0 && len == 4+4+(3+2)+4+(0+2)+4+(3+2)); hi_free(cmd); test("Format command with %%b string interpolation: "); len = redisFormatCommand(&cmd,"SET %b %b","foo",(size_t)3,"b\0r",(size_t)3); test_cond(strncmp(cmd,"*3\r\n$3\r\nSET\r\n$3\r\nfoo\r\n$3\r\nb\0r\r\n",len) == 0 && len == 4+4+(3+2)+4+(3+2)+4+(3+2)); hi_free(cmd); test("Format command with %%b and an empty string: "); len = redisFormatCommand(&cmd,"SET %b %b","foo",(size_t)3,"",(size_t)0); test_cond(strncmp(cmd,"*3\r\n$3\r\nSET\r\n$3\r\nfoo\r\n$0\r\n\r\n",len) == 0 && len == 4+4+(3+2)+4+(3+2)+4+(0+2)); hi_free(cmd); test("Format command with literal %%: "); len = redisFormatCommand(&cmd,"SET %% %%"); test_cond(strncmp(cmd,"*3\r\n$3\r\nSET\r\n$1\r\n%\r\n$1\r\n%\r\n",len) == 0 && len == 4+4+(3+2)+4+(1+2)+4+(1+2)); hi_free(cmd); /* Vararg width depends on the type. These tests make sure that the * width is correctly determined using the format and subsequent varargs * can correctly be interpolated. */ #define INTEGER_WIDTH_TEST(fmt, type) do { \ type value = 123; \ test("Format command with printf-delegation (" #type "): "); \ len = redisFormatCommand(&cmd,"key:%08" fmt " str:%s", value, "hello"); \ test_cond(strncmp(cmd,"*2\r\n$12\r\nkey:00000123\r\n$9\r\nstr:hello\r\n",len) == 0 && \ len == 4+5+(12+2)+4+(9+2)); \ hi_free(cmd); \ } while(0) #define FLOAT_WIDTH_TEST(type) do { \ type value = 123.0; \ test("Format command with printf-delegation (" #type "): "); \ len = redisFormatCommand(&cmd,"key:%08.3f str:%s", value, "hello"); \ test_cond(strncmp(cmd,"*2\r\n$12\r\nkey:0123.000\r\n$9\r\nstr:hello\r\n",len) == 0 && \ len == 4+5+(12+2)+4+(9+2)); \ hi_free(cmd); \ } while(0) INTEGER_WIDTH_TEST("d", int); INTEGER_WIDTH_TEST("hhd", char); INTEGER_WIDTH_TEST("hd", short); INTEGER_WIDTH_TEST("ld", long); INTEGER_WIDTH_TEST("lld", long long); INTEGER_WIDTH_TEST("u", unsigned int); INTEGER_WIDTH_TEST("hhu", unsigned char); INTEGER_WIDTH_TEST("hu", unsigned short); INTEGER_WIDTH_TEST("lu", unsigned long); INTEGER_WIDTH_TEST("llu", unsigned long long); FLOAT_WIDTH_TEST(float); FLOAT_WIDTH_TEST(double); test("Format command with unhandled printf format (specifier 'p' not supported): "); len = redisFormatCommand(&cmd,"key:%08p %b",(void*)1234,"foo",(size_t)3); test_cond(len == -1); test("Format command with invalid printf format (specifier missing): "); len = redisFormatCommand(&cmd,"%-"); test_cond(len == -1); const char *argv[3]; argv[0] = "SET"; argv[1] = "foo\0xxx"; argv[2] = "bar"; size_t lens[3] = { 3, 7, 3 }; int argc = 3; test("Format command by passing argc/argv without lengths: "); len = redisFormatCommandArgv(&cmd,argc,argv,NULL); test_cond(strncmp(cmd,"*3\r\n$3\r\nSET\r\n$3\r\nfoo\r\n$3\r\nbar\r\n",len) == 0 && len == 4+4+(3+2)+4+(3+2)+4+(3+2)); hi_free(cmd); test("Format command by passing argc/argv with lengths: "); len = redisFormatCommandArgv(&cmd,argc,argv,lens); test_cond(strncmp(cmd,"*3\r\n$3\r\nSET\r\n$7\r\nfoo\0xxx\r\n$3\r\nbar\r\n",len) == 0 && len == 4+4+(3+2)+4+(7+2)+4+(3+2)); hi_free(cmd); sds sds_cmd; sds_cmd = NULL; test("Format command into sds by passing argc/argv without lengths: "); len = redisFormatSdsCommandArgv(&sds_cmd,argc,argv,NULL); test_cond(strncmp(sds_cmd,"*3\r\n$3\r\nSET\r\n$3\r\nfoo\r\n$3\r\nbar\r\n",len) == 0 && len == 4+4+(3+2)+4+(3+2)+4+(3+2)); sdsfree(sds_cmd); sds_cmd = NULL; test("Format command into sds by passing argc/argv with lengths: "); len = redisFormatSdsCommandArgv(&sds_cmd,argc,argv,lens); test_cond(strncmp(sds_cmd,"*3\r\n$3\r\nSET\r\n$7\r\nfoo\0xxx\r\n$3\r\nbar\r\n",len) == 0 && len == 4+4+(3+2)+4+(7+2)+4+(3+2)); sdsfree(sds_cmd); } static void test_append_formatted_commands(struct config config) { redisContext *c; redisReply *reply; char *cmd; int len; c = do_connect(config); test("Append format command: "); len = redisFormatCommand(&cmd, "SET foo bar"); test_cond(redisAppendFormattedCommand(c, cmd, len) == REDIS_OK); assert(redisGetReply(c, (void*)&reply) == REDIS_OK); hi_free(cmd); freeReplyObject(reply); disconnect(c, 0); } static void test_reply_reader(void) { redisReader *reader; void *reply, *root; int ret; int i; test("Error handling in reply parser: "); reader = redisReaderCreate(); redisReaderFeed(reader,(char*)"@foo\r\n",6); ret = redisReaderGetReply(reader,NULL); test_cond(ret == REDIS_ERR && strcasecmp(reader->errstr,"Protocol error, got \"@\" as reply type byte") == 0); redisReaderFree(reader); /* when the reply already contains multiple items, they must be free'd * on an error. valgrind will bark when this doesn't happen. */ test("Memory cleanup in reply parser: "); reader = redisReaderCreate(); redisReaderFeed(reader,(char*)"*2\r\n",4); redisReaderFeed(reader,(char*)"$5\r\nhello\r\n",11); redisReaderFeed(reader,(char*)"@foo\r\n",6); ret = redisReaderGetReply(reader,NULL); test_cond(ret == REDIS_ERR && strcasecmp(reader->errstr,"Protocol error, got \"@\" as reply type byte") == 0); redisReaderFree(reader); reader = redisReaderCreate(); test("Can handle arbitrarily nested multi-bulks: "); for (i = 0; i < 128; i++) { redisReaderFeed(reader,(char*)"*1\r\n", 4); } redisReaderFeed(reader,(char*)"$6\r\nLOLWUT\r\n",12); ret = redisReaderGetReply(reader,&reply); root = reply; /* Keep track of the root reply */ test_cond(ret == REDIS_OK && ((redisReply*)reply)->type == REDIS_REPLY_ARRAY && ((redisReply*)reply)->elements == 1); test("Can parse arbitrarily nested multi-bulks correctly: "); while(i--) { assert(reply != NULL && ((redisReply*)reply)->type == REDIS_REPLY_ARRAY); reply = ((redisReply*)reply)->element[0]; } test_cond(((redisReply*)reply)->type == REDIS_REPLY_STRING && !memcmp(((redisReply*)reply)->str, "LOLWUT", 6)); freeReplyObject(root); redisReaderFree(reader); test("Correctly parses LLONG_MAX: "); reader = redisReaderCreate(); redisReaderFeed(reader, ":9223372036854775807\r\n",22); ret = redisReaderGetReply(reader,&reply); test_cond(ret == REDIS_OK && ((redisReply*)reply)->type == REDIS_REPLY_INTEGER && ((redisReply*)reply)->integer == LLONG_MAX); freeReplyObject(reply); redisReaderFree(reader); test("Set error when > LLONG_MAX: "); reader = redisReaderCreate(); redisReaderFeed(reader, ":9223372036854775808\r\n",22); ret = redisReaderGetReply(reader,&reply); test_cond(ret == REDIS_ERR && strcasecmp(reader->errstr,"Bad integer value") == 0); freeReplyObject(reply); redisReaderFree(reader); test("Correctly parses LLONG_MIN: "); reader = redisReaderCreate(); redisReaderFeed(reader, ":-9223372036854775808\r\n",23); ret = redisReaderGetReply(reader,&reply); test_cond(ret == REDIS_OK && ((redisReply*)reply)->type == REDIS_REPLY_INTEGER && ((redisReply*)reply)->integer == LLONG_MIN); freeReplyObject(reply); redisReaderFree(reader); test("Set error when < LLONG_MIN: "); reader = redisReaderCreate(); redisReaderFeed(reader, ":-9223372036854775809\r\n",23); ret = redisReaderGetReply(reader,&reply); test_cond(ret == REDIS_ERR && strcasecmp(reader->errstr,"Bad integer value") == 0); freeReplyObject(reply); redisReaderFree(reader); test("Set error when array < -1: "); reader = redisReaderCreate(); redisReaderFeed(reader, "*-2\r\n+asdf\r\n",12); ret = redisReaderGetReply(reader,&reply); test_cond(ret == REDIS_ERR && strcasecmp(reader->errstr,"Multi-bulk length out of range") == 0); freeReplyObject(reply); redisReaderFree(reader); test("Set error when bulk < -1: "); reader = redisReaderCreate(); redisReaderFeed(reader, "$-2\r\nasdf\r\n",11); ret = redisReaderGetReply(reader,&reply); test_cond(ret == REDIS_ERR && strcasecmp(reader->errstr,"Bulk string length out of range") == 0); freeReplyObject(reply); redisReaderFree(reader); test("Can configure maximum multi-bulk elements: "); reader = redisReaderCreate(); reader->maxelements = 1024; redisReaderFeed(reader, "*1025\r\n", 7); ret = redisReaderGetReply(reader,&reply); test_cond(ret == REDIS_ERR && strcasecmp(reader->errstr, "Multi-bulk length out of range") == 0); freeReplyObject(reply); redisReaderFree(reader); test("Multi-bulk never overflows regardless of maxelements: "); size_t bad_mbulk_len = (SIZE_MAX / sizeof(void *)) + 3; char bad_mbulk_reply[100]; snprintf(bad_mbulk_reply, sizeof(bad_mbulk_reply), "*%llu\r\n+asdf\r\n", (unsigned long long) bad_mbulk_len); reader = redisReaderCreate(); reader->maxelements = 0; /* Don't rely on default limit */ redisReaderFeed(reader, bad_mbulk_reply, strlen(bad_mbulk_reply)); ret = redisReaderGetReply(reader,&reply); test_cond(ret == REDIS_ERR && strcasecmp(reader->errstr, "Out of memory") == 0); freeReplyObject(reply); redisReaderFree(reader); #if LLONG_MAX > SIZE_MAX test("Set error when array > SIZE_MAX: "); reader = redisReaderCreate(); redisReaderFeed(reader, "*9223372036854775807\r\n+asdf\r\n",29); ret = redisReaderGetReply(reader,&reply); test_cond(ret == REDIS_ERR && strcasecmp(reader->errstr,"Multi-bulk length out of range") == 0); freeReplyObject(reply); redisReaderFree(reader); test("Set error when bulk > SIZE_MAX: "); reader = redisReaderCreate(); redisReaderFeed(reader, "$9223372036854775807\r\nasdf\r\n",28); ret = redisReaderGetReply(reader,&reply); test_cond(ret == REDIS_ERR && strcasecmp(reader->errstr,"Bulk string length out of range") == 0); freeReplyObject(reply); redisReaderFree(reader); #endif test("Works with NULL functions for reply: "); reader = redisReaderCreate(); reader->fn = NULL; redisReaderFeed(reader,(char*)"+OK\r\n",5); ret = redisReaderGetReply(reader,&reply); test_cond(ret == REDIS_OK && reply == (void*)REDIS_REPLY_STATUS); redisReaderFree(reader); test("Works when a single newline (\\r\\n) covers two calls to feed: "); reader = redisReaderCreate(); reader->fn = NULL; redisReaderFeed(reader,(char*)"+OK\r",4); ret = redisReaderGetReply(reader,&reply); assert(ret == REDIS_OK && reply == NULL); redisReaderFeed(reader,(char*)"\n",1); ret = redisReaderGetReply(reader,&reply); test_cond(ret == REDIS_OK && reply == (void*)REDIS_REPLY_STATUS); redisReaderFree(reader); test("Don't reset state after protocol error: "); reader = redisReaderCreate(); reader->fn = NULL; redisReaderFeed(reader,(char*)"x",1); ret = redisReaderGetReply(reader,&reply); assert(ret == REDIS_ERR); ret = redisReaderGetReply(reader,&reply); test_cond(ret == REDIS_ERR && reply == NULL); redisReaderFree(reader); test("Don't reset state after protocol error(not segfault): "); reader = redisReaderCreate(); redisReaderFeed(reader,(char*)"*3\r\n$3\r\nSET\r\n$5\r\nhello\r\n$", 25); ret = redisReaderGetReply(reader,&reply); assert(ret == REDIS_OK); redisReaderFeed(reader,(char*)"3\r\nval\r\n", 8); ret = redisReaderGetReply(reader,&reply); test_cond(ret == REDIS_OK && ((redisReply*)reply)->type == REDIS_REPLY_ARRAY && ((redisReply*)reply)->elements == 3); freeReplyObject(reply); redisReaderFree(reader); /* Regression test for issue #45 on GitHub. */ test("Don't do empty allocation for empty multi bulk: "); reader = redisReaderCreate(); redisReaderFeed(reader,(char*)"*0\r\n",4); ret = redisReaderGetReply(reader,&reply); test_cond(ret == REDIS_OK && ((redisReply*)reply)->type == REDIS_REPLY_ARRAY && ((redisReply*)reply)->elements == 0); freeReplyObject(reply); redisReaderFree(reader); /* RESP3 verbatim strings (GitHub issue #802) */ test("Can parse RESP3 verbatim strings: "); reader = redisReaderCreate(); redisReaderFeed(reader,(char*)"=10\r\ntxt:LOLWUT\r\n",17); ret = redisReaderGetReply(reader,&reply); test_cond(ret == REDIS_OK && ((redisReply*)reply)->type == REDIS_REPLY_VERB && !memcmp(((redisReply*)reply)->str,"LOLWUT", 6)); freeReplyObject(reply); redisReaderFree(reader); /* RESP3 push messages (Github issue #815) */ test("Can parse RESP3 push messages: "); reader = redisReaderCreate(); redisReaderFeed(reader,(char*)">2\r\n$6\r\nLOLWUT\r\n:42\r\n",21); ret = redisReaderGetReply(reader,&reply); test_cond(ret == REDIS_OK && ((redisReply*)reply)->type == REDIS_REPLY_PUSH && ((redisReply*)reply)->elements == 2 && ((redisReply*)reply)->element[0]->type == REDIS_REPLY_STRING && !memcmp(((redisReply*)reply)->element[0]->str,"LOLWUT",6) && ((redisReply*)reply)->element[1]->type == REDIS_REPLY_INTEGER && ((redisReply*)reply)->element[1]->integer == 42); freeReplyObject(reply); redisReaderFree(reader); test("Can parse RESP3 doubles: "); reader = redisReaderCreate(); redisReaderFeed(reader, ",3.14159265358979323846\r\n",25); ret = redisReaderGetReply(reader,&reply); test_cond(ret == REDIS_OK && ((redisReply*)reply)->type == REDIS_REPLY_DOUBLE && fabs(((redisReply*)reply)->dval - 3.14159265358979323846) < 0.00000001 && ((redisReply*)reply)->len == 22 && strcmp(((redisReply*)reply)->str, "3.14159265358979323846") == 0); freeReplyObject(reply); redisReaderFree(reader); test("Set error on invalid RESP3 double: "); reader = redisReaderCreate(); redisReaderFeed(reader, ",3.14159\000265358979323846\r\n",26); ret = redisReaderGetReply(reader,&reply); test_cond(ret == REDIS_ERR && strcasecmp(reader->errstr,"Bad double value") == 0); freeReplyObject(reply); redisReaderFree(reader); test("Correctly parses RESP3 double INFINITY: "); reader = redisReaderCreate(); redisReaderFeed(reader, ",inf\r\n",6); ret = redisReaderGetReply(reader,&reply); test_cond(ret == REDIS_OK && ((redisReply*)reply)->type == REDIS_REPLY_DOUBLE && isinf(((redisReply*)reply)->dval) && ((redisReply*)reply)->dval > 0); freeReplyObject(reply); redisReaderFree(reader); test("Set error when RESP3 double is NaN: "); reader = redisReaderCreate(); redisReaderFeed(reader, ",nan\r\n",6); ret = redisReaderGetReply(reader,&reply); test_cond(ret == REDIS_ERR && strcasecmp(reader->errstr,"Bad double value") == 0); freeReplyObject(reply); redisReaderFree(reader); test("Can parse RESP3 nil: "); reader = redisReaderCreate(); redisReaderFeed(reader, "_\r\n",3); ret = redisReaderGetReply(reader,&reply); test_cond(ret == REDIS_OK && ((redisReply*)reply)->type == REDIS_REPLY_NIL); freeReplyObject(reply); redisReaderFree(reader); test("Set error on invalid RESP3 nil: "); reader = redisReaderCreate(); redisReaderFeed(reader, "_nil\r\n",6); ret = redisReaderGetReply(reader,&reply); test_cond(ret == REDIS_ERR && strcasecmp(reader->errstr,"Bad nil value") == 0); freeReplyObject(reply); redisReaderFree(reader); test("Can parse RESP3 bool (true): "); reader = redisReaderCreate(); redisReaderFeed(reader, "#t\r\n",4); ret = redisReaderGetReply(reader,&reply); test_cond(ret == REDIS_OK && ((redisReply*)reply)->type == REDIS_REPLY_BOOL && ((redisReply*)reply)->integer); freeReplyObject(reply); redisReaderFree(reader); test("Can parse RESP3 bool (false): "); reader = redisReaderCreate(); redisReaderFeed(reader, "#f\r\n",4); ret = redisReaderGetReply(reader,&reply); test_cond(ret == REDIS_OK && ((redisReply*)reply)->type == REDIS_REPLY_BOOL && !((redisReply*)reply)->integer); freeReplyObject(reply); redisReaderFree(reader); test("Set error on invalid RESP3 bool: "); reader = redisReaderCreate(); redisReaderFeed(reader, "#foobar\r\n",9); ret = redisReaderGetReply(reader,&reply); test_cond(ret == REDIS_ERR && strcasecmp(reader->errstr,"Bad bool value") == 0); freeReplyObject(reply); redisReaderFree(reader); test("Can parse RESP3 map: "); reader = redisReaderCreate(); redisReaderFeed(reader, "%2\r\n+first\r\n:123\r\n$6\r\nsecond\r\n#t\r\n",34); ret = redisReaderGetReply(reader,&reply); test_cond(ret == REDIS_OK && ((redisReply*)reply)->type == REDIS_REPLY_MAP && ((redisReply*)reply)->elements == 4 && ((redisReply*)reply)->element[0]->type == REDIS_REPLY_STATUS && ((redisReply*)reply)->element[0]->len == 5 && !strcmp(((redisReply*)reply)->element[0]->str,"first") && ((redisReply*)reply)->element[1]->type == REDIS_REPLY_INTEGER && ((redisReply*)reply)->element[1]->integer == 123 && ((redisReply*)reply)->element[2]->type == REDIS_REPLY_STRING && ((redisReply*)reply)->element[2]->len == 6 && !strcmp(((redisReply*)reply)->element[2]->str,"second") && ((redisReply*)reply)->element[3]->type == REDIS_REPLY_BOOL && ((redisReply*)reply)->element[3]->integer); freeReplyObject(reply); redisReaderFree(reader); test("Can parse RESP3 set: "); reader = redisReaderCreate(); redisReaderFeed(reader, "~5\r\n+orange\r\n$5\r\napple\r\n#f\r\n:100\r\n:999\r\n",40); ret = redisReaderGetReply(reader,&reply); test_cond(ret == REDIS_OK && ((redisReply*)reply)->type == REDIS_REPLY_SET && ((redisReply*)reply)->elements == 5 && ((redisReply*)reply)->element[0]->type == REDIS_REPLY_STATUS && ((redisReply*)reply)->element[0]->len == 6 && !strcmp(((redisReply*)reply)->element[0]->str,"orange") && ((redisReply*)reply)->element[1]->type == REDIS_REPLY_STRING && ((redisReply*)reply)->element[1]->len == 5 && !strcmp(((redisReply*)reply)->element[1]->str,"apple") && ((redisReply*)reply)->element[2]->type == REDIS_REPLY_BOOL && !((redisReply*)reply)->element[2]->integer && ((redisReply*)reply)->element[3]->type == REDIS_REPLY_INTEGER && ((redisReply*)reply)->element[3]->integer == 100 && ((redisReply*)reply)->element[4]->type == REDIS_REPLY_INTEGER && ((redisReply*)reply)->element[4]->integer == 999); freeReplyObject(reply); redisReaderFree(reader); test("Can parse RESP3 bignum: "); reader = redisReaderCreate(); redisReaderFeed(reader,"(3492890328409238509324850943850943825024385\r\n",46); ret = redisReaderGetReply(reader,&reply); test_cond(ret == REDIS_OK && ((redisReply*)reply)->type == REDIS_REPLY_BIGNUM && ((redisReply*)reply)->len == 43 && !strcmp(((redisReply*)reply)->str,"3492890328409238509324850943850943825024385")); freeReplyObject(reply); redisReaderFree(reader); } static void test_free_null(void) { void *redisCtx = NULL; void *reply = NULL; test("Don't fail when redisFree is passed a NULL value: "); redisFree(redisCtx); test_cond(redisCtx == NULL); test("Don't fail when freeReplyObject is passed a NULL value: "); freeReplyObject(reply); test_cond(reply == NULL); } static void *hi_malloc_fail(size_t size) { (void)size; return NULL; } static void *hi_calloc_fail(size_t nmemb, size_t size) { (void)nmemb; (void)size; return NULL; } static void *hi_calloc_insecure(size_t nmemb, size_t size) { (void)nmemb; (void)size; insecure_calloc_calls++; return (void*)0xdeadc0de; } static void *hi_realloc_fail(void *ptr, size_t size) { (void)ptr; (void)size; return NULL; } static void test_allocator_injection(void) { void *ptr; hiredisAllocFuncs ha = { .mallocFn = hi_malloc_fail, .callocFn = hi_calloc_fail, .reallocFn = hi_realloc_fail, .strdupFn = strdup, .freeFn = free, }; // Override hiredis allocators hiredisSetAllocators(&ha); test("redisContext uses injected allocators: "); redisContext *c = redisConnect("localhost", 6379); test_cond(c == NULL); test("redisReader uses injected allocators: "); redisReader *reader = redisReaderCreate(); test_cond(reader == NULL); /* Make sure hiredis itself protects against a non-overflow checking calloc */ test("hiredis calloc wrapper protects against overflow: "); ha.callocFn = hi_calloc_insecure; hiredisSetAllocators(&ha); ptr = hi_calloc((SIZE_MAX / sizeof(void*)) + 3, sizeof(void*)); test_cond(ptr == NULL && insecure_calloc_calls == 0); // Return allocators to default hiredisResetAllocators(); } #define HIREDIS_BAD_DOMAIN "idontexist-noreally.com" static void test_blocking_connection_errors(void) { redisContext *c; struct addrinfo hints = {.ai_family = AF_INET}; struct addrinfo *ai_tmp = NULL; int rv = getaddrinfo(HIREDIS_BAD_DOMAIN, "6379", &hints, &ai_tmp); if (rv != 0) { // Address does *not* exist test("Returns error when host cannot be resolved: "); // First see if this domain name *actually* resolves to NXDOMAIN c = redisConnect(HIREDIS_BAD_DOMAIN, 6379); test_cond( c->err == REDIS_ERR_OTHER && (strcmp(c->errstr, "Name or service not known") == 0 || strcmp(c->errstr, "Can't resolve: " HIREDIS_BAD_DOMAIN) == 0 || strcmp(c->errstr, "Name does not resolve") == 0 || strcmp(c->errstr, "nodename nor servname provided, or not known") == 0 || strcmp(c->errstr, "node name or service name not known") == 0 || strcmp(c->errstr, "No address associated with hostname") == 0 || strcmp(c->errstr, "Temporary failure in name resolution") == 0 || strcmp(c->errstr, "hostname nor servname provided, or not known") == 0 || strcmp(c->errstr, "no address associated with name") == 0 || strcmp(c->errstr, "No such host is known. ") == 0)); redisFree(c); } else { printf("Skipping NXDOMAIN test. Found evil ISP!\n"); freeaddrinfo(ai_tmp); } #ifndef _WIN32 test("Returns error when the port is not open: "); c = redisConnect((char*)"localhost", 1); test_cond(c->err == REDIS_ERR_IO && strcmp(c->errstr,"Connection refused") == 0); redisFree(c); test("Returns error when the unix_sock socket path doesn't accept connections: "); c = redisConnectUnix((char*)"/tmp/idontexist.sock"); test_cond(c->err == REDIS_ERR_IO); /* Don't care about the message... */ redisFree(c); #endif } /* Test push handler */ void push_handler(void *privdata, void *r) { struct pushCounters *pcounts = privdata; redisReply *reply = r, *payload; assert(reply && reply->type == REDIS_REPLY_PUSH && reply->elements == 2); payload = reply->element[1]; if (payload->type == REDIS_REPLY_ARRAY) { payload = payload->element[0]; } if (payload->type == REDIS_REPLY_STRING) { pcounts->str++; } else if (payload->type == REDIS_REPLY_NIL) { pcounts->nil++; } freeReplyObject(reply); } /* Dummy function just to test setting a callback with redisOptions */ void push_handler_async(redisAsyncContext *ac, void *reply) { (void)ac; (void)reply; } static void test_resp3_push_handler(redisContext *c) { struct pushCounters pc = {0}; redisPushFn *old = NULL; redisReply *reply; void *privdata; /* Switch to RESP3 and turn on client tracking */ send_hello(c, 3); send_client_tracking(c, "ON"); privdata = c->privdata; c->privdata = &pc; reply = redisCommand(c, "GET key:0"); assert(reply != NULL); freeReplyObject(reply); test("RESP3 PUSH messages are handled out of band by default: "); reply = redisCommand(c, "SET key:0 val:0"); test_cond(reply != NULL && reply->type == REDIS_REPLY_STATUS); freeReplyObject(reply); assert((reply = redisCommand(c, "GET key:0")) != NULL); freeReplyObject(reply); old = redisSetPushCallback(c, push_handler); test("We can set a custom RESP3 PUSH handler: "); reply = redisCommand(c, "SET key:0 val:0"); /* We need another command because depending on the version of Redis, the * notification may be delivered after the command's reply. */ test_cond(reply != NULL); freeReplyObject(reply); reply = redisCommand(c, "PING"); test_cond(reply != NULL && reply->type == REDIS_REPLY_STATUS && pc.str == 1); freeReplyObject(reply); test("We properly handle a NIL invalidation payload: "); reply = redisCommand(c, "FLUSHDB"); test_cond(reply != NULL && reply->type == REDIS_REPLY_STATUS && pc.nil == 1); freeReplyObject(reply); /* Unset the push callback and generate an invalidate message making * sure it is not handled out of band. */ test("With no handler, PUSH replies come in-band: "); redisSetPushCallback(c, NULL); assert((reply = redisCommand(c, "GET key:0")) != NULL); freeReplyObject(reply); assert((reply = redisCommand(c, "SET key:0 invalid")) != NULL); /* Depending on Redis version, we may receive either push notification or * status reply. Both cases are valid. */ if (reply->type == REDIS_REPLY_STATUS) { freeReplyObject(reply); reply = redisCommand(c, "PING"); } test_cond(reply->type == REDIS_REPLY_PUSH); freeReplyObject(reply); test("With no PUSH handler, no replies are lost: "); assert(redisGetReply(c, (void**)&reply) == REDIS_OK); test_cond(reply != NULL && reply->type == REDIS_REPLY_STATUS); freeReplyObject(reply); /* Return to the originally set PUSH handler */ assert(old != NULL); redisSetPushCallback(c, old); /* Switch back to RESP2 and disable tracking */ c->privdata = privdata; send_client_tracking(c, "OFF"); send_hello(c, 2); } redisOptions get_redis_tcp_options(struct config config) { redisOptions options = {0}; REDIS_OPTIONS_SET_TCP(&options, config.tcp.host, config.tcp.port); return options; } static void test_resp3_push_options(struct config config) { redisAsyncContext *ac; redisContext *c; redisOptions options; test("We set a default RESP3 handler for redisContext: "); options = get_redis_tcp_options(config); assert((c = redisConnectWithOptions(&options)) != NULL); test_cond(c->push_cb != NULL); redisFree(c); test("We don't set a default RESP3 push handler for redisAsyncContext: "); options = get_redis_tcp_options(config); assert((ac = redisAsyncConnectWithOptions(&options)) != NULL); test_cond(ac->c.push_cb == NULL); redisAsyncFree(ac); test("Our REDIS_OPT_NO_PUSH_AUTOFREE flag works: "); options = get_redis_tcp_options(config); options.options |= REDIS_OPT_NO_PUSH_AUTOFREE; assert((c = redisConnectWithOptions(&options)) != NULL); test_cond(c->push_cb == NULL); redisFree(c); test("We can use redisOptions to set a custom PUSH handler for redisContext: "); options = get_redis_tcp_options(config); options.push_cb = push_handler; assert((c = redisConnectWithOptions(&options)) != NULL); test_cond(c->push_cb == push_handler); redisFree(c); test("We can use redisOptions to set a custom PUSH handler for redisAsyncContext: "); options = get_redis_tcp_options(config); options.async_push_cb = push_handler_async; assert((ac = redisAsyncConnectWithOptions(&options)) != NULL); test_cond(ac->push_cb == push_handler_async); redisAsyncFree(ac); } void free_privdata(void *privdata) { struct privdata *data = privdata; data->dtor_counter++; } static void test_privdata_hooks(struct config config) { struct privdata data = {0}; redisOptions options; redisContext *c; test("We can use redisOptions to set privdata: "); options = get_redis_tcp_options(config); REDIS_OPTIONS_SET_PRIVDATA(&options, &data, free_privdata); assert((c = redisConnectWithOptions(&options)) != NULL); test_cond(c->privdata == &data); test("Our privdata destructor fires when we free the context: "); redisFree(c); test_cond(data.dtor_counter == 1); } static void test_blocking_connection(struct config config) { redisContext *c; redisReply *reply; int major; c = do_connect(config); test("Is able to deliver commands: "); reply = redisCommand(c,"PING"); test_cond(reply->type == REDIS_REPLY_STATUS && strcasecmp(reply->str,"pong") == 0) freeReplyObject(reply); test("Is a able to send commands verbatim: "); reply = redisCommand(c,"SET foo bar"); test_cond (reply->type == REDIS_REPLY_STATUS && strcasecmp(reply->str,"ok") == 0) freeReplyObject(reply); test("%%s String interpolation works: "); reply = redisCommand(c,"SET %s %s","foo","hello world"); freeReplyObject(reply); reply = redisCommand(c,"GET foo"); test_cond(reply->type == REDIS_REPLY_STRING && strcmp(reply->str,"hello world") == 0); freeReplyObject(reply); test("%%b String interpolation works: "); reply = redisCommand(c,"SET %b %b","foo",(size_t)3,"hello\x00world",(size_t)11); freeReplyObject(reply); reply = redisCommand(c,"GET foo"); test_cond(reply->type == REDIS_REPLY_STRING && memcmp(reply->str,"hello\x00world",11) == 0) test("Binary reply length is correct: "); test_cond(reply->len == 11) freeReplyObject(reply); test("Can parse nil replies: "); reply = redisCommand(c,"GET nokey"); test_cond(reply->type == REDIS_REPLY_NIL) freeReplyObject(reply); /* test 7 */ test("Can parse integer replies: "); reply = redisCommand(c,"INCR mycounter"); test_cond(reply->type == REDIS_REPLY_INTEGER && reply->integer == 1) freeReplyObject(reply); test("Can parse multi bulk replies: "); freeReplyObject(redisCommand(c,"LPUSH mylist foo")); freeReplyObject(redisCommand(c,"LPUSH mylist bar")); reply = redisCommand(c,"LRANGE mylist 0 -1"); test_cond(reply->type == REDIS_REPLY_ARRAY && reply->elements == 2 && !memcmp(reply->element[0]->str,"bar",3) && !memcmp(reply->element[1]->str,"foo",3)) freeReplyObject(reply); /* m/e with multi bulk reply *before* other reply. * specifically test ordering of reply items to parse. */ test("Can handle nested multi bulk replies: "); freeReplyObject(redisCommand(c,"MULTI")); freeReplyObject(redisCommand(c,"LRANGE mylist 0 -1")); freeReplyObject(redisCommand(c,"PING")); reply = (redisCommand(c,"EXEC")); test_cond(reply->type == REDIS_REPLY_ARRAY && reply->elements == 2 && reply->element[0]->type == REDIS_REPLY_ARRAY && reply->element[0]->elements == 2 && !memcmp(reply->element[0]->element[0]->str,"bar",3) && !memcmp(reply->element[0]->element[1]->str,"foo",3) && reply->element[1]->type == REDIS_REPLY_STATUS && strcasecmp(reply->element[1]->str,"pong") == 0); freeReplyObject(reply); /* Make sure passing NULL to redisGetReply is safe */ test("Can pass NULL to redisGetReply: "); assert(redisAppendCommand(c, "PING") == REDIS_OK); test_cond(redisGetReply(c, NULL) == REDIS_OK); get_redis_version(c, &major, NULL); if (major >= 6) test_resp3_push_handler(c); test_resp3_push_options(config); test_privdata_hooks(config); disconnect(c, 0); } /* Send DEBUG SLEEP 0 to detect if we have this command */ static int detect_debug_sleep(redisContext *c) { int detected; redisReply *reply = redisCommand(c, "DEBUG SLEEP 0\r\n"); if (reply == NULL || c->err) { const char *cause = c->err ? c->errstr : "(none)"; fprintf(stderr, "Error testing for DEBUG SLEEP (Redis error: %s), exiting\n", cause); exit(-1); } detected = reply->type == REDIS_REPLY_STATUS; freeReplyObject(reply); return detected; } static void test_blocking_connection_timeouts(struct config config) { redisContext *c; redisReply *reply; ssize_t s; const char *sleep_cmd = "DEBUG SLEEP 3\r\n"; struct timeval tv; c = do_connect(config); test("Successfully completes a command when the timeout is not exceeded: "); reply = redisCommand(c,"SET foo fast"); freeReplyObject(reply); tv.tv_sec = 0; tv.tv_usec = 10000; redisSetTimeout(c, tv); reply = redisCommand(c, "GET foo"); test_cond(reply != NULL && reply->type == REDIS_REPLY_STRING && memcmp(reply->str, "fast", 4) == 0); freeReplyObject(reply); disconnect(c, 0); c = do_connect(config); test("Does not return a reply when the command times out: "); if (detect_debug_sleep(c)) { redisAppendFormattedCommand(c, sleep_cmd, strlen(sleep_cmd)); // flush connection buffer without waiting for the reply s = c->funcs->write(c); assert(s == (ssize_t)sdslen(c->obuf)); sdsfree(c->obuf); c->obuf = sdsempty(); tv.tv_sec = 0; tv.tv_usec = 10000; redisSetTimeout(c, tv); reply = redisCommand(c, "GET foo"); #ifndef _WIN32 test_cond(s > 0 && reply == NULL && c->err == REDIS_ERR_IO && strcmp(c->errstr, "Resource temporarily unavailable") == 0); #else test_cond(s > 0 && reply == NULL && c->err == REDIS_ERR_TIMEOUT && strcmp(c->errstr, "recv timeout") == 0); #endif freeReplyObject(reply); // wait for the DEBUG SLEEP to complete so that Redis server is unblocked for the following tests millisleep(3000); } else { test_skipped(); } test("Reconnect properly reconnects after a timeout: "); do_reconnect(c, config); reply = redisCommand(c, "PING"); test_cond(reply != NULL && reply->type == REDIS_REPLY_STATUS && strcmp(reply->str, "PONG") == 0); freeReplyObject(reply); test("Reconnect properly uses owned parameters: "); config.tcp.host = "foo"; config.unix_sock.path = "foo"; do_reconnect(c, config); reply = redisCommand(c, "PING"); test_cond(reply != NULL && reply->type == REDIS_REPLY_STATUS && strcmp(reply->str, "PONG") == 0); freeReplyObject(reply); disconnect(c, 0); } static void test_blocking_io_errors(struct config config) { redisContext *c; redisReply *reply; void *_reply; int major, minor; /* Connect to target given by config. */ c = do_connect(config); get_redis_version(c, &major, &minor); test("Returns I/O error when the connection is lost: "); reply = redisCommand(c,"QUIT"); if (major > 2 || (major == 2 && minor > 0)) { /* > 2.0 returns OK on QUIT and read() should be issued once more * to know the descriptor is at EOF. */ test_cond(strcasecmp(reply->str,"OK") == 0 && redisGetReply(c,&_reply) == REDIS_ERR); freeReplyObject(reply); } else { test_cond(reply == NULL); } #ifndef _WIN32 /* On 2.0, QUIT will cause the connection to be closed immediately and * the read(2) for the reply on QUIT will set the error to EOF. * On >2.0, QUIT will return with OK and another read(2) needed to be * issued to find out the socket was closed by the server. In both * conditions, the error will be set to EOF. */ assert(c->err == REDIS_ERR_EOF && strcmp(c->errstr,"Server closed the connection") == 0); #endif redisFree(c); c = do_connect(config); test("Returns I/O error on socket timeout: "); struct timeval tv = { 0, 1000 }; assert(redisSetTimeout(c,tv) == REDIS_OK); int respcode = redisGetReply(c,&_reply); #ifndef _WIN32 test_cond(respcode == REDIS_ERR && c->err == REDIS_ERR_IO && errno == EAGAIN); #else test_cond(respcode == REDIS_ERR && c->err == REDIS_ERR_TIMEOUT); #endif redisFree(c); } static void test_invalid_timeout_errors(struct config config) { redisContext *c; test("Set error when an invalid timeout usec value is given to redisConnectWithTimeout: "); config.tcp.timeout.tv_sec = 0; config.tcp.timeout.tv_usec = 10000001; c = redisConnectWithTimeout(config.tcp.host, config.tcp.port, config.tcp.timeout); test_cond(c->err == REDIS_ERR_IO && strcmp(c->errstr, "Invalid timeout specified") == 0); redisFree(c); test("Set error when an invalid timeout sec value is given to redisConnectWithTimeout: "); config.tcp.timeout.tv_sec = (((LONG_MAX) - 999) / 1000) + 1; config.tcp.timeout.tv_usec = 0; c = redisConnectWithTimeout(config.tcp.host, config.tcp.port, config.tcp.timeout); test_cond(c->err == REDIS_ERR_IO && strcmp(c->errstr, "Invalid timeout specified") == 0); redisFree(c); } /* Wrap malloc to abort on failure so OOM checks don't make the test logic * harder to follow. */ void *hi_malloc_safe(size_t size) { void *ptr = hi_malloc(size); if (ptr == NULL) { fprintf(stderr, "Error: Out of memory\n"); exit(-1); } return ptr; } static void test_throughput(struct config config) { redisContext *c = do_connect(config); redisReply **replies; int i, num; long long t1, t2; test("Throughput:\n"); for (i = 0; i < 500; i++) freeReplyObject(redisCommand(c,"LPUSH mylist foo")); num = 1000; replies = hi_malloc_safe(sizeof(redisReply*)*num); t1 = usec(); for (i = 0; i < num; i++) { replies[i] = redisCommand(c,"PING"); assert(replies[i] != NULL && replies[i]->type == REDIS_REPLY_STATUS); } t2 = usec(); for (i = 0; i < num; i++) freeReplyObject(replies[i]); hi_free(replies); printf("\t(%dx PING: %.3fs)\n", num, (t2-t1)/1000000.0); replies = hi_malloc_safe(sizeof(redisReply*)*num); t1 = usec(); for (i = 0; i < num; i++) { replies[i] = redisCommand(c,"LRANGE mylist 0 499"); assert(replies[i] != NULL && replies[i]->type == REDIS_REPLY_ARRAY); assert(replies[i] != NULL && replies[i]->elements == 500); } t2 = usec(); for (i = 0; i < num; i++) freeReplyObject(replies[i]); hi_free(replies); printf("\t(%dx LRANGE with 500 elements: %.3fs)\n", num, (t2-t1)/1000000.0); replies = hi_malloc_safe(sizeof(redisReply*)*num); t1 = usec(); for (i = 0; i < num; i++) { replies[i] = redisCommand(c, "INCRBY incrkey %d", 1000000); assert(replies[i] != NULL && replies[i]->type == REDIS_REPLY_INTEGER); } t2 = usec(); for (i = 0; i < num; i++) freeReplyObject(replies[i]); hi_free(replies); printf("\t(%dx INCRBY: %.3fs)\n", num, (t2-t1)/1000000.0); num = 10000; replies = hi_malloc_safe(sizeof(redisReply*)*num); for (i = 0; i < num; i++) redisAppendCommand(c,"PING"); t1 = usec(); for (i = 0; i < num; i++) { assert(redisGetReply(c, (void*)&replies[i]) == REDIS_OK); assert(replies[i] != NULL && replies[i]->type == REDIS_REPLY_STATUS); } t2 = usec(); for (i = 0; i < num; i++) freeReplyObject(replies[i]); hi_free(replies); printf("\t(%dx PING (pipelined): %.3fs)\n", num, (t2-t1)/1000000.0); replies = hi_malloc_safe(sizeof(redisReply*)*num); for (i = 0; i < num; i++) redisAppendCommand(c,"LRANGE mylist 0 499"); t1 = usec(); for (i = 0; i < num; i++) { assert(redisGetReply(c, (void*)&replies[i]) == REDIS_OK); assert(replies[i] != NULL && replies[i]->type == REDIS_REPLY_ARRAY); assert(replies[i] != NULL && replies[i]->elements == 500); } t2 = usec(); for (i = 0; i < num; i++) freeReplyObject(replies[i]); hi_free(replies); printf("\t(%dx LRANGE with 500 elements (pipelined): %.3fs)\n", num, (t2-t1)/1000000.0); replies = hi_malloc_safe(sizeof(redisReply*)*num); for (i = 0; i < num; i++) redisAppendCommand(c,"INCRBY incrkey %d", 1000000); t1 = usec(); for (i = 0; i < num; i++) { assert(redisGetReply(c, (void*)&replies[i]) == REDIS_OK); assert(replies[i] != NULL && replies[i]->type == REDIS_REPLY_INTEGER); } t2 = usec(); for (i = 0; i < num; i++) freeReplyObject(replies[i]); hi_free(replies); printf("\t(%dx INCRBY (pipelined): %.3fs)\n", num, (t2-t1)/1000000.0); disconnect(c, 0); } // static long __test_callback_flags = 0; // static void __test_callback(redisContext *c, void *privdata) { // ((void)c); // /* Shift to detect execution order */ // __test_callback_flags <<= 8; // __test_callback_flags |= (long)privdata; // } // // static void __test_reply_callback(redisContext *c, redisReply *reply, void *privdata) { // ((void)c); // /* Shift to detect execution order */ // __test_callback_flags <<= 8; // __test_callback_flags |= (long)privdata; // if (reply) freeReplyObject(reply); // } // // static redisContext *__connect_nonblock() { // /* Reset callback flags */ // __test_callback_flags = 0; // return redisConnectNonBlock("127.0.0.1", port, NULL); // } // // static void test_nonblocking_connection() { // redisContext *c; // int wdone = 0; // // test("Calls command callback when command is issued: "); // c = __connect_nonblock(); // redisSetCommandCallback(c,__test_callback,(void*)1); // redisCommand(c,"PING"); // test_cond(__test_callback_flags == 1); // redisFree(c); // // test("Calls disconnect callback on redisDisconnect: "); // c = __connect_nonblock(); // redisSetDisconnectCallback(c,__test_callback,(void*)2); // redisDisconnect(c); // test_cond(__test_callback_flags == 2); // redisFree(c); // // test("Calls disconnect callback and free callback on redisFree: "); // c = __connect_nonblock(); // redisSetDisconnectCallback(c,__test_callback,(void*)2); // redisSetFreeCallback(c,__test_callback,(void*)4); // redisFree(c); // test_cond(__test_callback_flags == ((2 << 8) | 4)); // // test("redisBufferWrite against empty write buffer: "); // c = __connect_nonblock(); // test_cond(redisBufferWrite(c,&wdone) == REDIS_OK && wdone == 1); // redisFree(c); // // test("redisBufferWrite against not yet connected fd: "); // c = __connect_nonblock(); // redisCommand(c,"PING"); // test_cond(redisBufferWrite(c,NULL) == REDIS_ERR && // strncmp(c->error,"write:",6) == 0); // redisFree(c); // // test("redisBufferWrite against closed fd: "); // c = __connect_nonblock(); // redisCommand(c,"PING"); // redisDisconnect(c); // test_cond(redisBufferWrite(c,NULL) == REDIS_ERR && // strncmp(c->error,"write:",6) == 0); // redisFree(c); // // test("Process callbacks in the right sequence: "); // c = __connect_nonblock(); // redisCommandWithCallback(c,__test_reply_callback,(void*)1,"PING"); // redisCommandWithCallback(c,__test_reply_callback,(void*)2,"PING"); // redisCommandWithCallback(c,__test_reply_callback,(void*)3,"PING"); // // /* Write output buffer */ // wdone = 0; // while(!wdone) { // usleep(500); // redisBufferWrite(c,&wdone); // } // // /* Read until at least one callback is executed (the 3 replies will // * arrive in a single packet, causing all callbacks to be executed in // * a single pass). */ // while(__test_callback_flags == 0) { // assert(redisBufferRead(c) == REDIS_OK); // redisProcessCallbacks(c); // } // test_cond(__test_callback_flags == 0x010203); // redisFree(c); // // test("redisDisconnect executes pending callbacks with NULL reply: "); // c = __connect_nonblock(); // redisSetDisconnectCallback(c,__test_callback,(void*)1); // redisCommandWithCallback(c,__test_reply_callback,(void*)2,"PING"); // redisDisconnect(c); // test_cond(__test_callback_flags == 0x0201); // redisFree(c); // } #ifdef HIREDIS_TEST_ASYNC struct event_base *base; typedef struct TestState { redisOptions *options; int checkpoint; int resp3; int disconnect; } TestState; /* Helper to disconnect and stop event loop */ void async_disconnect(redisAsyncContext *ac) { redisAsyncDisconnect(ac); event_base_loopbreak(base); } /* Testcase timeout, will trigger a failure */ void timeout_cb(int fd, short event, void *arg) { (void) fd; (void) event; (void) arg; printf("Timeout in async testing!\n"); exit(1); } /* Unexpected call, will trigger a failure */ void unexpected_cb(redisAsyncContext *ac, void *r, void *privdata) { (void) ac; (void) r; printf("Unexpected call: %s\n",(char*)privdata); exit(1); } /* Helper function to publish a message via own client. */ void publish_msg(redisOptions *options, const char* channel, const char* msg) { redisContext *c = redisConnectWithOptions(options); assert(c != NULL); redisReply *reply = redisCommand(c,"PUBLISH %s %s",channel,msg); assert(reply->type == REDIS_REPLY_INTEGER && reply->integer == 1); freeReplyObject(reply); disconnect(c, 0); } /* Expect a reply of type INTEGER */ void integer_cb(redisAsyncContext *ac, void *r, void *privdata) { redisReply *reply = r; TestState *state = privdata; assert(reply != NULL && reply->type == REDIS_REPLY_INTEGER); state->checkpoint++; if (state->disconnect) async_disconnect(ac); } /* Subscribe callback for test_pubsub_handling and test_pubsub_handling_resp3: * - a published message triggers an unsubscribe * - a command is sent before the unsubscribe response is received. */ void subscribe_cb(redisAsyncContext *ac, void *r, void *privdata) { redisReply *reply = r; TestState *state = privdata; assert(reply != NULL && reply->type == (state->resp3 ? REDIS_REPLY_PUSH : REDIS_REPLY_ARRAY) && reply->elements == 3); if (strcmp(reply->element[0]->str,"subscribe") == 0) { assert(strcmp(reply->element[1]->str,"mychannel") == 0 && reply->element[2]->str == NULL); publish_msg(state->options,"mychannel","Hello!"); } else if (strcmp(reply->element[0]->str,"message") == 0) { assert(strcmp(reply->element[1]->str,"mychannel") == 0 && strcmp(reply->element[2]->str,"Hello!") == 0); state->checkpoint++; /* Unsubscribe after receiving the published message. Send unsubscribe * which should call the callback registered during subscribe */ redisAsyncCommand(ac,unexpected_cb, (void*)"unsubscribe should call subscribe_cb()", "unsubscribe"); /* Send a regular command after unsubscribing, then disconnect */ state->disconnect = 1; redisAsyncCommand(ac,integer_cb,state,"LPUSH mylist foo"); } else if (strcmp(reply->element[0]->str,"unsubscribe") == 0) { assert(strcmp(reply->element[1]->str,"mychannel") == 0 && reply->element[2]->str == NULL); } else { printf("Unexpected pubsub command: %s\n", reply->element[0]->str); exit(1); } } /* Expect a reply of type ARRAY */ void array_cb(redisAsyncContext *ac, void *r, void *privdata) { redisReply *reply = r; TestState *state = privdata; assert(reply != NULL && reply->type == REDIS_REPLY_ARRAY); state->checkpoint++; if (state->disconnect) async_disconnect(ac); } /* Expect a NULL reply */ void null_cb(redisAsyncContext *ac, void *r, void *privdata) { (void) ac; assert(r == NULL); TestState *state = privdata; state->checkpoint++; } static void test_pubsub_handling(struct config config) { test("Subscribe, handle published message and unsubscribe: "); /* Setup event dispatcher with a testcase timeout */ base = event_base_new(); struct event *timeout = evtimer_new(base, timeout_cb, NULL); assert(timeout != NULL); evtimer_assign(timeout,base,timeout_cb,NULL); struct timeval timeout_tv = {.tv_sec = 10}; evtimer_add(timeout, &timeout_tv); /* Connect */ redisOptions options = get_redis_tcp_options(config); redisAsyncContext *ac = redisAsyncConnectWithOptions(&options); assert(ac != NULL && ac->err == 0); redisLibeventAttach(ac,base); /* Start subscribe */ TestState state = {.options = &options}; redisAsyncCommand(ac,subscribe_cb,&state,"subscribe mychannel"); /* Make sure non-subscribe commands are handled */ redisAsyncCommand(ac,array_cb,&state,"PING"); /* Start event dispatching loop */ test_cond(event_base_dispatch(base) == 0); event_free(timeout); event_base_free(base); /* Verify test checkpoints */ assert(state.checkpoint == 3); } /* Unexpected push message, will trigger a failure */ void unexpected_push_cb(redisAsyncContext *ac, void *r) { (void) ac; (void) r; printf("Unexpected call to the PUSH callback!\n"); exit(1); } static void test_pubsub_handling_resp3(struct config config) { test("Subscribe, handle published message and unsubscribe using RESP3: "); /* Setup event dispatcher with a testcase timeout */ base = event_base_new(); struct event *timeout = evtimer_new(base, timeout_cb, NULL); assert(timeout != NULL); evtimer_assign(timeout,base,timeout_cb,NULL); struct timeval timeout_tv = {.tv_sec = 10}; evtimer_add(timeout, &timeout_tv); /* Connect */ redisOptions options = get_redis_tcp_options(config); redisAsyncContext *ac = redisAsyncConnectWithOptions(&options); assert(ac != NULL && ac->err == 0); redisLibeventAttach(ac,base); /* Not expecting any push messages in this test */ redisAsyncSetPushCallback(ac, unexpected_push_cb); /* Switch protocol */ redisAsyncCommand(ac,NULL,NULL,"HELLO 3"); /* Start subscribe */ TestState state = {.options = &options, .resp3 = 1}; redisAsyncCommand(ac,subscribe_cb,&state,"subscribe mychannel"); /* Make sure non-subscribe commands are handled in RESP3 */ redisAsyncCommand(ac,integer_cb,&state,"LPUSH mylist foo"); redisAsyncCommand(ac,integer_cb,&state,"LPUSH mylist foo"); redisAsyncCommand(ac,integer_cb,&state,"LPUSH mylist foo"); /* Handle an array with 3 elements as a non-subscribe command */ redisAsyncCommand(ac,array_cb,&state,"LRANGE mylist 0 2"); /* Start event dispatching loop */ test_cond(event_base_dispatch(base) == 0); event_free(timeout); event_base_free(base); /* Verify test checkpoints */ assert(state.checkpoint == 6); } /* Subscribe callback for test_command_timeout_during_pubsub: * - a subscribe response triggers a published message * - the published message triggers a command that times out * - the command timeout triggers a disconnect */ void subscribe_with_timeout_cb(redisAsyncContext *ac, void *r, void *privdata) { redisReply *reply = r; TestState *state = privdata; /* The non-clean disconnect should trigger the * subscription callback with a NULL reply. */ if (reply == NULL) { state->checkpoint++; event_base_loopbreak(base); return; } assert(reply->type == (state->resp3 ? REDIS_REPLY_PUSH : REDIS_REPLY_ARRAY) && reply->elements == 3); if (strcmp(reply->element[0]->str,"subscribe") == 0) { assert(strcmp(reply->element[1]->str,"mychannel") == 0 && reply->element[2]->str == NULL); publish_msg(state->options,"mychannel","Hello!"); state->checkpoint++; } else if (strcmp(reply->element[0]->str,"message") == 0) { assert(strcmp(reply->element[1]->str,"mychannel") == 0 && strcmp(reply->element[2]->str,"Hello!") == 0); state->checkpoint++; /* Send a command that will trigger a timeout */ redisAsyncCommand(ac,null_cb,state,"DEBUG SLEEP 3"); redisAsyncCommand(ac,null_cb,state,"LPUSH mylist foo"); } else { printf("Unexpected pubsub command: %s\n", reply->element[0]->str); exit(1); } } static void test_command_timeout_during_pubsub(struct config config) { test("Command timeout during Pub/Sub: "); /* Setup event dispatcher with a testcase timeout */ base = event_base_new(); struct event *timeout = evtimer_new(base,timeout_cb,NULL); assert(timeout != NULL); evtimer_assign(timeout,base,timeout_cb,NULL); struct timeval timeout_tv = {.tv_sec = 10}; evtimer_add(timeout,&timeout_tv); /* Connect */ redisOptions options = get_redis_tcp_options(config); redisAsyncContext *ac = redisAsyncConnectWithOptions(&options); assert(ac != NULL && ac->err == 0); redisLibeventAttach(ac,base); /* Configure a command timout */ struct timeval command_timeout = {.tv_sec = 2}; redisAsyncSetTimeout(ac,command_timeout); /* Not expecting any push messages in this test */ redisAsyncSetPushCallback(ac,unexpected_push_cb); /* Switch protocol */ redisAsyncCommand(ac,NULL,NULL,"HELLO 3"); /* Start subscribe */ TestState state = {.options = &options, .resp3 = 1}; redisAsyncCommand(ac,subscribe_with_timeout_cb,&state,"subscribe mychannel"); /* Start event dispatching loop */ assert(event_base_dispatch(base) == 0); event_free(timeout); event_base_free(base); /* Verify test checkpoints */ test_cond(state.checkpoint == 5); } /* Subscribe callback for test_pubsub_multiple_channels */ void subscribe_channel_a_cb(redisAsyncContext *ac, void *r, void *privdata) { redisReply *reply = r; TestState *state = privdata; assert(reply != NULL && reply->type == REDIS_REPLY_ARRAY && reply->elements == 3); if (strcmp(reply->element[0]->str,"subscribe") == 0) { assert(strcmp(reply->element[1]->str,"A") == 0); publish_msg(state->options,"A","Hello!"); state->checkpoint++; } else if (strcmp(reply->element[0]->str,"message") == 0) { assert(strcmp(reply->element[1]->str,"A") == 0 && strcmp(reply->element[2]->str,"Hello!") == 0); state->checkpoint++; /* Unsubscribe to channels, including channel X & Z which we don't subscribe to */ redisAsyncCommand(ac,unexpected_cb, (void*)"unsubscribe should not call unexpected_cb()", "unsubscribe B X A A Z"); /* Unsubscribe to patterns, none which we subscribe to */ redisAsyncCommand(ac,unexpected_cb, (void*)"punsubscribe should not call unexpected_cb()", "punsubscribe"); /* Send a regular command after unsubscribing, then disconnect */ state->disconnect = 1; redisAsyncCommand(ac,integer_cb,state,"LPUSH mylist foo"); } else if (strcmp(reply->element[0]->str,"unsubscribe") == 0) { assert(strcmp(reply->element[1]->str,"A") == 0); state->checkpoint++; } else { printf("Unexpected pubsub command: %s\n", reply->element[0]->str); exit(1); } } /* Subscribe callback for test_pubsub_multiple_channels */ void subscribe_channel_b_cb(redisAsyncContext *ac, void *r, void *privdata) { redisReply *reply = r; TestState *state = privdata; assert(reply != NULL && reply->type == REDIS_REPLY_ARRAY && reply->elements == 3); if (strcmp(reply->element[0]->str,"subscribe") == 0) { assert(strcmp(reply->element[1]->str,"B") == 0); state->checkpoint++; } else if (strcmp(reply->element[0]->str,"unsubscribe") == 0) { assert(strcmp(reply->element[1]->str,"B") == 0); state->checkpoint++; } else { printf("Unexpected pubsub command: %s\n", reply->element[0]->str); exit(1); } } /* Test handling of multiple channels * - subscribe to channel A and B * - a published message on A triggers an unsubscribe of channel B, X, A and Z * where channel X and Z are not subscribed to. * - the published message also triggers an unsubscribe to patterns. Since no * pattern is subscribed to the responded pattern element type is NIL. * - a command sent after unsubscribe triggers a disconnect */ static void test_pubsub_multiple_channels(struct config config) { test("Subscribe to multiple channels: "); /* Setup event dispatcher with a testcase timeout */ base = event_base_new(); struct event *timeout = evtimer_new(base,timeout_cb,NULL); assert(timeout != NULL); evtimer_assign(timeout,base,timeout_cb,NULL); struct timeval timeout_tv = {.tv_sec = 10}; evtimer_add(timeout,&timeout_tv); /* Connect */ redisOptions options = get_redis_tcp_options(config); redisAsyncContext *ac = redisAsyncConnectWithOptions(&options); assert(ac != NULL && ac->err == 0); redisLibeventAttach(ac,base); /* Not expecting any push messages in this test */ redisAsyncSetPushCallback(ac,unexpected_push_cb); /* Start subscribing to two channels */ TestState state = {.options = &options}; redisAsyncCommand(ac,subscribe_channel_a_cb,&state,"subscribe A"); redisAsyncCommand(ac,subscribe_channel_b_cb,&state,"subscribe B"); /* Start event dispatching loop */ assert(event_base_dispatch(base) == 0); event_free(timeout); event_base_free(base); /* Verify test checkpoints */ test_cond(state.checkpoint == 6); } /* Command callback for test_monitor() */ void monitor_cb(redisAsyncContext *ac, void *r, void *privdata) { redisReply *reply = r; TestState *state = privdata; /* NULL reply is received when BYE triggers a disconnect. */ if (reply == NULL) { event_base_loopbreak(base); return; } assert(reply != NULL && reply->type == REDIS_REPLY_STATUS); state->checkpoint++; if (state->checkpoint == 1) { /* Response from MONITOR */ redisContext *c = redisConnectWithOptions(state->options); assert(c != NULL); redisReply *reply = redisCommand(c,"SET first 1"); assert(reply->type == REDIS_REPLY_STATUS); freeReplyObject(reply); redisFree(c); } else if (state->checkpoint == 2) { /* Response for monitored command 'SET first 1' */ assert(strstr(reply->str,"first") != NULL); redisContext *c = redisConnectWithOptions(state->options); assert(c != NULL); redisReply *reply = redisCommand(c,"SET second 2"); assert(reply->type == REDIS_REPLY_STATUS); freeReplyObject(reply); redisFree(c); } else if (state->checkpoint == 3) { /* Response for monitored command 'SET second 2' */ assert(strstr(reply->str,"second") != NULL); /* Send QUIT to disconnect */ redisAsyncCommand(ac,NULL,NULL,"QUIT"); } } /* Test handling of the monitor command * - sends MONITOR to enable monitoring. * - sends SET commands via separate clients to be monitored. * - sends QUIT to stop monitoring and disconnect. */ static void test_monitor(struct config config) { test("Enable monitoring: "); /* Setup event dispatcher with a testcase timeout */ base = event_base_new(); struct event *timeout = evtimer_new(base, timeout_cb, NULL); assert(timeout != NULL); evtimer_assign(timeout,base,timeout_cb,NULL); struct timeval timeout_tv = {.tv_sec = 10}; evtimer_add(timeout, &timeout_tv); /* Connect */ redisOptions options = get_redis_tcp_options(config); redisAsyncContext *ac = redisAsyncConnectWithOptions(&options); assert(ac != NULL && ac->err == 0); redisLibeventAttach(ac,base); /* Not expecting any push messages in this test */ redisAsyncSetPushCallback(ac,unexpected_push_cb); /* Start monitor */ TestState state = {.options = &options}; redisAsyncCommand(ac,monitor_cb,&state,"monitor"); /* Start event dispatching loop */ test_cond(event_base_dispatch(base) == 0); event_free(timeout); event_base_free(base); /* Verify test checkpoints */ assert(state.checkpoint == 3); } #endif /* HIREDIS_TEST_ASYNC */ /* tests for async api using polling adapter, requires no extra libraries*/ /* enum for the test cases, the callbacks have different logic based on them */ typedef enum astest_no { ASTEST_CONNECT=0, ASTEST_CONN_TIMEOUT, ASTEST_PINGPONG, ASTEST_PINGPONG_TIMEOUT, ASTEST_ISSUE_931, ASTEST_ISSUE_931_PING }astest_no; /* a static context for the async tests */ struct _astest { redisAsyncContext *ac; astest_no testno; int counter; int connects; int connect_status; int disconnects; int pongs; int disconnect_status; int connected; int err; char errstr[256]; }; static struct _astest astest; /* async callbacks */ static void asCleanup(void* data) { struct _astest *t = (struct _astest *)data; t->ac = NULL; } static void commandCallback(struct redisAsyncContext *ac, void* _reply, void* _privdata); static void connectCallback(redisAsyncContext *c, int status) { struct _astest *t = (struct _astest *)c->data; assert(t == &astest); assert(t->connects == 0); t->err = c->err; strcpy(t->errstr, c->errstr); t->connects++; t->connect_status = status; t->connected = status == REDIS_OK ? 1 : -1; if (t->testno == ASTEST_ISSUE_931) { /* disconnect again */ redisAsyncDisconnect(c); } else if (t->testno == ASTEST_ISSUE_931_PING) { status = redisAsyncCommand(c, commandCallback, NULL, "PING"); } } static void disconnectCallback(const redisAsyncContext *c, int status) { assert(c->data == (void*)&astest); assert(astest.disconnects == 0); astest.err = c->err; strcpy(astest.errstr, c->errstr); astest.disconnects++; astest.disconnect_status = status; astest.connected = 0; } static void commandCallback(struct redisAsyncContext *ac, void* _reply, void* _privdata) { redisReply *reply = (redisReply*)_reply; struct _astest *t = (struct _astest *)ac->data; assert(t == &astest); (void)_privdata; t->err = ac->err; strcpy(t->errstr, ac->errstr); t->counter++; if (t->testno == ASTEST_PINGPONG ||t->testno == ASTEST_ISSUE_931_PING) { assert(reply != NULL && reply->type == REDIS_REPLY_STATUS && strcmp(reply->str, "PONG") == 0); t->pongs++; redisAsyncFree(ac); } if (t->testno == ASTEST_PINGPONG_TIMEOUT) { /* two ping pongs */ assert(reply != NULL && reply->type == REDIS_REPLY_STATUS && strcmp(reply->str, "PONG") == 0); t->pongs++; if (t->counter == 1) { int status = redisAsyncCommand(ac, commandCallback, NULL, "PING"); assert(status == REDIS_OK); } else { redisAsyncFree(ac); } } } static redisAsyncContext *do_aconnect(struct config config, astest_no testno) { redisOptions options = {0}; memset(&astest, 0, sizeof(astest)); astest.testno = testno; astest.connect_status = astest.disconnect_status = -2; if (config.type == CONN_TCP) { options.type = REDIS_CONN_TCP; options.connect_timeout = &config.tcp.timeout; REDIS_OPTIONS_SET_TCP(&options, config.tcp.host, config.tcp.port); } else if (config.type == CONN_SSL) { options.type = REDIS_CONN_TCP; options.connect_timeout = &config.tcp.timeout; REDIS_OPTIONS_SET_TCP(&options, config.ssl.host, config.ssl.port); } else if (config.type == CONN_UNIX) { options.type = REDIS_CONN_UNIX; options.endpoint.unix_socket = config.unix_sock.path; } else if (config.type == CONN_FD) { options.type = REDIS_CONN_USERFD; /* Create a dummy connection just to get an fd to inherit */ redisContext *dummy_ctx = redisConnectUnix(config.unix_sock.path); if (dummy_ctx) { redisFD fd = disconnect(dummy_ctx, 1); printf("Connecting to inherited fd %d\n", (int)fd); options.endpoint.fd = fd; } } redisAsyncContext *c = redisAsyncConnectWithOptions(&options); assert(c); astest.ac = c; c->data = &astest; c->dataCleanup = asCleanup; redisPollAttach(c); redisAsyncSetConnectCallbackNC(c, connectCallback); redisAsyncSetDisconnectCallback(c, disconnectCallback); return c; } static void as_printerr(void) { printf("Async err %d : %s\n", astest.err, astest.errstr); } #define ASASSERT(e) do { \ if (!(e)) \ as_printerr(); \ assert(e); \ } while (0); static void test_async_polling(struct config config) { int status; redisAsyncContext *c; struct config defaultconfig = config; test("Async connect: "); c = do_aconnect(config, ASTEST_CONNECT); assert(c); while(astest.connected == 0) redisPollTick(c, 0.1); assert(astest.connects == 1); ASASSERT(astest.connect_status == REDIS_OK); assert(astest.disconnects == 0); test_cond(astest.connected == 1); test("Async free after connect: "); assert(astest.ac != NULL); redisAsyncFree(c); assert(astest.disconnects == 1); assert(astest.ac == NULL); test_cond(astest.disconnect_status == REDIS_OK); if (config.type == CONN_TCP || config.type == CONN_SSL) { /* timeout can only be simulated with network */ test("Async connect timeout: "); config.tcp.host = "192.168.254.254"; /* blackhole ip */ config.tcp.timeout.tv_usec = 100000; c = do_aconnect(config, ASTEST_CONN_TIMEOUT); assert(c); assert(c->err == 0); while(astest.connected == 0) redisPollTick(c, 0.1); assert(astest.connected == -1); /* * freeing should not be done, clearing should have happened. *redisAsyncFree(c); */ assert(astest.ac == NULL); test_cond(astest.connect_status == REDIS_ERR); config = defaultconfig; } /* Test a ping/pong after connection */ test("Async PING/PONG: "); c = do_aconnect(config, ASTEST_PINGPONG); while(astest.connected == 0) redisPollTick(c, 0.1); status = redisAsyncCommand(c, commandCallback, NULL, "PING"); assert(status == REDIS_OK); while(astest.ac) redisPollTick(c, 0.1); test_cond(astest.pongs == 1); /* Test a ping/pong after connection that didn't time out. * see https://github.com/redis/hiredis/issues/945 */ if (config.type == CONN_TCP || config.type == CONN_SSL) { test("Async PING/PONG after connect timeout: "); config.tcp.timeout.tv_usec = 10000; /* 10ms */ c = do_aconnect(config, ASTEST_PINGPONG_TIMEOUT); while(astest.connected == 0) redisPollTick(c, 0.1); /* sleep 0.1 s, allowing old timeout to arrive */ millisleep(10); status = redisAsyncCommand(c, commandCallback, NULL, "PING"); assert(status == REDIS_OK); while(astest.ac) redisPollTick(c, 0.1); test_cond(astest.pongs == 2); config = defaultconfig; } /* Test disconnect from an on_connect callback * see https://github.com/redis/hiredis/issues/931 */ test("Disconnect from onConnected callback (Issue #931): "); c = do_aconnect(config, ASTEST_ISSUE_931); while(astest.disconnects == 0) redisPollTick(c, 0.1); assert(astest.connected == 0); assert(astest.connects == 1); test_cond(astest.disconnects == 1); /* Test ping/pong from an on_connect callback * see https://github.com/redis/hiredis/issues/931 */ test("Ping/Pong from onConnected callback (Issue #931): "); c = do_aconnect(config, ASTEST_ISSUE_931_PING); /* connect callback issues ping, reponse callback destroys context */ while(astest.ac) redisPollTick(c, 0.1); assert(astest.connected == 0); assert(astest.connects == 1); assert(astest.disconnects == 1); test_cond(astest.pongs == 1); } /* End of Async polling_adapter driven tests */ int main(int argc, char **argv) { struct config cfg = { .tcp = { .host = "127.0.0.1", .port = 6379 }, .unix_sock = { .path = "/tmp/redis.sock" } }; int throughput = 1; int test_inherit_fd = 1; int skips_as_fails = 0; int test_unix_socket; /* Parse command line options. */ argv++; argc--; while (argc) { if (argc >= 2 && !strcmp(argv[0],"-h")) { argv++; argc--; cfg.tcp.host = argv[0]; } else if (argc >= 2 && !strcmp(argv[0],"-p")) { argv++; argc--; cfg.tcp.port = atoi(argv[0]); } else if (argc >= 2 && !strcmp(argv[0],"-s")) { argv++; argc--; cfg.unix_sock.path = argv[0]; } else if (argc >= 1 && !strcmp(argv[0],"--skip-throughput")) { throughput = 0; } else if (argc >= 1 && !strcmp(argv[0],"--skip-inherit-fd")) { test_inherit_fd = 0; } else if (argc >= 1 && !strcmp(argv[0],"--skips-as-fails")) { skips_as_fails = 1; #ifdef HIREDIS_TEST_SSL } else if (argc >= 2 && !strcmp(argv[0],"--ssl-port")) { argv++; argc--; cfg.ssl.port = atoi(argv[0]); } else if (argc >= 2 && !strcmp(argv[0],"--ssl-host")) { argv++; argc--; cfg.ssl.host = argv[0]; } else if (argc >= 2 && !strcmp(argv[0],"--ssl-ca-cert")) { argv++; argc--; cfg.ssl.ca_cert = argv[0]; } else if (argc >= 2 && !strcmp(argv[0],"--ssl-cert")) { argv++; argc--; cfg.ssl.cert = argv[0]; } else if (argc >= 2 && !strcmp(argv[0],"--ssl-key")) { argv++; argc--; cfg.ssl.key = argv[0]; #endif } else { fprintf(stderr, "Invalid argument: %s\n", argv[0]); exit(1); } argv++; argc--; } #ifndef _WIN32 /* Ignore broken pipe signal (for I/O error tests). */ signal(SIGPIPE, SIG_IGN); test_unix_socket = access(cfg.unix_sock.path, F_OK) == 0; #else /* Unix sockets don't exist in Windows */ test_unix_socket = 0; #endif test_allocator_injection(); test_format_commands(); test_reply_reader(); test_blocking_connection_errors(); test_free_null(); printf("\nTesting against TCP connection (%s:%d):\n", cfg.tcp.host, cfg.tcp.port); cfg.type = CONN_TCP; test_blocking_connection(cfg); test_blocking_connection_timeouts(cfg); test_blocking_io_errors(cfg); test_invalid_timeout_errors(cfg); test_append_formatted_commands(cfg); if (throughput) test_throughput(cfg); printf("\nTesting against Unix socket connection (%s): ", cfg.unix_sock.path); if (test_unix_socket) { printf("\n"); cfg.type = CONN_UNIX; test_blocking_connection(cfg); test_blocking_connection_timeouts(cfg); test_blocking_io_errors(cfg); if (throughput) test_throughput(cfg); } else { test_skipped(); } #ifdef HIREDIS_TEST_SSL if (cfg.ssl.port && cfg.ssl.host) { redisInitOpenSSL(); _ssl_ctx = redisCreateSSLContext(cfg.ssl.ca_cert, NULL, cfg.ssl.cert, cfg.ssl.key, NULL, NULL); assert(_ssl_ctx != NULL); printf("\nTesting against SSL connection (%s:%d):\n", cfg.ssl.host, cfg.ssl.port); cfg.type = CONN_SSL; test_blocking_connection(cfg); test_blocking_connection_timeouts(cfg); test_blocking_io_errors(cfg); test_invalid_timeout_errors(cfg); test_append_formatted_commands(cfg); if (throughput) test_throughput(cfg); redisFreeSSLContext(_ssl_ctx); _ssl_ctx = NULL; } #endif #ifdef HIREDIS_TEST_ASYNC cfg.type = CONN_TCP; printf("\nTesting asynchronous API against TCP connection (%s:%d):\n", cfg.tcp.host, cfg.tcp.port); cfg.type = CONN_TCP; int major; redisContext *c = do_connect(cfg); get_redis_version(c, &major, NULL); disconnect(c, 0); test_pubsub_handling(cfg); test_pubsub_multiple_channels(cfg); test_monitor(cfg); if (major >= 6) { test_pubsub_handling_resp3(cfg); test_command_timeout_during_pubsub(cfg); } #endif /* HIREDIS_TEST_ASYNC */ cfg.type = CONN_TCP; printf("\nTesting asynchronous API using polling_adapter TCP (%s:%d):\n", cfg.tcp.host, cfg.tcp.port); test_async_polling(cfg); if (test_unix_socket) { cfg.type = CONN_UNIX; printf("\nTesting asynchronous API using polling_adapter UNIX (%s):\n", cfg.unix_sock.path); test_async_polling(cfg); } if (test_inherit_fd) { printf("\nTesting against inherited fd (%s): ", cfg.unix_sock.path); if (test_unix_socket) { printf("\n"); cfg.type = CONN_FD; test_blocking_connection(cfg); } else { test_skipped(); } } if (fails || (skips_as_fails && skips)) { printf("*** %d TESTS FAILED ***\n", fails); if (skips) { printf("*** %d TESTS SKIPPED ***\n", skips); } return 1; } printf("ALL TESTS PASSED (%d skipped)\n", skips); return 0; }