/* This module is used to test a use case of a module that stores information * about keys in global memory, and relies on the enhanced data type callbacks to * get key name and dbid on various operations. * * it simulates a simple memory allocator. The smallest allocation unit of * the allocator is a mem block with a size of 4KB. Multiple mem blocks are combined * using a linked list. These linked lists are placed in a global dict named 'mem_pool'. * Each db has a 'mem_pool'. You can use the 'mem.alloc' command to allocate a specified * number of mem blocks, and use 'mem.free' to release the memory. Use 'mem.write', 'mem.read' * to write and read the specified mem block (note that each mem block can only be written once). * Use 'mem.usage' to get the memory usage under different dbs, and it will return the size * mem blocks and used mem blocks under the db. * The specific structure diagram is as follows: * * * Global variables of the module: * * mem blocks link * ┌─────┬─────┐ * │ │ │ ┌───┐ ┌───┐ ┌───┐ * │ k1 │ ───┼───►│4KB├───►│4KB├───►│4KB│ * │ │ │ └───┘ └───┘ └───┘ * ├─────┼─────┤ * ┌───────┐ ┌────► │ │ │ ┌───┐ ┌───┐ * │ │ │ │ k2 │ ───┼───►│4KB├───►│4KB│ * │ db0 ├──────┘ │ │ │ └───┘ └───┘ * │ │ ├─────┼─────┤ * ├───────┤ │ │ │ ┌───┐ ┌───┐ ┌───┐ * │ │ │ k3 │ ───┼───►│4KB├───►│4KB├───►│4KB│ * │ db1 ├──►null │ │ │ └───┘ └───┘ └───┘ * │ │ └─────┴─────┘ * ├───────┤ dict * │ │ * │ db2 ├─────────┐ * │ │ │ * ├───────┤ │ ┌─────┬─────┐ * │ │ │ │ │ │ ┌───┐ ┌───┐ ┌───┐ * │ db3 ├──►null │ │ k1 │ ───┼───►│4KB├───►│4KB├───►│4KB│ * │ │ │ │ │ │ └───┘ └───┘ └───┘ * └───────┘ │ ├─────┼─────┤ * mem_pool[MAX_DB] │ │ │ │ ┌───┐ ┌───┐ * └──►│ k2 │ ───┼───►│4KB├───►│4KB│ * │ │ │ └───┘ └───┘ * └─────┴─────┘ * dict * * * Keys in redis database: * * ┌───────┐ * │ size │ * ┌───────────►│ used │ * │ │ mask │ * ┌─────┬─────┐ │ └───────┘ ┌───────┐ * │ │ │ │ MemAllocObject │ size │ * │ k1 │ ───┼─┘ ┌───────────►│ used │ * │ │ │ │ │ mask │ * ├─────┼─────┤ ┌───────┐ ┌─────┬─────┐ │ └───────┘ * │ │ │ │ size │ │ │ │ │ MemAllocObject * │ k2 │ ───┼─────────────►│ used │ │ k1 │ ───┼─┘ * │ │ │ │ mask │ │ │ │ * ├─────┼─────┤ └───────┘ ├─────┼─────┤ * │ │ │ MemAllocObject │ │ │ * │ k3 │ ───┼─┐ │ k2 │ ───┼─┐ * │ │ │ │ │ │ │ │ * └─────┴─────┘ │ ┌───────┐ └─────┴─────┘ │ ┌───────┐ * redis db[0] │ │ size │ redis db[1] │ │ size │ * └───────────►│ used │ └───────────►│ used │ * │ mask │ │ mask │ * └───────┘ └───────┘ * MemAllocObject MemAllocObject * **/ #include "redismodule.h" #include #include #include #include #include static RedisModuleType *MemAllocType; #define MAX_DB 16 RedisModuleDict *mem_pool[MAX_DB]; typedef struct MemAllocObject { long long size; long long used; uint64_t mask; } MemAllocObject; MemAllocObject *createMemAllocObject(void) { MemAllocObject *o = RedisModule_Calloc(1, sizeof(*o)); return o; } /*---------------------------- mem block apis ------------------------------------*/ #define BLOCK_SIZE 4096 struct MemBlock { char block[BLOCK_SIZE]; struct MemBlock *next; }; void MemBlockFree(struct MemBlock *head) { if (head) { struct MemBlock *block = head->next, *next; RedisModule_Free(head); while (block) { next = block->next; RedisModule_Free(block); block = next; } } } struct MemBlock *MemBlockCreate(long long num) { if (num <= 0) { return NULL; } struct MemBlock *head = RedisModule_Calloc(1, sizeof(struct MemBlock)); struct MemBlock *block = head; while (--num) { block->next = RedisModule_Calloc(1, sizeof(struct MemBlock)); block = block->next; } return head; } long long MemBlockNum(const struct MemBlock *head) { long long num = 0; const struct MemBlock *block = head; while (block) { num++; block = block->next; } return num; } size_t MemBlockWrite(struct MemBlock *head, long long block_index, const char *data, size_t size) { size_t w_size = 0; struct MemBlock *block = head; while (block_index-- && block) { block = block->next; } if (block) { size = size > BLOCK_SIZE ? BLOCK_SIZE:size; memcpy(block->block, data, size); w_size += size; } return w_size; } int MemBlockRead(struct MemBlock *head, long long block_index, char *data, size_t size) { size_t r_size = 0; struct MemBlock *block = head; while (block_index-- && block) { block = block->next; } if (block) { size = size > BLOCK_SIZE ? BLOCK_SIZE:size; memcpy(data, block->block, size); r_size += size; } return r_size; } void MemPoolFreeDb(RedisModuleCtx *ctx, int dbid) { RedisModuleString *key; void *tdata; RedisModuleDictIter *iter = RedisModule_DictIteratorStartC(mem_pool[dbid], "^", NULL, 0); while((key = RedisModule_DictNext(ctx, iter, &tdata)) != NULL) { MemBlockFree((struct MemBlock *)tdata); } RedisModule_DictIteratorStop(iter); RedisModule_FreeDict(NULL, mem_pool[dbid]); mem_pool[dbid] = RedisModule_CreateDict(NULL); } struct MemBlock *MemBlockClone(const struct MemBlock *head) { struct MemBlock *newhead = NULL; if (head) { newhead = RedisModule_Calloc(1, sizeof(struct MemBlock)); memcpy(newhead->block, head->block, BLOCK_SIZE); struct MemBlock *newblock = newhead; const struct MemBlock *oldblock = head->next; while (oldblock) { newblock->next = RedisModule_Calloc(1, sizeof(struct MemBlock)); newblock = newblock->next; memcpy(newblock->block, oldblock->block, BLOCK_SIZE); oldblock = oldblock->next; } } return newhead; } /*---------------------------- event handler ------------------------------------*/ void swapDbCallback(RedisModuleCtx *ctx, RedisModuleEvent e, uint64_t sub, void *data) { REDISMODULE_NOT_USED(ctx); REDISMODULE_NOT_USED(e); REDISMODULE_NOT_USED(sub); RedisModuleSwapDbInfo *ei = data; // swap RedisModuleDict *tmp = mem_pool[ei->dbnum_first]; mem_pool[ei->dbnum_first] = mem_pool[ei->dbnum_second]; mem_pool[ei->dbnum_second] = tmp; } void flushdbCallback(RedisModuleCtx *ctx, RedisModuleEvent e, uint64_t sub, void *data) { REDISMODULE_NOT_USED(ctx); REDISMODULE_NOT_USED(e); int i; RedisModuleFlushInfo *fi = data; RedisModule_AutoMemory(ctx); if (sub == REDISMODULE_SUBEVENT_FLUSHDB_START) { if (fi->dbnum != -1) { MemPoolFreeDb(ctx, fi->dbnum); } else { for (i = 0; i < MAX_DB; i++) { MemPoolFreeDb(ctx, i); } } } } /*---------------------------- command implementation ------------------------------------*/ /* MEM.ALLOC key block_num */ int MemAlloc_RedisCommand(RedisModuleCtx *ctx, RedisModuleString **argv, int argc) { RedisModule_AutoMemory(ctx); if (argc != 3) { return RedisModule_WrongArity(ctx); } long long block_num; if ((RedisModule_StringToLongLong(argv[2], &block_num) != REDISMODULE_OK) || block_num <= 0) { return RedisModule_ReplyWithError(ctx, "ERR invalid block_num: must be a value greater than 0"); } RedisModuleKey *key = RedisModule_OpenKey(ctx, argv[1], REDISMODULE_READ | REDISMODULE_WRITE); int type = RedisModule_KeyType(key); if (type != REDISMODULE_KEYTYPE_EMPTY && RedisModule_ModuleTypeGetType(key) != MemAllocType) { return RedisModule_ReplyWithError(ctx, REDISMODULE_ERRORMSG_WRONGTYPE); } MemAllocObject *o; if (type == REDISMODULE_KEYTYPE_EMPTY) { o = createMemAllocObject(); RedisModule_ModuleTypeSetValue(key, MemAllocType, o); } else { o = RedisModule_ModuleTypeGetValue(key); } struct MemBlock *mem = MemBlockCreate(block_num); RedisModule_Assert(mem != NULL); RedisModule_DictSet(mem_pool[RedisModule_GetSelectedDb(ctx)], argv[1], mem); o->size = block_num; o->used = 0; o->mask = 0; RedisModule_ReplyWithLongLong(ctx, block_num); RedisModule_ReplicateVerbatim(ctx); return REDISMODULE_OK; } /* MEM.FREE key */ int MemFree_RedisCommand(RedisModuleCtx *ctx, RedisModuleString **argv, int argc) { RedisModule_AutoMemory(ctx); if (argc != 2) { return RedisModule_WrongArity(ctx); } RedisModuleKey *key = RedisModule_OpenKey(ctx, argv[1], REDISMODULE_READ); int type = RedisModule_KeyType(key); if (type != REDISMODULE_KEYTYPE_EMPTY && RedisModule_ModuleTypeGetType(key) != MemAllocType) { return RedisModule_ReplyWithError(ctx, REDISMODULE_ERRORMSG_WRONGTYPE); } int ret = 0; MemAllocObject *o; if (type == REDISMODULE_KEYTYPE_EMPTY) { RedisModule_ReplyWithLongLong(ctx, ret); return REDISMODULE_OK; } else { o = RedisModule_ModuleTypeGetValue(key); } int nokey; struct MemBlock *mem = (struct MemBlock *)RedisModule_DictGet(mem_pool[RedisModule_GetSelectedDb(ctx)], argv[1], &nokey); if (!nokey && mem) { RedisModule_DictDel(mem_pool[RedisModule_GetSelectedDb(ctx)], argv[1], NULL); MemBlockFree(mem); o->used = 0; o->size = 0; o->mask = 0; ret = 1; } RedisModule_ReplyWithLongLong(ctx, ret); RedisModule_ReplicateVerbatim(ctx); return REDISMODULE_OK; } /* MEM.WRITE key block_index data */ int MemWrite_RedisCommand(RedisModuleCtx *ctx, RedisModuleString **argv, int argc) { RedisModule_AutoMemory(ctx); if (argc != 4) { return RedisModule_WrongArity(ctx); } long long block_index; if ((RedisModule_StringToLongLong(argv[2], &block_index) != REDISMODULE_OK) || block_index < 0) { return RedisModule_ReplyWithError(ctx, "ERR invalid block_index: must be a value greater than 0"); } RedisModuleKey *key = RedisModule_OpenKey(ctx, argv[1], REDISMODULE_READ | REDISMODULE_WRITE); int type = RedisModule_KeyType(key); if (type != REDISMODULE_KEYTYPE_EMPTY && RedisModule_ModuleTypeGetType(key) != MemAllocType) { return RedisModule_ReplyWithError(ctx, REDISMODULE_ERRORMSG_WRONGTYPE); } MemAllocObject *o; if (type == REDISMODULE_KEYTYPE_EMPTY) { return RedisModule_ReplyWithError(ctx, "ERR Memory has not been allocated"); } else { o = RedisModule_ModuleTypeGetValue(key); } if (o->mask & (1UL << block_index)) { return RedisModule_ReplyWithError(ctx, "ERR block is busy"); } int ret = 0; int nokey; struct MemBlock *mem = (struct MemBlock *)RedisModule_DictGet(mem_pool[RedisModule_GetSelectedDb(ctx)], argv[1], &nokey); if (!nokey && mem) { size_t len; const char *buf = RedisModule_StringPtrLen(argv[3], &len); ret = MemBlockWrite(mem, block_index, buf, len); o->mask |= (1UL << block_index); o->used++; } RedisModule_ReplyWithLongLong(ctx, ret); RedisModule_ReplicateVerbatim(ctx); return REDISMODULE_OK; } /* MEM.READ key block_index */ int MemRead_RedisCommand(RedisModuleCtx *ctx, RedisModuleString **argv, int argc) { RedisModule_AutoMemory(ctx); if (argc != 3) { return RedisModule_WrongArity(ctx); } long long block_index; if ((RedisModule_StringToLongLong(argv[2], &block_index) != REDISMODULE_OK) || block_index < 0) { return RedisModule_ReplyWithError(ctx, "ERR invalid block_index: must be a value greater than 0"); } RedisModuleKey *key = RedisModule_OpenKey(ctx, argv[1], REDISMODULE_READ); int type = RedisModule_KeyType(key); if (type != REDISMODULE_KEYTYPE_EMPTY && RedisModule_ModuleTypeGetType(key) != MemAllocType) { return RedisModule_ReplyWithError(ctx, REDISMODULE_ERRORMSG_WRONGTYPE); } MemAllocObject *o; if (type == REDISMODULE_KEYTYPE_EMPTY) { return RedisModule_ReplyWithError(ctx, "ERR Memory has not been allocated"); } else { o = RedisModule_ModuleTypeGetValue(key); } if (!(o->mask & (1UL << block_index))) { return RedisModule_ReplyWithNull(ctx); } int nokey; struct MemBlock *mem = (struct MemBlock *)RedisModule_DictGet(mem_pool[RedisModule_GetSelectedDb(ctx)], argv[1], &nokey); RedisModule_Assert(nokey == 0 && mem != NULL); char buf[BLOCK_SIZE]; MemBlockRead(mem, block_index, buf, sizeof(buf)); /* Assuming that the contents are all c-style strings */ RedisModule_ReplyWithStringBuffer(ctx, buf, strlen(buf)); return REDISMODULE_OK; } /* MEM.USAGE dbid */ int MemUsage_RedisCommand(RedisModuleCtx *ctx, RedisModuleString **argv, int argc) { RedisModule_AutoMemory(ctx); if (argc != 2) { return RedisModule_WrongArity(ctx); } long long dbid; if ((RedisModule_StringToLongLong(argv[1], (long long *)&dbid) != REDISMODULE_OK)) { return RedisModule_ReplyWithError(ctx, "ERR invalid value: must be a integer"); } if (dbid < 0 || dbid >= MAX_DB) { return RedisModule_ReplyWithError(ctx, "ERR dbid out of range"); } long long size = 0, used = 0; void *data; RedisModuleString *key; RedisModuleDictIter *iter = RedisModule_DictIteratorStartC(mem_pool[dbid], "^", NULL, 0); while((key = RedisModule_DictNext(ctx, iter, &data)) != NULL) { int dbbackup = RedisModule_GetSelectedDb(ctx); RedisModule_SelectDb(ctx, dbid); RedisModuleKey *openkey = RedisModule_OpenKey(ctx, key, REDISMODULE_READ); int type = RedisModule_KeyType(openkey); RedisModule_Assert(type != REDISMODULE_KEYTYPE_EMPTY && RedisModule_ModuleTypeGetType(openkey) == MemAllocType); MemAllocObject *o = RedisModule_ModuleTypeGetValue(openkey); used += o->used; size += o->size; RedisModule_CloseKey(openkey); RedisModule_SelectDb(ctx, dbbackup); } RedisModule_DictIteratorStop(iter); RedisModule_ReplyWithArray(ctx, 4); RedisModule_ReplyWithSimpleString(ctx, "total"); RedisModule_ReplyWithLongLong(ctx, size); RedisModule_ReplyWithSimpleString(ctx, "used"); RedisModule_ReplyWithLongLong(ctx, used); return REDISMODULE_OK; } /* MEM.ALLOCANDWRITE key block_num block_index data block_index data ... */ int MemAllocAndWrite_RedisCommand(RedisModuleCtx *ctx, RedisModuleString **argv, int argc) { RedisModule_AutoMemory(ctx); if (argc < 3) { return RedisModule_WrongArity(ctx); } long long block_num; if ((RedisModule_StringToLongLong(argv[2], &block_num) != REDISMODULE_OK) || block_num <= 0) { return RedisModule_ReplyWithError(ctx, "ERR invalid block_num: must be a value greater than 0"); } RedisModuleKey *key = RedisModule_OpenKey(ctx, argv[1], REDISMODULE_READ | REDISMODULE_WRITE); int type = RedisModule_KeyType(key); if (type != REDISMODULE_KEYTYPE_EMPTY && RedisModule_ModuleTypeGetType(key) != MemAllocType) { return RedisModule_ReplyWithError(ctx, REDISMODULE_ERRORMSG_WRONGTYPE); } MemAllocObject *o; if (type == REDISMODULE_KEYTYPE_EMPTY) { o = createMemAllocObject(); RedisModule_ModuleTypeSetValue(key, MemAllocType, o); } else { o = RedisModule_ModuleTypeGetValue(key); } struct MemBlock *mem = MemBlockCreate(block_num); RedisModule_Assert(mem != NULL); RedisModule_DictSet(mem_pool[RedisModule_GetSelectedDb(ctx)], argv[1], mem); o->used = 0; o->mask = 0; o->size = block_num; int i = 3; long long block_index; for (; i < argc; i++) { /* Security is guaranteed internally, so no security check. */ RedisModule_StringToLongLong(argv[i], &block_index); size_t len; const char * buf = RedisModule_StringPtrLen(argv[i + 1], &len); MemBlockWrite(mem, block_index, buf, len); o->used++; o->mask |= (1UL << block_index); } RedisModule_ReplyWithSimpleString(ctx, "OK"); RedisModule_ReplicateVerbatim(ctx); return REDISMODULE_OK; } /*---------------------------- type callbacks ------------------------------------*/ void *MemAllocRdbLoad(RedisModuleIO *rdb, int encver) { if (encver != 0) { return NULL; } MemAllocObject *o = createMemAllocObject(); o->size = RedisModule_LoadSigned(rdb); o->used = RedisModule_LoadSigned(rdb); o->mask = RedisModule_LoadUnsigned(rdb); const RedisModuleString *key = RedisModule_GetKeyNameFromIO(rdb); int dbid = RedisModule_GetDbIdFromIO(rdb); if (o->size) { size_t size; char *tmpbuf; long long num = o->size; struct MemBlock *head = RedisModule_Calloc(1, sizeof(struct MemBlock)); tmpbuf = RedisModule_LoadStringBuffer(rdb, &size); memcpy(head->block, tmpbuf, size > BLOCK_SIZE ? BLOCK_SIZE:size); RedisModule_Free(tmpbuf); struct MemBlock *block = head; while (--num) { block->next = RedisModule_Calloc(1, sizeof(struct MemBlock)); block = block->next; tmpbuf = RedisModule_LoadStringBuffer(rdb, &size); memcpy(block->block, tmpbuf, size > BLOCK_SIZE ? BLOCK_SIZE:size); RedisModule_Free(tmpbuf); } RedisModule_DictSet(mem_pool[dbid], (RedisModuleString *)key, head); } return o; } void MemAllocRdbSave(RedisModuleIO *rdb, void *value) { MemAllocObject *o = value; RedisModule_SaveSigned(rdb, o->size); RedisModule_SaveSigned(rdb, o->used); RedisModule_SaveUnsigned(rdb, o->mask); const RedisModuleString *key = RedisModule_GetKeyNameFromIO(rdb); int dbid = RedisModule_GetDbIdFromIO(rdb); if (o->size) { int nokey; struct MemBlock *mem = (struct MemBlock *)RedisModule_DictGet(mem_pool[dbid], (RedisModuleString *)key, &nokey); RedisModule_Assert(nokey == 0 && mem != NULL); struct MemBlock *block = mem; while (block) { RedisModule_SaveStringBuffer(rdb, block->block, BLOCK_SIZE); block = block->next; } } } void MemAllocAofRewrite(RedisModuleIO *aof, RedisModuleString *key, void *value) { MemAllocObject *o = (MemAllocObject *)value; if (o->size) { int dbid = RedisModule_GetDbIdFromIO(aof); int nokey; size_t i = 0, j = 0; struct MemBlock *mem = (struct MemBlock *)RedisModule_DictGet(mem_pool[dbid], (RedisModuleString *)key, &nokey); RedisModule_Assert(nokey == 0 && mem != NULL); size_t array_size = o->size * 2; RedisModuleString ** string_array = RedisModule_Calloc(array_size, sizeof(RedisModuleString *)); while (mem) { string_array[i] = RedisModule_CreateStringFromLongLong(NULL, j); string_array[i + 1] = RedisModule_CreateString(NULL, mem->block, BLOCK_SIZE); mem = mem->next; i += 2; j++; } RedisModule_EmitAOF(aof, "mem.allocandwrite", "slv", key, o->size, string_array, array_size); for (i = 0; i < array_size; i++) { RedisModule_FreeString(NULL, string_array[i]); } RedisModule_Free(string_array); } else { RedisModule_EmitAOF(aof, "mem.allocandwrite", "sl", key, o->size); } } void MemAllocFree(void *value) { RedisModule_Free(value); } void MemAllocUnlink(RedisModuleString *key, const void *value) { REDISMODULE_NOT_USED(key); REDISMODULE_NOT_USED(value); /* When unlink and unlink2 exist at the same time, we will only call unlink2. */ RedisModule_Assert(0); } void MemAllocUnlink2(RedisModuleKeyOptCtx *ctx, const void *value) { MemAllocObject *o = (MemAllocObject *)value; const RedisModuleString *key = RedisModule_GetKeyNameFromOptCtx(ctx); int dbid = RedisModule_GetDbIdFromOptCtx(ctx); if (o->size) { void *oldval; RedisModule_DictDel(mem_pool[dbid], (RedisModuleString *)key, &oldval); RedisModule_Assert(oldval != NULL); MemBlockFree((struct MemBlock *)oldval); } } void MemAllocDigest(RedisModuleDigest *md, void *value) { MemAllocObject *o = (MemAllocObject *)value; RedisModule_DigestAddLongLong(md, o->size); RedisModule_DigestAddLongLong(md, o->used); RedisModule_DigestAddLongLong(md, o->mask); int dbid = RedisModule_GetDbIdFromDigest(md); const RedisModuleString *key = RedisModule_GetKeyNameFromDigest(md); if (o->size) { int nokey; struct MemBlock *mem = (struct MemBlock *)RedisModule_DictGet(mem_pool[dbid], (RedisModuleString *)key, &nokey); RedisModule_Assert(nokey == 0 && mem != NULL); struct MemBlock *block = mem; while (block) { RedisModule_DigestAddStringBuffer(md, (unsigned char *)block->block, BLOCK_SIZE); block = block->next; } } } void *MemAllocCopy2(RedisModuleKeyOptCtx *ctx, const void *value) { const MemAllocObject *old = value; MemAllocObject *new = createMemAllocObject(); new->size = old->size; new->used = old->used; new->mask = old->mask; int from_dbid = RedisModule_GetDbIdFromOptCtx(ctx); int to_dbid = RedisModule_GetToDbIdFromOptCtx(ctx); const RedisModuleString *fromkey = RedisModule_GetKeyNameFromOptCtx(ctx); const RedisModuleString *tokey = RedisModule_GetToKeyNameFromOptCtx(ctx); if (old->size) { int nokey; struct MemBlock *oldmem = (struct MemBlock *)RedisModule_DictGet(mem_pool[from_dbid], (RedisModuleString *)fromkey, &nokey); RedisModule_Assert(nokey == 0 && oldmem != NULL); struct MemBlock *newmem = MemBlockClone(oldmem); RedisModule_Assert(newmem != NULL); RedisModule_DictSet(mem_pool[to_dbid], (RedisModuleString *)tokey, newmem); } return new; } size_t MemAllocMemUsage2(RedisModuleKeyOptCtx *ctx, const void *value) { REDISMODULE_NOT_USED(ctx); uint64_t size = 0; MemAllocObject *o = (MemAllocObject *)value; size += sizeof(*o); size += o->size * sizeof(struct MemBlock); return size; } size_t MemAllocMemFreeEffort2(RedisModuleKeyOptCtx *ctx, const void *value) { REDISMODULE_NOT_USED(ctx); MemAllocObject *o = (MemAllocObject *)value; return o->size; } int RedisModule_OnLoad(RedisModuleCtx *ctx, RedisModuleString **argv, int argc) { REDISMODULE_NOT_USED(argv); REDISMODULE_NOT_USED(argc); if (RedisModule_Init(ctx, "datatype2", 1,REDISMODULE_APIVER_1) == REDISMODULE_ERR) { return REDISMODULE_ERR; } RedisModuleTypeMethods tm = { .version = REDISMODULE_TYPE_METHOD_VERSION, .rdb_load = MemAllocRdbLoad, .rdb_save = MemAllocRdbSave, .aof_rewrite = MemAllocAofRewrite, .free = MemAllocFree, .digest = MemAllocDigest, .unlink = MemAllocUnlink, // .defrag = MemAllocDefrag, // Tested in defragtest.c .unlink2 = MemAllocUnlink2, .copy2 = MemAllocCopy2, .mem_usage2 = MemAllocMemUsage2, .free_effort2 = MemAllocMemFreeEffort2, }; MemAllocType = RedisModule_CreateDataType(ctx, "mem_alloc", 0, &tm); if (MemAllocType == NULL) { return REDISMODULE_ERR; } if (RedisModule_CreateCommand(ctx, "mem.alloc", MemAlloc_RedisCommand, "write deny-oom", 1, 1, 1) == REDISMODULE_ERR) { return REDISMODULE_ERR; } if (RedisModule_CreateCommand(ctx, "mem.free", MemFree_RedisCommand, "write deny-oom", 1, 1, 1) == REDISMODULE_ERR) { return REDISMODULE_ERR; } if (RedisModule_CreateCommand(ctx, "mem.write", MemWrite_RedisCommand, "write deny-oom", 1, 1, 1) == REDISMODULE_ERR) { return REDISMODULE_ERR; } if (RedisModule_CreateCommand(ctx, "mem.read", MemRead_RedisCommand, "readonly", 1, 1, 1) == REDISMODULE_ERR) { return REDISMODULE_ERR; } if (RedisModule_CreateCommand(ctx, "mem.usage", MemUsage_RedisCommand, "readonly", 1, 1, 1) == REDISMODULE_ERR) { return REDISMODULE_ERR; } /* used for internal aof rewrite */ if (RedisModule_CreateCommand(ctx, "mem.allocandwrite", MemAllocAndWrite_RedisCommand, "write deny-oom", 1, 1, 1) == REDISMODULE_ERR) { return REDISMODULE_ERR; } for(int i = 0; i < MAX_DB; i++){ mem_pool[i] = RedisModule_CreateDict(NULL); } RedisModule_SubscribeToServerEvent(ctx, RedisModuleEvent_FlushDB, flushdbCallback); RedisModule_SubscribeToServerEvent(ctx, RedisModuleEvent_SwapDB, swapDbCallback); return REDISMODULE_OK; }