/************************************************************************* * Copyright (c) 2015-2021, NVIDIA CORPORATION. All rights reserved. * * See LICENSE.txt for license information ************************************************************************/ #ifndef NCCL_H_ #define NCCL_H_ #include #include #if CUDART_VERSION >= 11000 #include #endif #define NCCL_MAJOR 2 #define NCCL_MINOR 20 #define NCCL_PATCH 5 #define NCCL_SUFFIX "" #define NCCL_VERSION_CODE 22005 #define NCCL_VERSION(X,Y,Z) (((X) <= 2 && (Y) <= 8) ? (X) * 1000 + (Y) * 100 + (Z) : (X) * 10000 + (Y) * 100 + (Z)) #ifdef __cplusplus extern "C" { #endif #include /* Opaque handle to communicator */ typedef struct ncclComm* ncclComm_t; #define NCCL_COMM_NULL NULL #define NCCL_UNIQUE_ID_BYTES 128 typedef struct { char internal[NCCL_UNIQUE_ID_BYTES]; } ncclUniqueId; /* Error type */ typedef enum { ncclSuccess = 0, ncclUnhandledCudaError = 1, ncclSystemError = 2, ncclInternalError = 3, ncclInvalidArgument = 4, ncclInvalidUsage = 5, ncclRemoteError = 6, ncclInProgress = 7, ncclNumResults = 8 } ncclResult_t; #define NCCL_CONFIG_UNDEF_INT INT_MIN #define NCCL_CONFIG_UNDEF_PTR NULL #define NCCL_SPLIT_NOCOLOR -1 /* Communicator configuration. Users can assign value to attributes to specify the * behavior of a communicator. */ typedef struct ncclConfig_v21700 { /* attributes that users should never touch. */ size_t size; unsigned int magic; unsigned int version; /* attributes that users are able to customize. */ int blocking; int cgaClusterSize; int minCTAs; int maxCTAs; const char *netName; int splitShare; } ncclConfig_t; /* Config initializer must be assigned to initialize config structure when it is created. * Not initialized config will result in NCCL error. */ #define NCCL_CONFIG_INITIALIZER { \ sizeof(ncclConfig_t), /* size */ \ 0xcafebeef, /* magic */ \ NCCL_VERSION(NCCL_MAJOR, NCCL_MINOR, NCCL_PATCH), /* version */ \ NCCL_CONFIG_UNDEF_INT, /* blocking */ \ NCCL_CONFIG_UNDEF_INT, /* cgaClusterSize */ \ NCCL_CONFIG_UNDEF_INT, /* minCTAs */ \ NCCL_CONFIG_UNDEF_INT, /* maxCTAs */ \ NCCL_CONFIG_UNDEF_PTR, /* netName */ \ NCCL_CONFIG_UNDEF_INT /* splitShare */ \ } /* NCCL malloc and free function for all types of NCCL optimizations * (e.g. user buffer registration). The actual allocated size might * be larger than requested due to granularity requirement. */ ncclResult_t ncclMemAlloc(void** ptr, size_t size); ncclResult_t pncclMemAlloc(void** ptr, size_t size); ncclResult_t ncclMemFree(void *ptr); ncclResult_t pncclMemFree(void *ptr); /* Return the NCCL_VERSION_CODE of the NCCL library in the supplied integer. * This integer is coded with the MAJOR, MINOR and PATCH level of the * NCCL library */ ncclResult_t ncclGetVersion(int *version); ncclResult_t pncclGetVersion(int *version); /* Generates an Id to be used in ncclCommInitRank. ncclGetUniqueId should be * called once and the Id should be distributed to all ranks in the * communicator before calling ncclCommInitRank. */ ncclResult_t ncclGetUniqueId(ncclUniqueId* uniqueId); ncclResult_t pncclGetUniqueId(ncclUniqueId* uniqueId); /* Create a new communicator (multi thread/process version) with a configuration * set by users. */ ncclResult_t ncclCommInitRankConfig(ncclComm_t* comm, int nranks, ncclUniqueId commId, int rank, ncclConfig_t* config); ncclResult_t pncclCommInitRankConfig(ncclComm_t* comm, int nranks, ncclUniqueId commId, int rank, ncclConfig_t* config); /* Creates a new communicator (multi thread/process version). * rank must be between 0 and nranks-1 and unique within a communicator clique. * Each rank is associated to a CUDA device, which has to be set before calling * ncclCommInitRank. * ncclCommInitRank implicitly syncronizes with other ranks, so it must be * called by different threads/processes or use ncclGroupStart/ncclGroupEnd. */ ncclResult_t ncclCommInitRank(ncclComm_t* comm, int nranks, ncclUniqueId commId, int rank); ncclResult_t pncclCommInitRank(ncclComm_t* comm, int nranks, ncclUniqueId commId, int rank); /* Creates a clique of communicators (single process version). * This is a convenience function to create a single-process communicator clique. * Returns an array of ndev newly initialized communicators in comm. * comm should be pre-allocated with size at least ndev*sizeof(ncclComm_t). * If devlist is NULL, the first ndev CUDA devices are used. * Order of devlist defines user-order of processors within the communicator. */ ncclResult_t ncclCommInitAll(ncclComm_t* comm, int ndev, const int* devlist); ncclResult_t pncclCommInitAll(ncclComm_t* comm, int ndev, const int* devlist); /* Finalize a communicator. ncclCommFinalize flushes all issued communications, * and marks communicator state as ncclInProgress. The state will change to ncclSuccess * when the communicator is globally quiescent and related resources are freed; then, * calling ncclCommDestroy can locally free the rest of the resources (e.g. communicator * itself) without blocking. */ ncclResult_t ncclCommFinalize(ncclComm_t comm); ncclResult_t pncclCommFinalize(ncclComm_t comm); /* Frees local resources associated with communicator object. */ ncclResult_t ncclCommDestroy(ncclComm_t comm); ncclResult_t pncclCommDestroy(ncclComm_t comm); /* Frees resources associated with communicator object and aborts any operations * that might still be running on the device. */ ncclResult_t ncclCommAbort(ncclComm_t comm); ncclResult_t pncclCommAbort(ncclComm_t comm); /* Creates one or more communicators from an existing one. * Ranks with the same color will end up in the same communicator. * Within the new communicator, key will be used to order ranks. * NCCL_SPLIT_NOCOLOR as color will indicate the rank will not be part of any group * and will therefore return a NULL communicator. * If config is NULL, the new communicator will inherit the original communicator's * configuration*/ ncclResult_t ncclCommSplit(ncclComm_t comm, int color, int key, ncclComm_t *newcomm, ncclConfig_t* config); ncclResult_t pncclCommSplit(ncclComm_t comm, int color, int key, ncclComm_t *newcomm, ncclConfig_t* config); /* Returns a string for each error code. */ const char* ncclGetErrorString(ncclResult_t result); const char* pncclGetErrorString(ncclResult_t result); /* Returns a human-readable message of the last error that occurred. */ const char* ncclGetLastError(ncclComm_t comm); const char* pncclGetLastError(ncclComm_t comm); /* Checks whether the comm has encountered any asynchronous errors */ ncclResult_t ncclCommGetAsyncError(ncclComm_t comm, ncclResult_t *asyncError); ncclResult_t pncclCommGetAsyncError(ncclComm_t comm, ncclResult_t *asyncError); /* Gets the number of ranks in the communicator clique. */ ncclResult_t ncclCommCount(const ncclComm_t comm, int* count); ncclResult_t pncclCommCount(const ncclComm_t comm, int* count); /* Returns the cuda device number associated with the communicator. */ ncclResult_t ncclCommCuDevice(const ncclComm_t comm, int* device); ncclResult_t pncclCommCuDevice(const ncclComm_t comm, int* device); /* Returns the user-ordered "rank" associated with the communicator. */ ncclResult_t ncclCommUserRank(const ncclComm_t comm, int* rank); ncclResult_t pncclCommUserRank(const ncclComm_t comm, int* rank); /* Register CUDA buffer for zero-copy operation */ ncclResult_t ncclCommRegister(const ncclComm_t comm, void* buff, size_t size, void** handle); ncclResult_t pncclCommRegister(const ncclComm_t comm, void* buff, size_t size, void** handle); /* Deregister CUDA buffer */ ncclResult_t ncclCommDeregister(const ncclComm_t comm, void* handle); ncclResult_t pncclCommDeregister(const ncclComm_t comm, void* handle); /* Reduction operation selector */ typedef enum { ncclNumOps_dummy = 5 } ncclRedOp_dummy_t; typedef enum { ncclSum = 0, ncclProd = 1, ncclMax = 2, ncclMin = 3, ncclAvg = 4, /* ncclNumOps: The number of built-in ncclRedOp_t values. Also * serves as the least possible value for dynamic ncclRedOp_t's * as constructed by ncclRedOpCreate*** functions. */ ncclNumOps = 5, /* ncclMaxRedOp: The largest valid value for ncclRedOp_t. * It is defined to be the largest signed value (since compilers * are permitted to use signed enums) that won't grow * sizeof(ncclRedOp_t) when compared to previous NCCL versions to * maintain ABI compatibility. */ ncclMaxRedOp = 0x7fffffff>>(32-8*sizeof(ncclRedOp_dummy_t)) } ncclRedOp_t; /* Data types */ typedef enum { ncclInt8 = 0, ncclChar = 0, ncclUint8 = 1, ncclInt32 = 2, ncclInt = 2, ncclUint32 = 3, ncclInt64 = 4, ncclUint64 = 5, ncclFloat16 = 6, ncclHalf = 6, ncclFloat32 = 7, ncclFloat = 7, ncclFloat64 = 8, ncclDouble = 8, #if defined(__CUDA_BF16_TYPES_EXIST__) ncclBfloat16 = 9, ncclNumTypes = 10 #else ncclNumTypes = 9 #endif } ncclDataType_t; /* ncclScalarResidence_t: Location and dereferencing logic for scalar arguments. */ typedef enum { /* ncclScalarDevice: The scalar is in device-visible memory and will be * dereferenced while the collective is running. */ ncclScalarDevice = 0, /* ncclScalarHostImmediate: The scalar is in host-visible memory and will be * dereferenced before the ncclRedOpCreate***() function returns. */ ncclScalarHostImmediate = 1 } ncclScalarResidence_t; /* * ncclRedOpCreatePreMulSum * * Creates a new reduction operator which pre-multiplies input values by a given * scalar locally before reducing them with peer values via summation. For use * only with collectives launched against *comm* and *datatype*. The * *residence* argument indicates how/when the memory pointed to by *scalar* * will be dereferenced. Upon return, the newly created operator's handle * is stored in *op*. */ ncclResult_t ncclRedOpCreatePreMulSum(ncclRedOp_t *op, void *scalar, ncclDataType_t datatype, ncclScalarResidence_t residence, ncclComm_t comm); ncclResult_t pncclRedOpCreatePreMulSum(ncclRedOp_t *op, void *scalar, ncclDataType_t datatype, ncclScalarResidence_t residence, ncclComm_t comm); /* * ncclRedOpDestroy * * Destroys the reduction operator *op*. The operator must have been created by * ncclRedOpCreatePreMul with the matching communicator *comm*. An operator may be * destroyed as soon as the last NCCL function which is given that operator returns. */ ncclResult_t ncclRedOpDestroy(ncclRedOp_t op, ncclComm_t comm); ncclResult_t pncclRedOpDestroy(ncclRedOp_t op, ncclComm_t comm); /* * Collective communication operations * * Collective communication operations must be called separately for each * communicator in a communicator clique. * * They return when operations have been enqueued on the CUDA stream. * * Since they may perform inter-CPU synchronization, each call has to be done * from a different thread or process, or need to use Group Semantics (see * below). */ /* * Reduce * * Reduces data arrays of length count in sendbuff into recvbuff using op * operation. * recvbuff may be NULL on all calls except for root device. * root is the rank (not the CUDA device) where data will reside after the * operation is complete. * * In-place operation will happen if sendbuff == recvbuff. */ ncclResult_t ncclReduce(const void* sendbuff, void* recvbuff, size_t count, ncclDataType_t datatype, ncclRedOp_t op, int root, ncclComm_t comm, cudaStream_t stream); ncclResult_t pncclReduce(const void* sendbuff, void* recvbuff, size_t count, ncclDataType_t datatype, ncclRedOp_t op, int root, ncclComm_t comm, cudaStream_t stream); /* * (deprecated) Broadcast (in-place) * * Copies count values from root to all other devices. * root is the rank (not the CUDA device) where data resides before the * operation is started. * * This operation is implicitely in place. */ ncclResult_t ncclBcast(void* buff, size_t count, ncclDataType_t datatype, int root, ncclComm_t comm, cudaStream_t stream); ncclResult_t pncclBcast(void* buff, size_t count, ncclDataType_t datatype, int root, ncclComm_t comm, cudaStream_t stream); /* * Broadcast * * Copies count values from root to all other devices. * root is the rank (not the CUDA device) where data resides before the * operation is started. * * In-place operation will happen if sendbuff == recvbuff. */ ncclResult_t ncclBroadcast(const void* sendbuff, void* recvbuff, size_t count, ncclDataType_t datatype, int root, ncclComm_t comm, cudaStream_t stream); ncclResult_t pncclBroadcast(const void* sendbuff, void* recvbuff, size_t count, ncclDataType_t datatype, int root, ncclComm_t comm, cudaStream_t stream); /* * All-Reduce * * Reduces data arrays of length count in sendbuff using op operation, and * leaves identical copies of result on each recvbuff. * * In-place operation will happen if sendbuff == recvbuff. */ ncclResult_t ncclAllReduce(const void* sendbuff, void* recvbuff, size_t count, ncclDataType_t datatype, ncclRedOp_t op, ncclComm_t comm, cudaStream_t stream); ncclResult_t pncclAllReduce(const void* sendbuff, void* recvbuff, size_t count, ncclDataType_t datatype, ncclRedOp_t op, ncclComm_t comm, cudaStream_t stream); /* * Reduce-Scatter * * Reduces data in sendbuff using op operation and leaves reduced result * scattered over the devices so that recvbuff on rank i will contain the i-th * block of the result. * Assumes sendcount is equal to nranks*recvcount, which means that sendbuff * should have a size of at least nranks*recvcount elements. * * In-place operations will happen if recvbuff == sendbuff + rank * recvcount. */ ncclResult_t ncclReduceScatter(const void* sendbuff, void* recvbuff, size_t recvcount, ncclDataType_t datatype, ncclRedOp_t op, ncclComm_t comm, cudaStream_t stream); ncclResult_t pncclReduceScatter(const void* sendbuff, void* recvbuff, size_t recvcount, ncclDataType_t datatype, ncclRedOp_t op, ncclComm_t comm, cudaStream_t stream); /* * All-Gather * * Each device gathers sendcount values from other GPUs into recvbuff, * receiving data from rank i at offset i*sendcount. * Assumes recvcount is equal to nranks*sendcount, which means that recvbuff * should have a size of at least nranks*sendcount elements. * * In-place operations will happen if sendbuff == recvbuff + rank * sendcount. */ ncclResult_t ncclAllGather(const void* sendbuff, void* recvbuff, size_t sendcount, ncclDataType_t datatype, ncclComm_t comm, cudaStream_t stream); ncclResult_t pncclAllGather(const void* sendbuff, void* recvbuff, size_t sendcount, ncclDataType_t datatype, ncclComm_t comm, cudaStream_t stream); /* * Send * * Send data from sendbuff to rank peer. * * Rank peer needs to call ncclRecv with the same datatype and the same count from this * rank. * * This operation is blocking for the GPU. If multiple ncclSend and ncclRecv operations * need to progress concurrently to complete, they must be fused within a ncclGroupStart/ * ncclGroupEnd section. */ ncclResult_t ncclSend(const void* sendbuff, size_t count, ncclDataType_t datatype, int peer, ncclComm_t comm, cudaStream_t stream); ncclResult_t pncclSend(const void* sendbuff, size_t count, ncclDataType_t datatype, int peer, ncclComm_t comm, cudaStream_t stream); /* * Receive * * Receive data from rank peer into recvbuff. * * Rank peer needs to call ncclSend with the same datatype and the same count to this * rank. * * This operation is blocking for the GPU. If multiple ncclSend and ncclRecv operations * need to progress concurrently to complete, they must be fused within a ncclGroupStart/ * ncclGroupEnd section. */ ncclResult_t pncclRecv(void* recvbuff, size_t count, ncclDataType_t datatype, int peer, ncclComm_t comm, cudaStream_t stream); ncclResult_t ncclRecv(void* recvbuff, size_t count, ncclDataType_t datatype, int peer, ncclComm_t comm, cudaStream_t stream); /* * Group semantics * * When managing multiple GPUs from a single thread, and since NCCL collective * calls may perform inter-CPU synchronization, we need to "group" calls for * different ranks/devices into a single call. * * Grouping NCCL calls as being part of the same collective operation is done * using ncclGroupStart and ncclGroupEnd. ncclGroupStart will enqueue all * collective calls until the ncclGroupEnd call, which will wait for all calls * to be complete. Note that for collective communication, ncclGroupEnd only * guarantees that the operations are enqueued on the streams, not that * the operation is effectively done. * * Both collective communication and ncclCommInitRank can be used in conjunction * of ncclGroupStart/ncclGroupEnd, but not together. * * Group semantics also allow to fuse multiple operations on the same device * to improve performance (for aggregated collective calls), or to permit * concurrent progress of multiple send/receive operations. */ /* * Group Start * * Start a group call. All calls to NCCL until ncclGroupEnd will be fused into * a single NCCL operation. Nothing will be started on the CUDA stream until * ncclGroupEnd. */ ncclResult_t ncclGroupStart(); ncclResult_t pncclGroupStart(); /* * Group End * * End a group call. Start a fused NCCL operation consisting of all calls since * ncclGroupStart. Operations on the CUDA stream depending on the NCCL operations * need to be called after ncclGroupEnd. */ ncclResult_t ncclGroupEnd(); ncclResult_t pncclGroupEnd(); /* Register CUDA buffer for zero-copy operation */ ncclResult_t ncclCommRegister(const ncclComm_t comm, void* buff, size_t size, void** handle); ncclResult_t pncclCommRegister(const ncclComm_t comm, void* buff, size_t size, void** handle); /* Deregister CUDA buffer */ ncclResult_t ncclCommDeregister(const ncclComm_t comm, void* handle); ncclResult_t pncclCommDeregister(const ncclComm_t comm, void* handle); #ifdef __cplusplus } // end extern "C" #endif #endif // end include guard