/************************************************************************* * Copyright (c) 2015-2020, NVIDIA CORPORATION. All rights reserved. * Modifications Copyright (c) 2019-2020 Advanced Micro Devices, Inc. All rights reserved. * * See LICENSE.txt for license information ************************************************************************/ #include "nccl.h" #include "channel.h" #include "nvmlwrap.h" #include "bootstrap.h" #include "transport.h" #include "group.h" #include "net.h" #include "coll_net.h" #include "enqueue.h" #include "graph.h" #include "argcheck.h" #include #include #include #include #include #include #include #include #include #include #include "graph/topo.h" // [RCCL] #include "clique/CliqueManager.h" // [/RCCL] #define STR2(v) #v #define STR(v) STR2(v) #ifdef ENABLE_TRACE std::chrono::high_resolution_clock::time_point ncclEpoch; #endif #if CUDART_VERSION >= 9020 || defined(__HIP_PLATFORM_HCC__) || defined(__HCC__) || defined(__HIPCC__) #define NCCL_GROUP_CUDA_STREAM 0 // CGMD: CUDA 9.2,10.X Don't need to use an internal CUDA stream #else #define NCCL_GROUP_CUDA_STREAM 1 // CGMD: CUDA 9.0,9.1 Need to use an internal CUDA stream #endif const char* ncclFuncStr[NCCL_NUM_FUNCTIONS+4] = { "Broadcast", "Reduce", "AllGather", "ReduceScatter", "AllReduce", "Gather", "Scatter", "AllToAll", "AllToAllv" }; const char* ncclAlgoStr[NCCL_NUM_ALGORITHMS] = { "Tree", "Ring", "CollNet" }; const char* ncclProtoStr[NCCL_NUM_PROTOCOLS] = { "LL", "LL128", "Simple" }; NCCL_PARAM(GroupCudaStream, "GROUP_CUDA_STREAM", NCCL_GROUP_CUDA_STREAM); NCCL_PARAM(CheckPointers, "CHECK_POINTERS", 0); ncclNet_t* ncclNet = NULL; ncclCollNet_t* ncclCollNet = NULL; // Returns ncclInternalError if anything fails, causing that network to be ignored. ncclResult_t initNet(ncclNet_t* net) { int ndev; if (net->init(ncclDebugLog) != ncclSuccess) return ncclInternalError; if (net->devices(&ndev) != ncclSuccess) return ncclInternalError; if (ndev <= 0) return ncclSystemError; return ncclSuccess; } ncclResult_t initCollNet(ncclCollNet_t* collnet) { int ndev; if (collnet->init(ncclDebugLog) != ncclSuccess) return ncclInternalError; if (collnet->devices(&ndev) != ncclSuccess) return ncclInternalError; if (ndev <= 0) return ncclSystemError; return ncclSuccess; } ncclResult_t initNetPlugin(ncclNet_t** net, ncclCollNet_t** collnet) { void* netPluginLib = dlopen("librccl-net.so", RTLD_NOW | RTLD_LOCAL); if (netPluginLib == NULL) { // dlopen does not guarantee to set errno, but dlerror only gives us a // string, so checking errno doesn't hurt to try to provide a better // error message if (errno == ENOENT) { INFO(NCCL_INIT|NCCL_NET, "NET/Plugin : No plugin found (librccl-net.so), using internal implementation"); } else { INFO(NCCL_INIT|NCCL_NET, "NET/Plugin : Plugin load returned %d : %s.", errno, dlerror()); } return ncclSuccess; } ncclNet_t* extNet = (ncclNet_t*) dlsym(netPluginLib, STR(NCCL_PLUGIN_SYMBOL)); if (extNet == NULL) { INFO(NCCL_INIT|NCCL_NET, "NET/Plugin: Failed to find " STR(NCCL_PLUGIN_SYMBOL) " symbol."); } else if (initNet(extNet) == ncclSuccess) { *net = extNet; // Check for CollNet ncclCollNet_t* extCollNet = (ncclCollNet_t*) dlsym(netPluginLib, STR(NCCL_COLLNET_PLUGIN_SYMBOL)); if (extCollNet == NULL) { INFO(NCCL_INIT|NCCL_NET, "NET/Plugin: Failed to find " STR(NCCL_COLLNET_PLUGIN_SYMBOL) " symbol."); } else if (initCollNet(extCollNet) == ncclSuccess) { *collnet = extCollNet; } return ncclSuccess; } if (netPluginLib != NULL) dlclose(netPluginLib); return ncclSuccess; } ncclResult_t initNet() { // Always initialize bootstrap network NCCLCHECK(bootstrapNetInit()); NCCLCHECK(initNetPlugin(&ncclNet, &ncclCollNet)); if (ncclNet != NULL) return ncclSuccess; if (initNet(&ncclNetIb) == ncclSuccess) { ncclNet = &ncclNetIb; } else { NCCLCHECK(initNet(&ncclNetSocket)); ncclNet = &ncclNetSocket; } return ncclSuccess; } NCCL_PARAM(CollNetEnable, "COLLNET_ENABLE", 0); pthread_mutex_t initLock = PTHREAD_MUTEX_INITIALIZER; static bool initialized = false; static ncclResult_t ncclInit() { if (initialized) return ncclSuccess; pthread_mutex_lock(&initLock); if (!initialized) { initEnv(); NCCLCHECK(initNet()); INFO(NCCL_INIT, "Using network %s", ncclNetName()); initialized = true; } pthread_mutex_unlock(&initLock); return ncclSuccess; } NCCL_API(ncclResult_t, ncclGetVersion, int* version); ncclResult_t ncclGetVersion(int* version) { if (version == NULL) return ncclInvalidArgument; *version = NCCL_VERSION_CODE; return ncclSuccess; } NCCL_API(ncclResult_t, ncclGetUniqueId, ncclUniqueId* out); ncclResult_t ncclGetUniqueId(ncclUniqueId* out) { NCCLCHECK(ncclInit()); NCCLCHECK(PtrCheck(out, "GetUniqueId", "out")); return bootstrapGetUniqueId(out); } // Prevent compiler from optimizing out these operations #ifdef __clang__ #define NCCL_NO_OPTIMIZE __attribute__((optnone)) #else #define NCCL_NO_OPTIMIZE __attribute__((optimize("O0"))) #endif void NCCL_NO_OPTIMIZE commPoison(ncclComm_t comm) { comm->rank = comm->cudaDev = comm->busId = comm->nRanks = -1; } #ifdef ENABLE_COLLTRACE void *ncclCommThreadMain(void *arg) { ncclComm_t comm = (ncclComm_t)arg; do { int tail = LOAD(comm->hostDevComm.collTraceTail)%COLLTRACE_NUM_ITEMS; int head = comm->hostDevComm.collTraceHead; int count; if (head <= tail) count = tail - head; else count = COLLTRACE_NUM_ITEMS + head - tail; usleep(1000); //sleep 1ms for (int i = 0; i < count; i++) { char line[1024]; int offset = 0; #define VEGA_GPU_RTC_FREQUENCY 2.5E7 sprintf(line, "## [%12.6f] [%02d:%02d] %06lx", (double)(comm->hostDevComm.collTrace[head].timeStamp)/VEGA_GPU_RTC_FREQUENCY, comm->rank, comm->hostDevComm.collTrace[head].bid, comm->hostDevComm.collTrace[head].opCount); offset = strlen(line); switch (comm->hostDevComm.collTrace[head].type) { case ncclCollTraceKernelLaunchType: sprintf(line+offset, " KL hwid %8x funcIndex %d", comm->hostDevComm.collTrace[head].data_0, comm->hostDevComm.collTrace[head].funcIndex); break; case ncclCollTraceCollEndType: if (comm->hostDevComm.collTrace[head].funcIndex != -1) sprintf(line+offset, " CE next funcIndex %d", comm->hostDevComm.collTrace[head].funcIndex); else sprintf(line+offset, " KE"); break; case ncclCollTraceAbortType: sprintf(line+offset, " Abort"); break; default: sprintf(line+offset, " unknown collective trace data type"); break; } INFO(NCCL_COLL, "%s", line); head ++; head %= COLLTRACE_NUM_ITEMS; } comm->hostDevComm.collTraceHead = tail; } while(!LOAD(&comm->hostDevComm.collTraceExit)); pthread_exit(NULL); } #endif #undef NCCL_NO_OPTIMIZE static ncclResult_t commFree(ncclComm_t comm) { if (comm == NULL) return ncclSuccess; free(comm->p2plist.peerlist); free(comm->p2plist.connect.recv); free(comm->p2plist.connect.send); #ifdef ENABLE_PROFILING struct ncclProf* prof = (struct ncclProf*)malloc(sizeof(struct ncclProf)); CUDACHECK(hipMemcpy(prof, comm->hostDevComm.devProf, sizeof(struct ncclProf), hipMemcpyDeviceToHost)); uint64_t wait_cycle = 0, wait_recv_cycle = 0; for (int chan=0; channChannels; chan++) { wait_cycle += prof->wait_cycle[chan]; wait_recv_cycle += prof->wait_recv_cycle[chan]; } #define VEGA_GPU_RTC_FREQUENCY 2.5E7 if (comm->rank == 0) { INFO(NCCL_INIT, "# %4s %6s %6s %6s %6s %6s %7s %6s %6s %6s %6s %6s", "Rank", "total", " wait", "w_recv", "send", "rcRdS", "dRcRdCS", "dRcCS", "dRc", "cS", "rc", "rcCS"); INFO(NCCL_INIT, "# %4s %6s %6s %6s %6s %6s %7s %6s %6s %6s %6s %6s", "", "(s)", "(s)", "(s)", "(GB/s)", "(GB/s)", "(GB/s)", "(GB/s)", "(GB/s)", "(GB/s)", "(GB/s)", "(GB/s)", "(GB/s)"); } INFO(NCCL_INIT, "# %4d %6.4f %6.4f %6.4f %6.2f %6.2f %7.2f %6.2f %6.2f %6.2f %6.2f %6.2f", comm->rank, (double)prof->total_cycle/VEGA_GPU_RTC_FREQUENCY/comm->nChannels, (double)wait_cycle/VEGA_GPU_RTC_FREQUENCY/comm->nChannels, (double)wait_recv_cycle/VEGA_GPU_RTC_FREQUENCY/comm->nChannels, (prof->send_cycle) ? (double)prof->send_byte*comm->nChannels/((double)prof->send_cycle/VEGA_GPU_RTC_FREQUENCY*1.0E9) : 0, (prof->recvReduceSend_cycle) ? (double)prof->recvReduceSend_byte*comm->nChannels/((double)prof->recvReduceSend_cycle/VEGA_GPU_RTC_FREQUENCY*1.0E9) : 0, (prof->directRecvReduceCopySend_cycle) ? (double)prof->directRecvReduceCopySend_byte*comm->nChannels/((double)prof->directRecvReduceCopySend_cycle/VEGA_GPU_RTC_FREQUENCY*1.0E9) : 0, (prof->directRecvCopySend_cycle) ? (double)prof->directRecvCopySend_byte*comm->nChannels/((double)prof->directRecvCopySend_cycle/VEGA_GPU_RTC_FREQUENCY*1.0E9) : 0, (prof->directRecv_cycle) ? (double)prof->directRecv_byte*comm->nChannels/((double)prof->directRecv_cycle/VEGA_GPU_RTC_FREQUENCY*1.0E9) : 0, (prof->copySend_cycle) ? (double)prof->copySend_byte*comm->nChannels/((double)prof->copySend_cycle/VEGA_GPU_RTC_FREQUENCY*1.0E9) : 0, (prof->recv_cycle) ? (double)prof->recv_byte*comm->nChannels/((double)prof->recv_cycle/VEGA_GPU_RTC_FREQUENCY*1.0E9) : 0, (prof->recvCopySend_cycle) ? (double)prof->recvCopySend_byte*comm->nChannels/((double)prof->recvCopySend_cycle/VEGA_GPU_RTC_FREQUENCY*1.0E9) : 0); free(prof); CUDACHECK(hipFree(comm->hostDevComm.devProf)); for (int channel=0; channelnChannels, comm->p2pnChannels); channel++) { if (comm->channels[channel].send_byte) INFO(NCCL_INIT, "# [%03d:%02d] Proxy Send %6.2f GB/s (%ld bytes %d measurements)", comm->rank, channel, (comm->channels[channel].bw_count) ? (float)comm->channels[channel].bw_cumulative/comm->channels[channel].bw_count : 0, comm->channels[channel].send_byte, comm->channels[channel].bw_count); if (comm->channels[channel].recv_byte) INFO(NCCL_INIT, "# [%03d:%02d] Proxy Recv %6.2f GB/s (%ld bytes %d measurements)", comm->rank, channel, (comm->channels[channel].bw_count) ? (float)comm->channels[channel].bw_cumulative/comm->channels[channel].bw_count : 0, comm->channels[channel].recv_byte, comm->channels[channel].bw_count); } #endif #ifdef ENABLE_COLLTRACE STORE(&comm->hostDevComm.collTraceExit, 1); if (comm->hostDevComm.collTraceThread) pthread_join(comm->hostDevComm.collTraceThread, NULL); CUDACHECK(hipHostFree((void *)comm->hostDevComm.collTrace)); CUDACHECK(hipHostFree((void *)comm->hostDevComm.collTraceTail)); #endif free(comm->peerInfo); ncclTopoFree(comm->topo); if (comm->bootstrap) NCCLCHECK(bootstrapClose(comm->bootstrap)); CUDACHECK(hipFree(comm->hostDevComm.channels)); CUDACHECK(hipFree(comm->devComm)); for (int channel=0; channelchannels+channel, comm->nRanks)); if (comm->doneEvent != NULL) CUDACHECK(hipEventDestroy(comm->doneEvent)); if (comm->launchMode == ncclComm::GROUP) { CUDACHECK(hipStreamDestroy(comm->groupStream)); } // Last rank frees shared resources between threads int isLast; NCCLCHECK(ncclCpuBarrierIn(comm, &isLast)); if (isLast) { free(comm->intraBarrier); free(comm->intraParams); free(comm->intraCudaDevs); free(comm->intraCGMode); free(comm->intraCC); } CUDACHECK(hipHostFree((void *)comm->abortFlag)); // Poison comm to try and catch a double free commPoison(comm); free(comm); return ncclSuccess; } RCCL_PARAM(AllToAllDisable, "ALLTOALL_KERNEL_DISABLE", 1); RCCL_PARAM(ForceEnableClique, "FORCE_ENABLE_CLIQUE", 0); static ncclResult_t commAlloc(ncclComm_t* comret, int ndev, int rank) { if (ndev < 1) { WARN("invalid device count (%d) requested", ndev); return ncclInvalidArgument; } if (rank >= ndev || rank < 0) { WARN("rank %d exceeds ndev=%d", rank, ndev); return ncclInvalidArgument; } // Try to create a CUDA object right away. If there is something wrong with // the device we're on (failure cause #1) , better know it early. hipEvent_t doneEvent; CUDACHECK(hipEventCreateWithFlags(&doneEvent, hipEventDisableTiming)); struct ncclComm* comm; NCCLCHECK(ncclCalloc(&comm, 1)); comm->rank = comm->hostDevComm.rank =rank; comm->nRanks = comm->hostDevComm.nRanks = ndev; hipGetDevice(&comm->cudaDev); NCCLCHECK(getBusId(comm->cudaDev, &comm->busId)); TRACE(NCCL_INIT,"comm %p rank %d nranks %d cudaDev %d busId %x", comm, rank, ndev, comm->cudaDev, comm->busId); comm->doneEvent = doneEvent; comm->checkPointers = ncclParamCheckPointers() == 1 ? true : false; #if CUDART_VERSION >= 9020 || defined(__HIP_PLATFORM_HCC__) || defined(__HCC__) || defined(__HIPCC__) comm->groupCudaStream = ncclParamGroupCudaStream(); #else // Don't allow the user to overload the default setting in older CUDA builds comm->groupCudaStream = NCCL_GROUP_CUDA_STREAM; #endif comm->fatalError = ncclSuccess; NCCLCHECK(ncclCudaHostCalloc((uint32_t**)&comm->abortFlag, 1)); comm->hostDevComm.abortFlag = comm->abortFlag; STORE(comm->abortFlag, 0); comm->argsptr = &comm->args; #ifdef ENABLE_PROFILING NCCLCHECK(ncclCudaCalloc(&comm->hostDevComm.devProf, 1)); #endif #ifdef ENABLE_COLLTRACE CUDACHECK(hipHostMalloc((void**) &comm->hostDevComm.collTraceTail, sizeof(uint32_t), hipHostMallocMapped)); CUDACHECK(hipHostMalloc((void**) &comm->hostDevComm.collTrace, sizeof(struct ncclCollTrace) * COLLTRACE_NUM_ITEMS, hipHostMallocMapped)); memset(comm->hostDevComm.collTrace, 0, sizeof(struct ncclCollTrace) * COLLTRACE_NUM_ITEMS); comm->hostDevComm.collTraceExit = comm->hostDevComm.collTraceHead = *comm->hostDevComm.collTraceTail = 0; if ((ncclDebugLevel >= NCCL_LOG_INFO) && (ncclDebugMask & NCCL_COLL)) pthread_create(&comm->hostDevComm.collTraceThread, NULL, ncclCommThreadMain, (void *)comm); else comm->hostDevComm.collTraceThread = 0; #endif comm->collNetSupport = 0; comm->p2plist.count=0; NCCLCHECK(ncclCalloc(&comm->p2plist.peerlist, comm->nRanks)); for (int r=0; rnRanks; r++) comm->p2plist.peerlist[r].sendbytes = comm->p2plist.peerlist[r].recvbytes = -1; NCCLCHECK(ncclCalloc(&comm->p2plist.connect.recv, MAXCHANNELS*comm->nRanks)); NCCLCHECK(ncclCalloc(&comm->p2plist.connect.send, MAXCHANNELS*comm->nRanks)); // Mark channels as non initialized. for (int c=0; cchannels[c].id = -1; comm->alltoallDisable = false; if (rcclParamAllToAllDisable()) comm->alltoallDisable = true; *comret = comm; return ncclSuccess; } static ncclResult_t devCommSetup(ncclComm_t comm) { // Duplicate the channels on the device NCCLCHECK(ncclCudaCalloc(&comm->hostDevComm.channels, std::max(comm->nChannels, comm->p2pnChannels))); NCCLCHECK(ncclCudaMemcpy(comm->hostDevComm.channels, comm->channels, std::max(comm->nChannels, comm->p2pnChannels))); // Copy userRanks and peers for (int r=0; rnChannels, comm->p2pnChannels); r++) { NCCLCHECK(ncclCudaMemcpy(comm->channels[r].ring.devUserRanks, comm->channels[r].ring.userRanks, comm->nRanks)); } // Duplicate the dev comm on the device NCCLCHECK(ncclCudaCalloc(&comm->devComm, 1)); NCCLCHECK(ncclCudaMemcpy(comm->devComm, &comm->hostDevComm, 1)); return ncclSuccess; } // Pre-process the string so that running "strings" on the lib can quickly reveal the version. #if defined(__HIP_PLATFORM_HCC__) || defined(__HCC__) || defined(__HIPCC__) #define VERSION_STRING "RCCL version " STR(NCCL_MAJOR) "." STR(NCCL_MINOR) "." STR(NCCL_PATCH) NCCL_SUFFIX "+hip" STR(HIP_VERSION_MAJOR) "." STR(HIP_VERSION_MINOR) #else #define VERSION_STRING "NCCL version " STR(NCCL_MAJOR) "." STR(NCCL_MINOR) "." STR(NCCL_PATCH) NCCL_SUFFIX "+cuda" STR(CUDA_MAJOR) "." STR(CUDA_MINOR) #endif static void showVersion() { static int shown = 0; if (shown == 0 && ncclDebugLevel >= NCCL_LOG_VERSION) { printf("%s\n", VERSION_STRING); fflush(stdout); if (ncclDebugFile != stdout) INFO(NCCL_ALL,"%s", VERSION_STRING); // Also log NCCL version in one of the files shown = 1; } } static ncclResult_t fillInfo(struct ncclComm* comm, struct ncclPeerInfo* info, uint64_t commHash) { info->rank = comm->rank; CUDACHECK(hipGetDevice(&info->cudaDev)); info->hostHash=getHostHash()+commHash; info->pidHash=getPidHash()+commHash; // Get the device MAJOR:MINOR of /dev/shm so we can use that // information to decide whether we can use SHM for inter-process // communication in a container environment struct stat statbuf; SYSCHECK(stat("/dev/shm", &statbuf), "stat"); info->shmDev = statbuf.st_dev; info->busId = comm->busId; NCCLCHECK(ncclGpuGdrSupport(&info->gdrSupport)); return ncclSuccess; } static ncclResult_t setupChannel(struct ncclComm* comm, int channelId, int rank, int nranks, int* ringRanks) { TRACE(NCCL_INIT, "rank %d nranks %d", rank, nranks); NCCLCHECK(initChannel(comm, channelId)); struct ncclRing* ring = &comm->channels[channelId].ring; // Reorganize ranks to start with rank. int shift; for (shift = 0; shiftuserRanks[i] = ringRanks[(i+shift)%nranks]; } return ncclSuccess; } void* waitForNonNullPtr(void* p) { volatile void** ptr = (volatile void**) p; while (LOAD(ptr) == NULL) sched_yield(); return (void*)(LOAD(ptr)); } ncclResult_t initParams(struct ncclComm* comm) { hipLaunchParams* params = comm->myParams = comm->intraParams+comm->intraRank; params->args =(void **)&comm->argsptr; params->stream = NULL; params->sharedMem = 0; params->blockDim.x = 0; params->blockDim.y = params->blockDim.z = 1; params->gridDim.x = 0; params->gridDim.y = params->gridDim.z = 1; return ncclSuccess; } // Allocate/Set Intra Process Structures and set CG options ncclResult_t ncclCommSetIntra(struct ncclComm* comm, int rank, int ranks, struct ncclComm* comm0) { comm->intraRank = rank; comm->intraRanks = ranks; comm->intraPhase = 0; // Alloc shared structures if (rank == 0) { assert(comm == comm0); int* bar; NCCLCHECK(ncclCalloc(&bar, 2)); bar[0] = bar[1] = 0; comm->intraBarrier = bar; NCCLCHECK(ncclCalloc(&comm->intraParams, comm->intraRanks)); NCCLCHECK(ncclCalloc(&comm->intraCudaDevs, comm->intraRanks)); int* CGMode; NCCLCHECK(ncclCalloc(&CGMode, 1)); *CGMode = 0x11; comm->intraCGMode = CGMode; int* CC; NCCLCHECK(ncclCalloc(&CC, 1)); *CC = ncclCudaCompCap(); comm->intraCC = CC; } else { comm->intraBarrier = (int*)waitForNonNullPtr(&comm0->intraBarrier); comm->intraParams = (hipLaunchParams*)waitForNonNullPtr(&comm0->intraParams); comm->intraCudaDevs = (int*)waitForNonNullPtr(&comm0->intraCudaDevs); comm->intraCGMode = (int*)waitForNonNullPtr(&comm0->intraCGMode); comm->intraCC = (int*)waitForNonNullPtr(&comm0->intraCC); } comm->intraCudaDevs[comm->intraRank] = comm->cudaDev; NCCLCHECK(initParams(comm)); int cgMdLaunch = 1; // Set CG Mode comm->launchMode = ncclComm::GROUP; char* str = getenv("NCCL_LAUNCH_MODE"); if (str) INFO(NCCL_ENV, "NCCL_LAUNCH_MODE set by environment to %s", str); if (comm->intraRanks == 1 || (str && strcmp(str, "PARALLEL") == 0)) { comm->launchMode = ncclComm::PARALLEL; } if (comm->launchMode == ncclComm::GROUP) { CUDACHECK(hipStreamCreateWithFlags(&comm->groupStream, hipStreamNonBlocking)); #if CUDART_VERSION >= 9000 if (*comm->intraCC && (ncclCudaCompCap() == *comm->intraCC)) { // Check whether the GPU supports Cooperative Group Multi Device Launch (void) hipDeviceGetAttribute(&cgMdLaunch, cudaDevAttrCooperativeMultiDeviceLaunch, comm->cudaDev); } #endif } // Disable cgMdLaunch if any rank does not support it if (cgMdLaunch == 0) { *comm->intraCGMode = 0x10; } return ncclSuccess; } #define DEFAULT_LL_BUFFSIZE (NCCL_LL_LINES_PER_THREAD*NCCL_LL_MAX_NTHREADS*NCCL_STEPS*sizeof(union ncclLLFifoLine)) #define DEFAULT_LL128_BUFFSIZE (NCCL_LL128_ELEMS_PER_THREAD*NCCL_LL128_MAX_NTHREADS*NCCL_STEPS*sizeof(uint64_t)) #define DEFAULT_BUFFSIZE (1LL << 22) /* 4MiB */ #define DEFAULT_BUFFSIZE_ARM (1LL << 20) /* 1MiB */ NCCL_PARAM(BuffSize, "BUFFSIZE", -2); NCCL_PARAM(LlBuffSize, "LL_BUFFSIZE", -2); NCCL_PARAM(Ll128BuffSize, "LL128_BUFFSIZE", -2); static ncclResult_t computeBuffSizes(struct ncclComm* comm) { int cpuArch, cpuVendor, cpuModel; NCCLCHECK(ncclTopoCpuType(comm->topo, &cpuArch, &cpuVendor, &cpuModel)); int64_t envs[NCCL_NUM_PROTOCOLS] = { ncclParamLlBuffSize(), ncclParamLl128BuffSize(), ncclParamBuffSize() }; int defaults[NCCL_NUM_PROTOCOLS] = { DEFAULT_LL_BUFFSIZE, DEFAULT_LL128_BUFFSIZE, DEFAULT_BUFFSIZE }; if (cpuArch == NCCL_TOPO_CPU_ARCH_ARM) defaults[NCCL_PROTO_SIMPLE] = DEFAULT_BUFFSIZE_ARM; if (comm->nRanks >= 32) { defaults[NCCL_PROTO_SIMPLE] = 524288; INFO(NCCL_INIT, "Setting DEFAULT_BUFFSIZE to %d for nRanks %d", defaults[NCCL_PROTO_SIMPLE], comm->nRanks); } for (int p=0; pbuffSizes[p] = comm->hostDevComm.buffSizes[p] = envs[p] != -2 ? envs[p] : defaults[p]; } return ncclSuccess; } extern struct ncclTransport collNetTransport; // All ranks must participate in collNetSetup call // type: 0 for send, 1 for recv // return: 0 - unsupported, 1 - supported // We do not NCCLCHECK this call because we would fall back to P2P network in case CollNet setup fails static int collNetSetup(struct ncclComm* comm, struct ncclTopoGraph* collNetGraph, struct ncclChannel* channel, int rank, int nranks, int masterRank, int masterPeer, int nMasters, int type) { int rankInCollNet = -1; int supported = 0; int isMaster = (rank == masterRank) ? 1 : 0; struct { int collNetRank; ncclConnect connect; } sendrecvExchange; // check if we can connect to collnet, whose root is the nranks-th rank struct ncclPeerInfo *myInfo = comm->peerInfo+rank, *peerInfo = comm->peerInfo+nranks; peerInfo->rank = nranks; int ret = 1; if (isMaster) { NCCLCHECK(collNetTransport.canConnect(&ret, comm->topo, collNetGraph, myInfo, peerInfo)); } // send master receives connect info from peer recv master if (isMaster && type == 0) { NCCLCHECK(bootstrapRecv(comm->bootstrap, masterPeer, &sendrecvExchange, sizeof(sendrecvExchange))); rankInCollNet = sendrecvExchange.collNetRank; INFO(NCCL_INIT, "CollNet [send] : rank %d collNetRank %d collNetNranks %d received connect from rank %d", rank, rankInCollNet, nMasters, masterPeer); } // select struct ncclPeer* root = channel->peers+nranks; struct ncclConnector* conn = (type == 1) ? &root->recv : &root->send; struct ncclTransportComm* transportComm = (type == 1) ? &(collNetTransport.recv) : &(collNetTransport.send); conn->transportComm = transportComm; // setup struct ncclConnect myConnect; if (isMaster && ret > 0) { NCCLCHECK(transportComm->setup(comm->topo, collNetGraph, myInfo, peerInfo, &myConnect, conn, channel->id)); } // prepare connect handles ncclResult_t res; struct { int isMaster; ncclConnect connect; } *allConnects = NULL; ncclConnect *masterConnects = NULL; NCCLCHECK(ncclCalloc(&masterConnects, nMasters)); if (type == 1) { // recv side: AllGather // all ranks must participate NCCLCHECK(ncclCalloc(&allConnects, nranks)); allConnects[rank].isMaster = isMaster; memcpy(&(allConnects[rank].connect), &myConnect, sizeof(struct ncclConnect)); NCCLCHECKGOTO(bootstrapAllGather(comm->bootstrap, allConnects, sizeof(*allConnects)), res, cleanup); // consolidate int c = 0; for (int r = 0; r < nranks; r++) { if (allConnects[r].isMaster) { memcpy(masterConnects+c, &(allConnects[r].connect), sizeof(struct ncclConnect)); if (r == rank) rankInCollNet = c; c++; } } } else { // send side : copy in connect info received from peer recv master if (isMaster) memcpy(masterConnects+rankInCollNet, &(sendrecvExchange.connect), sizeof(struct ncclConnect)); } // connect if (isMaster && ret > 0) { NCCLCHECKGOTO(transportComm->connect(masterConnects, nMasters, rankInCollNet, conn), res, cleanup); struct ncclPeer* devRoot = channel->devPeers+nranks; struct ncclConnector* devConn = (type == 1) ? &devRoot->recv : &devRoot->send; CUDACHECKGOTO(hipMemcpy(devConn, conn, sizeof(struct ncclConnector), hipMemcpyHostToDevice), res, cleanup); } // recv side sends connect info to send side if (isMaster && type == 1) { sendrecvExchange.collNetRank = rankInCollNet; memcpy(&sendrecvExchange.connect, masterConnects+rankInCollNet, sizeof(struct ncclConnect)); NCCLCHECKGOTO(bootstrapSend(comm->bootstrap, masterPeer, &sendrecvExchange, sizeof(sendrecvExchange)), res, cleanup); INFO(NCCL_INIT, "CollNet [recv] : rank %d collNetRank %d collNetNranks %d sent connect to rank %d", rank, rankInCollNet, nMasters, masterPeer); } if (ret > 0) { supported = 1; } cleanup: if (allConnects != NULL) free(allConnects); if (masterConnects != NULL) free(masterConnects); return supported; } static ncclResult_t checkCollNetSetup(struct ncclComm* comm, int rank, int collNetSetupFail) { int nranks = comm->nRanks; // AllGather collNet setup results int* allGatherFailures; NCCLCHECK(ncclCalloc(&allGatherFailures, nranks)); allGatherFailures[rank] = collNetSetupFail; NCCLCHECK(bootstrapAllGather(comm->bootstrap, allGatherFailures, sizeof(int))); for (int i=0; inChannels; r++) { struct ncclChannel* channel = comm->channels+r; struct ncclPeer* peer = channel->peers+nranks; if (peer->send.transportResources && peer->send.transportComm) NCCLCHECK(peer->send.transportComm->free(peer->send.transportResources)); if (peer->recv.transportResources && peer->recv.transportComm) NCCLCHECK(peer->recv.transportComm->free(peer->recv.transportResources)); peer->send.transportResources = NULL; // avoid double free peer->recv.transportResources = NULL; // avoid double free } // Set support to 0 comm->collNetSupport = 0; } else { comm->collNetSupport = 1; } return ncclSuccess; } NCCL_PARAM(CrossNic, "CROSS_NIC", 2); NCCL_PARAM(GraphDumpFileRank, "GRAPH_DUMP_FILE_RANK", 0); static ncclResult_t initTransportsRank(struct ncclComm* comm, ncclUniqueId* commId) { // We use 3 AllGathers // 1. { peerInfo, comm } // 2. ConnectTransport[nranks], ConnectValue[nranks] // 3. { nThreads, nrings, compCap, prev[MAXCHANNELS], next[MAXCHANNELS] } int rank = comm->rank; int nranks = comm->nRanks; uint64_t commHash = getHash(commId->internal, NCCL_UNIQUE_ID_BYTES); TRACE(NCCL_INIT, "comm %p, commHash %lx, rank %d nranks %d - BEGIN", comm, commHash, rank, nranks); // [RCCL] Collect the PID of the root int rootPid; NCCLCHECK(bootstrapInit(commId, rank, nranks, &comm->bootstrap, &rootPid)); // [/RCCL] // AllGather1 - begin struct { struct ncclPeerInfo peerInfo; struct ncclComm* comm; } *allGather1Data; NCCLCHECK(ncclCalloc(&allGather1Data, nranks)); allGather1Data[rank].comm = comm; struct ncclPeerInfo* myInfo = &allGather1Data[rank].peerInfo; NCCLCHECK(fillInfo(comm, myInfo, commHash)); NCCLCHECK(bootstrapAllGather(comm->bootstrap, allGather1Data, sizeof(*allGather1Data))); NCCLCHECK(ncclCalloc(&comm->peerInfo, nranks+1)); // Extra rank to represent CollNet root for (int i = 0; i < nranks; i++) { memcpy(comm->peerInfo+i, &allGather1Data[i].peerInfo, sizeof(struct ncclPeerInfo)); if ((i != rank) && (comm->peerInfo[i].hostHash == myInfo->hostHash) && (comm->peerInfo[i].busId == myInfo->busId)) { WARN("Duplicate GPU detected : rank %d and rank %d both on CUDA device %x", rank, i, myInfo->busId); return ncclInvalidUsage; } } // AllGather1 data is used again below // AllGather1 - end // Topo detection / System graph creation NCCLCHECK(ncclTopoGetSystem(comm, &comm->topo)); // Compute paths between GPUs and NICs NCCLCHECK(ncclTopoComputePaths(comm->topo, comm->peerInfo)); // Remove inaccessible GPUs and unused NICs NCCLCHECK(ncclTopoTrimSystem(comm->topo, comm)); // Recompute paths after trimming NCCLCHECK(ncclTopoComputePaths(comm->topo, comm->peerInfo)); // Init search NCCLCHECK(ncclTopoSearchInit(comm->topo)); // Print final topology NCCLCHECK(ncclTopoPrint(comm->topo)); // Get rings and trees struct ncclTopoGraph ringGraph; ringGraph.id = 0; ringGraph.pattern = NCCL_TOPO_PATTERN_RING; ringGraph.crossNic = ncclParamCrossNic(); ringGraph.collNet = 0; ringGraph.minChannels = 1; ringGraph.maxChannels = MAXCHANNELS/2; NCCLCHECK(ncclTopoCompute(comm->topo, &ringGraph)); NCCLCHECK(ncclTopoPrintGraph(comm->topo, &ringGraph)); struct ncclTopoGraph treeGraph; treeGraph.id = 1; treeGraph.pattern = NCCL_TOPO_PATTERN_SPLIT_TREE; treeGraph.crossNic = ncclParamCrossNic(); treeGraph.collNet = 0; treeGraph.minChannels = comm->topo->nodes[NET].count != 0 ? 1 : ringGraph.nChannels; treeGraph.maxChannels = ringGraph.nChannels; NCCLCHECK(ncclTopoCompute(comm->topo, &treeGraph)); NCCLCHECK(ncclTopoPrintGraph(comm->topo, &treeGraph)); struct ncclTopoGraph collNetGraph; collNetGraph.id = 2; collNetGraph.pattern = NCCL_TOPO_PATTERN_TREE; collNetGraph.collNet = 1; collNetGraph.crossNic = ncclParamCrossNic(); collNetGraph.minChannels = collNetGraph.maxChannels = ringGraph.nChannels; NCCLCHECK(ncclTopoCompute(comm->topo, &collNetGraph)); NCCLCHECK(ncclTopoPrintGraph(comm->topo, &collNetGraph)); if (comm->rank == ncclParamGraphDumpFileRank()) { struct ncclTopoGraph* graphs[3] = { &ringGraph, &treeGraph, &collNetGraph }; NCCLCHECK(ncclTopoDumpGraphs(comm->topo, 3, graphs)); } // AllGather3 - begin struct ncclGraphInfo { int sameChannels; float speedIntra; float speedInter; int typeIntra; }; struct { int cudaCompCap; int fullCudaCompCap; int nChannels; int gcn; int alltoallDisable; struct ncclGraphInfo tree; struct ncclGraphInfo ring; struct ncclGraphInfo collNet; struct ncclTopoRanks topoRanks; } *allGather3Data; NCCLCHECK(ncclCalloc(&allGather3Data, nranks)); int idx; NCCLCHECK(ncclTopoIdToIndex(comm->topo, GPU, myInfo->busId, &idx)); allGather3Data[rank].cudaCompCap = comm->topo->nodes[GPU].nodes[idx].gpu.cudaCompCap; allGather3Data[rank].gcn = comm->topo->nodes[GPU].nodes[idx].gpu.gcn; allGather3Data[rank].nChannels = comm->nChannels = treeGraph.nChannels = ringGraph.nChannels = std::min(treeGraph.nChannels, ringGraph.nChannels); allGather3Data[rank].alltoallDisable = comm->alltoallDisable; allGather3Data[rank].tree.sameChannels = treeGraph.sameChannels; allGather3Data[rank].tree.speedIntra = treeGraph.speedIntra; allGather3Data[rank].tree.speedInter = treeGraph.speedInter; allGather3Data[rank].tree.typeIntra = treeGraph.typeIntra; allGather3Data[rank].ring.sameChannels = ringGraph.sameChannels; allGather3Data[rank].ring.speedIntra = ringGraph.speedIntra; allGather3Data[rank].ring.speedInter = ringGraph.speedInter; allGather3Data[rank].ring.typeIntra = ringGraph.typeIntra; allGather3Data[rank].collNet.sameChannels = collNetGraph.sameChannels; allGather3Data[rank].collNet.speedIntra = collNetGraph.speedIntra; allGather3Data[rank].collNet.speedInter = collNetGraph.speedInter; allGather3Data[rank].collNet.typeIntra = collNetGraph.typeIntra; NCCLCHECK(ncclTopoPreset(comm, &treeGraph, &ringGraph, &collNetGraph, &allGather3Data[rank].topoRanks)); NCCLCHECK(bootstrapAllGather(comm->bootstrap, allGather3Data, sizeof(*allGather3Data))); // Determine nNodes, firstRanks, ... int* nodesFirstRank; NCCLCHECK(ncclCalloc(&nodesFirstRank, nranks)); for (int i=0; inNodes; n++) { if (nodesFirstRank[n] == firstRank) node = n; } if (node == -1) { node = comm->nNodes++; nodesFirstRank[node] = firstRank; } if (i == comm->rank) comm->node = node; } // Determine the minimum CUDA Compute capability of all GPUs int myCompCap = allGather3Data[rank].cudaCompCap; int minCompCap = myCompCap, maxCompCap = myCompCap; for (int i = 0; i < nranks; i++) { minCompCap = std::min(allGather3Data[i].cudaCompCap, minCompCap); maxCompCap = std::max(allGather3Data[i].cudaCompCap, maxCompCap); } int nChannelsOrig = comm->nChannels; struct ncclTopoRanks** allTopoRanks; NCCLCHECK(ncclCalloc(&allTopoRanks, comm->nRanks)); int gcn = allGather3Data[0].gcn; int alltoallDisable = 0; for (int i=0; inChannels = std::min(allGather3Data[i].nChannels, comm->nChannels); treeGraph.sameChannels = std::min(allGather3Data[i].tree.sameChannels, treeGraph.sameChannels); treeGraph.speedIntra = std::min(allGather3Data[i].tree.speedIntra, treeGraph.speedIntra); treeGraph.speedInter = std::min(allGather3Data[i].tree.speedInter, treeGraph.speedInter); treeGraph.typeIntra = std::min(allGather3Data[i].tree.typeIntra, treeGraph.typeIntra); ringGraph.sameChannels = std::min(allGather3Data[i].ring.sameChannels, ringGraph.sameChannels); ringGraph.speedIntra = std::min(allGather3Data[i].ring.speedIntra, ringGraph.speedIntra); ringGraph.speedInter = std::min(allGather3Data[i].ring.speedInter, ringGraph.speedInter); ringGraph.typeIntra = std::min(allGather3Data[i].ring.typeIntra, ringGraph.typeIntra); collNetGraph.sameChannels = std::min(allGather3Data[i].collNet.sameChannels, collNetGraph.sameChannels); collNetGraph.speedIntra = std::min(allGather3Data[i].collNet.speedIntra, collNetGraph.speedIntra); collNetGraph.speedInter = std::min(allGather3Data[i].collNet.speedInter, collNetGraph.speedInter); collNetGraph.typeIntra = std::min(allGather3Data[i].collNet.typeIntra, collNetGraph.typeIntra); } if (comm->alltoallDisable != alltoallDisable) { comm->alltoallDisable = alltoallDisable; } INFO(NCCL_INIT, "RCCL AllToAll(v)/Scatter/Gather kernels %s", comm->alltoallDisable ? "disabled" : "enabled"); // count NETs used by ring int nNets = 0; int nets[MAXCHANNELS*2]; for (int i = 0; i < ringGraph.nChannels; i++) { for (int j = 0; j < 2; j++) { int k; for (k = 0; k < nNets; k++) if (nets[k] == ringGraph.inter[i*2+j]) break; if (k >= nNets) { nets[nNets] = ringGraph.inter[i*2+j]; nNets++; } } } if (comm->nChannels < nChannelsOrig) { // We started duplicating channels during Preset(), so we need to move the // duplicated channels since we have removed some. for (int i=0; inChannels; i++) memcpy(comm->channels+comm->nChannels+i, comm->channels+nChannelsOrig+i, sizeof(struct ncclChannel)); } int *rings; NCCLCHECK(ncclCalloc(&rings, nranks*MAXCHANNELS)); NCCLCHECK(ncclTopoPostset(comm, nodesFirstRank, allTopoRanks, rings, gcn, nNets)); if (comm->nNodes > 1 && ncclParamCollNetEnable() == 1 && collNetSupport() && collNetGraph.nChannels) { NCCLCHECK(ncclTopoConnectCollNet(comm, &collNetGraph, rank)); } free(allTopoRanks); free(nodesFirstRank); free(allGather3Data); // AllGather3 - end TRACE(NCCL_INIT, "rank %d nranks %d - BUILT %d TREES/RINGS", rank, nranks, comm->nChannels); NCCLCHECK(ncclTopoTuneModel(comm, minCompCap, maxCompCap, &treeGraph, &ringGraph, &collNetGraph)); char line[1024]; line[0]='\0'; for (int c=0; cnChannels; c++) { struct ncclTree* treeUp = &comm->channels[c].treeUp; struct ncclTree* treeDn = &comm->channels[c].treeDn; snprintf(line+strlen(line), 1023-strlen(line), " [%d] %d/%d/%d->%d->%d|%d->%d->%d/%d/%d", c, treeUp->down[0], treeUp->down[1], treeUp->down[2], rank, treeUp->up, treeDn->up, rank, treeDn->down[0], treeDn->down[1], treeDn->down[2]); INFO(NCCL_GRAPH, "Ring %d : %d -> %d -> %d", c, comm->channels[c].ring.prev, comm->rank, comm->channels[c].ring.next); } line[1023] = '\0'; INFO(NCCL_INIT, "Trees%s", line); // Set Affinity to a CPU local the our GPU, so that all memory we allocate // on the host is local. cpu_set_t affinitySave; sched_getaffinity(0, sizeof(cpu_set_t), &affinitySave); NCCLCHECK(ncclTopoSetAffinity(comm->topo, comm->rank)); ncclResult_t ret; NCCLCHECK(computeBuffSizes(comm)); // Connect with prev/next for each ring struct ncclConnect *connect; NCCLCHECKGOTO(ncclCalloc(&connect, 2), ret, affinity_restore); for (int c=0; cnChannels; c++) { struct ncclChannel* channel = comm->channels+c; NCCLCHECKGOTO(setupChannel(comm, c, rank, nranks, rings+c*nranks), ret, affinity_restore); if (comm->nRanks == 1) continue; NCCLCHECKGOTO(ncclTransportP2pSetup(comm, &ringGraph, channel, 1, &channel->ring.prev, 1, &channel->ring.next), ret, affinity_restore); NCCLCHECKGOTO(ncclTransportP2pSetup(comm, &treeGraph, channel, NCCL_MAX_TREE_ARITY, channel->treeUp.down, 1, &channel->treeUp.up), ret, affinity_restore); NCCLCHECKGOTO(ncclTransportP2pSetup(comm, &treeGraph, channel, 1, &channel->treeDn.up, NCCL_MAX_TREE_ARITY, channel->treeDn.down), ret, affinity_restore); } // Check if we can setup CollNet if (comm->nNodes > 1 && ncclParamCollNetEnable() == 1 && collNetSupport() && collNetGraph.nChannels) { int logicChannels = comm->nChannels/2; int collNetSetupFail = 0; const int recvIndex = 0; // recv GPU index is always 0 const int sendIndex = collNetGraph.pattern == NCCL_TOPO_PATTERN_TREE ? 0 : 1; // send GPU index depends on topo pattern for (int c=0; cchannels+logicChannels+c; struct ncclChannel* channelSend = comm->channels+c; NCCLCHECK(ncclTransportP2pSetup(comm, &collNetGraph, channelRecv, 1, &channelRecv->collTreeDn.up, 1, channelRecv->collTreeDn.down)); NCCLCHECK(ncclTransportP2pSetup(comm, &collNetGraph, channelSend, 1, channelSend->collTreeUp.down, 1, &channelSend->collTreeUp.up)); const int recvMaster = collNetGraph.intra[c*comm->localRanks+recvIndex]; const int sendMaster = collNetGraph.intra[c*comm->localRanks+sendIndex]; if (collNetSetup(comm, &collNetGraph, channelRecv, rank, nranks, recvMaster, sendMaster, comm->nNodes, 1) != 1) collNetSetupFail = 1; else if (collNetSetup(comm, &collNetGraph, channelSend, rank, nranks, sendMaster, recvMaster, comm->nNodes, 0) != 1) collNetSetupFail = 1; } // Verify CollNet setup across ranks NCCLCHECK(checkCollNetSetup(comm, rank, collNetSetupFail)); } TRACE(NCCL_INIT, "rank %d nranks %d - CONNECTED %d RINGS AND TREES", rank, nranks, comm->nChannels); free(connect); free(rings); // Compute nChannels per peer for p2p NCCLCHECK(ncclTopoComputeP2pChannels(comm)); if (!alltoallDisable) { int nc = comm->nChannels; if (comm->topo->type == RCCL_TOPO_4P2H_ROME) nc = 2; for (int c=0; cp2plist.connect; connect->nrecv[c] = 0; connect->nsend[c] = 0; for (int p=0; pchannels[c].peers[peerSend].send.connected == 0) { connect->send[c*nranks+connect->nsend[c]++] = peerSend; } if (comm->channels[c].peers[peerRecv].recv.connected == 0) { connect->recv[c*nranks+connect->nrecv[c]++] = peerRecv; } } } for (int c=0; cchannels+c; struct ncclP2PConnect* connect = &comm->p2plist.connect; #if 0 printf("channel %d recv: ", c); for (int i=0; inrecv[c]; i++) printf("%d ", connect->recv[c*nranks+i]); printf("\n"); printf("channel %d send: ", c); for (int i=0; insend[c]; i++) printf("%d ", connect->send[c*nranks+i]); printf("\n"); #endif NCCLCHECK(ncclTransportP2pSetup(comm, NULL, channel, connect->nrecv[c], connect->recv+c*nranks, connect->nsend[c], connect->send+c*nranks)); connect->nrecv[c] = 0; connect->nsend[c] = 0; } } // Compute intra ranks (using AllGather1 data) do { int intraRank0 = -1, intraRank = -1, intraRanks = 0; for (int i = 0; i < nranks; i++) { if ((allGather1Data[i].peerInfo.hostHash == allGather1Data[rank].peerInfo.hostHash) && (allGather1Data[i].peerInfo.pidHash == allGather1Data[rank].peerInfo.pidHash)) { if (intraRanks == 0) intraRank0 = i; if (i == rank) intraRank = intraRanks; intraRanks++; } } TRACE(NCCL_INIT,"hostHash[%d] %lx intraRank %d intraRanks %d intraRank0 %d", rank, allGather1Data[rank].peerInfo.hostHash, intraRank, intraRanks, intraRank0); if (intraRank == -1 || intraRank0 == -1 || allGather1Data[intraRank0].comm == NULL) { WARN("Failed to determine intra ranks hostHash[%d] %lx intraRank %d intraRanks %d intraRank0 %d", rank, allGather1Data[rank].peerInfo.hostHash, intraRank, intraRanks, intraRank0); return ncclInternalError; } NCCLCHECK(ncclCommSetIntra(comm, intraRank, intraRanks, allGather1Data[intraRank0].comm)); { // [RCCL] Check if clique-based kernels can be enabled and initialize CliqueManager if so CliqueManager::cliqueMode_t cliqueMode = CliqueManager::CLIQUE_DISABLED; if (comm->localRanks == comm->nRanks) { // Check that all the GPUs have peer access to one another bool hasPeerAccess = true; for (int i = 0; i < nranks && hasPeerAccess; i++) { int cudaDev1 = allGather1Data[i].peerInfo.cudaDev; for (int j = 0; j < nranks; j++) { if (i == j) continue; int cudaDev2 = allGather1Data[j].peerInfo.cudaDev; int p2p; if (hipDeviceCanAccessPeer(&p2p, cudaDev1, cudaDev2) != hipSuccess || !p2p) { hasPeerAccess = false; break; } } } if (hasPeerAccess) { if (intraRanks == nranks) cliqueMode = CliqueManager::CLIQUE_SINGLE_PROCESS; else cliqueMode = CliqueManager::CLIQUE_SINGLE_NODE; } // For now, only enable clique-based kernels on CR8_G topologies, unless explicitly asked if (!rcclParamForceEnableClique()) { // Disable clique-kernel support if not on CR8 topology if (!(comm->topo->nodes[NET].count == 0 && comm->topo->type == RCCL_TOPO_CR8G)) { INFO(NCCL_INIT, "Disabling clique-based kernels due to topology (force enable with RCCL_FORCE_ENABLE_CLIQUE)"); cliqueMode = CliqueManager::CLIQUE_DISABLED; } } } comm->cliqueManager = new CliqueManager(rank, nranks, cliqueMode); NCCLCHECK(comm->cliqueManager->Init(commId, rootPid)); } // [/RCCL] } while(0); // Done with AllGather1 data free(allGather1Data); if (comm->nNodes) NCCLCHECK(ncclProxyCreate(comm)); // We should have allocated all buffers, collective fifos, ... we can // restore the affinity. affinity_restore: sched_setaffinity(0, sizeof(cpu_set_t), &affinitySave); if (ret != ncclSuccess) return ret; TRACE(NCCL_INIT, "rank %d nranks %d - DONE", rank, nranks); return ncclSuccess; } ncclResult_t ncclCommInitRankSync(ncclComm_t* newcomm, int nranks, ncclUniqueId commId, int myrank, int cudaDev) { ncclResult_t res; CUDACHECK(hipSetDevice(cudaDev)); NCCLCHECKGOTO(commAlloc(newcomm, nranks, myrank), res, cleanup); NCCLCHECKGOTO(initTransportsRank(*newcomm, &commId), res, cleanup); NCCLCHECKGOTO(devCommSetup(*newcomm), res, cleanup); INFO(NCCL_INIT,"comm %p rank %d nranks %d cudaDev %d busId %x - Init COMPLETE", *newcomm, myrank, nranks, (*newcomm)->cudaDev, (*newcomm)->busId); return ncclSuccess; cleanup: if ((*newcomm) && (*newcomm)->bootstrap) bootstrapAbort((*newcomm)->bootstrap); *newcomm = NULL; return res; } static ncclResult_t ncclCommInitRankDev(ncclComm_t* newcomm, int nranks, ncclUniqueId commId, int myrank, int cudaDev) { ncclResult_t res; char* env = getenv("NCCL_COMM_ID"); if (env && myrank == 0) { INFO(NCCL_ENV, "NCCL_COMM_ID set by environment to %s", env); NCCLCHECKGOTO(bootstrapCreateRoot(&commId, true), res, end); } NCCLCHECKGOTO(ncclInit(), res, end); if (myrank == 0) showVersion(); // Make sure the CUDA runtime is initialized. CUDACHECKGOTO(hipFree(NULL), res, end); NCCLCHECKGOTO(PtrCheck(newcomm, "CommInitRank", "newcomm"), res, end); if (nranks < 1 || myrank < 0 || myrank >= nranks) { WARN("Invalid rank requested : %d/%d", myrank, nranks); res = ncclInvalidArgument; goto end; } if (ncclAsyncMode()) { NCCLCHECKGOTO(ncclAsyncInit(ncclCommInitRankSync, newcomm, nranks, commId, myrank, cudaDev), res, end); } else { NCCLCHECKGOTO(ncclCommInitRankSync(newcomm, nranks, commId, myrank, cudaDev), res, end); } end: if (ncclAsyncMode()) return ncclAsyncErrCheck(res); else return res; } NCCL_API(ncclResult_t, ncclCommInitRank, ncclComm_t* newcomm, int nranks, ncclUniqueId commId, int myrank); ncclResult_t ncclCommInitRank(ncclComm_t* newcomm, int nranks, ncclUniqueId commId, int myrank) { int cudaDev; CUDACHECK(hipGetDevice(&cudaDev)); NCCLCHECK(ncclCommInitRankDev(newcomm, nranks, commId, myrank, cudaDev)); return ncclSuccess; } NCCL_API(ncclResult_t, ncclCommInitAll, ncclComm_t* comms, int ndev, const int* devlist); ncclResult_t ncclCommInitAll(ncclComm_t* comms, int ndev, const int* devlist) { NCCLCHECK(PtrCheck(comms, "CommInitAll", "comms")); if (ndev < 0) { WARN("Invalid device count requested : %d", ndev); return ncclInvalidArgument; } ncclUniqueId uniqueId; NCCLCHECK(ncclGetUniqueId(&uniqueId)); NCCLCHECK(ncclGroupStart()); for (int i=0; irank; #endif CUDACHECK(hipGetDevice(&savedDevice)); int commDevice = comm->cudaDev; if (savedDevice != commDevice) { CUDACHECK(hipSetDevice(commDevice)); } TRACE(NCCL_INIT, "Destroying comm %p rank %d abortFlag %d fatalError %d", comm, rank, LOAD(comm->abortFlag), comm->fatalError); CUDACHECK(hipStreamSynchronize(comm->groupStream)); NCCLCHECK(ncclProxyDestroy(comm)); NCCLCHECK(commFree(comm)); if (savedDevice != commDevice) CUDACHECK(hipSetDevice(savedDevice)); TRACE(NCCL_INIT, "Destroyed comm %p rank %d", comm, rank); return ncclSuccess; } NCCL_API(ncclResult_t, ncclCommDestroy, ncclComm_t comm); ncclResult_t ncclCommDestroy(ncclComm_t comm) { if (comm == NULL) return ncclSuccess; TRACE(NCCL_INIT, "comm %p rank %d nRanks %d cudaDev %d busId %x", comm, comm->rank, comm->nRanks, comm->cudaDev, comm->busId); // Try and prevent a double free of the comm struct (user error) if (comm->rank == -1 || comm->nRanks <= 0 || comm->cudaDev == -1 || comm->busId == -1) { WARN("comm %p has already been destroyed", comm); return ncclInvalidArgument; } // [RCCL] Delete CliqueManager if it exists if (comm->cliqueManager) delete comm->cliqueManager; // [/RCCL] return commDestroy(comm); } NCCL_API(ncclResult_t, ncclCommAbort, ncclComm_t comm); ncclResult_t ncclCommAbort(ncclComm_t comm) { if (comm == NULL) return ncclSuccess; // Ask anything that might still be running on the device to quit STORE(comm->abortFlag, 1); // do not destroy comm because kernel maybe still running // return commDestroy(comm); return ncclSuccess; } NCCL_API(const char*, ncclGetErrorString, ncclResult_t code); const char* ncclGetErrorString(ncclResult_t code) { switch (code) { case ncclSuccess : return "no error"; case ncclUnhandledCudaError : return "unhandled cuda error"; case ncclSystemError : return "unhandled system error"; case ncclInternalError : return "internal error"; case ncclInvalidArgument : return "invalid argument"; case ncclInvalidUsage : return "invalid usage"; default : return "unknown result code"; } } NCCL_API(ncclResult_t, ncclCommGetAsyncError, ncclComm_t comm, ncclResult_t *asyncError); ncclResult_t ncclCommGetAsyncError(ncclComm_t comm, ncclResult_t *asyncError) { NCCLCHECK(PtrCheck(comm, "ncclGetAsyncError", "comm")); NCCLCHECK(PtrCheck(asyncError, "ncclGetAsyncError", "asyncError")); *asyncError = comm->fatalError; return ncclSuccess; } NCCL_API(ncclResult_t, ncclCommCount, const ncclComm_t comm, int* count); ncclResult_t ncclCommCount(const ncclComm_t comm, int* count) { NCCLCHECK(PtrCheck(comm, "CommCount", "comm")); NCCLCHECK(PtrCheck(count, "CommCount", "count")); *count = comm->nRanks; return ncclSuccess; } NCCL_API(ncclResult_t, ncclCommCuDevice, const ncclComm_t comm, int* devid); ncclResult_t ncclCommCuDevice(const ncclComm_t comm, int* devid) { NCCLCHECK(PtrCheck(comm, "CommCuDevice", "comm")); NCCLCHECK(PtrCheck(devid, "CommCuDevice", "devid")); *devid = comm->cudaDev; return ncclSuccess; } NCCL_API(ncclResult_t, ncclCommUserRank, const ncclComm_t comm, int* rank); ncclResult_t ncclCommUserRank(const ncclComm_t comm, int* rank) { NCCLCHECK(PtrCheck(comm, "CommUserRank", "comm")); NCCLCHECK(PtrCheck(rank, "CommUserRank", "rank")); *rank = comm->rank; return ncclSuccess; }