316 satır
16 KiB
C++
316 satır
16 KiB
C++
/*************************************************************************
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* Copyright (c) 2016-2020, NVIDIA CORPORATION. All rights reserved.
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* Modifications Copyright (c) 2019-2020 Advanced Micro Devices, Inc. All rights reserved.
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*
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* See LICENSE.txt for license information
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************************************************************************/
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#include "core.h"
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#include "devcomm.h"
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#include "comm.h"
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#include "topo.h"
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NCCL_PARAM(Nthreads, "NTHREADS", -2);
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NCCL_PARAM(Ll128Nthreads, "LL128_NTHREADS", -2);
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static int getNthreads(const char* name, int env, int min, int max, int def) {
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int nt = env;
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if (nt > 0) {
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if (nt % WARP_SIZE != 0) {
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WARN("Invalid %s %d (must be a multiple of %d)", name, nt, WARP_SIZE);
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nt = max;
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} else if (nt > max) {
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WARN("Invalid %s %d (maximum %d).", name, nt, max);
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nt = max;
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} else if (nt < min) {
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WARN("Invalid %s %d (minimum %d).", name, nt, min);
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nt = min;
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}
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} else {
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nt = def;
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}
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return nt;
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}
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ncclResult_t parseList(const char* str, const char* elems[], int nelems, int* list) {
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int def, set;
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if (str[0] == '^') {
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def = 1; set = 0; str++;
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} else {
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def = 0; set = 1;
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}
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for (int i=0; i<nelems; i++) list[i] = def;
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char* tokStr = strdup(str);
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char* tmpStr;
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char* token = strtok_r(tokStr, ",", &tmpStr);
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while (token) {
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for (int i=0; i<nelems; i++)
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if (strcasecmp(token, elems[i]) == 0) list[i] = set;
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token = strtok_r(NULL, ",", &tmpStr);
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}
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free(tokStr);
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return ncclSuccess;
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}
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// Latencies in us, Bandwidths in GB/s
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// Tree { LL, LL128, Simple } , Ring { LL, LL128, Simple }
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static const float baseLat [NCCL_NUM_ALGORITHMS][NCCL_NUM_PROTOCOLS] = { { 39.0, 39.0, 49.0 }, { 21.0, 21.0, 30.0 }, { 37.9, 37.9, 40.4 } };
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// NVLink, PCI, Network
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#define NCCL_HW_NVLINK 0
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#define NCCL_HW_PCI 1
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#define NCCL_HW_NET 2
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// Tree/Simple is the latency a 256kB chunk, which is ~ base lat + 256k/12GB/s (+ 256k/12GB/s for the network).
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static const float hwLat [3][NCCL_NUM_ALGORITHMS][NCCL_NUM_PROTOCOLS] =
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{ /* NVLINK */
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{ /* Tree (LL/LL128/Simple)*/ { 2.5, 2.5, 5.5 }, /* Ring (LL/LL128/Simple)*/ { 2.5, 2.5, 5 }, /* CollNet (LL/LL128/Simple)*/ { 1.1, 1.1, 3.3 } },
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/* PCI */
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{ /* Tree (LL/LL128/Simple)*/ { 2.2, 2.2, 5.7 }, /* Ring (LL/LL128/Simple)*/ { 1.3, 1.3, 1.9 }, /* CollNet (LL/LL128/Simple)*/ { 1.1, 1.1, 1.7 } },
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/* NET */
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{ /* Tree (LL/LL128/Simple)*/ { 28.0, 28.0, 66.0 }, /* Ring (LL/LL128/Simple)*/ { 8.5, 8.5, 19.0 }, /* CollNet (LL/LL128/Simple)*/ { 6.5, 6.5, 14.5 } }
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};
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// LL128 max BW (per channel) for the different collectives
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// ncclFuncBroadcast, ncclFuncReduce, ncclFuncAllGather, ncclFuncReduceScatter, ncclFuncAllReduce
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static const double ll128MaxBwPerCh[NCCL_NUM_FUNCTIONS] = { 18.8, 12.0, 18.3, 15.2, 16.9 };
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static const double llMaxBws[2][3] = { /* Volta-N1/Intel-N2/Intel-N4) */ {39.0, 39.0, 20.4}, /* Ampere-N1/AMD-N2/AMD-N4) */ {87.7, 22.5 /*avg of ring & tree*/, 19.0} };
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static const double perChMaxTreeBws[2][3] = { /* Volta (N1/N2/N4) */ {26.5, 18.5, 10.0}, /* Ampere (N1/N2/N4) */ {24.0, 22.5, 16.0} };
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ncclResult_t ncclTopoTuneModel(struct ncclComm* comm, int minCompCap, int maxCompCap, struct ncclTopoGraph* treeGraph, struct ncclTopoGraph* ringGraph, struct ncclTopoGraph* collNetGraph) {
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int simpleDefaultThreads = (ringGraph->speedIntra*ringGraph->nChannels <= PCI_WIDTH) ? 256 : NCCL_SIMPLE_MAX_NTHREADS;
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comm->maxThreads[NCCL_ALGO_RING][NCCL_PROTO_SIMPLE] =
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#if defined(__HIP_PLATFORM_HCC__) || defined(__HCC__) || defined(__HIPCC__)
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getNthreads("NCCL_NTHREADS", ncclParamNthreads(), 4*WARP_SIZE, NCCL_MAX_NTHREADS, simpleDefaultThreads);
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comm->maxThreads[NCCL_ALGO_TREE][NCCL_PROTO_SIMPLE] = comm->maxThreads[NCCL_ALGO_COLLNET][NCCL_PROTO_SIMPLE] =
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getNthreads("NCCL_NTHREADS", ncclParamNthreads(), 4*WARP_SIZE, NCCL_MAX_NTHREADS, NCCL_MAX_NTHREADS);
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comm->maxThreads[NCCL_ALGO_RING][NCCL_PROTO_LL] = comm->maxThreads[NCCL_ALGO_TREE][NCCL_PROTO_LL] = comm->maxThreads[NCCL_ALGO_COLLNET][NCCL_PROTO_LL] =
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getNthreads("NCCL_NTHREADS", ncclParamNthreads(), 4*WARP_SIZE, NCCL_MAX_NTHREADS, NCCL_MAX_NTHREADS);
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#else
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getNthreads("NCCL_NTHREADS", ncclParamNthreads(), 2*WARP_SIZE, NCCL_SIMPLE_MAX_NTHREADS, simpleDefaultThreads);
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comm->maxThreads[NCCL_ALGO_TREE][NCCL_PROTO_SIMPLE] = comm->maxThreads[NCCL_ALGO_COLLNET][NCCL_PROTO_SIMPLE] =
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getNthreads("NCCL_NTHREADS", ncclParamNthreads(), 2*WARP_SIZE, NCCL_SIMPLE_MAX_NTHREADS, NCCL_SIMPLE_MAX_NTHREADS);
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comm->maxThreads[NCCL_ALGO_RING][NCCL_PROTO_LL] = comm->maxThreads[NCCL_ALGO_TREE][NCCL_PROTO_LL] = comm->maxThreads[NCCL_ALGO_COLLNET][NCCL_PROTO_LL] =
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getNthreads("NCCL_NTHREADS", ncclParamNthreads(), 2*WARP_SIZE, NCCL_LL_MAX_NTHREADS, NCCL_LL_MAX_NTHREADS);
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#endif
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comm->maxThreads[NCCL_ALGO_RING][NCCL_PROTO_LL128] = comm->maxThreads[NCCL_ALGO_TREE][NCCL_PROTO_LL128] = comm->maxThreads[NCCL_ALGO_COLLNET][NCCL_PROTO_LL128] =
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getNthreads("NCCL_LL128_NTHREADS", ncclParamLl128Nthreads(), NCCL_LL128_MAX_NTHREADS/4, NCCL_LL128_MAX_NTHREADS, NCCL_LL128_MAX_NTHREADS);
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int nNodes = comm->nNodes;
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int nRanks = comm->nRanks;
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if (nRanks <= 1) return ncclSuccess;
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int compCap80 = minCompCap == 80 && maxCompCap == 80 ? 1 : 0;
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int cpuArch, cpuVendor, cpuModel;
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NCCLCHECK(ncclTopoCpuType(comm->topo, &cpuArch, &cpuVendor, &cpuModel));
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int index2 = nNodes <= 2 ? nNodes-1 : 2;
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// LL: for single node, we look at GPU type; for multi-node, we look at CPU type
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int index1 = nNodes == 1 ? compCap80 : cpuVendor == NCCL_TOPO_CPU_VENDOR_AMD ? 1 : 0;
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double llMaxBw = llMaxBws[index1][index2];
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double perChMaxTreeBw = perChMaxTreeBws[compCap80][index2];
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float ppn = (float)nRanks / nNodes; // if ppn < 2, then we are sending/receiving at the same GPU through the NIC, apply some bw discount
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struct ncclTopoGraph* graphs[NCCL_NUM_ALGORITHMS] = { treeGraph, ringGraph, collNetGraph };
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int intraHw[NCCL_NUM_ALGORITHMS], hw[NCCL_NUM_ALGORITHMS];
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for (int a=0; a<NCCL_NUM_ALGORITHMS; a++) intraHw[a] = graphs[a]->typeIntra == LINK_NVL ? NCCL_HW_NVLINK : NCCL_HW_PCI;
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for (int a=0; a<NCCL_NUM_ALGORITHMS; a++) hw[a] = nNodes == 1 ? intraHw[a] : NCCL_HW_NET;
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for (int coll=0; coll<NCCL_NUM_FUNCTIONS; coll++) {
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int nsteps = coll == ncclFuncAllReduce ? 2*(nRanks-1) :
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coll == ncclFuncReduceScatter || coll == ncclFuncAllGather ? nRanks-1 :
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nRanks;
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int nInterSteps = coll == ncclFuncAllReduce ? 2*(nNodes-1) :
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coll == ncclFuncReduceScatter || coll == ncclFuncAllGather ? nNodes-1 :
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nNodes;
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for (int a=0; a<NCCL_NUM_ALGORITHMS; a++) {
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if (coll != ncclFuncAllReduce && a != NCCL_ALGO_RING) continue;
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for (int p=0; p<NCCL_NUM_PROTOCOLS; p++) {
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float speed = nNodes <= 2 || a == NCCL_ALGO_COLLNET ? graphs[a]->speedIntra : graphs[a]->speedInter;
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float busBw = graphs[a]->nChannels * speed;
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// Various model refinements
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#if defined(__HIP_PLATFORM_HCC__) || defined(__HCC__) || defined(__HIPCC__)
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if (a == NCCL_ALGO_RING && p == NCCL_PROTO_LL) busBw *= 1.0/5.0;
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if (a == NCCL_ALGO_RING && p == NCCL_PROTO_LL128) busBw = std::min(busBw * (ppn < 2 ? 0.7 : 0.92 /*120.0/128.0*/), ll128MaxBwPerCh[coll]*graphs[a]->nChannels);
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double maxTreeBw = comm->nNodes > 2 ?
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compCap80 && p == NCCL_PROTO_LL128 ? 105.0 : 80.0 :
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compCap80 && p == NCCL_PROTO_LL128 ? 130.0 : 110.0;
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if (a == NCCL_ALGO_TREE) busBw = std::min(busBw*.27, comm->nNodes > 1 ? 70.0 : 90.0);
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if (a == NCCL_ALGO_TREE && p == NCCL_PROTO_LL) busBw *= 1.0/2.3;
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if (a == NCCL_ALGO_TREE && p == NCCL_PROTO_LL128) busBw = std::min(busBw * (comm->nNodes == 1 ? 7.0/9.0 : 0.915 /*120.0/128.0*/), ll128MaxBwPerCh[coll]*graphs[a]->nChannels*7.0/9.0);
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#else
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if (compCap80) busBw = std::min(busBw, 235.0f);
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if (a == NCCL_ALGO_RING && p == NCCL_PROTO_LL) { busBw = std::min(llMaxBw, busBw * ((nNodes > 1 || coll == ncclFuncAllReduce || coll == ncclFuncReduce) ? 1.0/4.0 : 1.0/3.0)); }
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if (a == NCCL_ALGO_RING && p == NCCL_PROTO_LL128) busBw = std::min(busBw * (ppn < 2 ? 0.7 : 0.92 /*120.0/128.0*/), ll128MaxBwPerCh[coll]*graphs[a]->nChannels);
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if (a == NCCL_ALGO_TREE) busBw = std::min(busBw*.92, graphs[a]->nChannels*perChMaxTreeBw);
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if (a == NCCL_ALGO_TREE && p == NCCL_PROTO_LL) busBw = std::min(busBw*1.0/3.8, llMaxBw);
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if (a == NCCL_ALGO_TREE && p == NCCL_PROTO_LL128) busBw = std::min(busBw * (nNodes == 1 ? 7.0/9.0 : 0.915 /*120.0/128.0*/), ll128MaxBwPerCh[coll]*graphs[a]->nChannels);
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#endif
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if (a == NCCL_ALGO_COLLNET) busBw *= .9;
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if (a == NCCL_ALGO_COLLNET && p == NCCL_PROTO_LL) busBw *= 1.0/2.0; // Take into account that GDR read is disabled on both sides
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if (a == NCCL_ALGO_COLLNET && p == NCCL_PROTO_LL128) busBw = 0; // CollNet does not support LL128
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// Convert bus BW to algorithm BW
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float ratio = (a != NCCL_ALGO_RING) ? .5 : (1.0 * nRanks) / nsteps;
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comm->bandwidths[coll][a][p] = busBw * ratio;
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comm->latencies[coll][a][p] = baseLat[a][p];
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float intraLat = hwLat[intraHw[a]][a][p];
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float interLat = hwLat[NCCL_HW_NET][a][p];
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if (a == NCCL_ALGO_RING) {
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float lat = hwLat[hw[a]][a][p];
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if ((coll == ncclFuncReduce || coll == ncclFuncBroadcast)) {
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if (ringGraph->sameChannels) {
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comm->latencies[coll][a][p] += lat;
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} else {
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if (p == NCCL_PROTO_SIMPLE) lat = hwLat[hw[a]][NCCL_ALGO_TREE][p]; // Add some chunk latency, waiting for proper chunk modeling
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comm->latencies[coll][a][p] += nsteps*lat;
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}
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} else {
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comm->latencies[coll][a][p] += (nsteps-nInterSteps)*intraLat + nInterSteps*interLat;
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}
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} else if (a == NCCL_ALGO_TREE) {
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comm->latencies[coll][a][p] +=
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2 * ((nRanks/nNodes-1) * intraLat + log2i(nNodes) * interLat);
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} else {
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comm->latencies[coll][a][p] +=
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2 * (nRanks/nNodes-1) * intraLat + interLat;
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}
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}
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}
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}
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// Protocols/Algorithms enable/disable, and user overrides.
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// All are enabled except ll128 which is enabled by default only in certain cases.
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int protoEnable[NCCL_NUM_PROTOCOLS] = { 1, 2, 1 };
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int algoEnable[NCCL_NUM_ALGORITHMS] = { 1, 1, 1 };
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const char *protoStr = getenv("NCCL_PROTO");
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if (protoStr) {
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INFO(NCCL_ENV, "NCCL_PROTO set by environment to %s", protoStr);
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NCCLCHECK(parseList(protoStr, ncclProtoStr, NCCL_NUM_PROTOCOLS, protoEnable));
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}
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const char *algoStr = getenv("NCCL_ALGO");
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if (algoStr) {
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INFO(NCCL_ENV, "NCCL_ALGO set by environment to %s", algoStr);
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NCCLCHECK(parseList(algoStr, ncclAlgoStr, NCCL_NUM_ALGORITHMS, algoEnable));
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}
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// Disable CollNet if it is not supported
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if (comm->collNetSupport == 0) {
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algoEnable[NCCL_ALGO_COLLNET] = 0;
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// If user has hard set NCCL_ALGO=COLLNET, ignore it
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if (algoEnable[NCCL_ALGO_RING] == 0 && algoEnable[NCCL_ALGO_TREE] == 0) {
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algoEnable[NCCL_ALGO_RING] = algoEnable[NCCL_ALGO_TREE] = 1;
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if (comm->rank == 0) WARN("CollNet is not supported or fails to initialize, ignoring NCCL_ALGO=COLLNET");
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}
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}
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for (int c=0; c<NCCL_NUM_FUNCTIONS; c++) for (int a=0; a<NCCL_NUM_ALGORITHMS; a++) for (int p=0; p<NCCL_NUM_PROTOCOLS; p++) {
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int pEnable = protoEnable[p];
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if (pEnable == 2 && p == NCCL_PROTO_LL128) {
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// Enable LL128 by default only on Volta/Ampere+NVLink. Other cases are not tested and may cause silent data corruption.
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pEnable = (graphs[a]->typeInter <= PATH_PXB) && graphs[a]->typeIntra <= PATH_NVL &&
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((minCompCap == 70 && maxCompCap == 70) || (minCompCap == 80 && maxCompCap == 80)) ? 1 : 0;
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}
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if (pEnable == 0) comm->bandwidths[c][a][p] = 0;
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// Only disable algo for Allreduce since others only have one
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if (c == ncclFuncAllReduce && algoEnable[a] == 0) comm->bandwidths[c][a][p] = 0;
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}
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if (comm->rank == 0) {
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char line[1024];
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sprintf(line, "Latency/AlgBw |");
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for (int a=0; a<NCCL_NUM_ALGORITHMS; a++) {
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for (int p=0; p<NCCL_NUM_PROTOCOLS; p++) {
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sprintf(line+strlen(line), " %7s/%6s |", ncclAlgoStr[a], ncclProtoStr[p]);
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}
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}
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INFO(NCCL_TUNING, "%s", line);
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sprintf(line, " Max NThreads |");
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for (int a=0; a<NCCL_NUM_ALGORITHMS; a++) {
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for (int p=0; p<NCCL_NUM_PROTOCOLS; p++) {
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sprintf(line+strlen(line), " %14d |", comm->maxThreads[a][p]);
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}
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}
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INFO(NCCL_TUNING, "%s", line);
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for (int c=0; c<NCCL_NUM_FUNCTIONS; c++) {
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sprintf(line, "%13s |", ncclFuncStr[c]);
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for (int a=0; a<NCCL_NUM_ALGORITHMS; a++) {
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for (int p=0; p<NCCL_NUM_PROTOCOLS; p++) {
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sprintf(line+strlen(line), "%8.1f/%6.1f |", comm->latencies[c][a][p], comm->bandwidths[c][a][p]);
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}
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}
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INFO(NCCL_TUNING, "%s", line);
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}
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}
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// Set per-thread amount of work before we increase nThreads and nChannels
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for (int a=0; a<NCCL_NUM_ALGORITHMS; a++) {
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comm->threadThresholds[a][NCCL_PROTO_LL] = NCCL_LL_THREAD_THRESHOLD;
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comm->threadThresholds[a][NCCL_PROTO_LL128] = NCCL_LL128_THREAD_THRESHOLD;
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comm->threadThresholds[a][NCCL_PROTO_SIMPLE] = NCCL_SIMPLE_THREAD_THRESHOLD;
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}
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comm->threadThresholds[NCCL_ALGO_RING][NCCL_PROTO_LL] *= nRanks;
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// Override defaults with user env
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char* str = getenv("NCCL_THREAD_THRESHOLDS");
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if (str) {
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INFO(NCCL_ENV, "NCCL_THREAD_THRESHOLDS set by environment to %s", str);
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ssize_t t[NCCL_NUM_ALGORITHMS][NCCL_NUM_PROTOCOLS] = {{ -2, -2, -2 }, { -2, -2, -2}};
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sscanf(str, "%ld %ld %ld %ld %ld %ld", t[0], t[0]+1, t[0]+2, t[1], t[1]+1, t[1]+2);
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for (int a=0; a<NCCL_NUM_ALGORITHMS; a++) {
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for (int p=0; p<NCCL_NUM_PROTOCOLS; p++) {
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if (t[a][p] >= 0) comm->threadThresholds[a][p] = t[a][p];
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}
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}
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}
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INFO(NCCL_INIT, "threadThresholds %ld/%ld/%ld | %ld/%ld/%ld | %ld/%ld/%ld",
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comm->threadThresholds[NCCL_ALGO_TREE][NCCL_PROTO_LL],
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comm->threadThresholds[NCCL_ALGO_TREE][NCCL_PROTO_LL128],
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comm->threadThresholds[NCCL_ALGO_TREE][NCCL_PROTO_SIMPLE],
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comm->threadThresholds[NCCL_ALGO_RING][NCCL_PROTO_LL],
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comm->threadThresholds[NCCL_ALGO_RING][NCCL_PROTO_LL128],
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comm->threadThresholds[NCCL_ALGO_RING][NCCL_PROTO_SIMPLE],
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comm->threadThresholds[NCCL_ALGO_COLLNET][NCCL_PROTO_LL],
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comm->threadThresholds[NCCL_ALGO_COLLNET][NCCL_PROTO_LL128],
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comm->threadThresholds[NCCL_ALGO_COLLNET][NCCL_PROTO_SIMPLE]);
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return ncclSuccess;
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}
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// Trees are not perfectly sticking to the model for medium sizes. Applying a static correction
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// factor is not ideal but works quite well. Powers of two, 64 B to 128MB.
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static float treeCorrectionFactor[NCCL_NUM_PROTOCOLS][22] = {
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{ 1.0, 1.0, 1.0, 1.0, 1.0, 1.0, 1.0, .84, .49, .42, .60, .75, .87, .94, .94, .99, 1.0, 1.0 , 1.0 , 1.0 , 1.0 , 1.0 },
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{ 1.0, 1.0, 1.0, 1.0, 1.0, 1.0, 1.0, .84, .49, .42, .60, .75, .87, .94, .94, .99, 1.0, 1.0 , 1.0 , 1.0 , 1.0 , 1.0 },
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{ 1.0, 1.0, 1.0, 1.0, 1.0, 1.0, .41, .27, .25, .39, .46, .72, .76, .87, .92, .97, 1.0, 1.0 , 1.0 , 1.0 , 1.0 , 1.0 }
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};
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static float ringCorrectionFactor[NCCL_NUM_PROTOCOLS][22] = {
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{ 1.0, 1.0, 1.0, 1.0, 1.0, 1.0, .25, .41, .55, .56, .78, .94, 1.0, 1.0, 1.0, 1.0, 1.0, 1.0 , 1.0 , 1.0 , 1.0 , 1.0 },
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{ 1.0, 1.0, 1.0, 1.0, 1.0, 1.0, .25, .41, .55, .56, .78, .94, 1.0, 1.0, 1.0, 1.0, 1.0, 1.0 , 1.0 , 1.0 , 1.0 , 1.0 },
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{ 1.0, 1.0, 1.0, 1.0, 1.0, 1.0, .04, .08, .09, .09, .11, .13, .25, .40, .59, .76, .86, 1.0 , 1.0 , 1.0 , 1.0 , 1.0 }
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};
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ncclResult_t ncclTopoGetAlgoTime(struct ncclInfo* info, int algorithm, int protocol, float* time) {
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float bw = info->comm->bandwidths[info->coll][algorithm][protocol];
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float lat = info->comm->latencies[info->coll][algorithm][protocol];
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if (bw == 0) {
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*time = -1.0; return ncclSuccess;
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}
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int logSize = log2i(info->nBytes>>6);
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#if defined(__HIP_PLATFORM_HCC__) || defined(__HCC__) || defined(__HIPCC__)
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if (algorithm == NCCL_ALGO_TREE && logSize < 22) bw *= treeCorrectionFactor[protocol][logSize];
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else if (algorithm == NCCL_ALGO_RING && logSize < 22) bw *= ringCorrectionFactor[protocol][logSize];
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#else
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if (algorithm == NCCL_ALGO_TREE && logSize < 23) bw *= treeCorrectionFactor[protocol][logSize];
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if (info->nChannels != 0) bw = bw / info->comm->nChannels * info->nChannels;
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if (algorithm == NCCL_ALGO_RING && protocol == NCCL_PROTO_SIMPLE && info->comm->nNodes > 1
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&& info->coll == ncclFuncAllReduce && info->nBytes >= info->comm->nRanks/16.0*65536) lat *= 1.9; // Plateau effect of ring
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#endif
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*time = lat + (info->nBytes) / (1000 * bw);
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return ncclSuccess;
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}
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