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Commit 9484fd1c authored by xiabo's avatar xiabo
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Adapt to 0.1.0

parent 477f2db8
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Showing with 2119 additions and 2037 deletions
src/turbomind/utils/cublasMMWrapper.cc
View file @ 9484fd1c
......@@ -185,124 +185,126 @@ void cublasMMWrapper::Gemm(cublasOperation_t transa,
cublasLtMatmulAlgo_info info = cublas_algo_map_->getAlgo(batch_count, m, n, k, getCublasDataType(Atype_));
if (findAlgo) {
if (info.stages != -1) {
using_cublasLt = true;
}
else {
using_cublasLt = false;
}
}
if (using_cublasLt) {
cublasLtMatmulDesc_t operationDesc = NULL;
cublasLtMatrixLayout_t Adesc = NULL, Bdesc = NULL, Cdesc = NULL;
cudaDataType_t scaleType;
#if (CUDART_VERSION >= 11000)
cublasComputeType_t computeType;
#else
cudaDataType_t computeType;
#endif
if (is_fp16_computeType) {
#if (CUDART_VERSION >= 11000)
computeType = CUBLAS_COMPUTE_16F;
#else
computeType = CUDA_R_16F;
#endif
scaleType = CUDA_R_16F;
}
else {
#if (CUDART_VERSION >= 11000)
computeType = CUBLAS_COMPUTE_32F;
#else
computeType = CUDA_R_32F;
#endif
scaleType = CUDA_R_32F;
}
// --------------------------------------
// Create descriptors for the original matrices
cublasLtMatrixLayoutCreate(&Adesc, Atype_, transa == CUBLAS_OP_N ? m : k, transa == CUBLAS_OP_N ? k : m, lda);
cublasLtMatrixLayoutCreate(&Bdesc, Btype_, transb == CUBLAS_OP_N ? k : n, transb == CUBLAS_OP_N ? n : k, ldb);
cublasLtMatrixLayoutCreate(&Cdesc, Ctype_, m, n, ldc);
#if (CUDART_VERSION >= 11000)
cublasLtMatmulDescCreate(&operationDesc, computeType, scaleType);
#else
cublasLtMatmulDescCreate(&operationDesc, computeType);
#endif
cublasLtMatmulDescSetAttribute(operationDesc, CUBLASLT_MATMUL_DESC_TRANSA, &transa, sizeof(cublasOperation_t));
cublasLtMatmulDescSetAttribute(operationDesc, CUBLASLT_MATMUL_DESC_TRANSB, &transb, sizeof(cublasOperation_t));
cublasLtMatmulAlgo_t algo;
void* workSpace = cublas_workspace_;
int workspaceSize = cublas_workspace_ == NULL ? 0 : CUBLAS_WORKSPACE_SIZE;
if (findAlgo) {
if (info.workspaceSize > workspaceSize) {
findAlgo = 0;
}
else {
cublasLtMatmulAlgoInit(
cublaslt_handle_, computeType, scaleType, Atype_, Btype_, Ctype_, Ctype_, info.algoId, &algo);
cublasLtMatmulAlgoConfigSetAttribute(
&algo, CUBLASLT_ALGO_CONFIG_CUSTOM_OPTION, &(info.customOption), sizeof(info.customOption));
cublasLtMatmulAlgoConfigSetAttribute(
&algo, CUBLASLT_ALGO_CONFIG_TILE_ID, &(info.tile), sizeof(info.tile));
cublasLtMatmulAlgoConfigSetAttribute(
&algo, CUBLASLT_ALGO_CONFIG_SPLITK_NUM, &(info.splitK_val), sizeof(info.splitK_val));
cublasLtMatmulAlgoConfigSetAttribute(
&algo, CUBLASLT_ALGO_CONFIG_CTA_SWIZZLING, &(info.swizzle), sizeof(info.swizzle));
cublasLtMatmulAlgoConfigSetAttribute(&algo,
CUBLASLT_ALGO_CONFIG_REDUCTION_SCHEME,
&(info.reductionScheme),
sizeof(info.reductionScheme));
#if (CUDART_VERSION >= 11000)
cublasLtMatmulAlgoConfigSetAttribute(
&algo, CUBLASLT_ALGO_CONFIG_STAGES_ID, &(info.stages), sizeof(info.stages));
#endif
#if (CUBLAS_VER_MAJOR == 11 && CUBLAS_VER_MINOR == 11 && CUBLAS_VER_PATCH >= 3)
cublasLtMatmulAlgoConfigSetAttribute(
&algo, CUBLASLT_ALGO_CONFIG_INNER_SHAPE_ID, &(info.inner_shapeId), sizeof(info.inner_shapeId));
cublasLtMatmulAlgoConfigSetAttribute(&algo,
CUBLASLT_ALGO_CONFIG_CLUSTER_SHAPE_ID,
&(info.cluster_shapeId),
sizeof(info.cluster_shapeId));
#elif (CUBLAS_VER_MAJOR == 11 && CUBLAS_VER_MINOR == 11 && CUBLAS_VER_PATCH < 3)
cublasLtMatmulAlgoConfigSetAttribute(
&algo, CUBLASLT_ALGO_CONFIG_MMA_SHAPE_ID, &(info.mma_shapeId), sizeof(info.mma_shapeId));
cublasLtMatmulAlgoConfigSetAttribute(
&algo, CUBLASLT_ALGO_CONFIG_CGA_SHAPE_ID, &(info.cga_shapeId), sizeof(info.cga_shapeId));
cublasLtMatmulAlgoConfigSetAttribute(
&algo, CUBLASLT_ALGO_CONFIG_SCHEDULING_MODE, &(info.sche_mode), sizeof(info.sche_mode));
#endif
using_cublasLt = false;
}
}
cublasLtMatmul(cublaslt_handle_,
operationDesc,
alpha,
A,
Adesc,
B,
Bdesc,
beta,
C,
Cdesc,
C,
Cdesc,
(findAlgo == 1 ? (&algo) : NULL),
workSpace,
workspaceSize,
stream_);
cublasLtMatmulDescDestroy(operationDesc);
cublasLtMatrixLayoutDestroy(Adesc);
cublasLtMatrixLayoutDestroy(Bdesc);
cublasLtMatrixLayoutDestroy(Cdesc);
sync_check_cuda_error();
}
else {
// if (using_cublasLt) {
// if (0) {
// cublasLtMatmulDesc_t operationDesc = NULL;
// cublasLtMatrixLayout_t Adesc = NULL, Bdesc = NULL, Cdesc = NULL;
// cudaDataType_t scaleType;
// #if (CUDART_VERSION >= 11000)
// cublasComputeType_t computeType;
// #else
// cudaDataType_t computeType;
// #endif
// if (is_fp16_computeType) {
// #if (CUDART_VERSION >= 11000)
// computeType = CUBLAS_COMPUTE_16F;
// #else
// computeType = CUDA_R_16F;
// #endif
// scaleType = CUDA_R_16F;
// }
// else {
// #if (CUDART_VERSION >= 11000)
// computeType = CUBLAS_COMPUTE_32F;
// #else
// computeType = CUDA_R_32F;
// #endif
// scaleType = CUDA_R_32F;
// }
// // --------------------------------------
// // Create descriptors for the original matrices
// cublasLtMatrixLayoutCreate(&Adesc, Atype_, transa == CUBLAS_OP_N ? m : k, transa == CUBLAS_OP_N ? k : m, lda);
// cublasLtMatrixLayoutCreate(&Bdesc, Btype_, transb == CUBLAS_OP_N ? k : n, transb == CUBLAS_OP_N ? n : k, ldb);
// cublasLtMatrixLayoutCreate(&Cdesc, Ctype_, m, n, ldc);
// #if (CUDART_VERSION >= 11000)
// cublasLtMatmulDescCreate(&operationDesc, computeType, scaleType);
// #else
// cublasLtMatmulDescCreate(&operationDesc, computeType);
// #endif
// cublasLtMatmulDescSetAttribute(operationDesc, CUBLASLT_MATMUL_DESC_TRANSA, &transa, sizeof(cublasOperation_t));
// cublasLtMatmulDescSetAttribute(operationDesc, CUBLASLT_MATMUL_DESC_TRANSB, &transb, sizeof(cublasOperation_t));
// cublasLtMatmulAlgo_t algo;
// void* workSpace = cublas_workspace_;
// int workspaceSize = cublas_workspace_ == NULL ? 0 : CUBLAS_WORKSPACE_SIZE;
// if (findAlgo) {
// if (info.workspaceSize > workspaceSize) {
// findAlgo = 0;
// }
// else {
// cublasLtMatmulAlgoInit(
// cublaslt_handle_, computeType, scaleType, Atype_, Btype_, Ctype_, Ctype_, info.algoId, &algo);
// cublasLtMatmulAlgoConfigSetAttribute(
// &algo, CUBLASLT_ALGO_CONFIG_CUSTOM_OPTION, &(info.customOption), sizeof(info.customOption));
// cublasLtMatmulAlgoConfigSetAttribute(
// &algo, CUBLASLT_ALGO_CONFIG_TILE_ID, &(info.tile), sizeof(info.tile));
// cublasLtMatmulAlgoConfigSetAttribute(
// &algo, CUBLASLT_ALGO_CONFIG_SPLITK_NUM, &(info.splitK_val), sizeof(info.splitK_val));
// cublasLtMatmulAlgoConfigSetAttribute(
// &algo, CUBLASLT_ALGO_CONFIG_CTA_SWIZZLING, &(info.swizzle), sizeof(info.swizzle));
// cublasLtMatmulAlgoConfigSetAttribute(&algo,
// CUBLASLT_ALGO_CONFIG_REDUCTION_SCHEME,
// &(info.reductionScheme),
// sizeof(info.reductionScheme));
// // #if (CUDART_VERSION >= 11000)
// // cublasLtMatmulAlgoConfigSetAttribute(
// // &algo, CUBLASLT_ALGO_CONFIG_STAGES_ID, &(info.stages), sizeof(info.stages));
// // #endif
// #if (CUBLAS_VER_MAJOR == 11 && CUBLAS_VER_MINOR == 11 && CUBLAS_VER_PATCH >= 3)
// cublasLtMatmulAlgoConfigSetAttribute(
// &algo, CUBLASLT_ALGO_CONFIG_INNER_SHAPE_ID, &(info.inner_shapeId), sizeof(info.inner_shapeId));
// cublasLtMatmulAlgoConfigSetAttribute(&algo,
// CUBLASLT_ALGO_CONFIG_CLUSTER_SHAPE_ID,
// &(info.cluster_shapeId),
// sizeof(info.cluster_shapeId));
// #elif (CUBLAS_VER_MAJOR == 11 && CUBLAS_VER_MINOR == 11 && CUBLAS_VER_PATCH < 3)
// cublasLtMatmulAlgoConfigSetAttribute(
// &algo, CUBLASLT_ALGO_CONFIG_MMA_SHAPE_ID, &(info.mma_shapeId), sizeof(info.mma_shapeId));
// cublasLtMatmulAlgoConfigSetAttribute(
// &algo, CUBLASLT_ALGO_CONFIG_CGA_SHAPE_ID, &(info.cga_shapeId), sizeof(info.cga_shapeId));
// cublasLtMatmulAlgoConfigSetAttribute(
// &algo, CUBLASLT_ALGO_CONFIG_SCHEDULING_MODE, &(info.sche_mode), sizeof(info.sche_mode));
// #endif
// }
// }
// // cublasLtMatmul(cublaslt_handle_,
// // operationDesc,
// // alpha,
// // A,
// // Adesc,
// // B,
// // Bdesc,
// // beta,
// // C,
// // Cdesc,
// // C,
// // Cdesc,
// // (findAlgo == 1 ? (&algo) : NULL),
// // workSpace,
// // workspaceSize,
// // stream_);
// cublasLtMatmulDescDestroy(operationDesc);
// cublasLtMatrixLayoutDestroy(Adesc);
// cublasLtMatrixLayoutDestroy(Bdesc);
// cublasLtMatrixLayoutDestroy(Cdesc);
// sync_check_cuda_error();
// }
// else {
int cublasAlgo = info.algoId;
check_cuda_error(cublasGemmEx(cublas_handle_,
transa,
......@@ -324,7 +326,7 @@ void cublasMMWrapper::Gemm(cublasOperation_t transa,
computeType_,
static_cast<cublasGemmAlgo_t>(cublasAlgo)));
sync_check_cuda_error();
}
// }
mu_->unlock();
}
......@@ -341,7 +343,7 @@ void cublasMMWrapper::setFP16GemmConfig()
Atype_ = CUDA_R_16F;
Btype_ = CUDA_R_16F;
Ctype_ = CUDA_R_16F;
computeType_ = CUDA_R_32F;
computeType_ = CUDA_R_16F;
}
#ifdef ENABLE_BF16
......@@ -381,81 +383,81 @@ CublasDataType cublasMMWrapper::getCublasDataType(cudaDataType_t data_type)
return FLOAT_DATATYPE;
}
#if (CUDART_VERSION >= 11000)
// input, weight, output are row-major
// only works for cublas 11.x
void cublasMMWrapper::Gemm(cublasOperation_t transa,
cublasOperation_t transb,
const int m,
const int n,
const int k,
const void* A,
const int lda,
const void* B,
const int ldb,
const void* bias,
void* C,
const int ldc)
{
TM_LOG_DEBUG(__PRETTY_FUNCTION__);
cudaDataType_t Atype, Btype, Ctype;
cublasComputeType_t computeType;
cudaDataType_t scaleType;
float alpha_float = 1.0f;
float beta_float = 0.0f;
half alpha_half = half(1.0f);
half beta_half = half(0.0f);
void * alpha, *beta;
// int is_fp16_computeType = computeType_ == CUDA_R_16F ? 1 : 0;
if (Atype_ == CUDA_R_32F) {
computeType = CUBLAS_COMPUTE_32F_FAST_TF32;
Atype = CUDA_R_32F;
Btype = CUDA_R_32F;
Ctype = CUDA_R_32F;
scaleType = CUDA_R_32F;
alpha = &alpha_float;
beta = &beta_float;
}
else if (Atype_ == CUDA_R_16BF) {
computeType = CUBLAS_COMPUTE_32F_FAST_TF32;
Atype = CUDA_R_16BF;
Btype = CUDA_R_16BF;
Ctype = CUDA_R_16BF;
scaleType = CUDA_R_32F;
alpha = &alpha_float;
beta = &beta_float;
}
else {
computeType = CUBLAS_COMPUTE_16F;
Atype = CUDA_R_16F;
Btype = CUDA_R_16F;
Ctype = CUDA_R_16F;
scaleType = CUDA_R_16F;
alpha = &alpha_half;
beta = &beta_half;
}
cublasLtMatmulDesc_t operationDesc = NULL;
cublasLtMatrixLayout_t Adesc = NULL, Bdesc = NULL, Cdesc = NULL;
cublasLtEpilogue_t epi = CUBLASLT_EPILOGUE_BIAS;
cublasLtMatrixLayoutCreate(&Adesc, Atype, (transa == CUBLAS_OP_N) ? m : k, (transa == CUBLAS_OP_N) ? k : m, lda);
cublasLtMatrixLayoutCreate(&Bdesc, Btype, (transb == CUBLAS_OP_N) ? k : n, (transb == CUBLAS_OP_N) ? n : k, ldb);
cublasLtMatrixLayoutCreate(&Cdesc, Ctype, m, n, ldc);
cublasLtMatmulDescCreate(&operationDesc, computeType, scaleType);
cublasLtMatmulDescSetAttribute(operationDesc, CUBLASLT_MATMUL_DESC_TRANSA, &transa, sizeof(cublasOperation_t));
cublasLtMatmulDescSetAttribute(operationDesc, CUBLASLT_MATMUL_DESC_TRANSB, &transb, sizeof(cublasOperation_t));
cublasLtMatmulDescSetAttribute(operationDesc, CUBLASLT_MATMUL_DESC_EPILOGUE, &epi, sizeof(cublasLtEpilogue_t));
cublasLtMatmulDescSetAttribute(operationDesc, CUBLASLT_MATMUL_DESC_BIAS_POINTER, &bias, sizeof(const void*));
check_cuda_error(cublasLtMatmul(
cublaslt_handle_, operationDesc, alpha, A, Adesc, B, Bdesc, beta, C, Cdesc, C, Cdesc, NULL, NULL, 0, stream_));
cublasLtMatrixLayoutDestroy(Adesc);
cublasLtMatrixLayoutDestroy(Bdesc);
cublasLtMatrixLayoutDestroy(Cdesc);
cublasLtMatmulDescDestroy(operationDesc);
}
#endif
// #if (CUDART_VERSION >= 11000)
// // input, weight, output are row-major
// // only works for cublas 11.x
// void cublasMMWrapper::Gemm(cublasOperation_t transa,
// cublasOperation_t transb,
// const int m,
// const int n,
// const int k,
// const void* A,
// const int lda,
// const void* B,
// const int ldb,
// const void* bias,
// void* C,
// const int ldc)
// {
// TM_LOG_DEBUG(__PRETTY_FUNCTION__);
// cudaDataType_t Atype, Btype, Ctype;
// cublasComputeType_t computeType;
// cudaDataType_t scaleType;
// float alpha_float = 1.0f;
// float beta_float = 0.0f;
// half alpha_half = half(1.0f);
// half beta_half = half(0.0f);
// void * alpha, *beta;
// // int is_fp16_computeType = computeType_ == CUDA_R_16F ? 1 : 0;
// if (Atype_ == CUDA_R_32F) {
// computeType = CUBLAS_COMPUTE_32F_FAST_TF32;
// Atype = CUDA_R_32F;
// Btype = CUDA_R_32F;
// Ctype = CUDA_R_32F;
// scaleType = CUDA_R_32F;
// alpha = &alpha_float;
// beta = &beta_float;
// }
// else if (Atype_ == CUDA_R_16BF) {
// computeType = CUBLAS_COMPUTE_32F_FAST_TF32;
// Atype = CUDA_R_16BF;
// Btype = CUDA_R_16BF;
// Ctype = CUDA_R_16BF;
// scaleType = CUDA_R_32F;
// alpha = &alpha_float;
// beta = &beta_float;
// }
// else {
// computeType = CUBLAS_COMPUTE_16F;
// Atype = CUDA_R_16F;
// Btype = CUDA_R_16F;
// Ctype = CUDA_R_16F;
// scaleType = CUDA_R_16F;
// alpha = &alpha_half;
// beta = &beta_half;
// }
// cublasLtMatmulDesc_t operationDesc = NULL;
// cublasLtMatrixLayout_t Adesc = NULL, Bdesc = NULL, Cdesc = NULL;
// cublasLtEpilogue_t epi = CUBLASLT_EPILOGUE_BIAS;
// cublasLtMatrixLayoutCreate(&Adesc, Atype, (transa == CUBLAS_OP_N) ? m : k, (transa == CUBLAS_OP_N) ? k : m, lda);
// cublasLtMatrixLayoutCreate(&Bdesc, Btype, (transb == CUBLAS_OP_N) ? k : n, (transb == CUBLAS_OP_N) ? n : k, ldb);
// cublasLtMatrixLayoutCreate(&Cdesc, Ctype, m, n, ldc);
// cublasLtMatmulDescCreate(&operationDesc, computeType, scaleType);
// cublasLtMatmulDescSetAttribute(operationDesc, CUBLASLT_MATMUL_DESC_TRANSA, &transa, sizeof(cublasOperation_t));
// cublasLtMatmulDescSetAttribute(operationDesc, CUBLASLT_MATMUL_DESC_TRANSB, &transb, sizeof(cublasOperation_t));
// cublasLtMatmulDescSetAttribute(operationDesc, CUBLASLT_MATMUL_DESC_EPILOGUE, &epi, sizeof(cublasLtEpilogue_t));
// cublasLtMatmulDescSetAttribute(operationDesc, CUBLASLT_MATMUL_DESC_BIAS_POINTER, &bias, sizeof(const void*));
// // check_cuda_error(cublasLtMatmul(
// // cublaslt_handle_, operationDesc, alpha, A, Adesc, B, Bdesc, beta, C, Cdesc, C, Cdesc, NULL, NULL, 0, stream_));
// cublasLtMatrixLayoutDestroy(Adesc);
// cublasLtMatrixLayoutDestroy(Bdesc);
// cublasLtMatrixLayoutDestroy(Cdesc);
// cublasLtMatmulDescDestroy(operationDesc);
// }
// #endif
void cublasMMWrapper::setStream(cudaStream_t stream)
{
stream_ = stream;
......@@ -985,7 +987,8 @@ void cublasMMWrapper::_Int8Gemm(const int m,
* - 0: int8 * int8 -> int32 -> int8
* - 1: int8 * int8 -> int32 -> int32
*/
#if (CUBLAS_VERSION) <= 11601
// #if (CUBLAS_VERSION) <= 11601
#if 1
FT_CHECK_WITH_INFO(false, "CUBLAS version too low.");
#else
......
src/turbomind/utils/cublasMMWrapper.h
View file @ 9484fd1c
......@@ -207,20 +207,20 @@ public:
CublasDataType getCublasDataType(cudaDataType_t data_type);
#if (CUDART_VERSION >= 11000)
void Gemm(cublasOperation_t transa,
cublasOperation_t transb,
const int m,
const int n,
const int k,
const void* A,
const int lda,
const void* B,
const int ldb,
const void* bias,
void* C,
const int ldc);
#endif
// #if (CUDART_VERSION >= 11000)
// void Gemm(cublasOperation_t transa,
// cublasOperation_t transb,
// const int m,
// const int n,
// const int k,
// const void* A,
// const int lda,
// const void* B,
// const int ldb,
// const void* bias,
// void* C,
// const int ldc);
// #endif
void stridedBatchedGemm(cublasOperation_t transa,
cublasOperation_t transb,
......
src/turbomind/utils/cuda_type_utils.cuh
View file @ 9484fd1c
......@@ -322,7 +322,7 @@ __device__ inline int8_t cuda_cast<int8_t, half>(half val)
int16_t int16_in;
};
fp16 = val;
asm volatile("cvt.rni.sat.s8.f16 %0, %1;" : "=h"(int16) : "h"(int16_in));
// asm volatile("cvt.rni.sat.s8.f16 %0, %1;" : "=h"(int16) : "h"(int16_in));
return int8[0];
}
......@@ -333,20 +333,31 @@ __device__ inline int16_t cuda_cast<int16_t, half2>(half2 val)
int8_t int8[2];
int16_t int16;
};
int8[0] = cuda_cast<int8_t>(val.x);
int8[1] = cuda_cast<int8_t>(val.y);
// int8[0] = cuda_cast<int8_t>(val.x);
// int8[1] = cuda_cast<int8_t>(val.y);
int8[0] = cuda_cast<int8_t>((val.data[0]));
int8[1] = cuda_cast<int8_t>((val.data[1]));
return int16;
}
template<>
__device__ inline int8_t cuda_cast<int8_t, float>(float val)
{
union {
int8_t int8[2];
int16_t int16;
};
asm volatile("cvt.rni.sat.s8.f32 %0, %1;" : "=h"(int16) : "f"(val));
return int8[0];
// union {
// int8_t int8[2];
// int16_t int16;
// };
// asm volatile("cvt.rni.sat.s8.f32 %0, %1;" : "=h"(int16) : "f"(val));
// return int8[0];
int8_t dst;
if (val >= 128){
dst = 127;
}else if (val < -128){
dst = -128;
}else{
dst = static_cast<int8_t>(val);
}
return dst;
}
template<>
......@@ -528,7 +539,8 @@ __device__ inline To cuda_max(Ti val)
template<>
__device__ inline half cuda_max(half2 val)
{
return (val.x > val.y) ? val.x : val.y;
// return (val.x > val.y) ? val.x : val.y;
return (val.data[0] > val.data[1]) ? val.data[0] : val.data[1];
}
#ifdef ENABLE_BF16
template<>
......
src/turbomind/utils/custom_ar_comm.cc
View file @ 9484fd1c
......@@ -152,17 +152,17 @@ void initCustomAllReduceComm(std::vector<std::shared_ptr<AbstractCustomComm>>* c
return;
}
#if defined(CUDART_VERSION) && CUDART_VERSION >= 11020
for (size_t i = 0; i < rank_size; i++) {
custom_all_reduce_comms->push_back(std::make_shared<CustomAllReduceComm<T>>(rank_size, i));
}
custom_all_reduce_comms->at(0)->allocateAndExchangePeerAccessPointer(custom_all_reduce_comms);
#else
// #if defined(CUDART_VERSION) && CUDART_VERSION >= 11020
// for (size_t i = 0; i < rank_size; i++) {
// custom_all_reduce_comms->push_back(std::make_shared<CustomAllReduceComm<T>>(rank_size, i));
// }
// custom_all_reduce_comms->at(0)->allocateAndExchangePeerAccessPointer(custom_all_reduce_comms);
// #else
TM_LOG_WARNING("Custom All Reduce is not supported before CUDA 11.2. Using NCCL as Comm.");
for (size_t i = 0; i < rank_size; i++) {
custom_all_reduce_comms->push_back(nullptr);
}
#endif
// #endif
}
// Template instantiation
......
src/turbomind/utils/gemm.cc
View file @ 9484fd1c
......@@ -26,7 +26,7 @@ Gemm::Gemm(IAllocator* allocator, cudaStream_t stream, std::string config_file)
stream_ = stream;
mutex_ = new std::mutex(); // mutex per process
check_cuda_error(cublasCreate(&cublas_handle_));
check_cuda_error(cublasLtCreate(&cublaslt_handle_));
// check_cuda_error(cublasLtCreate(&cublaslt_handle_));
check_cuda_error(cublasSetStream(cublas_handle_, stream));
if (allocator_ != nullptr) {
......@@ -41,7 +41,7 @@ Gemm::~Gemm()
allocator_->free((void**)(&workspace_));
allocator_ = nullptr;
}
cublasLtDestroy(cublaslt_handle_);
// cublasLtDestroy(cublaslt_handle_);
cublasDestroy(cublas_handle_);
delete cublas_algo_map_;
delete mutex_;
......@@ -248,7 +248,8 @@ void Gemm::gemm(const GemmOp transa,
mutex_->lock();
// Use cublas as default in FP32 and cublasLt as default in FP16
bool is_fp16_compute_type = compute_type_ == TYPE_FP16;
bool using_cublasLt = Atype == TYPE_FP16;
// bool using_cublasLt = Atype == TYPE_FP16;
bool using_cublasLt = (Atype == TYPE_FP16) ? false : false;
int batch_count = 1;
half h_alpha = (half)alpha;
......@@ -267,82 +268,83 @@ void Gemm::gemm(const GemmOp transa,
using_cublasLt = (info.stages != -1);
}
if (using_cublasLt) {
const size_t a_rows = (a_op == getCublasOperation(GEMM_OP_N)) ? _m : k;
const size_t a_cols = (a_op == getCublasOperation(GEMM_OP_N)) ? k : _m;
const size_t b_rows = (b_op == getCublasOperation(GEMM_OP_N)) ? k : _n;
const size_t b_cols = (b_op == getCublasOperation(GEMM_OP_N)) ? _n : k;
cublasLtMatmulDesc_t matmul_desc = NULL;
cublasLtMatrixLayout_t a_desc = NULL, b_desc = NULL, c_desc = NULL;
cudaDataType_t scale_type = getCublasDataType(compute_type_);
auto compute_type = getCublasComputeType(compute_type_);
// --------------------------------------
// Create descriptors for the original matrices
cublasLtMatrixLayoutCreate(&a_desc, a_type, a_rows, a_cols, _lda);
cublasLtMatrixLayoutCreate(&b_desc, b_type, b_rows, b_cols, _ldb);
cublasLtMatrixLayoutCreate(&c_desc, c_type, _m, _n, ldc);
#if (CUDART_VERSION >= 11000)
cublasLtMatmulDescCreate(&matmul_desc, compute_type, scale_type);
#else
cublasLtMatmulDescCreate(&matmul_desc, compute_type);
#endif
cublasLtMatmulDescSetAttribute(matmul_desc, CUBLASLT_MATMUL_DESC_TRANSA, &a_op, sizeof(cublasOperation_t));
cublasLtMatmulDescSetAttribute(matmul_desc, CUBLASLT_MATMUL_DESC_TRANSB, &b_op, sizeof(cublasOperation_t));
cublasLtMatmulAlgo_t algo;
void* workspace = workspace_;
int workspace_size = workspace_ == nullptr ? 0 : CUBLAS_WORKSPACE_SIZE;
if (findAlgo) {
if (info.workspaceSize > workspace_size) {
findAlgo = 0;
}
else {
cublasLtMatmulAlgoInit(
cublaslt_handle_, compute_type, scale_type, a_type, b_type, c_type, c_type, info.algoId, &algo);
cublasLtMatmulAlgoConfigSetAttribute(
&algo, CUBLASLT_ALGO_CONFIG_CUSTOM_OPTION, &(info.customOption), sizeof(info.customOption));
cublasLtMatmulAlgoConfigSetAttribute(
&algo, CUBLASLT_ALGO_CONFIG_TILE_ID, &(info.tile), sizeof(info.tile));
cublasLtMatmulAlgoConfigSetAttribute(
&algo, CUBLASLT_ALGO_CONFIG_SPLITK_NUM, &(info.splitK_val), sizeof(info.splitK_val));
cublasLtMatmulAlgoConfigSetAttribute(
&algo, CUBLASLT_ALGO_CONFIG_CTA_SWIZZLING, &(info.swizzle), sizeof(info.swizzle));
cublasLtMatmulAlgoConfigSetAttribute(
&algo, CUBLASLT_ALGO_CONFIG_REDUCTION_SCHEME, &(info.reductionScheme), sizeof(int));
#if (CUDART_VERSION >= 11000)
cublasLtMatmulAlgoConfigSetAttribute(
&algo, CUBLASLT_ALGO_CONFIG_STAGES_ID, &(info.stages), sizeof(info.stages));
#endif
}
}
// if (using_cublasLt) {
// if(0) {
// const size_t a_rows = (a_op == getCublasOperation(GEMM_OP_N)) ? _m : k;
// const size_t a_cols = (a_op == getCublasOperation(GEMM_OP_N)) ? k : _m;
// const size_t b_rows = (b_op == getCublasOperation(GEMM_OP_N)) ? k : _n;
// const size_t b_cols = (b_op == getCublasOperation(GEMM_OP_N)) ? _n : k;
// cublasLtMatmulDesc_t matmul_desc = NULL;
// cublasLtMatrixLayout_t a_desc = NULL, b_desc = NULL, c_desc = NULL;
// cudaDataType_t scale_type = getCublasDataType(compute_type_);
// auto compute_type = getCublasComputeType(compute_type_);
// // --------------------------------------
// // Create descriptors for the original matrices
// cublasLtMatrixLayoutCreate(&a_desc, a_type, a_rows, a_cols, _lda);
// cublasLtMatrixLayoutCreate(&b_desc, b_type, b_rows, b_cols, _ldb);
// cublasLtMatrixLayoutCreate(&c_desc, c_type, _m, _n, ldc);
// #if (CUDART_VERSION >= 11000)
// cublasLtMatmulDescCreate(&matmul_desc, compute_type, scale_type);
// #else
// cublasLtMatmulDescCreate(&matmul_desc, compute_type);
// #endif
// cublasLtMatmulDescSetAttribute(matmul_desc, CUBLASLT_MATMUL_DESC_TRANSA, &a_op, sizeof(cublasOperation_t));
// cublasLtMatmulDescSetAttribute(matmul_desc, CUBLASLT_MATMUL_DESC_TRANSB, &b_op, sizeof(cublasOperation_t));
// cublasLtMatmulAlgo_t algo;
// void* workspace = workspace_;
// int workspace_size = workspace_ == nullptr ? 0 : CUBLAS_WORKSPACE_SIZE;
// if (findAlgo) {
// if (info.workspaceSize > workspace_size) {
// findAlgo = 0;
// }
// else {
// cublasLtMatmulAlgoInit(
// cublaslt_handle_, compute_type, scale_type, a_type, b_type, c_type, c_type, info.algoId, &algo);
// cublasLtMatmulAlgoConfigSetAttribute(
// &algo, CUBLASLT_ALGO_CONFIG_CUSTOM_OPTION, &(info.customOption), sizeof(info.customOption));
// cublasLtMatmulAlgoConfigSetAttribute(
// &algo, CUBLASLT_ALGO_CONFIG_TILE_ID, &(info.tile), sizeof(info.tile));
// cublasLtMatmulAlgoConfigSetAttribute(
// &algo, CUBLASLT_ALGO_CONFIG_SPLITK_NUM, &(info.splitK_val), sizeof(info.splitK_val));
// cublasLtMatmulAlgoConfigSetAttribute(
// &algo, CUBLASLT_ALGO_CONFIG_CTA_SWIZZLING, &(info.swizzle), sizeof(info.swizzle));
// cublasLtMatmulAlgoConfigSetAttribute(
// &algo, CUBLASLT_ALGO_CONFIG_REDUCTION_SCHEME, &(info.reductionScheme), sizeof(int));
// #if (CUDART_VERSION >= 11000)
// cublasLtMatmulAlgoConfigSetAttribute(
// &algo, CUBLASLT_ALGO_CONFIG_STAGES_ID, &(info.stages), sizeof(info.stages));
// #endif
// }
// }
cublasLtMatmul(cublaslt_handle_,
matmul_desc,
alpha_ptr,
a_data_ptr,
a_desc,
b_data_ptr,
b_desc,
beta_ptr,
C,
c_desc,
C,
c_desc,
(findAlgo == 1 ? (&algo) : NULL),
workspace,
workspace_size,
stream_);
cublasLtMatmulDescDestroy(matmul_desc);
cublasLtMatrixLayoutDestroy(a_desc);
cublasLtMatrixLayoutDestroy(b_desc);
cublasLtMatrixLayoutDestroy(c_desc);
sync_check_cuda_error();
}
else {
// cublasLtMatmul(cublaslt_handle_,
// matmul_desc,
// alpha_ptr,
// a_data_ptr,
// a_desc,
// b_data_ptr,
// b_desc,
// beta_ptr,
// C,
// c_desc,
// C,
// c_desc,
// (findAlgo == 1 ? (&algo) : NULL),
// workspace,
// workspace_size,
// stream_);
// cublasLtMatmulDescDestroy(matmul_desc);
// cublasLtMatrixLayoutDestroy(a_desc);
// cublasLtMatrixLayoutDestroy(b_desc);
// cublasLtMatrixLayoutDestroy(c_desc);
// sync_check_cuda_error();
// }
// else {
cudaDataType_t compute_type = getCublasDataType(compute_type_);
int cublas_algo = info.algoId;
check_cuda_error(cublasGemmEx(cublas_handle_,
......@@ -365,7 +367,7 @@ void Gemm::gemm(const GemmOp transa,
compute_type,
static_cast<cublasGemmAlgo_t>(cublas_algo)));
sync_check_cuda_error();
}
// }
mutex_->unlock();
}
......@@ -1033,19 +1035,19 @@ cudaDataType_t getCublasDataType(DataType dtype)
}
}
#if (CUDART_VERSION >= 11000)
cublasComputeType_t getCublasComputeType(DataType ctype)
{
switch (ctype) {
case TYPE_FP16:
return CUBLAS_COMPUTE_16F;
case TYPE_FP32:
return CUBLAS_COMPUTE_32F;
default:
throw GemmNotSupportedException("Not supported cublas compute type.");
}
}
#else
// #if (CUDART_VERSION >= 11000)
// cublasComputeType_t getCublasComputeType(DataType ctype)
// {
// switch (ctype) {
// case TYPE_FP16:
// return CUBLAS_COMPUTE_16F;
// case TYPE_FP32:
// return CUBLAS_COMPUTE_32F;
// default:
// throw GemmNotSupportedException("Not supported cublas compute type.");
// }
// }
// #else
cudaDataType_t getCublasComputeType(DataType ctype)
{
switch (ctype) {
......@@ -1057,7 +1059,7 @@ cudaDataType_t getCublasComputeType(DataType ctype)
throw GemmNotSupportedException("Not supported cublas compute type.");
}
}
#endif
// #endif
cublasOperation_t getCublasOperation(GemmOp op)
{
......
src/turbomind/utils/gemm.h
View file @ 9484fd1c
......@@ -622,11 +622,11 @@ std::shared_ptr<Gemm>
createGemm(IAllocator* allocator, cudaStream_t stream, bool sparse = false, bool quantized = false);
cudaDataType_t getCublasDataType(DataType dtype);
#if (CUDART_VERSION >= 11000)
cublasComputeType_t getCublasComputeType(DataType dtype);
#else
// #if (CUDART_VERSION >= 11000)
// cublasComputeType_t getCublasComputeType(DataType dtype);
// #else
cudaDataType_t getCublasComputeType(DataType dtype);
#endif
// #endif
cublasOperation_t getCublasOperation(GemmOp op);
std::string getGemmOpString(const GemmOp& op);
......
src/turbomind/utils/gemm_test/CMakeLists.txt
View file @ 9484fd1c
......@@ -13,7 +13,8 @@
# limitations under the License.
cmake_minimum_required(VERSION 3.8)
find_package(CUDAToolkit REQUIRED)
#find_package(CUDAToolkit REQUIRED)
find_package(CUDA REQUIRED)
set(gemm_func_files
gemm_func.cc
......@@ -51,59 +52,71 @@ set(swin_gemm_func_files
swin_gemm_func.cc
)
set(CMAKE_CXX_FLAGS "${CMAKE_CXX_FLAGS} -fPIC")
set(CMAKE_CUDA_FLAGS "${CMAKE_CUDA_FLAGS} -fPIC")
add_library(gemm_func STATIC ${gemm_func_files})
target_link_libraries(gemm_func PUBLIC CUDA::cublas CUDA::cublasLt CUDA::cudart cuda_utils logger)
set_property(TARGET gemm_func PROPERTY POSITION_INDEPENDENT_CODE ON)
set_property(TARGET gemm_func PROPERTY CUDA_RESOLVE_DEVICE_SYMBOLS ON)
#target_link_libraries(gemm_func PUBLIC cublas cublasLt cudart cuda_utils logger)
target_link_libraries(gemm_func PUBLIC cublas cudart cuda_utils logger)
#set_property(TARGET gemm_func PROPERTY POSITION_INDEPENDENT_CODE ON)
#set_property(TARGET gemm_func PROPERTY CUDA_RESOLVE_DEVICE_SYMBOLS ON)
add_library(encoder_gemm_func STATIC ${encoder_gemm_func_files})
target_link_libraries(encoder_gemm_func PUBLIC CUDA::cublas CUDA::cublasLt CUDA::cudart gemm_func cuda_utils logger)
#target_link_libraries(encoder_gemm_func PUBLIC cublas cublasLt cudart gemm_func cuda_utils logger)
target_link_libraries(encoder_gemm_func PUBLIC cublas cudart gemm_func cuda_utils logger)
if (SPARSITY_SUPPORT)
target_link_libraries(encoder_gemm_func PUBLIC CUDA::cusparse -lcusparseLt)
target_link_libraries(encoder_gemm_func PUBLIC cusparse -lcusparseLt)
endif()
set_property(TARGET encoder_gemm_func PROPERTY POSITION_INDEPENDENT_CODE ON)
set_property(TARGET encoder_gemm_func PROPERTY CUDA_RESOLVE_DEVICE_SYMBOLS ON)
#set_property(TARGET encoder_gemm_func PROPERTY POSITION_INDEPENDENT_CODE ON)
#set_property(TARGET encoder_gemm_func PROPERTY CUDA_RESOLVE_DEVICE_SYMBOLS ON)
add_library(encoder_igemm_func STATIC ${encoder_igemm_func_files})
target_link_libraries(encoder_igemm_func PUBLIC CUDA::cublas CUDA::cublasLt CUDA::cudart cuda_utils logger)
#target_link_libraries(encoder_igemm_func PUBLIC cublas cublasLt cudart cuda_utils logger)
target_link_libraries(encoder_igemm_func PUBLIC cublas cudart cuda_utils logger)
if (SPARSITY_SUPPORT)
target_link_libraries(encoder_igemm_func PUBLIC CUDA::cusparse -lcusparseLt)
target_link_libraries(encoder_igemm_func PUBLIC cusparse -lcusparseLt)
endif()
set_property(TARGET encoder_igemm_func PROPERTY POSITION_INDEPENDENT_CODE ON)
set_property(TARGET encoder_igemm_func PROPERTY CUDA_RESOLVE_DEVICE_SYMBOLS ON)
#set_property(TARGET encoder_igemm_func PROPERTY POSITION_INDEPENDENT_CODE ON)
#set_property(TARGET encoder_igemm_func PROPERTY CUDA_RESOLVE_DEVICE_SYMBOLS ON)
add_library(decoding_gemm_func STATIC ${decoding_gemm_func_files})
target_link_libraries(decoding_gemm_func PUBLIC CUDA::cublas CUDA::cublasLt CUDA::cudart gemm_func cuda_utils logger)
set_property(TARGET decoding_gemm_func PROPERTY POSITION_INDEPENDENT_CODE ON)
set_property(TARGET decoding_gemm_func PROPERTY CUDA_RESOLVE_DEVICE_SYMBOLS ON)
#target_link_libraries(decoding_gemm_func PUBLIC cublas cublasLt cudart gemm_func cuda_utils logger)
target_link_libraries(decoding_gemm_func PUBLIC cublas cudart gemm_func cuda_utils logger)
#set_property(TARGET decoding_gemm_func PROPERTY POSITION_INDEPENDENT_CODE ON)
#set_property(TARGET decoding_gemm_func PROPERTY CUDA_RESOLVE_DEVICE_SYMBOLS ON)
add_library(gpt_gemm_func STATIC ${gpt_gemm_func_files})
target_link_libraries(gpt_gemm_func PUBLIC CUDA::cublas CUDA::cublasLt CUDA::cudart gemm_func cuda_utils logger)
#target_link_libraries(gpt_gemm_func PUBLIC cublas cublasLt cudart gemm_func cuda_utils logger)
target_link_libraries(gpt_gemm_func PUBLIC cublas cudart gemm_func cuda_utils logger)
if (SPARSITY_SUPPORT)
target_link_libraries(gpt_gemm_func PUBLIC CUDA::cusparse -lcusparseLt)
target_link_libraries(gpt_gemm_func PUBLIC cusparse -lcusparseLt)
endif()
set_property(TARGET gpt_gemm_func PROPERTY POSITION_INDEPENDENT_CODE ON)
set_property(TARGET gpt_gemm_func PROPERTY CUDA_RESOLVE_DEVICE_SYMBOLS ON)
#set_property(TARGET gpt_gemm_func PROPERTY POSITION_INDEPENDENT_CODE ON)
#set_property(TARGET gpt_gemm_func PROPERTY CUDA_RESOLVE_DEVICE_SYMBOLS ON)
add_library(xlnet_gemm_func STATIC ${xlnet_gemm_func_files})
target_link_libraries(xlnet_gemm_func PUBLIC CUDA::cublas CUDA::cublasLt CUDA::cudart gemm_func cuda_utils logger)
set_property(TARGET xlnet_gemm_func PROPERTY POSITION_INDEPENDENT_CODE ON)
set_property(TARGET xlnet_gemm_func PROPERTY CUDA_RESOLVE_DEVICE_SYMBOLS ON)
#target_link_libraries(xlnet_gemm_func PUBLIC cublas cublasLt cudart gemm_func cuda_utils logger)
target_link_libraries(xlnet_gemm_func PUBLIC cublas cudart gemm_func cuda_utils logger)
#set_property(TARGET xlnet_gemm_func PROPERTY POSITION_INDEPENDENT_CODE ON)
#set_property(TARGET xlnet_gemm_func PROPERTY CUDA_RESOLVE_DEVICE_SYMBOLS ON)
add_library(t5_gemm_func STATIC ${t5_gemm_func_files})
target_link_libraries(t5_gemm_func PUBLIC CUDA::cublas CUDA::cublasLt CUDA::cudart gemm_func cuda_utils logger)
#target_link_libraries(t5_gemm_func PUBLIC cublas cublasLt cudart gemm_func cuda_utils logger)
target_link_libraries(t5_gemm_func PUBLIC cublas cudart gemm_func cuda_utils logger)
if (SPARSITY_SUPPORT)
target_link_libraries(t5_gemm_func PUBLIC CUDA::cusparse -lcusparseLt)
target_link_libraries(t5_gemm_func PUBLIC cusparse -lcusparseLt)
endif()
set_property(TARGET t5_gemm_func PROPERTY POSITION_INDEPENDENT_CODE ON)
set_property(TARGET t5_gemm_func PROPERTY CUDA_RESOLVE_DEVICE_SYMBOLS ON)
#set_property(TARGET t5_gemm_func PROPERTY POSITION_INDEPENDENT_CODE ON)
#set_property(TARGET t5_gemm_func PROPERTY CUDA_RESOLVE_DEVICE_SYMBOLS ON)
add_library(swin_igemm_func STATIC ${swin_igemm_func_files})
target_link_libraries(swin_igemm_func PUBLIC CUDA::cublas CUDA::cublasLt CUDA::cudart gemm_func encoder_igemm_func cuda_utils logger)
set_property(TARGET swin_igemm_func PROPERTY POSITION_INDEPENDENT_CODE ON)
set_property(TARGET swin_igemm_func PROPERTY CUDA_RESOLVE_DEVICE_SYMBOLS ON)
#target_link_libraries(swin_igemm_func PUBLIC cublas cublasLt cudart gemm_func encoder_igemm_func cuda_utils logger)
target_link_libraries(swin_igemm_func PUBLIC cublas cudart gemm_func encoder_igemm_func cuda_utils logger)
#set_property(TARGET swin_igemm_func PROPERTY POSITION_INDEPENDENT_CODE ON)
#set_property(TARGET swin_igemm_func PROPERTY CUDA_RESOLVE_DEVICE_SYMBOLS ON)
add_library(swin_gemm_func STATIC ${swin_gemm_func_files})
target_link_libraries(swin_gemm_func PUBLIC CUDA::cublas CUDA::cublasLt CUDA::cudart gemm_func cuda_utils logger)
set_property(TARGET swin_gemm_func PROPERTY POSITION_INDEPENDENT_CODE ON)
set_property(TARGET swin_gemm_func PROPERTY CUDA_RESOLVE_DEVICE_SYMBOLS ON)
#target_link_libraries(swin_gemm_func PUBLIC cublas cublasLt cudart gemm_func cuda_utils logger)
target_link_libraries(swin_gemm_func PUBLIC cublas cudart gemm_func cuda_utils logger)
#set_property(TARGET swin_gemm_func PROPERTY POSITION_INDEPENDENT_CODE ON)
#set_property(TARGET swin_gemm_func PROPERTY CUDA_RESOLVE_DEVICE_SYMBOLS ON)
src/turbomind/utils/gemm_test/decoding_gemm_func.cc
View file @ 9484fd1c
......@@ -130,8 +130,8 @@ void generate_decoding_gemm_config(int batch_size,
cublasHandle_t cublas_handle;
check_cuda_error(cublasCreate(&cublas_handle));
cublasLtHandle_t ltHandle;
check_cuda_error(cublasLtCreate(&ltHandle));
// cublasLtHandle_t ltHandle;
// check_cuda_error(cublasLtCreate(&ltHandle));
cudaDataType_t AType;
cudaDataType_t BType;
......@@ -148,16 +148,19 @@ void generate_decoding_gemm_config(int batch_size,
CType = CUDA_R_32F;
computeType = CUDA_R_32F;
startAlgo = (int)CUBLAS_GEMM_DEFAULT;
endAlgo = (int)CUBLAS_GEMM_ALGO23;
// endAlgo = (int)CUBLAS_GEMM_ALGO23;
endAlgo = (int)CUBLAS_GEMM_DEFAULT;
}
else if (std::is_same<T, half>::value) {
data_type = HALF_DATATYPE;
AType = CUDA_R_16F;
BType = CUDA_R_16F;
CType = CUDA_R_16F;
computeType = CUDA_R_32F;
startAlgo = (int)CUBLAS_GEMM_DEFAULT_TENSOR_OP;
endAlgo = (int)CUBLAS_GEMM_ALGO15_TENSOR_OP;
computeType = CUDA_R_16F;
// startAlgo = (int)CUBLAS_GEMM_DEFAULT_TENSOR_OP;
// endAlgo = (int)CUBLAS_GEMM_ALGO15_TENSOR_OP;
startAlgo = (int)CUBLAS_GEMM_DEFAULT;
endAlgo = (int)CUBLAS_GEMM_DEFAULT;
}
#ifdef ENABLE_BF16
else if (std::is_same<T, __nv_bfloat16>::value) {
......@@ -166,11 +169,14 @@ void generate_decoding_gemm_config(int batch_size,
BType = CUDA_R_16BF;
CType = CUDA_R_16BF;
computeType = CUDA_R_32F;
startAlgo = (int)CUBLAS_GEMM_DEFAULT_TENSOR_OP;
endAlgo = (int)CUBLAS_GEMM_ALGO15_TENSOR_OP;
// startAlgo = (int)CUBLAS_GEMM_DEFAULT_TENSOR_OP;
// endAlgo = (int)CUBLAS_GEMM_ALGO15_TENSOR_OP;
startAlgo = (int)CUBLAS_GEMM_DEFAULT;
endAlgo = (int)CUBLAS_GEMM_DEFAULT;
}
#endif
using scaleT = typename ScaleTypeConverter<T>::Type;
// using scaleT = typename ScaleTypeConverter<T>::Type;
using scaleT = typename ScaleTypeConverter<T, true>::Type;
scaleT alpha = (scaleT)1.0f;
scaleT beta = (scaleT)0.0f;
......@@ -241,38 +247,39 @@ void generate_decoding_gemm_config(int batch_size,
const int ALGO_COMBINATIONS = 5000;
customMatmulPerf_t perfResults[ALGO_COMBINATIONS];
LtHgemmCustomFind<T, scaleT>(ltHandle,
batch_size * beam_width,
seq_len,
head_num,
size_per_head,
n,
m,
k,
&alpha,
d_B,
d_A,
&beta,
d_C,
cublas_workspace,
workSpaceSize,
fd,
perfResults,
ALGO_COMBINATIONS);
if (perfResults[0].time < exec_time) {
printPerfStructure(batch_size * beam_width,
seq_len,
head_num,
size_per_head,
n,
m,
k,
perfResults[0],
fd,
data_type,
0);
}
else {
// LtHgemmCustomFind<T, scaleT>(ltHandle,
// batch_size * beam_width,
// seq_len,
// head_num,
// size_per_head,
// n,
// m,
// k,
// &alpha,
// d_B,
// d_A,
// &beta,
// d_C,
// cublas_workspace,
// workSpaceSize,
// fd,
// perfResults,
// ALGO_COMBINATIONS);
// if (perfResults[0].time < exec_time) {
// printPerfStructure(batch_size * beam_width,
// seq_len,
// head_num,
// size_per_head,
// n,
// m,
// k,
// perfResults[0],
// fd,
// data_type,
// 0);
// }
// else {
{
fprintf(fd,
"%d %d %d %d %d ### %d %d %d %d %d -1 -1 -1 -1 -1 -1 -1 "
#if (CUBLAS_VER_MAJOR == 11 && CUBLAS_VER_MINOR == 11 && CUBLAS_VER_PATCH >= 3)
......
src/turbomind/utils/gemm_test/encoder_gemm_func.cc
View file @ 9484fd1c
......@@ -127,8 +127,8 @@ void generate_encoder_gemm_config(
cublasHandle_t cublas_handle;
check_cuda_error(cublasCreate(&cublas_handle));
cublasLtHandle_t ltHandle;
check_cuda_error(cublasLtCreate(&ltHandle));
// cublasLtHandle_t ltHandle;
// check_cuda_error(cublasLtCreate(&ltHandle));
cudaDataType_t AType;
cudaDataType_t BType;
......@@ -145,16 +145,19 @@ void generate_encoder_gemm_config(
CType = CUDA_R_32F;
computeType = CUDA_R_32F;
startAlgo = (int)CUBLAS_GEMM_DEFAULT;
endAlgo = (int)CUBLAS_GEMM_ALGO23;
// endAlgo = (int)CUBLAS_GEMM_ALGO23;
endAlgo = (int)CUBLAS_GEMM_DEFAULT;
}
else if (std::is_same<T, half>::value) {
data_type = HALF_DATATYPE;
AType = CUDA_R_16F;
BType = CUDA_R_16F;
CType = CUDA_R_16F;
computeType = CUDA_R_32F;
startAlgo = (int)CUBLAS_GEMM_DEFAULT_TENSOR_OP;
endAlgo = (int)CUBLAS_GEMM_ALGO15_TENSOR_OP;
computeType = CUDA_R_16F;
// startAlgo = (int)CUBLAS_GEMM_DEFAULT_TENSOR_OP;
// endAlgo = (int)CUBLAS_GEMM_ALGO15_TENSOR_OP;
startAlgo = (int)CUBLAS_GEMM_DEFAULT;
endAlgo = (int)CUBLAS_GEMM_DEFAULT;
}
#ifdef ENABLE_BF16
else if (std::is_same<T, __nv_bfloat16>::value) {
......@@ -163,11 +166,14 @@ void generate_encoder_gemm_config(
BType = CUDA_R_16BF;
CType = CUDA_R_16BF;
computeType = CUDA_R_32F;
startAlgo = (int)CUBLAS_GEMM_DEFAULT_TENSOR_OP;
endAlgo = (int)CUBLAS_GEMM_ALGO15_TENSOR_OP;
// startAlgo = (int)CUBLAS_GEMM_DEFAULT_TENSOR_OP;
// endAlgo = (int)CUBLAS_GEMM_ALGO15_TENSOR_OP;
startAlgo = (int)CUBLAS_GEMM_DEFAULT;
endAlgo = (int)CUBLAS_GEMM_DEFAULT;
}
#endif
using scaleT = typename ScaleTypeConverter<T, false>::Type;
// using scaleT = typename ScaleTypeConverter<T, false>::Type;
using scaleT = typename ScaleTypeConverter<T, true>::Type;
scaleT alpha = (scaleT)1.0f;
scaleT beta = (scaleT)0.0f;
......@@ -331,30 +337,31 @@ void generate_encoder_gemm_config(
// Let try a fixed number of combinations
const int ALGO_COMBINATIONS = 5000;
customMatmulPerf_t perfResults[ALGO_COMBINATIONS];
LtHgemmCustomFind<T, scaleT>(ltHandle,
batch_size,
seq_len,
head_num,
size_per_head,
n,
m,
k,
&alpha,
d_B,
d_A,
&beta,
d_C,
cublas_workspace,
workSpaceSize,
fd,
perfResults,
ALGO_COMBINATIONS);
if (perfResults[0].time < exec_time) {
printPerfStructure(
batch_size, seq_len, head_num, size_per_head, n, m, k, perfResults[0], fd, data_type, 0);
exec_time = perfResults[0].time;
}
else {
// LtHgemmCustomFind<T, scaleT>(ltHandle,
// batch_size,
// seq_len,
// head_num,
// size_per_head,
// n,
// m,
// k,
// &alpha,
// d_B,
// d_A,
// &beta,
// d_C,
// cublas_workspace,
// workSpaceSize,
// fd,
// perfResults,
// ALGO_COMBINATIONS);
// if (perfResults[0].time < exec_time) {
// printPerfStructure(
// batch_size, seq_len, head_num, size_per_head, n, m, k, perfResults[0], fd, data_type, 0);
// exec_time = perfResults[0].time;
// }
// else {
{
fprintf(fd,
"%d %d %d %d %d ### %d %d %d %d %d -1 -1 -1 -1 -1 -1 -1 "
#if (CUBLAS_VER_MAJOR == 11 && CUBLAS_VER_MINOR == 11 && CUBLAS_VER_PATCH >= 3)
......
src/turbomind/utils/gemm_test/gemm_func.cc
View file @ 9484fd1c
This diff is collapsed.
src/turbomind/utils/gemm_test/gpt_gemm_func.cc
View file @ 9484fd1c
......@@ -223,8 +223,8 @@ void generate_gpt_gemm_config(int batch_size,
cublasHandle_t cublas_handle;
check_cuda_error(cublasCreate(&cublas_handle));
cublasLtHandle_t ltHandle;
check_cuda_error(cublasLtCreate(&ltHandle));
// cublasLtHandle_t ltHandle;
// check_cuda_error(cublasLtCreate(&ltHandle));
cudaDataType_t AType;
cudaDataType_t BType;
......@@ -244,7 +244,8 @@ void generate_gpt_gemm_config(int batch_size,
DType = CUDA_R_32F;
computeType = CUDA_R_32F;
startAlgo = (int)CUBLAS_GEMM_DEFAULT;
endAlgo = (int)CUBLAS_GEMM_ALGO23;
// endAlgo = (int)CUBLAS_GEMM_ALGO23;
endAlgo = (int)CUBLAS_GEMM_DEFAULT;
}
else if (std::is_same<T, half>::value) {
data_type = HALF_DATATYPE;
......@@ -252,9 +253,11 @@ void generate_gpt_gemm_config(int batch_size,
BType = CUDA_R_16F;
CType = CUDA_R_16F;
DType = CUDA_R_16F;
computeType = CUDA_R_32F;
startAlgo = (int)CUBLAS_GEMM_DEFAULT_TENSOR_OP;
endAlgo = (int)CUBLAS_GEMM_ALGO15_TENSOR_OP;
computeType = CUDA_R_16F;
// startAlgo = (int)CUBLAS_GEMM_DEFAULT_TENSOR_OP;
// endAlgo = (int)CUBLAS_GEMM_ALGO15_TENSOR_OP;
startAlgo = (int)CUBLAS_GEMM_DEFAULT;
endAlgo = (int)CUBLAS_GEMM_DEFAULT;
}
#ifdef ENABLE_BF16
else if (std::is_same<T, __nv_bfloat16>::value) {
......@@ -264,8 +267,10 @@ void generate_gpt_gemm_config(int batch_size,
CType = CUDA_R_16BF;
DType = CUDA_R_16BF;
computeType = CUDA_R_32F;
startAlgo = (int)CUBLAS_GEMM_DEFAULT_TENSOR_OP;
endAlgo = (int)CUBLAS_GEMM_ALGO15_TENSOR_OP;
// startAlgo = (int)CUBLAS_GEMM_DEFAULT_TENSOR_OP;
// endAlgo = (int)CUBLAS_GEMM_ALGO15_TENSOR_OP;
startAlgo = (int)CUBLAS_GEMM_DEFAULT;
endAlgo = (int)CUBLAS_GEMM_DEFAULT;
}
#endif
#ifdef ENABLE_FP8
......@@ -293,12 +298,24 @@ void generate_gpt_gemm_config(int batch_size,
DType_FP8[9] = CUDA_R_16BF;
#endif
computeType = CUDA_R_32F;
startAlgo = (int)CUBLAS_GEMM_DEFAULT_TENSOR_OP;
endAlgo = (int)CUBLAS_GEMM_ALGO15_TENSOR_OP;
// startAlgo = (int)CUBLAS_GEMM_DEFAULT_TENSOR_OP;
// endAlgo = (int)CUBLAS_GEMM_ALGO15_TENSOR_OP;
startAlgo = (int)CUBLAS_GEMM_DEFAULT;
endAlgo = (int)CUBLAS_GEMM_DEFAULT;
}
#endif
float alpha = (float)1.0f;
float beta = (float)0.0f;
// float alpha = (float)1.0f;
// float beta = (float)0.0f;
float f_alpha = (float)1.0f;
float f_beta = (float)0.0f;
half h_alpha = (half)(f_alpha);
half h_beta = (half)(f_beta);
int is_fp16_computeType = computeType == CUDA_R_16F ? 1 : 0;
const void* alpha = is_fp16_computeType ? reinterpret_cast<void*>(&h_alpha) : reinterpret_cast<void*>(&f_alpha);
const void* beta = is_fp16_computeType ? reinterpret_cast<void*>(&h_beta) : reinterpret_cast<void*>(&f_beta);
printf("***Encoder Gemm Testing Begin***\n");
printf("***Cublas Gemm Testing Begin***\n");
......@@ -342,7 +359,7 @@ void generate_gpt_gemm_config(int batch_size,
max_input_len,
max_input_len,
size_per_head,
&alpha,
&f_alpha,
d_B,
BType,
size_per_head,
......@@ -351,13 +368,13 @@ void generate_gpt_gemm_config(int batch_size,
AType,
size_per_head,
max_input_len * size_per_head,
&beta,
&f_beta,
d_C,
CUDA_R_32F, // CType,
max_input_len,
max_input_len * max_input_len,
batchCount[i],
computeType,
CUDA_R_32F,
static_cast<cublasGemmAlgo_t>(algo));
}
else if (i == 2) {
......@@ -456,44 +473,45 @@ void generate_gpt_gemm_config(int batch_size,
customMatmulPerf_t perfResults[ALGO_COMBINATIONS];
// for gpt, computeType & scaleType should be FP32
LtHgemmCustomFind<T, float>(ltHandle,
batch_size * beam_width,
i == 1 || i == 2 ? max_input_len : 1,
head_num,
size_per_head,
n,
m,
k,
&alpha,
d_B,
d_A,
&beta,
d_C,
cublas_workspace,
workSpaceSize,
fd,
perfResults,
ALGO_COMBINATIONS,
DType_FP8[i],
batchCount[i],
strideA[i],
strideB[i],
strideD[i]);
if (perfResults[0].time < exec_time) {
printPerfStructure(batch_size * beam_width,
seq_len,
head_num,
size_per_head,
n,
m,
k,
perfResults[0],
fd,
data_type,
0,
batchCount[i]);
}
else {
// LtHgemmCustomFind<T, float>(ltHandle,
// batch_size * beam_width,
// i == 1 || i == 2 ? max_input_len : 1,
// head_num,
// size_per_head,
// n,
// m,
// k,
// &alpha,
// d_B,
// d_A,
// &beta,
// d_C,
// cublas_workspace,
// workSpaceSize,
// fd,
// perfResults,
// ALGO_COMBINATIONS,
// DType_FP8[i],
// batchCount[i],
// strideA[i],
// strideB[i],
// strideD[i]);
// if (perfResults[0].time < exec_time) {
// printPerfStructure(batch_size * beam_width,
// seq_len,
// head_num,
// size_per_head,
// n,
// m,
// k,
// perfResults[0],
// fd,
// data_type,
// 0,
// batchCount[i]);
// }
// else {
{
fprintf(fd,
"%d %d %d %d %d ### %d %d %d %d %d -1 -1 -1 -1 -1 -1 -1 "
#if (CUBLAS_VER_MAJOR == 11 && CUBLAS_VER_MINOR == 11 && CUBLAS_VER_PATCH >= 3)
......
src/turbomind/utils/gemm_test/swin_gemm_func.cc
View file @ 9484fd1c
......@@ -133,8 +133,8 @@ void generate_swin_gemm_config(
cublasHandle_t cublas_handle;
check_cuda_error(cublasCreate(&cublas_handle));
cublasLtHandle_t ltHandle;
check_cuda_error(cublasLtCreate(&ltHandle));
// cublasLtHandle_t ltHandle;
// check_cuda_error(cublasLtCreate(&ltHandle));
cudaDataType_t AType;
cudaDataType_t BType;
......@@ -151,16 +151,19 @@ void generate_swin_gemm_config(
CType = CUDA_R_32F;
computeType = CUDA_R_32F;
startAlgo = (int)CUBLAS_GEMM_DEFAULT;
endAlgo = (int)CUBLAS_GEMM_ALGO23;
// endAlgo = (int)CUBLAS_GEMM_ALGO23;
endAlgo = (int)CUBLAS_GEMM_DEFAULT;
}
else if (std::is_same<T, half>::value) {
data_type = HALF_DATATYPE;
AType = CUDA_R_16F;
BType = CUDA_R_16F;
CType = CUDA_R_16F;
computeType = CUDA_R_32F;
startAlgo = (int)CUBLAS_GEMM_DEFAULT_TENSOR_OP;
endAlgo = (int)CUBLAS_GEMM_ALGO15_TENSOR_OP;
computeType = CUDA_R_16F;
// startAlgo = (int)CUBLAS_GEMM_DEFAULT_TENSOR_OP;
// endAlgo = (int)CUBLAS_GEMM_ALGO15_TENSOR_OP;
startAlgo = (int)CUBLAS_GEMM_DEFAULT;
endAlgo = (int)CUBLAS_GEMM_DEFAULT;
}
#ifdef ENABLE_BF16
else if (std::is_same<T, __nv_bfloat16>::value) {
......@@ -169,11 +172,14 @@ void generate_swin_gemm_config(
BType = CUDA_R_16BF;
CType = CUDA_R_16BF;
computeType = CUDA_R_32F;
startAlgo = (int)CUBLAS_GEMM_DEFAULT_TENSOR_OP;
endAlgo = (int)CUBLAS_GEMM_ALGO15_TENSOR_OP;
// startAlgo = (int)CUBLAS_GEMM_DEFAULT_TENSOR_OP;
// endAlgo = (int)CUBLAS_GEMM_ALGO15_TENSOR_OP;
startAlgo = (int)CUBLAS_GEMM_DEFAULT;
endAlgo = (int)CUBLAS_GEMM_DEFAULT;
}
#endif
using scaleT = typename ScaleTypeConverter<T, false>::Type;
// using scaleT = typename ScaleTypeConverter<T, false>::Type;
using scaleT = typename ScaleTypeConverter<T, true>::Type;
scaleT alpha = (scaleT)1.0f;
scaleT beta = (scaleT)0.0f;
......@@ -309,30 +315,31 @@ void generate_swin_gemm_config(
const int ALGO_COMBINATIONS = 5000;
customMatmulPerf_t perfResults[ALGO_COMBINATIONS];
LtHgemmCustomFind<T, scaleT>(ltHandle,
batch_size,
seq_len,
head_num,
size_per_head,
n,
m,
k,
&alpha,
d_B,
d_A,
&beta,
d_C,
cublas_workspace,
workSpaceSize,
fd,
perfResults,
ALGO_COMBINATIONS);
if (perfResults[0].time < exec_time) {
printPerfStructure(
batch_size, seq_len, head_num, size_per_head, n, m, k, perfResults[0], fd, data_type, 0);
exec_time = perfResults[0].time;
}
else {
// LtHgemmCustomFind<T, scaleT>(ltHandle,
// batch_size,
// seq_len,
// head_num,
// size_per_head,
// n,
// m,
// k,
// &alpha,
// d_B,
// d_A,
// &beta,
// d_C,
// cublas_workspace,
// workSpaceSize,
// fd,
// perfResults,
// ALGO_COMBINATIONS);
// if (perfResults[0].time < exec_time) {
// printPerfStructure(
// batch_size, seq_len, head_num, size_per_head, n, m, k, perfResults[0], fd, data_type, 0);
// exec_time = perfResults[0].time;
// }
// else {
{
fprintf(fd,
"%d %d %d %d %d ### %d %d %d %d %d -1 -1 -1 -1 -1 -1 -1 "
#if (CUBLAS_VER_MAJOR == 11 && CUBLAS_VER_MINOR == 11 && CUBLAS_VER_PATCH >= 3)
......
src/turbomind/utils/gemm_test/swin_igemm_func.cc
View file @ 9484fd1c
......@@ -144,23 +144,23 @@ int igemm_config_INT8IO(int m, int n, int k, FILE* fout, void* buffer)
int8_t* d_B = d_A + m * k; // k * n, stored in column-major
int8_t* d_C = (int8_t*)(d_B + k * n); // m * n, stored in column-major
cublasLtHandle_t ltHandle;
cublasLtCreate(&ltHandle);
LtIgemmCustomFind(ltHandle,
m,
n,
k,
&alpha, /* host pointer */
d_A,
d_B,
&beta, /* host pointer */
d_C,
NULL,
0,
fout);
cublasLtDestroy(ltHandle);
// cublasLtHandle_t ltHandle;
// cublasLtCreate(&ltHandle);
// LtIgemmCustomFind(ltHandle,
// m,
// n,
// k,
// &alpha, /* host pointer */
// d_A,
// d_B,
// &beta, /* host pointer */
// d_C,
// NULL,
// 0,
// fout);
// cublasLtDestroy(ltHandle);
return 0;
}
......
src/turbomind/utils/gemm_test/t5_gemm_func.cc
View file @ 9484fd1c
......@@ -195,8 +195,8 @@ void generate_t5_gemm_config(int batch_size,
cublasHandle_t cublas_handle;
check_cuda_error(cublasCreate(&cublas_handle));
cublasLtHandle_t ltHandle;
check_cuda_error(cublasLtCreate(&ltHandle));
// cublasLtHandle_t ltHandle;
// check_cuda_error(cublasLtCreate(&ltHandle));
cudaDataType_t AType;
cudaDataType_t BType;
......@@ -213,16 +213,19 @@ void generate_t5_gemm_config(int batch_size,
CType = CUDA_R_32F;
computeType = CUDA_R_32F;
startAlgo = (int)CUBLAS_GEMM_DEFAULT;
endAlgo = (int)CUBLAS_GEMM_ALGO23;
// endAlgo = (int)CUBLAS_GEMM_ALGO23;
endAlgo = (int)CUBLAS_GEMM_DEFAULT;
}
else if (std::is_same<T, half>::value) {
data_type = HALF_DATATYPE;
AType = CUDA_R_16F;
BType = CUDA_R_16F;
CType = CUDA_R_16F;
computeType = CUDA_R_32F;
startAlgo = (int)CUBLAS_GEMM_DEFAULT_TENSOR_OP;
endAlgo = (int)CUBLAS_GEMM_ALGO15_TENSOR_OP;
computeType = CUDA_R_16F;
// startAlgo = (int)CUBLAS_GEMM_DEFAULT_TENSOR_OP;
// endAlgo = (int)CUBLAS_GEMM_ALGO15_TENSOR_OP;
startAlgo = (int)CUBLAS_GEMM_DEFAULT;
endAlgo = (int)CUBLAS_GEMM_DEFAULT;
}
#ifdef ENABLE_BF16
else if (std::is_same<T, __nv_bfloat16>::value) {
......@@ -231,8 +234,10 @@ void generate_t5_gemm_config(int batch_size,
BType = CUDA_R_16BF;
CType = CUDA_R_16BF;
computeType = CUDA_R_32F;
startAlgo = (int)CUBLAS_GEMM_DEFAULT_TENSOR_OP;
endAlgo = (int)CUBLAS_GEMM_ALGO15_TENSOR_OP;
// startAlgo = (int)CUBLAS_GEMM_DEFAULT_TENSOR_OP;
// endAlgo = (int)CUBLAS_GEMM_ALGO15_TENSOR_OP;
startAlgo = (int)CUBLAS_GEMM_DEFAULT;
endAlgo = (int)CUBLAS_GEMM_DEFAULT;
}
#endif
float f_alpha = (float)1.0f;
......@@ -442,60 +447,61 @@ void generate_t5_gemm_config(int batch_size,
scaleT alpha_scale = (scaleT)1.0f;
scaleT beta_scale = (scaleT)0.0f;
LtHgemmCustomFind<T, scaleT>(ltHandle,
m,
seq_len,
head_num,
size_per_head,
n,
m,
k,
&(alpha_scale),
d_B,
d_A,
&(beta_scale),
d_C,
cublas_workspace,
workSpaceSize,
fd,
perfResults,
ALGO_COMBINATIONS);
}
else {
LtHgemmCustomFind<T, float>(ltHandle,
m,
seq_len,
head_num,
size_per_head,
n,
m,
k,
&(f_alpha),
d_B,
d_A,
&(f_beta),
d_C,
cublas_workspace,
workSpaceSize,
fd,
perfResults,
ALGO_COMBINATIONS);
}
if (perfResults[0].time < exec_time) {
printPerfStructure(batch_size * (i <= 5 || i == 1 ? 1 : beam_width),
seq_len,
head_num,
size_per_head,
n,
m,
k,
perfResults[0],
fd,
data_type,
0);
// LtHgemmCustomFind<T, scaleT>(ltHandle,
// m,
// seq_len,
// head_num,
// size_per_head,
// n,
// m,
// k,
// &(alpha_scale),
// d_B,
// d_A,
// &(beta_scale),
// d_C,
// cublas_workspace,
// workSpaceSize,
// fd,
// perfResults,
// ALGO_COMBINATIONS);
}
else {
// LtHgemmCustomFind<T, float>(ltHandle,
// m,
// seq_len,
// head_num,
// size_per_head,
// n,
// m,
// k,
// &(f_alpha),
// d_B,
// d_A,
// &(f_beta),
// d_C,
// cublas_workspace,
// workSpaceSize,
// fd,
// perfResults,
// ALGO_COMBINATIONS);
}
// if (perfResults[0].time < exec_time) {
// printPerfStructure(batch_size * (i <= 5 || i == 1 ? 1 : beam_width),
// seq_len,
// head_num,
// size_per_head,
// n,
// m,
// k,
// perfResults[0],
// fd,
// data_type,
// 0);
// }
// else {
{
fprintf(fd,
"%d %d %d %d %d ### %d %d %d %d %d -1 -1 -1 -1 -1 -1 -1 "
#if (CUBLAS_VER_MAJOR == 11 && CUBLAS_VER_MINOR == 11 && CUBLAS_VER_PATCH >= 3)
......
src/turbomind/utils/gemm_test/xlnet_gemm_func.cc
View file @ 9484fd1c
......@@ -218,8 +218,8 @@ void generate_xlnet_gemm_config(int batch_size,
cublasHandle_t cublas_handle;
check_cuda_error(cublasCreate(&cublas_handle));
cublasLtHandle_t ltHandle;
check_cuda_error(cublasLtCreate(&ltHandle));
// cublasLtHandle_t ltHandle;
// check_cuda_error(cublasLtCreate(&ltHandle));
cudaDataType_t AType;
cudaDataType_t BType;
......@@ -236,16 +236,19 @@ void generate_xlnet_gemm_config(int batch_size,
CType = CUDA_R_32F;
computeType = CUDA_R_32F;
startAlgo = (int)CUBLAS_GEMM_DEFAULT;
endAlgo = (int)CUBLAS_GEMM_ALGO23;
// endAlgo = (int)CUBLAS_GEMM_ALGO23;
endAlgo = (int)CUBLAS_GEMM_DEFAULT;
}
else if (std::is_same<T, half>::value) {
data_type = HALF_DATATYPE;
AType = CUDA_R_16F;
BType = CUDA_R_16F;
CType = CUDA_R_16F;
computeType = CUDA_R_32F;
startAlgo = (int)CUBLAS_GEMM_DEFAULT_TENSOR_OP;
endAlgo = (int)CUBLAS_GEMM_ALGO15_TENSOR_OP;
computeType = CUDA_R_16F;
// startAlgo = (int)CUBLAS_GEMM_DEFAULT_TENSOR_OP;
// endAlgo = (int)CUBLAS_GEMM_ALGO15_TENSOR_OP;
startAlgo = (int)CUBLAS_GEMM_DEFAULT;
endAlgo = (int)CUBLAS_GEMM_DEFAULT;
}
#ifdef ENABLE_BF16
else if (std::is_same<T, __nv_bfloat16>::value) {
......@@ -254,12 +257,15 @@ void generate_xlnet_gemm_config(int batch_size,
BType = CUDA_R_16BF;
CType = CUDA_R_16BF;
computeType = CUDA_R_32F;
startAlgo = (int)CUBLAS_GEMM_DEFAULT_TENSOR_OP;
endAlgo = (int)CUBLAS_GEMM_ALGO15_TENSOR_OP;
// startAlgo = (int)CUBLAS_GEMM_DEFAULT_TENSOR_OP;
// endAlgo = (int)CUBLAS_GEMM_ALGO15_TENSOR_OP;
startAlgo = (int)CUBLAS_GEMM_DEFAULT;
endAlgo = (int)CUBLAS_GEMM_DEFAULT;
}
#endif
using scaleT = typename ScaleTypeConverter<T, false>::Type;
// using scaleT = typename ScaleTypeConverter<T, false>::Type;
using scaleT = typename ScaleTypeConverter<T, true>::Type;
scaleT alpha = (scaleT)1.0f;
scaleT beta = (scaleT)0.0f;
......@@ -358,30 +364,31 @@ void generate_xlnet_gemm_config(int batch_size,
const int ALGO_COMBINATIONS = 5000;
customMatmulPerf_t perfResults[ALGO_COMBINATIONS];
LtHgemmCustomFind<T, scaleT>(ltHandle,
batch_size,
seq_len,
head_num,
size_per_head,
n,
m,
k,
&alpha,
d_B,
d_A,
&beta,
d_C,
cublas_workspace,
workSpaceSize,
fd,
perfResults,
ALGO_COMBINATIONS);
if (perfResults[0].time < exec_time) {
printPerfStructure(
batch_size, seq_len, head_num, size_per_head, n, m, k, perfResults[0], fd, data_type, 0);
exec_time = perfResults[0].time;
}
else {
// LtHgemmCustomFind<T, scaleT>(ltHandle,
// batch_size,
// seq_len,
// head_num,
// size_per_head,
// n,
// m,
// k,
// &alpha,
// d_B,
// d_A,
// &beta,
// d_C,
// cublas_workspace,
// workSpaceSize,
// fd,
// perfResults,
// ALGO_COMBINATIONS);
// if (perfResults[0].time < exec_time) {
// printPerfStructure(
// batch_size, seq_len, head_num, size_per_head, n, m, k, perfResults[0], fd, data_type, 0);
// exec_time = perfResults[0].time;
// }
// else {
{
fprintf(fd,
"%d %d %d %d %d ### %d %d %d %d %d -1 -1 -1 -1 -1 -1 -1 "
#if (CUBLAS_VER_MAJOR == 11 && CUBLAS_VER_MINOR == 11 && CUBLAS_VER_PATCH >= 3)
......
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