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fix(mgb/dnn): add cuda float naive matmul algo 

GitOrigin-RevId: db7f7fc057
tags/v1.3.1
Megvii Engine Team 4 years ago
parent
4f0e6eae35
commit
756c1eb7f2
4 changed files with 121 additions and 18 deletions
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  1. +52
    -7
      dnn/src/cuda/matrix_mul/naive.cpp
  2. +26
    -9
      dnn/src/cuda/matrix_mul/naive.cu
  3. +3
    -2
      dnn/src/cuda/matrix_mul/naive.cuh
  4. +40
    -0
      dnn/test/cuda/matrix_mul.cpp

+ 52
- 7
dnn/src/cuda/matrix_mul/naive.cpp View File

@@ -17,8 +17,21 @@
using namespace megdnn;
using namespace cuda;

#include "midout.h"
MIDOUT_DECL(megdnn_naive_matmul)

bool MatrixMulForwardImpl::AlgoNaive::is_available(const SizeArgs& args) const {
return args.can_be_treated_as_int8x8x32();
if (args.can_be_treated_as_int8x8x32())
return true;
auto&& layout_a = args.layout_a;
auto&& layout_b = args.layout_b;
auto&& layout_c = args.layout_c;
return layout_a.dtype.enumv() == layout_b.dtype.enumv() &&
(layout_a.dtype.enumv() == DTypeEnum::Float32 ||
layout_a.dtype.enumv() == DTypeEnum::Float16) &&
(layout_c.dtype.enumv() == DTypeEnum::Float32 ||
layout_c.dtype.enumv() == DTypeEnum::Float16) &&
args.opr->param().format == param::MatrixMul::Format::DEFAULT;
}
void MatrixMulForwardImpl::AlgoNaive::exec(const ExecArgs& args) const {
auto&& param = args.opr->param();
@@ -28,13 +41,45 @@ void MatrixMulForwardImpl::AlgoNaive::exec(const ExecArgs& args) const {
LDB = args.tensor_b.layout.stride[0],
LDC = args.tensor_c.layout.stride[0];

int8_t* A = args.tensor_a.compatible_ptr<dt_int8>();
int8_t* B = args.tensor_b.compatible_ptr<dt_int8>();
int32_t* C = args.tensor_c.compatible_ptr<dt_int32>();

auto&& handle = concrete_handle(args.opr->handle());
exec_gemm_int8_naive(A, B, C, m, n, k, LDA, LDB, LDC, param.transposeA,
param.transposeB, cuda_stream(handle));

using ComputeMode = Param::ComputeMode;
#define DISPATCH_CMODE(in_dt, out_dt, in_ct, out_ct, comp_ct, cmode) \
MIDOUT_BEGIN(megdnn_naive_matmul, midout_iv(#in_dt #out_dt #in_ct, \
#out_ct, #comp_ct, #cmode)) { \
do { \
using namespace dtype; \
if (args.tensor_a.layout.dtype.enumv() == \
DTypeTrait<in_dt>::enumv && \
args.tensor_c.layout.dtype.enumv() == \
DTypeTrait<out_dt>::enumv && \
param.compute_mode == cmode) { \
in_ct* A = args.tensor_a.compatible_ptr<in_ct>(); \
in_ct* B = args.tensor_b.compatible_ptr<in_ct>(); \
out_ct* C = args.tensor_c.compatible_ptr<out_ct>(); \
exec_gemm_naive<in_ct, in_ct, out_ct, comp_ct>( \
A, B, C, m, n, k, LDA, LDB, LDC, param.transposeA, \
param.transposeB, cuda_stream(handle)); \
return; \
} \
} while (0); \
} \
MIDOUT_END();
#define DISPATCH(in_dt, out_dt, in_ct, out_ct, comp_ct) \
DISPATCH_CMODE(in_dt, out_dt, in_ct, out_ct, comp_ct, ComputeMode::DEFAULT)

DISPATCH(Float32, Float32, dt_float32, dt_float32, dt_float32);
DISPATCH(Float16, Float16, dt_float16, dt_float16, dt_float16);
DISPATCH(Int8, Int32, dt_int8, dt_int32, dt_int32);
DISPATCH(QuantizedS8, QuantizedS32, dt_int8, dt_int32, dt_int32);
DNN_INC_FLOAT16(DISPATCH_CMODE(Float16, Float16, dt_float16, dt_float16,
dt_float32, ComputeMode::FLOAT32));
#undef DISPATCH_CMODE
#undef DISPATCH
megdnn_throw(ssprintf(
"unsupported Matmul(%s, %s) -> %s with cmode = %d",
args.layout_a.dtype.name(), args.layout_b.dtype.name(),
args.layout_c.dtype.name(), static_cast<int>(param.compute_mode)));
}

// vim: syntax=cpp.doxygen

+ 26
- 9
dnn/src/cuda/matrix_mul/naive.cu View File

@@ -14,16 +14,18 @@
#include "src/cuda/utils.cuh"

namespace {
__global__ void do_exec(const int8_t* A, const int8_t* B, int32_t* C, size_t M,

template <typename AType, typename BType, typename CType, typename CompType>
__global__ void do_exec(const AType* A, const BType* B, CType* C, size_t M,
size_t N, size_t K, size_t LDA, size_t LDB, size_t LDC,
bool transA, bool transB) {
size_t m = blockIdx.x;
for (; m < M; m += gridDim.x) {
size_t n = threadIdx.x;
for (; n < N; n += blockDim.x) {
int32_t res = 0;
CompType res = static_cast<CompType>(0);
for (size_t k = 0; k < K; ++k) {
int8_t av = transA ? A[k * LDA + m] : A[m * LDA + k],
AType av = transA ? A[k * LDA + m] : A[m * LDA + k],
bv = transB ? B[n * LDB + k] : B[k * LDB + n];
res += av * bv;
}
@@ -36,14 +38,29 @@ __global__ void do_exec(const int8_t* A, const int8_t* B, int32_t* C, size_t M,
namespace megdnn {
namespace cuda {

void exec_gemm_int8_naive(const int8_t* A, const int8_t* B, int32_t* C,
size_t M, size_t N, size_t K, size_t LDA, size_t LDB,
size_t LDC, bool transA, bool transB,
cudaStream_t stream) {
do_exec<<<128, 128, 0, stream>>>(A, B, C, M, N, K, LDA, LDB, LDC, transA,
transB);
template <typename AType, typename BType, typename CType, typename CompType>
void exec_gemm_naive(const AType* A, const BType* B, CType* C, size_t M,
size_t N, size_t K, size_t LDA, size_t LDB, size_t LDC,
bool transA, bool transB, cudaStream_t stream) {
do_exec<AType, BType, CType, CompType><<<128, 128, 0, stream>>>(
A, B, C, M, N, K, LDA, LDB, LDC, transA, transB);
}

#define INST(in_ct, out_ct, comp_ct) \
template void exec_gemm_naive<typename in_ct, typename in_ct, \
typename out_ct, typename comp_ct>( \
const in_ct* A, const in_ct* B, out_ct* C, size_t M, size_t N, \
size_t K, size_t LDA, size_t LDB, size_t LDC, bool transA, \
bool transB, cudaStream_t stream);

INST(megdnn::dt_float32, megdnn::dt_float32, megdnn::dt_float32)
INST(megdnn::dt_float16, megdnn::dt_float16, megdnn::dt_float16)
INST(megdnn::dt_int8, megdnn::dt_int32, megdnn::dt_int32)
INST(megdnn::dt_float16, megdnn::dt_float16, megdnn::dt_float32)

#undef cb
#undef INST

} // namespace cuda
} // namespace megdnn



+ 3
- 2
dnn/src/cuda/matrix_mul/naive.cuh View File

@@ -15,8 +15,9 @@
namespace megdnn {
namespace cuda {

void exec_gemm_int8_naive(const int8_t* A, const int8_t* B, int32_t* C,
size_t m, size_t n, size_t k, size_t ldA, size_t ldB,
template <typename AType, typename BType, typename CType, typename CompType>
void exec_gemm_naive(const AType* A, const BType* B, CType* C, size_t m,
size_t n, size_t k, size_t ldA, size_t ldB,
size_t ldC, bool transA, bool transB,
cudaStream_t stream);
} // namespace cuda


+ 40
- 0
dnn/test/cuda/matrix_mul.cpp View File

@@ -185,6 +185,46 @@ TEST_F(CUDA, MATRIX_MUL_INT8x8x32_NAIVE) {
}
}

TEST_F(CUDA, MATRIX_MUL_FLOAT_NAIVE) {
Checker<MatrixMul> checker(handle_cuda());
checker.set_before_exec_callback(AlgoChecker<MatrixMulForward>("NAIVE"));
using Param = MatrixMul::Param;
size_t m = 12, n = 16, k = 20;

std::vector<DType> dtype_array;
dtype_array.push_back(dtype::Float32());
dtype_array.push_back(dtype::Float16());

for (DType dtype : dtype_array) {
for (unsigned mask = 0; mask < 4; ++mask) {
Param param;
param.transposeA = mask & 1;
param.transposeB = mask & 2;
DType stype = dtype;
TensorShape A, B;
if (param.transposeA)
A = TensorShape{k, m};
else
A = TensorShape{m, k};
if (param.transposeB)
B = TensorShape{n, k};
else
B = TensorShape{k, n};
if (dtype == dtype::Float16()) {
param.compute_mode = param::MatrixMul::ComputeMode::FLOAT32;
}
checker.set_param(param)
.set_dtype(0, stype)
.set_dtype(1, stype)
.set_dtype(2, dtype)
.set_epsilon(dtype == dtype::Float16()
? 5e-2
: 5e-3)
.execs({A, B, {}});
}
}
}

TEST_F(CUDA, MATRIX_MUL) {
if (cuda::current_device_prop().major < 6) {
printf("Skip CUDA.MATRIX_MUL test as current device doesn't support\n");


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