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wgmma_sm90.cu
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wgmma_sm90.cu
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/***************************************************************************************************
* Copyright (c) 2024 - 2024 NVIDIA CORPORATION & AFFILIATES. All rights reserved.
* SPDX-License-Identifier: BSD-3-Clause
*
* Redistribution and use in source and binary forms, with or without
* modification, are permitted provided that the following conditions are met:
*
* 1. Redistributions of source code must retain the above copyright notice, this
* list of conditions and the following disclaimer.
*
* 2. Redistributions in binary form must reproduce the above copyright notice,
* this list of conditions and the following disclaimer in the documentation
* and/or other materials provided with the distribution.
*
* 3. Neither the name of the copyright holder nor the names of its
* contributors may be used to endorse or promote products derived from
* this software without specific prior written permission.
*
* THIS SOFTWARE IS PROVIDED BY THE COPYRIGHT HOLDERS AND CONTRIBUTORS "AS IS"
* AND ANY EXPRESS OR IMPLIED WARRANTIES, INCLUDING, BUT NOT LIMITED TO, THE
* IMPLIED WARRANTIES OF MERCHANTABILITY AND FITNESS FOR A PARTICULAR PURPOSE ARE
* DISCLAIMED. IN NO EVENT SHALL THE COPYRIGHT HOLDER OR CONTRIBUTORS BE LIABLE
* FOR ANY DIRECT, INDIRECT, INCIDENTAL, SPECIAL, EXEMPLARY, OR CONSEQUENTIAL
* DAMAGES (INCLUDING, BUT NOT LIMITED TO, PROCUREMENT OF SUBSTITUTE GOODS OR
* SERVICES; LOSS OF USE, DATA, OR PROFITS; OR BUSINESS INTERRUPTION) HOWEVER
* CAUSED AND ON ANY THEORY OF LIABILITY, WHETHER IN CONTRACT, STRICT LIABILITY,
* OR TORT (INCLUDING NEGLIGENCE OR OTHERWISE) ARISING IN ANY WAY OUT OF THE USE
* OF THIS SOFTWARE, EVEN IF ADVISED OF THE POSSIBILITY OF SUCH DAMAGE.
*
**************************************************************************************************/
#include <cstdlib>
#include <cstdio>
#include <cassert>
#include <thrust/host_vector.h>
#include <thrust/device_vector.h>
#include <cute/tensor.hpp>
#include "cutlass/cluster_launch.hpp"
#include "cutlass/arch/barrier.h"
#include "cutlass/pipeline/sm90_pipeline.hpp"
#include "cutlass/util/print_error.hpp"
#include "cutlass/util/GPU_Clock.hpp"
#include "cutlass/util/helper_cuda.hpp"
#include "cutlass/arch/mma_sm90.h"
#include "cutlass/device_kernel.h"
using namespace cute;
template <class ElementA,
class ElementB,
class SmemLayoutA, // (M,K,P)
class SmemLayoutB> // (N,K,P)
struct SharedStorage
{
array_aligned<ElementA, cosize_v<SmemLayoutA>> smem_A;
array_aligned<ElementB, cosize_v<SmemLayoutB>> smem_B;
uint64_t tma_barrier[size<2>(SmemLayoutA{})];
uint64_t mma_barrier[size<2>(SmemLayoutA{})];
};
template <class ProblemShape, class CtaTiler,
class TA, class SmemLayoutA, class TmaA,
class TB, class SmemLayoutB, class TmaB,
class TC, class CStride, class TiledMma,
class Alpha, class Beta>
__global__ static
__launch_bounds__(decltype(size(TiledMma{}))::value)
void
gemm_device(ProblemShape shape_MNK, CtaTiler cta_tiler,
TA const* A, CUTLASS_GRID_CONSTANT TmaA const tma_a,
TB const* B, CUTLASS_GRID_CONSTANT TmaB const tma_b,
TC * C, CStride dC, TiledMma mma,
Alpha alpha, Beta beta)
{
// Preconditions
CUTE_STATIC_ASSERT_V(rank(shape_MNK) == Int<3>{}); // (M, N, K)
CUTE_STATIC_ASSERT_V(rank(cta_tiler) == Int<3>{}); // (BLK_M, BLK_N, BLK_K)
static_assert(is_static<SmemLayoutA>::value);
static_assert(is_static<SmemLayoutB>::value);
CUTE_STATIC_ASSERT_V(size<0>(SmemLayoutA{}) == size<0>(cta_tiler)); // BLK_M
CUTE_STATIC_ASSERT_V(size<0>(SmemLayoutB{}) == size<1>(cta_tiler)); // BLK_N
CUTE_STATIC_ASSERT_V(size<1>(SmemLayoutA{}) == size<2>(cta_tiler)); // BLK_K
CUTE_STATIC_ASSERT_V(size<1>(SmemLayoutB{}) == size<2>(cta_tiler)); // BLK_K
CUTE_STATIC_ASSERT_V(congruent(select<0,1>(shape_MNK), dC)); // dC strides for shape MN
//
// Full and Tiled Tensors
//
// Represent the full tensors
auto [M, N, K] = shape_MNK;
Tensor mA = tma_a.get_tma_tensor(make_shape(M,K)); // (M,K) TMA Tensor
Tensor mB = tma_b.get_tma_tensor(make_shape(N,K)); // (N,K) TMA Tensor
Tensor mC = make_tensor(make_gmem_ptr(C), make_shape(M,N), dC); // (M,N)
// Get the appropriate blocks for this thread block
auto cta_coord = make_coord(blockIdx.x, blockIdx.y, _); // (m,n,k)
Tensor gA = local_tile(mA, cta_tiler, cta_coord, Step<_1, X,_1>{}); // (BLK_M,BLK_K,k)
Tensor gB = local_tile(mB, cta_tiler, cta_coord, Step< X,_1,_1>{}); // (BLK_N,BLK_K,k)
Tensor gC = local_tile(mC, cta_tiler, cta_coord, Step<_1,_1, X>{}); // (BLK_M,BLK_N)
// Shared memory tensors
extern __shared__ char shared_memory[];
using SharedStorage = SharedStorage<TA, TB, SmemLayoutA, SmemLayoutB>;
SharedStorage& smem = *reinterpret_cast<SharedStorage*>(shared_memory);
Tensor sA = make_tensor(make_smem_ptr(smem.smem_A.data()), SmemLayoutA{}); // (BLK_M,BLK_K,PIPE)
Tensor sB = make_tensor(make_smem_ptr(smem.smem_B.data()), SmemLayoutB{}); // (BLK_N,BLK_K,PIPE)
//
// Partition the copying of A and B tiles
//
// TUTORIAL:
// These are TMA partitionings, which have a dedicated custom partitioner.
// The Int<0>, Layout<_1> indicates that the TMAs are not multicasted.
// Any multicasting must be in conformance with tma_x constructed with make_tma_atom on host.
// The group_modes<0,2> transforms the (X,Y,Z)-shaped tensors into ((X,Y),Z)-shaped tensors
// with the understanding that the TMA is responsible for everything in mode-0.
// The tma_partition reorders and offsets mode-0 according to the tma_x atom and the multicast info.
//
auto [tAgA, tAsA] = tma_partition(tma_a, Int<0>{}, Layout<_1>{},
group_modes<0,2>(sA), group_modes<0,2>(gA)); // (TMA,k) and (TMA,PIPE)
auto [tBgB, tBsB] = tma_partition(tma_b, Int<0>{}, Layout<_1>{},
group_modes<0,2>(sB), group_modes<0,2>(gB)); // (TMA,k) and (TMA,PIPE)
// The TMA is responsible for copying everything in mode-0 of tAsA and tBsB
constexpr int kTmaTransactionBytes = CUTE_STATIC_V(size<0>(tAsA)) * sizeof(TA) +
CUTE_STATIC_V(size<0>(tBsB)) * sizeof(TB);
//
// PREFETCH
//
auto K_PIPE_MAX = size<1>(tAsA);
// Total count of tiles
int k_tile_count = size<1>(tAgA);
// Current tile index in gmem to read from
int k_tile = 0;
// Initialize Barriers
int warp_idx = cutlass::canonical_warp_idx_sync();
int lane_predicate = cute::elect_one_sync();
uint64_t* producer_mbar = smem.tma_barrier;
uint64_t* consumer_mbar = smem.mma_barrier;
using ProducerBarType = cutlass::arch::ClusterTransactionBarrier; // TMA
using ConsumerBarType = cutlass::arch::ClusterBarrier; // MMA
CUTE_UNROLL
for (int pipe = 0; pipe < K_PIPE_MAX; ++pipe) {
if ((warp_idx == 0) && lane_predicate) {
ProducerBarType::init(&producer_mbar[pipe], 1);
ConsumerBarType::init(&consumer_mbar[pipe], 128);
}
}
// Ensure barrier init is complete on all CTAs
cluster_sync();
// Start async loads for all pipes
CUTE_UNROLL
for (int pipe = 0; pipe < K_PIPE_MAX; ++pipe)
{
if ((warp_idx == 0) && lane_predicate)
{
// Set expected Tx Bytes after each reset / init
ProducerBarType::arrive_and_expect_tx(&producer_mbar[pipe], kTmaTransactionBytes);
copy(tma_a.with(producer_mbar[pipe]), tAgA(_,k_tile), tAsA(_,pipe));
copy(tma_b.with(producer_mbar[pipe]), tBgB(_,k_tile), tBsB(_,pipe));
}
--k_tile_count;
++k_tile;
}
//
// Define A/B partitioning and C accumulators
//
// TUTORIAL:
// The tCrA and tCrB are actually Tensors of MMA Descriptors constructed as views of SMEM.
// The MMA Descriptor generation is automatic via inspection and validation of the SMEM Layouts.
// Because the MMA reads directly from SMEM and the fragments are descriptors rather than registers,
// there is no need for copy(tCsA, tCrA) in the mainloop.
//
ThrMMA thr_mma = mma.get_thread_slice(threadIdx.x);
Tensor tCsA = thr_mma.partition_A(sA); // (MMA,MMA_M,MMA_K,PIPE)
Tensor tCsB = thr_mma.partition_B(sB); // (MMA,MMA_N,MMA_K,PIPE)
Tensor tCgC = thr_mma.partition_C(gC); // (MMA,MMA_M,MMA_N)
// Allocate accumulators and clear them
Tensor tCrC = thr_mma.make_fragment_C(tCgC); // (MMA,MMA_M,MMA_N)
clear(tCrC);
// Allocate "fragments"
Tensor tCrA = thr_mma.make_fragment_A(tCsA); // (MMA,MMA_M,MMA_K,PIPE)
Tensor tCrB = thr_mma.make_fragment_B(tCsB); // (MMA,MMA_N,MMA_K,PIPE)
//
// PIPELINED MAIN LOOP
//
// TUTORIAL:
// Rather than interleaving the stages and instructions like in SM70 and SM80,
// the SM90 mainloops rely on explicit producer-consumer synchronization
// on the purely async instructions TMA and MMA.
// More advanced pipeline and warp-specialization strategies are available in CUTLASS mainloops.
//
// A PipelineState is a circular pipe index [.index()] and a pipe phase [.phase()]
// that flips each cycle through K_PIPE_MAX.
auto write_state = cutlass::PipelineState<K_PIPE_MAX>(); // TMA writes
auto read_state = cutlass::PipelineState<K_PIPE_MAX>(); // MMA reads
CUTE_NO_UNROLL
while (k_tile_count > -K_PIPE_MAX)
{
// Wait for Producer to complete
int read_pipe = read_state.index();
ProducerBarType::wait(&producer_mbar[read_pipe], read_state.phase());
// MMAs to cover 1 K_TILE
warpgroup_arrive();
gemm(mma, tCrA(_,_,_,read_pipe), tCrB(_,_,_,read_pipe), tCrC); // (V,M) x (V,N) => (V,M,N)
warpgroup_commit_batch();
// Wait for all MMAs in a K_TILE to complete
warpgroup_wait<0>();
// Notify that consumption is done
ConsumerBarType::arrive(&consumer_mbar[read_pipe]);
++read_state;
if ((warp_idx == 0) && lane_predicate)
{
int pipe = write_state.index();
// Wait for Consumer to complete consumption
ConsumerBarType::wait(&consumer_mbar[pipe], write_state.phase());
// Set expected Tx Bytes after each reset / init
ProducerBarType::arrive_and_expect_tx(&producer_mbar[pipe], kTmaTransactionBytes);
copy(tma_a.with(producer_mbar[pipe]), tAgA(_,k_tile), tAsA(_,pipe));
copy(tma_b.with(producer_mbar[pipe]), tBgB(_,k_tile), tBsB(_,pipe));
++write_state;
}
--k_tile_count;
++k_tile;
}
//
// Epilogue (unpredicated)
//
axpby(alpha, tCrC, beta, tCgC);
}
// Setup params for an NT GEMM
template <class TA, class TB, class TC,
class Alpha, class Beta>
void
gemm_nt(int m, int n, int k,
Alpha alpha,
TA const* A, int ldA,
TB const* B, int ldB,
Beta beta,
TC * C, int ldC,
cudaStream_t stream = 0)
{
// Define shapes (dynamic)
auto M = int(m);
auto N = int(n);
auto K = int(k);
auto prob_shape = make_shape(M, N, K); // (M, N, K)
// Define TN strides (mixed)
auto dA = make_stride(Int<1>{}, ldA); // (dM, dK)
auto dB = make_stride(Int<1>{}, ldB); // (dN, dK)
auto dC = make_stride(Int<1>{}, ldC); // (dM, dN)
// Define CTA tile sizes (static)
auto bM = Int<128>{};
auto bN = Int<128>{};
auto bK = Int< 64>{};
auto cta_tiler = make_shape(bM, bN, bK); // (BLK_M, BLK_N, BLK_K)
auto bP = Int< 3>{}; // Pipeline
// Define the smem layouts (static)
auto sA = tile_to_shape(GMMA::Layout_MN_SW128_Atom<TA>{}, make_shape(bM,bK,bP));
auto sB = tile_to_shape(GMMA::Layout_MN_SW128_Atom<TB>{}, make_shape(bN,bK,bP));
// Define the MMA
TiledMMA tiled_mma = make_tiled_mma(SM90_64x64x16_F16F16F16_SS<GMMA::Major::MN,GMMA::Major::MN>{});
// Define the TMAs
// Create Global memory tensors for TMA inspection
Tensor mA = make_tensor(A, make_shape(M,K), dA);
Tensor mB = make_tensor(B, make_shape(N,K), dB);
// Create TMA Atoms with the desired copy operation on the source and destination
Copy_Atom tmaA = make_tma_atom(SM90_TMA_LOAD{}, mA, sA(_,_,0), make_shape(bM,bK));
Copy_Atom tmaB = make_tma_atom(SM90_TMA_LOAD{}, mB, sB(_,_,0), make_shape(bN,bK));
//
// Setup and Launch
//
// Launch parameter setup
int smem_size = int(sizeof(SharedStorage<TA, TB, decltype(sA), decltype(sB)>));
dim3 dimBlock(size(tiled_mma));
dim3 dimCluster(2, 1, 1);
dim3 dimGrid(round_up(size(ceil_div(m, bM)), dimCluster.x),
round_up(size(ceil_div(n, bN)), dimCluster.y));
cutlass::ClusterLaunchParams params = {dimGrid, dimBlock, dimCluster, smem_size};
void const* kernel_ptr = reinterpret_cast<void const*>(
&gemm_device<decltype(prob_shape), decltype(cta_tiler),
TA, decltype(sA), decltype(tmaA),
TB, decltype(sB), decltype(tmaB),
TC, decltype(dC), decltype(tiled_mma),
decltype(alpha), decltype(beta)>);
CUTE_CHECK_ERROR(cudaFuncSetAttribute(
kernel_ptr,
cudaFuncAttributeMaxDynamicSharedMemorySize,
smem_size));
// Kernel Launch
cutlass::Status status = cutlass::launch_kernel_on_cluster(params, kernel_ptr,
prob_shape, cta_tiler,
A, tmaA,
B, tmaB,
C, dC, tiled_mma,
alpha, beta);
CUTE_CHECK_LAST();
if (status != cutlass::Status::kSuccess) {
std::cerr << "Error: Failed at kernel Launch" << std::endl;
}
}
// Setup params for a TN GEMM
template <class TA, class TB, class TC,
class Alpha, class Beta>
void
gemm_tn(int m, int n, int k,
Alpha alpha,
TA const* A, int ldA,
TB const* B, int ldB,
Beta beta,
TC * C, int ldC,
cudaStream_t stream = 0)
{
// Define shapes (dynamic)
auto M = int(m);
auto N = int(n);
auto K = int(k);
auto prob_shape = make_shape(M, N, K); // (M, N, K)
// Define TN strides (mixed)
auto dA = make_stride(ldA, Int<1>{}); // (dM, dK)
auto dB = make_stride(ldB, Int<1>{}); // (dN, dK)
auto dC = make_stride(Int<1>{}, ldC); // (dM, dN)
// Define CTA tile sizes (static)
auto bM = Int<128>{};
auto bN = Int<128>{};
auto bK = Int< 64>{};
auto cta_tiler = make_shape(bM, bN, bK); // (BLK_M, BLK_N, BLK_K)
auto bP = Int<3>{}; // Pipeline
// Define the smem layouts (static)
auto sA = tile_to_shape(GMMA::Layout_K_SW128_Atom<TA>{}, make_shape(bM,bK,bP));
auto sB = tile_to_shape(GMMA::Layout_K_SW128_Atom<TB>{}, make_shape(bN,bK,bP));
// Define the MMA
TiledMMA tiled_mma = make_tiled_mma(SM90_64x64x16_F16F16F16_SS<GMMA::Major::K,GMMA::Major::K>{});
// Define the TMAs
// Create Global memory tensors for TMA inspection
Tensor mA = make_tensor(A, make_shape(M,K), dA);
Tensor mB = make_tensor(B, make_shape(N,K), dB);
// Create TMA Atoms with the desired copy operation on the source and destination
Copy_Atom tmaA = make_tma_atom(SM90_TMA_LOAD{}, mA, sA(_,_,0), make_shape(bM,bK));
Copy_Atom tmaB = make_tma_atom(SM90_TMA_LOAD{}, mB, sB(_,_,0), make_shape(bN,bK));
//
// Setup and Launch
//
// Launch parameter setup
int smem_size = int(sizeof(SharedStorage<TA, TB, decltype(sA), decltype(sB)>));
dim3 dimBlock(size(tiled_mma));
dim3 dimCluster(2, 1, 1);
dim3 dimGrid(round_up(size(ceil_div(m, bM)), dimCluster.x),
round_up(size(ceil_div(n, bN)), dimCluster.y));
cutlass::ClusterLaunchParams params = {dimGrid, dimBlock, dimCluster, smem_size};
void const* kernel_ptr = reinterpret_cast<void const*>(
&gemm_device<decltype(prob_shape), decltype(cta_tiler),
TA, decltype(sA), decltype(tmaA),
TB, decltype(sB), decltype(tmaB),
TC, decltype(dC), decltype(tiled_mma),
decltype(alpha), decltype(beta)>);
CUTE_CHECK_ERROR(cudaFuncSetAttribute(
kernel_ptr,
cudaFuncAttributeMaxDynamicSharedMemorySize,
smem_size));
// Kernel Launch
cutlass::Status status = cutlass::launch_kernel_on_cluster(params, kernel_ptr,
prob_shape, cta_tiler,
A, tmaA,
B, tmaB,
C, dC, tiled_mma,
alpha, beta);
CUTE_CHECK_LAST();
if (status != cutlass::Status::kSuccess) {
std::cerr << "Error: Failed at kernel Launch" << std::endl;
}
}
template <class TA, class TB, class TC,
class Alpha, class Beta>
void
gemm(char transA, char transB, int m, int n, int k,
Alpha alpha,
TA const* A, int ldA,
TB const* B, int ldB,
Beta beta,
TC * C, int ldC,
cudaStream_t stream = 0)
{
if (transA == 'N' && transB == 'T') {
return gemm_nt(m, n, k, alpha, A, ldA, B, ldB, beta, C, ldC, stream);
} else
if (transA == 'T' && transB == 'N') {
return gemm_tn(m, n, k, alpha, A, ldA, B, ldB, beta, C, ldC, stream);
}
assert(false && "Not implemented");
}
int main(int argc, char** argv)
{
cudaDeviceProp props;
cudaError_t error = cudaGetDeviceProperties(&props, 0);
if (error != cudaSuccess) {
std::cerr << "cudaGetDeviceProperties() returned an error: " << cudaGetErrorString(error) << std::endl;
return -1;
}
if (props.major != 9) {
std::cout << "This example requires NVIDIA's Hopper Architecture GPU with compute capability 90a\n" << std::endl;
return 0;
}
#if defined(CUTLASS_ARCH_MMA_SM90_SUPPORTED)
int m = 512;
if (argc >= 2)
sscanf(argv[1], "%d", &m);
int n = 256;
if (argc >= 3)
sscanf(argv[2], "%d", &n);
int k = 1024;
if (argc >= 4)
sscanf(argv[3], "%d", &k);
char transA = 'N';
if (argc >= 5)
sscanf(argv[4], "%c", &transA);
char transB = 'T';
if (argc >= 6)
sscanf(argv[5], "%c", &transB);
using TA = cute::half_t;
using TB = cute::half_t;
using TC = cute::half_t;
using TI = cute::half_t;
TI alpha = TI(1.0f);
TI beta = TI(0.0f);
thrust::host_vector<TA> h_A(m*k);
thrust::host_vector<TB> h_B(n*k);
thrust::host_vector<TC> h_C(m*n);
// Initialize the tensors
for (int j = 0; j < m*k; ++j) h_A[j] = TA(int((rand() % 2) ? 1 : -1));
for (int j = 0; j < n*k; ++j) h_B[j] = TB(int((rand() % 2) ? 1 : -1));
for (int j = 0; j < m*n; ++j) h_C[j] = TC(0);
thrust::device_vector<TA> d_A = h_A;
thrust::device_vector<TB> d_B = h_B;
thrust::device_vector<TC> d_C = h_C;
double gflops = (2.0*m*n*k) * 1e-9;
const int timing_iterations = 100;
GPU_Clock timer;
int ldA = 0, ldB = 0, ldC = m;
if (transA == 'N') {
ldA = m;
} else if (transA == 'T') {
ldA = k;
} else {
assert(false);
}
if (transB == 'N') {
ldB = k;
} else if (transB == 'T') {
ldB = n;
} else {
assert(false);
}
// Run once
d_C = h_C;
gemm(transA, transB, m, n, k,
alpha,
d_A.data().get(), ldA,
d_B.data().get(), ldB,
beta,
d_C.data().get(), ldC);
CUTE_CHECK_LAST();
thrust::host_vector<TC> cute_result = d_C;
// Timing iterations
timer.start();
for (int i = 0; i < timing_iterations; ++i) {
gemm(transA, transB, m, n, k,
alpha,
d_A.data().get(), ldA,
d_B.data().get(), ldB,
beta,
d_C.data().get(), ldC);
}
double cute_time = timer.seconds() / timing_iterations;
CUTE_CHECK_LAST();
printf("CUTE_GEMM: [%6.1f]GFlop/s (%6.4f)ms\n", gflops / cute_time, cute_time*1000);
#else
std::cout << "CUTLASS_ARCH_MMA_SM90_SUPPORTED must be enabled, but it is not. Test is waived \n" << std::endl;
#endif
return 0;
}