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/******************************************************************************
* Copyright (c) 2023, Tri Dao.
******************************************************************************/
#pragma once
// #include <c10/cuda/CUDAException.h> // For C10_CUDA_CHECK and C10_CUDA_KERNEL_LAUNCH_CHECK
#include "error.h"
#include "static_switch.h"
#include "hardware_info.h"
#include "flash.h"
#include "flash_fwd_kernel.h"
// Determine if the architecture supports FLASH and define a macro to handle parameter modifiers
#if defined(__CUDA_ARCH__) && __CUDA_ARCH__ >= 800
#define ARCH_SUPPORTS_FLASH
#define KERNEL_PARAM_MODIFIER __grid_constant__
#else
#define KERNEL_PARAM_MODIFIER
#endif
// Define a macro for unsupported architecture handling to centralize the error message
#define FLASH_UNSUPPORTED_ARCH printf("FATAL: FlashAttention requires building with sm version sm80-sm90, but was built for < 8.0!");
// Use a macro to clean up kernel definitions
#define DEFINE_FLASH_FORWARD_KERNEL(kernelName, ...) \
template<typename Kernel_traits, __VA_ARGS__> \
__global__ void kernelName(KERNEL_PARAM_MODIFIER const Flash_fwd_params params)
DEFINE_FLASH_FORWARD_KERNEL(flash_fwd_kernel, bool Is_dropout, bool Is_causal, bool Is_local, bool Has_alibi, bool Is_even_MN, bool Is_even_K, bool Is_softcap, bool Return_softmax) {
#if defined(ARCH_SUPPORTS_FLASH)
static_assert(!(Is_causal && Is_local)); // Enforce constraints
flash::compute_attn<Kernel_traits, Is_dropout, Is_causal, Is_local, Has_alibi, Is_even_MN, Is_even_K, Is_softcap, Return_softmax>(params);
#else
FLASH_UNSUPPORTED_ARCH
#endif
}
DEFINE_FLASH_FORWARD_KERNEL(flash_fwd_splitkv_kernel, bool Is_causal, bool Is_local, bool Has_alibi, bool Is_even_MN, bool Is_even_K, bool Is_softcap, bool Split, bool Append_KV) {
#if defined(ARCH_SUPPORTS_FLASH)
flash::compute_attn_splitkv<Kernel_traits, Is_causal, Is_local, Has_alibi, Is_even_MN, Is_even_K, Is_softcap, Split, Append_KV>(params);
#else
FLASH_UNSUPPORTED_ARCH
#endif
}
DEFINE_FLASH_FORWARD_KERNEL(flash_fwd_splitkv_combine_kernel, int kBlockM, int Log_max_splits, bool Is_even_K) {
static_assert(Log_max_splits >= 1);
flash::combine_attn_seqk_parallel<Kernel_traits, kBlockM, Log_max_splits, Is_even_K>(params);
}
template<typename Kernel_traits, bool Is_dropout, bool Is_causal>
void run_flash_fwd(Flash_fwd_params ¶ms, cudaStream_t stream) {
constexpr size_t smem_size = Kernel_traits::kSmemSize;
// printf("smem_size = %d\n", smem_size);
// Work-around for gcc 7. It doesn't like nested BOOL_SWITCH.
// https://github.com/kokkos/kokkos-kernels/issues/349
// https://github.com/HazyResearch/flash-attention/issues/21
const int num_m_block = (params.seqlen_q + Kernel_traits::kBlockM - 1) / Kernel_traits::kBlockM;
dim3 grid(num_m_block, params.b, params.h);
const bool is_even_MN = params.cu_seqlens_q == nullptr && params.cu_seqlens_k == nullptr && params.seqlen_k % Kernel_traits::kBlockN == 0 && params.seqlen_q % Kernel_traits::kBlockM == 0;
const bool is_even_K = params.d == Kernel_traits::kHeadDim;
const bool return_softmax = params.p_ptr != nullptr;
BOOL_SWITCH(is_even_MN, IsEvenMNConst, [&] {
EVENK_SWITCH(is_even_K, IsEvenKConst, [&] {
LOCAL_SWITCH((params.window_size_left >= 0 || params.window_size_right >= 0) && !Is_causal, Is_local, [&] {
BOOL_SWITCH(return_softmax, ReturnSoftmaxConst, [&] {
ALIBI_SWITCH(params.alibi_slopes_ptr != nullptr, Has_alibi, [&] {
SOFTCAP_SWITCH(params.softcap > 0.0, Is_softcap, [&] {
// Will only return softmax if dropout, to reduce compilation time.
// If not IsEvenKConst, we also set IsEvenMNConst to false to reduce number of templates.
// If return_softmax, set IsEvenMNConst to false to reduce number of templates
// If head dim > 128, set IsEvenMNConst to false to reduce number of templates
// If Is_local, set Is_causal to false
auto kernel = &flash_fwd_kernel<Kernel_traits, Is_dropout && !Is_softcap, Is_causal, Is_local && !Is_causal, Has_alibi, IsEvenMNConst && IsEvenKConst && !Is_local && !ReturnSoftmaxConst && Kernel_traits::kHeadDim <= 128, IsEvenKConst, Is_softcap, ReturnSoftmaxConst && Is_dropout && !Is_softcap>;
// auto kernel = &flash_fwd_kernel<Kernel_traits, false, Is_causal, false, false, true, true, false>;
// printf("IsEvenMNConst = %d, IsEvenKConst = %d, Is_local = %d, Is_causal = %d, ReturnSoftmaxConst = %d, Is_dropout = %d\n", int(IsEvenMNConst), int(IsEvenKConst), int(Is_local), int(Is_causal), int(ReturnSoftmaxConst), int(Is_dropout));
// auto kernel = &flash_fwd_kernel<Kernel_traits, false, Is_causal, false, true, true, false>;
if (smem_size >= 48 * 1024) {
C10_CUDA_CHECK(cudaFuncSetAttribute(
kernel, cudaFuncAttributeMaxDynamicSharedMemorySize, smem_size));
}
// int ctas_per_sm;
// cudaError status_ = cudaOccupancyMaxActiveBlocksPerMultiprocessor(
// &ctas_per_sm, kernel, Kernel_traits::kNThreads, smem_size);
// printf("smem_size = %d, CTAs per SM = %d\n", int(smem_size), ctas_per_sm);
kernel<<<grid, Kernel_traits::kNThreads, smem_size, stream>>>(params);
C10_CUDA_KERNEL_LAUNCH_CHECK();
});
});
});
});
});
});
}
template<typename Kernel_traits, bool Is_causal>
void run_flash_splitkv_fwd(Flash_fwd_params ¶ms, cudaStream_t stream) {
static_assert(!Kernel_traits::Is_Q_in_regs, "SplitKV implementation does not support Is_Q_in_regs");
static_assert(!Kernel_traits::Share_Q_K_smem, "SplitKV implementation does not support Share_Q_K_smem");
constexpr size_t smem_size = Kernel_traits::kSmemSize;
const int num_m_block = (params.seqlen_q + Kernel_traits::kBlockM - 1) / Kernel_traits::kBlockM;
dim3 grid(num_m_block, params.num_splits > 1 ? params.num_splits : params.b, params.num_splits > 1 ? params.b * params.h : params.h);
const bool is_even_MN = params.cu_seqlens_q == nullptr && params.cu_seqlens_k == nullptr && params.seqlen_k % Kernel_traits::kBlockN == 0 && params.seqlen_q % Kernel_traits::kBlockM == 0;
const bool is_even_K = params.d == Kernel_traits::kHeadDim;
BOOL_SWITCH(is_even_MN, IsEvenMNConst, [&] {
EVENK_SWITCH(is_even_K, IsEvenKConst, [&] {
LOCAL_SWITCH((params.window_size_left >= 0 || params.window_size_right >= 0) && !Is_causal, Is_local, [&] {
BOOL_SWITCH(params.num_splits > 1, Split, [&] {
BOOL_SWITCH(params.knew_ptr != nullptr, Append_KV, [&] {
ALIBI_SWITCH(params.alibi_slopes_ptr != nullptr, Has_alibi, [&] {
SOFTCAP_SWITCH(params.softcap > 0.0, Is_softcap, [&] {
// If Append_KV, then we must have seqlen_offsets, which means cu_seqlens_k != nullptr.
// If not IsEvenKConst, we also set IsEvenMNConst to false to reduce number of templates.
// If Is_local, set Is_causal to false
auto kernel = &flash_fwd_splitkv_kernel<Kernel_traits, Is_causal, Is_local && !Is_causal, Has_alibi, IsEvenMNConst && !Append_KV && IsEvenKConst && !Is_local && Kernel_traits::kHeadDim <= 128, IsEvenKConst, Is_softcap, Split, Append_KV>;
// auto kernel = &flash_fwd_splitkv_kernel<Kernel_traits, Is_causal, false, true, Split, Append_KV>;
// auto kernel = &flash_fwd_splitkv_kernel<Kernel_traits, Is_causal, false, IsEvenKConst>;
if (smem_size >= 48 * 1024) {
C10_CUDA_CHECK(cudaFuncSetAttribute(
kernel, cudaFuncAttributeMaxDynamicSharedMemorySize, smem_size));
}
kernel<<<grid, Kernel_traits::kNThreads, smem_size, stream>>>(params);
C10_CUDA_KERNEL_LAUNCH_CHECK();
});
});
});
});
});
});
});
if (params.num_splits > 1) {
// We want kBlockM to be as small as possible for more parallelism.
// With 128 threads we can load 512 elements at a time, so if headdim is divisible by 128, kBlockM = 4.
// If headdim is divisible by 64, then we set kBlockM = 8, etc.
constexpr static int kBlockM = Kernel_traits::kHeadDim % 128 == 0 ? 4 : (Kernel_traits::kHeadDim % 64 == 0 ? 8 : 16);
dim3 grid_combine((params.b * params.h * params.seqlen_q + kBlockM - 1) / kBlockM);
EVENK_SWITCH(is_even_K, IsEvenKConst, [&] {
if (params.num_splits <= 2) {
flash_fwd_splitkv_combine_kernel<Kernel_traits, kBlockM, 1, IsEvenKConst><<<grid_combine, Kernel_traits::kNThreads, 0, stream>>>(params);
} else if (params.num_splits <= 4) {
flash_fwd_splitkv_combine_kernel<Kernel_traits, kBlockM, 2, IsEvenKConst><<<grid_combine, Kernel_traits::kNThreads, 0, stream>>>(params);
} else if (params.num_splits <= 8) {
flash_fwd_splitkv_combine_kernel<Kernel_traits, kBlockM, 3, IsEvenKConst><<<grid_combine, Kernel_traits::kNThreads, 0, stream>>>(params);
} else if (params.num_splits <= 16) {
flash_fwd_splitkv_combine_kernel<Kernel_traits, kBlockM, 4, IsEvenKConst><<<grid_combine, Kernel_traits::kNThreads, 0, stream>>>(params);
} else if (params.num_splits <= 32) {
flash_fwd_splitkv_combine_kernel<Kernel_traits, kBlockM, 5, IsEvenKConst><<<grid_combine, Kernel_traits::kNThreads, 0, stream>>>(params);
} else if (params.num_splits <= 64) {
flash_fwd_splitkv_combine_kernel<Kernel_traits, kBlockM, 6, IsEvenKConst><<<grid_combine, Kernel_traits::kNThreads, 0, stream>>>(params);
} else if (params.num_splits <= 128) {
flash_fwd_splitkv_combine_kernel<Kernel_traits, kBlockM, 7, IsEvenKConst><<<grid_combine, Kernel_traits::kNThreads, 0, stream>>>(params);
}
C10_CUDA_KERNEL_LAUNCH_CHECK();
});
}
}
template<typename T, int Headdim, bool Is_causal>
void run_mha_fwd_splitkv_dispatch(Flash_fwd_params ¶ms, cudaStream_t stream) {
constexpr static int kBlockM = 64; // Fixed for all head dimensions
// TD [2023-08-28]: nvcc segfaults for headdim 96 with block size 64 x 256,
// and for headdim 192 with block size 64 x 128.
// Also for headdim 160 with block size 64 x 128 after the rotary addition.
constexpr static int kBlockN = Headdim <= 64 ? 256 : (Headdim <= 128 ? 128 : 64);
run_flash_splitkv_fwd<Flash_fwd_kernel_traits<Headdim, kBlockM, kBlockN, 4, false, false, T>, Is_causal>(params, stream);
}
template<typename T, bool Is_causal>
void run_mha_fwd_hdim32(Flash_fwd_params ¶ms, cudaStream_t stream) {
constexpr static int Headdim = 32;
DROPOUT_SWITCH(params.p_dropout < 1.f, Is_dropout, [&] {
run_flash_fwd<Flash_fwd_kernel_traits<Headdim, 128, 128, 4, false, false, T>, Is_dropout, Is_causal>(params, stream);
});
}
template<typename T, bool Is_causal>
void run_mha_fwd_hdim64(Flash_fwd_params ¶ms, cudaStream_t stream) {
constexpr static int Headdim = 64;
DROPOUT_SWITCH(params.p_dropout < 1.f, Is_dropout, [&] {
if constexpr(!Is_dropout) {
// Using 8 warps is 18% slower for seqlen=2k, 2 warps is 5% slower
// Using block size (64 x 256) is 27% slower for seqlen=2k
// Using block size (256 x 64) is 85% slower for seqlen=2k, because of register spilling
run_flash_fwd<Flash_fwd_kernel_traits<Headdim, 128, 128, 4, false, false, T>, Is_dropout, Is_causal>(params, stream);
// run_flash_fwd<Flash_fwd_kernel_traits<Headdim, 128, 64, 4, true, false, T>, Is_dropout, Is_causal>(params, stream);
// run_flash_fwd<Flash_fwd_kernel_traits<Headdim, 128, 64, 4, true, true, T>, Is_dropout, Is_causal>(params, stream);
} else {
run_flash_fwd<Flash_fwd_kernel_traits<Headdim, 128, 64, 4, false, false, T>, Is_dropout, Is_causal>(params, stream);
// run_flash_fwd<Flash_fwd_kernel_traits<Headdim, 128, 64, 4, true, true, T>, Is_dropout, Is_causal>(params, stream);
// run_flash_fwd<Flash_fwd_kernel_traits<Headdim, 128, 64, 4, true, false, T>, Is_dropout, Is_causal>(params, stream);
// run_flash_fwd<Flash_fwd_kernel_traits<Headdim, 128, 128, 4, false, false, T>, Is_dropout, Is_causal>(params, stream);
}
});
}
inline bool cuda_is_sm8x() {
// dprops = at::cuda::getCurrentDeviceProperties();
// return dprops->major == 8 && dprops->minor > 0;
return false;
}
template<typename T, bool Is_causal>
void run_mha_fwd_hdim96(Flash_fwd_params ¶ms, cudaStream_t stream) {
constexpr static int Headdim = 96;
auto [cc_major, cc_minor] = get_compute_capability(get_current_device());
bool is_sm8x = cc_major == 8 && cc_minor > 0;
DROPOUT_SWITCH(params.p_dropout < 1.f, Is_dropout, [&] {
// For sm86 or sm89, 64 x 64 is the fastest for causal (because it's square),
if (is_sm8x) {
if constexpr(!Is_causal) {
run_flash_fwd<Flash_fwd_kernel_traits<Headdim, 128, 64, 4, false, false, T>, Is_dropout, Is_causal>(params, stream);
} else {
run_flash_fwd<Flash_fwd_kernel_traits<Headdim, 64, 64, 4, false, false, T>, Is_dropout, Is_causal>(params, stream);
}
} else {
run_flash_fwd<Flash_fwd_kernel_traits<Headdim, 128, 64, 4, false, false, T>, Is_dropout, Is_causal>(params, stream);
}
// run_flash_fwd<Flash_fwd_kernel_traits<Headdim, 128, 64, 4, true, false, T>, Is_dropout, Is_causal>(params, stream);
// run_flash_fwd<Flash_fwd_kernel_traits<Headdim, 128, 64, 4, true, true, T>, Is_dropout, Is_causal>(params, stream);
// These two are always slower
// run_flash_fwd<Flash_fwd_kernel_traits<96, 128, 128, 4, true, T>>(params, stream);
// run_flash_fwd<Flash_fwd_kernel_traits<96, 64, 128, 4, true, T>>(params, stream);
});
}
template<typename T, bool Is_causal>
void run_mha_fwd_hdim128(Flash_fwd_params ¶ms, cudaStream_t stream) {
constexpr static int Headdim = 128;
auto [cc_major, cc_minor] = get_compute_capability(get_current_device());
bool is_sm8x = cc_major == 8 && cc_minor > 0;
DROPOUT_SWITCH(params.p_dropout < 1.f, Is_dropout, [&] {
if constexpr(!Is_dropout) {
// For sm86 or sm89, 64 x 64 is the fastest for causal (because it's square),
// and 128 x 32 (48 KB smem) is the fastest for non-causal since we get 2 CTAs per SM.
if (is_sm8x) {
if constexpr(!Is_causal) {
run_flash_fwd<Flash_fwd_kernel_traits<Headdim, 128, 32, 4, false, false, T>, Is_dropout, Is_causal>(params, stream);
} else {
run_flash_fwd<Flash_fwd_kernel_traits<Headdim, 64, 64, 4, false, false, T>, Is_dropout, Is_causal>(params, stream);
}
} else {
run_flash_fwd<Flash_fwd_kernel_traits<Headdim, 128, 64, 4, false, false, T>, Is_dropout, Is_causal>(params, stream);
}
// run_flash_fwd<Flash_fwd_kernel_traits<Headdim, 128, 64, 4, true, false, T>, Is_dropout, Is_causal>(params, stream);
// run_flash_fwd<Flash_fwd_kernel_traits<Headdim, 128, 64, 4, true, true, T>, Is_dropout, Is_causal>(params, stream);
// run_flash_fwd<Flash_fwd_kernel_traits<Headdim, 64, 128, 4, false, false, T>, Is_dropout, Is_causal>(params, stream);
// Using 8 warps (128 x 128 and 256 x 64) is 28% slower for seqlen=2k
// run_flash_fwd<Flash_fwd_kernel_traits<Headdim, 128, 128, 8, false, false, T>, Is_dropout, Is_causal>(params, stream);
// run_flash_fwd<Flash_fwd_kernel_traits<Headdim, 128, 64, 8, false, false, T>, Is_dropout, Is_causal>(params, stream);
// 1st ones are good for H100, A100
// 2nd one is good for A6000 bc we get slightly better occupancy
} else {
run_flash_fwd<Flash_fwd_kernel_traits<Headdim, 128, 32, 4, false, false, T>, Is_dropout, Is_causal>(params, stream);
// run_flash_fwd<Flash_fwd_kernel_traits<Headdim, 64, 64, 4, false, false, T>, Is_dropout, Is_causal>(params, stream);
// run_flash_fwd<Flash_fwd_kernel_traits<Headdim, 128, 32, 4, true, false, T>, Is_dropout, Is_causal>(params, stream);
// run_flash_fwd<Flash_fwd_kernel_traits<Headdim, 128, 32, 4, true, true, T>, Is_dropout, Is_causal>(params, stream);
}
});
}
template<typename T, bool Is_causal>
void run_mha_fwd_hdim160(Flash_fwd_params ¶ms, cudaStream_t stream) {
constexpr static int Headdim = 160;
auto [cc_major, cc_minor] = get_compute_capability(get_current_device());
bool is_sm8x = cc_major == 8 && cc_minor > 0;
DROPOUT_SWITCH(params.p_dropout < 1.f, Is_dropout, [&] {
// For A100, H100, 128 x 32 is the fastest.
// For sm86 or sm89, 64 x 64 is the fastest for causal (because it's square),
// and 128 x 64 with 8 warps is the fastest for non-causal.
if (is_sm8x) {
if constexpr(!Is_causal) {
run_flash_fwd<Flash_fwd_kernel_traits<Headdim, 128, 64, 8, false, false, T>, Is_dropout, Is_causal>(params, stream);
} else {
run_flash_fwd<Flash_fwd_kernel_traits<Headdim, 64, 64, 4, false, false, T>, Is_dropout, Is_causal>(params, stream);
}
} else {
run_flash_fwd<Flash_fwd_kernel_traits<Headdim, 128, 32, 4, false, false, T>, Is_dropout, Is_causal>(params, stream);
}
// run_flash_fwd<Flash_fwd_kernel_traits<Headdim, 128, 32, 4, false, true, T>, Is_dropout, Is_causal>(params, stream);
// run_flash_fwd<Flash_fwd_kernel_traits<Headdim, 128, 64, 4, false, false, T>, Is_dropout, Is_causal>(params, stream);
// run_flash_fwd<Flash_fwd_kernel_traits<Headdim, 128, 64, 4, false, T>>(params, stream);
// run_flash_fwd<Flash_fwd_kernel_traits<Headdim, 64, 128, 4, false, T>>(params, stream);
// run_flash_fwd<Flash_fwd_kernel_traits<Headdim, 64, 64, 4, false, T>>(params, stream);
// run_flash_fwd<Flash_fwd_kernel_traits<Headdim, 128, 64, 8, false, T>>(params, stream);
// run_flash_fwd<Flash_fwd_kernel_traits<Headdim, 128, 128, 8, false, T>>(params, stream);
});
}
template<typename T, bool Is_causal>
void run_mha_fwd_hdim192(Flash_fwd_params ¶ms, cudaStream_t stream) {
constexpr static int Headdim = 192;
DROPOUT_SWITCH(params.p_dropout < 1.f, Is_dropout, [&] {
if constexpr(!Is_dropout) {
run_flash_fwd<Flash_fwd_kernel_traits<Headdim, 128, 64, 8, false, false, T>, Is_dropout, Is_causal>(params, stream);
} else {
run_flash_fwd<Flash_fwd_kernel_traits<Headdim, 64, 64, 4, false, false, T>, Is_dropout, Is_causal>(params, stream);
}
// run_flash_fwd<Flash_fwd_kernel_traits<Headdim, 64, 32, 4, false, false, T>, Is_dropout, Is_causal>(params, stream);
// run_flash_fwd<Flash_fwd_kernel_traits<Headdim, 128, 32, 8, false, false, T>, Is_dropout, Is_causal>(params, stream);
// run_flash_fwd<Flash_fwd_kernel_traits<Headdim, 128, 64, 4, false, T>>(params, stream);
// run_flash_fwd<Flash_fwd_kernel_traits<Headdim, 64, 128, 4, false, T>>(params, stream);
// run_flash_fwd<Flash_fwd_kernel_traits<Headdim, 128, 128, 8, false, T>>(params, stream);
});
}
template<typename T, bool Is_causal>
void run_mha_fwd_hdim224(Flash_fwd_params ¶ms, cudaStream_t stream) {
constexpr static int Headdim = 224;
int device;
cudaGetDevice(&device);
int max_smem_per_block;
cudaError status_ = cudaDeviceGetAttribute(
&max_smem_per_block, cudaDevAttrMaxSharedMemoryPerBlockOptin, device);
if (status_ != cudaSuccess) {
C10_CUDA_CHECK(status_);
}
// printf("max_smem_per_block = %d\n", max_smem_per_block);
DROPOUT_SWITCH(params.p_dropout < 1.f, Is_dropout, [&] {
if (max_smem_per_block >= 2 * Headdim * (128 + 2 * 64)) { // 112 KB
run_flash_fwd<Flash_fwd_kernel_traits<Headdim, 128, 64, 8, false, false, T>, Is_dropout, Is_causal>(params, stream);
} else {
run_flash_fwd<Flash_fwd_kernel_traits<Headdim, 64, 64, 4, false, false, T>, Is_dropout, Is_causal>(params, stream);
}
// run_flash_fwd<Flash_fwd_kernel_traits<Headdim, 128, 32, 4, false, false, T>, Is_dropout, Is_causal>(params, stream);
// run_flash_fwd<Flash_fwd_kernel_traits<Headdim, 64, 32, 4, false, false, T>, Is_dropout, Is_causal>(params, stream);
// We can't do 128 x 32 with 8 warps because with headdim 224, kBlockKSmem = 32.
// If we have N = 32, there are only 1024 elements to load at once, where each load
// is 8 elements. This means we can only use 128 threads and not 256 threads.
// run_flash_fwd<Flash_fwd_kernel_traits<Headdim, 128, 32, 8, false, false, T>, Is_dropout, Is_causal>(params, stream);
});
}
template<typename T, bool Is_causal>
void run_mha_fwd_hdim256(Flash_fwd_params ¶ms, cudaStream_t stream) {
constexpr static int Headdim = 256;
int device;
cudaGetDevice(&device);
int max_smem_per_sm, max_smem_per_block;
cudaError status_ = cudaDeviceGetAttribute(
&max_smem_per_sm, cudaDevAttrMaxSharedMemoryPerMultiprocessor, device);
status_ = cudaDeviceGetAttribute(
&max_smem_per_block, cudaDevAttrMaxSharedMemoryPerBlockOptin, device);
if (status_ != cudaSuccess) {
C10_CUDA_CHECK(status_);
}
// printf("max_smem_per_sm = %d, max_smem_per_block = %d\n", max_smem_per_sm, max_smem_per_block);
DROPOUT_SWITCH(params.p_dropout < 1.f, Is_dropout, [&] {
// For A100, we want to run with 128 x 64 (128KB smem).
// For H100 we want to run with 64 x 64 (96KB smem) since then we can get 2 CTAs per SM.
if (max_smem_per_block >= 2 * Headdim * (128 + 2 * 64) && max_smem_per_sm < 4 * Headdim * (64 + 2 * 64)) {
run_flash_fwd<Flash_fwd_kernel_traits<Headdim, 128, 64, 8, false, false, T>, Is_dropout, Is_causal>(params, stream);
} else {
run_flash_fwd<Flash_fwd_kernel_traits<Headdim, 64, 64, 4, false, false, T>, Is_dropout, Is_causal>(params, stream);
}
// 64 KB
// run_flash_fwd<Flash_fwd_kernel_traits<Headdim, 64, 32, 4, false, false, T>, Is_dropout, Is_causal>(params, stream);
// 96 KB
// run_flash_fwd<Flash_fwd_kernel_traits<Headdim, 128, 32, 8, false, false, T>, Is_dropout, Is_causal>(params, stream);
});
}
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