/****************************************************************************** * Copyright (c) 2024, Tri Dao. ******************************************************************************/ #pragma once #include "namespace_config.h" #include // For C10_CUDA_CHECK and C10_CUDA_KERNEL_LAUNCH_CHECK #include "static_switch.h" #include "hardware_info.h" #include "flash.h" #include "flash_bwd_preprocess_kernel.h" #include "flash_bwd_kernel.h" namespace FLASH_NAMESPACE { // 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_BACKWARD_KERNEL(kernelName, ...) \ template \ __global__ void kernelName(KERNEL_PARAM_MODIFIER const Flash_bwd_params params) DEFINE_FLASH_BACKWARD_KERNEL(flash_bwd_dq_dk_dv_loop_kernel, bool Is_dropout, bool Is_causal, bool Has_alibi, bool Is_even_M, bool Is_even_K) { #if defined(ARCH_SUPPORTS_FLASH) FLASH_NAMESPACE::compute_dq_dk_dv(params); #else FLASH_UNSUPPORTED_ARCH #endif } DEFINE_FLASH_BACKWARD_KERNEL(flash_bwd_dq_dk_dv_loop_seqk_parallel_kernel, bool Is_dropout, bool Is_causal, bool Is_local, bool Has_alibi, bool Is_even_MN, bool Is_even_K, bool Is_softcap) { #if defined(ARCH_SUPPORTS_FLASH) static_assert(!(Is_causal && Is_local)); // If Is_local is true, Is_causal should be false FLASH_NAMESPACE::compute_dq_dk_dv_seqk_parallel(params); #else FLASH_UNSUPPORTED_ARCH #endif } template __global__ void flash_bwd_dot_do_o_kernel(const Flash_bwd_params params) { FLASH_NAMESPACE::compute_dot_do_o(params); } template __global__ void flash_bwd_clear_dkvaccum_kernel(const Flash_bwd_params params) { FLASH_NAMESPACE::clear_dKVaccum(params); } template __global__ void flash_bwd_convert_dq_kernel(const Flash_bwd_params params, const int nsplits) { FLASH_NAMESPACE::convert_dQ(params, nsplits); } template __global__ void flash_bwd_convert_dkv_kernel(const Flash_bwd_params params) { FLASH_NAMESPACE::convert_dKV(params); } template void run_flash_bwd_seqk_parallel(Flash_bwd_params ¶ms, cudaStream_t stream) { const int num_m_block = (params.seqlen_q + Kernel_traits::kBlockM - 1) / Kernel_traits::kBlockM; dim3 grid_m(num_m_block, params.b, params.h); const int num_n_block = (params.seqlen_k + Kernel_traits::kBlockN - 1) / Kernel_traits::kBlockN; int gridDimx = num_n_block; if (params.deterministic) { int num_sm = get_num_sm(get_current_device()); gridDimx = (num_sm + params.b * params.h - 1) / (params.b * params.h); } dim3 grid_n(gridDimx, params.b, params.h); if (!params.deterministic) { flash_bwd_dot_do_o_kernel<<>>(params); } else { flash_bwd_dot_do_o_kernel<<>>(params); } C10_CUDA_KERNEL_LAUNCH_CHECK(); // We want to specialize to is_even_MN and not just is_even_M, since in the case where N is not // a multiple of kBlockN, we'll need to apply mask in the loop. const bool is_even_MN = params.cu_seqlens_q == nullptr && params.cu_seqlens_k == nullptr && params.seqlen_q % Kernel_traits::kBlockM == 0 && params.seqlen_k % Kernel_traits::kBlockN == 0; const bool is_even_K = params.d == Kernel_traits::kHeadDim; constexpr int smem_size_dq_dk_dv = Kernel_traits::kSmemSize1colblock; // printf("smem_size_dq_dk_dv = %d\n", smem_size_dq_dk_dv); BOOL_SWITCH(is_even_MN, IsEvenMNConst, [&] { EVENK_SWITCH(is_even_K, IsEvenKConst, [&] { LOCAL_SWITCH((params.window_size_left >= 0 || params.window_size_right >= 0) && !params.is_causal, Is_local, [&] { ALIBI_SWITCH(params.alibi_slopes_ptr != nullptr, Has_alibi, [&] { SOFTCAP_SWITCH(params.softcap > 0.0, Is_softcap, [&] { // If not IsEvenKConst, we also 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_bwd_dq_dk_dv_loop_seqk_parallel_kernel; // auto kernel = &flash_bwd_dq_dk_dv_loop_seqk_parallel_kernel; if (smem_size_dq_dk_dv >= 48 * 1024) { C10_CUDA_CHECK(cudaFuncSetAttribute( kernel, cudaFuncAttributeMaxDynamicSharedMemorySize, smem_size_dq_dk_dv)); } kernel<<>>(params); C10_CUDA_KERNEL_LAUNCH_CHECK(); }); }); }); }); }); auto kernel_dq = &flash_bwd_convert_dq_kernel; if (Kernel_traits::kSmemdQSize >= 48 * 1024) { C10_CUDA_CHECK(cudaFuncSetAttribute( kernel_dq, cudaFuncAttributeMaxDynamicSharedMemorySize, Kernel_traits::kSmemdQSize)); } kernel_dq<<>>(params, !params.deterministic ? 1 : gridDimx); C10_CUDA_KERNEL_LAUNCH_CHECK(); } template void run_flash_bwd(Flash_bwd_params ¶ms, cudaStream_t stream) { #ifndef FLASHATTENTION_DISABLE_BACKWARD run_flash_bwd_seqk_parallel(params, stream); #endif } template void run_mha_bwd_hdim32(Flash_bwd_params ¶ms, cudaStream_t stream) { constexpr static int Headdim = 32; 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_); } DROPOUT_SWITCH(params.p_dropout < 1.f, Is_dropout, [&] { if (max_smem_per_block >= 2 * ((3 * 128 + 2 * 128) * Headdim + 2 * 128 * 128)) { // 104 KB if constexpr(!Is_dropout) { // We can afford more registers to keep V in registers run_flash_bwd, Is_dropout, Is_causal>(params, stream); } else { run_flash_bwd, Is_dropout, Is_causal>(params, stream); } } else { // 96 KB run_flash_bwd, Is_dropout, Is_causal>(params, stream); } }); } template void run_mha_bwd_hdim64(Flash_bwd_params ¶ms, cudaStream_t stream) { constexpr static int Headdim = 64; 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, [&] { // Changing AtomLayoutMdQ from 2 to 4 takes the same time // run_flash_bwd>(params, stream); // run_flash_bwd>(params, stream); // run_flash_bwd>(params, stream); // run_flash_bwd, Is_dropout>(params, stream); // This is slightly faster. We want to split M more so we need fewer registers to store LSE. if (max_smem_per_block >= 144 * 1024) { run_flash_bwd, Is_dropout, Is_causal>(params, stream); // This has a lot of register spilling // run_flash_bwd, Is_dropout>(params, stream); } else { // if (params.h == params.h_k) { // run_flash_bwd, Is_dropout>(params, stream); run_flash_bwd, Is_dropout, Is_causal>(params, stream); // run_flash_bwd, Is_dropout>(params, stream); // run_flash_bwd, Is_dropout>(params, stream); // } else { // } } }); // run_flash_bwd>(params, stream); // run_flash_bwd>(params, stream); // run_flash_bwd>(params, stream); // run_flash_bwd>(params, stream); // M=128, N=64 is quite slow, I think because we need to read/write dQaccum twice as many times // run_flash_bwd>(params, stream); // run_flash_bwd>(params, stream); // run_flash_bwd>(params, stream); // run_flash_bwd>(params, stream); } template void run_mha_bwd_hdim96(Flash_bwd_params ¶ms, cudaStream_t stream) { constexpr static int Headdim = 96; 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 >= 116 * 1024) { if constexpr(!Is_dropout) { // 92KB run_flash_bwd, Is_dropout, Is_causal>(params, stream); } else { // 116 KB // This is faster for dropout since we don't have many registers to spare run_flash_bwd, Is_dropout, Is_causal>(params, stream); } } else { run_flash_bwd, Is_dropout, Is_causal>(params, stream); } }); } template void run_mha_bwd_hdim128(Flash_bwd_params ¶ms, cudaStream_t stream) { constexpr static int Headdim = 128; 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, [&] { // run_flash_bwd>(params, stream); // This is faster, in the case of sequence-parallel bwd (where we need fewer registers). // Out of these three, the 2nd one is slightly faster (2% faster than the first). Idk why. // run_flash_bwd>(params, stream); if (max_smem_per_block >= 144 * 1024) { run_flash_bwd, Is_dropout, Is_causal>(params, stream); // run_flash_bwd_seqk_parallel, Is_dropout>(params, stream); // run_flash_bwd_seqk_parallel, Is_dropout>(params, stream); // run_flash_bwd, Is_dropout>(params, stream); // run_flash_bwd, Is_dropout>(params, stream); // run_flash_bwd, Is_dropout>(params, stream); } else { // run_flash_bwd, Is_dropout>(params, stream); run_flash_bwd, Is_dropout, Is_causal>(params, stream); } // run_flash_bwd>(params, stream); // run_flash_bwd>(params, stream); }); } template void run_mha_bwd_hdim160(Flash_bwd_params ¶ms, cudaStream_t stream) { constexpr static int Headdim = 160; 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_); } DROPOUT_SWITCH(params.p_dropout < 1.f, Is_dropout, [&] { if (max_smem_per_block >= 116 * 1024) { run_flash_bwd, Is_dropout, Is_causal>(params, stream); } else { run_flash_bwd, Is_dropout, Is_causal>(params, stream); } }); } template void run_mha_bwd_hdim192(Flash_bwd_params ¶ms, cudaStream_t stream) { constexpr static int Headdim = 192; 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_); } DROPOUT_SWITCH(params.p_dropout < 1.f, Is_dropout, [&] { if (max_smem_per_block >= 136 * 1024) { run_flash_bwd, Is_dropout, Is_causal>(params, stream); } else { run_flash_bwd, Is_dropout, Is_causal>(params, stream); } }); } template void run_mha_bwd_hdim256(Flash_bwd_params ¶ms, cudaStream_t stream) { constexpr static int Headdim = 256; 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_); } DROPOUT_SWITCH(params.p_dropout < 1.f, Is_dropout, [&] { if (max_smem_per_block >= 176 * 1024) { // H100 run_flash_bwd, Is_dropout, Is_causal>(params, stream); } else if (max_smem_per_block >= 144 * 1024) { // A100, we don't do double buffering to save smem run_flash_bwd, Is_dropout, Is_causal>(params, stream); } else { // sm86 and sm89, max smem is 99 KB. Only works without dropout. V in regs and no double buffering. if constexpr (!Is_dropout) { run_flash_bwd, false, Is_causal>(params, stream); } } }); } } // namespace FLASH_NAMESPACE {