chore: vendor sglang v0.5.10 snapshot
This commit is contained in:
550
third_party/sglang/sgl-kernel/csrc/cpu/flash_attn.cpp
vendored
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550
third_party/sglang/sgl-kernel/csrc/cpu/flash_attn.cpp
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/*****************************************************************************************
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* Copyright (c) 2025 - 2025 Codeplay Software Ltd. All rights reserved.
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* Copyright (C) 2025 Intel Corporation, All rights reserved.
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* SPDX-License-Identifier: BSD-3-Clause
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*
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* Redistribution and use in source and binary forms, with or without
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* modification, are permitted provided that the following conditions are met:
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*
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* 1. Redistributions of source code must retain the above copyright notice, this
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* list of conditions and the following disclaimer.
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*
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* 2. Redistributions in binary form must reproduce the above copyright notice,
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* this list of conditions and the following disclaimer in the documentation
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* and/or other materials provided with the distribution.
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*
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* 3. Neither the name of the copyright holder nor the names of its
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* contributors may be used to endorse or promote products derived from
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* this software without specific prior written permission.
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*
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* THIS SOFTWARE IS PROVIDED BY THE COPYRIGHT HOLDERS AND CONTRIBUTORS "AS IS"
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* AND ANY EXPRESS OR IMPLIED WARRANTIES, INCLUDING, BUT NOT LIMITED TO, THE
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* IMPLIED WARRANTIES OF MERCHANTABILITY AND FITNESS FOR A PARTICULAR PURPOSE ARE
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* DISCLAIMED. IN NO EVENT SHALL THE COPYRIGHT HOLDER OR CONTRIBUTORS BE LIABLE
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* FOR ANY DIRECT, INDIRECT, INCIDENTAL, SPECIAL, EXEMPLARY, OR CONSEQUENTIAL
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* DAMAGES (INCLUDING, BUT NOT LIMITED TO, PROCUREMENT OF SUBSTITUTE GOODS OR
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* SERVICES; LOSS OF USE, DATA, OR PROFITS; OR BUSINESS INTERRUPTION) HOWEVER
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* CAUSED AND ON ANY THEORY OF LIABILITY, WHETHER IN CONTRACT, STRICT LIABILITY,
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* OR TORT (INCLUDING NEGLIGENCE OR OTHERWISE) ARISING IN ANY WAY OUT OF THE USE
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* OF THIS SOFTWARE, EVEN IF ADVISED OF THE POSSIBILITY OF SUCH DAMAGE.
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*
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****************************************************************************************/
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#include "flash_attn.h"
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#include "common.h"
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#include "gemm.h"
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// [NOTE]: flash attention interface for CPU
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namespace {
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template <typename scalar_t, int BLOCK_M, int BLOCK_N>
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void flash_attn_kernel_impl(
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scalar_t* __restrict__ out,
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const scalar_t* __restrict__ q,
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const scalar_t* __restrict__ k,
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const scalar_t* __restrict__ v,
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void* __restrict__ buffer,
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int seqlen_q,
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int seqlen_k,
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int batches,
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int num_heads,
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int num_heads_kv,
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int head_size,
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int head_size_v,
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int q_strideM,
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int q_strideH,
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int k_strideN,
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int k_strideH,
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int v_strideN,
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int v_strideH,
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float sm_scale,
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int buffer_size_per_thread,
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bool causal) {
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// strides
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const int o_strideM = num_heads * head_size_v;
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const int o_strideH = head_size_v;
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// we use same buffer for packed key and value
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const int ldb_tmp = std::max(head_size, head_size_v);
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const int num_groups = num_heads / num_heads_kv;
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TORCH_CHECK(num_groups * num_heads_kv == num_heads);
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// number of super locks along M
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int MB = div_up(seqlen_q, BLOCK_M);
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// parallel on [batches, num_heads, MB]
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parallel_for(batches * num_heads * MB, [&](int begin, int end) {
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int bs{0}, head_id{0}, mb{0};
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data_index_init(begin, bs, batches, head_id, num_heads, mb, MB);
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int tid = get_thread_num();
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// s_i and s_delta: [BLOCK_M, BLOCK_N]
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float* __restrict__ s_i = reinterpret_cast<float*>((char*)(buffer) + tid * buffer_size_per_thread);
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scalar_t* __restrict__ s_delta = reinterpret_cast<scalar_t*>(s_i);
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// v_prime: [BLOCK_M, head_size_v]
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float* __restrict__ v_prime = s_i + BLOCK_M * BLOCK_N;
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// Btmp: [BLOCK_N, max(head_size, head_size_v)]
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scalar_t* __restrict__ Btmp = reinterpret_cast<scalar_t*>(v_prime + BLOCK_M * head_size_v);
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// init Btmp and Btmp2 just once for each thread to prevent NaN
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fill_stub(Btmp, 0.f, BLOCK_N * ldb_tmp);
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alignas(64) float s_prime[BLOCK_M];
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alignas(64) float m_prime[BLOCK_M];
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for (int i = begin; i < end; ++i) {
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// [Note] use int64_t to avoid overflow
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// For large inputs, for example bs = 4096, seqlen_q = 4097, m = 0, q_strideM = 128:
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// The index calculated below: (seq_q_start_loc + m) * q_strideM = 4096 * 4097 * 128 will overflow int
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int64_t seq_q_start_loc = bs * seqlen_q;
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int64_t seq_k_start_loc = bs * seqlen_k;
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// offset and size in MB
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int m = mb * BLOCK_M;
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int m_size = std::min(BLOCK_M, seqlen_q - m);
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assert(m_size > 0);
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int head_kv_id = head_id / num_groups;
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// get query
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const scalar_t* __restrict__ q_ptr = q + (seq_q_start_loc + m) * q_strideM + head_id * q_strideH;
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// init v', s' and m'
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fill_stub(v_prime, 0.f, m_size * head_size_v);
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fill_stub(s_prime, 0.f, m_size);
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fill_stub(m_prime, -std::numeric_limits<scalar_t>::infinity(), m_size);
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int num_keys = causal ? std::min(m + m_size, seqlen_k) : seqlen_k;
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for (int n = 0; n < num_keys; n += BLOCK_N) {
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int n_size = std::min(BLOCK_N, num_keys - n);
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// `n_size` is K in 2nd gemm, pad to TILE_K;
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const int padded_n_size = div_up(n_size, TILE_K) * TILE_K;
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// get key and pack
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pack_vnni<scalar_t>(
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/* dst */ Btmp,
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/* src */ k + (seq_k_start_loc + n) * k_strideN + head_kv_id * k_strideH,
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/* N */ n_size,
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/* K */ head_size,
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/* ld_src */ k_strideN,
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/* ld_dst */ BLOCK_N);
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// calculate s_i <- Q @ K
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at::native::cpublas::brgemm(
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/* M */ m_size,
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/* N */ n_size,
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/* K */ head_size,
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/* lda */ q_strideM,
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/* ldb */ BLOCK_N,
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/* ldc */ BLOCK_N,
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/* add_C */ false,
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/* A */ q_ptr,
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/* B */ Btmp,
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/* C */ s_i);
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// apply causal mask
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if (causal && num_keys - n <= BLOCK_N) {
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for (int row = 0; row < m_size; ++row) {
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int last_col = m + row - n;
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// fill [last_col + 1, n_size) to -inf
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float* row_ptr = s_i + row * BLOCK_N;
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fill_stub(row_ptr + last_col + 1, -std::numeric_limits<float>::infinity(), n_size - last_col - 1);
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}
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}
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flash_attn_softmax<scalar_t, BLOCK_M, BLOCK_N>::apply(
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s_i, s_delta, v_prime, s_prime, m_prime, m_size, n_size, padded_n_size, head_size_v, sm_scale);
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// get value and pack
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pack_vnni2<scalar_t>(
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/* dst */ Btmp,
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/* src */ v + (seq_k_start_loc + n) * v_strideN + head_kv_id * v_strideH,
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/* K */ n_size,
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/* N */ head_size_v,
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/* ld_src */ v_strideN,
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/* ld_dst */ head_size_v);
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// calculate V' <- s_delta @ V + V'
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at::native::cpublas::brgemm(
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/* M */ m_size,
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/* N */ head_size_v,
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/* K */ padded_n_size, // n_size
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/* lda */ BLOCK_N,
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/* ldb */ head_size_v,
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/* ldc */ head_size_v,
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/* add_C */ true,
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/* A */ s_delta,
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/* B */ Btmp,
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/* C */ v_prime);
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} // loop with seqlen_k
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scalar_t* __restrict__ out_ptr = out + (seq_q_start_loc + m) * o_strideM + head_id * o_strideH;
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for (int row = 0; row < m_size; ++row) {
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float s = 1 / s_prime[row];
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copy_stub<scalar_t>(out_ptr + row * o_strideM, v_prime + row * head_size_v, s, head_size_v);
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}
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// move to the next index
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data_index_step(bs, batches, head_id, num_heads, mb, MB);
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}
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at::native::cpublas::brgemm_release();
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});
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}
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template <typename scalar_t, int BLOCK_M, int BLOCK_N>
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void flash_attn_varlen_kernel_impl(
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scalar_t* __restrict__ out,
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const scalar_t* __restrict__ q,
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const scalar_t* __restrict__ k,
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const scalar_t* __restrict__ v,
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const int32_t* __restrict__ cu_seqlens_q,
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const int32_t* __restrict__ cu_seqlens_k,
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void* __restrict__ buffer,
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int32_t* __restrict__ indices,
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int max_seqlen_q,
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int max_seqlen_k,
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int batches,
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int num_heads,
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int num_heads_kv,
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int head_size,
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int head_size_v,
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int q_strideM,
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int q_strideH,
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int k_strideN,
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int k_strideH,
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int v_strideN,
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int v_strideH,
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float sm_scale,
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int buffer_size_per_thread,
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bool causal) {
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// strides
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const int o_strideM = num_heads * head_size_v;
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const int o_strideH = head_size_v;
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// compute index (bs, mb_offset) for Query blocks
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// do this sequentially as usually problem size won't be big
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int idx = 0;
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for (int32_t bs = 0; bs < batches; ++bs) {
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int32_t seqlen_q = cu_seqlens_q[bs + 1] - cu_seqlens_q[bs];
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int32_t seqlen_k = cu_seqlens_k[bs + 1] - cu_seqlens_k[bs];
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TORCH_CHECK(seqlen_q <= max_seqlen_q && seqlen_k <= max_seqlen_k);
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int32_t blocks = div_up(seqlen_q, BLOCK_M);
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for (int32_t offset = 0; offset < blocks; ++offset) {
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indices[idx * 2 + 0] = bs;
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indices[idx * 2 + 1] = offset;
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idx++;
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}
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}
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// number of query blocks
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int MB = idx;
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// we use same buffer for packed key and value
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const int ldb_tmp = std::max(head_size, head_size_v);
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const int num_groups = num_heads / num_heads_kv;
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TORCH_CHECK(num_groups * num_heads_kv == num_heads);
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// parallel on [MB, num_heads]
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parallel_for(num_heads * MB, [&](int begin, int end) {
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int head_id{0}, mb{0};
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data_index_init(begin, head_id, num_heads, mb, MB);
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int tid = get_thread_num();
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// s_i and s_delta: [BLOCK_M, BLOCK_N]
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float* __restrict__ s_i = reinterpret_cast<float*>((char*)(buffer) + tid * buffer_size_per_thread);
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scalar_t* __restrict__ s_delta = reinterpret_cast<scalar_t*>(s_i);
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// v_prime: [BLOCK_M, head_size_v]
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float* __restrict__ v_prime = s_i + BLOCK_M * BLOCK_N;
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// Btmp: [BLOCK_N, max(head_size, head_size_v)]
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scalar_t* __restrict__ Btmp = reinterpret_cast<scalar_t*>(v_prime + BLOCK_M * head_size_v);
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// init Btmp just once for each thread to prevent NaN
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fill_stub(Btmp, 0.f, BLOCK_N * ldb_tmp);
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alignas(64) float s_prime[BLOCK_M];
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alignas(64) float m_prime[BLOCK_M];
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for (int i = begin; i < end; ++i) {
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int32_t bs = indices[mb * 2 + 0];
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// See [Note] use int64_t to avoid overflow
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int64_t seq_q_start_loc = cu_seqlens_q[bs];
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int64_t seq_k_start_loc = cu_seqlens_k[bs];
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int32_t seqlen_q = cu_seqlens_q[bs + 1] - cu_seqlens_q[bs];
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// offset and size in MB
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int m = indices[mb * 2 + 1] * BLOCK_M;
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int m_size = std::min(BLOCK_M, seqlen_q - m);
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assert(m_size > 0);
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int head_kv_id = head_id / num_groups;
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// get query
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const scalar_t* __restrict__ q_ptr = q + (seq_q_start_loc + m) * q_strideM + head_id * q_strideH;
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// init v', s' and m'
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fill_stub(v_prime, 0.f, m_size * head_size_v);
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fill_stub(s_prime, 0.f, m_size);
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fill_stub(m_prime, -std::numeric_limits<scalar_t>::infinity(), m_size);
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int seqlen_k = cu_seqlens_k[bs + 1] - cu_seqlens_k[bs];
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int num_keys = causal ? std::min(m + m_size, seqlen_k) : seqlen_k;
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for (int n = 0; n < num_keys; n += BLOCK_N) {
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int n_size = std::min(BLOCK_N, num_keys - n);
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// `n_size` is K in 2nd gemm, pad to TILE_K;
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const int padded_n_size = div_up(n_size, TILE_K) * TILE_K;
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// get key and pack
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pack_vnni<scalar_t>(
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/* dst */ Btmp,
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/* src */ k + (seq_k_start_loc + n) * k_strideN + head_kv_id * k_strideH,
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/* N */ n_size,
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/* K */ head_size,
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/* ld_src */ k_strideN,
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/* ld_dst */ BLOCK_N);
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// calculate s_i <- Q @ K
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at::native::cpublas::brgemm(
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/* M */ m_size,
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/* N */ n_size,
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/* K */ head_size,
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/* lda */ q_strideM,
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/* ldb */ BLOCK_N,
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/* ldc */ BLOCK_N,
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/* add_C */ false,
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/* A */ q_ptr,
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/* B */ Btmp,
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/* C */ s_i);
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// apply causal mask
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if (causal && num_keys - n <= BLOCK_N) {
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for (int row = 0; row < m_size; ++row) {
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int last_col = m + row - n;
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// fill [last_col + 1, n_size) to -inf
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float* row_ptr = s_i + row * BLOCK_N;
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fill_stub(row_ptr + last_col + 1, -std::numeric_limits<float>::infinity(), n_size - last_col - 1);
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}
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}
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flash_attn_softmax<scalar_t, BLOCK_M, BLOCK_N>::apply(
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s_i, s_delta, v_prime, s_prime, m_prime, m_size, n_size, padded_n_size, head_size_v, sm_scale);
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// get value and pack
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pack_vnni2<scalar_t>(
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/* dst */ Btmp,
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/* src */ v + (seq_k_start_loc + n) * v_strideN + head_kv_id * v_strideH,
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/* K */ n_size,
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/* N */ head_size_v,
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/* ld_src */ v_strideN,
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/* ld_dst */ head_size_v);
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// calculate V' <- s_delta @ V + V'
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at::native::cpublas::brgemm(
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/* M */ m_size,
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/* N */ head_size_v,
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/* K */ padded_n_size, // n_size
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/* lda */ BLOCK_N,
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/* ldb */ head_size_v,
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/* ldc */ head_size_v,
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/* add_C */ true,
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/* A */ s_delta,
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/* B */ Btmp,
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/* C */ v_prime);
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} // loop with seqlen_k
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scalar_t* __restrict__ out_ptr = out + (seq_q_start_loc + m) * o_strideM + head_id * o_strideH;
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for (int row = 0; row < m_size; ++row) {
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float s = 1 / s_prime[row];
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copy_stub<scalar_t>(out_ptr + row * o_strideM, v_prime + row * head_size_v, s, head_size_v);
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}
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// move to the next index
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data_index_step(head_id, num_heads, mb, MB);
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}
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at::native::cpublas::brgemm_release();
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});
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}
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} // anonymous namespace
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template <typename index_t>
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inline bool has_varlen_sequences(
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const at::Tensor& cu_seqlens_q,
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const at::Tensor& cu_seqlens_k,
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int batches,
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index_t max_seqlen_q,
|
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index_t max_seqlen_k) {
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const index_t* cu_seqlens_q_data = cu_seqlens_q.data_ptr<index_t>();
|
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const index_t* cu_seqlens_k_data = cu_seqlens_k.data_ptr<index_t>();
|
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for (int bs = 0; bs < batches; ++bs) {
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index_t seqlen_q = cu_seqlens_q_data[bs + 1] - cu_seqlens_q_data[bs];
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index_t seqlen_k = cu_seqlens_k_data[bs + 1] - cu_seqlens_k_data[bs];
|
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if (seqlen_q != max_seqlen_q || seqlen_k != max_seqlen_k) {
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return true;
|
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}
|
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}
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||||
return false;
|
||||
}
|
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template <int BLOCK_M, int BLOCK_N>
|
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inline int resize_buffer(at::Tensor& buffer, int num_threads, int head_size, int head_size_v) {
|
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static_assert(BLOCK_M <= BLOCK_N, "Make sure BLOCK_M <= BLOCK_N to prevent buffer overflows during causal masking");
|
||||
const int size_per_thread =
|
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/* s_i */ BLOCK_M * BLOCK_N * sizeof(float) +
|
||||
/* v_prime */ BLOCK_M * head_size_v * sizeof(float) +
|
||||
/* Btmp */ BLOCK_N * std::max(head_size, head_size_v) * sizeof(uint16_t);
|
||||
|
||||
buffer.resize_({num_threads, size_per_thread});
|
||||
return size_per_thread;
|
||||
}
|
||||
|
||||
template <int BLOCK_M>
|
||||
inline void resize_indices(at::Tensor& indices, int num_seqs, int max_seqlen_q) {
|
||||
// we allocate memory based on max seqlen
|
||||
indices.resize_({num_seqs, div_up(max_seqlen_q, BLOCK_M), 2});
|
||||
}
|
||||
|
||||
// [NOTE]: `flash_attn_varlen_func` AMX kernel
|
||||
//
|
||||
// q: [num_tokens, num_heads, head_size]
|
||||
// k: [num_tokens, num_heads_kv, head_size]
|
||||
// v: [num_tokens, num_heads_kv, head_size_v]
|
||||
// cu_seqlens_q: [num_seqs + 1]
|
||||
// cu_seqlens_k: [num_seqs + 1]
|
||||
// out: [num_tokens, num_heads, head_size_v]
|
||||
//
|
||||
at::Tensor flash_attn_varlen_func(
|
||||
const at::Tensor& q,
|
||||
const at::Tensor& k,
|
||||
const at::Tensor& v,
|
||||
const at::Tensor& cu_seqlens_q,
|
||||
const at::Tensor& cu_seqlens_k,
|
||||
int64_t max_seqlen_q,
|
||||
int64_t max_seqlen_k,
|
||||
bool causal) {
|
||||
RECORD_FUNCTION(
|
||||
"sgl_kernel::flash_attn_varlen_func",
|
||||
std::vector<c10::IValue>({q, k, v, cu_seqlens_q, cu_seqlens_k, max_seqlen_q, max_seqlen_k, causal}));
|
||||
|
||||
CHECK_LAST_DIM_CONTIGUOUS_INPUT(q);
|
||||
CHECK_LAST_DIM_CONTIGUOUS_INPUT(k);
|
||||
CHECK_LAST_DIM_CONTIGUOUS_INPUT(v);
|
||||
CHECK_DIM(3, q);
|
||||
CHECK_DIM(3, k);
|
||||
CHECK_DIM(3, v);
|
||||
CHECK_INPUT(cu_seqlens_q);
|
||||
CHECK_INPUT(cu_seqlens_k);
|
||||
CHECK_EQ(cu_seqlens_q.scalar_type(), at::kInt);
|
||||
CHECK_EQ(cu_seqlens_k.scalar_type(), at::kInt);
|
||||
|
||||
int num_seqs = cu_seqlens_q.size(0) - 1;
|
||||
int num_tokens = q.size(0);
|
||||
int num_heads = q.size(1);
|
||||
int num_heads_kv = k.size(1);
|
||||
int head_size = q.size(2);
|
||||
int head_size_v = v.size(2);
|
||||
|
||||
// strides for q, k and v
|
||||
int q_strideM = q.stride(0);
|
||||
int q_strideH = q.stride(1);
|
||||
int k_strideN = k.stride(0);
|
||||
int k_strideH = k.stride(1);
|
||||
int v_strideN = v.stride(0);
|
||||
int v_strideH = v.stride(1);
|
||||
|
||||
// check sizes
|
||||
CHECK_EQ(k.size(2), head_size);
|
||||
CHECK_EQ(v.size(1), num_heads_kv);
|
||||
CHECK_EQ(cu_seqlens_k.size(0), num_seqs + 1);
|
||||
|
||||
// D and DV need to be even as we transpose by 512-bit
|
||||
TORCH_CHECK(head_size % 2 == 0, "invalid head_size ", head_size);
|
||||
TORCH_CHECK(head_size_v % 2 == 0, "invalid head_size_v ", head_size_v);
|
||||
|
||||
// softmax scale
|
||||
double sm_scale = 1.0 / std::sqrt(static_cast<double>(head_size));
|
||||
|
||||
// check whether the batch has variant lengths
|
||||
const bool is_varlen =
|
||||
has_varlen_sequences<int32_t>(cu_seqlens_q, cu_seqlens_k, num_seqs, max_seqlen_q, max_seqlen_k);
|
||||
|
||||
int num_threads = at::get_num_threads();
|
||||
at::Tensor buffer = at::empty({}, q.options().dtype(at::kChar));
|
||||
at::Tensor indices = at::empty({}, q.options().dtype(at::kInt));
|
||||
at::Tensor out = at::empty({num_tokens, num_heads, head_size_v}, q.options());
|
||||
|
||||
// TODO: tune the block size
|
||||
constexpr int BLOCK_M = 512;
|
||||
constexpr int BLOCK_N = 768;
|
||||
|
||||
AT_DISPATCH_REDUCED_FLOATING_TYPES(q.scalar_type(), "flash_attn_varlen_func", [&] {
|
||||
int sz = resize_buffer<BLOCK_M, BLOCK_N>(buffer, num_threads, head_size, head_size_v);
|
||||
|
||||
if (is_varlen) {
|
||||
resize_indices<BLOCK_M>(indices, num_seqs, max_seqlen_q);
|
||||
flash_attn_varlen_kernel_impl<scalar_t, BLOCK_M, BLOCK_N>(
|
||||
out.data_ptr<scalar_t>(),
|
||||
q.data_ptr<scalar_t>(),
|
||||
k.data_ptr<scalar_t>(),
|
||||
v.data_ptr<scalar_t>(),
|
||||
cu_seqlens_q.data_ptr<int32_t>(),
|
||||
cu_seqlens_k.data_ptr<int32_t>(),
|
||||
buffer.data_ptr(),
|
||||
indices.data_ptr<int32_t>(),
|
||||
max_seqlen_q,
|
||||
max_seqlen_k,
|
||||
num_seqs,
|
||||
num_heads,
|
||||
num_heads_kv,
|
||||
head_size,
|
||||
head_size_v,
|
||||
q_strideM,
|
||||
q_strideH,
|
||||
k_strideN,
|
||||
k_strideH,
|
||||
v_strideN,
|
||||
v_strideH,
|
||||
sm_scale,
|
||||
sz,
|
||||
causal);
|
||||
} else {
|
||||
flash_attn_kernel_impl<scalar_t, BLOCK_M, BLOCK_N>(
|
||||
out.data_ptr<scalar_t>(),
|
||||
q.data_ptr<scalar_t>(),
|
||||
k.data_ptr<scalar_t>(),
|
||||
v.data_ptr<scalar_t>(),
|
||||
buffer.data_ptr(),
|
||||
max_seqlen_q,
|
||||
max_seqlen_k,
|
||||
num_seqs,
|
||||
num_heads,
|
||||
num_heads_kv,
|
||||
head_size,
|
||||
head_size_v,
|
||||
q_strideM,
|
||||
q_strideH,
|
||||
k_strideN,
|
||||
k_strideH,
|
||||
v_strideN,
|
||||
v_strideH,
|
||||
sm_scale,
|
||||
sz,
|
||||
causal);
|
||||
}
|
||||
});
|
||||
|
||||
return out;
|
||||
}
|
||||
Reference in New Issue
Block a user