MegEngine/dnn/src/aarch64/matrix_mul/int8_dot/strategy.cpp

/**
 * \file dnn/src/aarch64/matrix_mul/int8_dot/strategy.cpp
 * MegEngine is Licensed under the Apache License, Version 2.0 (the "License")
 *
 * Copyright (c) 2014-2021 Megvii Inc. All rights reserved.
 *
 * Unless required by applicable law or agreed to in writing,
 * software distributed under the License is distributed on an
 * "AS IS" BASIS, WITHOUT ARRANTIES OR CONDITIONS OF ANY KIND, either express or implied.
 */

#include "src/aarch64/matrix_mul/int8_dot/strategy.h"
#if MGB_ENABLE_DOT
#include "src/aarch64/matrix_mul/asm/common.h"
#include "src/arm_common/simd_macro/marm_neon.h"
#include "src/common/utils.h"
#include "src/aarch64/matrix_mul/int8_dot/kernel_8x12x4.h"
#include "src/aarch64/matrix_mul/int8_dot/kernel_mk4_8x12x4.h"

using namespace megdnn;
using namespace aarch64;
using namespace aarch64::matmul;

/* ====================== gemm_s8_8x12 ===========================*/
MEGDNN_REG_GEMM_STRATEGY_IMPL(gemm_s8_8x12);

void gemm_s8_8x12::pack_A(dt_int8* outptr, const dt_int8* inptr, int ldin,
                          int y0, int ymax, int k0, int kmax,
                          bool transpose) const {
    if (transpose) {
        matmul_8x12x4::gemm_s8_8x12_pack_A_t(outptr, inptr, ldin, y0, ymax, k0,
                                             kmax);
    } else {
        matmul_8x12x4::gemm_s8_8x12_pack_A_n(outptr, inptr, ldin, y0, ymax, k0,
                                             kmax);
    }
}

void gemm_s8_8x12::pack_B(dt_int8* out, const dt_int8* in, int ldin, int x0,
                          int xmax, int k0, int kmax, bool transpose) const {
    if (transpose) {
        matmul_8x12x4::gemm_s8_8x12_pack_B_t(out, in, ldin, x0, xmax, k0, kmax);
    } else {
        matmul_8x12x4::gemm_s8_8x12_pack_B_n(out, in, ldin, x0, xmax, k0, kmax);
    }
}

void gemm_s8_8x12::kern(const dt_int8* packA, const dt_int8* packB, size_t M,
                        size_t N, size_t K, dt_int32* C, size_t LDC,
                        bool is_first_k, const dt_int32*, dt_int32*) const {
    megdnn_assert(A_dtype.enumv() == B_dtype.enumv() &&
                          ((A_dtype.enumv() == DTypeEnum::Int8 &&
                            C_dtype.enumv() == DTypeEnum::Int32) ||
                           (A_dtype.enumv() == DTypeEnum::QuantizedS8 &&
                            C_dtype.enumv() == DTypeEnum::QuantizedS32)),
                  "A: %s B: %s C: %s", A_dtype.name(), B_dtype.name(),
                  C_dtype.name());

    MEGDNN_MARK_USED_VAR(A_dtype);
    MEGDNN_MARK_USED_VAR(B_dtype);
    MEGDNN_MARK_USED_VAR(C_dtype);

    constexpr size_t A_INTERLEAVE = 8;
    constexpr size_t B_INTERLEAVE = 12;
    //! K is packed to times of 4
    K = round_up<size_t>(K, 4);
    const int K8 = (K << 3);
    const int K12 = K * 12;
    const int K4 = K * 4;

    size_t m = 0;
    for (; m + A_INTERLEAVE - 1 < M; m += A_INTERLEAVE) {
        int32_t* output = C + (m * LDC);

        size_t n = 0;
        const dt_int8* cur_packB = packB;
        for (; n + B_INTERLEAVE - 1 < N; n += B_INTERLEAVE) {
            matmul_8x12x4::kern_8x12(packA, cur_packB, K, output, LDC,
                                     is_first_k);
            output += B_INTERLEAVE;
            cur_packB += K12;
        }

        for (; n < N; n += 4) {
            matmul_8x12x4::kern_8x4(packA, cur_packB, K, output, LDC,
                                    is_first_k, std::min<size_t>(N - n, 4));
            output += 4;
            cur_packB += K4;
        }
        packA += K8;
    }

    for (; m < M; m += 4) {
        int32_t* output = C + (m * LDC);
        const dt_int8* cur_packB = packB;
        size_t n = 0;
        for (; n + B_INTERLEAVE - 1 < N; n += B_INTERLEAVE) {
            matmul_8x12x4::kern_4x12(packA, cur_packB, K, output, LDC,
                                     is_first_k, std::min<size_t>(M - m, 4));
            output += B_INTERLEAVE;
            cur_packB += K12;
        }

        for (; n < N; n += 4) {
            matmul_8x12x4::kern_4x4(packA, cur_packB, K, output, LDC,
                                    is_first_k, std::min<size_t>(M - m, 4),
                                    std::min<size_t>(N - n, 4));
            output += 4;
            cur_packB += K4;
        }
        packA += K4;
    }
}

/* ====================== gemm_mk4_s8_8x12 ===========================*/
MEGDNN_REG_GEMM_STRATEGY_IMPL(gemm_mk4_s8_8x12);

void gemm_mk4_s8_8x12::pack_A(dt_int8* outptr, const dt_int8* inptr, int ldin,
                              int y0, int ymax, int k0, int kmax,
                              bool transpose) const {
    megdnn_assert(!transpose, "matrix mul mk4 with transposed matrix A is not supported");
    matmul_mk4_8x12x4::gemm_mk4_s8_8x12_pack_A(outptr, inptr, ldin, y0, ymax, k0,
                                             kmax);
}

void gemm_mk4_s8_8x12::pack_B(dt_int8* out, const dt_int8* in, int ldin, int x0,
                              int xmax, int k0, int kmax,
                              bool transpose) const {
    megdnn_assert(!transpose, "matrix mul mk4 with transposed matrix B is not supported");
    matmul_mk4_8x12x4::gemm_mk4_s8_8x12_pack_B(out, in, ldin, x0, xmax, k0, kmax);
}

void gemm_mk4_s8_8x12::kern(const dt_int8* packA, const dt_int8* packB,
                            size_t M, size_t N, size_t K, dt_int32* C,
                            size_t LDC, bool is_first_k, const dt_int32*,
                            dt_int32*) const {
    megdnn_assert(A_dtype.enumv() == B_dtype.enumv() &&
                          ((A_dtype.enumv() == DTypeEnum::Int8 &&
                            C_dtype.enumv() == DTypeEnum::Int32) ||
                           (A_dtype.enumv() == DTypeEnum::QuantizedS8 &&
                            C_dtype.enumv() == DTypeEnum::QuantizedS32)),
                  "A: %s B: %s C: %s", A_dtype.name(), B_dtype.name(),
                  C_dtype.name());

    MEGDNN_MARK_USED_VAR(A_dtype);
    MEGDNN_MARK_USED_VAR(B_dtype);
    MEGDNN_MARK_USED_VAR(C_dtype);

    constexpr size_t A_INTERLEAVE = 8;
    constexpr size_t B_INTERLEAVE = 12;
    //! K is packed to times of 4
    K = round_up<size_t>(K, 4);
    const int K8 = (K << 3);
    const int K12 = K * 12;
    const int K4 = K * 4;

    size_t m = 0;
    for (; m + A_INTERLEAVE - 1 < M; m += A_INTERLEAVE) {
        int32_t* output = C + ((m >> 2) * LDC);

        size_t n = 0;
        const dt_int8* cur_packB = packB;
        for (; n + B_INTERLEAVE - 1 < N; n += B_INTERLEAVE) {
            matmul_mk4_8x12x4::kern_8x12(packA, cur_packB, K, output, LDC,
                                         is_first_k);
            output += (B_INTERLEAVE << 2);
            cur_packB += K12;
        }

        for (; n < N; n += 4) {
            matmul_mk4_8x12x4::kern_8x4(packA, cur_packB, K, output, LDC,
                                        is_first_k, std::min<size_t>(N - n, 4));
            output += 16;
            cur_packB += K4;
        }
        packA += K8;
    }

    for (; m < M; m += 4) {
        int32_t* output = C + ((m >> 2) * LDC);
        const dt_int8* cur_packB = packB;
        size_t n = 0;
        for (; n + B_INTERLEAVE - 1 < N; n += B_INTERLEAVE) {
            matmul_mk4_8x12x4::kern_4x12(packA, cur_packB, K, output, LDC,
                                         is_first_k);
            output += (B_INTERLEAVE << 2);
            cur_packB += K12;
        }

        for (; n < N; n += 4) {
            matmul_mk4_8x12x4::kern_4x4(packA, cur_packB, K, output, LDC,
                                        is_first_k, std::min<size_t>(N - n, 4));
            output += 16;
            cur_packB += K4;
        }
        packA += K4;
    }
}

#endif
// vim: syntax=cpp.doxygen