/*
 * Copyright (c) 2018-2019 ARM Limited.
 *
 * SPDX-License-Identifier: MIT
 *
 * Permission is hereby granted, free of charge, to any person obtaining a copy
 * of this software and associated documentation files (the "Software"), to
 * deal in the Software without restriction, including without limitation the
 * rights to use, copy, modify, merge, publish, distribute, sublicense, and/or
 * sell copies of the Software, and to permit persons to whom the Software is
 * furnished to do so, subject to the following conditions:
 *
 * The above copyright notice and this permission notice shall be included in all
 * copies or substantial portions of the Software.
 *
 * THE SOFTWARE IS PROVIDED "AS IS", WITHOUT WARRANTY OF ANY KIND, EXPRESS OR
 * IMPLIED, INCLUDING BUT NOT LIMITED TO THE WARRANTIES OF MERCHANTABILITY,
 * FITNESS FOR A PARTICULAR PURPOSE AND NONINFRINGEMENT. IN NO EVENT SHALL THE
 * AUTHORS OR COPYRIGHT HOLDERS BE LIABLE FOR ANY CLAIM, DAMAGES OR OTHER
 * LIABILITY, WHETHER IN AN ACTION OF CONTRACT, TORT OR OTHERWISE, ARISING FROM,
 * OUT OF OR IN CONNECTION WITH THE SOFTWARE OR THE USE OR OTHER DEALINGS IN THE
 * SOFTWARE.
 */
#pragma once

#include <memory>
#include <cstring>

#include "arm_gemm_local.hpp"
#include "gemm_common.hpp"

namespace arm_gemm {

enum class GemmMethod
{
    DEFAULT,
    GEMV_BATCHED,
    GEMV_PRETRANSPOSED,
    GEMV_NATIVE_TRANSPOSED,
    GEMM_NATIVE,
    GEMM_HYBRID,
    GEMM_INTERLEAVED,
    QUANTIZE_WRAPPER,
    GEMM_HYBRID_QUANTIZED
};

struct KernelDescription
{
    GemmMethod   method      = GemmMethod::DEFAULT;
    std::string  name        = "";
    bool         is_default  = false;

    KernelDescription(GemmMethod m, std::string n, bool d=false) : method(m), name(n), is_default(d) { }
    KernelDescription() noexcept  { }
};

struct GemmConfig
{
    GemmMethod   method           = GemmMethod::DEFAULT;
    std::string  filter           = "";
    unsigned int inner_block_size = 0;
    unsigned int outer_block_size = 0;

    GemmConfig(GemmMethod method) : method(method) { }
    GemmConfig() { }
};

struct Activation
{
    enum class Type {
        None,
        ReLU,
        BoundedReLU
    };

    Type    type;
    float   param1;
    float   param2;

    Activation(Type type=Type::None, float p1=0.0f, float p2=0.0f) : type(type), param1(p1), param2(p2) { }
};

struct GemmArgs
{
public:
    const CPUInfo    *_ci;
    unsigned int      _Msize;
    unsigned int      _Nsize;
    unsigned int      _Ksize;
    unsigned int      _nbatches;
    unsigned int      _nmulti;
    bool              _trA;
    bool              _trB;
    Activation        _act;
    int               _maxthreads;
    bool              _pretransposed_hint;
    const GemmConfig *_cfg;

    GemmArgs(const CPUInfo *ci, const unsigned int M, const unsigned int N,
             const unsigned int K, const unsigned int nbatches,
             const unsigned int nmulti, const bool trA, const bool trB,
             Activation act, const int maxthreads,
             const bool pretransposed_hint, const GemmConfig *cfg=nullptr ) :
             _ci(ci), _Msize(M), _Nsize(N), _Ksize(K), _nbatches(nbatches), _nmulti(nmulti),
             _trA(trA), _trB(trB), _act(act), _maxthreads(maxthreads),
             _pretransposed_hint(pretransposed_hint), _cfg(cfg)
    {
    }
};

struct Requantize32
{
public:
    const int32_t  *bias = nullptr;
    size_t          bias_multi_stride = 0;
    int32_t         a_offset = 0;
    int32_t         b_offset = 0;
    int32_t         c_offset = 0;
    bool            per_channel_requant = false;
    int32_t         per_layer_shift = 0;
    int32_t         per_layer_mul = 0;
    const int32_t  *per_channel_shifts = nullptr;
    const int32_t  *per_channel_muls = nullptr;
    int32_t         minval = 0;
    int32_t         maxval = 0;

    Requantize32() = default;

    // Constructor for per-tensor quantization
    Requantize32(const int32_t *bias, size_t bias_multi_stride,
                 int32_t a_offset, int32_t b_offset, int32_t c_offset,
                 int32_t requant_shift, int32_t requant_mul,
                 int32_t minv, int32_t maxv) :
        bias(bias), bias_multi_stride(bias_multi_stride),
        a_offset(a_offset), b_offset(b_offset), c_offset(c_offset),
        per_channel_requant(false), per_layer_shift(requant_shift), per_layer_mul(requant_mul),
        minval(minv), maxval(maxv)
    {
    }

    // Constructor for per-channel quantization
    Requantize32(const int32_t *bias, size_t bias_multi_stride,
                 int32_t a_offset, int32_t b_offset, int32_t c_offset,
                 const int32_t *requant_shifts, const int32_t *requant_muls,
                 int32_t minv, int32_t maxv) :
        bias(bias), bias_multi_stride(bias_multi_stride),
        a_offset(a_offset), b_offset(b_offset), c_offset(c_offset),
        per_channel_requant(true), per_channel_shifts(requant_shifts), per_channel_muls(requant_muls),
        minval(minv), maxval(maxv)
    {
    }
};

struct Nothing
{
};

template<typename Top, typename Tret>
using UniqueGemmCommon = std::unique_ptr<GemmCommon<Top, Tret> >;

/* Low level API calls.
 * These are implemented as 'GemmArgs' versions, or with the arguments explicitly listed. */

/* get_gemm_method(): Given the templated types and provided parameters,
 * which is the preferred method to implement this GEMM?  */
template<typename Top, typename Tret, class OutputStage = Nothing>
KernelDescription get_gemm_method(const GemmArgs &args, const OutputStage & ={});

template<typename Top, typename Tret, class OutputStage = Nothing>
UniqueGemmCommon<Top, Tret> gemm(const GemmArgs &args, const OutputStage & ={});

template<typename Top, typename Tret, class OutputStage = Nothing>
std::vector<KernelDescription> get_compatible_kernels(const GemmArgs &args, const OutputStage & ={});

} // namespace arm_gemm