feat(gopt): add deconv nchw4 int8 opt pass, add deconv nchw int8

GitOrigin-RevId: c0530a949e
4 years ago · ba2ad46e54
--- a/dnn/src/cuda/convolution/backward_data/algo.cpp
+++ b/dnn/src/cuda/convolution/backward_data/algo.cpp
@@ -36,6 +36,9 @@ ConvolutionBackwardDataImpl::AlgoPack::AlgoPack() {
        int8_algos.push_back(&algo);
    }
    int8_algos.push_back(&int8_nchw_dotprod);
    all_algos.push_back(&int8_nchw_dotprod);
    all_algos.reserve(all_algos.size() * 2);
    // add gconv algos by AlgoGroupConvGeneral
--- a/dnn/src/cuda/convolution/backward_data/algo.h
+++ b/dnn/src/cuda/convolution/backward_data/algo.h
@@ -39,7 +39,8 @@ public:
        CUDA_CHANWISE_SMALL,
        CUDA_BFLOAT16,
        CUDA_GROUP_CONV_GENERAL,
        CUDA_IMPLICIT_GEMM_NCHW4_DOTPROD_INT8
        CUDA_IMPLICIT_GEMM_NCHW4_DOTPROD_INT8,
        CUDA_IMPLICIT_GEMM_NCHW_DOTPROD_INT8
    };
    using Mapper = std::unordered_map<AlgorithmDesc, AlgoBase*>;
@@ -254,12 +255,6 @@ public:
        int warp_k;
        int stage;
        std::string to_string() {
            /// default algorithm
            if (threadblock_m == 128 && threadblock_n == 128 &&
                threadblock_k == 32 && warp_m == 32 && warp_n == 64 &&
                warp_k == 32 && stage == 2) {
                return "";
            }
            return ssprintf("_%dX%dX%d_%dX%dX%d_%dstage", threadblock_m,
                            threadblock_n, threadblock_k, warp_m, warp_n,
                            warp_k, stage);
@@ -284,6 +279,24 @@ private:
    std::string m_name;
 };
 class ConvolutionBackwardDataImpl::AlgoInt8NCHWDotProdImplicitGemm final
        : public AlgoBase {
 public:
    bool is_available(const SizeArgs& args) const override;
    size_t get_workspace_in_bytes(const SizeArgs& args) const override;
    void exec(const ExecArgs& args) const override;
    const char* name() const override {
        return "INT8_NCHW_DOTPROD_IMPLICIT_GEMM";
    }
    AlgoAttribute attribute() const override {
        return AlgoAttribute::REPRODUCIBLE;
    }
    MEGDNN_DECL_ALGO_TYPE(CUDA_IMPLICIT_GEMM_NCHW_DOTPROD_INT8);
 private:
    WorkspaceBundle get_workspace_bundle(dt_byte* raw_ptr,
                                         const SizeArgs& args) const;
 };
 class ConvolutionBackwardDataImpl::AlgoPack : NonCopyableObj {
    // defined in cudnn.cpp
    void fill_cudnn_algos();
@@ -303,6 +316,7 @@ public:
    std::unordered_map<AlgoBase*, AlgoGroupConvGeneral*> algo2gconv;
    AlgoBFloat16 bfloat16;
    std::vector<AlgoInt8NCHW4DotProdImplicitGemm> int8_nchw4_dotprod;
    AlgoInt8NCHWDotProdImplicitGemm int8_nchw_dotprod;
    std::vector<AlgoBase*>
            //! all algorithms
--- a/dnn/src/cuda/convolution/backward_data/implicit_gemm_int8_nchw4_dp4a.cpp
+++ b/dnn/src/cuda/convolution/backward_data/implicit_gemm_int8_nchw4_dp4a.cpp
@@ -1,5 +1,5 @@
 /**
 * \file dnn/src/cuda/conv_bias/implicit_gemm_int8_nchw4_dp4a.cpp
 * \file dnn/src/cuda/convolution/backward_data/implicit_gemm_int8_nchw4_dp4a.cpp
 * MegEngine is Licensed under the Apache License, Version 2.0 (the "License")
 *
 * Copyright (c) 2014-2021 Megvii Inc. All rights reserved.
--- a/dnn/src/cuda/convolution/backward_data/implicit_gemm_int8_nchw_dp4a.cpp
+++ b/dnn/src/cuda/convolution/backward_data/implicit_gemm_int8_nchw_dp4a.cpp
@@ -0,0 +1,154 @@
 /**
 * \file
 * dnn/src/cuda/convolution/backward_data/implicit_gemm_int8_nchw4_dp4a.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 "./algo.h"
 #include "src/cuda/utils.h"
 #include "src/cuda/convolution_helper/parameter.cuh"
 #include "src/cuda/convolution/backward_data/cutlass_deconvolution_wrapper.cuh"
 using namespace megdnn;
 using namespace cuda;
 bool ConvolutionBackwardDataImpl::AlgoInt8NCHWDotProdImplicitGemm::
        is_available(const SizeArgs& args) const {
    auto&& fm = args.filter_meta;
    if (fm.format != Param::Format::NCHW)
        return false;
    bool available = true;
    auto src_dtype = args.diff_layout->dtype,
         filter_dtype = args.filter_layout->dtype,
         dst_dtype = args.grad_layout->dtype;
    available &= (src_dtype.enumv() == DTypeEnum::QuantizedS8 &&
                  filter_dtype.enumv() == DTypeEnum::QuantizedS8 &&
                  dst_dtype.enumv() == DTypeEnum::QuantizedS8);
    // TODO support group deconv int8
    available &= (fm.group == 1);
    // ic and oc must be multiples of 4
    available &= ((fm.group * fm.icpg) % 4 == 0 && (fm.group * fm.ocpg) % 4 == 0);
    // mode must be cross correlation
    available &= !fm.should_flip;
    // mode must be 2D
    available &= fm.spatial_ndim == 2;
    // TODO: support dialtion
    available &= (fm.dilation[0] == 1 && fm.dilation[1] == 1);
    // FIXME: too large filter size is not supported now
    available &= fm.spatial[0] * fm.spatial[1] <= 64;
    // only support sm_61 or later, platform should have fast native int8
    // support
    available &= is_compute_capability_required(6, 1);
    return available;
 }
 WorkspaceBundle ConvolutionBackwardDataImpl::AlgoInt8NCHWDotProdImplicitGemm::
        get_workspace_bundle(dt_byte* raw_ptr, const SizeArgs& args) const {
    size_t ws_filter = args.filter_layout->span().dist_byte();
    size_t ws_diff = args.diff_layout->span().dist_byte();
    size_t ws_grad = args.grad_layout->span().dist_byte();
    return WorkspaceBundle{raw_ptr, {ws_filter, ws_diff, ws_grad}};
 }
 size_t ConvolutionBackwardDataImpl::AlgoInt8NCHWDotProdImplicitGemm::
        get_workspace_in_bytes(const SizeArgs& args) const {
    return get_workspace_bundle(nullptr, args).total_size_in_bytes();
 }
 void ConvolutionBackwardDataImpl::AlgoInt8NCHWDotProdImplicitGemm::exec(
        const ExecArgs& args) const {
    auto&& fm = args.filter_meta;
    size_t n = args.diff_layout->operator[](0),
           co = args.diff_layout->operator[](1),
           ho = args.diff_layout->operator[](2),
           wo = args.diff_layout->operator[](3);
    size_t ci = args.grad_layout->operator[](1),
           hi = args.grad_layout->operator[](2),
           wi = args.grad_layout->operator[](3);
    size_t fh = fm.spatial[0], fw = fm.spatial[1];
    size_t sh = fm.stride[0], sw = fm.stride[1];
    size_t ph = fm.padding[0], pw = fm.padding[1];
    auto&& stream = cuda_stream(args.opr->handle());
    auto bundle = get_workspace_bundle(args.workspace.raw_ptr, args);
    int8_t* inner_filter_ptr = nullptr;
    int8_t* inner_diff_ptr = nullptr;
    // TODO: weight preprocess
    {
        inner_filter_ptr = reinterpret_cast<int8_t*>(bundle.get(0));
        // reformat filter from nchw to n4hwc4
        TensorLayout exec_src{{co / 4, 4, ci, fh, fw}, dtype::Int8()};
        TensorLayout exec_dst{{co / 4, fh, fw, ci, 4}, dtype::Int8()};
        exec_src = exec_src.dimshuffle({0, 3, 4, 2, 1});
        auto&& relayout =
                args.opr->handle()->create_operator<RelayoutForward>();
        relayout->exec({args.filter_tensor->raw_ptr, exec_src},
                       {inner_filter_ptr, exec_dst});
    }
    {
        inner_diff_ptr = reinterpret_cast<int8_t*>(bundle.get(1));
        // reformat diff from nchw to nchw4
        TensorLayout exec_src{{n, co / 4, 4, ho, wo}, dtype::Int8()};
        TensorLayout exec_dst{{n, co / 4, ho, wo, 4}, dtype::Int8()};
        exec_src = exec_src.dimshuffle({0, 1, 3, 4, 2});
        auto&& relayout =
                args.opr->handle()->create_operator<RelayoutForward>();
        relayout->exec({args.diff_tensor->raw_ptr, exec_src},
                       {inner_diff_ptr, exec_dst});
    }
    int8_t* inner_grad_ptr = reinterpret_cast<int8_t*>(bundle.get(2));
    convolution::ConvParam kern_param;
    kern_param.n = n, kern_param.co = co, kern_param.ci = ci,
    kern_param.hi = hi, kern_param.wi = wi, kern_param.ho = ho,
    kern_param.wo = wo, kern_param.ph = ph, kern_param.pw = pw,
    kern_param.sh = sh, kern_param.sw = sw, kern_param.fh = fh,
    kern_param.fw = fw;
    float diff_scale =
                  args.diff_layout->dtype.param<dtype::QuantizedS8>().scale,
          filter_scale =
                  args.filter_layout->dtype.param<dtype::QuantizedS8>().scale,
          grad_scale =
                  args.grad_layout->dtype.param<dtype::QuantizedS8>().scale;
    float alpha = diff_scale * filter_scale / grad_scale;
    // only use 16x64x8_16x64x8_2stages impl
    cutlass_wrapper::do_deconv_int8_implicit_gemm_dp4a_ncdiv4hw4(
            inner_diff_ptr, inner_filter_ptr, inner_grad_ptr, nullptr,
            kern_param, alpha, cutlass_wrapper::GemmCoord{16, 64, 8},
            cutlass_wrapper::GemmCoord{16, 64, 8}, 2, stream);
    after_kernel_launch();
    {
        // reformat grad from nchw4 to nchw
        TensorLayout exec_src{{n, ci / 4, hi, wi, 4}, dtype::Int8()};
        TensorLayout exec_dst{{n, ci / 4, 4, hi, wi}, dtype::Int8()};
        exec_src = exec_src.dimshuffle({0, 1, 4, 2, 3});
        auto&& relayout =
                args.opr->handle()->create_operator<RelayoutForward>();
        relayout->exec({inner_grad_ptr, exec_src},
                       {args.grad_tensor->raw_ptr, exec_dst});
    }
 }
 // vim: syntax=cpp.doxygen
--- a/dnn/src/cuda/convolution/opr_impl.h
+++ b/dnn/src/cuda/convolution/opr_impl.h
@@ -106,6 +106,7 @@ public:
    class AlgoGroupConvGeneral;
    class AlgoBFloat16;
    class AlgoInt8NCHW4DotProdImplicitGemm;
    class AlgoInt8NCHWDotProdImplicitGemm;
    class AlgoPack;
--- a/dnn/test/common/convolution.cpp
+++ b/dnn/test/common/convolution.cpp
@@ -434,7 +434,7 @@ std::vector<TestArg> convolution::get_args_int8_nchw4_conv_bwd_data() {
    param::Convolution cur_param;
    // clang-format off
    for (auto mode : {param::ConvBias::Mode::CROSS_CORRELATION}) {
    for (auto mode : {param::Convolution::Mode::CROSS_CORRELATION}) {
    for (size_t b : {64, 16}) {
    for (size_t ic : {16, 32}) {
    for (size_t oc : {16, 32}) {
@@ -449,8 +449,8 @@ std::vector<TestArg> convolution::get_args_int8_nchw4_conv_bwd_data() {
        size_t f = kernel_size;
        cur_param.mode = mode;
        cur_param.format = param::ConvBias::Format::NCHW4;
        cur_param.sparse = param::ConvBias::Sparse::DENSE;
        cur_param.format = param::Convolution::Format::NCHW4;
        cur_param.sparse = param::Convolution::Sparse::DENSE;
        cur_param.pad_h = cur_param.pad_w = p;
        cur_param.stride_h = cur_param.stride_w = s;
@@ -460,6 +460,54 @@ std::vector<TestArg> convolution::get_args_int8_nchw4_conv_bwd_data() {
    } } } } } } } } }
    // clang-format on
    cur_param.pad_h = cur_param.pad_w = 1;
    cur_param.stride_h = cur_param.stride_w = 1;
    args.emplace_back(cur_param, TensorShape{16, 4, 8, 11, 4},
                      TensorShape{16, 4, 3, 3, 4});
    return args;
 }
 std::vector<TestArg> convolution::get_args_int8_nchw_conv_bwd_data() {
    std::vector<TestArg> args;
    param::Convolution cur_param;
    // clang-format off
    for (auto mode : {param::Convolution::Mode::CROSS_CORRELATION}) {
    for (size_t b : {64, 16}) {
    for (size_t ic : {16, 32}) {
    for (size_t oc : {16, 32}) {
    for (size_t h : {8}) {
    for (size_t w : {8, 11}) {
    for (size_t kernel_size : {3, 4, 5, 7}) {
    for (int p : {0, static_cast<int>(kernel_size / 2)}) {
    for (size_t s : {2}) {
        if (kernel_size >= 7) {
            b = std::min(b, 32_z);
        }
        size_t f = kernel_size;
        cur_param.mode = mode;
        cur_param.format = param::Convolution::Format::NCHW;
        cur_param.sparse = param::Convolution::Sparse::DENSE;
        cur_param.pad_h = cur_param.pad_w = p;
        cur_param.stride_h = cur_param.stride_w = s;
        //! bias channel
        args.emplace_back(cur_param, TensorShape{b, ic, h, w},
                          TensorShape{oc, ic, f, f});
    } } } } } } } } }
    // clang-format on
    // test stride = 1
    cur_param.pad_h = cur_param.pad_w = 1;
    cur_param.stride_h = cur_param.stride_w = 1;
    args.emplace_back(cur_param, TensorShape{16, 16, 8, 11},
                      TensorShape{16, 16, 3, 3});
    return args;
 }
--- a/dnn/test/common/convolution.h
+++ b/dnn/test/common/convolution.h
@@ -49,6 +49,7 @@ std::vector<TestArg> get_1x1_args();
 std::vector<TestArg> get_dilated_args();
 std::vector<TestArg> get_chanwise_args();
 std::vector<TestArg> get_args_int8_nchw4_conv_bwd_data();
 std::vector<TestArg> get_args_int8_nchw_conv_bwd_data();
 //! \param stage 0 for fwd, 1 for bwd data, 2 for bwd filter
 using ConvEPSGetter =
--- a/dnn/test/cuda/convolution.cpp
+++ b/dnn/test/cuda/convolution.cpp
@@ -266,19 +266,78 @@ TEST_F(CUDA, CONVOLUTION_BACKWARD_DATA_MATMUL) {
    }
 }
 TEST_F(CUDA, CONVOLUTION_BACKWARD_DATA_INT8_DP4A) {
 TEST_F(CUDA, CONVOLUTION_BACKWARD_DATA_INT8_NCHW4_DP4A) {
    if (!cuda::is_compute_capability_required(6, 1)) {
        printf("Skip CUDA.CONVOLUTION_BACKWARD_DATA_INT8_DP4A test as current "
               "device doesn't support\n");
        printf("Skip CUDA.CONVOLUTION_BACKWARD_DATA_INT8_NCHW4_DP4A test as "
               "current device doesn't support\n");
        return;
    }
    using namespace convolution;
    std::vector<TestArg> args = get_args_int8_nchw4_conv_bwd_data();
    struct AlgoParam {
        int threadblock_m;
        int threadblock_n;
        int threadblock_k;
        int warp_m;
        int warp_n;
        int warp_k;
        int stage;
        std::string to_string() {
            return ssprintf("_%dX%dX%d_%dX%dX%d_%dstage", threadblock_m,
                            threadblock_n, threadblock_k, warp_m, warp_n,
                            warp_k, stage);
        }
    };
    std::vector<AlgoParam> all_params;
    all_params.emplace_back(AlgoParam{16, 64, 8, 16, 64, 8, 2});
    all_params.emplace_back(AlgoParam{16, 128, 16, 16, 64, 16, 2});
    all_params.emplace_back(AlgoParam{16, 128, 16, 16, 128, 16, 1});
    all_params.emplace_back(AlgoParam{32, 128, 32, 32, 64, 32, 2});
    all_params.emplace_back(AlgoParam{64, 128, 32, 64, 32, 32, 2});
    for (auto algo_param : all_params) {
        Checker<ConvolutionBackwardData> checker(handle_cuda());
        std::string algo_name(ssprintf("INT8_NCHW4_DOTPROD_IMPLICIT_GEMM%s",
                                       algo_param.to_string().c_str()));
        checker.set_before_exec_callback(
                AlgoChecker<ConvolutionBackwardData>(algo_name.c_str()));
        checker.set_epsilon(1 + 1e-3).set_max_avg_error(1e-1);
        for (auto&& arg : args) {
            UniformIntRNG rng(-3, 3);
            auto src = TensorLayout(arg.src, dtype::QuantizedS8{1.2f});
            auto filter = TensorLayout(arg.filter, dtype::QuantizedS8{1.3f});
            TensorLayout dst;
            dst.dtype = dtype::QuantizedS8{1.2f};
            {
                auto opr = handle_cuda()->create_operator<Convolution>();
                opr->param() = arg.param;
                opr->deduce_layout(src, filter, dst);
            }
            checker.set_rng(0, &rng).set_rng(1, &rng).set_param(arg.param).exec(
                    TensorLayoutArray{filter, dst, src});
        }
    }
 }
 TEST_F(CUDA, CONVOLUTION_BACKWARD_DATA_INT8_NCHW_DP4A) {
    if (!cuda::is_compute_capability_required(6, 1)) {
        printf("Skip CUDA.CONVOLUTION_BACKWARD_DATA_INT8_NCHW_DP4A test as "
               "current device doesn't support\n");
        return;
    }
    using namespace convolution;
    std::vector<TestArg> args = get_args_int8_nchw_conv_bwd_data();
    Checker<ConvolutionBackwardData> checker(handle_cuda());
    checker.set_before_exec_callback(AlgoChecker<ConvolutionBackwardData>(
            "INT8_NCHW4_DOTPROD_IMPLICIT_GEMM"));
            "INT8_NCHW_DOTPROD_IMPLICIT_GEMM"));
    checker.set_epsilon(1 + 1e-3).set_max_avg_error(1e-1);
--- a/src/gopt/impl/fuse_nchw4_int8_preprocess.cpp
+++ b/src/gopt/impl/fuse_nchw4_int8_preprocess.cpp
@@ -459,7 +459,8 @@ void FuseWarpPerspectiveDimshufflePass::apply(OptState& opt) const {
                                     opr::WarpPerspective::Param new_param,
                                     megdnn::DType dst_dtype,
                                     SymbolVar& new_warp) {
        OperatorNodeConfig new_config(dst_dtype);
        OperatorNodeConfig new_config = warp->config();
        new_config.output_dtype(dst_dtype);
        if (warp->input().size() == 3) {
            auto src = rewriter.get_var(warp->input(0)),
                 mat = rewriter.get_var(warp->input(1)),
--- a/src/gopt/impl/tensor_reformat.cpp
+++ b/src/gopt/impl/tensor_reformat.cpp
@@ -1514,6 +1514,46 @@ std::unique_ptr<EnableNCHW4Pass> EnableNCHW4Pass::make_nchw4_converter() {
        return new_opr;
    };
    auto replace_deconv_opr = [trans_nchw4, conv_format](
                                    OperatorNodeBase* opr,
                                    const VarNodeArray& new_inp) {
        if (new_inp[1]->dtype().enumv() == DTypeEnum::Float32) {
            return serialization::copy_opr_shallow(*opr, new_inp,
                                                   opr->config());
        }
        mgb_assert(opr->input().size() == new_inp.size());
        auto& deconv_opr = opr->cast_final_safe<opr::ConvolutionBackwardData>();
        if ((deconv_opr.param().format !=
             megdnn::param::Convolution::Format::NCHW) ||
            (deconv_opr.param().sparse !=
             megdnn::param::Convolution::Sparse::DENSE)) {
            return serialization::copy_opr_shallow(*opr, new_inp,
                                                   opr->config());
        }
        VarNode *deconv_src = new_inp[1], *deconv_filter = new_inp[0];
        auto deconv_mode = trans_nchw4(deconv_opr.param().sparse, deconv_filter);
        // src: NCHW --> NCWH4
        if (deconv_src->shape().ndim != 5) {
            mgb_assert(deconv_src->shape().ndim == 4);
            auto new_src =
                    RelayoutPlaceholder::make(deconv_src, deconv_mode.src);
            deconv_src = new_src.node();
        }
        // weight: NCHW --> NCHW4
        auto new_filter =
                RelayoutPlaceholder::make(deconv_filter, deconv_mode.weight);
        deconv_filter = new_filter.node();
        // format: NCHW --> NCHW4
        auto new_param = deconv_opr.param();
        new_param.format = conv_format;
        // dst
        auto new_deconv_opr = opr::ConvolutionBackwardData::make_deconv(
                deconv_src, deconv_filter, new_param,
                deconv_opr.execution_policy(), deconv_opr.config());
        OperatorNodeBase* new_opr = new_deconv_opr.node()->owner_opr();
        return new_opr;
    };
    auto replace_batch_conv_bias_opr = [batch_conv_bias_format,
                                        src_to_nchw4_mode](
                                               OperatorNodeBase* opr,
@@ -1806,6 +1846,8 @@ std::unique_ptr<EnableNCHW4Pass> EnableNCHW4Pass::make_nchw4_converter() {
    auto&& replace_func = ret->m_opr_replace_func;
    //! supportted nchw4
    replace_func[opr::Convolution::typeinfo()] = replace_conv_opr;
    replace_func[opr::ConvolutionBackwardData::typeinfo()] =
            replace_deconv_opr;
    replace_func[opr::ConvBias::typeinfo()] = replace_conv_bias_opr;
    replace_func[opr::BatchConvBias::typeinfo()] = replace_batch_conv_bias_opr;
    replace_func[opr::PoolingForward::typeinfo()] = replace_pooling_opr;
@@ -1818,8 +1860,6 @@ std::unique_ptr<EnableNCHW4Pass> EnableNCHW4Pass::make_nchw4_converter() {
    replace_func[opr::PowC::typeinfo()] = replace_elemwise_opr;
    //! not supported nchw4
    replace_func[opr::Concat::typeinfo()] = relayout_inp_to_nchw;
    replace_func[opr::ConvolutionBackwardData::typeinfo()] =
            relayout_inp_to_nchw;
    replace_func[opr::Subtensor::typeinfo()] = relayout_inp_to_nchw;
    replace_func[opr::GetVarShape::typeinfo()] = relayout_inp_to_nchw;
    replace_func[opr::Dimshuffle::typeinfo()] = relayout_inp_to_nchw;
--- a/src/gopt/test/inference.cpp
+++ b/src/gopt/test/inference.cpp
@@ -2923,6 +2923,7 @@ TEST(TestGoptInference, ConvertFormatNCHW4GPU) {
    auto conv1 = opr::ConvBiasForward::make(
            x, w1, b1, param_conv_bias, {},
            OperatorNodeConfig{dtype::QuantizedS8{2.5f}});
    // group
    // icpg != 1 && ocpg != 1
    param_conv_bias.sparse = opr::ConvBias::Param::Sparse::GROUP;
@@ -2932,8 +2933,19 @@ TEST(TestGoptInference, ConvertFormatNCHW4GPU) {
            conv1, w2, b2, param_conv_bias, {},
            OperatorNodeConfig{dtype::QuantizedS8{2.5f}});
    auto conv2_fp32 = opr::TypeCvt::make(conv2, dtype::Float32());
    auto y = conv2_fp32 + opr::TypeCvt::make(b2, dtype::Float32());
    opr::Convolution::Param param_deconv;
    param_deconv.format = opr::Convolution::Param::Format::NCHW;
    param_deconv.stride_h = param_deconv.stride_w = 2;
    param_deconv.pad_h = param_deconv.pad_w = 2;
    // dense
    param_deconv.sparse = opr::Convolution::Param::Sparse::DENSE;
    auto w3 = mkcvar("w3", {8, 8, 4, 4}, dtype::QuantizedS8(2.5f));
    auto deconv1 = opr::ConvolutionBackwardData::make_deconv(
            conv2, w3, param_deconv, {},
            OperatorNodeConfig{dtype::QuantizedS8{2.5f}});
    auto deconv1_fp32 = opr::TypeCvt::make(deconv1, dtype::Float32());
    auto y = deconv1_fp32 + opr::TypeCvt::make(b2, dtype::Float32());
    SymbolVar y_opt;
    {
@@ -2944,6 +2956,8 @@ TEST(TestGoptInference, ConvertFormatNCHW4GPU) {
    ASSERT_EQ(opr::ConvBias::Param::Format::NCHW4,
              find_opr<opr::ConvBias>(y_opt).param().format);
    ASSERT_EQ(opr::ConvolutionBackwardData::Param::Format::NCHW4,
              find_opr<opr::ConvolutionBackwardData>(y_opt).param().format);
    auto nr_reshape = find_opr_num<mgb::opr::Reshape>(y_opt);
    ASSERT_EQ(2u, nr_reshape);
--- a/src/opr/impl/dnn/dnn.oprdecl
+++ b/src/opr/impl/dnn/dnn.oprdecl
@@ -51,7 +51,7 @@ decl_opr('ConvolutionBackwardData',
         ],
         desc='batched deconvolution on channeled 2D images; the underlying '
         'computation is in fact gradient of convolution w.r.t. data',
         version=2)
         version=2, has_out_dtype=True)
 decl_opr('MaskConvolution',
         inputs=[Doc('src',
--- a/src/opr/test/dnn/convolution.cpp
+++ b/src/opr/test/dnn/convolution.cpp
@@ -609,10 +609,11 @@ TEST(TestOprDNN, DeconvolutionExePolicy_QuantizedS8) {
    using S = Policy::Strategy;
 #if MGB_ENABLE_FASTRUN
    for (auto strategy : {S::PROFILE, S::HEURISTIC, S::PROFILE_REPRODUCIBLE,
                          S::PROFILE_HEURISTIC}) {
    for (auto strategy :
         {S::PROFILE, S::HEURISTIC, S(S::PROFILE | S::REPRODUCIBLE),
          S(S::PROFILE | S::HEURISTIC)}) {
 #else
    for (auto strategy : {S : HEURISTIC, S::PROFILE_HEURISTIC}) {
    for (auto strategy: {S:HEURISTIC, S(S::PROFILE | S::HEURISTIC)}) {
 #endif
        auto graph = ComputingGraph::make();
        HostTensorGenerator<> gen;