feat(mge/bn): add NHWC support for bn

GitOrigin-RevId: 0a5bb6f72d
3 years ago · c0ccd0ea7e
--- a/imperative/python/megengine/functional/nn.py
+++ b/imperative/python/megengine/functional/nn.py
@@ -1122,7 +1122,8 @@ def batch_norm(
    momentum: float = 0.9,
    eps: float = 1e-5,
    inplace: bool = True,
    compute_mode="default"
    compute_mode="default",
    param_dim="dim_1c11"
 ):
    r"""Applies batch normalization to the input.

@@ -1147,16 +1148,23 @@ def batch_norm(
    if inp.ndim != 4:
        raise NotImplementedError("batch_norm for ndim != 4")

    C = inp.shape[1]
    if param_dim == "dim_1c11":
        C = inp.shape[1]
        pshape = (1, C, 1, 1)
    elif param_dim == "dim_111c":
        C = inp.shape[3]
        pshape = (1, 1, 1, C)
    else:
        raise ValueError("Invalid param_dim {}".format(param_dim))

    def make_full_if_none(x, value):
        if x is None:
            (x,) = Const(value, dtype=inp.dtype, device=inp.device)()
            shape = astensor1d((1, C, 1, 1), inp, dtype="int32", device=inp.device)
            shape = astensor1d(pshape, inp, dtype="int32", device=inp.device)
            (result,) = apply(builtin.Broadcast(), x, shape)
            return result
        elif x.ndim == 1:
            shape = astensor1d((1, C, 1, 1), inp, dtype="int32", device=inp.device)
            shape = astensor1d(pshape, inp, dtype="int32", device=inp.device)
            (result,) = apply(builtin.Reshape(), x, shape)
            return result
        return x
@@ -1183,19 +1191,19 @@ def batch_norm(

    if not training:
        op = builtin.BatchNorm(
            fwd_mode=BatchNorm.FwdMode.INFERENCE, epsilon=eps, param_dim="dim_1c11"
            fwd_mode=BatchNorm.FwdMode.INFERENCE, epsilon=eps, param_dim=param_dim
        )
        ret = apply(op, inp, weight, bias, running_mean, running_var)[-1]
        return ret

    else:
        op = builtin.BatchNorm(
            avg_factor=1 - momentum, epsilon=eps, param_dim="dim_1c11"
            avg_factor=1 - momentum, epsilon=eps, param_dim=param_dim
        )
        if has_mean or has_var:
            running_mean = make_full_if_none(running_mean, 0)
            running_var = make_full_if_none(running_var, 1)
            new_mean, new_var, _, _, inp = apply(
            new_mean, new_var, *_, inp = apply(
                op, inp, weight, bias, running_mean, running_var
            )
            if not has_mean:
@@ -1213,7 +1221,7 @@ def batch_norm(
            else:
                return inp, new_mean, new_var
        else:
            (_, _, inp,) = apply(op, inp, weight, bias)
            inp = apply(op, inp, weight, bias)[-1]
            return inp


--- a/imperative/python/megengine/module/batchnorm.py
+++ b/imperative/python/megengine/module/batchnorm.py
@@ -27,6 +27,7 @@ class _BatchNorm(Module):
        track_running_stats=True,
        freeze=False,
        compute_mode="default",
        param_dim="dim_1c11",
        **kwargs
    ):
        super(_BatchNorm, self).__init__(**kwargs)
@@ -38,6 +39,7 @@ class _BatchNorm(Module):
        self._track_running_stats_saved = track_running_stats
        self.freeze = freeze
        self.compute_mode = compute_mode
        self.param_dim = param_dim
        if self.freeze:
            assert (
                self._track_running_stats_saved
@@ -125,6 +127,7 @@ class _BatchNorm(Module):
            momentum=exponential_average_factor,
            eps=self.eps,
            compute_mode=self.compute_mode,
            param_dim=self.param_dim,
        )

        if _ndims != 4:
--- a/imperative/python/test/unit/functional/test_functional.py
+++ b/imperative/python/test/unit/functional/test_functional.py
@@ -811,7 +811,8 @@ def test_batch_conv_bias():
    run(1, 4, 4, 5, 5, 3, 3, 0, 0, 1, 1, True)


 def test_conv2d_io16c32():
 def test_conv2d_autocast():
    """check amp's result is equal to manually converted result"""
    amp.enabled = True
    inp = tensor(np.random.randn(1, 3, 224, 224), dtype=np.float32)
    weight = tensor(np.random.randn(64, 3, 7, 7), dtype=np.float32)
@@ -918,11 +919,14 @@ def test_layer_norm():
    assert abs(outvar.mean()) < 1e-7


 def test_batchnorm2d_io16c32():
 def test_batchnorm2d_autocast():
    """check amp's result is equal to manually converted result"""
    amp.enabled = True
    inp = tensor(np.random.randn(1, 3, 224, 224), dtype=np.float32)
    weight = tensor(np.ones((1, 3, 1, 1)), dtype=np.float32)
    bias = tensor(np.zeros((1, 3, 1, 1)), dtype=np.float32)
    tshape = (1, 224, 224, 3)
    pshape = (1, 1, 1, 3)
    inp = tensor(np.random.randn(*tshape), dtype=np.float32)
    weight = tensor(np.ones(pshape, dtype=np.float32))
    bias = tensor(np.zeros(pshape, dtype=np.float32))

    out = F.batch_norm(inp, weight=weight, bias=bias, training=True, inplace=False)

--- a/imperative/src/impl/ops/batch_norm.cpp
+++ b/imperative/src/impl/ops/batch_norm.cpp
@@ -51,16 +51,16 @@ std::tuple<SmallVector<LogicalTensorDesc>, bool> infer_output_attrs_fallible(
              "BatchNorm expects 3 or 5 inputs; got %lu actually", nr_inp);
    // need running mean/variance
    bool need_stat = (nr_inp == 5) && op_def.fwd_mode == BatchNorm::FwdMode::TRAINING;
    size_t nr_out = need_stat? 5 : 3;
    size_t nr_out = need_stat? 6 : 4;
    SmallVector<LogicalTensorDesc> out_shapes(nr_out);
    auto&& i0 = inputs[0];
    auto&& i1 = inputs[1];
    // [running_mean, running_var,] save_mean, save_var
    for (size_t i = 0; i < nr_out-1; ++ i) {
    for (size_t i = 0; i < nr_out-2; ++ i) {
        out_shapes[i] = {i1.layout, i1.comp_node};
    }
    // output tensor
    out_shapes[nr_out-1] = {i0.layout, i0.comp_node};
    out_shapes[nr_out-2] = {TensorLayout({0}, dtype::Byte()), i0.comp_node}; // reserve
    out_shapes[nr_out-1] = {i0.layout, i0.comp_node}; // output
    return {out_shapes, out_shapes[nr_out-1].layout.ndim != 0};
 }

--- a/imperative/src/impl/proxy_graph.cpp
+++ b/imperative/src/impl/proxy_graph.cpp
@@ -689,7 +689,8 @@ ProxyGraph::make_backward_graph(
        output_descs.push_back({TensorLayout{i->dtype()}, i->comp_node()});
    }
    auto output_grads = make_input_place_holders(output_descs);
    mgb_assert(output_grads.size() == output_has_grad.size());
    mgb_assert(output_grads.size() == output_has_grad.size(), "%d vs %d",
               output_grads.size(), output_has_grad.size());
    bool any_input_has_grad = false;
    for (size_t i = 0; i < output_grads.size(); ++ i) {
        if (!output_has_grad[i]) {
--- a/imperative/src/test/backward_graph.cpp
+++ b/imperative/src/test/backward_graph.cpp
@@ -207,7 +207,7 @@ TEST(TestImperative, BatchNormGrad) {
        attr.param.write_pod(param);
        OpDef::make_backward_graph(attr, {inp, stat, stat, stat, stat},
                                   {true, true, true, false, false},
                                   {false, false, false, false, true});
                                   {false, false, false, false, false, true});
    }
    {
        auto op = OprAttr::make("BatchNorm");
@@ -216,7 +216,7 @@ TEST(TestImperative, BatchNormGrad) {
        param.fwd_mode = Param::FwdMode::TRAINING;
        attr.param.write_pod(param);
        OpDef::make_backward_graph(attr, {inp, stat, stat}, {true, true, true},
                                   {false, false, true});
                                   {false, false, false, true});
    }
 }

--- a/imperative/src/test/helper.cpp
+++ b/imperative/src/test/helper.cpp
@@ -99,7 +99,7 @@ UNUSED void print(const char* s) {
 OprChecker::OprChecker(std::shared_ptr<OpDef> opdef)
    : m_op(opdef) {}

 void OprChecker::run(std::vector<InputSpec> inp_keys) {
 void OprChecker::run(std::vector<InputSpec> inp_keys, std::set<size_t> bypass) {
    HostTensorGenerator<> gen;
    size_t nr_inps = inp_keys.size();
    SmallVector<HostTensorND> host_inp(nr_inps);
@@ -151,6 +151,8 @@ void OprChecker::run(std::vector<InputSpec> inp_keys) {
    func->execute().wait(); // run last because it may contain inplace operations

    for(size_t i = 0; i < nr_oups; ++ i) {
        if (bypass.find(i) != bypass.end())
            continue;
        MGB_ASSERT_TENSOR_EQ(host_sym_oup[i], host_imp_oup[i]);
    }
 }
--- a/imperative/src/test/helper.h
+++ b/imperative/src/test/helper.h
@@ -23,7 +23,7 @@ class OprChecker {
 public:
     using InputSpec = std::variant<HostTensorND, TensorShape>;
     OprChecker(std::shared_ptr<OpDef> opdef);
     void run(std::vector<InputSpec> inp_shapes);
     void run(std::vector<InputSpec> inp_shapes, std::set<size_t> bypass={});
 private:
     std::shared_ptr<OpDef> m_op;
 };
--- a/imperative/src/test/imperative.cpp
+++ b/imperative/src/test/imperative.cpp
@@ -73,7 +73,7 @@ TEST(TestImperative, BatchNorm) {
          TensorShape{1, C, 1, 1},
          TensorShape{1, C, 1, 1},
          TensorShape{1, C, 1, 1}
     });
     }, {4});
 }

 TEST(TestImperative, Concat) {
--- a/src/gopt/impl/inference.cpp
+++ b/src/gopt/impl/inference.cpp
@@ -1766,7 +1766,7 @@ void ConvertBatchNormToElemwisePass::apply(OptState& state) const {
                              x.dtype().name(), res.dtype().name());
                }
                rewriter.replace_var(
                        opr->output(4), res.node(),
                        opr->output(5), res.node(),
                        mgb_cstr_log(
                                "replace batch_norm(x, scale, bias, mean, "
                                "varience) "
--- a/src/gopt/test/inference.cpp
+++ b/src/gopt/test/inference.cpp
@@ -35,6 +35,7 @@
 #include "megdnn/tensor_format.h"

 #include <random>
 #include <vector>

 #if MGB_CUDA
 #include <cudnn.h>
@@ -1665,44 +1666,49 @@ TEST(TestGoptInference, concatbypass) {
 TEST(TestGoptInference, ConvertBatchNormPass) {
    auto cn = CompNode::load("cpu0");

    HostTensorGenerator<> gen(0, 1, 0);
    auto graph = ComputingGraph::make();
    graph->options().graph_opt_level = 0;
    auto mkvar = [&](const char* name, const TensorShape& shp) {
        return opr::Host2DeviceCopy::make(*graph, gen(shp, cn)).rename(name);
    };
    auto mkcvar = [&](const char* name, const TensorShape& shp) {
        return opr::SharedDeviceTensor::make(*graph, *gen(shp, cn))
                .rename(name);
    };
    using Param = opr::BatchNorm::Param;
    Param param(Param::ParamDim::DIM_1C11, Param::FwdMode::INFERENCE);
    TensorShape shp = {1, 3, 1, 1};
    auto x = mkvar("x", {2, 3, 16, 24}), scale = mkcvar("scale", shp),
         bias = mkcvar("bias", shp), mean = mkcvar("mean", shp);
    auto host_variance = gen(shp, cn);
    for (size_t i = 0; i < shp.total_nr_elems(); ++i) {
        host_variance->ptr<float>()[i] =
                std::abs(host_variance->ptr<float>()[i]);
    }
    auto variance = opr::SharedDeviceTensor::make(*graph, *host_variance)
                            .rename("variance");
    auto y = opr::BatchNorm::make(x, scale, bias, mean, variance, param)[4];
    SymbolVar y_opt;
    unpack_vector(gopt::optimize_for_inference(
                          {y}, gopt::OptimizeForInferenceOptions{}),
                  y_opt);
    ASSERT_EQ(0u, find_opr_num<opr::BatchNorm>(y_opt));
    graph->compile({{y_opt, {}}})
            ->to_json()
            ->writeto_fpath(
                    output_file("TestGoptInference.ConvertBatchNormPass.json"));
    std::vector<TensorShape> shps = {{1, 3, 1, 1}, {1, 1, 1, 3}},
                xshps = {{2, 3, 16, 24}, {2, 16, 24, 3}};
    for (int t = 0; t < 2; t++) {
        HostTensorGenerator<> gen(0, 1, 0);
        auto graph = ComputingGraph::make();
        graph->options().graph_opt_level = 0;
        auto mkvar = [&](const char* name, const TensorShape& shp) {
            return opr::Host2DeviceCopy::make(*graph, gen(shp, cn)).rename(name);
        };
        auto mkcvar = [&](const char* name, const TensorShape& shp) {
            return opr::SharedDeviceTensor::make(*graph, *gen(shp, cn))
                    .rename(name);
        };
        using Param = opr::BatchNorm::Param;
        Param::ParamDim param_dim = t == 0 ? Param::ParamDim::DIM_1C11 : Param::ParamDim::DIM_111C;
        Param param(param_dim, Param::FwdMode::INFERENCE);
        TensorShape shp = shps[t], xshp = xshps[t];
        auto x = mkvar("x", xshp), scale = mkcvar("scale", shp),
             bias = mkcvar("bias", shp), mean = mkcvar("mean", shp);
        auto host_variance = gen(shp, cn);
        for (size_t i = 0; i < shp.total_nr_elems(); ++i) {
            host_variance->ptr<float>()[i] =
                    std::abs(host_variance->ptr<float>()[i]);
        }
        auto variance = opr::SharedDeviceTensor::make(*graph, *host_variance)
                                .rename("variance");
        auto y = opr::BatchNorm::make(x, scale, bias, mean, variance, param)[5];
        SymbolVar y_opt;
        unpack_vector(gopt::optimize_for_inference(
                              {y}, gopt::OptimizeForInferenceOptions{}),
                      y_opt);
        ASSERT_EQ(0u, find_opr_num<opr::BatchNorm>(y_opt));
        graph->compile({{y_opt, {}}})
                ->to_json()
                ->writeto_fpath(
                        output_file("TestGoptInference.ConvertBatchNormPass.json"));

    HostTensorND host_y, host_y_opt;
    auto func = graph->compile({make_callback_copy(y, host_y),
                                make_callback_copy(y_opt, host_y_opt)});
    func->execute();
    MGB_ASSERT_TENSOR_NEAR(host_y, host_y_opt, 1e-5);
        HostTensorND host_y, host_y_opt;
        auto func = graph->compile({make_callback_copy(y, host_y),
                                    make_callback_copy(y_opt, host_y_opt)});
        func->execute();
        MGB_ASSERT_TENSOR_NEAR(host_y, host_y_opt, 1e-5);
    }
 }

 TEST(TestGoptInference, ConvBiasNonlinearityFusePass) {
--- a/src/opr/impl/dnn/batch_norm.cpp
+++ b/src/opr/impl/dnn/batch_norm.cpp
@@ -62,10 +62,12 @@ BatchNormForward::BatchNormForward(VarNode *x,
    }

    init_megdnn_opr(*this, param);
    output(4)->add_flag(VarNode::Flag::ALLOW_EMPTY_SHAPE);

    add_input({x, scale, bias, mean, variance});

    output(4)->add_flag(VarNode::Flag::ALLOW_EMPTY_SHAPE); // reserve
    output(5)->add_flag(VarNode::Flag::ALLOW_EMPTY_SHAPE);
    // running mean/var
    if (param.fwd_mode == Param::FwdMode::INFERENCE) {
        auto mark_empty_var = [&](VarNode *var) {
            var->add_flag(VarNode::Flag::ALLOW_EMPTY_SHAPE)
@@ -92,9 +94,10 @@ BatchNormForward::BatchNormForward(VarNode *x,
          {x, scale, bias}}
 {
    init_megdnn_opr(*this, param);
    output(4)->add_flag(VarNode::Flag::ALLOW_EMPTY_SHAPE);

    add_input({x, scale, bias});
    output(4)->add_flag(VarNode::Flag::ALLOW_EMPTY_SHAPE); // reserve
    output(5)->add_flag(VarNode::Flag::ALLOW_EMPTY_SHAPE);
    auto mark_empty_var = [&](VarNode *var) {
        var->add_flag(VarNode::Flag::ALLOW_EMPTY_SHAPE)
            .add_flag(VarNode::Flag::VOLATILE_CONTENT);
@@ -151,7 +154,7 @@ BatchNormForward::do_make_node_prop() const {

 void BatchNormForward::scn_do_execute() {
    auto &&x = input(0)->dev_tensor();
    auto &&y = output(4)->dev_tensor();
    auto &&y = output(5)->dev_tensor();
    if (need_stats()) {
        auto &&o0 = output(0)->dev_tensor(),
             &&o1 = output(1)->dev_tensor(),
@@ -192,9 +195,10 @@ void BatchNormForward::scn_do_execute() {
    }
    auto save_mean = output(2)->dev_tensor().as_megdnn();
    auto save_variance = output(3)->dev_tensor().as_megdnn();
    auto reserve = output(4)->dev_tensor().as_megdnn();
    auto workspace = intl::get_megdnn_workspace_from_var(output().back());
    megdnn_opr()->exec(x.as_megdnn(), scale, bias, mean, variance,
        save_mean, save_variance, y.as_megdnn(), workspace);
        save_mean, save_variance, reserve, y.as_megdnn(), workspace);
 }

 void BatchNormForward::add_input_layout_constraint() {
@@ -208,18 +212,25 @@ void BatchNormForward::get_output_var_shape(
        "expect input, scale and bias to be 4 dim tensor, but "
        "got input dim: %zu, scale dim: %zu, bias dim: %zu",
        inp_shape[0].ndim, inp_shape[1].ndim, inp_shape[2].ndim);

    size_t inp_c = inp_shape[0][1],
           scale_c = inp_shape[1][1],
           bias_c = inp_shape[2][1];
    
    size_t channel_idx;
    if (param().param_dim == Param::ParamDim::DIM_111C) {
        channel_idx = 3;
    } else {
        channel_idx = 1;
    }
    size_t inp_c = inp_shape[0][channel_idx],
           scale_c = inp_shape[1][channel_idx],
           bias_c = inp_shape[2][channel_idx];
    mgb_assert(inp_c == scale_c && inp_c == bias_c,
        "inconsistent channel size, input chennel: %zu, scale channel: %zu, bias channel: %zu",
        inp_c, scale_c, bias_c);

    out_shape[4] = inp_shape[0];
    out_shape[5] = inp_shape[0];
    for (size_t i = 0; i < 4; ++ i) {
        out_shape[i] = inp_shape[1];
    }
    out_shape[4] = {megdnn_opr()->get_reserve_in_bytes({inp_shape[0], input(0)->dtype()})};
    if (!need_stats()) {
        out_shape[0] = out_shape[1] = {0};
    }
@@ -231,7 +242,7 @@ size_t BatchNormForward::get_workspace_size_bytes(
 #define in(x) {input_shapes[x], input(x)->dtype()}
 #define out(x) {output_shapes[x], output(x)->dtype()}
    return megdnn_opr()->get_workspace_in_bytes(
            in(0), in(1), in(2), out(0), out(1), out(2), out(3), out(4));
            in(0), in(1), in(2), out(0), out(1), out(2), out(3), out(4), out(5));
 #undef in
 #undef out
 }
@@ -249,7 +260,8 @@ void BatchNormForward::init_output_dtype() {
    for (size_t i = 2; i < nr_inp; ++ i) {
        mgb_assert(input(1)->dtype() == input(i)->dtype());
    }
    output(4)->dtype(input(0)->dtype());
    output(4)->dtype(dtype::Byte()); // reserve
    output(5)->dtype(input(0)->dtype()); // output
    for (size_t i = 0; i < 4; ++ i) {
        output(i)->dtype(input(1)->dtype());
    }
@@ -271,9 +283,10 @@ MGB_IMPL_OPR_GRAD(BatchNormForward) {
    switch (opr.param().fwd_mode) {
    case BatchNorm::Param::FwdMode::TRAINING:
        grad = BatchNormBackward::make(
                opr.input(0), out_grad[4],
                opr.input(0), out_grad[5],
                opr.output(2), opr.output(3),
                opr.input(1), opr.param());
                opr.input(1), opr.output(4), // reserve
                opr.param());
        for (size_t i = 0; i < 3; ++ i) {
            ret[i] = grad[(i + 2) % 3].node();
        }
@@ -281,13 +294,13 @@ MGB_IMPL_OPR_GRAD(BatchNormForward) {
    case BatchNorm::Param::FwdMode::INFERENCE:
        auto sqrt_var = PowC::make((SymbolVar{opr.input(4)}
                        + static_cast<dt_float32>(opr.param().epsilon)), 0.5, opr.config());
        auto d_bn_scale_unreduced = SymbolVar{out_grad[4]} *
        auto d_bn_scale_unreduced = SymbolVar{out_grad[5]} *
                            (SymbolVar{opr.input(0)} - SymbolVar{opr.input(3)}) / sqrt_var;
        auto d_bn_scale = Reduce::make(d_bn_scale_unreduced,
                            Reduce::Param::Mode::SUM, GetVarShape::make(opr.input(1)));
        auto d_bn_bias = Reduce::make(out_grad[4],
        auto d_bn_bias = Reduce::make(out_grad[5],
                            Reduce::Param::Mode::SUM, GetVarShape::make(opr.input(2)));
        auto dx = SymbolVar{out_grad[4]} * SymbolVar{opr.input(1)} / sqrt_var;
        auto dx = SymbolVar{out_grad[5]} * SymbolVar{opr.input(1)} / sqrt_var;

        ret[0] = dx.node();
        ret[1] = d_bn_scale.node();
@@ -302,26 +315,26 @@ MGB_DYN_TYPE_OBJ_FINAL_IMPL(BatchNormBackward);

 BatchNormBackward::BatchNormBackward(VarNode *x,
        VarNode *y_grad, VarNode *save_mean,
        VarNode* save_variance, VarNode *scale,
        VarNode* save_variance, VarNode *scale, VarNode *reserve,
        const Param &param, const OperatorNodeConfig &config):
    Super({x->owner_graph(), config, "batch_norm_bwd",
            {x, y_grad, save_mean, save_variance, scale}},
            {x, y_grad, save_mean, save_variance, scale, reserve}},
            0, true)
 {
    init_megdnn_opr(*this, param);
    add_input({x, y_grad, save_mean, save_variance, scale});
    add_input({x, y_grad, save_mean, save_variance, scale, reserve});
 }

 SymbolVarArray BatchNormBackward::make(SymbolVar x,
        SymbolVar y_grad, SymbolVar save_mean,
        SymbolVar save_variance, SymbolVar scale,
        SymbolVar save_variance, SymbolVar scale, SymbolVar reserve,
        const Param &param,
        const OperatorNodeConfig &config) {
    auto&& out = x.node()
                    ->owner_graph()
                    ->insert_opr(std::make_unique<BatchNormBackward>(
                        x.node(), y_grad.node(), save_mean.node(),
                        save_variance.node(), scale.node(), param, config))
                        save_variance.node(), scale.node(), reserve.node(), param, config))
                    ->output();
    SymbolVarArray ret(out.size());
    for (size_t i = 0; i < ret.size(); i++) {
@@ -355,4 +368,11 @@ void BatchNormBackward::init_output_dtype() {
    output(2)->dtype(input(0)->dtype());
 }

 cg::OperatorNodeBase::NodeProp*
 BatchNormBackward::do_make_node_prop() const {
    auto ret = Super::do_make_node_prop();
    ret->add_dep_type_existing_var(input(5),
                                   NodeProp::DepType::VALUE_ALLOW_EMPTY);
    return ret;
 }
 // vim: syntax=cpp.doxygen foldmethod=marker foldmarker=f{{{,f}}}
--- a/src/opr/impl/dnn/dnn.sereg.h
+++ b/src/opr/impl/dnn/dnn.sereg.h
@@ -391,14 +391,14 @@ struct OprMaker<opr::BatchNorm, 0> {
 };

 template <>
 struct OprMaker<opr::BatchNormBackward, 5> {
 struct OprMaker<opr::BatchNormBackward, 6> {
    using Param = opr::BatchNormBackward::Param;
    static cg::OperatorNodeBase* make(const Param& param,
                                      const cg::VarNodeArray& i,
                                      ComputingGraph& graph,
                                      const OperatorNodeConfig& config) {
        MGB_MARK_USED_VAR(graph);
        return opr::BatchNormBackward::make(i[0], i[1], i[2], i[3], i[4], param,
        return opr::BatchNormBackward::make(i[0], i[1], i[2], i[3], i[4], i[5], param,
                                            config)[0]
                .node()
                ->owner_opr();
@@ -576,7 +576,7 @@ using ConvBiasForwardV4 = ConvBiasForward;
 MGB_SEREG_OPR(ConvBiasForwardV4, 0);

 MGB_SEREG_OPR(BatchNorm, 0);
 MGB_SEREG_OPR(BatchNormBackward, 5);
 MGB_SEREG_OPR(BatchNormBackward, 6);

 using LocalShareForwardV1 = LocalShareForward;
 using LocalShareBackwardDataV1 = LocalShareBackwardData;
--- a/src/opr/impl/internal/megdnn_opr_wrapper.inl
+++ b/src/opr/impl/internal/megdnn_opr_wrapper.inl
@@ -183,6 +183,10 @@ namespace {
 #define _FOREACH_IO(_i, _o) _i(0), _i(1), _i(2), _i(3), _i(4), _o(0), _o(1), _o(2)
 #include "./megdnn_opr_wrapper_megdnn_opr_meth_invoker_impl.inl"

 #define _NR_INPUTS 6
 #define _NR_OUTPUTS 3
 #define _FOREACH_IO(_i, _o) _i(0), _i(1), _i(2), _i(3), _i(4), _i(5), _o(0), _o(1), _o(2)
 #include "./megdnn_opr_wrapper_megdnn_opr_meth_invoker_impl.inl"
 } // anonymous namespace

    /* ======================= MegDNNOprWrapperFwd ======================= */
--- a/src/opr/include/megbrain/opr/dnn/batch_norm.h
+++ b/src/opr/include/megbrain/opr/dnn/batch_norm.h
@@ -24,7 +24,7 @@ namespace opr {
 /* input:
 *   x, scale, bias, [running_mean, running_variance]
 * output:
 *   running_mean, running_variance, save_mean, save_inv_variance, y
 *   running_mean, running_variance, save_mean, save_inv_variance, reserve, y
 *
 * All params have the same definition with cudnn batch normalization.
 *
@@ -35,6 +35,9 @@ namespace opr {
 *
 * For statistic(mean and variance) update:
 *     running_mean = (1 - moving_average) * running_mean + moving_average * new_mean
 *
 * Output reserve is used for cudnnBatchNormalizationForwardTrainingEx, and should
 * be preserved for backward.
 */
 MGB_DEFINE_OPR_CLASS(BatchNormForward,
    cg::OutshapePureByInshapeOpr<
@@ -86,7 +89,7 @@ MGB_DEFINE_OPR_CLASS(BatchNormForward,
 using BatchNorm = BatchNormForward;

 /* input:
 *   x, y_grad, save_mean, save_inv_variance, scale
 *   x, y_grad, save_mean, save_inv_variance, scale, reserve
 * output:
 *   scale_grad, bias_grad, x_grad
 */
@@ -97,15 +100,17 @@ MGB_DEFINE_OPR_CLASS(BatchNormBackward,
    public:
        BatchNormBackward(VarNode *x, VarNode *y_grad,
                VarNode *save_mean, VarNode *save_variance,
                VarNode *scale,
                VarNode *scale, VarNode *reserve,
                const Param &param,
                const OperatorNodeConfig &config);
        static SymbolVarArray make(SymbolVar x,
                SymbolVar y_grad, SymbolVar save_mean,
                SymbolVar save_variance, SymbolVar scale,
                SymbolVar reserve,
                const Param &param = {},
                const OperatorNodeConfig &config = {});
    private:
        NodeProp* do_make_node_prop() const override;
        void init_output_static_infer_desc() override;
        void init_output_dtype() override;
 };
--- a/src/opr/test/dnn/batch_norm.cpp
+++ b/src/opr/test/dnn/batch_norm.cpp
@@ -95,13 +95,13 @@ SymbolVarArray batch_norm(const SymbolVarArray& inputs, const Param &param) {
    SymbolVarArray ret;
    if (inputs.size() == 3) {
        ret = opr::BatchNorm::make(inputs[0], inputs[1], inputs[2], param);
        return {ret[4], ret[2], ret[3]};
        return {ret[5], ret[2], ret[3]};
    }
    else {
        mgb_assert(inputs.size() == 5);
        ret = opr::BatchNorm::make(inputs[0], inputs[1], inputs[2],
                                   inputs[3], inputs[4], param);
        return {ret[4], ret[0], ret[1]};
        return {ret[5], ret[0], ret[1]};
    }
 }