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feat(mgb/gopt): add an opt pass for padding channels to enable fast int8/int4 support on GPU 

GitOrigin-RevId: 94c719bb5c
release-1.5
Megvii Engine Team 4 years ago
parent
56e863b7d4
commit
63a9bd30a8
3 changed files with 657 additions and 0 deletions
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  1. +340
    -0
      src/gopt/impl/tensor_reformat.cpp
  2. +10
    -0
      src/gopt/include/megbrain/gopt/inference.h
  3. +307
    -0
      src/gopt/test/inference.cpp

+ 340
- 0
src/gopt/impl/tensor_reformat.cpp View File

@@ -3624,4 +3624,344 @@ void FoldingConvBiasDimshufflePass::apply(OptState& opt) const {
MIDOUT_E
}

/* ==================== PaddingChaannelPass ================= */
const char* PaddingChannelPass::name() const {
return mgb_cstr_log("padding output channel to multiple of 4/32");
}

void PaddingChannelPass::apply(OptState& opt) const {
MIDOUT_B("PaddingChannelPassPass::apply");
// do not check shape
opt.set_var_replace_check_flag(VarReplaceCheckFlag::CHECK_ALL ^
VarReplaceCheckFlag::CHECK_SHAPE);

ThinHashSet<OperatorNodeBase*> padding_oprs;
ThinHashMap<Typeinfo*, thin_function<OperatorNodeBase*(
OperatorNodeBase*, const VarNodeArray&)>>
opr_replace_funcs;

auto rewriter = opt.graph().make_rewriter();
auto pad_in_channels = [](VarNode* inp, size_t pad_channels) -> VarNode* {
mgb_assert(inp->shape().ndim == 4);
mgb_assert(inp->dtype().enumv() == DTypeEnum::QuantizedS8 ||
inp->dtype().enumv() == DTypeEnum::QuantizedS32);
TensorShape shape{inp->shape()[0], pad_channels, inp->shape()[2],
inp->shape()[3]};
std::shared_ptr<HostTensorND> host_val = std::make_shared<HostTensorND>(
inp->comp_node(), shape, inp->dtype());
auto ptr = host_val->raw_ptr();
std::memset(ptr, 0, shape.total_nr_elems() * inp->dtype().size());
auto padding =
opr::ImmutableTensor::make(*inp->owner_graph(), *host_val);
auto out = opr::Concat::make({inp, padding}, 1);
return out.node();
};

auto pad_out_channels = [](VarNode* inp, size_t pad_channels) -> VarNode* {
mgb_assert(inp->shape().ndim == 4);
mgb_assert(inp->dtype().enumv() == DTypeEnum::QuantizedS8 ||
inp->dtype().enumv() == DTypeEnum::QuantizedS32);
TensorShape shape{pad_channels, inp->shape()[1], inp->shape()[2],
inp->shape()[3]};
std::shared_ptr<HostTensorND> host_val = std::make_shared<HostTensorND>(
inp->comp_node(), shape, inp->dtype());
auto ptr = host_val->raw_ptr();
std::memset(ptr, 0, shape.total_nr_elems() * inp->dtype().size());
auto padding =
opr::ImmutableTensor::make(*inp->owner_graph(), *host_val);
auto out = opr::Concat::make({inp, padding}, 0);
return out.node();
};

auto extract_subtensor = [](VarNode* inp,
size_t orig_channels) -> VarNode* {
mgb_assert(inp->shape().ndim == 4);
auto x = SymbolVar(inp);
auto cv = [&x](int v) { return x.make_scalar(v); };
using AIdx = opr::Subtensor::AxisIndexer;
auto sub = opr::Subtensor::make(
x, {AIdx::make_interval(0, None, None, cv(1)),
AIdx::make_interval(1, None, cv(orig_channels), None),
AIdx::make_interval(2, None, None, cv(1)),
AIdx::make_interval(3, None, None, cv(1))});
return sub.node();
};

// padding policy for conv bias with data type qint8
auto padding_policy_qint8 = [&padding_oprs, &pad_in_channels,
&pad_out_channels](
OperatorNodeBase* opr,
const VarNodeArray& new_inp) {
mgb_assert(opr->input().size() == new_inp.size());
mgb_assert(new_inp.size() == 3);
mgb_assert(opr->input(1)->shape().eq_shape(new_inp[1]->shape()));
auto inps = new_inp;
size_t out_channels = opr->input(1)->shape()[0];
size_t in_channels = opr->input(1)->shape()[1];
size_t new_in_channels = new_inp[0]->shape()[1];
// pad input channels
if (padding_oprs.count(opr->input(0)->owner_opr())) {
size_t pad_channels = new_in_channels - in_channels;
inps[1] = pad_in_channels(new_inp[1], pad_channels);
} else {
size_t pad_channels = 0;
mgb_assert(new_in_channels == in_channels);
if (in_channels <= 16) {
if (in_channels % 4)
pad_channels = 4 - (in_channels % 4); // pad to use dp4a
} else {
if (in_channels % 32)
pad_channels =
32 - (in_channels % 32); // pad to use tensorcore
}
if (pad_channels > 0) {
inps[0] = pad_in_channels(new_inp[0], pad_channels);
inps[1] = pad_in_channels(new_inp[1], pad_channels);
}
}
out_channels = inps[1]->shape()[0];
in_channels = inps[1]->shape()[1];
size_t pad_channels = 0;
if (in_channels <= 16) {
if (out_channels % 4)
pad_channels = 4 - (out_channels % 4);
} else {
if (out_channels <= 16) {
if (out_channels % 4)
pad_channels = 4 - (out_channels % 4);
} else {
if (out_channels % 32)
pad_channels = 32 - (out_channels % 32);
}
}
if (pad_channels > 0) {
inps[1] = pad_out_channels(inps[1], pad_channels);
inps[2] = pad_in_channels(inps[2], pad_channels);
padding_oprs.insert(opr);
}
return serialization::copy_opr_shallow(*opr, inps, opr->config());
};

// padding policy for conv bias with data type qint4 and quint4
auto padding_policy_int4 = [&padding_oprs, &pad_in_channels,
&pad_out_channels](
OperatorNodeBase* opr,
const VarNodeArray& new_inp) {
mgb_assert(opr->input().size() == new_inp.size());
mgb_assert(new_inp.size() == 3);
mgb_assert(opr->input(1)->shape().eq_shape(new_inp[1]->shape()));
auto inps = new_inp;
return serialization::copy_opr_shallow(*opr, inps, opr->config());
};

opr_replace_funcs[opr::ConvBiasForward::typeinfo()] =
[&padding_oprs, &padding_policy_qint8, &padding_policy_int4](
OperatorNodeBase* opr, const VarNodeArray& new_inp) {
if (opr->input(0)->dtype().enumv() == DTypeEnum::QuantizedS8) {
return padding_policy_qint8(opr, new_inp);
} else if (opr->input(0)->dtype().enumv() ==
DTypeEnum::QuantizedS4 ||
opr->input(0)->dtype().enumv() ==
DTypeEnum::Quantized4Asymm) {
return padding_policy_int4(opr, new_inp);
} else {
mgb_assert(
padding_oprs.count(opr->input(0)->owner_opr()) == 0,
"conv bias operator for data type(%s) cannot be "
"padded channel. "
"consumer(%s), producer(%s)",
opr->input(0)->dtype().name(), opr->cname(),
opr->input(0)->owner_opr()->cname());
return serialization::copy_opr_shallow(*opr, new_inp,
opr->config());
}
};
opr_replace_funcs[opr::ConvolutionBackwardData::typeinfo()] =
[&padding_oprs, &pad_in_channels, &pad_out_channels](
OperatorNodeBase* opr, const VarNodeArray& new_inp) {
if (opr->input(1)->dtype().enumv() != DTypeEnum::QuantizedS8) {
mgb_assert(
padding_oprs.count(opr->input(0)->owner_opr()) == 0,
"conv bwd data operator for data type(%s) cannot "
"be "
"padded channel. "
"consumer(%s), producer(%s)",
opr->input(0)->dtype().name(), opr->cname(),
opr->input(0)->owner_opr()->cname());
return serialization::copy_opr_shallow(*opr, new_inp,
opr->config());
}
mgb_assert(opr->input().size() == new_inp.size());
mgb_assert(new_inp.size() == 2,
"deconv (conv bwd data) operator for inference can "
"only have 2 input vars(got:%zu)",
new_inp.size());
mgb_assert(
opr->input(0)->shape().eq_shape(new_inp[0]->shape()));
auto inps = new_inp;
size_t out_channels = opr->input(0)->shape()[0];
size_t in_channels = opr->input(0)->shape()[1];
size_t new_out_channels = new_inp[1]->shape()[1];
// pad output channels
if (padding_oprs.count(opr->input(1)->owner_opr())) {
size_t pad_channels = new_out_channels - out_channels;
inps[0] = pad_out_channels(new_inp[0], pad_channels);
} else {
size_t pad_channels = 0;
if (out_channels % 4)
pad_channels = 4 - (out_channels % 4);
if (pad_channels > 0) {
inps[0] = pad_out_channels(new_inp[0], pad_channels);
inps[1] = pad_in_channels(new_inp[1], pad_channels);
}
}
out_channels = inps[0]->shape()[0];
in_channels = inps[0]->shape()[1];
// pad input channels
size_t pad_channels = 0;
if (in_channels % 4)
pad_channels = 4 - (in_channels % 4);
if (pad_channels > 0) {
inps[0] = pad_in_channels(inps[0], pad_channels);
padding_oprs.insert(opr);
}
return serialization::copy_opr_shallow(*opr, inps,
opr->config());
};
auto replace_format_aware_opr = [&padding_oprs](
OperatorNodeBase* opr,
const VarNodeArray& new_inp) {
if (opr->input(0)->dtype().enumv() != DTypeEnum::QuantizedS8 &&
opr->input(0)->dtype().enumv() != DTypeEnum::QuantizedS4 &&
opr->input(0)->dtype().enumv() != DTypeEnum::Quantized4Asymm) {
mgb_assert(padding_oprs.count(opr->input(0)->owner_opr()) == 0,
"operator(type:%s,name:%s) for data type(%s) cannot be "
"padded channel. extra info:"
"consumer(%s), producer(%s)",
opr->dyn_typeinfo()->name, opr->cname(),
opr->input(0)->dtype().name(), opr->cname(),
opr->input(0)->owner_opr()->cname());
return serialization::copy_opr_shallow(*opr, new_inp,
opr->config());
}
mgb_assert(opr->input().size() == new_inp.size());
if (padding_oprs.count(opr->input(0)->owner_opr())) {
padding_oprs.insert(opr);
}
return serialization::copy_opr_shallow(*opr, new_inp, opr->config());
};
opr_replace_funcs[opr::PoolingForward::typeinfo()] =
replace_format_aware_opr;
opr_replace_funcs[opr::WarpPerspectiveForward::typeinfo()] =
replace_format_aware_opr;

auto replace_elemwise_like_opr = [&padding_oprs, &extract_subtensor](
OperatorNodeBase* opr,
const VarNodeArray& new_inp) {
mgb_assert(opr->input().size() == new_inp.size());
bool have_padding_inp = false;
bool padding_all_inps = true;
bool same_padding = true;
size_t channels_after_padding = 0;
for (auto&& cur_inp : opr->input()) {
bool padding_cur_inp = padding_oprs.count(cur_inp->owner_opr()) > 0;
if (padding_cur_inp) {
if (!have_padding_inp)
have_padding_inp = true;
if (channels_after_padding == 0) {
channels_after_padding = cur_inp->shape()[1];
} else {
same_padding =
channels_after_padding == cur_inp->shape()[1];
}
}
if (padding_all_inps && (!padding_cur_inp || !same_padding))
padding_all_inps = false;
}
if (have_padding_inp && !padding_all_inps) {
auto inps = new_inp;
for (size_t i = 0; i < new_inp.size(); ++i) {
auto cur_inp = opr->input(i);
bool padding_cur_inp =
padding_oprs.count(cur_inp->owner_opr()) > 0;
if (padding_cur_inp) {
size_t orig_channels = cur_inp->shape()[1];
inps[i] = extract_subtensor(inps[i], orig_channels);
}
}
return serialization::copy_opr_shallow(*opr, inps, opr->config());
}
if (padding_all_inps) {
padding_oprs.insert(opr);
}
return serialization::copy_opr_shallow(*opr, new_inp, opr->config());
};
opr_replace_funcs[opr::ElemwiseMultiType::typeinfo()] =
replace_elemwise_like_opr;
opr_replace_funcs[opr::Elemwise::typeinfo()] = replace_elemwise_like_opr;
opr_replace_funcs[opr::TypeCvt::typeinfo()] = replace_elemwise_like_opr;

auto replace_nonpadding_oprs = [&padding_oprs, &extract_subtensor](
OperatorNodeBase* opr,
const VarNodeArray& new_inp) {
mgb_assert(opr->input().size() == new_inp.size());
bool have_padding_inp = false;
auto inps = new_inp;
for (size_t i = 0; i < new_inp.size(); ++i) {
auto cur_inp = opr->input(i);
bool padding_cur_inp = padding_oprs.count(cur_inp->owner_opr()) > 0;
if (padding_cur_inp) {
if (!have_padding_inp)
have_padding_inp = true;
size_t orig_channels = cur_inp->shape()[1];
inps[i] = extract_subtensor(inps[i], orig_channels);
}
}
return serialization::copy_opr_shallow(*opr, inps, opr->config());
};
opr_replace_funcs[opr::Reshape::typeinfo()] = replace_nonpadding_oprs;
opr_replace_funcs[opr::GetVarShape::typeinfo()] = replace_nonpadding_oprs;
opr_replace_funcs[opr::Concat::typeinfo()] = replace_nonpadding_oprs;

auto on_opr = [&opt, &rewriter, &opr_replace_funcs,
&extract_subtensor](OperatorNodeBase* opr) {
auto it = opr_replace_funcs.find(opr->dyn_typeinfo());
if (it != opr_replace_funcs.end()) {
VarNodeArray new_inp;
new_inp.reserve(opr->input().size());
for (auto&& inp : opr->input()) {
new_inp.push_back(rewriter.get_var(inp));
}
auto new_opr = (it->second)(opr, new_inp);
auto &&out0 = opr->output(), &&out1 = new_opr->output();
mgb_assert(out0.size() == out1.size(),
"bad opr replace: src=%s{%s} dst=%s{%s}, "
"src.size=%zu "
"dst.size=%zu",
opr->cname(), opr->dyn_typeinfo()->name,
new_opr->cname(), new_opr->dyn_typeinfo()->name,
out0.size(), out1.size());
for (size_t i = 0; i < out0.size(); ++i) {
if (!out0[i]->contain_flag(VarNode::Flag::VOLATILE_CONTENT)) {
mgb_assert(!out1[i]->contain_flag(
VarNode::Flag::VOLATILE_CONTENT));
auto src = out0[i];
auto dst = out1[i];
if (opt.graph().endpoint_contain(src) &&
!src->shape().eq_shape(dst->shape())) {
size_t orig_channels = src->shape()[1];
dst = extract_subtensor(dst, orig_channels);
}
rewriter.replace_var(src, dst, nullptr);
}
}
} else {
rewriter.auto_replace_outputs(opr);
}
};
opt.graph().iter(on_opr);
rewriter.apply_inplace();

MIDOUT_E
}
// vim: syntax=cpp.doxygen foldmethod=marker foldmarker=f{{{,f}}}

+ 10
- 0
src/gopt/include/megbrain/gopt/inference.h View File

@@ -409,6 +409,16 @@ namespace gopt {
void apply(OptState& opt) const override;
};

/*!
* \brief padding channel to enable fast int8/int4 support
* assume input network is built in NCHW tensor format
*/
class PaddingChannelPass final : public Pass {
public:
const char* name() const override;
void apply(OptState& opt) const override;
};

} // namespace gopt
} // namespace mgb



+ 307
- 0
src/gopt/test/inference.cpp View File

@@ -4178,6 +4178,313 @@ TEST(TestGoptInference, FoldingConvDimshuffleNCHW32NCHW4) {
MGB_ASSERT_TENSOR_EQ(host_y_fuse, host_y_non_fuse);
}
#endif

TEST(TestGoptInference, PaddingChannels) {
REQUIRE_GPU(1);
auto cn = CompNode::load("gpu0");
cn.activate();
auto&& prop = CompNodeEnv::from_comp_node(cn).cuda_env().device_prop;
auto sm_ver = prop.major * 10 + prop.minor;
if (sm_ver < 61) {
printf("This testcast ignored due to insufficient cuda cap(got: %d, "
"expected: %d)\n",
sm_ver, 61);
return;
}

HostTensorGenerator<dtype::Int8> gen;
auto graph = ComputingGraph::make();
graph->options().graph_opt_level = 0;
auto mkvar = [&](const char* name, const TensorShape& shp,
const DType& dtype) {
return opr::TypeCvt::make(
opr::Host2DeviceCopy::make(*graph, gen(shp, cn)).rename(name),
dtype);
};
auto mkcvar = [&](const char* name, const TensorShape& shp,
const DType& dtype) {
return opr::TypeCvt::make(
opr::SharedDeviceTensor::make(*graph, *gen(shp, cn))
.rename(name),
dtype);
};

auto x = mkvar("x", {16, 3, 14, 14}, dtype::QuantizedS8(2.5f)),
w = mkcvar("w", {20, 3, 3, 3}, dtype::QuantizedS8(2.5f)),
b = mkcvar("b", {1, 20, 1, 1}, dtype::QuantizedS32(6.25f));
opr::ConvBias::Param param;
param.format = opr::ConvBias::Param::Format::NCHW;
param.nonlineMode = opr::ConvBias::Param::NonlineMode::RELU;
param.stride_h = param.stride_w = 1;
param.pad_h = param.pad_w = 1;

auto y = opr::ConvBias::make(x, w, b, param, {},
OperatorNodeConfig{dtype::QuantizedS8(2.5f)});
auto w1 = mkcvar("w1", {24, 20, 3, 3}, dtype::QuantizedS8(2.5f)),
b1 = mkcvar("b1", {1, 24, 1, 1}, dtype::QuantizedS32(6.25f));
auto y1 = opr::ConvBias::make(y, w1, b1, param, {},
OperatorNodeConfig{dtype::QuantizedS8(2.5f)});
auto w2 = mkcvar("w2", {20, 24, 3, 3}, dtype::QuantizedS8(2.5f)),
b2 = mkcvar("b2", {1, 20, 1, 1}, dtype::QuantizedS32(6.25f));
auto y2 = opr::ConvBias::make(y1, w2, b2, param, {},
OperatorNodeConfig{dtype::QuantizedS8(2.5f)});
using ElemMultiMode = opr::ElemwiseMultiType::Param::Mode;
auto y3 = opr::ElemwiseMultiType::make(
{y, y2}, {ElemMultiMode::QFUSE_ADD_RELU},
OperatorNodeConfig{dtype::QuantizedS8{1.2f}});
y3 = opr::TypeCvt::make(y3, dtype::Float32());
SymbolVar y3_pad;
unpack_vector(gopt::GraphOptimizer{}
.add_pass<gopt::PaddingChannelPass>()
.apply({{y3}})
.endpoint_vars(),
y3_pad);
ASSERT_EQ(y3_pad.node()->shape()[1], y3.node()->shape()[1]);
SmallVector<cg::OperatorNodeBase*> oprs;
auto cb = [&oprs](cg::OperatorNodeBase* opr) {
if (opr->same_type<opr::ConvBias>()) {
oprs.push_back(opr);
}
};
cg::DepOprIter{cb}.add(y3_pad.node()->owner_opr());
ASSERT_EQ(oprs.size(), 3);
ASSERT_EQ(oprs[0]->output(0)->shape()[1], 20);
ASSERT_EQ(oprs[1]->output(0)->shape()[1], 32);
ASSERT_EQ(oprs[2]->output(0)->shape()[1], 32);
HostTensorND t1, t2;
auto func1 = graph->compile({make_callback_copy(y3, t1)});
func1->execute();
auto func2 = graph->compile({make_callback_copy(y3_pad, t2)});
func2->execute();
MGB_ASSERT_TENSOR_EQ(t1, t2);
}

TEST(TestGoptInference, ConcatAfterPaddingChannels) {
REQUIRE_GPU(1);
auto cn = CompNode::load("gpu0");
cn.activate();
auto&& prop = CompNodeEnv::from_comp_node(cn).cuda_env().device_prop;
auto sm_ver = prop.major * 10 + prop.minor;
if (sm_ver < 61) {
printf("This testcast ignored due to insufficient cuda cap(got: %d, "
"expected: %d)\n",
sm_ver, 61);
return;
}

HostTensorGenerator<dtype::Int8> gen;
auto graph = ComputingGraph::make();
graph->options().graph_opt_level = 0;
auto mkvar = [&](const char* name, const TensorShape& shp,
const DType& dtype) {
return opr::TypeCvt::make(
opr::Host2DeviceCopy::make(*graph, gen(shp, cn)).rename(name),
dtype);
};
auto mkcvar = [&](const char* name, const TensorShape& shp,
const DType& dtype) {
return opr::TypeCvt::make(
opr::SharedDeviceTensor::make(*graph, *gen(shp, cn))
.rename(name),
dtype);
};

auto x = mkvar("x", {16, 3, 14, 14}, dtype::QuantizedS8(2.5f)),
w = mkcvar("w", {18, 3, 3, 3}, dtype::QuantizedS8(2.5f)),
b = mkcvar("b", {1, 18, 1, 1}, dtype::QuantizedS32(6.25f));
opr::ConvBias::Param param;
param.format = opr::ConvBias::Param::Format::NCHW;
param.nonlineMode = opr::ConvBias::Param::NonlineMode::RELU;
param.stride_h = param.stride_w = 1;
param.pad_h = param.pad_w = 1;

auto y = opr::ConvBias::make(x, w, b, param, {},
OperatorNodeConfig{dtype::QuantizedS8(2.5f)});
auto w1 = mkcvar("w1", {18, 18, 3, 3}, dtype::QuantizedS8(2.5f)),
b1 = mkcvar("b1", {1, 18, 1, 1}, dtype::QuantizedS32(6.25f));
auto y1 = opr::ConvBias::make(y, w1, b1, param, {},
OperatorNodeConfig{dtype::QuantizedS8(2.5f)});
// concat at batch dim
auto y2 = opr::Concat::make({y, y1}, 0);
y2 = opr::TypeCvt::make(y2, dtype::Float32());
SymbolVar y2_pad;
unpack_vector(gopt::GraphOptimizer{}
.add_pass<gopt::PaddingChannelPass>()
.apply({{y2}})
.endpoint_vars(),
y2_pad);
ASSERT_EQ(y2_pad.node()->shape()[1], y2.node()->shape()[1]);
SmallVector<cg::OperatorNodeBase*> oprs;
auto cb = [&oprs](cg::OperatorNodeBase* opr) {
if (opr->same_type<opr::ConvBias>()) {
oprs.push_back(opr);
}
};
cg::DepOprIter{cb}.add(y2_pad.node()->owner_opr());
ASSERT_EQ(oprs.size(), 2);
ASSERT_EQ(oprs[0]->output(0)->shape()[1], 20);
ASSERT_EQ(oprs[1]->output(0)->shape()[1], 32);
HostTensorND t1, t2;
auto func1 = graph->compile({make_callback_copy(y2, t1)});
func1->execute();
auto func2 = graph->compile({make_callback_copy(y2_pad, t2)});
func2->execute();
MGB_ASSERT_TENSOR_EQ(t1, t2);
}

// FIXME replace cpu with gpu to enable gpu validation
TEST(TestGoptInference, PaddingChannelsWithPooling) {
REQUIRE_GPU(1);
auto cn = CompNode::load("cpu0");
// cn.activate();
// auto&& prop = CompNodeEnv::from_comp_node(cn).cuda_env().device_prop;
// auto sm_ver = prop.major * 10 + prop.minor;
// if (sm_ver < 61) {
// printf("This testcast ignored due to insufficient cuda cap(got: %d, "
// "expected: %d)\n",
// sm_ver, 61);
// return;
// }

HostTensorGenerator<dtype::Int8> gen;
auto graph = ComputingGraph::make();
graph->options().graph_opt_level = 0;
auto mkvar = [&](const char* name, const TensorShape& shp,
const DType& dtype) {
return opr::TypeCvt::make(
opr::Host2DeviceCopy::make(*graph, gen(shp, cn)).rename(name),
dtype);
};
auto mkcvar = [&](const char* name, const TensorShape& shp,
const DType& dtype) {
return opr::TypeCvt::make(
opr::SharedDeviceTensor::make(*graph, *gen(shp, cn))
.rename(name),
dtype);
};

auto x = mkvar("x", {16, 3, 14, 14}, dtype::QuantizedS8(2.5f)),
w = mkcvar("w", {20, 3, 3, 3}, dtype::QuantizedS8(2.5f)),
b = mkcvar("b", {1, 20, 1, 1}, dtype::QuantizedS32(6.25f));
opr::ConvBias::Param param;
param.format = opr::ConvBias::Param::Format::NCHW;
param.nonlineMode = opr::ConvBias::Param::NonlineMode::RELU;
param.stride_h = param.stride_w = 1;
param.pad_h = param.pad_w = 1;

auto y = opr::ConvBias::make(x, w, b, param, {},
OperatorNodeConfig{dtype::QuantizedS8(2.5f)});
auto w1 = mkcvar("w1", {24, 20, 3, 3}, dtype::QuantizedS8(2.5f)),
b1 = mkcvar("b1", {1, 24, 1, 1}, dtype::QuantizedS32(6.25f));
auto y1 = opr::ConvBias::make(y, w1, b1, param, {},
OperatorNodeConfig{dtype::QuantizedS8(2.5f)});

opr::Pooling::Param pool_param;
pool_param.format = opr::Pooling::Param::Format::NCHW;
y1 = opr::Pooling::make(y1, pool_param);
y1 = opr::TypeCvt::make(y1, dtype::Float32());
SymbolVar y1_pad;
unpack_vector(gopt::GraphOptimizer{}
.add_pass<gopt::PaddingChannelPass>()
.apply({{y1}})
.endpoint_vars(),
y1_pad);
ASSERT_EQ(y1_pad.node()->shape()[1], y1.node()->shape()[1]);
SmallVector<cg::OperatorNodeBase*> oprs;
auto cb = [&oprs](cg::OperatorNodeBase* opr) {
if (opr->same_type<opr::Pooling>()) {
oprs.push_back(opr);
}
};
cg::DepOprIter{cb}.add(y1_pad.node()->owner_opr());
ASSERT_EQ(oprs[0]->output(0)->shape()[1], 32);
HostTensorND t1, t2;
auto func1 = graph->compile({make_callback_copy(y1, t1)});
func1->execute();
auto func2 = graph->compile({make_callback_copy(y1_pad, t2)});
func2->execute();
MGB_ASSERT_TENSOR_EQ(t1, t2);
}

// FIXME replace cpu with gpu to enable gpu validation
TEST(TestGoptInference, PaddingChannelsWithWarpPerspective) {
REQUIRE_GPU(1);
auto cn = CompNode::load("cpu0");
// cn.activate();
// auto&& prop = CompNodeEnv::from_comp_node(cn).cuda_env().device_prop;
// auto sm_ver = prop.major * 10 + prop.minor;
// if (sm_ver < 61) {
// printf("This testcast ignored due to insufficient cuda cap(got: %d, "
// "expected: %d)\n",
// sm_ver, 61);
// return;
// }

HostTensorGenerator<dtype::Int8> gen;
auto graph = ComputingGraph::make();
graph->options().graph_opt_level = 0;
auto mkvar = [&](const char* name, const TensorShape& shp,
const DType& dtype) {
return opr::TypeCvt::make(
opr::Host2DeviceCopy::make(*graph, gen(shp, cn)).rename(name),
dtype);
};
auto mkcvar = [&](const char* name, const TensorShape& shp,
const DType& dtype) {
return opr::TypeCvt::make(
opr::SharedDeviceTensor::make(*graph, *gen(shp, cn))
.rename(name),
dtype);
};

std::shared_ptr<HostTensorND> mat = std::make_shared<HostTensorND>(
cn, TensorShape{16, 3, 3}, dtype::Float32());
warp_perspective_mat_gen(*mat, 16, 14, 14);
auto mat_var = opr::Host2DeviceCopy::make(*graph, mat).rename("mat");

auto x = mkvar("x", {16, 3, 14, 14}, dtype::QuantizedS8(2.5f)),
w = mkcvar("w", {20, 3, 3, 3}, dtype::QuantizedS8(2.5f)),
b = mkcvar("b", {1, 20, 1, 1}, dtype::QuantizedS32(6.25f));
opr::ConvBias::Param param;
param.format = opr::ConvBias::Param::Format::NCHW;
param.nonlineMode = opr::ConvBias::Param::NonlineMode::RELU;
param.stride_h = param.stride_w = 1;
param.pad_h = param.pad_w = 1;

auto y = opr::ConvBias::make(x, w, b, param, {},
OperatorNodeConfig{dtype::QuantizedS8(2.5f)});
auto w1 = mkcvar("w1", {24, 20, 3, 3}, dtype::QuantizedS8(2.5f)),
b1 = mkcvar("b1", {1, 24, 1, 1}, dtype::QuantizedS32(6.25f));
auto y1 = opr::ConvBias::make(y, w1, b1, param, {},
OperatorNodeConfig{dtype::QuantizedS8(2.5f)});

opr::WarpPerspective::Param warp_param;
warp_param.format = opr::WarpPerspective::Param::Format::NCHW;
y1 = opr::WarpPerspective::make(y1, mat_var, TensorShape{14, 14},
warp_param);
y1 = opr::TypeCvt::make(y1, dtype::Float32());
SymbolVar y1_pad;
unpack_vector(gopt::GraphOptimizer{}
.add_pass<gopt::PaddingChannelPass>()
.apply({{y1}})
.endpoint_vars(),
y1_pad);
ASSERT_EQ(y1_pad.node()->shape()[1], y1.node()->shape()[1]);
SmallVector<cg::OperatorNodeBase*> oprs;
auto cb = [&oprs](cg::OperatorNodeBase* opr) {
if (opr->same_type<opr::WarpPerspective>()) {
oprs.push_back(opr);
}
};
cg::DepOprIter{cb}.add(y1_pad.node()->owner_opr());
ASSERT_EQ(oprs[0]->output(0)->shape()[1], 32);
HostTensorND t1, t2;
auto func1 = graph->compile({make_callback_copy(y1, t1)});
func1->execute();
auto func2 = graph->compile({make_callback_copy(y1_pad, t2)});
func2->execute();
MGB_ASSERT_TENSOR_EQ(t1, t2);
}
#endif

// vim: syntax=cpp.doxygen foldmethod=marker foldmarker=f{{{,f}}}

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