[Kunlun & CUDA & BANG] add depth2space operator (#178)

* add depth2space operator

* fix format

* add depth2space on cambricon bang

* add depth2space on gpu

---------

Co-authored-by: wanghailu <wanghailu0717@163.com>
Co-authored-by: wanghailu <wanghailu@qiyuanlab.com>
Co-authored-by: Haojie Wang <haojie0429@gmail.com>
This commit is contained in:
Hardy 2023-11-10 17:58:26 +08:00 committed by GitHub
parent 1ea450882b
commit 50862df765
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GPG Key ID: 4AEE18F83AFDEB23
9 changed files with 278 additions and 1 deletions

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@ -86,6 +86,8 @@ class GraphHandlerObj {
Tensor allReduceAvg(Tensor input, Tensor output); Tensor allReduceAvg(Tensor input, Tensor output);
TensorVec allGather(Tensor input, std::optional<TensorVec> outputs, int n); TensorVec allGather(Tensor input, std::optional<TensorVec> outputs, int n);
Tensor broadcast(Tensor input, Tensor output, int root); Tensor broadcast(Tensor input, Tensor output, int root);
Tensor depthToSpace(Tensor input, Tensor output, int blocksize,
std::string mode);
//------ modifiers //------ modifiers

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@ -19,4 +19,33 @@ class TransposeObj : public OperatorObj {
vector<int> getWorkloadVector() const override; vector<int> getWorkloadVector() const override;
vector<int> getOpAttrVector() const override; vector<int> getOpAttrVector() const override;
}; };
class DepthToSpaceObj : public OperatorObj {
public:
DepthToSpaceObj(GraphObj *graph, Tensor input, Tensor output, int blocksize,
std::string mode);
OP_CLONE(DepthToSpaceObj);
optional<vector<Shape>> inferShape(const TensorVec &inputs) const override;
std::string toString() const override;
int numInputs() const override { return 1; }
int numOutputs() const override { return 1; }
int getBlockSize() const { return blockSize; }
int getMode() const { return D2SMode; }
auto getModeString() const { return D2SModeString; }
auto getReshapeDim() const { return reshapeDim; }
auto getTransposeDim() const { return transposeDim; }
auto getOutDim() const { return outDim; }
private:
int blockSize;
int D2SMode;
std::string D2SModeString;
mutable std::vector<int> reshapeDim = {1, 1, 1, 1, 1, 1};
mutable std::vector<int> transposeDim = {1, 1, 1, 1, 1, 1};
mutable std::vector<int> outDim = {1, 1, 1, 1};
vector<int> getWorkloadVector() const override;
vector<int> getOpAttrVector() const override;
};
} // namespace infini } // namespace infini

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@ -491,6 +491,21 @@ class OnnxStub:
tensors.get(node.output[0]), tensors.get(node.output[0]),
perm, perm,
) )
elif node.op_type == "DepthToSpace":
blocksize = next(
(attr.i for attr in node.attribute if attr.name == "blocksize"),
None,
)
mode = next(
(attr.s for attr in node.attribute if attr.name == "mode"),
None,
)
tensors[node.output[0]] = self.handler.depthToSpace(
tensors[node.input[0]],
tensors.get(node.output[0]),
blocksize,
mode,
)
elif node.op_type == "Reshape": elif node.op_type == "Reshape":
dims = _search_shape(model, node.input[0]) dims = _search_shape(model, node.input[0])
size = reduce(lambda acc, x: acc * x, dims) size = reduce(lambda acc, x: acc * x, dims)

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@ -425,6 +425,19 @@ Tensor GraphHandlerObj::where(Tensor inputX, Tensor inputY, Tensor condition,
} }
} }
Tensor GraphHandlerObj::depthToSpace(Tensor input, Tensor output, int blocksize,
std::string mode) {
if (output) {
g->addOpWithOutputs<DepthToSpaceObj>(std::move(input), output,
blocksize, mode);
return output;
} else {
return g
->addOp<DepthToSpaceObj>(std::move(input), output, blocksize, mode)
->getOutput();
}
}
static CastType inferCastType(Tensor input, int to) { static CastType inferCastType(Tensor input, int to) {
auto iType = input->getDType(); auto iType = input->getDType();
auto oType = DataType(to); auto oType = DataType(to);

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@ -111,6 +111,7 @@ void export_values(py::module &m) {
.VALUE(OpType, Expand) .VALUE(OpType, Expand)
.VALUE(OpType, Erf) .VALUE(OpType, Erf)
.VALUE(OpType, Where) .VALUE(OpType, Where)
.VALUE(OpType, DepthToSpace)
.export_values(); .export_values();
#undef VALUE #undef VALUE
@ -286,6 +287,13 @@ static int cast_to_of(Operator op) {
return castOutputDtype.getIndex(); return castOutputDtype.getIndex();
} }
static std::tuple<int, std::string> depth_to_space_attrs_of(Operator op) {
IT_ASSERT(op->getOpType() == OpType::DepthToSpace);
auto depth_to_space = dynamic_cast<const DepthToSpaceObj *>(op.get());
return std::make_tuple(depth_to_space->getBlockSize(),
depth_to_space->getModeString());
}
void export_functions(py::module &m) { void export_functions(py::module &m) {
#define FUNCTION(NAME) def(#NAME, &NAME) #define FUNCTION(NAME) def(#NAME, &NAME)
m.def("cpu_runtime", &NativeCpuRuntimeObj::getInstance) m.def("cpu_runtime", &NativeCpuRuntimeObj::getInstance)
@ -321,7 +329,8 @@ void export_functions(py::module &m) {
.FUNCTION(split_axis_of) .FUNCTION(split_axis_of)
.FUNCTION(gather_axis_of) .FUNCTION(gather_axis_of)
.FUNCTION(flatten_axis_of) .FUNCTION(flatten_axis_of)
.FUNCTION(cast_to_of); .FUNCTION(cast_to_of)
.FUNCTION(depth_to_space_attrs_of);
#undef FUNCTION #undef FUNCTION
} }
@ -477,6 +486,7 @@ void init_graph_builder(py::module &m) {
.def("pRelu", &Handler::pRelu, policy::move) .def("pRelu", &Handler::pRelu, policy::move)
.def("clip", &Handler::clip, policy::move) .def("clip", &Handler::clip, policy::move)
.def("transpose", &Handler::transpose, policy::move) .def("transpose", &Handler::transpose, policy::move)
.def("depthToSpace", &Handler::depthToSpace, policy::move)
.def("reshape", &Handler::reshape, policy::move) .def("reshape", &Handler::reshape, policy::move)
.def("concat", &Handler::concat, policy::move) .def("concat", &Handler::concat, policy::move)
.def("split", &Handler::split, policy::move) .def("split", &Handler::split, policy::move)

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@ -48,6 +48,62 @@ class TransposeCnnl : public BangKernelWithoutConfig {
} }
}; };
class DepthToSpaceCnnl : public BangKernelWithoutConfig {
void compute(const Operator &_op,
const RuntimeObj *_context) const override {
auto op = as<DepthToSpaceObj>(_op);
auto context = dynamic_cast<const BangRuntimeObj *>(_context);
void *const aData = (op->getInputs(0)->getRawDataPtr<void *>());
void *const cData = (op->getOutput()->getRawDataPtr<void *>());
auto reshape = op->getReshapeDim();
auto transpose = op->getTransposeDim();
auto mode = op->getMode();
std::vector<int> permute;
if (mode == 0) {
permute = {0, 3, 4, 1, 5, 2};
} else {
permute = {0, 1, 4, 2, 5, 3};
}
cnnlTensorDescriptor_t aDesc, cDesc;
auto dimout = op->getOutput()->getDims();
checkCnnlError(cnnlCreateTensorDescriptor(&aDesc));
checkCnnlError(cnnlSetTensorDescriptor(aDesc, CNNL_LAYOUT_ARRAY,
CNNL_DTYPE_FLOAT, reshape.size(),
reshape.data()));
checkCnnlError(cnnlCreateTensorDescriptor(&cDesc));
checkCnnlError(
cnnlSetTensorDescriptor(cDesc, CNNL_LAYOUT_ARRAY, CNNL_DTYPE_FLOAT,
transpose.size(), transpose.data()));
cnnlTransposeDescriptor_t opDesc;
checkCnnlError(cnnlCreateTransposeDescriptor(&opDesc));
checkCnnlError(
cnnlSetTransposeDescriptor(opDesc, permute.size(), permute.data()));
size_t wsSize;
cnnlGetTransposeWorkspaceSize(context->cnnlHandle(), aDesc, opDesc,
&wsSize);
BangPtr wsData = context->getWorkspace(wsSize);
cnnlStatus_t stat =
cnnlTranspose_v2(context->cnnlHandle(), opDesc, aDesc, aData, cDesc,
cData, wsData, wsSize);
if (stat != CNNL_STATUS_SUCCESS)
return;
checkCnnlError(cnnlDestroyTensorDescriptor(aDesc));
checkCnnlError(cnnlDestroyTensorDescriptor(cDesc));
checkCnnlError(cnnlDestroyTransposeDescriptor(opDesc));
}
};
REGISTER_KERNEL(Device::BANG, OpType::Transpose, DataType::Float32, REGISTER_KERNEL(Device::BANG, OpType::Transpose, DataType::Float32,
TransposeCnnl, "Transpose_cnnl_BANG_Float32"); TransposeCnnl, "Transpose_cnnl_BANG_Float32");
REGISTER_KERNEL(Device::BANG, OpType::DepthToSpace, DataType::Float32,
DepthToSpaceCnnl, "DepthToSpace_cnnl_BANG_Float32");
}; // namespace infini }; // namespace infini

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@ -43,7 +43,54 @@ class TransposeCuda : public CudaKernelWithoutConfig {
} }
}; };
class DepthToSpaceCuda : public CudaKernelWithoutConfig {
void compute(const Operator &_op,
const RuntimeObj *_context) const override {
auto op = as<DepthToSpaceObj>(_op);
auto input = op->getInputs(0);
auto output = op->getOutput();
void *const inputData = input->getRawDataPtr<void *>();
void *const outputData = output->getRawDataPtr<void *>();
const auto &reshape = op->getReshapeDim();
const auto &transpose = op->getTransposeDim();
auto mode = op->getMode();
std::vector<int> perm;
if (mode == 0) {
perm = {0, 3, 4, 1, 5, 2};
} else {
perm = {0, 1, 4, 2, 5, 3};
}
int size = input->size();
int nDims = reshape.size();
// Compute strides
SmallArray strides, buffer;
IT_ASSERT(nDims <= SMALL_ARRAY_SIZE);
int curStride = 1;
for (int i = nDims - 1; i >= 0; --i) {
buffer.data[i] = curStride;
curStride *= reshape[i];
}
for (int i = 0; i < nDims; ++i) {
strides.data[i] = buffer.data[perm[i]];
}
SmallArray outputDims;
for (int i = 0; i < nDims; ++i) {
outputDims.data[i] = transpose[i];
}
transpose_kernel((float *)inputData, (float *)outputData, nDims, size,
strides, outputDims);
}
};
REGISTER_KERNEL(Device::CUDA, OpType::Transpose, DataType::Float32, REGISTER_KERNEL(Device::CUDA, OpType::Transpose, DataType::Float32,
TransposeCuda, "Transpose_CUDA_Float32"); TransposeCuda, "Transpose_CUDA_Float32");
REGISTER_KERNEL(Device::CUDA, OpType::DepthToSpace, DataType::Float32,
DepthToSpaceCuda, "DepthToSpace_CUDA_Float32");
} // namespace infini } // namespace infini

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@ -27,6 +27,33 @@ class TransposeXdnn : public KUNLUNKernelWithoutConfig {
} }
}; };
class DepthToSpaceXdnn : public KUNLUNKernelWithoutConfig {
void compute(const Operator &_op,
const RuntimeObj *_context) const override {
auto op = as<DepthToSpaceObj>(_op);
auto context = dynamic_cast<const KUNLUNRuntimeObj *>(_context);
void *const aData = (op->getInputs(0)->getRawDataPtr<void *>());
void *const cData = (op->getOutput()->getRawDataPtr<void *>());
auto reshape = op->getReshapeDim();
auto mode = op->getMode();
std::vector<int> permute;
if (mode == 0) {
permute = {0, 3, 4, 1, 5, 2};
} else {
permute = {0, 1, 4, 2, 5, 3};
}
auto ret = baidu::xpu::api::transpose<float>(
context->KUNLUNHandle(), (float *)aData, (float *)cData, reshape,
permute);
assert(ret == 0);
return;
}
};
REGISTER_KERNEL(Device::KUNLUN, OpType::Transpose, DataType::Float32, REGISTER_KERNEL(Device::KUNLUN, OpType::Transpose, DataType::Float32,
TransposeXdnn, "Transpose_xdnn_KUNLUN_Float32"); TransposeXdnn, "Transpose_xdnn_KUNLUN_Float32");
REGISTER_KERNEL(Device::KUNLUN, OpType::DepthToSpace, DataType::Float32,
DepthToSpaceXdnn, "DepthToSpace_xdnn_KUNLUN_Float32");
}; // namespace infini }; // namespace infini

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@ -53,4 +53,82 @@ vector<int> TransposeObj::getOpAttrVector() const {
return {type.underlying()}; return {type.underlying()};
} }
DepthToSpaceObj::DepthToSpaceObj(GraphObj *graph, Tensor input, Tensor output,
int blocksize, std::string mode)
: OperatorObj(OpType::DepthToSpace, {input}, {output}) {
blockSize = blocksize;
D2SMode = 0;
D2SModeString = "DCR";
if (mode == "CRD") {
D2SMode = 1;
D2SModeString = "CRD";
}
IT_ASSERT(checkValid(graph));
}
optional<vector<Shape>>
DepthToSpaceObj::inferShape(const TensorVec &inputs) const {
const auto A = inputs[0];
auto inputDim = A->getDims();
IT_ASSERT(inputDim.size() == 4);
if (D2SMode == 0) {
reshapeDim[0] = inputDim[0];
reshapeDim[1] = blockSize;
reshapeDim[2] = blockSize;
reshapeDim[3] = inputDim[1] / (blockSize * blockSize);
reshapeDim[4] = inputDim[2];
reshapeDim[5] = inputDim[3];
transposeDim[0] = reshapeDim[0];
transposeDim[1] = reshapeDim[3];
transposeDim[2] = reshapeDim[4];
transposeDim[3] = reshapeDim[1];
transposeDim[4] = reshapeDim[5];
transposeDim[5] = reshapeDim[2];
outDim[0] = inputDim[0];
outDim[1] = inputDim[1] / (blockSize * blockSize);
outDim[2] = inputDim[2] * blockSize;
outDim[3] = inputDim[3] * blockSize;
} else {
reshapeDim[0] = inputDim[0];
reshapeDim[1] = inputDim[1] / (blockSize * blockSize);
reshapeDim[2] = blockSize;
reshapeDim[3] = blockSize;
reshapeDim[4] = inputDim[2];
reshapeDim[5] = inputDim[3];
transposeDim[0] = reshapeDim[0];
transposeDim[1] = reshapeDim[1];
transposeDim[2] = reshapeDim[4];
transposeDim[3] = reshapeDim[2];
transposeDim[4] = reshapeDim[5];
transposeDim[5] = reshapeDim[3];
outDim[0] = inputDim[0];
outDim[1] = inputDim[1] / (blockSize * blockSize);
outDim[2] = inputDim[2] * blockSize;
outDim[3] = inputDim[3] * blockSize;
}
return {{outDim}};
}
std::string DepthToSpaceObj::toString() const {
std::ostringstream os;
os << type.toString() << "[" << getGuid() << "]";
os << "(";
os << vecToString(inputs[0]->getDims()) << ",";
os << "input=" << inputs[0]->getGuid() << ",";
os << "output=" << outputs[0]->getGuid() << ")";
return os.str();
}
vector<int> DepthToSpaceObj::getWorkloadVector() const {
vector<int> ret{type.underlying()};
const Shape shape = outputs[0]->getDims();
ret.insert(ret.end(), shape.begin(), shape.end());
return ret;
}
vector<int> DepthToSpaceObj::getOpAttrVector() const {
return {type.underlying()};
}
}; // namespace infini }; // namespace infini