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concat_split_op.h
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concat_split_op.h
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#ifndef CAFFE2_OPERATORS_CONCAT_SPLIT_OP_H_
#define CAFFE2_OPERATORS_CONCAT_SPLIT_OP_H_
#include "caffe2/core/context.h"
#include "caffe2/core/operator.h"
#include "caffe2/core/types.h"
#include "caffe2/utils/math.h"
namespace caffe2 {
namespace {
inline int GetDimFromOrderString(const string& str) {
auto order = StringToStorageOrder(str);
switch (order) {
case StorageOrder::NHWC:
return 3;
case StorageOrder::NCHW:
return 1;
default:
CAFFE_THROW("Unsupported storage order: ", str);
return -1;
}
}
} // namespace
template <class Context>
class SplitOp final : public Operator<Context> {
public:
static const int kSplitOpInputSize = 2;
USE_OPERATOR_CONTEXT_FUNCTIONS;
SplitOp(const OperatorDef& operator_def, Workspace* ws)
: Operator<Context>(operator_def, ws),
split_(this->template GetRepeatedArgument<int>("split")) {
CAFFE_ENFORCE(
!(OperatorBase::HasArgument("axis") &&
OperatorBase::HasArgument("order")),
"You shouldn't specify both the dim to split, and the order "
"in the case of 4-D images.");
if (OperatorBase::HasArgument("axis")) {
axis_ = this->template GetSingleArgument<int>("axis", -1);
// only exists for computing the gradient of a Concat with 'add_axis'
add_axis_ = this->template GetSingleArgument<int>("add_axis", 0);
} else {
axis_ = GetDimFromOrderString(
this->template GetSingleArgument<string>("order", "NCHW"));
add_axis_ = 0;
}
}
bool RunOnDevice() override;
protected:
int axis_;
int add_axis_;
vector<int> split_;
// Input: X, optionally split
// The split tensor is stored in CPU.
};
template <class Context>
class SplitByLengthsOp final : public Operator<Context> {
public:
USE_OPERATOR_CONTEXT_FUNCTIONS;
SplitByLengthsOp(const OperatorDef& operator_def, Workspace* ws)
: Operator<Context>(operator_def, ws) {
CAFFE_ENFORCE(
!(OperatorBase::HasArgument("axis") &&
OperatorBase::HasArgument("order")),
"You shouldn't specify both the dim to split, and the order "
"in the case of 4-D images.");
if (OperatorBase::HasArgument("axis")) {
axis_ = this->template GetSingleArgument<int>("axis", 0);
} else {
axis_ = GetDimFromOrderString(
this->template GetSingleArgument<string>("order", "NCHW"));
}
}
bool RunOnDevice() override;
protected:
int axis_;
Tensor inclusive_scan_buffer_{Context::GetDeviceType()};
Tensor inclusive_scan_length_buffer_{Context::GetDeviceType()};
// Input: X, optionally split
// The split tensor is stored in CPU.
};
template <class Context>
class ConcatOp final : public Operator<Context> {
public:
USE_OPERATOR_CONTEXT_FUNCTIONS;
ConcatOp(const OperatorDef& operator_def, Workspace* ws)
: Operator<Context>(operator_def, ws) {
CAFFE_ENFORCE(
!(OperatorBase::HasArgument("axis") &&
OperatorBase::HasArgument("order")),
"You shouldn't specify both the dim to concat, and the order "
"in the case of 4-D images.");
if (OperatorBase::HasArgument("axis")) {
axis_ = this->template GetSingleArgument<int>("axis", -1);
add_axis_ = this->template GetSingleArgument<int>("add_axis", 0);
} else {
axis_ = GetDimFromOrderString(
this->template GetSingleArgument<string>("order", "NCHW"));
add_axis_ = 0;
}
}
bool RunOnDevice() override;
protected:
int axis_;
int add_axis_;
// Input: a number of tensors. Output: Y, split
// The split are stored in CPU.
};
// Implementations
template <class Context>
bool SplitOp<Context>::RunOnDevice() {
auto& input = Input(0);
int canonical_axis = input.canonical_axis_index(axis_);
CAFFE_ENFORCE_LT(
canonical_axis, input.dim(), "Axis not in input ndim range.");
const int input_channels = input.dim32(canonical_axis);
const int* axis_data;
vector<int> equal_split;
if (InputSize() == kSplitOpInputSize) {
// We obtain split from the input tensor.
CAFFE_ENFORCE_EQ(
split_.size(),
0,
"If you set split with an input blob, do not pass in "
"split in the argument.");
auto& split_tensor = this->template Input<Tensor>(1, CPU);
CAFFE_ENFORCE_EQ(split_tensor.numel(), OutputSize());
axis_data = split_tensor.template data<int>();
} else if (split_.size() == 0) {
CAFFE_ENFORCE_EQ(
input_channels % OutputSize(),
0,
"If you did not specify split explicitly, the number of "
"input channels should be divisible by the output size.");
equal_split.resize(OutputSize(), input_channels / OutputSize());
axis_data = equal_split.data();
} else {
// We obtain split from the parameters.
CAFFE_ENFORCE_EQ(
split_.size(),
OutputSize(),
"The number of splits specified should be equal to the "
"number of outputs.");
axis_data = split_.data();
}
CAFFE_ENFORCE_EQ(
add_axis_ ? OutputSize()
: std::accumulate(axis_data, axis_data + OutputSize(), 0),
input_channels,
"Sum of split dimensions do not match: should be ",
input_channels);
vector<int64_t> output_dims(input.sizes().vec());
int before = 1, after = 1;
for (int i = 0; i < canonical_axis; ++i) {
before *= input.dim32(i);
}
for (int i = canonical_axis + 1; i < input.dim(); ++i) {
after *= input.dim32(i);
}
if (add_axis_) {
output_dims.erase(output_dims.begin() + canonical_axis);
}
size_t input_offset = 0;
for (int i = 0; i < OutputSize(); ++i) {
auto* output = Output(i);
auto axis_dim = add_axis_ ? 1 : axis_data[i];
if (!add_axis_) {
output_dims[canonical_axis] = axis_data[i];
}
output->Resize(output_dims);
math::CopyMatrix<Context>(
input.itemsize(),
before,
axis_dim * after,
static_cast<const char*>(input.raw_data()) + input_offset,
input.dim32(canonical_axis) * after,
output->raw_mutable_data(input.dtype()),
axis_dim * after,
&context_,
input.dtype().copy());
input_offset += axis_dim * after * input.itemsize();
}
return true;
}
// Implementations
template <class Context>
bool SplitByLengthsOp<Context>::RunOnDevice() {
auto& input = Input(0);
auto& length = this->template Input<Tensor>(1, CPU);
auto length_length = length.numel();
CAFFE_ENFORCE_EQ(
length_length % OutputSize(),
0,
"len(Lengths) should be divisible by OutputSize().");
int canonical_axis = input.canonical_axis_index(axis_);
CAFFE_ENFORCE_LT(
canonical_axis, input.dim(), "Axis not in input ndim range.");
const int input_channels = input.dim32(canonical_axis);
const auto* axis_data = length.template data<int>();
CAFFE_ENFORCE_EQ(
std::accumulate(axis_data, axis_data + length.numel(), 0),
input_channels,
"Sum of split dimensions do not match: should be ",
input_channels);
vector<int64_t> output_dims(input.sizes().vec());
int before = input.size_to_dim(canonical_axis);
int after = input.size_from_dim(canonical_axis + 1);
size_t input_offset = 0;
for (int i = 0; i < OutputSize(); ++i) {
auto* output = Output(i);
const auto* axis_offset = axis_data + length_length / OutputSize() * i;
auto axis_dim = std::accumulate(
axis_offset, axis_offset + length_length / OutputSize(), 0);
output_dims[canonical_axis] = axis_dim;
output->Resize(output_dims);
math::CopyMatrix<Context>(
input.itemsize(),
before,
axis_dim * after,
static_cast<const char*>(input.raw_data()) + input_offset,
input.dim32(canonical_axis) * after,
output->raw_mutable_data(input.dtype()),
axis_dim * after,
&context_,
input.dtype().copy());
input_offset += axis_dim * after * input.itemsize();
}
return true;
}
template <class Context>
bool ConcatOp<Context>::RunOnDevice() {
auto* output = Output(0);
// We can override default options(Context::GetDeviceType())
// by explictly passing in device type we want
Tensor* split = Output(
1, std::vector<int64_t>(1, InputSize()), at::dtype<int>().device(CPU));
int* axis_data = split->template mutable_data<int>();
auto& input_zero = Input(0);
int adj_size = input_zero.dim() + (add_axis_ ? 1 : 0);
int canonical_axis = canonical_axis_index_(axis_, adj_size);
CAFFE_ENFORCE_LT(canonical_axis, adj_size, "Axis not in input ndim range.");
for (int i = 1; i < InputSize(); ++i) {
CAFFE_ENFORCE(
Input(i).dtype() == input_zero.dtype(),
"All inputs must have the same type, expected: ",
input_zero.dtype().name(),
" but got: ",
Input(i).dtype().name(),
" for input: ",
i);
}
int before = 1, after = 1;
vector<int64_t> output_dims(input_zero.sizes().vec());
for (int i = 0; i < input_zero.dim(); ++i) {
if (i == canonical_axis && !add_axis_) {
continue;
}
int dim = input_zero.dim32(i);
if (i < canonical_axis) {
before *= dim;
} else { // i > canonical_axis || i == canonical_axis && add_axis_
after *= dim;
}
// check the input dims are compatible.
for (int j = 1; j < InputSize(); ++j) {
int dim_j = Input(j).dim32(i);
CAFFE_ENFORCE(
dim == dim_j,
"Expect dimension = ",
dim,
" got ",
dim_j,
" at axis = ",
i,
" for input: ",
j,
". The input tensors can only have different dimensions "
"when arg 'add_axis' = 0 and along the axis = ",
canonical_axis,
" <",
Input(0).sizes(),
"> vs <",
Input(j).sizes(),
">.");
}
}
int output_channels = 0;
for (int i = 0; i < InputSize(); ++i) {
axis_data[i] = add_axis_ ? 1 : Input(i).dim32(canonical_axis);
output_channels += axis_data[i];
}
if (add_axis_) {
output_dims.insert(output_dims.begin() + canonical_axis, output_channels);
} else {
output_dims[canonical_axis] = output_channels;
}
output->Resize(output_dims);
size_t output_offset = 0;
for (int i = 0; i < InputSize(); ++i) {
auto& input = Input(i);
auto axis_dim = add_axis_ ? 1 : input.dim32(canonical_axis);
math::CopyMatrix<Context>(
input.itemsize(),
before,
axis_dim * after,
input.raw_data(),
axis_dim * after,
static_cast<char*>(output->raw_mutable_data(input_zero.dtype())) +
output_offset,
output_channels * after,
&context_,
input_zero.dtype().copy());
output_offset += axis_dim * after * input.itemsize();
}
return true;
}
} // namespace caffe2
#endif // CAFFE2_OPERATORS_CONCAT_SPLIT_OP_H_