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RNN_miopen.cpp
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RNN_miopen.cpp
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#define TORCH_ASSERT_ONLY_METHOD_OPERATORS
#include <ATen/native/RNN.h>
#include <ATen/core/Tensor.h>
#include <ATen/Config.h>
#include <ATen/InitialTensorOptions.h>
#include <ATen/MatrixRef.h>
#include <ATen/TensorUtils.h>
#include <ATen/cuda/CUDAConfig.h>
#include <c10/util/Exception.h>
#include <c10/util/irange.h>
#ifndef AT_PER_OPERATOR_HEADERS
#include <ATen/Functions.h>
#include <ATen/NativeFunctions.h>
#else
#include <ATen/ops/cat.h>
#include <ATen/ops/empty.h>
#include <ATen/ops/miopen_rnn.h>
#include <ATen/ops/miopen_rnn_native.h>
#include <ATen/ops/miopen_rnn_backward_native.h>
#include <ATen/ops/zeros.h>
#include <ATen/ops/zeros_like.h>
#endif
#if !AT_ROCM_ENABLED()
namespace at { namespace native {
std::tuple<Tensor, Tensor, Tensor, Tensor, Tensor> miopen_rnn(
const Tensor& input_r, TensorList weight, int64_t weight_stride0,
const Tensor& hx, const c10::optional<Tensor>& cx_opt,
int64_t fn_mode, int64_t fn_hidden_size, int64_t fn_num_layers,
bool batch_first, double fn_dropout, bool fn_train, bool fn_bidirectional,
IntArrayRef fn_batch_sizes, const c10::optional<Tensor>& fn_dropout_state_opt
) {
AT_ERROR("miopen_rnn : ATen not compiled with MIOpen support.");
}
std::tuple<Tensor, Tensor, Tensor, std::vector<Tensor>> miopen_rnn_backward(
const Tensor& input, TensorList weight, int64_t weight_stride0, const Tensor& weight_buf, const Tensor& hx, const c10::optional<Tensor>& cx_opt,
const Tensor& output, const c10::optional<Tensor>& grad_output_r_opt, const c10::optional<Tensor>& grad_hy_r_opt, const c10::optional<Tensor>& grad_cy_r_opt, int64_t mode, int64_t hidden_size, int64_t num_layers, bool batch_first,
double dropout, bool train, bool bidirectional, IntArrayRef batch_sizes, const c10::optional<Tensor>& dropout_state_opt,
const Tensor& reserve, std::array<bool, 4> output_mask
) {
AT_ERROR("miopen_rnn_backward: ATen not compiled with MIOpen support.");
}
}} //namespace at::native
#else // AT_ROCM_ENABLED()
#include <ATen/miopen/miopen-wrapper.h>
#include <ATen/miopen/Descriptors.h>
#include <ATen/miopen/Types.h>
#include <ATen/miopen/Utils.h>
#include <ATen/TensorUtils.h>
#include <functional>
#include <iterator>
#include <sstream>
#include <algorithm>
#include <memory>
#include <mutex>
#include <stdint.h>
#include <unordered_map>
namespace at { namespace native {
//RNNDescriptor.
struct RNNDescriptorParams {
int64_t hidden_size;
int64_t num_layers;
miopenRNNDirectionMode_t direction;
miopenRNNMode_t rnn_mode;
miopenDataType_t datatype;
miopenRNNAlgo_t algo = miopenRNNdefault;
miopenRNNInputMode_t input_mode = miopenRNNlinear;
miopenRNNBiasMode_t bias_mode = miopenRNNNoBias;
int64_t num_directions() const {
return (direction == miopenRNNbidirection) ? 2 : 1;
}
void set_bidirectional(bool fn_bidirectional) {
direction = fn_bidirectional ? miopenRNNbidirection : miopenRNNunidirection;
}
void set_algo(miopenRNNAlgo_t algo) {
this->algo = algo;
}
void set_mode(int64_t fn_mode) {
switch (fn_mode) {
case 0:
rnn_mode = miopenRNNRELU;
break;
case 1:
rnn_mode = miopenRNNTANH;
break;
case 2:
rnn_mode = miopenLSTM;
break;
case 3:
rnn_mode = miopenGRU;
break;
default:
{
std::ostringstream oss;
oss << "unrecognized miopen RNN mode " << fn_mode;
AT_ERROR(oss.str());
}
}
}
void set(int64_t mode, int64_t hidden_size, int64_t num_layers, bool bidirectional, miopenDataType_t datatype, miopenRNNBiasMode_t bias_mode) {
this->set_mode(mode);
this->hidden_size = hidden_size;
this->num_layers = num_layers;
this->set_bidirectional(bidirectional);
this->datatype = datatype;
this->bias_mode = bias_mode;
}
RNNDescriptor descriptor() const {
RNNDescriptor rnn_desc;
rnn_desc.set(hidden_size, num_layers, input_mode, direction, rnn_mode, bias_mode, algo, datatype);
return rnn_desc;
}
};
//TensorDescriptor list.
std::vector<TensorDescriptor> rnn_descriptor_sequence(const Tensor& tensor, IntArrayRef batch_sizes) {
std::vector<TensorDescriptor> descriptors(batch_sizes.size());
size_t i =0;
auto batch_tensor_size = tensor.sizes().vec();
for (auto batch_size : batch_sizes) {
batch_tensor_size[0] = batch_size;
descriptors[i].set(getMiopenDataType(tensor), batch_tensor_size, tensor.strides(), 3);
i++;
}
return descriptors;
}
std::vector<TensorDescriptor> rnn_descriptor(const Tensor& tensor, int64_t N) {
std::vector<TensorDescriptor> descriptors(N);
for (const auto i : c10::irange(N)) {
descriptors[i].set(tensor, 5);
}
return descriptors;
}
struct TensorDescriptorListParams {
IntArrayRef batch_sizes;
int64_t seq_length;
int64_t mini_batch;
int64_t input_size;
int64_t batch_sizes_sum;
bool is_input_packed() const {
return batch_sizes.size() != 0;
}
void set(IntArrayRef input_sizes, IntArrayRef batch_sizes_, bool batch_first) {
batch_sizes = batch_sizes_;
if (is_input_packed()) {
seq_length = batch_sizes.size();
mini_batch = batch_sizes[0];
batch_sizes_sum = input_sizes[0];
input_size = input_sizes[1];
} else {
if (batch_first) {
seq_length = input_sizes[1];
mini_batch = input_sizes[0];
} else {
seq_length = input_sizes[0];
mini_batch = input_sizes[1];
}
input_size = input_sizes[2];
batch_sizes_sum = -1;
}
}
std::vector<TensorDescriptor> descriptors(Tensor x) const {
auto is_input_packed = batch_sizes.size() != 0;
if (is_input_packed) {
return rnn_descriptor_sequence(x, batch_sizes);
} else {
return rnn_descriptor(x[0], seq_length);
}
}
};
struct RNNParams {
RNNDescriptorParams rnn;
TensorDescriptorListParams tensors;
};
struct RNNDescriptors {
RNNDescriptor rnn_desc;
std::vector<TensorDescriptor> x_descs;
std::vector<TensorDescriptor> y_descs;
TensorDescriptor hx_desc;
TensorDescriptor hy_desc;
TensorDescriptor cx_desc;
TensorDescriptor cy_desc;
RNNDescriptors(const RNNParams& fn, miopenHandle_t handle, Tensor x, Tensor y, Tensor hx, Tensor cx) {
rnn_desc = fn.rnn.descriptor();
x_descs = fn.tensors.descriptors(x);
y_descs = fn.tensors.descriptors(y);
hx_desc.set(hx, 5);
hy_desc.set(hx, 5);
cx_desc.set(hx, 5);
cy_desc.set(hx, 5);
}
std::vector<miopenTensorDescriptor_t> get_descs(const std::vector<TensorDescriptor>& descs) {
std::vector<miopenTensorDescriptor_t> r;
r.reserve(descs.size());
for (auto& desc : descs) {
r.emplace_back(desc.desc());
}
return r;
}
std::vector<miopenTensorDescriptor_t> get_x_descs() {
return get_descs(x_descs);
}
std::vector<miopenTensorDescriptor_t> get_y_descs() {
return get_descs(y_descs);
}
};
Tensor permute_wei_for_miopen(Tensor wei, int64_t mode)
{
if (mode < 2)
return wei;
Tensor permuted_wei;
if(mode == 2) { // LSTM
auto sliced_tensor = wei.chunk(4, 0);
permuted_wei = at::cat({sliced_tensor[0], sliced_tensor[1], sliced_tensor[3], sliced_tensor[2]});
}
else if(mode == 3) { // GRU
auto sliced_tensor = wei.chunk(3, 0);
permuted_wei = at::cat({sliced_tensor[1], sliced_tensor[0], sliced_tensor[2]});
}
return permuted_wei;
}
void _viewOrCopyParams(MatrixRef<Tensor> params_from, MatrixRef<Tensor> params_to, bool copy) {
TORCH_CHECK(params_from.size(0) == params_to.size(0), "number of layers mismatch");
for (const auto i : c10::irange(params_from.size(0))) {
auto layer_params_from = params_from[i];
auto layer_params_to = params_to[i];
// NOTE: these lists have all weights before all biases, so if the layer
// doesn't use biases, iteration will terminate once layer_params_from ends
// and ignore them.
for (auto a = layer_params_from.begin(), b = layer_params_to.begin();
a != layer_params_from.end() && b != layer_params_to.end();
++a, ++b) {
auto param_from = *a, param_to = *b;
TORCH_CHECK(param_from.type() == param_to.type(), "parameter types mismatch");
if (copy) {
param_to.copy_(param_from.view_as(param_to));
} else {
param_from.resize_as_(param_to);
}
}
}
}
void _copyParams_and_permute(MatrixRef<Tensor> params_from, MatrixRef<Tensor> params_to, int64_t mode) {
TORCH_CHECK(params_from.size(0) == params_to.size(0), "number of layers mismatch");
for (const auto i : c10::irange(params_from.size(0))) {
auto layer_params_from = params_from[i];
auto layer_params_to = params_to[i];
for (auto a = layer_params_from.begin(), b = layer_params_to.begin();
a != layer_params_from.end() && b != layer_params_to.end();
++a, ++b) {
auto param_from = *a, param_to = *b;
TORCH_CHECK(param_from.type() == param_to.type(), "parameter types mismatch");
auto tmp = permute_wei_for_miopen(param_from, mode);
param_to.copy_(tmp.view_as(param_to));
}
}
}
void _copyParams(MatrixRef<Tensor> params_from, MatrixRef<Tensor> params_to) {
_viewOrCopyParams(params_from, params_to, true);
}
void _viewParams(MatrixRef<Tensor> params_from, MatrixRef<Tensor> params_to) {
_viewOrCopyParams(params_from, params_to, false);
}
int64_t get_num_weights(miopenHandle_t handle, const RNNDescriptor& rnn_desc,
const TensorDescriptor& x_desc, miopenDataType_t datatype)
{
size_t weight_size;
MIOPEN_CHECK(miopenGetRNNParamsSize(handle, rnn_desc.desc(), x_desc.desc(), &weight_size, datatype));
auto element_size = dataSize(datatype);
TORCH_CHECK(weight_size % element_size == 0, "miopenGetRNNParamsSize returned nonsensical weight_size.");
return weight_size / element_size;
}
int64_t _num_linear_layers(miopenRNNMode_t mode) {
switch(mode) {
case miopenLSTM:
return 8;
case miopenGRU:
return 6;
case miopenRNNRELU:
return 2;
case miopenRNNTANH:
return 2;
default:
AT_ERROR("Unknown miopen RNN mode : ", mode);
}
}
std::pair<std::vector<Tensor>, size_t> get_parameters(miopenHandle_t handle, const RNNDescriptorParams& rnn,
const RNNDescriptor& rnn_desc, const TensorDescriptor& x_desc, const FilterDescriptor& w_desc,
const Tensor& weight_buf)
{
std::vector<Tensor> params;
int64_t num_linear_layers = _num_linear_layers(rnn.rnn_mode);
int64_t num_layers = rnn.num_directions() * rnn.num_layers;
size_t cur_offset = 0;
size_t global_layer_params_count = 0;
auto elem_size = dataSize(getMiopenDataType(weight_buf));
auto bias_mode = rnn.bias_mode;
for (const auto layer : c10::irange(num_layers)) {
size_t layer_params_count = 0;
// Get layer params
for (const auto linear_id : c10::irange(num_linear_layers)) {
FilterDescriptor lin_layer_mat_desc;
size_t offset;
MIOPEN_CHECK(miopenGetRNNLayerParamOffset(
rnn_desc.desc(),
layer,
x_desc.desc(),
linear_id,
lin_layer_mat_desc.mut_desc(),
&offset));
size_t param_size;
MIOPEN_CHECK(miopenGetRNNLayerParamSize(
handle,
rnn_desc.desc(),
layer,
x_desc.desc(),
linear_id,
¶m_size));
param_size /= elem_size;
if(linear_id == 0 || linear_id == num_linear_layers / 2) {
std::initializer_list<int64_t> size = { static_cast<int64_t>(param_size * num_linear_layers / 2), 1L};
Tensor param = at::empty({0}, weight_buf.options()).set_(weight_buf.storage(), offset, size);
params.emplace_back(std::move(param));
layer_params_count++;
} else {
TORCH_INTERNAL_ASSERT(cur_offset == offset,
"cur_offset = ", cur_offset, " ; offset = ", offset);
}
cur_offset = offset + param_size;
}
// Get bias params
if (bias_mode == miopenRNNwithBias) {
for (const auto linear_id : c10::irange(num_linear_layers)) {
FilterDescriptor lin_layer_mat_desc;
size_t offset;
MIOPEN_CHECK(miopenGetRNNLayerBiasOffset(
rnn_desc.desc(),
layer,
x_desc.desc(),
linear_id,
lin_layer_mat_desc.mut_desc(),
&offset));
size_t bias_size;
MIOPEN_CHECK(miopenGetRNNLayerBiasSize(
handle,
rnn_desc.desc(),
layer,
linear_id,
&bias_size));
bias_size /= elem_size;
if(linear_id == 0 || linear_id == num_linear_layers / 2) {
std::initializer_list<int64_t> size = { static_cast<int64_t>(bias_size * num_linear_layers / 2), 1L};
Tensor param = at::empty({0}, weight_buf.options()).set_(weight_buf.storage(), offset, size);
params.emplace_back(std::move(param));
layer_params_count++;
} else {
TORCH_INTERNAL_ASSERT(cur_offset == offset,
"cur_offset = ", cur_offset, " ; offset = ", offset);
}
cur_offset = offset + bias_size;
}
}
if (layer == 0) {
global_layer_params_count = layer_params_count;
} else {
TORCH_INTERNAL_ASSERT(global_layer_params_count == layer_params_count,
"global_layer_params_count = ", global_layer_params_count,
"; layer_params_count = ", layer_params_count);
}
} // layer
return std::make_pair(params, global_layer_params_count);
}
std::vector<int64_t> _input_size(const TensorDescriptorListParams& tensors) {
if (tensors.is_input_packed()) {
return {tensors.batch_sizes_sum, tensors.input_size};
} else {
return {tensors.seq_length, tensors.mini_batch, tensors.input_size};
}
}
std::vector<int64_t> _hidden_size(const RNNDescriptorParams& rnn, const TensorDescriptorListParams& tensors) {
return {rnn.num_layers * rnn.num_directions(), tensors.mini_batch, rnn.hidden_size};
}
std::vector<int64_t> _output_size(const RNNDescriptorParams& rnn, const TensorDescriptorListParams& tensors) {
if (tensors.is_input_packed()) {
return {tensors.batch_sizes_sum, rnn.hidden_size * rnn.num_directions()};
} else {
return {tensors.seq_length, tensors.mini_batch, rnn.hidden_size * rnn.num_directions()};
}
}
std::tuple<Tensor, Tensor, Tensor, Tensor, Tensor> miopen_rnn(
const Tensor& input_r, TensorList weight, int64_t weight_stride0,
const Tensor& hx, const c10::optional<Tensor>& cx_opt,
int64_t fn_mode, int64_t fn_hidden_size, int64_t fn_num_layers,
bool batch_first, double fn_dropout, bool fn_train, bool fn_bidirectional,
IntArrayRef fn_batch_sizes, const c10::optional<Tensor>& fn_dropout_state_opt
) {
// See [Note: hacky wrapper removal for optional tensor]
c10::MaybeOwned<Tensor> cx_maybe_owned = at::borrow_from_optional_tensor(cx_opt);
const Tensor& cx = *cx_maybe_owned;
const Tensor& fn_dropout_state = c10::value_or_else(fn_dropout_state_opt, [] {return Tensor();});
check_attributes(input_r, weight, {hx, cx});
auto input = input_r;
RNNParams fn;
auto datatype = getMiopenDataType(input);
miopenRNNBiasMode_t bias_mode = (weight_stride0 == 4) ? miopenRNNwithBias : miopenRNNNoBias;
fn.rnn.set(fn_mode, fn_hidden_size, fn_num_layers, fn_bidirectional, datatype, bias_mode);
fn.tensors.set(input.sizes(), fn_batch_sizes, batch_first);
if (fn.rnn.rnn_mode != miopenLSTM) {
TORCH_CHECK(!cx.defined(), "miopen_rnn: illegal defined cx for non-LSTM RNN.");
}
auto is_input_packed = fn.tensors.batch_sizes.size() != 0;
if (batch_first && !is_input_packed) {
input = input.transpose(0, 1);
}
auto hidden_size = _hidden_size(fn.rnn, fn.tensors);
auto output_size = _output_size(fn.rnn, fn.tensors);
TORCH_CHECK(hx.is_contiguous(), "miopen_rnn : hx is not contiguous.");
TORCH_CHECK(!cx.defined() || cx.is_contiguous(), "miopen_rnn : cx is not contiguous.");
auto x = input.contiguous();
auto output = at::empty(output_size, input.options());
auto hy = at::empty(hidden_size, hx.options());
Tensor cy;
if (cx.defined()) {
cy = at::empty(hidden_size, cx.options());
} else {
cy = at::empty({0}, hx.options());
}
auto y = output;
auto handle = getMiopenHandle();
miopenRNNAlgo_t algo = miopenRNNdefault;
fn.rnn.set_algo(algo);
RNNDescriptors descs(fn, handle, x, y, hx, cx);
FilterDescriptor w_desc;
auto num_weights = get_num_weights(handle, descs.rnn_desc, descs.x_descs[0], datatype);
auto weight_buf = at::empty(num_weights, x.options());
w_desc.set(weight_buf, 3);
weight_buf.zero_();
std::vector<Tensor> params;
size_t params_stride0;
std::tie(params, params_stride0) = get_parameters(handle, fn.rnn, descs.rnn_desc, descs.x_descs[0], w_desc, weight_buf);
if (fn_mode < 2)
_copyParams(MatrixRef<Tensor>{weight, static_cast<size_t>(weight_stride0)},
MatrixRef<Tensor>{params, params_stride0});
else
_copyParams_and_permute(MatrixRef<Tensor>{weight, static_cast<size_t>(weight_stride0)},
MatrixRef<Tensor>{params, params_stride0}, fn_mode);
TORCH_CHECK(!cx.defined() || cx.sizes().equals(hidden_size), "Expected cell size ", IntArrayRef{hidden_size}, ", got", cx.sizes());
size_t workspace_size;
auto x_descs_arr = descs.get_x_descs();
auto y_descs_arr = descs.get_y_descs();
//Allocate workspace size.
MIOPEN_CHECK(miopenGetRNNWorkspaceSize(handle, descs.rnn_desc.desc(), fn.tensors.seq_length, x_descs_arr.data(), &workspace_size));
auto workspace = at::empty(workspace_size, input.options().dtype(kByte));
//Train or inference.
Tensor reserve;
if (fn_train) { //Train.
size_t reserver_size;
MIOPEN_CHECK(miopenGetRNNTrainingReserveSize(handle, descs.rnn_desc.desc(), fn.tensors.seq_length, x_descs_arr.data(), &reserver_size));
reserve = at::empty(reserver_size, input.options().dtype(kByte));
MIOPEN_CHECK(miopenRNNForwardTraining(handle, descs.rnn_desc.desc(), fn.tensors.seq_length,
x_descs_arr.data(), x.data_ptr(),
descs.hx_desc.desc(), hx.data_ptr(),
descs.cx_desc.desc(), cx.defined() ? cx.data_ptr() : nullptr,
w_desc.desc(), weight_buf.data_ptr(),
y_descs_arr.data(), y.data_ptr(),
descs.hy_desc.desc(), hy.data_ptr(),
descs.cy_desc.desc(), cy.defined() ? cy.data_ptr() : nullptr,
workspace.data_ptr(), workspace_size, reserve.data_ptr(), reserver_size ));
} else { //Inference.
reserve = at::empty({0}, input.options().dtype(kByte));
MIOPEN_CHECK(miopenRNNForwardInference(handle, descs.rnn_desc.desc(), fn.tensors.seq_length,
x_descs_arr.data(), x.data_ptr(),
descs.hx_desc.desc(), hx.data_ptr(),
descs.cx_desc.desc(), cx.defined() ? cx.data_ptr() : nullptr,
w_desc.desc(), weight_buf.data_ptr(),
y_descs_arr.data(), y.data_ptr(),
descs.hy_desc.desc(), hy.data_ptr(),
descs.cy_desc.desc(), cy.defined() ? cy.data_ptr() : nullptr,
workspace.data_ptr(), workspace_size));
}
if (batch_first && !is_input_packed) {
output.transpose_(0, 1);
}
return std::make_tuple(output, hy, cy, reserve, weight_buf);
}
std::tuple<Tensor, Tensor, Tensor, Tensor> miopen_rnn_backward_input(
const Tensor& input_r, const Tensor& weight_buf, const Tensor& hx, const Tensor& cx,
const Tensor& output_r, const Tensor& grad_output_r, const Tensor& grad_hy,
const Tensor& grad_cy,
int64_t fn_mode, int64_t fn_hidden_size,
int64_t fn_num_layers, bool batch_first, double fn_dropout,
bool fn_train, bool fn_bidirectional, IntArrayRef fn_batch_sizes,
const Tensor& fn_dropout_state, const Tensor& fn_reserve,
std::array<bool, 3> output_mask
) {
auto input = input_r;
auto grad_output = grad_output_r;
auto output = output_r;
RNNParams fn;
auto datatype = getMiopenDataType(input);
fn.rnn.set(fn_mode, fn_hidden_size, fn_num_layers, fn_bidirectional, datatype, miopenRNNwithBias);
fn.tensors.set(input.sizes(), fn_batch_sizes, batch_first);
auto handle = getMiopenHandle();
if(fn.rnn.rnn_mode != miopenLSTM) {
TORCH_CHECK(!cx.defined(), "rnn: illegal defined cx for non-LSTM RNN");
}
auto is_input_packed = fn_batch_sizes.size() != 0;
if (batch_first && !is_input_packed) {
input = input.transpose(0, 1);
grad_output = grad_output.transpose(0, 1);
output = output.transpose(0, 1);
}
auto input_size = _input_size(fn.tensors);
auto hidden_size = _hidden_size(fn.rnn, fn.tensors);
auto output_size = _output_size(fn.rnn, fn.tensors);
TORCH_CHECK(hx.is_contiguous(), "rnn: hx is not contiguous");
TORCH_CHECK(!cx.defined() || cx.is_contiguous(), "rnn: cx is not contiguous");
auto x = input.contiguous();
auto dy = grad_output.contiguous();
auto y = output;
auto w = weight_buf;
auto dx = at::empty(input.sizes(), input.options());
auto dhy = grad_hy.contiguous().view(hidden_size);
auto dcy = grad_cy.defined() ? grad_cy.contiguous().view(hidden_size) : Tensor();
auto dhx = at::empty(hidden_size, hx.options());
TORCH_INTERNAL_ASSERT(cx.defined() || !output_mask[2],
"illegally required grad of cx for non-LSTM RNN");
auto dcx = cx.defined() ? at::empty(hidden_size, cx.options()) : Tensor();
TORCH_CHECK(fn_train, "miopen RNN backward can only be called in training mode");
TORCH_CHECK(input.sizes().equals(input_size),
"Expected input size ", IntArrayRef{input_size}, ", got ", input.sizes());
TORCH_CHECK(output.sizes().equals(output_size),
"Expected output size ", IntArrayRef{output_size}, ", got ", output.sizes());
TORCH_CHECK(!hx.defined() || hx.sizes().equals(hidden_size),
"Expected hidden size ", IntArrayRef{hidden_size}, ", got ", hx.sizes());
TORCH_CHECK(!cx.defined() || cx.sizes().equals(hidden_size),
"Expected cell size ", IntArrayRef{hidden_size}, ", got ", cx.sizes());
TORCH_CHECK(!dhy.defined() || dhy.sizes().equals(hidden_size),
"Expected d_hidden size ", IntArrayRef{hidden_size}, ", got ", dhy.sizes());
TORCH_CHECK(!dcy.defined() || dcy.sizes().equals(hidden_size),
"Expected d_cell size ", IntArrayRef{hidden_size}, ", got ", dcy.sizes());
TORCH_CHECK(dhy.is_cuda() && dy.is_cuda() && (!dcy.defined() || dcy.is_cuda()),
"Gradients aren't HIP tensors");
miopenRNNAlgo_t algo = miopenRNNdefault;
fn.rnn.set_algo(algo);
RNNDescriptors descs(fn, handle, x, y, hx, cx);
FilterDescriptor w_desc;
w_desc.set(weight_buf, 3);
size_t workspace_size;
auto x_descs_arr = descs.get_x_descs();
auto y_descs_arr = descs.get_y_descs();
MIOPEN_CHECK(miopenGetRNNWorkspaceSize(
handle,
descs.rnn_desc.desc(),
fn.tensors.seq_length,
x_descs_arr.data(),
&workspace_size
));
auto workspace = at::empty(workspace_size, input.options().dtype(kByte));
MIOPEN_CHECK(miopenRNNBackwardData(
handle,
descs.rnn_desc.desc(),
fn.tensors.seq_length,
y_descs_arr.data(), y.data_ptr(),
y_descs_arr.data(), dy.data_ptr(),
descs.hy_desc.desc(), dhy.data_ptr(),
descs.cy_desc.desc(), cx.defined() ? dcy.data_ptr() : nullptr,
w_desc.desc(), w.data_ptr(),
descs.hx_desc.desc(), hx.data_ptr(),
descs.cx_desc.desc(), cx.defined() ? cx.data_ptr() : nullptr,
x_descs_arr.data(), dx.data_ptr(),
descs.hx_desc.desc(), dhx.data_ptr(),
descs.cx_desc.desc(), cx.defined() ? dcx.data_ptr() : nullptr,
workspace.data_ptr(), workspace.size(0),
fn_reserve.data_ptr(), fn_reserve.size(0)
));
if(batch_first && !is_input_packed) {
dx = dx.transpose_(0, 1);
}
return std::make_tuple(dx, dhx, dcx, workspace);
}
std::vector<Tensor> miopen_rnn_backward_weight(
const Tensor& input_r, TensorList weight_arr, int64_t weight_stride0,
const Tensor& weight_buf, const Tensor& hx, const Tensor& cx,
const Tensor& output_r,
int64_t fn_mode, int64_t fn_hidden_size,
int64_t fn_num_layers, bool batch_first, double fn_dropout,
bool fn_train, bool fn_bidirectional, IntArrayRef fn_batch_sizes,
const Tensor& fn_dropout_state, const Tensor& fn_reserve, const Tensor& fn_workspace
) {
MatrixRef<Tensor> weight{ weight_arr, static_cast<size_t>(weight_stride0) };
auto input = input_r;
auto output = output_r;
RNNParams fn;
auto datatype = getMiopenDataType(input);
miopenRNNBiasMode_t bias_mode = (weight_stride0 == 4) ? miopenRNNwithBias : miopenRNNNoBias;
fn.rnn.set(fn_mode, fn_hidden_size, fn_num_layers, fn_bidirectional, datatype, bias_mode);
fn.tensors.set(input.sizes(), fn_batch_sizes, batch_first);
auto handle = getMiopenHandle();
if (fn.rnn.rnn_mode != miopenLSTM) {
TORCH_CHECK(!cx.defined(), "rnn: illegal defined cx for non-LSTM RNN");
}
auto is_input_packed = fn_batch_sizes.size() != 0;
if (batch_first && !is_input_packed) {
input = input.transpose(0, 1);
output = output.transpose(0, 1);
}
auto input_size = _input_size(fn.tensors);
auto hidden_size = _hidden_size(fn.rnn, fn.tensors);
TORCH_CHECK(fn_train, "miopen RNN backward can only be called in training mode");
TORCH_CHECK(input.sizes().equals(input_size),
"Expected input size ", IntArrayRef{input_size}, ", got ", input.sizes());
TORCH_CHECK(!hx.defined() || hx.sizes().equals(hidden_size),
"Expected hidden size ", IntArrayRef{hidden_size}, ", got ", hx.sizes());
TORCH_CHECK(hx.is_contiguous(), "rnn: hx is not contiguous");
TORCH_CHECK(!cx.defined() || cx.is_contiguous(), "rnn: cx is not contiguous");
auto x = input.contiguous();
const auto& y = output;
auto dw = at::zeros(weight_buf.sizes(), weight_buf.options());
miopenRNNAlgo_t algo = miopenRNNdefault;
fn.rnn.set_algo(algo);
RNNDescriptors descs(fn, handle, x, y, hx, cx);
FilterDescriptor w_desc;
w_desc.set(weight_buf, 3);
auto x_descs_arr = descs.get_x_descs();
auto y_descs_arr = descs.get_y_descs();
MIOPEN_CHECK(miopenRNNBackwardWeights(
handle,
descs.rnn_desc.desc(),
fn.tensors.seq_length,
x_descs_arr.data(), x.data_ptr(),
descs.hx_desc.desc(), hx.data_ptr(),
y_descs_arr.data(), y.data_ptr(),
w_desc.desc(), dw.data_ptr(),
fn_workspace.data_ptr(), fn_workspace.size(0),
fn_reserve.data_ptr(), fn_reserve.size(0)
));
std::vector<Tensor> grad_params_arr;
size_t grad_params_stride0;
std::tie(grad_params_arr, grad_params_stride0) = get_parameters(handle, fn.rnn, descs.rnn_desc, descs.x_descs[0], w_desc, dw);
if (grad_params_stride0 == static_cast<size_t>(weight_stride0)) {
_viewParams(MatrixRef<Tensor>{grad_params_arr, grad_params_stride0},
MatrixRef<Tensor>{weight_arr, static_cast<size_t>(weight_stride0)});
return grad_params_arr;
} else {
std::vector<Tensor> grad_weight_arr;
grad_weight_arr.reserve( weight.numel() );
for (const auto& w : weight_arr) {
grad_weight_arr.emplace_back(at::empty(w.sizes(), w.options()));
}
_copyParams(MatrixRef<Tensor>{grad_params_arr, grad_params_stride0},
MatrixRef<Tensor>{grad_weight_arr, static_cast<size_t>(weight_stride0)});
return grad_weight_arr;
}
}
std::tuple<Tensor, Tensor, Tensor, std::vector<Tensor>> miopen_rnn_backward(
const Tensor& input, TensorList weight, int64_t weight_stride0, const Tensor& weight_buf, const Tensor& hx, const c10::optional<Tensor>& cx_opt,
const Tensor& output, const c10::optional<Tensor>& grad_output_r_opt, const c10::optional<Tensor>& grad_hy_r_opt, const c10::optional<Tensor>& grad_cy_r_opt, int64_t mode, int64_t hidden_size, int64_t num_layers, bool batch_first,
double dropout, bool train, bool bidirectional, IntArrayRef batch_sizes, const c10::optional<Tensor>& dropout_state_opt,
const Tensor& reserve, std::array<bool, 4> output_mask
) {
// See [Note: hacky wrapper removal for optional tensor]
c10::MaybeOwned<Tensor> cx_maybe_owned = at::borrow_from_optional_tensor(cx_opt);
const Tensor& cx = *cx_maybe_owned;
const Tensor& grad_output_r = c10::value_or_else(grad_output_r_opt, [] {return Tensor();});
const Tensor& grad_hy_r = c10::value_or_else(grad_hy_r_opt, [] {return Tensor();});
const Tensor& grad_cy_r = c10::value_or_else(grad_cy_r_opt, [] {return Tensor();});
const Tensor& dropout_state = c10::value_or_else(dropout_state_opt, [] {return Tensor();});
if (!grad_output_r.defined() && !grad_hy_r.defined() && !grad_cy_r.defined()) {
return std::tuple<Tensor, Tensor, Tensor, std::vector<Tensor>>(Tensor(), Tensor(), Tensor(), std::vector<Tensor>(weight.size()));
}
auto grad_output = grad_output_r.defined() ? grad_output_r : at::zeros_like(output, LEGACY_CONTIGUOUS_MEMORY_FORMAT);
auto grad_hy = grad_hy_r.defined() ? grad_hy_r : at::zeros_like(hx, LEGACY_CONTIGUOUS_MEMORY_FORMAT);
auto grad_cy = cx.defined() ? (grad_cy_r.defined() ? grad_cy_r : at::zeros_like(cx, LEGACY_CONTIGUOUS_MEMORY_FORMAT)) : grad_cy_r;
Tensor dx, dhx, dcx, ws;
std::tie(dx, dhx, dcx, ws) = at::native::miopen_rnn_backward_input(input, weight_buf, hx, cx, output, grad_output, grad_hy, grad_cy, mode, hidden_size, num_layers, batch_first, dropout, train, bidirectional, batch_sizes, dropout_state, reserve, {output_mask[0], output_mask[1], output_mask[2]});
std::vector<Tensor> dw;
if (output_mask[3]) {
dw = at::native::miopen_rnn_backward_weight(input, weight, weight_stride0, weight_buf, hx, cx, output, mode, hidden_size, num_layers, batch_first, dropout, train, bidirectional, batch_sizes, dropout_state, reserve, ws);
if (mode > 1) {
for (const auto i : c10::irange(dw.size())) {
dw[i] = permute_wei_for_miopen(dw[i], mode);
}
}
}
return std::tuple<Tensor, Tensor, Tensor, std::vector<Tensor>>{dx, dhx, dcx, dw};
}
namespace {
std::tuple<Tensor, Tensor> unpack_hidden(const Tensor& hidden) {
return std::make_tuple(hidden, at::Tensor{});
}
std::tuple<Tensor, Tensor> unpack_hidden(const std::tuple<Tensor, Tensor>& hidden) {
return hidden;
}
template<typename hidden_type>
hidden_type pack_hidden(const Tensor& hx, const Tensor& cx) {
static_assert(std::is_same<hidden_type, void>::value, "pack_hidden not implemented for this type");
AT_ERROR("NOT IMPLEMENTED");
}
template<>
Tensor pack_hidden<Tensor>(const Tensor& hx, const Tensor& cx) {
AT_ASSERT(cx.numel() == 0);
return hx;
}
template<>
std::tuple<Tensor, Tensor> pack_hidden<std::tuple<Tensor, Tensor>>(const Tensor& hx, const Tensor& cx) {
return std::make_tuple(hx, cx);
}
template<typename hidden_type>
std::pair<Tensor, hidden_type> _miopen_impl(
const Tensor& input, const Tensor& _batch_sizes, const hidden_type& hidden,
TensorList params, bool has_biases, miopenRNNMode_t mode,
int64_t num_layers, double dropout_p, bool train, bool bidirectional) {
Tensor hx, cx;
std::tie(hx, cx) = unpack_hidden(hidden);
int64_t hidden_size = hx.size(2);
TORCH_CHECK(_batch_sizes.dim() == 1, "batch_sizes tensor should be 1D");
IntArrayRef batch_sizes { _batch_sizes.data_ptr<int64_t>(), static_cast<size_t>(_batch_sizes.size(0)) };
Tensor dropout_state = at::empty({0}, input.options());
auto miopen_output = at::miopen_rnn(
input, params, has_biases ? 4 : 2,
hx, cx, static_cast<int>(mode), hidden_size, num_layers, /*batch_first=*/false,
dropout_p, train, bidirectional, batch_sizes, dropout_state);
return {std::get<0>(miopen_output),
pack_hidden<hidden_type>(std::get<1>(miopen_output), std::get<2>(miopen_output))};
}
template<typename hidden_type>
std::pair<Tensor, hidden_type> _miopen_impl(
const Tensor& input, const hidden_type& hidden,
TensorList params, bool has_biases, miopenRNNMode_t mode,
int64_t num_layers, double dropout_p, bool train, bool bidirectional, bool batch_first) {
Tensor hx, cx;
std::tie(hx, cx) = unpack_hidden(hidden);
int64_t hidden_size = hx.size(2);
Tensor dropout_state = at::empty({0}, input.options());
auto miopen_output = at::miopen_rnn(
input, params, has_biases ? 4 : 2,
hx, cx, static_cast<int>(mode), hidden_size, num_layers, batch_first, dropout_p,
train, bidirectional, /*batch_sizes=*/{}, dropout_state);
return {std::get<0>(miopen_output),
pack_hidden<hidden_type>(std::get<1>(miopen_output), std::get<2>(miopen_output))};
}
#define ONE_HIDDEN_RNN(NAME, MODE) \
void NAME##_miopen(Tensor& output, Tensor& hy, \
const Tensor& input, const Tensor& hx, \
TensorList params, bool has_biases, \
int64_t num_layers, double dropout_p, bool train, bool bidirectional, bool batch_first) { \
std::tie(output, hy) = _miopen_impl(input, hx, params, has_biases, \
MODE, num_layers, dropout_p, train, bidirectional, batch_first); \
} \
\
void NAME##_packed_miopen(Tensor& output, Tensor& hy, \
const Tensor& data, const Tensor& batch_sizes, const Tensor& hx, \
TensorList params, bool has_biases, \
int64_t num_layers, double dropout_p, bool train, bool bidirectional) { \
std::tie(output, hy) = _miopen_impl(data, batch_sizes, hx, params, \
has_biases, MODE, num_layers, dropout_p, train, bidirectional); \
} \
\
REGISTER_CUDA_DISPATCH(NAME##_miopen_stub, &NAME##_miopen); \
REGISTER_CUDA_DISPATCH(NAME##_packed_miopen_stub, &NAME##_packed_miopen);
ONE_HIDDEN_RNN(gru, miopenGRU)
ONE_HIDDEN_RNN(rnn_tanh, miopenRNNTANH)
ONE_HIDDEN_RNN(rnn_relu, miopenRNNRELU)
void lstm_miopen(Tensor& output, Tensor& hy, Tensor& cy,
const Tensor& input, TensorList hx,
TensorList params, bool has_biases,
int64_t num_layers, double dropout_p, bool train, bool bidirectional, bool batch_first) {
auto result = _miopen_impl(input, std::make_tuple(hx[0], hx[1]), params, has_biases,
miopenLSTM, num_layers, dropout_p, train, bidirectional, batch_first);
output = result.first;
hy = std::get<0>(result.second);
cy = std::get<1>(result.second);
}
void lstm_packed_miopen(Tensor& output, Tensor& hy, Tensor& cy,
const Tensor& data, const Tensor& batch_sizes, TensorList hx,
TensorList params, bool has_biases,
int64_t num_layers, double dropout_p, bool train, bool bidirectional) {
auto result = _miopen_impl(data, batch_sizes, std::make_tuple(hx[0], hx[1]),
params, has_biases, miopenLSTM, num_layers, dropout_p, train, bidirectional);
output = result.first;
hy = std::get<0>(result.second);
cy = std::get<1>(result.second);
}
REGISTER_CUDA_DISPATCH(lstm_miopen_stub, &lstm_miopen);
REGISTER_CUDA_DISPATCH(lstm_packed_miopen_stub, &lstm_packed_miopen);
} // anonymous namepsace
}} //namespace native.
#endif