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LossNLL2d.cpp
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LossNLL2d.cpp
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#include <ATen/ATen.h>
#include <ATen/AccumulateType.h>
#include <ATen/Dispatch.h>
#include <ATen/Parallel.h>
#include <ATen/TensorUtils.h>
namespace at {
namespace native {
namespace {
// Returns a contiguous tensor if the source tensor
// is defined. Otherwise returns the undefined
// source tensor unmodified.
inline Tensor optional_contiguous(const Tensor& source) {
return source.defined() ? source.contiguous() : source;
}
// Returns the address of the first element of a tensor
// or nullptr if the tensor is undefined.
template <typename scalar_t>
inline scalar_t* optional_data(const Tensor& source) {
return source.defined() ? source.data_ptr<scalar_t>() : nullptr;
}
inline void check_inputs_nll_loss2d(
const Tensor& input,
const Tensor& target,
const Tensor& weight) {
TORCH_CHECK(
target.dim() == 3,
"only batches of spatial targets supported (3D tensors)"
" but got targets of dimension: ",
target.dim());
TORCH_CHECK(
input.dim() == 4,
"only batches of spatial inputs supported (4D tensors), "
"but got input of dimension: ",
input.dim());
TORCH_CHECK(
!weight.defined() || weight.numel() == input.size(1),
"weight tensor should be defined either for all or no classes");
const int64_t input0 = input.size(0);
const int64_t input2 = input.size(2);
const int64_t input3 = input.size(3);
const int64_t target0 = target.size(0);
const int64_t target1 = target.size(1);
const int64_t target2 = target.size(2);
TORCH_CHECK(
input0 == target0 && input2 == target1 && input3 == target2,
"size mismatch (got input: ",
input.sizes(),
" , target: ",
target.sizes());
}
inline void check_gradout_shape_nll_loss2d(
const Tensor& grad_output,
const Tensor& target) {
TORCH_CHECK(
grad_output.dim() == 3,
"grad_output must have same dimension as target (3) but got dimension: ",
grad_output.sizes());
const int64_t grad_output0 = grad_output.size(0);
const int64_t grad_output1 = grad_output.size(1);
const int64_t grad_output2 = grad_output.size(2);
const int64_t target0 = target.size(0);
const int64_t target1 = target.size(1);
const int64_t target2 = target.size(2);
TORCH_CHECK(
grad_output0 == target0 && grad_output1 == target1 &&
grad_output2 == target2,
"size mismatch (got grad_output: ",
grad_output.sizes(),
" target: ",
target.sizes());
}
template <typename scalar_t>
static void nll_loss2d_forward_out_frame(
Tensor& output,
Tensor& total_weight,
const Tensor& input,
const Tensor& target,
const Tensor& weight,
int64_t reduction,
int64_t ignore_index) {
const int64_t n_classes = input.size(1);
scalar_t* total_weight_data = total_weight.data_ptr<scalar_t>();
*total_weight_data = 0;
auto weight_contiguous = optional_contiguous(weight);
const scalar_t* weight_data = optional_data<scalar_t>(weight_contiguous);
if (reduction == Reduction::None) {
const int64_t batch_size = input.size(0);
const int64_t H = input.size(2);
const int64_t W = input.size(3);
output.resize_({batch_size, H, W});
auto input_acc = input.accessor<scalar_t, 4>();
auto output_acc = output.accessor<scalar_t, 3>();
auto target_acc = target.accessor<int64_t, 3>();
at::parallel_for(0, batch_size, 0, [&](int64_t start, int64_t end) {
for (int64_t b = start; b < end; b++) {
for (int64_t h = 0; h < H; h++) {
for (int64_t w = 0; w < W; w++) {
const int64_t cur_target = (int64_t)target_acc[b][h][w];
if (cur_target == ignore_index) {
output_acc[b][h][w] = static_cast<scalar_t>(0);
continue;
}
TORCH_CHECK_INDEX(
cur_target >= 0 && cur_target < n_classes,
"Target ",
cur_target,
" is out of bounds.");
// load optional weight value
const scalar_t cur_weight = weight_data != nullptr
? weight_data[cur_target]
: static_cast<scalar_t>(1);
output_acc[b][h][w] = -input_acc[b][cur_target][h][w] * cur_weight;
}
}
}
});
return;
}
// produce scalar outputs for the reduction case
output.resize_({});
auto input_contiguous = input.contiguous();
auto target_contiguous = target.contiguous();
const scalar_t* input_data = input_contiguous.data_ptr<scalar_t>();
const int64_t* target_data = target_contiguous.data_ptr<int64_t>();
const int64_t batch_size = input.size(0);
const int64_t map_size = input.size(2) * input.size(3);
const int64_t sample_size = map_size * n_classes;
scalar_t total_weight_val = 0;
scalar_t output_val = 0;
for (int64_t b = 0; b < batch_size; b++) {
for (int64_t elem = 0; elem < map_size; elem++) {
const int64_t cur_target = target_data[b * map_size + elem];
if (cur_target == ignore_index) {
continue;
}
TORCH_CHECK_INDEX(
cur_target >= 0 && cur_target < n_classes,
"Target ",
cur_target,
" is out of bounds.");
const scalar_t weight_val =
weight_data ? weight_data[cur_target] : static_cast<scalar_t>(1);
total_weight_val += weight_val;
output_val -= input_data[b * sample_size + cur_target * map_size + elem] *
weight_val;
}
}
if (reduction == Reduction::Mean &&
(total_weight_val != 0 || input.numel() == 0)) {
// allow NaN result for total_weight_val == 0 case, see #15870
output_val /= total_weight_val;
}
*total_weight_data = total_weight_val;
*output.data_ptr<scalar_t>() = output_val;
}
void nll_loss2d_forward_out_cpu_template(
Tensor& output,
Tensor& total_weight,
const Tensor& input,
const Tensor& target,
const Tensor& weight,
int64_t reduction,
int64_t ignore_index) {
check_inputs_nll_loss2d(input, target, weight);
total_weight.resize_({});
AT_DISPATCH_FLOATING_TYPES_AND(
ScalarType::BFloat16,
input.scalar_type(),
"nll_loss2d_forward_out_frame",
[&] {
nll_loss2d_forward_out_frame<scalar_t>(
output,
total_weight,
input,
target,
weight,
reduction,
ignore_index);
});
}
template <typename scalar_t>
static void nll_loss2d_backward_out_frame(
Tensor& grad_input,
const Tensor& grad_output,
const Tensor& input,
const Tensor& target,
const Tensor& weight,
int64_t reduction,
int64_t ignore_index,
const Tensor& total_weight) {
auto weight_contiguous = optional_contiguous(weight);
const scalar_t* weight_data = optional_data<scalar_t>(weight_contiguous);
if (reduction == at::Reduction::None) {
check_gradout_shape_nll_loss2d(grad_output, target);
const int64_t batch_size = input.size(0);
const int64_t H = input.size(2);
const int64_t W = input.size(3);
auto grad_input_acc = grad_input.accessor<scalar_t, 4>();
auto grad_output_acc = grad_output.accessor<scalar_t, 3>();
auto target_acc = target.accessor<int64_t, 3>();
at::parallel_for(0, batch_size, 0, [&](int64_t start, int64_t end) {
for (int64_t b = start; b < end; b++) {
for (int64_t h = 0; h < H; h++) {
for (int64_t w = 0; w < W; w++) {
const int64_t cur_target = target_acc[b][h][w];
if (cur_target == ignore_index) {
continue;
}
const scalar_t value =
-(weight_data ? weight_data[cur_target]
: static_cast<scalar_t>(1));
const scalar_t grad_output_value = grad_output_acc[b][h][w];
grad_input_acc[b][cur_target][h][w] = value * grad_output_value;
}
}
}
});
return;
}
const scalar_t total_weight_value = *total_weight.data_ptr<scalar_t>();
if (total_weight_value <= 0) {
return;
}
TORCH_CHECK(
grad_output.dim() <= 1 && grad_output.numel() == 1,
"Expected a single element grad_output tensor, but got: ",
grad_output.sizes());
const scalar_t grad_output_value = *grad_output.data_ptr<scalar_t>();
const auto target_contiguous = target.contiguous();
const int64_t* target_data = target_contiguous.data_ptr<int64_t>();
scalar_t* grad_input_data = grad_input.data_ptr<scalar_t>();
const int64_t batch_size = input.size(0);
const int64_t n_classes = input.size(1);
const int64_t map_size = input.size(2) * input.size(3);
const int64_t sample_size = map_size * n_classes;
scalar_t normalize = (reduction == at::Reduction::Mean)
? total_weight_value
: static_cast<scalar_t>(1);
at::parallel_for(0, batch_size, 0, [&](int64_t start, int64_t end) {
for (int64_t b = start; b < end; b++) {
for (int64_t elem = 0; elem < map_size; elem++) {
const int64_t cur_target = target_data[b * map_size + elem];
if (cur_target == ignore_index) {
continue;
}
TORCH_CHECK_INDEX(
cur_target >= 0 && cur_target < n_classes,
"Target ",
cur_target,
" is out of bounds.");
const int64_t index = b * sample_size + cur_target * map_size + elem;
const scalar_t w = weight_data != nullptr ? weight_data[cur_target]
: static_cast<scalar_t>(1);
grad_input_data[index] = -w / normalize * grad_output_value;
}
}
});
}
void nll_loss2d_backward_out_cpu_template(
Tensor& grad_input,
const Tensor& grad_output,
const Tensor& input,
const Tensor& target,
const Tensor& weight,
int64_t reduction,
int64_t ignore_index,
const Tensor& total_weight) {
check_inputs_nll_loss2d(input, target, weight);
grad_input.resize_as_(input);
grad_input.zero_();
TORCH_CHECK(grad_input.is_contiguous(), "grad_input must be contiguous");
TORCH_CHECK(
total_weight.numel() == 1,
"expected total_weight to be a single element tensor, got: ",
total_weight.sizes(),
" (",
total_weight.numel(),
" elements)");
AT_DISPATCH_FLOATING_TYPES_AND(
ScalarType::BFloat16,
input.scalar_type(),
"nll_loss2d_backward_out_frame",
[&] {
nll_loss2d_backward_out_frame<scalar_t>(
grad_input,
grad_output,
input,
target,
weight,
reduction,
ignore_index,
total_weight);
});
}
} // namespace
std::tuple<Tensor&, Tensor&> nll_loss2d_forward_out_cpu(
Tensor& output,
Tensor& total_weight,
const Tensor& self,
const Tensor& target,
const Tensor& weight,
int64_t reduction,
int64_t ignore_index) {
nll_loss2d_forward_out_cpu_template(
output, total_weight, self, target, weight, reduction, ignore_index);
return std::tuple<Tensor&, Tensor&>(output, total_weight);
}
std::tuple<Tensor, Tensor> nll_loss2d_forward_cpu(
const Tensor& self,
const Tensor& target,
const Tensor& weight,
int64_t reduction,
int64_t ignore_index) {
auto output = at::empty({0}, self.options());
auto total_weight = at::empty({0}, self.options());
nll_loss2d_forward_out_cpu(
output, total_weight, self, target, weight, reduction, ignore_index);
return std::make_tuple(output, total_weight);
}
Tensor& nll_loss2d_backward_out_cpu(
Tensor& grad_input,
const Tensor& grad_output,
const Tensor& self,
const Tensor& target,
const Tensor& weight,
int64_t reduction,
int64_t ignore_index,
const Tensor& total_weight) {
nll_loss2d_backward_out_cpu_template(
grad_input,
grad_output,
self,
target,
weight,
reduction,
ignore_index,
total_weight);
return grad_input;
}
Tensor nll_loss2d_backward_cpu(
const Tensor& grad_output,
const Tensor& self,
const Tensor& target,
const Tensor& weight,
int64_t reduction,
int64_t ignore_index,
const Tensor& total_weight) {
auto grad_input = at::zeros_like(self);
nll_loss2d_backward_out_cpu(
grad_input,
grad_output,
self,
target,
weight,
reduction,
ignore_index,
total_weight);
return grad_input;
}
Tensor & nll_loss2d_out(Tensor & output, const Tensor & self, const Tensor & target, const Tensor & weight, int64_t reduction, int64_t ignore_index) {
Tensor total_weight = at::empty({0}, self.options());
return std::get<0>(at::nll_loss2d_forward_out(output, total_weight, self, target, weight, reduction, ignore_index));
}
Tensor nll_loss2d(const Tensor & self, const Tensor & target, const Tensor & weight, int64_t reduction, int64_t ignore_index) {
return std::get<0>(at::nll_loss2d_forward(self, target, weight, reduction, ignore_index));
}
} // namespace native
} // namespace at