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Loss.cpp
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Loss.cpp
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// define constants like M_PI and C keywords for MSVC
#ifdef _MSC_VER
#ifndef _USE_MATH_DEFINES
#define _USE_MATH_DEFINES
#endif
#include <math.h>
#endif
#include <ATen/ATen.h>
#include <ATen/NativeFunctions.h>
#include <ATen/Dispatch.h>
#include <ATen/CPUApplyUtils.h>
#include <ATen/native/BinaryOps.h>
#include <ATen/native/PointwiseOps.h>
#include <ATen/native/TensorIterator.h>
#include <ATen/native/cpu/Loops.h>
constexpr float EPSILON = 1e-12;
namespace {
static inline at::Tensor apply_loss_reduction(const at::Tensor& unreduced, int64_t reduction) {
if (reduction == at::Reduction::Mean) {
return unreduced.mean();
} else if (reduction == at::Reduction::Sum) {
return unreduced.sum();
}
return unreduced;
}
}
namespace at { namespace native {
DEFINE_DISPATCH(smooth_l1_stub);
DEFINE_DISPATCH(smooth_l1_backward_stub);
DEFINE_DISPATCH(mse_stub);
DEFINE_DISPATCH(mse_backward_stub);
Tensor cosine_embedding_loss(const Tensor& input1, const Tensor& input2, const Tensor& target, double margin, int64_t reduction) {
auto prod_sum = (input1 * input2).sum(1);
auto mag_square1 = (input1 * input1).sum(1) + EPSILON;
auto mag_square2 = (input2 * input2).sum(1) + EPSILON;
auto denom = (mag_square1 * mag_square2).sqrt_();
auto cos = prod_sum / denom;
auto zeros = at::zeros_like(cos, LEGACY_CONTIGUOUS_MEMORY_FORMAT);
auto pos = 1 - cos;
auto neg = (cos - margin).clamp_min_(0);
auto output_pos = at::where(target == 1, pos, zeros);
auto output_neg = at::where(target == -1, neg, zeros);
auto output = output_pos + output_neg;
return apply_loss_reduction(output, reduction);
}
Tensor hinge_embedding_loss(const Tensor& self, const Tensor& target, double margin, int64_t reduction) {
auto zeros = at::zeros_like(self, LEGACY_CONTIGUOUS_MEMORY_FORMAT);
auto margin_clamp = (margin - self).clamp_min_(0);
auto output_margin = at::where(target != 1, margin_clamp, zeros);
auto output_self = at::where(target != -1, self, zeros);
auto output = output_margin + output_self;
return apply_loss_reduction(output, reduction);
}
Tensor triplet_margin_loss(const Tensor& anchor, const Tensor& positive, const Tensor& negative, double margin,
double p, double eps, bool swap, int64_t reduction) {
auto dist_pos = at::pairwise_distance(anchor, positive, p, eps);
auto dist_neg = at::pairwise_distance(anchor, negative, p, eps);
if (swap) {
auto dist_swap = at::pairwise_distance(positive, negative, p, eps);
dist_neg = at::min(dist_neg, dist_swap);
}
auto output = at::clamp_min(margin + dist_pos - dist_neg, 0);
return apply_loss_reduction(output, reduction);
}
Tensor margin_ranking_loss(const Tensor& input1, const Tensor& input2, const Tensor& target, double margin, int64_t reduction) {
auto output = (-target * (input1 - input2) + margin).clamp_min_(0);
return apply_loss_reduction(output, reduction);
}
Tensor _kl_div_log_target(const Tensor& input, const Tensor& target, int64_t reduction) {
auto output = at::exp(target) * (target - input);
return apply_loss_reduction(output, reduction);
}
Tensor _kl_div_non_log_target(const Tensor& input, const Tensor& target, int64_t reduction) {
auto output_pos = target * (at::log(target) - input);
auto zeros = at::zeros_like(output_pos, LEGACY_CONTIGUOUS_MEMORY_FORMAT);
auto output = at::where(target > 0, output_pos, zeros);
return apply_loss_reduction(output, reduction);
}
Tensor kl_div(const Tensor& input, const Tensor& target, int64_t reduction, bool log_target) {
return log_target ? _kl_div_log_target(input, target, reduction)
: _kl_div_non_log_target(input, target, reduction);
}
Tensor kl_div_backward_cpu(const Tensor& grad, const Tensor& input, const Tensor& target, int64_t reduction, bool log_target) {
auto grad_input = at::zeros_like(input, LEGACY_CONTIGUOUS_MEMORY_FORMAT);
auto grad_expand = grad.expand_as(input);
if (!log_target) {
auto iter = TensorIteratorConfig()
.add_output(grad_input)
.add_input(target)
.add_input(grad_expand)
.build();
AT_DISPATCH_FLOATING_TYPES(input.scalar_type(), "kl_div_backward_cpu", [&]() {
cpu_serial_kernel(iter, [](scalar_t target_val, scalar_t grad_val) -> scalar_t{
return target_val > 0 ? -target_val * grad_val : 0;
});
});
}
else {
grad_input = -at::exp(target) * grad_expand;
}
if (reduction == at::Reduction::Mean) {
return grad_input / input.numel();
}
return grad_input;
}
Tensor binary_cross_entropy_cpu(const Tensor& input, const Tensor& target, const Tensor& weight, int64_t reduction) {
Tensor loss = at::empty_like(input);
return at::native::binary_cross_entropy_out_cpu(loss, input, target, weight, reduction);
}
Tensor& binary_cross_entropy_out_cpu(Tensor& loss, const Tensor& input, const Tensor& target, const Tensor& weight, int64_t reduction) {
Tensor loss_squeezed = at::squeeze(loss);
auto iter = TensorIteratorConfig()
.add_output(loss_squeezed)
.add_input(at::squeeze(input))
.add_input(at::squeeze(target))
.build();
AT_DISPATCH_FLOATING_TYPES(loss.scalar_type(), "binary_cross_entropy", [&] {
at::native::cpu_kernel(
iter,
[] (scalar_t input_val, scalar_t target_val) {
TORCH_CHECK(
(input_val >= 0) && (input_val <= 1),
"all elements of input should be between 0 and 1"
);
// Binary cross entropy tensor is defined by the equation:
// L = -w (y ln(x) + (1-y) ln(1-x))
return (target_val - scalar_t(1))
* std::max(scalar_t(std::log(scalar_t(1) - input_val)), scalar_t(-100))
- target_val * std::max(scalar_t(std::log(input_val)), scalar_t(-100));
}
);
});
if (weight.defined()) {
loss.mul_(weight);
}
if (reduction != at::Reduction::None) {
Tensor loss_reduced = apply_loss_reduction(loss, reduction);
loss.resize_as_(loss_reduced).copy_(loss_reduced);
}
return loss;
}
Tensor binary_cross_entropy_backward_cpu(const Tensor& grad, const Tensor& input, const Tensor& target, const Tensor& weight, int64_t reduction) {
Tensor grad_input = at::empty_like(input);
return at::native::binary_cross_entropy_backward_out_cpu(grad_input, grad, input, target, weight, reduction);
}
Tensor& binary_cross_entropy_backward_out_cpu(Tensor& grad_input, const Tensor& grad, const Tensor& input, const Tensor& target, const Tensor& weight, int64_t reduction) {
Tensor grad_input_squeezed = at::squeeze(grad_input);
auto iter = TensorIteratorConfig()
.add_output(grad_input_squeezed)
.add_input(at::squeeze(grad))
.add_input(at::squeeze(input))
.add_input(at::squeeze(target))
.build();
AT_DISPATCH_FLOATING_TYPES(grad_input.scalar_type(), "binary_cross_entropy_backward", [&] {
at::native::cpu_kernel(
iter,
[] (scalar_t grad_val, scalar_t input_val, scalar_t target_val) {
// The gradient is the partial derivative of BCELoss
// with respect to x
// d(L)/d(x) = -w (y - x) / (x - x^2)
return grad_val * (input_val - target_val)
/ (scalar_t(std::max(
(scalar_t(1) - input_val) * input_val,
scalar_t(EPSILON)
)));
}
);
});
if (weight.defined()) {
grad_input.mul_(weight);
}
if (reduction == at::Reduction::Mean) {
grad_input.div_(input.numel());
}
return grad_input;
}
Tensor binary_cross_entropy_with_logits(const Tensor& input, const Tensor& target, const Tensor& weight, const Tensor& pos_weight, int64_t reduction) {
Tensor loss;
auto max_val = (-input).clamp_min_(0);
if (pos_weight.defined()) {
// pos_weight need to be broadcasted, thus mul(target) is not inplace.
auto log_weight = (pos_weight - 1).mul(target).add_(1);
loss = (1 - target).mul_(input).add_(log_weight.mul_(((-max_val).exp_().add_((-input - max_val).exp_())).log_().add_(max_val)));
} else {
loss = (1 - target).mul_(input).add_(max_val).add_((-max_val).exp_().add_((-input -max_val).exp_()).log_());
}
if (weight.defined()) {
loss.mul_(weight);
}
return apply_loss_reduction(loss, reduction);
}
Tensor binary_cross_entropy_with_logits_backward(const Tensor& grad, const Tensor& input, const Tensor& target, const Tensor& weight, const Tensor& pos_weight, int64_t reduction) {
Tensor grad_input;
if (pos_weight.defined()) {
// pos_weight need to be broadcasted, thus mul(target) is not inplace.
auto t = pos_weight.mul(target);
grad_input = t.add(1).sub_(target).mul_(input.sigmoid()).sub_(t).mul_(grad);
} else {
grad_input = (input.sigmoid() - target).mul_(grad);
}
if (weight.defined()) {
grad_input.mul_(weight);
}
if (reduction == at::Reduction::Mean) {
return grad_input / input.numel();
}
return grad_input;
}
Tensor poisson_nll_loss(const Tensor& input, const Tensor& target, const bool log_input, const bool full, const double eps, const int64_t reduction)
{
Tensor loss;
if (log_input) {
loss = at::exp(input) - target * input;
} else {
loss = input - target * at::log(input + eps);
}
if (full) {
auto stirling_term = target * at::log(target) - target + 0.5 * at::log(2 * M_PI * target);
loss += stirling_term.masked_fill(target <= 1, 0);
}
return apply_loss_reduction(loss, reduction);
}
Tensor& soft_margin_loss_backward_out(Tensor& grad_input, const Tensor& grad_output, const Tensor& input, const Tensor& target, int64_t reduction) {
auto norm = reduction == Reduction::Mean ? 1. / input.numel() : 1.;
auto z = at::exp(-target * input);
// inplace version of: grad_input = -norm * target * z / (1. + z) * grad_output;
at::mul_out(grad_input, target, z).mul_(-norm);
z.add_(1);
grad_input.div_(z).mul_(grad_output);
return grad_input;
}
Tensor soft_margin_loss_backward(const Tensor& grad_output, const Tensor& input, const Tensor& target, int64_t reduction) {
auto grad_input = at::empty({0}, input.options());
at::soft_margin_loss_backward_out(grad_input, grad_output, input, target, reduction);
return grad_input;
}
Tensor& soft_margin_loss_out(
Tensor& output,
const Tensor& input,
const Tensor& target,
int64_t reduction) {
// compute inplace variant of: output = at::log(1. + at::exp(-input * target));
at::neg_out(output, input).mul_(target).exp_().add_(1.).log_();
if (reduction != Reduction::None) {
auto tmp = apply_loss_reduction(output, reduction);
output.resize_({});
output.copy_(tmp);
}
return output;
}
Tensor soft_margin_loss(
const Tensor& input,
const Tensor& target,
int64_t reduction) {
auto output = at::empty({0}, input.options());
at::soft_margin_loss_out(output, input, target, reduction);
return output;
}
Tensor smooth_l1_loss(const Tensor& input, const Tensor& target, const int64_t reduction, double beta) {
TORCH_CHECK(beta >= 0, "smooth_l1_loss does not support negative values for beta.")
if (beta == 0) {
return at::native::l1_loss(input, target, reduction);
}
Tensor loss;
auto iter = TensorIterator::binary_op(loss, input, target);
smooth_l1_stub(iter.device_type(), iter, beta);
return apply_loss_reduction(iter.output(), reduction);
}
Tensor& smooth_l1_loss_out(Tensor& result, const Tensor& input, const Tensor& target, int64_t reduction, double beta) {
TORCH_CHECK(beta >= 0, "smooth_l1_loss does not support negative values for beta.")
if (beta == 0) {
return at::native::l1_loss_out(result, input, target, reduction);
}
if (reduction != Reduction::None) {
Tensor loss;
auto iter = TensorIterator::binary_op(loss, input, target);
smooth_l1_stub(iter.device_type(), iter, beta);
if (reduction == Reduction::Mean) {
at::mean_out(result, iter.output(), 0);
} else {
at::sum_out(result, iter.output(), 0);
}
} else {
auto iter = TensorIterator::binary_op(result, input, target);
smooth_l1_stub(iter.device_type(), iter, beta);
}
return result;
}
Tensor& smooth_l1_loss_backward_out(Tensor& grad_input, const Tensor& grad_output, const Tensor& input, const Tensor& target, int64_t reduction, double beta) {
if (beta <= 0)
return at::native::l1_loss_backward_out(grad_input, grad_output, input, target, reduction);
auto norm = reduction == Reduction::Mean ? 1. / input.numel() : 1.;
auto iter = at::TensorIteratorConfig()
.add_output(grad_input)
.add_input(input)
.add_input(target)
.add_input(grad_output)
.build();
smooth_l1_backward_stub(iter.device_type(), iter, norm, beta);
return grad_input;
}
Tensor smooth_l1_loss_backward(const Tensor& grad_output, const Tensor& input, const Tensor& target, int64_t reduction, double beta) {
if (beta <= 0)
return at::native::l1_loss_backward(grad_output, input, target, reduction);
auto grad_input = at::zeros_like(input, LEGACY_CONTIGUOUS_MEMORY_FORMAT);
return at::smooth_l1_loss_backward_out(grad_input, grad_output, input, target, reduction, beta);
}
Tensor mse_loss(const Tensor& input, const Tensor& target, int64_t reduction) {
Tensor loss;
auto iter = TensorIterator::binary_op(loss, input, target);
mse_stub(iter.device_type(), iter);
return apply_loss_reduction(iter.output(), reduction);
}
Tensor& mse_loss_out(Tensor&result, const Tensor& input, const Tensor& target, int64_t reduction) {
if (reduction != Reduction::None) {
Tensor loss;
auto iter = TensorIterator::binary_op(loss, input, target);
mse_stub(iter.device_type(), iter);
if (reduction == Reduction::Mean) {
at::mean_out(result, iter.output(), 0);
} else {
at::sum_out(result, iter.output(), 0);
}
} else {
auto iter = TensorIterator::binary_op(result, input, target);
mse_stub(iter.device_type(), iter);;
}
return result;
}
Tensor mse_loss_backward(const Tensor& grad_output, const Tensor& input, const Tensor& target, int64_t reduction) {
Tensor grad_input = at::zeros_like(input, LEGACY_CONTIGUOUS_MEMORY_FORMAT);
return at::mse_loss_backward_out(grad_input, grad_output, input, target, reduction);
}
Tensor& mse_loss_backward_out(Tensor& grad_input, const Tensor& grad_output,
const Tensor& input, const Tensor& target, int64_t reduction) {
auto norm = reduction == Reduction::Mean ? 2. / input.numel() : 2.;
auto iter = at::TensorIteratorConfig()
.add_output(grad_input)
.add_input(input)
.add_input(target)
.add_input(grad_output)
.build();
mse_backward_stub(iter.device_type(), iter, norm);
return grad_input;
}
Tensor l1_loss(const Tensor& input, const Tensor& target, int64_t reduction) {
auto loss = input.sub(target).abs_();
return apply_loss_reduction(loss, reduction);
}
Tensor& l1_loss_out(Tensor&result, const Tensor& input, const Tensor& target, int64_t reduction) {
if (reduction != Reduction::None) {
auto loss = input.sub(target).abs_();
if (reduction == Reduction::Mean) {
at::mean_out(result, loss, 0);
} else {
at::sum_out(result, loss, 0);
}
} else {
at::sub_out(result, input, target).abs_();
}
return result;
}
Tensor l1_loss_backward(const Tensor& grad_output, const Tensor& input, const Tensor& target, int64_t reduction) {
Tensor grad_input = at::zeros_like(input, LEGACY_CONTIGUOUS_MEMORY_FORMAT);
return at::l1_loss_backward_out(grad_input, grad_output, input, target, reduction);
}
Tensor& l1_loss_backward_out(Tensor& grad_input, const Tensor& grad_output,
const Tensor& input, const Tensor& target, int64_t reduction) {
auto norm = reduction == Reduction::Mean ? grad_output / input.numel() : grad_output;
at::sub_out(grad_input, input, target).sign_().mul_(norm);
return grad_input;
}
}} // namespace at::native