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BinaryMiscBackwardOpsKernels.cu
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BinaryMiscBackwardOpsKernels.cu
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#include <ATen/native/BinaryOps.h>
#include <limits>
#include <ATen/AccumulateType.h>
#include <ATen/Dispatch.h>
#include <ATen/native/DispatchStub.h>
#include <ATen/native/TensorIterator.h>
#include <ATen/native/cuda/Loops.cuh>
// NOTE: CUDA on Windows requires that the enclosing function
// of a __device__ lambda not have internal linkage.
namespace at {
namespace native {
void sigmoid_backward_kernel_cuda(TensorIterator& iter) {
if(isComplexType(iter.dtype())) {
AT_DISPATCH_COMPLEX_TYPES(iter.dtype(), "sigmoid_backward_cuda", [&]() {
gpu_kernel(iter, [] GPU_LAMBDA(scalar_t a, scalar_t b) -> scalar_t {
return a * std::conj((scalar_t{1.} - b) * b);
});
});
} else {
AT_DISPATCH_FLOATING_TYPES_AND2(at::ScalarType::Half, at::ScalarType::BFloat16, iter.dtype(), "sigmoid_backward_cuda", [&]() {
gpu_kernel(iter, []GPU_LAMBDA(scalar_t a, scalar_t b) -> scalar_t {
return a * (scalar_t(1.) - b) * b;
});
});
}
}
void logit_backward_kernel_cuda(TensorIterator& iter, const Scalar& eps_scalar) {
AT_DISPATCH_FLOATING_TYPES_AND2(
at::ScalarType::Half,
at::ScalarType::BFloat16,
iter.dtype(),
"logit_cuda",
[&]() {
using T_ACC = acc_type<scalar_t, true>;
const T_ACC eps = eps_scalar.to<T_ACC>();
if (eps < T_ACC(0)) {
gpu_kernel(
iter, [] GPU_LAMBDA(scalar_t dy, scalar_t x) -> scalar_t {
const T_ACC dy_acc = static_cast<T_ACC>(dy);
const T_ACC x_acc = static_cast<T_ACC>(x);
return (x_acc < T_ACC(0) || x_acc > T_ACC(1))
? std::numeric_limits<T_ACC>::quiet_NaN()
: dy_acc / (x_acc * (T_ACC(1) - x_acc));
});
} else {
const T_ACC lo = eps;
const T_ACC hi = T_ACC(1) - eps;
gpu_kernel(
iter, [lo, hi] GPU_LAMBDA(scalar_t dy, scalar_t x) -> scalar_t {
const T_ACC dy_acc = static_cast<T_ACC>(dy);
const T_ACC x_acc = static_cast<T_ACC>(x);
return (x_acc < lo || x_acc > hi)
? T_ACC(0)
: dy_acc / (x_acc * (T_ACC(1) - x_acc));
});
}
});
}
void tanh_backward_kernel_cuda(TensorIterator& iter) {
if(isComplexType(iter.dtype())) {
AT_DISPATCH_COMPLEX_TYPES(iter.dtype(), "tanh_backward_complex_cuda", [&]() {
gpu_kernel(iter, [] GPU_LAMBDA(scalar_t a, scalar_t b) -> scalar_t {
return a * std::conj(scalar_t{1.} - b * b);
});
});
} else {
AT_DISPATCH_FLOATING_TYPES_AND2(at::ScalarType::Half, at::ScalarType::BFloat16, iter.dtype(), "tanh_backward_cuda", [&]() {
gpu_kernel(iter, [] GPU_LAMBDA(scalar_t a, scalar_t b) -> scalar_t {
return a * (scalar_t{1.} - b * b);
});
});
}
}
REGISTER_DISPATCH(sigmoid_backward_stub, &sigmoid_backward_kernel_cuda);
REGISTER_DISPATCH(logit_backward_stub, &logit_backward_kernel_cuda);
REGISTER_DISPATCH(tanh_backward_stub, &tanh_backward_kernel_cuda);
} // namespace native
} // namespace at