// Copyright (c) 2025 PaddlePaddle Authors. All Rights Reserved. // // Licensed under the Apache License, Version 2.0 (the "License"); // you may not use this file except in compliance with the License. // You may obtain a copy of the License at // // http://www.apache.org/licenses/LICENSE-2.0 // // Unless required by applicable law or agreed to in writing, software // distributed under the License is distributed on an "AS IS" BASIS, // WITHOUT WARRANTIES OR CONDITIONS OF ANY KIND, either express or implied. // See the License for the specific language governing permissions and // limitations under the License. #include "paddle/phi/kernels/index_elementwise_put_grad_kernel.h" #include "paddle/phi/backends/cpu/cpu_context.h" #include "paddle/phi/core/kernel_registry.h" #include "paddle/phi/kernels/cast_kernel.h" #include "paddle/phi/kernels/full_kernel.h" #include "paddle/phi/kernels/funcs/index_elementwise.h" #include "paddle/phi/kernels/funcs/index_put_utils.h" #include "paddle/phi/kernels/funcs/stride_utils.h" #include "paddle/phi/kernels/reduce_sum_kernel.h" namespace phi { template void CPUIndexElementwisePutGradKernel( const CPUContext& dev_ctx, const DenseTensor& out_grad, const std::vector& index, const std::vector& input_dims, const std::vector& input_strides, const std::vector& index_dims, const std::vector& index_strides, const int64_t slice_offset, DenseTensor* x_grad, DenseTensor* value_grad) { int64_t numel = 0; int64_t num_indices = 0; std::vector shape_tmp; std::vector stride_tmp; funcs::cal_shape_stride(index_dims, &num_indices, &shape_tmp, &stride_tmp); auto sizes = std::array{}; auto strides = std::array{}; for (int64_t i = 0; i < num_indices; i++) { sizes[i] = index_dims[i]; strides[i] = index_strides[i]; } std::array strides_array; std::vector desired_shape; std::array, 3> strides_vec; std::vector value_dims; std::vector value_strides; if (value_grad) { value_dims = vectorize(value_grad->dims()); value_strides = vectorize(value_grad->strides()); } funcs::IndexPutStride<3>(input_dims, input_strides, SizeOf(out_grad.dtype()), value_dims, value_strides, 4, shape_tmp, stride_tmp, SizeOf(index[0]->dtype()), &desired_shape, &strides_array, &numel, strides_vec); auto offset_calc = funcs::CPUmake_offset_calculator_put<3>(desired_shape, strides_array); const int64_t N = numel; PADDLE_ENFORCE_EQ(true, (N >= 0 && N <= std::numeric_limits::max()), common::errors::PreconditionNotMet( "the value of N should be in [0, " "std::numeric_limits::max()]")); using dtype = funcs::OpaqueType; if (!value_grad) { char* out_ptr = reinterpret_cast(x_grad->data()); if (index.size() == 1 && index[0]->dtype() == DataType::BOOL) { const bool* mask_data = index[0]->data(); for (int64_t idx = 0; idx < N; idx++) { const auto offsets = offset_calc.cpu_get(idx); char* const out_data = out_ptr + offsets[0] + slice_offset; if (mask_data[idx]) { *reinterpret_cast(out_data) = T(0); } } } else { auto index_ptrs = funcs::GetIndexDataPtrs(index); for (int64_t idx = 0; idx < N; idx++) { const auto offsets = offset_calc.cpu_get(idx); char* const out_data = out_ptr + offsets[0] + slice_offset; int64_t offset = 0; for (int64_t i = 0; i < num_indices; i++) { int64_t index = *reinterpret_cast(index_ptrs[i] + offsets[2]); if (index < 0) { index += sizes[i]; } offset += index * strides[i]; } T num = T(0); *reinterpret_cast(out_data + offset) = *reinterpret_cast(&num); } } } else if (!x_grad) { auto index_ptrs = funcs::GetIndexDataPtrs(index); const char* out_ptr = reinterpret_cast(out_grad.data()); char* value_ptr = reinterpret_cast(value_grad->data()); for (int64_t idx = 0; idx < N; idx++) { const auto offsets = offset_calc.cpu_get(idx); const char* const out_data = out_ptr + offsets[0] + slice_offset; char* const value_data = value_ptr + offsets[1]; int64_t offset = 0; for (int64_t i = 0; i < num_indices; i++) { int64_t index = *reinterpret_cast(index_ptrs[i] + offsets[2]); if (index < 0) { index += sizes[i]; } offset += index * strides[i]; } *reinterpret_cast(value_data) = *reinterpret_cast(out_data + offset); } } else { auto index_ptrs = funcs::GetIndexDataPtrs(index); char* out_ptr = reinterpret_cast(x_grad->data()); char* value_ptr = reinterpret_cast(value_grad->data()); for (int64_t idx = 0; idx < N; idx++) { const auto offsets = offset_calc.cpu_get(idx); char* const out_data = out_ptr + offsets[0] + slice_offset; char* const value_data = value_ptr + offsets[1]; int64_t offset = 0; for (int64_t i = 0; i < num_indices; i++) { int64_t index = *reinterpret_cast(index_ptrs[i] + offsets[2]); if (index < 0) { index += sizes[i]; } offset += index * strides[i]; } T num = T(0); *reinterpret_cast(value_data) = *reinterpret_cast(out_data + offset); *reinterpret_cast(out_data + offset) = *reinterpret_cast(&num); } } } template void LaunchIndexElementwisePutWithTensorGradKernel( const Context& dev_ctx, const std::vector& indices, const DenseTensor& out_grad, const std::vector& input_dims, const std::vector& input_strides, const std::vector& index_dims, const std::vector& index_strides, const int64_t slice_offset, DenseTensor* value_grad, DenseTensor* x_grad) { if (x_grad && !value_grad) { Copy(dev_ctx, out_grad, dev_ctx.GetPlace(), false, x_grad); CPUIndexElementwisePutGradKernel(dev_ctx, out_grad, indices, input_dims, input_strides, index_dims, index_strides, slice_offset, x_grad, value_grad); } else if (value_grad) { if (x_grad) { Copy(dev_ctx, out_grad, dev_ctx.GetPlace(), false, x_grad); } if (value_grad->numel() == 1) { DenseTensor tmp_value_grad(value_grad->dtype()); tmp_value_grad.Resize(input_dims); dev_ctx.template Alloc(&tmp_value_grad); CPUIndexElementwisePutGradKernel(dev_ctx, out_grad, indices, input_dims, input_strides, index_dims, index_strides, slice_offset, x_grad, &tmp_value_grad); std::vector v_dims(tmp_value_grad.dims().size()); std::iota(v_dims.begin(), v_dims.end(), 0); IntArray v_axis(v_dims); SumKernel(dev_ctx, tmp_value_grad, v_axis, value_grad->dtype(), false, value_grad); } else if (value_grad->dims() == make_ddim(input_dims)) { dev_ctx.template Alloc(value_grad); CPUIndexElementwisePutGradKernel(dev_ctx, out_grad, indices, input_dims, input_strides, index_dims, index_strides, slice_offset, x_grad, value_grad); } else { DenseTensor tmp_value_grad(value_grad->dtype()); tmp_value_grad.Resize(input_dims); dev_ctx.template Alloc(&tmp_value_grad); CPUIndexElementwisePutGradKernel(dev_ctx, out_grad, indices, input_dims, input_strides, index_dims, index_strides, slice_offset, x_grad, &tmp_value_grad); std::vector after_dims = vectorize(tmp_value_grad.dims()); std::vector before_dims = vectorize(value_grad->dims()); std::vector compress_dims; std::vector dims_without_1; funcs::CalCompressedDimsWith1AndWithout1( &after_dims, &before_dims, &compress_dims, &dims_without_1); auto pre_dims = value_grad->dims(); value_grad->Resize(dims_without_1); IntArray v_axis(compress_dims); SumKernel(dev_ctx, tmp_value_grad, v_axis, value_grad->dtype(), false, value_grad); value_grad->Resize(pre_dims); } } } template void LaunchIndexElementwisePutGradKernel( const Context& dev_ctx, const std::vector& indices, const DenseTensor& out_grad, const std::vector& input_dims, const std::vector& input_strides, const std::vector& index_dims, const std::vector& index_strides, const int64_t slice_offset, DenseTensor* x_grad) { if (x_grad) { Copy(dev_ctx, out_grad, dev_ctx.GetPlace(), false, x_grad); CPUIndexElementwisePutGradKernel(dev_ctx, out_grad, indices, input_dims, input_strides, index_dims, index_strides, slice_offset, x_grad, nullptr); } } template void IndexElementwisePutGradKernel( const Context& dev_ctx, const DenseTensor& x, const std::vector& indices, const DenseTensor& out_grad, const std::vector& input_dims, const std::vector& input_strides, const std::vector& index_dims, const std::vector& index_strides, const int64_t slice_offset, DenseTensor* x_grad) { const auto& index_type = indices[0]->dtype(); PADDLE_ENFORCE_EQ(index_type == DataType::INT64 || (index_type == DataType::BOOL && indices.size() == 1), true, common::errors::InvalidArgument( "Index holds the wrong type, it holds [%s], but " "desires to be [%s].", index_type, DataType::INT64)); std::vector tmp_args; if (indices.empty()) { if (x_grad) { Copy(dev_ctx, out_grad, dev_ctx.GetPlace(), false, x_grad); } return; } LaunchIndexElementwisePutGradKernel(dev_ctx, indices, out_grad, input_dims, input_strides, index_dims, index_strides, slice_offset, x_grad); } template void IndexElementwisePutWithTensorGradKernel( const Context& dev_ctx, const DenseTensor& x, const std::vector& indices, const DenseTensor& value, const DenseTensor& out_grad, const std::vector& input_dims, const std::vector& input_strides, const std::vector& index_dims, const std::vector& index_strides, const int64_t slice_offset, DenseTensor* x_grad, DenseTensor* value_grad) { const auto& index_type = indices[0]->dtype(); PADDLE_ENFORCE_EQ(index_type == DataType::INT64, true, common::errors::InvalidArgument( "Index holds the wrong type, it holds [%s], but " "desires to be [%s].", index_type, DataType::INT64)); std::vector tmp_args; if (indices.empty()) { if (x_grad) { Copy(dev_ctx, out_grad, dev_ctx.GetPlace(), false, x_grad); } if (value_grad) { Full(dev_ctx, value_grad->dims(), 0.0f, value_grad); } return; } LaunchIndexElementwisePutWithTensorGradKernel(dev_ctx, indices, out_grad, input_dims, input_strides, index_dims, index_strides, slice_offset, value_grad, x_grad); } } // namespace phi PD_REGISTER_KERNEL(index_elementwise_put_grad, CPU, ALL_LAYOUT, phi::IndexElementwisePutGradKernel, bool, float, double, int, int8_t, int64_t, int16_t, uint8_t, phi::float16, phi::bfloat16, phi::complex64, phi::complex128) {} PD_REGISTER_KERNEL(index_elementwise_put_with_tensor_grad, CPU, ALL_LAYOUT, phi::IndexElementwisePutWithTensorGradKernel, bool, float, double, int, int8_t, int64_t, int16_t, uint8_t, phi::float16, phi::bfloat16, phi::complex64, phi::complex128) {}