/* Copyright (c) 2021 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. */ #ifdef PADDLE_WITH_HIP #include namespace cub = hipcub; #else #include #endif #include #include "paddle/fluid/operators/amp/fp16_type_traits.h" #include "paddle/fluid/operators/margin_cross_entropy_op.h" #include "paddle/fluid/operators/math/softmax_impl.h" #include "paddle/fluid/operators/reduce_ops/reduce_op.cu.h" #include "paddle/fluid/operators/reduce_ops/reduce_op.h" #include "paddle/fluid/string/string_helper.h" #include "paddle/phi/api/include/tensor.h" #include "paddle/phi/kernels/funcs/axis_utils.h" #include "paddle/phi/kernels/funcs/math_function.h" #if defined(PADDLE_WITH_NCCL) || defined(PADDLE_WITH_RCCL) #include "paddle/fluid/distributed/collective/ProcessGroup.h" #include "paddle/fluid/platform/collective_helper.h" #include "paddle/fluid/platform/device/gpu/nccl_helper.h" #endif namespace paddle { namespace operators { using Tensor = framework::Tensor; static constexpr int kNumCUDAThreads = 512; static constexpr int kNumMaxinumNumBlocks = 4096; static inline int NumBlocks(const int N) { return std::min((N + kNumCUDAThreads - 1) / kNumCUDAThreads, kNumMaxinumNumBlocks); } void GetClassInterval(const gpuStream_t& stream, const platform::Place& place, const platform::DeviceContext& ctx, const int rid, const int rank, const int nranks, const int D, Tensor* class_interval) { std::vector shard_dim_vec(nranks + 1, 0); shard_dim_vec[rank + 1] = D; if (nranks <= 1) { framework::TensorFromVector(shard_dim_vec, ctx, class_interval); return; } #if defined(PADDLE_WITH_NCCL) || defined(PADDLE_WITH_RCCL) Tensor num_classes_per_device; framework::TensorFromVector(shard_dim_vec, ctx, &num_classes_per_device); int* num_classes_per_device_ptr = num_classes_per_device.data(); auto map = distributed::ProcessGroupMapFromGid::getInstance(); if (map->has(rid)) { // Use ProcessGroup distributed::ProcessGroup* pg = map->get(rid); std::vector in_tensor; std::vector out_tensor; in_tensor.push_back(num_classes_per_device); out_tensor.push_back(num_classes_per_device); distributed::AllreduceOptions opts; opts.reduce_op = distributed::ReduceOp::SUM; auto task = pg->AllReduce(in_tensor, out_tensor, opts); task->Wait(); } else { const auto& comm = platform::NCCLCommContext::Instance().Get(rid, place); // use global calculate stream const auto calcu_stream = static_cast( platform::DeviceContextPool::Instance().Get(place)) ->stream(); PADDLE_ENFORCE_GPU_SUCCESS(platform::dynload::ncclAllReduce( num_classes_per_device_ptr, num_classes_per_device_ptr, num_classes_per_device.numel(), platform::ToNCCLDataType( framework::TransToProtoVarType(num_classes_per_device.dtype())), ncclSum, comm->comm(), calcu_stream)); } auto class_interval_ptr = class_interval->mutable_data({nranks + 1}, place); size_t cub_temp_storage_bytes = 0; cub::DeviceScan::InclusiveSum( nullptr, cub_temp_storage_bytes, nullptr, nullptr, nranks + 1, stream); auto cub_temp_storage = memory::Alloc(place, cub_temp_storage_bytes); cub::DeviceScan::InclusiveSum(cub_temp_storage->ptr(), cub_temp_storage_bytes, num_classes_per_device_ptr, class_interval_ptr, nranks + 1, stream); return; #endif } template __global__ void AddMarginToPositiveLogitsKernel(T* logit, const IndexT* label, const float margin1, const float margin2, const float margin3, const int rank, const int nranks, const int64_t N, const int64_t D, const int* class_interval_ptr) { using MPType = typename details::MPTypeTrait::Type; int start_index = class_interval_ptr[rank]; int end_index = class_interval_ptr[rank + 1]; int num_classes = class_interval_ptr[nranks]; CUDA_KERNEL_LOOP(i, N) { auto real_label = label[i]; PADDLE_ENFORCE((real_label < num_classes) && (real_label >= 0), "The index is out of bounds, " "please check whether the value of label and " "input meet the number of class. It should " "be less than [%d], but received [%d]", num_classes, real_label); if (real_label >= start_index && real_label < end_index) { int64_t offset = i * D + real_label - start_index; if (fabs(margin1 - 1.0) > 1e-8 || fabs(margin2) > 1e-8) { MPType x = static_cast(logit[offset]); MPType theta = acos(x); if (fabs(margin1 - 1.0) > 1e-8) { theta *= static_cast(margin1); } if (fabs(margin2) > 1e-8) { theta += static_cast(margin2); } logit[offset] = static_cast(cos(theta)); } if (fabs(margin3) > 1e-8) { MPType y = static_cast(logit[offset]); y -= static_cast(margin3); logit[offset] = static_cast(y); } } } } template __global__ void ScaleLogitKernel(T* logits, const float scale, const int64_t N, const int64_t D) { CUDA_KERNEL_LOOP(i, N * D) { logits[i] *= static_cast(scale); } } template __global__ void LogitsMinusMaxKernel(T* logits, const T* logits_max_per_row, const int64_t N, const int64_t D) { CUDA_KERNEL_LOOP(i, N * D) { auto row = i / D; logits[i] -= logits_max_per_row[row]; } } template __global__ void LogitsMinusLogSumKernel(T* logits, const T* logits_sum_per_row, const int64_t N, const int64_t D) { CUDA_KERNEL_LOOP(i, N * D) { auto row = i / D; logits[i] -= kps::details::Log(logits_sum_per_row[row]); } } template __global__ void HardLabelSoftmaxWithCrossEntropyKernel( T* loss, T* log_softmax, const IndexT* labels, const int rank, const int64_t N, const int64_t D, const int* class_interval_ptr) { int start_index = class_interval_ptr[rank]; CUDA_KERNEL_LOOP(i, N * D) { auto row = i / D; auto col = i % D; if ((col + start_index) == labels[row]) { auto softmax = log_softmax[i]; loss[row] = -softmax; log_softmax[i] = kps::details::Exp(softmax); } else { log_softmax[i] = kps::details::Exp(log_softmax[i]); } } } template __global__ void CalculateGrad(T* logits_grad, const T* loss_grad, const T* logits, const IndexT* labels, const float margin1, const float margin2, const float scale, const int rank, const int64_t N, const int64_t D, const int* class_interval_ptr) { using MPType = typename details::MPTypeTrait::Type; int start_index = class_interval_ptr[rank]; CUDA_KERNEL_LOOP(i, N * D) { auto row = i / D; auto col = i % D; if ((col + start_index) == labels[row]) { logits_grad[i] = (logits_grad[i] - static_cast(1.0)) * loss_grad[row]; if (fabs(margin1 - 1.0) > 1e-8 || fabs(margin2) > 1e-8) { MPType dout = static_cast(logits_grad[i]); MPType one = static_cast(1.0f); MPType x = static_cast(logits[i]); MPType m1 = static_cast(margin1); MPType m2 = static_cast(margin2); MPType d = m1 * sin(m1 * acos(x) + m2) / sqrt(one - x * x); logits_grad[i] = static_cast(dout * d); } } else { logits_grad[i] *= loss_grad[row]; } if (fabs(scale - 1.0) > 1e-8) { logits_grad[i] *= static_cast(scale); } } } template class MarginCrossEntropyOpCUDAKernel : public framework::OpKernel { public: void Compute(const framework::ExecutionContext& ctx) const override { const Tensor* logits = ctx.Input("Logits"); const Tensor* labels = ctx.Input("Label"); Tensor* softmax = ctx.Output("Softmax"); Tensor* loss = ctx.Output("Loss"); const int rid = ctx.Attr("ring_id"); const int nranks = ctx.Attr("nranks"); const int rank = ctx.Attr("rank"); const float margin1 = ctx.Attr("margin1"); const float margin2 = ctx.Attr("margin2"); const float margin3 = ctx.Attr("margin3"); const float scale = ctx.Attr("scale"); const auto& place = ctx.GetPlace(); auto& dev_ctx = ctx.template device_context(); #if defined(PADDLE_WITH_NCCL) || defined(PADDLE_WITH_RCCL) platform::NCCLComm* comm; distributed::ProcessGroup* pg = nullptr; gpuStream_t stream; if (nranks > 1) { auto map = distributed::ProcessGroupMapFromGid::getInstance(); if (map->has(rid)) { // Use ProcessGroup pg = map->get(rid); } else { comm = platform::NCCLCommContext::Instance().Get(rid, place); // use global calculate stream stream = static_cast( platform::DeviceContextPool::Instance().Get(place)) ->stream(); } } #endif // allocate memory on device. T* softmax_ptr = softmax->mutable_data(place); T* loss_ptr = loss->mutable_data(place); const auto& logits_dims = logits->dims(); const auto& labels_dims = labels->dims(); const int axis = logits_dims.size() - 1; const int N = phi::funcs::SizeToAxis(axis, logits_dims); const int D = phi::funcs::SizeFromAxis(axis, logits_dims); int blocks = NumBlocks(N); int threads = kNumCUDAThreads; const auto& label_type = framework::TransToProtoVarType(labels->dtype()); // copy logits to softmax variable since we can't modify logits, // and it also be used when calculate grad framework::TensorCopy( *logits, ctx.GetPlace(), ctx.device_context(), softmax); Tensor softmax_2d; softmax_2d.ShareDataWith(*softmax).Resize({N, D}); T* logits_ptr = softmax_2d.data(); Tensor class_interval; GetClassInterval(dev_ctx.stream(), place, ctx.cuda_device_context(), rid, rank, nranks, D, &class_interval); // step 1, preprocess logits // add margin for positive elements // theta = acos(x_i) // (cos(m1 * theta + m2) - m3) // save match_logits, used for gradient computation. if (label_type == framework::proto::VarType::INT32) { typedef int32_t LabelT; AddMarginToPositiveLogitsKernel <<>>( logits_ptr, labels->data(), margin1, margin2, margin3, rank, nranks, N, D, class_interval.data()); } else if (label_type == framework::proto::VarType::INT64) { typedef int64_t LabelT; AddMarginToPositiveLogitsKernel <<>>( logits_ptr, labels->data(), margin1, margin2, margin3, rank, nranks, N, D, class_interval.data()); } else { PADDLE_THROW(platform::errors::Unimplemented( "margin_cross_entropy label type noly support int32 and int64, " "but got %s", label_type)); } // scale by s ScaleLogitKernel<<>>( logits_ptr, scale, N, D); // step 2, obtain logit_max Tensor logits_max; logits_max = ctx.AllocateTmpTensor({N, 1}, dev_ctx); T* logits_max_buff = logits_max.mutable_data(place); TensorReduceImpl>( dev_ctx, softmax_2d, &logits_max, kps::IdentityFunctor(), {1}, dev_ctx.stream()); #if defined(PADDLE_WITH_NCCL) || defined(PADDLE_WITH_RCCL) if (nranks > 1) { if (pg) { std::vector in_tensor; std::vector out_tensor; in_tensor.push_back(logits_max); out_tensor.push_back(logits_max); distributed::AllreduceOptions opts; opts.reduce_op = distributed::ReduceOp::MAX; auto task = pg->AllReduce(in_tensor, out_tensor, opts); task->Wait(); } else { PADDLE_ENFORCE_GPU_SUCCESS(platform::dynload::ncclAllReduce( logits_max_buff, logits_max_buff, logits_max.numel(), platform::ToNCCLDataType( framework::TransToProtoVarType(logits_max.dtype())), ncclMax, comm->comm(), stream)); } } #endif // step 3, logit - logit_max LogitsMinusMaxKernel<<>>( logits_ptr, logits_max_buff, N, D); // step 4, sum(exp(logit - logit_max)) Tensor sum_exp_logits; sum_exp_logits = ctx.AllocateTmpTensor({N, 1}, dev_ctx); T* sum_exp_logits_buff = sum_exp_logits.mutable_data(place); TensorReduceImpl>( dev_ctx, softmax_2d, &sum_exp_logits, kps::ExpFunctor(), {1}, dev_ctx.stream()); #if defined(PADDLE_WITH_NCCL) || defined(PADDLE_WITH_RCCL) if (nranks > 1) { if (pg) { std::vector in_tensor; std::vector out_tensor; in_tensor.push_back(sum_exp_logits); out_tensor.push_back(sum_exp_logits); distributed::AllreduceOptions opts; opts.reduce_op = distributed::ReduceOp::SUM; auto task = pg->AllReduce(in_tensor, out_tensor, opts); task->Wait(); } else { PADDLE_ENFORCE_GPU_SUCCESS(platform::dynload::ncclAllReduce( sum_exp_logits_buff, sum_exp_logits_buff, sum_exp_logits.numel(), platform::ToNCCLDataType( framework::TransToProtoVarType(sum_exp_logits.dtype())), ncclSum, comm->comm(), stream)); } } #endif // step 5, (logit - logit_max) - log(sum(exp(logit - logit_max))) LogitsMinusLogSumKernel <<>>( logits_ptr, sum_exp_logits_buff, N, D); // step 6, prob = exp((logit - logit_max) - log(sum(exp(logit - // logit_max)))) // loss = -((logit_i - logit_max) - log(sum(exp(logit - logit_max)))) phi::funcs::SetConstant()( dev_ctx, loss, static_cast(0.0)); if (label_type == framework::proto::VarType::INT32) { typedef int32_t LabelT; HardLabelSoftmaxWithCrossEntropyKernel <<>>( loss_ptr, logits_ptr, labels->data(), rank, N, D, class_interval.data()); } else if (label_type == framework::proto::VarType::INT64) { typedef int64_t LabelT; HardLabelSoftmaxWithCrossEntropyKernel <<>>( loss_ptr, logits_ptr, labels->data(), rank, N, D, class_interval.data()); } #if defined(PADDLE_WITH_NCCL) || defined(PADDLE_WITH_RCCL) if (nranks > 1) { if (pg) { std::vector in_tensor; std::vector out_tensor; in_tensor.push_back(*loss); out_tensor.push_back(*loss); distributed::AllreduceOptions opts; opts.reduce_op = distributed::ReduceOp::SUM; auto task = pg->AllReduce(in_tensor, out_tensor, opts); task->Wait(); } else { PADDLE_ENFORCE_GPU_SUCCESS(platform::dynload::ncclAllReduce( loss_ptr, loss_ptr, loss->numel(), platform::ToNCCLDataType( framework::TransToProtoVarType(loss->dtype())), ncclSum, comm->comm(), stream)); } } #endif } }; template class MarginCrossEntropyGradCUDAKernel : public framework::OpKernel { public: void Compute(const framework::ExecutionContext& context) const override { const Tensor* labels = context.Input("Label"); const Tensor* logits = context.Input("Logits"); const Tensor* softmax = context.Input("Softmax"); const Tensor* loss_grad = context.Input(framework::GradVarName("Loss")); Tensor* logit_grad = context.Output(framework::GradVarName("Logits")); const bool return_softmax = context.Attr("return_softmax"); const int rid = context.Attr("ring_id"); const int nranks = context.Attr("nranks"); const int rank = context.Attr("rank"); const float margin1 = context.Attr("margin1"); const float margin2 = context.Attr("margin2"); const float margin3 = context.Attr("margin3"); const float scale = context.Attr("scale"); auto& dev_ctx = context.template device_context(); const auto sofrmax_dims = softmax->dims(); const int axis = sofrmax_dims.size() - 1; const int N = phi::funcs::SizeToAxis(axis, sofrmax_dims); const int D = phi::funcs::SizeFromAxis(axis, sofrmax_dims); if (return_softmax) { framework::TensorCopy( *softmax, context.GetPlace(), context.device_context(), logit_grad); } else { logit_grad->ShareDataWith(*softmax); } int blocks = NumBlocks(N * D); int threads = kNumCUDAThreads; const auto& label_type = framework::TransToProtoVarType(labels->dtype()); Tensor class_interval; GetClassInterval(dev_ctx.stream(), context.GetPlace(), context.cuda_device_context(), rid, rank, nranks, D, &class_interval); if (label_type == framework::proto::VarType::INT32) { typedef int32_t LabelT; CalculateGrad<<>>( logit_grad->data(), loss_grad->data(), logits->data(), labels->data(), margin1, margin2, scale, rank, N, D, class_interval.data()); } else if (label_type == framework::proto::VarType::INT64) { typedef int64_t LabelT; CalculateGrad<<>>( logit_grad->data(), loss_grad->data(), logits->data(), labels->data(), margin1, margin2, scale, rank, N, D, class_interval.data()); } } }; } // namespace operators } // namespace paddle namespace ops = paddle::operators; namespace plat = paddle::platform; REGISTER_OP_CUDA_KERNEL(margin_cross_entropy, ops::MarginCrossEntropyOpCUDAKernel, ops::MarginCrossEntropyOpCUDAKernel, ops::MarginCrossEntropyOpCUDAKernel); REGISTER_OP_CUDA_KERNEL(margin_cross_entropy_grad, ops::MarginCrossEntropyGradCUDAKernel, ops::MarginCrossEntropyGradCUDAKernel, ops::MarginCrossEntropyGradCUDAKernel);