/* Copyright 2017 The TensorFlow 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 "tensorflow/compiler/xla/service/computation_placer.h" #include #include #include #include "absl/memory/memory.h" #include "absl/strings/str_cat.h" #include "tensorflow/compiler/xla/literal.h" #include "tensorflow/compiler/xla/shape_util.h" #include "tensorflow/compiler/xla/status.h" #include "tensorflow/compiler/xla/status_macros.h" #include "tensorflow/compiler/xla/statusor.h" #include "tensorflow/compiler/xla/types.h" #include "tensorflow/compiler/xla/util.h" #include "tensorflow/core/lib/core/errors.h" #include "tensorflow/core/lib/core/status.h" #include "tensorflow/core/platform/logging.h" #include "tensorflow/core/platform/stream_executor_no_cuda.h" using absl::StrAppend; using absl::StrCat; namespace xla { Status DeviceAssignment::Serialize(DeviceAssignmentProto* proto) const { proto->set_replica_count(replica_count()); proto->set_computation_count(computation_count()); for (int computation = 0; computation < computation_count(); ++computation) { DeviceAssignmentProto::ComputationDevice* computation_device = proto->add_computation_devices(); for (int replica = 0; replica < replica_count(); ++replica) { computation_device->add_replica_device_ids((*this)(replica, computation)); } } return Status::OK(); } /* static */ StatusOr> DeviceAssignment::Deserialize(const DeviceAssignmentProto& proto) { TF_RET_CHECK(proto.computation_devices_size() == proto.computation_count()); if (proto.replica_count() <= 0 || proto.computation_count() <= 0) { return InvalidArgument( "Invalid device assignment topology: replica_count=%d, " "computation_count=%d", proto.replica_count(), proto.computation_count()); } auto assignment = absl::make_unique( proto.replica_count(), proto.computation_count()); for (int computation = 0; computation < proto.computation_count(); ++computation) { const auto& computation_device = proto.computation_devices(computation); TF_RET_CHECK(computation_device.replica_device_ids_size() == proto.replica_count()); for (int replica = 0; replica < proto.replica_count(); ++replica) { (*assignment)(replica, computation) = computation_device.replica_device_ids(replica); } } return std::move(assignment); } string DeviceAssignment::ToString() const { string output = StrCat("Computations: ", computation_count(), " Replicas: ", replica_count(), "\n"); for (int computation = 0; computation < computation_count(); ++computation) { StrAppend(&output, "Computation ", computation, ": "); for (int replica = 0; replica < replica_count(); ++replica) { StrAppend(&output, operator()(replica, computation), " "); } StrAppend(&output, "\n"); } return output; } StatusOr ComputationPlacer::DeviceId(int replica, int computation, int replica_count, int computation_count) { TF_RET_CHECK(replica < replica_count); TF_RET_CHECK(computation < computation_count); return computation * replica_count + replica; } StatusOr ComputationPlacer::AssignDevices( int replica_count, int computation_count) { DeviceAssignment assignment(replica_count, computation_count); for (int replica = 0; replica < replica_count; ++replica) { for (int computation = 0; computation < computation_count; ++computation) { TF_ASSIGN_OR_RETURN( int device_id, DeviceId(replica, computation, replica_count, computation_count)); assignment(replica, computation) = device_id; } } return std::move(assignment); } /* static */ void ComputationPlacer::RegisterComputationPlacer( se::Platform::Id platform_id, ComputationPlacerCreationFunction creation_function) { tensorflow::mutex_lock lock( ComputationPlacer::platform_computation_placer_mutex_); auto* computation_placers = GetPlatformComputationPlacers(); CHECK(computation_placers->find(platform_id) == computation_placers->end()); (*computation_placers)[platform_id].creation_function = creation_function; } /* static */ StatusOr ComputationPlacer::GetForPlatform( const se::Platform* platform) { tensorflow::mutex_lock lock( ComputationPlacer::platform_computation_placer_mutex_); auto* computation_placers = GetPlatformComputationPlacers(); auto it = computation_placers->find(platform->id()); if (it == computation_placers->end()) { return NotFound( "could not find registered computation placer for platform %s -- check " "target linkage", platform->Name()); } if (it->second.placer == nullptr) { // Lazily create the computation placer the first time it is needed. it->second.placer = (*it->second.creation_function)(); } return it->second.placer.get(); } /* static */ tensorflow::mutex ComputationPlacer::platform_computation_placer_mutex_( tensorflow::LINKER_INITIALIZED); /* static */ std::map* ComputationPlacer::GetPlatformComputationPlacers() { static auto* r = new std::map; return r; } } // namespace xla static std::unique_ptr CreateComputationPlacer() { return absl::make_unique(); } static bool InitModule() { xla::ComputationPlacer::RegisterComputationPlacer( stream_executor::host::kHostPlatformId, &CreateComputationPlacer); xla::ComputationPlacer::RegisterComputationPlacer( stream_executor::cuda::kCudaPlatformId, &CreateComputationPlacer); return true; } static bool module_initialized = InitModule();