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context_gpu.h
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context_gpu.h
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#ifndef CAFFE2_CORE_CONTEXT_GPU_H_
#define CAFFE2_CORE_CONTEXT_GPU_H_
#include <ctime>
#include <mutex>
#include "caffe2/core/common.h"
#include "caffe2/core/common_gpu.h"
#include "caffe2/core/context.h"
#include "caffe2/core/context_base.h"
#include "caffe2/core/logging.h"
#include "caffe2/core/numa.h"
#include "caffe2/core/tensor.h"
#include "caffe2/core/types.h"
#include "caffe2/proto/caffe2_pb.h"
// Since we are using the macro CAFFE2_USE_CUDNN, we will need to include this
// file after common.h is included.
#ifdef CAFFE2_USE_CUDNN
#include "caffe2/core/common_cudnn.h"
#endif // CAFFE2_USE_CUDNN
#include <c10/core/Device.h>
#include <c10/core/Stream.h>
#include <c10/cuda/CUDAStream.h>
#include <c10/cuda/CUDAGuard.h>
namespace caffe2 {
enum class CudaMemoryPoolType {
NONE = 0,
CUB = 1,
THC = 2,
};
/**
* Gets the current memory pool type used by Caffe2.
*
* The memory pool is set up during caffe2's global initialization time.
*/
CAFFE2_CUDA_API CudaMemoryPoolType GetCudaMemoryPoolType();
/**
* A struct to host thread-local cuda objects.
*
* In Caffe2, each thread has its own non-default cuda stream as well as
* related objects such as cublas and curand handles. This is achieved by
* having the ThreadLocalCUDAObjects wrapper that takes care of allocating
* and deallocating these objects at the thread scope. This class is solely
* used inside CUDAContext and should not be used externally.
*
* This class manages the mapping from logical stream ID (int stream_id
* passed around in Caffe2) and CUDAStream objects. We intend to eventually
* deprecate the logical stream ID interface, but not for now.
*/
class CAFFE2_CUDA_API ThreadLocalCUDAObjects {
friend class CUDAContext;
private:
ThreadLocalCUDAObjects() {
for (DeviceIndex i = 0; i < C10_COMPILE_TIME_MAX_GPUS; ++i) {
cuda_streams_[i] = vector<c10::cuda::CUDAStream>();
}
}
// Record current stream id for the current thread.
// This is the new API we're trying to migrate use cases to and get rid of
// explicit stream id passing. For now it's invoked in
// CUDAContext::SwitchToDevice
void SetCurrentStreamId(DeviceIndex gpu, StreamId stream_id) {
// TODO: use current device id from thread local instead of passing gpu in
if (stream_id != -1) {
c10::cuda::setCurrentCUDAStream(GetCUDAStream(gpu, stream_id));
}
}
// Retrieves the CUDAStream corresponding to a logical stream ID, ensuring
// that it exists in cuda_streams_ if it has not been allocated yet.
c10::cuda::CUDAStream GetCUDAStream(DeviceIndex gpu, StreamId stream_id) {
vector<c10::cuda::CUDAStream>& gpu_streams = cuda_streams_[gpu];
while (gpu_streams.size() <= static_cast<size_t>(stream_id)) {
// NB: This streams are not guaranteed to be unique; we'll
// wrap around once we run out of streams in the pool.
gpu_streams.emplace_back(c10::cuda::getStreamFromPool(/* high priority */ false, gpu));
}
return gpu_streams[stream_id];
}
// Uses the logical stream id from the thread local to pick the stream
// We're going to migrate all usages to this case API instead of passing the
// stream id directly
cudaStream_t GetStream(DeviceIndex gpu) {
return c10::cuda::getCurrentCUDAStream(gpu).stream();
}
cudaStream_t GetStream(DeviceIndex gpu, StreamId stream_id) {
return GetCUDAStream(gpu, stream_id).stream();
}
// Uses the logical stream id from the thread local to pick the stream
// We're going to migrate all usages to this case API instead of passing the
// stream id directly
cublasHandle_t GetHandle(DeviceIndex gpu) {
return GetHandle(c10::cuda::getCurrentCUDAStream(gpu));
}
cublasHandle_t GetHandle(c10::cuda::CUDAStream cuda_stream) {
CUDAGuard guard(cuda_stream.device_index());
// Default construct in the map if it doesn't exist, and return a mutable
// reference to it.
auto& r = cublas_handles_[cuda_stream];
if (r == nullptr) {
CUBLAS_ENFORCE(cublasCreate(&r));
// The default is CUBLAS_POINTER_MODE_HOST. You can override
// it after obtaining the cublas handle, but do that with
// caution.
CUBLAS_ENFORCE(cublasSetPointerMode(r, CUBLAS_POINTER_MODE_HOST));
CUBLAS_ENFORCE(cublasSetStream(r, cuda_stream));
}
return r;
}
#ifdef CAFFE2_USE_CUDNN
// Uses the logical stream id from the thread local to pick the stream
// We're going to migrate all usages to this case API instead of passing the
// stream id directly
cudnnHandle_t GetCudnnHandle(DeviceIndex gpu) {
return GetCudnnHandle(c10::cuda::getCurrentCUDAStream(gpu));
}
cudnnHandle_t GetCudnnHandle(c10::cuda::CUDAStream cuda_stream) {
CUDAGuard guard(cuda_stream.device_index());
auto& r = cudnn_handles_[cuda_stream];
if (r == nullptr) {
CUDNN_ENFORCE(cudnnCreate(&r));
CUDNN_ENFORCE(cudnnSetStream(r, cuda_stream));
}
return r;
}
#endif // CAFFE2_USE_CUDNN
~ThreadLocalCUDAObjects() noexcept {
for (auto element : cublas_handles_) {
if (element.second) {
CUBLAS_CHECK(cublasDestroy(element.second));
}
}
#ifdef CAFFE2_USE_CUDNN
for (auto element : cudnn_handles_) {
if (element.second) {
CUDNN_CHECK(cudnnDestroy(element.second));
}
}
#endif // CAFFE2_USE_CUDNN
}
// WARNING: mapping from logical stream ID to c10::cuda::CUDAStream
// is NOT bijective; multiple logical stream IDs may map to the
// same underlying stream ID.
vector<c10::cuda::CUDAStream> cuda_streams_[C10_COMPILE_TIME_MAX_GPUS];
std::unordered_map<c10::cuda::CUDAStream, cublasHandle_t> cublas_handles_;
#ifdef CAFFE2_USE_CUDNN
std::unordered_map<c10::cuda::CUDAStream, cudnnHandle_t> cudnn_handles_;
#endif // CAFFE2_USE_CUDNN
};
class CAFFE2_CUDA_API CUDAContext final : public BaseContext {
public:
// The default cuda context constructor.
explicit CUDAContext(DeviceIndex gpu_id = -1);
explicit CUDAContext(const DeviceOption& option);
explicit CUDAContext(Device device)
: CUDAContext(DeviceToOption(device)) {}
~CUDAContext() override;
inline void SwitchToDevice(StreamId stream_id) override {
getCudaObjects().SetCurrentStreamId(gpu_id_, stream_id);
CaffeCudaSetDevice(gpu_id_);
}
// void SwitchToDevice()
using BaseContext::SwitchToDevice;
inline void WaitEvent(const Event& ev) override {
ev.Wait(CUDA, this);
}
inline void Record(Event* ev, const char* err_msg = nullptr) const override {
CAFFE_ENFORCE(ev, "Event must not be null.");
ev->Record(CUDA, this, err_msg);
}
// Note on current use cases:
// FinishDeviceComputation must be called on the same cpu thread as
// SwitchToDevice()
void FinishDeviceComputation() override {
CUDA_ENFORCE(cudaStreamSynchronize(getCudaObjects().GetStream(gpu_id_)));
cudaError_t error = cudaGetLastError();
if (error != cudaSuccess) {
CAFFE_THROW("Encountered CUDA error: ", cudaGetErrorString(error));
}
}
inline int device_id() const {
return gpu_id_;
}
inline cudaStream_t cuda_stream() const {
return getCudaObjects().GetStream(gpu_id_);
}
static cudaStream_t cuda_stream(DeviceIndex gpu_id, StreamId stream_id) {
return getCudaObjects().GetStream(gpu_id, stream_id);
}
cublasHandle_t cublas_handle() {
return getCudaObjects().GetHandle(gpu_id_);
}
#ifdef CAFFE2_USE_CUDNN
cudnnHandle_t cudnn_handle() {
return getCudaObjects().GetCudnnHandle(gpu_id_);
}
#endif // CAFFE2_USE_CUDNN
curandGenerator_t& curand_generator() {
if (!curand_generator_) {
CUDAGuard guard(gpu_id_);
CURAND_ENFORCE(
curandCreateGenerator(&curand_generator_, CURAND_RNG_PSEUDO_DEFAULT));
CURAND_ENFORCE(
curandSetPseudoRandomGeneratorSeed(curand_generator_, random_seed_));
CHECK_NOTNULL(curand_generator_);
}
CURAND_ENFORCE(curandSetStream(curand_generator_, cuda_stream()));
return curand_generator_;
}
inline static at::DataPtr New(size_t nbytes) {
return GetAllocator(CUDA)->allocate(nbytes);
}
// Get a mutex to lock out cudaMalloc / cudaFree calls when
// NCCL kernels are being launched. Should remove threat of
// deadlocks
static std::mutex& mutex();
// Functions to query memory stats. Only available if flag
// --caffe2_gpu_memory_tracking is enabled.
static std::vector<long> TotalMemoryByGpu();
static std::vector<long> MaxMemoryByGpu();
template <class SrcContext, class DstContext>
inline void CopyBytes(size_t nbytes, const void* src, void* dst) {
CUDA_ENFORCE(cudaMemcpyAsync(
dst,
src,
nbytes,
cudaMemcpyDefault,
getCudaObjects().GetStream(gpu_id_)));
}
void CopyBytesSameDevice(size_t nbytes, const void* src, void* dst) override {
CopyBytes<CUDAContext, CUDAContext>(nbytes, src, dst);
}
void CopyBytesToCPU(size_t nbytes, const void* src, void* dst) override {
CopyBytes<CUDAContext, CPUContext>(nbytes, src, dst);
}
void CopyBytesFromCPU(size_t nbytes, const void* src, void* dst) override {
CopyBytes<CPUContext, CUDAContext>(nbytes, src, dst);
}
template <typename T, class SrcContext, class DstContext>
inline void Copy(int n, const T* src, T* dst) {
CopyBytes<SrcContext, DstContext>(n * sizeof(T),
static_cast<const void*>(src),
static_cast<void*>(dst));
}
template <class SrcContext, class DstContext>
inline void
CopyItems(const TypeMeta meta, size_t n, const void* src, void* dst) {
CAFFE_ENFORCE(!meta.copy(), "CUDAContext requires fundamental types.");
CopyBytes<SrcContext, DstContext>(n * meta.itemsize(), src, dst);
}
static void CopyBytesAsync(
size_t nbytes,
const void* src,
Device src_device,
void* dst,
Device dst_device);
static void CopyBytesSync(
size_t nbytes,
const void* src,
Device src_device,
void* dst,
Device dst_device);
// By default CUDA operators have async device parts
static bool HasAsyncPartDefault() {
return true;
}
static bool SupportsAsyncScheduling() {
return true;
}
static bool IsStreamFree(const DeviceOption& option, StreamId stream_id) {
auto stream = CUDAContext::cuda_stream(option.device_id(), stream_id);
auto status = cudaStreamQuery(stream);
if (status == cudaErrorNotReady) {
// ignore and clear the error if not ready
(void)cudaGetLastError();
}
return status == cudaSuccess;
}
at::Device device() const override {
return at::Device(CUDA, gpu_id_);
}
DeviceType device_type() const override {
return CUDA;
}
static constexpr DeviceType GetDeviceType() {
return CUDA;
}
protected:
int gpu_id_;
int random_seed_;
curandGenerator_t curand_generator_{nullptr};
static ThreadLocalCUDAObjects& getCudaObjects();
};
using TensorCUDA = Tensor;
} // namespace caffe2
#endif // CAFFE2_CORE_CONTEXT_GPU_H_