// Copyright (C) 2015 Davis E. King (davis@dlib.net) // License: Boost Software License See LICENSE.txt for the full license. #ifndef DLIB_GPU_DaTA_H_ #define DLIB_GPU_DaTA_H_ #include "gpu_data_abstract.h" #include #include #include "cuda_errors.h" #include "../serialize.h" namespace dlib { // ---------------------------------------------------------------------------------------- class gpu_data { /*! CONVENTION - if (size() != 0) then - data_host == a pointer to size() floats in CPU memory. - if (data_device) then - data_device == a pointer to size() floats in device memory. - if (there might be an active async transfer from host to device) then - have_active_transfer == true - We use the host_current and device_current bools to keep track of which copy of the data (or both) are most current. e.g. if the CPU has modified the data and it hasn't been copied to the device yet then host_current==true and device_current==false. Similarly, we use device_in_use==true to indicate that device() has been called and no operation to wait for all CUDA kernel completion has been executed. So if device_in_use==true then there might be a CUDA kernel executing that is using the device memory block contained in this object. !*/ public: gpu_data( ) : data_size(0), host_current(true), device_current(true),have_active_transfer(false),device_in_use(false), the_device_id(0) { } // Not copyable gpu_data(const gpu_data&) = delete; gpu_data& operator=(const gpu_data&) = delete; // but is movable gpu_data(gpu_data&& item) : gpu_data() { swap(item); } gpu_data& operator=(gpu_data&& item) { swap(item); return *this; } int device_id() const { return the_device_id; } #ifdef DLIB_USE_CUDA void async_copy_to_device() const; void set_size(size_t new_size); #else // Note that calls to host() or device() will block until any async transfers are complete. void async_copy_to_device() const{} void set_size(size_t new_size) { if (new_size == 0) { data_size = 0; host_current = true; device_current = true; device_in_use = false; data_host.reset(); data_device.reset(); } else if (new_size != data_size) { data_size = new_size; host_current = true; device_current = true; device_in_use = false; data_host.reset(new float[new_size], std::default_delete()); data_device.reset(); } } #endif const float* host() const { copy_to_host(); return data_host.get(); } float* host() { copy_to_host(); device_current = false; return data_host.get(); } float* host_write_only() { host_current = true; device_current = false; return data_host.get(); } const float* device() const { #ifndef DLIB_USE_CUDA DLIB_CASSERT(false, "CUDA NOT ENABLED"); #endif copy_to_device(); device_in_use = true; return data_device.get(); } float* device() { #ifndef DLIB_USE_CUDA DLIB_CASSERT(false, "CUDA NOT ENABLED"); #endif copy_to_device(); host_current = false; device_in_use = true; return data_device.get(); } float* device_write_only() { #ifndef DLIB_USE_CUDA DLIB_CASSERT(false, "CUDA NOT ENABLED"); #endif wait_for_transfer_to_finish(); host_current = false; device_current = true; device_in_use = true; return data_device.get(); } bool host_ready ( ) const { return host_current; } bool device_ready ( ) const { return device_current && !have_active_transfer; } size_t size() const { return data_size; } void swap (gpu_data& item) { std::swap(data_size, item.data_size); std::swap(host_current, item.host_current); std::swap(device_current, item.device_current); std::swap(have_active_transfer, item.have_active_transfer); std::swap(data_host, item.data_host); std::swap(data_device, item.data_device); std::swap(cuda_stream, item.cuda_stream); std::swap(the_device_id, item.the_device_id); } private: #ifdef DLIB_USE_CUDA void copy_to_device() const; void copy_to_host() const; void wait_for_transfer_to_finish() const; #else void copy_to_device() const{} void copy_to_host() const{} void wait_for_transfer_to_finish() const{} #endif size_t data_size; mutable bool host_current; mutable bool device_current; mutable bool have_active_transfer; mutable bool device_in_use; std::shared_ptr data_host; std::shared_ptr data_device; std::shared_ptr cuda_stream; int the_device_id; }; inline void serialize(const gpu_data& item, std::ostream& out) { int version = 1; serialize(version, out); serialize(item.size(), out); auto data = item.host(); for (size_t i = 0; i < item.size(); ++i) serialize(data[i], out); } inline void deserialize(gpu_data& item, std::istream& in) { int version; deserialize(version, in); if (version != 1) throw serialization_error("Unexpected version found while deserializing dlib::gpu_data."); size_t s; deserialize(s, in); item.set_size(s); auto data = item.host(); for (size_t i = 0; i < item.size(); ++i) deserialize(data[i], in); } #ifdef DLIB_USE_CUDA void memcpy (gpu_data& dest, const gpu_data& src); void memcpy ( gpu_data& dest, size_t dest_offset, const gpu_data& src, size_t src_offset, size_t num ); #else inline void memcpy (gpu_data& dest, const gpu_data& src) { DLIB_CASSERT(dest.size() == src.size()); if (src.size() == 0 || &dest == &src) return; std::memcpy(dest.host_write_only(), src.host(), sizeof(float)*src.size()); } inline void memcpy ( gpu_data& dest, size_t dest_offset, const gpu_data& src, size_t src_offset, size_t num ) { DLIB_CASSERT(dest_offset + num <= dest.size()); DLIB_CASSERT(src_offset + num <= src.size()); if (num == 0) return; if (&dest == &src && std::max(dest_offset, src_offset) < std::min(dest_offset,src_offset)+num) { // if they perfectly alias each other then there is nothing to do if (dest_offset == src_offset) return; else std::memmove(dest.host()+dest_offset, src.host()+src_offset, sizeof(float)*num); } else { // if we write to the entire thing then we can use host_write_only() if (dest_offset == 0 && num == dest.size()) std::memcpy(dest.host_write_only(), src.host()+src_offset, sizeof(float)*num); else std::memcpy(dest.host()+dest_offset, src.host()+src_offset, sizeof(float)*num); } } #endif // ---------------------------------------------------------------------------------------- } #endif // DLIB_GPU_DaTA_H_