Lightweight class encapsulating pitched memory on a GPU and passed to nvcc-compiled code (CUDA kernels). Typically, it is used internally by OpenCV and by users who write device code. You can call its members from both host and device code.
template <typename T> struct DevMem2D_
{
int cols;
int rows;
T* data;
size_t step;
DevMem2D_() : cols(0), rows(0), data(0), step(0){};
DevMem2D_(int rows, int cols, T *data, size_t step);
template <typename U>
explicit DevMem2D_(const DevMem2D_<U>& d);
typedef T elem_type;
enum { elem_size = sizeof(elem_type) };
__CV_GPU_HOST_DEVICE__ size_t elemSize() const;
/* returns pointer to the beginning of the given image row */
__CV_GPU_HOST_DEVICE__ T* ptr(int y = 0);
__CV_GPU_HOST_DEVICE__ const T* ptr(int y = 0) const;
};
typedef DevMem2D_<unsigned char> DevMem2D;
typedef DevMem2D_<float> DevMem2Df;
typedef DevMem2D_<int> DevMem2Di;
Structure similar to gpu::DevMem2D_ but containing only a pointer and row step. Width and height fields are excluded due to performance reasons. The structure is intended for internal use or for users who write device code.
template<typename T> struct PtrStep_
{
T* data;
size_t step;
PtrStep_();
PtrStep_(const DevMem2D_<T>& mem);
typedef T elem_type;
enum { elem_size = sizeof(elem_type) };
__CV_GPU_HOST_DEVICE__ size_t elemSize() const;
__CV_GPU_HOST_DEVICE__ T* ptr(int y = 0);
__CV_GPU_HOST_DEVICE__ const T* ptr(int y = 0) const;
};
typedef PtrStep_<unsigned char> PtrStep;
typedef PtrStep_<float> PtrStepf;
typedef PtrStep_<int> PtrStepi;
Structure similar to gpu::DevMem2D_ but containing only a pointer and a row step in elements. Width and height fields are excluded due to performance reasons. This class can only be constructed if sizeof(T) is a multiple of 256. The structure is intended for internal use or for users who write device code.
template<typename T> struct PtrElemStep_ : public PtrStep_<T>
{
PtrElemStep_(const DevMem2D_<T>& mem);
__CV_GPU_HOST_DEVICE__ T* ptr(int y = 0);
__CV_GPU_HOST_DEVICE__ const T* ptr(int y = 0) const;
};
Base storage class for GPU memory with reference counting. Its interface matches the Mat interface with the following limitations:
Beware that the latter limitation may lead to overloaded matrix operators that cause memory allocations. The GpuMat class is convertible to gpu::DevMem2D_ and gpu::PtrStep_ so it can be passed directly to the kernel.
Note
In contrast with Mat, in most cases GpuMat::isContinuous() == false . This means that rows are aligned to a size depending on the hardware. Single-row GpuMat is always a continuous matrix.
class CV_EXPORTS GpuMat
{
public:
//! default constructor
GpuMat();
GpuMat(int rows, int cols, int type);
GpuMat(Size size, int type);
.....
//! builds GpuMat from Mat. Blocks uploading to device.
explicit GpuMat (const Mat& m);
//! returns lightweight DevMem2D_ structure for passing
//to nvcc-compiled code. Contains size, data ptr and step.
template <class T> operator DevMem2D_<T>() const;
template <class T> operator PtrStep_<T>() const;
//! blocks uploading data to GpuMat.
void upload(const cv::Mat& m);
void upload(const CudaMem& m, Stream& stream);
//! downloads data from device to host memory. Blocking calls.
operator Mat() const;
void download(cv::Mat& m) const;
//! download async
void download(CudaMem& m, Stream& stream) const;
};
Note
You are not recommended to leave static or global GpuMat variables allocated, that is, to rely on its destructor. The destruction order of such variables and CUDA context is undefined. GPU memory release function returns error if the CUDA context has been destroyed before.
See also
Class with reference counting wrapping special memory type allocation functions from CUDA. Its interface is also Mat()-like but with additional memory type parameters.
Note
Allocation size of such memory types is usually limited. For more details, see CUDA 2.2 Pinned Memory APIs document or CUDA C Programming Guide.
class CV_EXPORTS CudaMem
{
public:
enum { ALLOC_PAGE_LOCKED = 1, ALLOC_ZEROCOPY = 2,
ALLOC_WRITE_COMBINED = 4 };
CudaMem(Size size, int type, int alloc_type = ALLOC_PAGE_LOCKED);
//! creates from cv::Mat with coping data
explicit CudaMem(const Mat& m, int alloc_type = ALLOC_PAGE_LOCKED);
......
void create(Size size, int type, int alloc_type = ALLOC_PAGE_LOCKED);
//! returns matrix header with disabled ref. counting for CudaMem data.
Mat createMatHeader() const;
operator Mat() const;
//! maps host memory into device address space
GpuMat createGpuMatHeader() const;
operator GpuMat() const;
//if host memory can be mapped to gpu address space;
static bool canMapHostMemory();
int alloc_type;
};
Creates a header without reference counting to gpu::CudaMem data.
Maps CPU memory to GPU address space and creates the gpu::GpuMat header without reference counting for it. This can be done only if memory was allocated with the ALLOC_ZEROCOPY flag and if it is supported by the hardware. Laptops often share video and CPU memory, so address spaces can be mapped, which eliminates an extra copy.
Returns true if the current hardware supports address space mapping and ALLOC_ZEROCOPY memory allocation.
This class encapsulates a queue of asynchronous calls. Some functions have overloads with the additional gpu::Stream parameter. The overloads do initialization work (allocate output buffers, upload constants, and so on), start the GPU kernel, and return before results are ready. You can check whether all operations are complete via gpu::Stream::queryIfComplete(). You can asynchronously upload/download data from/to page-locked buffers, using the gpu::CudaMem or Mat header that points to a region of gpu::CudaMem.
Note
Currently, you may face problems if an operation is enqueued twice with different data. Some functions use the constant GPU memory, and next call may update the memory before the previous one has been finished. But calling different operations asynchronously is safe because each operation has its own constant buffer. Memory copy/upload/download/set operations to the buffers you hold are also safe.
class CV_EXPORTS Stream
{
public:
Stream();
~Stream();
Stream(const Stream&);
Stream& operator=(const Stream&);
bool queryIfComplete();
void waitForCompletion();
//! downloads asynchronously.
// Warning! cv::Mat must point to page locked memory
(i.e. to CudaMem data or to its subMat)
void enqueueDownload(const GpuMat& src, CudaMem& dst);
void enqueueDownload(const GpuMat& src, Mat& dst);
//! uploads asynchronously.
// Warning! cv::Mat must point to page locked memory
(i.e. to CudaMem data or to its ROI)
void enqueueUpload(const CudaMem& src, GpuMat& dst);
void enqueueUpload(const Mat& src, GpuMat& dst);
void enqueueCopy(const GpuMat& src, GpuMat& dst);
void enqueueMemSet(const GpuMat& src, Scalar val);
void enqueueMemSet(const GpuMat& src, Scalar val, const GpuMat& mask);
// converts matrix type, ex from float to uchar depending on type
void enqueueConvert(const GpuMat& src, GpuMat& dst, int type,
double a = 1, double b = 0);
};
Returns true if the current stream queue is finished. Otherwise, it returns false.
Blocks the current CPU thread until all operations in the stream are complete.
Class that enables getting cudaStream_t from gpu::Stream and is declared in stream_accessor.hpp because it is the only public header that depends on the CUDA Runtime API. Including it brings a dependency to your code.
struct StreamAccessor
{
CV_EXPORTS static cudaStream_t getStream(const Stream& stream);
};
Creates a continuous matrix in the GPU memory.
Parameters: |
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The following wrappers are also available:
Matrix is called continuous if its elements are stored continuously, that is, without gaps at the end of each row.
Ensures that the size of a matrix is big enough and the matrix has a proper type. The function does not reallocate memory if the matrix has proper attributes already.
Parameters: |
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