luoyc a9c35a4807 opencv source code commit 1 rok temu
..
hal a9c35a4807 opencv source code commit 1 rok temu
include a9c35a4807 opencv source code commit 1 rok temu
CMakeLists.txt a9c35a4807 opencv source code commit 1 rok temu
README.md a9c35a4807 opencv source code commit 1 rok temu

README.md

C++ wrappers for OpenVX-1.x C API

Core ideas:

  • lightweight - minimal overhead vs standard C API
  • automatic references counting
  • exceptions instead of return codes
  • object-oriented design
  • (NYI) helpers for user-defined kernels & nodes
  • C++ 11 friendly

Quick start sample

The following short sample gives basic knowledges on the wrappers usage:

#include "ivx.hpp"
#include "ivx_lib_debug.hpp" // ivx::debug::*

int main()
{
	vx_uint32 width = 640, height = 480;
	try
	{
		ivx::Context context = ivx::Context::create();
		ivx::Graph graph = ivx::Graph::create(context);
		ivx::Image
		    gray = ivx::Image::create(context, width, height, VX_DF_IMAGE_U8),
		    gb   = ivx::Image::createVirtual(graph),
		    res  = ivx::Image::create(context, width, height, VX_DF_IMAGE_U8);

		context.loadKernels("openvx-debug");  // ivx::debug::*

		ivx::debug::fReadImage(context, inputPath, gray);

		ivx::Node::create(graph, VX_KERNEL_GAUSSIAN_3x3, gray, gb);
		ivx::Node::create(
		    graph,
		    VX_KERNEL_THRESHOLD,
		    gb,
		    ivx::Threshold::createBinary(context, VX_TYPE_UINT8, 50),
		    res
		);

		graph.verify();
		graph.process();

		ivx::debug::fWriteImage(context, res, "ovx-res-cpp.pgm");
    }
    catch (const ivx::RuntimeError& e)
    {
        printf("ErrorRuntime: code = %d(%x), message = %s\n", e.status(), e.status(), e.what());
        return e.status();
    }
    catch (const ivx::WrapperError& e)
    {
        printf("ErrorWrapper: message = %s\n", e.what());
        return -1;
    }
    catch(const std::exception& e)
    {
        printf("runtime_error: message = %s\n", e.what());
        return -1;
    }

    return 0;
}
	

C++ API overview

The wrappers have header-only implementation that simplifies their integration to projects. All the API is inside ivx namespace (E.g. class ivx::Graph).

While the C++ API is pretty much the same for underlying OpenVX version 1.0 and 1.1, there are alternative code branches for some features implementation that are selected at compile time via #ifdef preprocessor directives. E.g. external ref-counting is implemented for 1.0 version and native OpenVX one is used (via vxRetainReference() and vxReleaseXYZ()) for version 1.1.

Also there are some C++ 11 features are used (e.g. rvalue ref-s) when their availability is detected at compile time.

C++ exceptions are used for errors indication instead of return codes. There are two types of exceptions are defined: RuntimeError is thrown when OpenVX C call returned unsuccessful result and WrapperError is thrown when a problem is occured in the wrappers code. Both exception calsses are derived from std::exception (actually from its inheritants).

The so called OpenVX objects (e.g. vx_image) are represented as C++ classes in wrappers. All these classes use automatic ref-counting that allows development of exception-safe code. All these classes have create() or createXYZ() static methods for instances creation. (E.g. Image::create(), Image::createVirtual() and Image::createFromHandle()) Most of the wrapped OpenVX functions are represented as methods of the corresponding C++ classes, but in most cases they still accept C "object" types (e.g. vx_image or vx_context) that allows mixing of C and C++ OpenVX API use. E.g.:

class Image
{
    static Image create(vx_context context, vx_uint32 width, vx_uint32 height, vx_df_image format);
    static Image createVirtual(vx_graph graph, vx_uint32 width = 0, vx_uint32 height = 0, vx_df_image format = VX_DF_IMAGE_VIRT);
    // ...
}

All the classes instances can automatically be converted to the corresponding C "object" types.

For more details please refer to C++ wrappers reference manual or directly to their source code.