fast-yolo4/3rdparty/opencv/inc/opencv2/gapi/gcompiled.hpp
2024-09-25 09:43:03 +08:00

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// This file is part of OpenCV project.
// It is subject to the license terms in the LICENSE file found in the top-level directory
// of this distribution and at http://opencv.org/license.html.
//
// Copyright (C) 2018-2020 Intel Corporation
#ifndef OPENCV_GAPI_GCOMPILED_HPP
#define OPENCV_GAPI_GCOMPILED_HPP
#include <vector>
#include <opencv2/gapi/opencv_includes.hpp>
#include <opencv2/gapi/own/assert.hpp>
#include <opencv2/gapi/garg.hpp>
namespace cv {
// This class represents a compiled computation.
// In theory (and ideally), it can be used w/o the rest of APIs.
// In theory (and ideally), it can be serialized/deserialized.
// It can enable scenarious like deployment to an autonomous devince, FuSa, etc.
//
// Currently GCompiled assumes all GMats you used to pass data to G-API
// are valid and not destroyed while you use a GCompiled object.
//
// FIXME: In future, there should be a way to name I/O objects and specify it
// to GCompiled externally (for example, when it is loaded on the target system).
/**
* \addtogroup gapi_main_classes
* @{
*/
/**
* @brief Represents a compiled computation (graph). Can only be used
* with image / data formats & resolutions it was compiled for, with
* some exceptions.
*
* This class represents a product of graph compilation (calling
* cv::GComputation::compile()). Objects of this class actually do
* data processing, and graph execution is incapsulated into objects
* of this class. Execution model itself depends on kernels and
* backends which were using during the compilation, see @ref
* gapi_compile_args for details.
*
* In a general case, GCompiled objects can be applied to data only in
* that formats/resolutions they were compiled for (see @ref
* gapi_meta_args). However, if the underlying backends allow, a
* compiled object can be _reshaped_ to handle data (images) of
* different resolution, though formats and types must remain the same.
*
* GCompiled is very similar to `std::function<>` in its semantics --
* running it looks like a function call in the user code.
*
* At the moment, GCompiled objects are not reentrant -- generally,
* the objects are stateful since graph execution itself is a stateful
* process and this state is now maintained in GCompiled's own memory
* (not on the process stack).
*
* At the same time, two different GCompiled objects produced from the
* single cv::GComputation are completely independent and can be used
* concurrently.
*
* @sa GStreamingCompiled
*/
class GAPI_EXPORTS GCompiled
{
public:
/// @private
class GAPI_EXPORTS Priv;
/**
* @brief Constructs an empty object
*/
GCompiled();
/**
* @brief Run the compiled computation, a generic version.
*
* @param ins vector of inputs to process.
* @param outs vector of outputs to produce.
*
* Input/output vectors must have the same number of elements as
* defined in the cv::GComputation protocol (at the moment of its
* construction). Shapes of elements also must conform to protocol
* (e.g. cv::Mat needs to be passed where cv::GMat has been
* declared as input, and so on). Run-time exception is generated
* otherwise.
*
* Objects in output vector may remain empty (like cv::Mat) --
* G-API will automatically initialize output objects to proper formats.
*
* @note Don't construct GRunArgs/GRunArgsP objects manually, use
* cv::gin()/cv::gout() wrappers instead.
*/
void operator() (GRunArgs &&ins, GRunArgsP &&outs); // Generic arg-to-arg
#if !defined(GAPI_STANDALONE)
/**
* @brief Execute an unary computation
*
* @overload
* @param in input cv::Mat for unary computation
* @param out output cv::Mat for unary computation
* process.
*/
void operator() (cv::Mat in, cv::Mat &out); // Unary overload
/**
* @brief Execute an unary computation
*
* @overload
* @param in input cv::Mat for unary computation
* @param out output cv::Scalar for unary computation
* process.
*/
void operator() (cv::Mat in, cv::Scalar &out); // Unary overload (scalar)
/**
* @brief Execute a binary computation
*
* @overload
* @param in1 first input cv::Mat for binary computation
* @param in2 second input cv::Mat for binary computation
* @param out output cv::Mat for binary computation
* process.
*/
void operator() (cv::Mat in1, cv::Mat in2, cv::Mat &out); // Binary overload
/**
* @brief Execute an binary computation
*
* @overload
* @param in1 first input cv::Mat for binary computation
* @param in2 second input cv::Mat for binary computation
* @param out output cv::Scalar for binary computation
* process.
*/
void operator() (cv::Mat in1, cv::Mat in2, cv::Scalar &out); // Binary overload (scalar)
/**
* @brief Execute a computation with arbitrary number of
* inputs/outputs.
*
* @overload
* @param ins vector of input cv::Mat objects to process by the
* computation.
* @param outs vector of output cv::Mat objects to produce by the
* computation.
*
* Numbers of elements in ins/outs vectors must match numbers of
* inputs/outputs which were used to define the source GComputation.
*/
void operator() (const std::vector<cv::Mat> &ins, // Compatibility overload
const std::vector<cv::Mat> &outs);
#endif // !defined(GAPI_STANDALONE)
/// @private
Priv& priv();
/**
* @brief Check if compiled object is valid (non-empty)
*
* @return true if the object is runnable (valid), false otherwise
*/
explicit operator bool () const;
/**
* @brief Vector of metadata this graph was compiled for.
*
* @return Unless _reshape_ is not supported, return value is the
* same vector which was passed to cv::GComputation::compile() to
* produce this compiled object. Otherwise, it is the latest
* metadata vector passed to reshape() (if that call was
* successful).
*/
const GMetaArgs& metas() const; // Meta passed to compile()
/**
* @brief Vector of metadata descriptions of graph outputs
*
* @return vector with formats/resolutions of graph's output
* objects, auto-inferred from input metadata vector by
* operations which form this computation.
*
* @note GCompiled objects produced from the same
* cv::GComputiation graph with different input metas may return
* different values in this vector.
*/
const GMetaArgs& outMetas() const;
/**
* @brief Check if the underlying backends support reshape or not.
*
* @return true if supported, false otherwise.
*/
bool canReshape() const;
/**
* @brief Reshape a compiled graph to support new image
* resolutions.
*
* Throws an exception if an error occurs.
*
* @param inMetas new metadata to reshape on. Vector size and
* metadata shapes must match the computation's protocol.
* @param args compilation arguments to use.
*/
// FIXME: Why it requires compile args?
void reshape(const GMetaArgs& inMetas, const GCompileArgs& args);
/**
* @brief Prepare inner kernels states for a new video-stream.
*
* GCompiled objects may be used to process video streams frame by frame.
* In this case, a GCompiled is called on every image frame individually.
* Starting OpenCV 4.4, some kernels in the graph may have their internal
* states (see GAPI_OCV_KERNEL_ST for the OpenCV backend).
* In this case, if user starts processing another video stream with
* this GCompiled, this method needs to be called to let kernels re-initialize
* their internal states to a new video stream.
*/
void prepareForNewStream();
protected:
/// @private
std::shared_ptr<Priv> m_priv;
};
/** @} */
}
#endif // OPENCV_GAPI_GCOMPILED_HPP