fast-yolo4/3rdparty/opencv/inc/opencv2/gapi/gcommon.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_GCOMMON_HPP
#define OPENCV_GAPI_GCOMMON_HPP
#include <functional> // std::hash
#include <vector> // std::vector
#include <type_traits> // decay
#include <opencv2/gapi/opencv_includes.hpp>
#include <opencv2/gapi/util/any.hpp>
#include <opencv2/gapi/util/optional.hpp>
#include <opencv2/gapi/own/exports.hpp>
#include <opencv2/gapi/own/assert.hpp>
#include <opencv2/gapi/render/render_types.hpp>
#include <opencv2/gapi/s11n/base.hpp>
namespace cv {
class GMat; // FIXME: forward declaration for GOpaqueTraits
namespace detail
{
// This is a trait-like structure to mark backend-specific compile arguments
// with tags
template<typename T> struct CompileArgTag;
// These structures are tags which separate kernels and transformations
struct KernelTag
{};
struct TransformTag
{};
// This enum is utilized mostly by GArray and GOpaque to store and recognize their internal data
// types (aka Host type). Also it is widely used during serialization routine.
enum class OpaqueKind: int
{
CV_UNKNOWN, // Unknown, generic, opaque-to-GAPI data type unsupported in graph seriallization
CV_BOOL, // bool user G-API data
CV_INT, // int user G-API data
CV_INT64, // int64_t user G-API data
CV_DOUBLE, // double user G-API data
CV_FLOAT, // float user G-API data
CV_UINT64, // uint64_t user G-API data
CV_STRING, // std::string user G-API data
CV_POINT, // cv::Point user G-API data
CV_POINT2F, // cv::Point2f user G-API data
CV_SIZE, // cv::Size user G-API data
CV_RECT, // cv::Rect user G-API data
CV_SCALAR, // cv::Scalar user G-API data
CV_MAT, // cv::Mat user G-API data
CV_DRAW_PRIM, // cv::gapi::wip::draw::Prim user G-API data
};
// Type traits helper which simplifies the extraction of kind from type
template<typename T> struct GOpaqueTraits;
template<typename T> struct GOpaqueTraits { static constexpr const OpaqueKind kind = OpaqueKind::CV_UNKNOWN; };
template<> struct GOpaqueTraits<int> { static constexpr const OpaqueKind kind = OpaqueKind::CV_INT; };
template<> struct GOpaqueTraits<int64_t> { static constexpr const OpaqueKind kind = OpaqueKind::CV_INT64; };
template<> struct GOpaqueTraits<double> { static constexpr const OpaqueKind kind = OpaqueKind::CV_DOUBLE; };
template<> struct GOpaqueTraits<float> { static constexpr const OpaqueKind kind = OpaqueKind::CV_FLOAT; };
template<> struct GOpaqueTraits<uint64_t> { static constexpr const OpaqueKind kind = OpaqueKind::CV_UINT64; };
template<> struct GOpaqueTraits<bool> { static constexpr const OpaqueKind kind = OpaqueKind::CV_BOOL; };
template<> struct GOpaqueTraits<std::string> { static constexpr const OpaqueKind kind = OpaqueKind::CV_STRING; };
template<> struct GOpaqueTraits<cv::Size> { static constexpr const OpaqueKind kind = OpaqueKind::CV_SIZE; };
template<> struct GOpaqueTraits<cv::Scalar> { static constexpr const OpaqueKind kind = OpaqueKind::CV_SCALAR; };
template<> struct GOpaqueTraits<cv::Point> { static constexpr const OpaqueKind kind = OpaqueKind::CV_POINT; };
template<> struct GOpaqueTraits<cv::Point2f> { static constexpr const OpaqueKind kind = OpaqueKind::CV_POINT2F; };
template<> struct GOpaqueTraits<cv::Mat> { static constexpr const OpaqueKind kind = OpaqueKind::CV_MAT; };
template<> struct GOpaqueTraits<cv::Rect> { static constexpr const OpaqueKind kind = OpaqueKind::CV_RECT; };
template<> struct GOpaqueTraits<cv::GMat> { static constexpr const OpaqueKind kind = OpaqueKind::CV_MAT; };
template<> struct GOpaqueTraits<cv::gapi::wip::draw::Prim>
{ static constexpr const OpaqueKind kind = OpaqueKind::CV_DRAW_PRIM; };
using GOpaqueTraitsArrayTypes = std::tuple<int, double, float, uint64_t, bool, std::string, cv::Size, cv::Scalar, cv::Point, cv::Point2f,
cv::Mat, cv::Rect, cv::gapi::wip::draw::Prim>;
// GOpaque is not supporting cv::Mat and cv::Scalar since there are GScalar and GMat types
using GOpaqueTraitsOpaqueTypes = std::tuple<int, double, float, uint64_t, bool, std::string, cv::Size, cv::Point, cv::Point2f, cv::Rect,
cv::gapi::wip::draw::Prim>;
} // namespace detail
// This definition is here because it is reused by both public(?) and internal
// modules. Keeping it here wouldn't expose public details (e.g., API-level)
// to components which are internal and operate on a lower-level entities
// (e.g., compiler, backends).
// FIXME: merge with ArgKind?
// FIXME: replace with variant[format desc]?
enum class GShape: int
{
GMAT,
GSCALAR,
GARRAY,
GOPAQUE,
GFRAME,
};
namespace gapi {
namespace s11n {
namespace detail {
template<typename T> struct wrap_serialize;
} // namespace detail
} // namespace s11n
} // namespace gapi
struct GCompileArg;
namespace detail {
template<typename T>
using is_compile_arg = std::is_same<GCompileArg, typename std::decay<T>::type>;
} // namespace detail
// CompileArg is an unified interface over backend-specific compilation
// information
// FIXME: Move to a separate file?
/** \addtogroup gapi_compile_args
* @{
*
* @brief Compilation arguments: data structures controlling the
* compilation process
*
* G-API comes with a number of graph compilation options which can be
* passed to cv::GComputation::apply() or
* cv::GComputation::compile(). Known compilation options are listed
* in this page, while extra backends may introduce their own
* compilation options (G-API transparently accepts _everything_ which
* can be passed to cv::compile_args(), it depends on underlying
* backends if an option would be interpreted or not).
*
* For example, if an example computation is executed like this:
*
* @snippet samples/cpp/tutorial_code/gapi/doc_snippets/api_ref_snippets.cpp graph_decl_apply
*
* Extra parameter specifying which kernels to compile with can be
* passed like this:
*
* @snippet samples/cpp/tutorial_code/gapi/doc_snippets/api_ref_snippets.cpp apply_with_param
*/
/**
* @brief Represents an arbitrary compilation argument.
*
* Any value can be wrapped into cv::GCompileArg, but only known ones
* (to G-API or its backends) can be interpreted correctly.
*
* Normally objects of this class shouldn't be created manually, use
* cv::compile_args() function which automatically wraps everything
* passed in (a variadic template parameter pack) into a vector of
* cv::GCompileArg objects.
*/
struct GCompileArg
{
public:
// NB: Required for pythnon bindings
GCompileArg() = default;
std::string tag;
// FIXME: use decay in GArg/other trait-based wrapper before leg is shot!
template<typename T, typename std::enable_if<!detail::is_compile_arg<T>::value, int>::type = 0>
explicit GCompileArg(T &&t)
: tag(detail::CompileArgTag<typename std::decay<T>::type>::tag())
, serializeF(cv::gapi::s11n::detail::has_S11N_spec<T>::value ?
&cv::gapi::s11n::detail::wrap_serialize<T>::serialize :
nullptr)
, arg(t)
{
}
template<typename T> T& get()
{
return util::any_cast<T>(arg);
}
template<typename T> const T& get() const
{
return util::any_cast<T>(arg);
}
void serialize(cv::gapi::s11n::IOStream& os) const
{
if (serializeF)
{
serializeF(os, *this);
}
}
private:
std::function<void(cv::gapi::s11n::IOStream&, const GCompileArg&)> serializeF;
util::any arg;
};
using GCompileArgs = std::vector<GCompileArg>;
inline cv::GCompileArgs& operator += ( cv::GCompileArgs &lhs,
const cv::GCompileArgs &rhs)
{
lhs.reserve(lhs.size() + rhs.size());
lhs.insert(lhs.end(), rhs.begin(), rhs.end());
return lhs;
}
/**
* @brief Wraps a list of arguments (a parameter pack) into a vector of
* compilation arguments (cv::GCompileArg).
*/
template<typename... Ts> GCompileArgs compile_args(Ts&&... args)
{
return GCompileArgs{ GCompileArg(args)... };
}
namespace gapi
{
/**
* @brief Retrieves particular compilation argument by its type from
* cv::GCompileArgs
*/
template<typename T>
inline cv::util::optional<T> getCompileArg(const cv::GCompileArgs &args)
{
for (auto &compile_arg : args)
{
if (compile_arg.tag == cv::detail::CompileArgTag<T>::tag())
{
return cv::util::optional<T>(compile_arg.get<T>());
}
}
return cv::util::optional<T>();
}
namespace s11n {
namespace detail {
template<typename T> struct wrap_serialize
{
static void serialize(IOStream& os, const GCompileArg& arg)
{
using DT = typename std::decay<T>::type;
S11N<DT>::serialize(os, arg.get<DT>());
}
};
} // namespace detail
} // namespace s11n
} // namespace gapi
/**
* @brief Ask G-API to dump compiled graph in Graphviz format under
* the given file name.
*
* Specifies a graph dump path (path to .dot file to be generated).
* G-API will dump a .dot file under specified path during a
* compilation process if this flag is passed.
*/
struct graph_dump_path
{
std::string m_dump_path;
};
/** @} */
namespace detail
{
template<> struct CompileArgTag<cv::graph_dump_path>
{
static const char* tag() { return "gapi.graph_dump_path"; }
};
}
} // namespace cv
// std::hash overload for GShape
namespace std
{
template<> struct hash<cv::GShape>
{
size_t operator() (cv::GShape sh) const
{
return std::hash<int>()(static_cast<int>(sh));
}
};
} // namespace std
#endif // OPENCV_GAPI_GCOMMON_HPP