// 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) 2016, Intel Corporation, all rights reserved.
// Third party copyrights are property of their respective owners.
/*
C + + wrappers over OpenVX 1. x C API
Details : TBD
*/
# pragma once
# ifndef IVX_HPP
# define IVX_HPP
# ifndef __cplusplus
# error This file has to be compiled with C++ compiler
# endif
# include <VX/vx.h>
# include <VX/vxu.h>
# ifndef IVX_USE_CXX98
// checking compiler
# if __cplusplus < 201103L && (!defined(_MSC_VER) || _MSC_VER < 1800)
# define IVX_USE_CXX98
# endif
# endif // IVX_USE_CXX98
# if defined(IVX_USE_CXX98) && !defined(IVX_HIDE_INFO_WARNINGS)
# ifdef _MSC_VER
# pragma message ("ivx.hpp: The ISO C++ 2011 standard is not enabled, switching to C++98 fallback implementation.")
# else
# warning The ISO C++ 2011 standard is not enabled, switching to C++98 fallback implementation.
# endif
# endif // IVX_USE_CXX98
# ifndef IVX_USE_EXTERNAL_REFCOUNT
// checking OpenVX version
# ifndef VX_VERSION_1_1
# define IVX_USE_EXTERNAL_REFCOUNT
# endif
# endif // IVX_USE_CXX98
# if defined(IVX_USE_EXTERNAL_REFCOUNT) && !defined(IVX_HIDE_INFO_WARNINGS)
# ifdef _MSC_VER
# pragma message ("ivx.hpp: OpenVX version < 1.1, switching to external refcounter implementation.")
# else
# warning OpenVX version < 1.1, switching to external refcounter implementation.
# endif
# endif // IVX_USE_EXTERNAL_REFCOUNT
# include <stdexcept>
# include <utility>
# include <string>
# include <vector>
# ifndef IVX_USE_CXX98
# include <type_traits>
namespace ivx
{
using std : : is_same ;
using std : : is_pointer ;
}
# else
namespace ivx
{
// helpers for compile-time type checking
template < typename , typename > struct is_same { static const bool value = false ; } ;
template < typename T > struct is_same < T , T > { static const bool value = true ; } ;
template < typename T > struct is_pointer { static const bool value = false ; } ;
template < typename T > struct is_pointer < T * > { static const bool value = true ; } ;
template < typename T > struct is_pointer < const T * > { static const bool value = true ; } ;
}
# endif
# ifdef IVX_USE_OPENCV
# include "opencv2/core.hpp"
# endif
// disabling false alarm warnings
# if defined(_MSC_VER)
# pragma warning(push)
//#pragma warning( disable : 4??? )
# elif defined(__clang__)
# pragma clang diagnostic push
# pragma clang diagnostic ignored "-Wunused-local-typedef"
# pragma clang diagnostic ignored "-Wmissing-prototypes"
# elif defined(__GNUC__)
# pragma GCC diagnostic push
# pragma GCC diagnostic ignored "-Wunused-local-typedefs"
# pragma GCC diagnostic ignored "-Wunused-value"
# pragma GCC diagnostic ignored "-Wmissing-declarations"
# endif // compiler macro
namespace ivx
{
/// Exception class for OpenVX runtime errors
class RuntimeError : public std : : runtime_error
{
public :
/// Constructor
explicit RuntimeError ( vx_status st , const std : : string & msg = " " )
: runtime_error ( msg ) , _status ( st )
{ }
/// OpenVX error code
vx_status status ( ) const
{ return _status ; }
private :
vx_status _status ;
} ;
/// Exception class for wrappers logic errors
class WrapperError : public std : : logic_error
{
public :
/// Constructor
explicit WrapperError ( const std : : string & msg ) : logic_error ( msg )
{ }
} ;
inline void checkVxStatus ( vx_status status , const std : : string & func , const std : : string & msg )
{
if ( status ! = VX_SUCCESS ) throw RuntimeError ( status , func + " () : " + msg ) ;
}
/// Helper macro for turning a runtime error in the provided code into a \RuntimeError
# define IVX_CHECK_STATUS(code) checkVxStatus(code, __func__, #code)
/// OpenVX enum to type compile-time converter (TODO: add more types)
template < vx_enum E > struct EnumToType { } ;
template < > struct EnumToType < VX_TYPE_CHAR > { typedef vx_char type ; static const vx_size bytes = sizeof ( type ) ; } ;
template < > struct EnumToType < VX_TYPE_INT8 > { typedef vx_int8 type ; static const vx_size bytes = sizeof ( type ) ; } ;
template < > struct EnumToType < VX_TYPE_UINT8 > { typedef vx_uint8 type ; static const vx_size bytes = sizeof ( type ) ; } ;
template < > struct EnumToType < VX_TYPE_INT16 > { typedef vx_int16 type ; static const vx_size bytes = sizeof ( type ) ; } ;
template < > struct EnumToType < VX_TYPE_UINT16 > { typedef vx_uint16 type ; static const vx_size bytes = sizeof ( type ) ; } ;
template < > struct EnumToType < VX_TYPE_INT32 > { typedef vx_int32 type ; static const vx_size bytes = sizeof ( type ) ; } ;
template < > struct EnumToType < VX_TYPE_UINT32 > { typedef vx_uint32 type ; static const vx_size bytes = sizeof ( type ) ; } ;
template < > struct EnumToType < VX_TYPE_INT64 > { typedef vx_int64 type ; static const vx_size bytes = sizeof ( type ) ; } ;
template < > struct EnumToType < VX_TYPE_UINT64 > { typedef vx_uint64 type ; static const vx_size bytes = sizeof ( type ) ; } ;
template < > struct EnumToType < VX_TYPE_FLOAT32 > { typedef vx_float32 type ; static const vx_size bytes = sizeof ( type ) ; } ;
template < > struct EnumToType < VX_TYPE_FLOAT64 > { typedef vx_float64 type ; static const vx_size bytes = sizeof ( type ) ; } ;
template < > struct EnumToType < VX_TYPE_ENUM > { typedef vx_enum type ; static const vx_size bytes = sizeof ( type ) ; } ;
template < > struct EnumToType < VX_TYPE_SIZE > { typedef vx_size type ; static const vx_size bytes = sizeof ( type ) ; } ;
template < > struct EnumToType < VX_TYPE_DF_IMAGE > { typedef vx_df_image type ; static const vx_size bytes = sizeof ( type ) ; } ;
template < > struct EnumToType < VX_TYPE_BOOL > { typedef vx_bool type ; static const vx_size bytes = sizeof ( type ) ; } ;
template < > struct EnumToType < VX_TYPE_KEYPOINT > { typedef vx_keypoint_t type ; static const vx_size bytes = sizeof ( type ) ; } ;
# ifndef IVX_USE_CXX98
template < vx_enum E > using EnumToType_t = typename EnumToType < E > : : type ;
# endif
/// Gets size in bytes for the provided OpenVX type enum
inline vx_size enumToTypeSize ( vx_enum type )
{
switch ( type )
{
case VX_TYPE_CHAR : return EnumToType < VX_TYPE_CHAR > : : bytes ;
case VX_TYPE_INT8 : return EnumToType < VX_TYPE_INT8 > : : bytes ;
case VX_TYPE_UINT8 : return EnumToType < VX_TYPE_UINT8 > : : bytes ;
case VX_TYPE_INT16 : return EnumToType < VX_TYPE_INT16 > : : bytes ;
case VX_TYPE_UINT16 : return EnumToType < VX_TYPE_UINT16 > : : bytes ;
case VX_TYPE_INT32 : return EnumToType < VX_TYPE_INT32 > : : bytes ;
case VX_TYPE_UINT32 : return EnumToType < VX_TYPE_UINT32 > : : bytes ;
case VX_TYPE_INT64 : return EnumToType < VX_TYPE_INT64 > : : bytes ;
case VX_TYPE_UINT64 : return EnumToType < VX_TYPE_UINT64 > : : bytes ;
case VX_TYPE_FLOAT32 : return EnumToType < VX_TYPE_FLOAT32 > : : bytes ;
case VX_TYPE_FLOAT64 : return EnumToType < VX_TYPE_FLOAT64 > : : bytes ;
case VX_TYPE_ENUM : return EnumToType < VX_TYPE_ENUM > : : bytes ;
case VX_TYPE_SIZE : return EnumToType < VX_TYPE_SIZE > : : bytes ;
case VX_TYPE_DF_IMAGE : return EnumToType < VX_TYPE_DF_IMAGE > : : bytes ;
case VX_TYPE_BOOL : return EnumToType < VX_TYPE_BOOL > : : bytes ;
case VX_TYPE_KEYPOINT : return EnumToType < VX_TYPE_KEYPOINT > : : bytes ;
default : throw WrapperError ( std : : string ( __func__ ) + " : unsupported type enum " ) ;
}
}
/// type to enum compile-time converter (TODO: add more types)
template < typename T > struct TypeToEnum { } ;
template < > struct TypeToEnum < vx_char > { static const vx_enum value = VX_TYPE_CHAR ; } ;
template < > struct TypeToEnum < vx_int8 > { static const vx_enum value = VX_TYPE_INT8 ; } ;
template < > struct TypeToEnum < vx_uint8 > { static const vx_enum value = VX_TYPE_UINT8 ; } ;
template < > struct TypeToEnum < vx_int16 > { static const vx_enum value = VX_TYPE_INT16 ; } ;
template < > struct TypeToEnum < vx_uint16 > { static const vx_enum value = VX_TYPE_UINT16 ; } ;
template < > struct TypeToEnum < vx_int32 > { static const vx_enum value = VX_TYPE_INT32 ; } ;
template < > struct TypeToEnum < vx_uint32 > { static const vx_enum value = VX_TYPE_UINT32 ; } ;
template < > struct TypeToEnum < vx_int64 > { static const vx_enum value = VX_TYPE_INT64 ; } ;
template < > struct TypeToEnum < vx_uint64 > { static const vx_enum value = VX_TYPE_UINT64 ; } ;
template < > struct TypeToEnum < vx_float32 > { static const vx_enum value = VX_TYPE_FLOAT32 ; } ;
template < > struct TypeToEnum < vx_float64 > { static const vx_enum value = VX_TYPE_FLOAT64 ; } ;
template < > struct TypeToEnum < vx_bool > { static const vx_enum value = VX_TYPE_BOOL ; } ;
template < > struct TypeToEnum < vx_keypoint_t > { static const vx_enum value = VX_TYPE_KEYPOINT ; } ;
// the commented types are aliases (of integral tyes) and have conflicts with the types above
//template<> struct TypeToEnum<vx_enum> { static const vx_enum val = VX_TYPE_ENUM; };
//template<> struct TypeToEnum<vx_size> { static const vx_enum val = VX_TYPE_SIZE; };
//template<> struct TypeToEnum<vx_df_image> { static const vx_enum val = VX_TYPE_DF_IMAGE; };
inline bool areTypesCompatible ( const vx_enum a , const vx_enum b )
{
return enumToTypeSize ( a ) = = enumToTypeSize ( b ) ;
}
# ifdef IVX_USE_OPENCV
inline int enumToCVType ( vx_enum type )
{
switch ( type )
{
case VX_TYPE_CHAR : return CV_8UC1 ; //While OpenCV support 8S as well, 8U is supported wider
case VX_TYPE_INT8 : return CV_8SC1 ;
case VX_TYPE_UINT8 : return CV_8UC1 ;
case VX_TYPE_INT16 : return CV_16SC1 ;
case VX_TYPE_UINT16 : return CV_16UC1 ;
case VX_TYPE_INT32 : return CV_32SC1 ;
case VX_TYPE_UINT32 : return CV_32SC1 ; //That's not the best option but there is CV_32S type only
case VX_TYPE_FLOAT32 : return CV_32FC1 ;
case VX_TYPE_FLOAT64 : return CV_64FC1 ;
case VX_TYPE_ENUM : return CV_32SC1 ;
case VX_TYPE_BOOL : return CV_32SC1 ;
default : throw WrapperError ( std : : string ( __func__ ) + " : unsupported type enum " ) ;
}
}
# endif
/// Helper type, provides info for OpenVX 'objects' (vx_reference extending) types
template < typename T > struct RefTypeTraits { } ;
class Context ;
template < > struct RefTypeTraits < vx_context >
{
typedef vx_context vxType ;
typedef Context wrapperType ;
static const vx_enum vxTypeEnum = VX_TYPE_CONTEXT ;
static vx_status release ( vxType & ref ) { return vxReleaseContext ( & ref ) ; }
} ;
class Graph ;
template < > struct RefTypeTraits < vx_graph >
{
typedef vx_graph vxType ;
typedef Graph wrapperType ;
static const vx_enum vxTypeEnum = VX_TYPE_GRAPH ;
static vx_status release ( vxType & ref ) { return vxReleaseGraph ( & ref ) ; }
} ;
class Node ;
template < > struct RefTypeTraits < vx_node >
{
typedef vx_node vxType ;
typedef Node wrapperType ;
static const vx_enum vxTypeEnum = VX_TYPE_NODE ;
static vx_status release ( vxType & ref ) { return vxReleaseNode ( & ref ) ; }
} ;
class Kernel ;
template < > struct RefTypeTraits < vx_kernel >
{
typedef vx_kernel vxType ;
typedef Kernel wrapperType ;
static const vx_enum vxTypeEnum = VX_TYPE_KERNEL ;
static vx_status release ( vxType & ref ) { return vxReleaseKernel ( & ref ) ; }
} ;
class Param ;
template < > struct RefTypeTraits < vx_parameter >
{
typedef vx_parameter vxType ;
typedef Param wrapperType ;
static const vx_enum vxTypeEnum = VX_TYPE_PARAMETER ;
static vx_status release ( vxType & ref ) { return vxReleaseParameter ( & ref ) ; }
} ;
class Image ;
template < > struct RefTypeTraits < vx_image >
{
typedef vx_image vxType ;
typedef Image wrapperType ;
static const vx_enum vxTypeEnum = VX_TYPE_IMAGE ;
static vx_status release ( vxType & ref ) { return vxReleaseImage ( & ref ) ; }
} ;
class Scalar ;
template < > struct RefTypeTraits < vx_scalar >
{
typedef vx_scalar vxType ;
typedef Scalar wrapperType ;
static const vx_enum vxTypeEnum = VX_TYPE_SCALAR ;
static vx_status release ( vxType & ref ) { return vxReleaseScalar ( & ref ) ; }
} ;
class Array ;
template < > struct RefTypeTraits < vx_array >
{
typedef vx_array vxType ;
typedef Array wrapperType ;
static const vx_enum vxTypeEnum = VX_TYPE_ARRAY ;
static vx_status release ( vxType & ref ) { return vxReleaseArray ( & ref ) ; }
} ;
class Threshold ;
template < > struct RefTypeTraits < vx_threshold >
{
typedef vx_threshold vxType ;
typedef Threshold wrapperType ;
static const vx_enum vxTypeEnum = VX_TYPE_THRESHOLD ;
static vx_status release ( vxType & ref ) { return vxReleaseThreshold ( & ref ) ; }
} ;
class Convolution ;
template < > struct RefTypeTraits < vx_convolution >
{
typedef vx_convolution vxType ;
typedef Convolution wrapperType ;
static const vx_enum vxTypeEnum = VX_TYPE_CONVOLUTION ;
static vx_status release ( vxType & ref ) { return vxReleaseConvolution ( & ref ) ; }
} ;
class Matrix ;
template < > struct RefTypeTraits < vx_matrix >
{
typedef vx_matrix vxType ;
typedef Matrix wrapperType ;
static const vx_enum vxTypeEnum = VX_TYPE_MATRIX ;
static vx_status release ( vxType & ref ) { return vxReleaseMatrix ( & ref ) ; }
} ;
class LUT ;
template < > struct RefTypeTraits < vx_lut >
{
typedef vx_lut vxType ;
typedef LUT wrapperType ;
static const vx_enum vxTypeEnum = VX_TYPE_LUT ;
static vx_status release ( vxType & ref ) { return vxReleaseLUT ( & ref ) ; }
} ;
# ifdef IVX_USE_CXX98
/// Casting to vx_reference with compile-time check
// takes 'vx_reference' itself and RefWrapper<T> via 'operator vx_reference()'
inline vx_reference castToReference ( vx_reference ref )
{ return ref ; }
// takes vx_reference extensions that have RefTypeTraits<T> specializations
template < typename T >
inline vx_reference castToReference ( const T & ref , typename RefTypeTraits < T > : : vxType dummy = 0 )
{ ( void ) dummy ; return ( vx_reference ) ref ; }
# else
template < typename T , typename = void >
struct is_ref : std : : is_same < T , vx_reference > { } ; // allow vx_reference
// allow RefWrapper<> types
template < typename T >
# ifndef _MSC_VER
struct is_ref < T , decltype ( T ( ) . operator vx_reference ( ) , void ( ) ) > : std : : true_type { } ;
# else
// workarounding VC14 compiler crash
struct is_ref < T , decltype ( T : : vxType ( ) , void ( ) ) > : std : : true_type { } ;
# endif
// allow vx_reference extensions
template < typename T >
struct is_ref < T , decltype ( RefTypeTraits < T > : : vxTypeEnum , void ( ) ) > : std : : true_type { } ;
/// Casting to vx_reference with compile-time check
template < typename T >
inline vx_reference castToReference ( const T & obj )
{
static_assert ( is_ref < T > : : value , " unsupported conversion " ) ;
return ( vx_reference ) obj ;
}
# endif // IVX_USE_CXX98
inline void checkVxRef ( vx_reference ref , const std : : string & func , const std : : string & msg )
{
vx_status status = vxGetStatus ( ref ) ;
if ( status ! = VX_SUCCESS ) throw RuntimeError ( status , func + " () : " + msg ) ;
}
/// Helper macro for checking the provided OpenVX 'object' and throwing a \RuntimeError in case of error
# define IVX_CHECK_REF(code) checkVxRef(castToReference(code), __func__, #code)
# ifdef IVX_USE_EXTERNAL_REFCOUNT
/// Base class for OpenVX 'objects' wrappers
template < typename T > class RefWrapper
{
public :
typedef T vxType ;
static const vx_enum vxTypeEnum = RefTypeTraits < T > : : vxTypeEnum ;
/// Default constructor
RefWrapper ( ) : ref ( 0 ) , refcount ( 0 )
{ }
/// Constructor
/// \param r OpenVX 'object' (e.g. vx_image)
/// \param retainRef flag indicating whether to increase ref counter in constructor (false by default)
explicit RefWrapper ( T r , bool retainRef = false ) : ref ( 0 ) , refcount ( 0 )
{ reset ( r , retainRef ) ; }
/// Copy constructor
RefWrapper ( const RefWrapper & r ) : ref ( r . ref ) , refcount ( r . refcount )
{ addRef ( ) ; }
# ifndef IVX_USE_CXX98
/// Move constructor
RefWrapper ( RefWrapper & & rw ) noexcept : RefWrapper ( )
{
using std : : swap ;
swap ( ref , rw . ref ) ;
swap ( refcount , rw . refcount ) ;
}
# endif
/// Casting to the wrapped OpenVX 'object'
operator T ( ) const
{ return ref ; }
/// Casting to vx_reference since every OpenVX 'object' extends it
operator vx_reference ( ) const
{ return castToReference ( ref ) ; }
/// Assigning a new value (decreasing ref counter for the old one)
/// \param r OpenVX 'object' (e.g. vx_image)
/// \param retainRef flag indicating whether to increase ref counter in constructor (false by default)
void reset ( T r , bool retainRef = false )
{
release ( ) ;
ref = r ;
# ifdef VX_VERSION_1_1
if ( retainRef ) addRef ( ) ;
# else
// if 'retainRef' -just don't use ref-counting for v 1.0
if ( ! retainRef ) refcount = new int ( 1 ) ;
# endif
checkRef ( ) ;
}
/// Assigning an empty value (decreasing ref counter for the old one)
void reset ( )
{ release ( ) ; }
/// Dropping kept value without releas decreasing ref counter
/// \return the value being dropped
T detach ( )
{
T tmp = ref ;
ref = 0 ;
release ( ) ;
return tmp ;
}
/// Unified assignment operator (covers both copy and move cases)
RefWrapper & operator = ( RefWrapper r )
{
using std : : swap ;
swap ( ref , r . ref ) ;
swap ( refcount , r . refcount ) ;
return * this ;
}
/// Checking for non-empty
bool operator ! ( ) const
{ return ref = = 0 ; }
# ifndef IVX_USE_CXX98
/// Explicit boolean evaluation (called automatically inside conditional operators only)
explicit operator bool ( ) const
{ return ref ! = 0 ; }
# endif
/// Getting a context that is kept in each OpenVX 'object' (call get<Context>())
template < typename C >
C get ( ) const
{
typedef int static_assert_context [ is_same < C , Context > : : value ? 1 : - 1 ] ;
vx_context c = vxGetContext ( castToReference ( ref ) ) ;
// vxGetContext doesn't increment ref count, let do it in wrapper c-tor
return C ( c , true ) ;
}
# ifndef IVX_USE_CXX98
/// Getting a context that is kept in each OpenVX 'object'
template < typename C = Context , typename = typename std : : enable_if < std : : is_same < C , Context > : : value > : : type >
C getContext ( ) const
{
vx_context c = vxGetContext ( castToReference ( ref ) ) ;
// vxGetContext doesn't increment ref count, let do it in wrapper c-tor
return C ( c , true ) ;
}
# endif // IVX_USE_CXX98
protected :
T ref ;
int * refcount ;
void addRef ( )
{
# ifdef VX_VERSION_1_1
if ( ref ) IVX_CHECK_STATUS ( vxRetainReference ( castToReference ( ref ) ) ) ;
# else //TODO: make thread-safe
if ( refcount ) + + ( * refcount ) ;
# endif
}
void release ( )
{
# ifdef VX_VERSION_1_1
if ( ref ) RefTypeTraits < T > : : release ( ref ) ;
# else //TODO: make thread-safe
if ( refcount & & - - ( * refcount ) = = 0 )
{
if ( ref ) RefTypeTraits < T > : : release ( ref ) ;
ref = 0 ;
delete refcount ;
refcount = 0 ;
}
# endif
}
void checkRef ( ) const
{
IVX_CHECK_REF ( ref ) ;
vx_enum type ;
IVX_CHECK_STATUS ( vxQueryReference ( ( vx_reference ) ref , VX_REF_ATTRIBUTE_TYPE , & type , sizeof ( type ) ) ) ;
if ( type ! = vxTypeEnum ) throw WrapperError ( " incompatible reference type " ) ;
}
~ RefWrapper ( )
{ release ( ) ; }
} ;
# ifdef IVX_USE_CXX98
# define IVX_REF_STD_CTORS_AND_ASSIGNMENT(Class) \
Class ( ) : RefWrapper ( ) { } \
explicit Class ( Class : : vxType _ref , bool retainRef = false ) : RefWrapper ( _ref , retainRef ) { } \
Class ( const Class & _obj ) : RefWrapper ( _obj ) { } \
\
Class & operator = ( Class _obj ) { using std : : swap ; swap ( ref , _obj . ref ) ; swap ( refcount , _obj . refcount ) ; return * this ; }
# else
# define IVX_REF_STD_CTORS_AND_ASSIGNMENT(Class) \
Class ( ) : RefWrapper ( ) { } \
explicit Class ( Class : : vxType _ref , bool retainRef = false ) : RefWrapper ( _ref , retainRef ) { } \
Class ( const Class & _obj ) : RefWrapper ( _obj ) { } \
Class ( Class & & _obj ) : RefWrapper ( std : : move ( _obj ) ) { } \
\
Class & operator = ( Class _obj ) { using std : : swap ; swap ( ref , _obj . ref ) ; swap ( refcount , _obj . refcount ) ; return * this ; }
# endif // IVX_USE_CXX98
# else // not IVX_USE_EXTERNAL_REFCOUNT
/// Base class for OpenVX 'objects' wrappers
template < typename T > class RefWrapper
{
public :
typedef T vxType ;
static const vx_enum vxTypeEnum = RefTypeTraits < T > : : vxTypeEnum ;
/// Default constructor
RefWrapper ( ) : ref ( 0 )
{ }
/// Constructor
/// \param r OpenVX 'object' (e.g. vx_image)
/// \param retainRef flag indicating whether to increase ref counter in constructor (false by default)
explicit RefWrapper ( T r , bool retainRef = false ) : ref ( 0 )
{ reset ( r , retainRef ) ; }
/// Copy constructor
RefWrapper ( const RefWrapper & r ) : ref ( r . ref )
{ addRef ( ) ; }
# ifndef IVX_USE_CXX98
/// Move constructor
RefWrapper ( RefWrapper & & rw ) noexcept : RefWrapper ( )
{
using std : : swap ;
swap ( ref , rw . ref ) ;
}
# endif
/// Casting to the wrapped OpenVX 'object'
operator T ( ) const
{ return ref ; }
/// Casting to vx_reference since every OpenVX 'object' extends it
operator vx_reference ( ) const
{ return castToReference ( ref ) ; }
/// Getting a context that is kept in each OpenVX 'object' (call get<Context>())
template < typename C >
C get ( ) const
{
typedef int static_assert_context [ is_same < C , Context > : : value ? 1 : - 1 ] ;
vx_context c = vxGetContext ( castToReference ( ref ) ) ;
// vxGetContext doesn't increment ref count, let do it in wrapper c-tor
return C ( c , true ) ;
}
# ifndef IVX_USE_CXX98
/// Getting a context that is kept in each OpenVX 'object'
template < typename C = Context , typename = typename std : : enable_if < std : : is_same < C , Context > : : value > : : type >
C getContext ( ) const
{
vx_context c = vxGetContext ( castToReference ( ref ) ) ;
// vxGetContext doesn't increment ref count, let do it in wrapper c-tor
return C ( c , true ) ;
}
# endif // IVX_USE_CXX98
/// Assigning a new value (decreasing ref counter for the old one)
/// \param r OpenVX 'object' (e.g. vx_image)
/// \param retainRef flag indicating whether to increase ref counter in constructor (false by default)
void reset ( T r , bool retainRef = false )
{
release ( ) ;
ref = r ;
if ( retainRef ) addRef ( ) ;
checkRef ( ) ;
}
/// Assigning an empty value (decreasing ref counter for the old one)
void reset ( )
{ release ( ) ; }
/// Dropping kept value without releas decreasing ref counter
/// \return the value being dropped
T detach ( )
{
T tmp = ref ;
ref = 0 ;
return tmp ;
}
/// Unified assignment operator (covers both copy and move cases)
RefWrapper & operator = ( RefWrapper r )
{
using std : : swap ;
swap ( ref , r . ref ) ;
return * this ;
}
/// Checking for non-empty
bool operator ! ( ) const
{ return ref = = 0 ; }
# ifndef IVX_USE_CXX98
/// Explicit boolean evaluation (called automatically inside conditional operators only)
explicit operator bool ( ) const
{ return ref ! = 0 ; }
# endif
protected :
T ref ;
void addRef ( )
{ if ( ref ) IVX_CHECK_STATUS ( vxRetainReference ( ( vx_reference ) ref ) ) ; }
void release ( )
{
if ( ref ) RefTypeTraits < T > : : release ( ref ) ;
ref = 0 ;
}
void checkRef ( ) const
{
IVX_CHECK_REF ( ref ) ;
vx_enum type ;
IVX_CHECK_STATUS ( vxQueryReference ( ( vx_reference ) ref , VX_REF_ATTRIBUTE_TYPE , & type , sizeof ( type ) ) ) ;
if ( type ! = vxTypeEnum ) throw WrapperError ( " incompatible reference type " ) ;
}
~ RefWrapper ( )
{ release ( ) ; }
} ;
# ifdef IVX_USE_CXX98
# define IVX_REF_STD_CTORS_AND_ASSIGNMENT(Class) \
Class ( ) : RefWrapper ( ) { } \
explicit Class ( Class : : vxType _ref , bool retainRef = false ) : RefWrapper ( _ref , retainRef ) { } \
Class ( const Class & _obj ) : RefWrapper ( _obj ) { } \
\
Class & operator = ( Class _obj ) { using std : : swap ; swap ( ref , _obj . ref ) ; return * this ; }
# else
# define IVX_REF_STD_CTORS_AND_ASSIGNMENT(Class) \
Class ( ) : RefWrapper ( ) { } \
explicit Class ( Class : : vxType _ref , bool retainRef = false ) : RefWrapper ( _ref , retainRef ) { } \
Class ( const Class & _obj ) : RefWrapper ( _obj ) { } \
Class ( Class & & _obj ) : RefWrapper ( std : : move ( _obj ) ) { } \
\
Class & operator = ( Class _obj ) { using std : : swap ; swap ( ref , _obj . ref ) ; return * this ; }
# endif // IVX_USE_CXX98
# endif // IVX_USE_EXTERNAL_REFCOUNT
# ifndef VX_VERSION_1_1
//TODO: provide wrapper for border mode
typedef vx_border_mode_t vx_border_t ;
# endif
/// vx_context wrapper
class Context : public RefWrapper < vx_context >
{
public :
IVX_REF_STD_CTORS_AND_ASSIGNMENT ( Context )
/// vxCreateContext() wrapper
static Context create ( )
{ return Context ( vxCreateContext ( ) ) ; }
/// vxGetContext() wrapper
template < typename T >
static Context getFrom ( const T & ref )
{
vx_context c = vxGetContext ( castToReference ( ref ) ) ;
// vxGetContext doesn't increment ref count, let do it in wrapper c-tor
return Context ( c , true ) ;
}
/// vxLoadKernels() wrapper
void loadKernels ( const std : : string & module )
{ IVX_CHECK_STATUS ( vxLoadKernels ( ref , module . c_str ( ) ) ) ; }
/// vxQueryContext() wrapper
template < typename T >
void query ( vx_enum att , T & value ) const
{ IVX_CHECK_STATUS ( vxQueryContext ( ref , att , & value , sizeof ( value ) ) ) ; }
# ifndef VX_VERSION_1_1
static const vx_enum
VX_CONTEXT_VENDOR_ID = VX_CONTEXT_ATTRIBUTE_VENDOR_ID ,
VX_CONTEXT_VERSION = VX_CONTEXT_ATTRIBUTE_VERSION ,
VX_CONTEXT_UNIQUE_KERNELS = VX_CONTEXT_ATTRIBUTE_UNIQUE_KERNELS ,
VX_CONTEXT_MODULES = VX_CONTEXT_ATTRIBUTE_MODULES ,
VX_CONTEXT_REFERENCES = VX_CONTEXT_ATTRIBUTE_REFERENCES ,
VX_CONTEXT_IMPLEMENTATION = VX_CONTEXT_ATTRIBUTE_IMPLEMENTATION ,
VX_CONTEXT_EXTENSIONS_SIZE = VX_CONTEXT_ATTRIBUTE_EXTENSIONS_SIZE ,
VX_CONTEXT_EXTENSIONS = VX_CONTEXT_ATTRIBUTE_EXTENSIONS ,
VX_CONTEXT_CONVOLUTION_MAX_DIMENSION = VX_CONTEXT_ATTRIBUTE_CONVOLUTION_MAXIMUM_DIMENSION ,
VX_CONTEXT_OPTICAL_FLOW_MAX_WINDOW_DIMENSION = VX_CONTEXT_ATTRIBUTE_OPTICAL_FLOW_WINDOW_MAXIMUM_DIMENSION ,
VX_CONTEXT_IMMEDIATE_BORDER = VX_CONTEXT_ATTRIBUTE_IMMEDIATE_BORDER_MODE ,
VX_CONTEXT_UNIQUE_KERNEL_TABLE = VX_CONTEXT_ATTRIBUTE_UNIQUE_KERNEL_TABLE ;
# endif
/// vxQueryContext(VX_CONTEXT_VENDOR_ID) wrapper
vx_uint16 vendorID ( ) const
{
vx_uint16 v ;
query ( VX_CONTEXT_VENDOR_ID , v ) ;
return v ;
}
/// vxQueryContext(VX_CONTEXT_VERSION) wrapper
vx_uint16 version ( ) const
{
vx_uint16 v ;
query ( VX_CONTEXT_VERSION , v ) ;
return v ;
}
/// vxQueryContext(VX_CONTEXT_UNIQUE_KERNELS) wrapper
vx_uint32 uniqueKernels ( ) const
{
vx_uint32 v ;
query ( VX_CONTEXT_UNIQUE_KERNELS , v ) ;
return v ;
}
/// vxQueryContext(VX_CONTEXT_MODULES) wrapper
vx_uint32 modules ( ) const
{
vx_uint32 v ;
query ( VX_CONTEXT_MODULES , v ) ;
return v ;
}
/// vxQueryContext(VX_CONTEXT_REFERENCES) wrapper
vx_uint32 references ( ) const
{
vx_uint32 v ;
query ( VX_CONTEXT_REFERENCES , v ) ;
return v ;
}
/// vxQueryContext(VX_CONTEXT_EXTENSIONS_SIZE) wrapper
vx_size extensionsSize ( ) const
{
vx_size v ;
query ( VX_CONTEXT_EXTENSIONS_SIZE , v ) ;
return v ;
}
/// vxQueryContext(VX_CONTEXT_CONVOLUTION_MAX_DIMENSION) wrapper
vx_size convolutionMaxDimension ( ) const
{
vx_size v ;
query ( VX_CONTEXT_CONVOLUTION_MAX_DIMENSION , v ) ;
return v ;
}
/// vxQueryContext(VX_CONTEXT_OPTICAL_FLOW_MAX_WINDOW_DIMENSION) wrapper
vx_size opticalFlowMaxWindowSize ( ) const
{
vx_size v ;
query ( VX_CONTEXT_OPTICAL_FLOW_MAX_WINDOW_DIMENSION , v ) ;
return v ;
}
/// vxQueryContext(VX_CONTEXT_IMMEDIATE_BORDER) wrapper
vx_border_t borderMode ( ) const
{
vx_border_t v ;
query ( VX_CONTEXT_IMMEDIATE_BORDER , v ) ;
return v ;
}
/// vxQueryContext(VX_CONTEXT_IMPLEMENTATION) wrapper
std : : string implementation ( ) const
{
std : : vector < vx_char > v ( VX_MAX_IMPLEMENTATION_NAME ) ;
IVX_CHECK_STATUS ( vxQueryContext ( ref , VX_CONTEXT_IMPLEMENTATION , & v [ 0 ] , v . size ( ) * sizeof ( vx_char ) ) ) ;
return std : : string ( v . data ( ) ) ;
}
/// vxQueryContext(VX_CONTEXT_EXTENSIONS) wrapper
std : : string extensions ( ) const
{
std : : vector < vx_char > v ( extensionsSize ( ) ) ;
IVX_CHECK_STATUS ( vxQueryContext ( ref , VX_CONTEXT_EXTENSIONS , & v [ 0 ] , v . size ( ) * sizeof ( vx_char ) ) ) ;
return std : : string ( v . data ( ) ) ;
}
/// vxQueryContext(VX_CONTEXT_UNIQUE_KERNEL_TABLE) wrapper
std : : vector < vx_kernel_info_t > kernelTable ( ) const
{
std : : vector < vx_kernel_info_t > v ( uniqueKernels ( ) ) ;
IVX_CHECK_STATUS ( vxQueryContext ( ref , VX_CONTEXT_UNIQUE_KERNEL_TABLE , & v [ 0 ] , v . size ( ) * sizeof ( vx_kernel_info_t ) ) ) ;
return v ;
}
# ifdef VX_VERSION_1_1
/// vxQueryContext(VX_CONTEXT_IMMEDIATE_BORDER_POLICY) wrapper
vx_enum borderPolicy ( ) const
{
vx_enum v ;
query ( VX_CONTEXT_IMMEDIATE_BORDER_POLICY , v ) ;
return v ;
}
/// vxQueryContext(VX_CONTEXT_NONLINEAR_MAX_DIMENSION) wrapper
vx_size nonlinearMaxDimension ( ) const
{
vx_size v ;
query ( VX_CONTEXT_NONLINEAR_MAX_DIMENSION , v ) ;
return v ;
}
# endif
/// vxSetContextAttribute(VX_CONTEXT_IMMEDIATE_BORDER) wrapper
void setBorderMode ( vx_border_t & border )
{ IVX_CHECK_STATUS ( vxSetContextAttribute ( ref , VX_CONTEXT_IMMEDIATE_BORDER , & border , sizeof ( border ) ) ) ; }
} ;
/// vx_graph wrapper
class Graph : public RefWrapper < vx_graph >
{
public :
IVX_REF_STD_CTORS_AND_ASSIGNMENT ( Graph ) ;
/// vxCreateGraph() wrapper
static Graph create ( vx_context c )
{ return Graph ( vxCreateGraph ( c ) ) ; }
/// vxVerifyGraph() wrapper
void verify ( )
{ IVX_CHECK_STATUS ( vxVerifyGraph ( ref ) ) ; }
/// vxProcessGraph() wrapper
void process ( )
{ IVX_CHECK_STATUS ( vxProcessGraph ( ref ) ) ; }
/// vxScheduleGraph() wrapper
void schedule ( )
{ IVX_CHECK_STATUS ( vxScheduleGraph ( ref ) ) ; }
/// vxWaitGraph() wrapper
void wait ( )
{ IVX_CHECK_STATUS ( vxWaitGraph ( ref ) ) ; }
} ;
/// vx_kernel wrapper
class Kernel : public RefWrapper < vx_kernel >
{
public :
IVX_REF_STD_CTORS_AND_ASSIGNMENT ( Kernel ) ;
/// vxGetKernelByEnum() wrapper
static Kernel getByEnum ( vx_context c , vx_enum kernelID )
{ return Kernel ( vxGetKernelByEnum ( c , kernelID ) ) ; }
/// vxGetKernelByName() wrapper
static Kernel getByName ( vx_context c , const std : : string & name )
{ return Kernel ( vxGetKernelByName ( c , name . c_str ( ) ) ) ; }
} ;
# ifdef IVX_USE_CXX98
/// vx_node wrapper
class Node : public RefWrapper < vx_node >
{
public :
IVX_REF_STD_CTORS_AND_ASSIGNMENT ( Node ) ;
/// vxCreateGenericNode() wrapper
static Node create ( vx_graph g , vx_kernel k )
{ return Node ( vxCreateGenericNode ( g , k ) ) ; }
/// Create node for the kernel and set the parameters
static Node create ( vx_graph graph , vx_kernel kernel , const std : : vector < vx_reference > & params )
{
Node node = Node : : create ( graph , kernel ) ;
vx_uint32 i = 0 ;
for ( std : : vector < vx_reference > : : const_iterator p = params . begin ( ) ; p ! = params . end ( ) ; + + p )
node . setParameterByIndex ( i + + , * p ) ;
return node ;
}
/// Create node for the kernel ID and set the parameters
static Node create ( vx_graph graph , vx_enum kernelID , const std : : vector < vx_reference > & params )
{ return Node : : create ( graph , Kernel : : getByEnum ( Context : : getFrom ( graph ) , kernelID ) , params ) ; }
/// Create node for the kernel ID and set one parameter
template < typename T0 >
static Node create ( vx_graph g , vx_enum kernelID ,
const T0 & arg0 )
{
std : : vector < vx_reference > params ;
params . push_back ( castToReference ( arg0 ) ) ;
return create ( g , Kernel : : getByEnum ( Context : : getFrom ( g ) , kernelID ) , params ) ;
}
/// Create node for the kernel ID and set two parameters
template < typename T0 , typename T1 >
static Node create ( vx_graph g , vx_enum kernelID ,
const T0 & arg0 , const T1 & arg1 )
{
std : : vector < vx_reference > params ;
params . push_back ( castToReference ( arg0 ) ) ;
params . push_back ( castToReference ( arg1 ) ) ;
return create ( g , Kernel : : getByEnum ( Context : : getFrom ( g ) , kernelID ) , params ) ;
}
/// Create node for the kernel ID and set three parameters
template < typename T0 , typename T1 , typename T2 >
static Node create ( vx_graph g , vx_enum kernelID ,
const T0 & arg0 , const T1 & arg1 , const T2 & arg2 )
{
std : : vector < vx_reference > params ;
params . push_back ( castToReference ( arg0 ) ) ;
params . push_back ( castToReference ( arg1 ) ) ;
params . push_back ( castToReference ( arg2 ) ) ;
return create ( g , Kernel : : getByEnum ( Context : : getFrom ( g ) , kernelID ) , params ) ;
}
/// Create node for the kernel ID and set four parameters
template < typename T0 , typename T1 , typename T2 , typename T3 >
static Node create ( vx_graph g , vx_enum kernelID ,
const T0 & arg0 , const T1 & arg1 , const T2 & arg2 ,
const T3 & arg3 )
{
std : : vector < vx_reference > params ;
params . push_back ( castToReference ( arg0 ) ) ;
params . push_back ( castToReference ( arg1 ) ) ;
params . push_back ( castToReference ( arg2 ) ) ;
params . push_back ( castToReference ( arg3 ) ) ;
return create ( g , Kernel : : getByEnum ( Context : : getFrom ( g ) , kernelID ) , params ) ;
}
/// Create node for the kernel ID and set five parameters
template < typename T0 , typename T1 , typename T2 , typename T3 , typename T4 >
static Node create ( vx_graph g , vx_enum kernelID ,
const T0 & arg0 , const T1 & arg1 , const T2 & arg2 ,
const T3 & arg3 , const T4 & arg4 )
{
std : : vector < vx_reference > params ;
params . push_back ( castToReference ( arg0 ) ) ;
params . push_back ( castToReference ( arg1 ) ) ;
params . push_back ( castToReference ( arg2 ) ) ;
params . push_back ( castToReference ( arg3 ) ) ;
params . push_back ( castToReference ( arg4 ) ) ;
return create ( g , Kernel : : getByEnum ( Context : : getFrom ( g ) , kernelID ) , params ) ;
}
/// Create node for the kernel ID and set six parameters
template < typename T0 , typename T1 , typename T2 , typename T3 , typename T4 , typename T5 >
static Node create ( vx_graph g , vx_enum kernelID ,
const T0 & arg0 , const T1 & arg1 , const T2 & arg2 ,
const T3 & arg3 , const T4 & arg4 , const T5 & arg5 )
{
std : : vector < vx_reference > params ;
params . push_back ( castToReference ( arg0 ) ) ;
params . push_back ( castToReference ( arg1 ) ) ;
params . push_back ( castToReference ( arg2 ) ) ;
params . push_back ( castToReference ( arg3 ) ) ;
params . push_back ( castToReference ( arg4 ) ) ;
params . push_back ( castToReference ( arg5 ) ) ;
return create ( g , Kernel : : getByEnum ( Context : : getFrom ( g ) , kernelID ) , params ) ;
}
/// Create node for the kernel ID and set seven parameters
template < typename T0 , typename T1 , typename T2 , typename T3 , typename T4 , typename T5 ,
typename T6 >
static Node create ( vx_graph g , vx_enum kernelID ,
const T0 & arg0 , const T1 & arg1 , const T2 & arg2 ,
const T3 & arg3 , const T4 & arg4 , const T5 & arg5 ,
const T6 & arg6 )
{
std : : vector < vx_reference > params ;
params . push_back ( castToReference ( arg0 ) ) ;
params . push_back ( castToReference ( arg1 ) ) ;
params . push_back ( castToReference ( arg2 ) ) ;
params . push_back ( castToReference ( arg3 ) ) ;
params . push_back ( castToReference ( arg4 ) ) ;
params . push_back ( castToReference ( arg5 ) ) ;
params . push_back ( castToReference ( arg6 ) ) ;
return create ( g , Kernel : : getByEnum ( Context : : getFrom ( g ) , kernelID ) , params ) ;
}
/// Create node for the kernel ID and set eight parameters
template < typename T0 , typename T1 , typename T2 , typename T3 , typename T4 , typename T5 ,
typename T6 , typename T7 >
static Node create ( vx_graph g , vx_enum kernelID ,
const T0 & arg0 , const T1 & arg1 , const T2 & arg2 ,
const T3 & arg3 , const T4 & arg4 , const T5 & arg5 ,
const T6 & arg6 , const T7 & arg7 )
{
std : : vector < vx_reference > params ;
params . push_back ( castToReference ( arg0 ) ) ;
params . push_back ( castToReference ( arg1 ) ) ;
params . push_back ( castToReference ( arg2 ) ) ;
params . push_back ( castToReference ( arg3 ) ) ;
params . push_back ( castToReference ( arg4 ) ) ;
params . push_back ( castToReference ( arg5 ) ) ;
params . push_back ( castToReference ( arg6 ) ) ;
params . push_back ( castToReference ( arg7 ) ) ;
return create ( g , Kernel : : getByEnum ( Context : : getFrom ( g ) , kernelID ) , params ) ;
}
/// Create node for the kernel ID and set nine parameters
template < typename T0 , typename T1 , typename T2 , typename T3 , typename T4 , typename T5 ,
typename T6 , typename T7 , typename T8 >
static Node create ( vx_graph g , vx_enum kernelID ,
const T0 & arg0 , const T1 & arg1 , const T2 & arg2 ,
const T3 & arg3 , const T4 & arg4 , const T5 & arg5 ,
const T6 & arg6 , const T7 & arg7 , const T8 & arg8 )
{
std : : vector < vx_reference > params ;
params . push_back ( castToReference ( arg0 ) ) ;
params . push_back ( castToReference ( arg1 ) ) ;
params . push_back ( castToReference ( arg2 ) ) ;
params . push_back ( castToReference ( arg3 ) ) ;
params . push_back ( castToReference ( arg4 ) ) ;
params . push_back ( castToReference ( arg5 ) ) ;
params . push_back ( castToReference ( arg6 ) ) ;
params . push_back ( castToReference ( arg7 ) ) ;
params . push_back ( castToReference ( arg8 ) ) ;
return create ( g , Kernel : : getByEnum ( Context : : getFrom ( g ) , kernelID ) , params ) ;
}
/// Create node for the kernel ID and set ten parameters
template < typename T0 , typename T1 , typename T2 , typename T3 , typename T4 , typename T5 ,
typename T6 , typename T7 , typename T8 , typename T9 >
static Node create ( vx_graph g , vx_enum kernelID ,
const T0 & arg0 , const T1 & arg1 , const T2 & arg2 ,
const T3 & arg3 , const T4 & arg4 , const T5 & arg5 ,
const T6 & arg6 , const T7 & arg7 , const T8 & arg8 ,
const T9 & arg9 )
{
std : : vector < vx_reference > params ;
params . push_back ( castToReference ( arg0 ) ) ;
params . push_back ( castToReference ( arg1 ) ) ;
params . push_back ( castToReference ( arg2 ) ) ;
params . push_back ( castToReference ( arg3 ) ) ;
params . push_back ( castToReference ( arg4 ) ) ;
params . push_back ( castToReference ( arg5 ) ) ;
params . push_back ( castToReference ( arg6 ) ) ;
params . push_back ( castToReference ( arg7 ) ) ;
params . push_back ( castToReference ( arg8 ) ) ;
params . push_back ( castToReference ( arg9 ) ) ;
return create ( g , Kernel : : getByEnum ( Context : : getFrom ( g ) , kernelID ) , params ) ;
}
/// vxSetParameterByIndex() wrapper
void setParameterByIndex ( vx_uint32 index , vx_reference value )
{ IVX_CHECK_STATUS ( vxSetParameterByIndex ( ref , index , value ) ) ; }
} ;
# else // not IVX_USE_CXX98
/// vx_node wrapper
class Node : public RefWrapper < vx_node >
{
public :
IVX_REF_STD_CTORS_AND_ASSIGNMENT ( Node ) ;
/// vxCreateGenericNode() wrapper
static Node create ( vx_graph g , vx_kernel k )
{ return Node ( vxCreateGenericNode ( g , k ) ) ; }
/// Create node for the kernel and set the parameters
static Node create ( vx_graph graph , vx_kernel kernel , const std : : vector < vx_reference > & params )
{
Node node = Node : : create ( graph , kernel ) ;
vx_uint32 i = 0 ;
for ( const auto & p : params )
node . setParameterByIndex ( i + + , p ) ;
return node ;
}
/// Create node for the kernel ID and set the parameters
static Node create ( vx_graph graph , vx_enum kernelID , const std : : vector < vx_reference > & params )
{ return Node : : create ( graph , Kernel : : getByEnum ( Context : : getFrom ( graph ) , kernelID ) , params ) ; }
/// Create node for the kernel ID and set the specified parameters
template < typename . . . Ts >
static Node create ( vx_graph g , vx_enum kernelID , const Ts & . . . args )
{ return create ( g , Kernel : : getByEnum ( Context : : getFrom ( g ) , kernelID ) , { castToReference ( args ) . . . } ) ; }
/// vxSetParameterByIndex() wrapper
void setParameterByIndex ( vx_uint32 index , vx_reference value )
{ IVX_CHECK_STATUS ( vxSetParameterByIndex ( ref , index , value ) ) ; }
} ;
# endif // IVX_USE_CXX98
/// vx_image wrapper
class Image : public RefWrapper < vx_image >
{
public :
IVX_REF_STD_CTORS_AND_ASSIGNMENT ( Image ) ;
/// vxCreateImage() wrapper
static Image create ( vx_context context , vx_uint32 width , vx_uint32 height , vx_df_image format )
{ return Image ( vxCreateImage ( context , width , height , format ) ) ; }
/// vxCreateVirtualImage() wrapper
static Image createVirtual ( vx_graph graph , vx_uint32 width = 0 , vx_uint32 height = 0 , vx_df_image format = VX_DF_IMAGE_VIRT )
{ return Image ( vxCreateVirtualImage ( graph , width , height , format ) ) ; }
# ifdef VX_VERSION_1_1
/// vxCreateUniformImage() wrapper
static Image createUniform ( vx_context context , vx_uint32 width , vx_uint32 height , vx_df_image format , const vx_pixel_value_t & value )
{ return Image ( vxCreateUniformImage ( context , width , height , format , & value ) ) ; }
# else
/// vxCreateUniformImage() wrapper
static Image createUniform ( vx_context context , vx_uint32 width , vx_uint32 height , vx_df_image format , const void * value )
{ return Image ( vxCreateUniformImage ( context , width , height , format , value ) ) ; }
# endif
/// Planes number for the specified image format (fourcc)
/// \return 0 for unknown formats
static vx_size planes ( vx_df_image format )
{
switch ( format )
{
case VX_DF_IMAGE_IYUV :
case VX_DF_IMAGE_YUV4 : return 3 ;
case VX_DF_IMAGE_NV12 :
case VX_DF_IMAGE_NV21 : return 2 ;
case VX_DF_IMAGE_RGB :
case VX_DF_IMAGE_RGBX :
case VX_DF_IMAGE_UYVY :
case VX_DF_IMAGE_YUYV :
case VX_DF_IMAGE_U8 :
case VX_DF_IMAGE_U16 :
case VX_DF_IMAGE_S16 :
case VX_DF_IMAGE_U32 :
case VX_DF_IMAGE_S32 :
case /*VX_DF_IMAGE_F32*/ VX_DF_IMAGE ( ' F ' , ' 0 ' , ' 3 ' , ' 2 ' ) :
return 1 ;
default : return 0 ;
}
}
/// Create vx_imagepatch_addressing_t structure with default values
static vx_imagepatch_addressing_t createAddressing ( )
{ vx_imagepatch_addressing_t ipa = VX_IMAGEPATCH_ADDR_INIT ; return ipa ; }
/// Create vx_imagepatch_addressing_t structure with the provided values
static vx_imagepatch_addressing_t createAddressing (
vx_uint32 dimX , vx_uint32 dimY ,
vx_int32 strideX , vx_int32 strideY ,
vx_uint32 scaleX = VX_SCALE_UNITY , vx_uint32 scaleY = VX_SCALE_UNITY )
{
if ( std : : abs ( strideY ) < std : : abs ( strideX * ( vx_int32 ) dimX ) )
throw WrapperError ( std : : string ( __func__ ) + " (): invalid arguments " ) ;
vx_imagepatch_addressing_t ipa = VX_IMAGEPATCH_ADDR_INIT ;
ipa . dim_x = dimX ;
ipa . dim_y = dimY ;
ipa . stride_x = strideX ;
ipa . stride_y = strideY ;
ipa . scale_x = scaleX ;
ipa . scale_y = scaleY ;
return ipa ;
}
/// Create vx_imagepatch_addressing_t structure for the specified image plane and its valid region
vx_imagepatch_addressing_t createAddressing ( vx_uint32 planeIdx )
{ return createAddressing ( planeIdx , getValidRegion ( ) ) ; }
/// Create vx_imagepatch_addressing_t structure for the specified image plane and the provided region
vx_imagepatch_addressing_t createAddressing ( vx_uint32 planeIdx , const vx_rectangle_t & rect )
{
vx_uint32 w = rect . end_x - rect . start_x , h = rect . end_y - rect . start_y ;
vx_size patchBytes = computePatchSize ( planeIdx , rect ) ;
vx_imagepatch_addressing_t ipa = createAddressing ( w , h , ( vx_int32 ) ( patchBytes / w / h ) , ( vx_int32 ) ( patchBytes / h ) ) ;
return ipa ;
}
# ifndef VX_VERSION_1_1
static const vx_enum VX_MEMORY_TYPE_HOST = VX_IMPORT_TYPE_HOST ;
# endif
/// vxCreateImageFromHandle() wrapper
static Image createFromHandle (
vx_context context , vx_df_image format ,
const std : : vector < vx_imagepatch_addressing_t > & addrs ,
const std : : vector < void * > & ptrs , vx_enum memType = VX_MEMORY_TYPE_HOST )
{
vx_size num = planes ( format ) ;
if ( num = = 0 )
throw WrapperError ( std : : string ( __func__ ) + " (): unknown/unexpected planes number for the requested format " ) ;
if ( addrs . size ( ) ! = num | | ptrs . size ( ) ! = num )
throw WrapperError ( std : : string ( __func__ ) + " (): incomplete input " ) ;
# ifdef VX_VERSION_1_1
return Image ( vxCreateImageFromHandle ( context , format , & addrs [ 0 ] , & ptrs [ 0 ] , memType ) ) ;
# else
return Image ( vxCreateImageFromHandle ( context , format ,
const_cast < vx_imagepatch_addressing_t * > ( & addrs [ 0 ] ) ,
const_cast < void * * > ( & ptrs [ 0 ] ) , memType ) ) ;
# endif
}
/// vxCreateImageFromHandle() wrapper for a single plane image
static Image createFromHandle ( vx_context context , vx_df_image format , const vx_imagepatch_addressing_t & addr , void * ptr )
{
if ( planes ( format ) ! = 1 ) throw WrapperError ( std : : string ( __func__ ) + " (): not a single plane format " ) ;
return Image ( vxCreateImageFromHandle ( context , format , const_cast < vx_imagepatch_addressing_t * > ( & addr ) , & ptr , VX_MEMORY_TYPE_HOST ) ) ;
}
# ifdef VX_VERSION_1_1
/// vxSwapImageHandle() wrapper
/// \param newPtrs keeps addresses of new image planes data, can be of image planes size or empty when new pointers are not provided
/// \param prevPtrs storage for the previous addresses of image planes data, can be of image planes size or empty when previous pointers are not needed
void swapHandle ( const std : : vector < void * > & newPtrs , std : : vector < void * > & prevPtrs )
{
vx_size num = planes ( ) ;
if ( num = = 0 )
throw WrapperError ( std : : string ( __func__ ) + " (): unexpected planes number " ) ;
if ( ! newPtrs . empty ( ) & & newPtrs . size ( ) ! = num )
throw WrapperError ( std : : string ( __func__ ) + " (): unexpected number of input pointers " ) ;
if ( ! prevPtrs . empty ( ) & & prevPtrs . size ( ) ! = num )
throw WrapperError ( std : : string ( __func__ ) + " (): unexpected number of output pointers " ) ;
IVX_CHECK_STATUS ( vxSwapImageHandle ( ref ,
newPtrs . empty ( ) ? 0 : & newPtrs [ 0 ] ,
prevPtrs . empty ( ) ? 0 : & prevPtrs [ 0 ] ,
num ) ) ;
}
/// vxSwapImageHandle() wrapper for a single plane image
/// \param newPtr an address of new image data, can be zero when new pointer is not provided
/// \return the previuos address of image data
void * swapHandle ( void * newPtr )
{
if ( planes ( ) ! = 1 ) throw WrapperError ( std : : string ( __func__ ) + " (): not a single plane image " ) ;
void * prevPtr = 0 ;
IVX_CHECK_STATUS ( vxSwapImageHandle ( ref , & newPtr , & prevPtr , 1 ) ) ;
return prevPtr ;
}
/// vxSwapImageHandle() wrapper for the case when no new pointers provided and previous ones are not needed (retrive memory back)
void swapHandle ( )
{ IVX_CHECK_STATUS ( vxSwapImageHandle ( ref , 0 , 0 , 0 ) ) ; }
/// vxCreateImageFromChannel() wrapper
Image createFromChannel ( vx_enum channel )
{ return Image ( vxCreateImageFromChannel ( ref , channel ) ) ; }
# endif // VX_VERSION_1_1
/// vxQueryImage() wrapper
template < typename T >
void query ( vx_enum att , T & value ) const
{ IVX_CHECK_STATUS ( vxQueryImage ( ref , att , & value , sizeof ( value ) ) ) ; }
# ifndef VX_VERSION_1_1
static const vx_enum
VX_IMAGE_WIDTH = VX_IMAGE_ATTRIBUTE_WIDTH ,
VX_IMAGE_HEIGHT = VX_IMAGE_ATTRIBUTE_HEIGHT ,
VX_IMAGE_FORMAT = VX_IMAGE_ATTRIBUTE_FORMAT ,
VX_IMAGE_PLANES = VX_IMAGE_ATTRIBUTE_PLANES ,
VX_IMAGE_SPACE = VX_IMAGE_ATTRIBUTE_SPACE ,
VX_IMAGE_RANGE = VX_IMAGE_ATTRIBUTE_RANGE ,
VX_IMAGE_SIZE = VX_IMAGE_ATTRIBUTE_SIZE ;
# endif
/// vxQueryImage(VX_IMAGE_WIDTH) wrapper
vx_uint32 width ( ) const
{
vx_uint32 v ;
query ( VX_IMAGE_WIDTH , v ) ;
return v ;
}
/// vxQueryImage(VX_IMAGE_HEIGHT) wrapper
vx_uint32 height ( ) const
{
vx_uint32 v ;
query ( VX_IMAGE_HEIGHT , v ) ;
return v ;
}
/// vxQueryImage(VX_IMAGE_FORMAT) wrapper
vx_df_image format ( ) const
{
vx_df_image v ;
query ( VX_IMAGE_FORMAT , v ) ;
return v ;
}
/// vxQueryImage(VX_IMAGE_PLANES) wrapper
vx_size planes ( ) const
{
vx_size v ;
query ( VX_IMAGE_PLANES , v ) ;
return v ;
}
/// vxQueryImage(VX_IMAGE_SPACE) wrapper
vx_enum space ( ) const
{
vx_enum v ;
query ( VX_IMAGE_SPACE , v ) ;
return v ;
}
/// vxQueryImage(VX_IMAGE_RANGE) wrapper
vx_enum range ( ) const
{
vx_enum v ;
query ( VX_IMAGE_RANGE , v ) ;
return v ;
}
/// vxQueryImage(VX_IMAGE_SIZE) wrapper
vx_size size ( ) const
{
vx_size v ;
query ( VX_IMAGE_SIZE , v ) ;
return v ;
}
# ifdef VX_VERSION_1_1
/// vxQueryImage(VX_IMAGE_MEMORY_TYPE) wrapper
vx_memory_type_e memType ( ) const
{
vx_memory_type_e v ;
query ( VX_IMAGE_MEMORY_TYPE , v ) ;
return v ;
}
# endif // VX_VERSION_1_1
/// vxGetValidRegionImage() wrapper
vx_rectangle_t getValidRegion ( ) const
{
vx_rectangle_t rect ;
IVX_CHECK_STATUS ( vxGetValidRegionImage ( ref , & rect ) ) ;
return rect ;
}
/// vxComputeImagePatchSize(valid region) wrapper
vx_size computePatchSize ( vx_uint32 planeIdx )
{ return computePatchSize ( planeIdx , getValidRegion ( ) ) ; }
/// vxComputeImagePatchSize() wrapper
vx_size computePatchSize ( vx_uint32 planeIdx , const vx_rectangle_t & rect )
{
vx_size bytes = vxComputeImagePatchSize ( ref , & rect , planeIdx ) ;
if ( bytes = = 0 ) throw WrapperError ( std : : string ( __func__ ) + " (): vxComputeImagePatchSize returned 0 " ) ;
return bytes ;
}
# ifdef VX_VERSION_1_1
/// vxSetImageValidRectangle() wrapper
void setValidRectangle ( const vx_rectangle_t & rect )
{ IVX_CHECK_STATUS ( vxSetImageValidRectangle ( ref , & rect ) ) ; }
# endif // VX_VERSION_1_1
/// Copy image plane content to the provided memory
void copyTo ( vx_uint32 planeIdx , const vx_imagepatch_addressing_t & addr , void * data )
{
if ( ! data ) throw WrapperError ( std : : string ( __func__ ) + " (): output pointer is 0 " ) ;
vx_rectangle_t r = getValidRegion ( ) ;
// TODO: add sizes consistency checks
/*
vx_uint32 w = r . end_x - r . start_x , h = r . end_y - r . start_y ;
if ( w ! = addr . dim_x ) throw WrapperError ( " Image::copyTo(): inconsistent dimension X " ) ;
if ( h ! = addr . dim_y ) throw WrapperError ( " Image::copyTo(): inconsistent dimension Y " ) ;
*/
# ifdef VX_VERSION_1_1
IVX_CHECK_STATUS ( vxCopyImagePatch ( ref , & r , planeIdx , & addr , data , VX_READ_ONLY , VX_MEMORY_TYPE_HOST ) ) ;
# else
vx_imagepatch_addressing_t * a = const_cast < vx_imagepatch_addressing_t * > ( & addr ) ;
IVX_CHECK_STATUS ( vxAccessImagePatch ( ref , & r , planeIdx , a , & data , VX_READ_ONLY ) ) ;
IVX_CHECK_STATUS ( vxCommitImagePatch ( ref , 0 , planeIdx , a , data ) ) ;
# endif
}
/// Copy the provided memory data to the specified image plane
void copyFrom ( vx_uint32 planeIdx , const vx_imagepatch_addressing_t & addr , const void * data )
{
if ( ! data ) throw WrapperError ( std : : string ( __func__ ) + " (): input pointer is 0 " ) ;
vx_rectangle_t r = getValidRegion ( ) ;
// TODO: add sizes consistency checks
/*
vx_uint32 w = r . end_x - r . start_x , h = r . end_y - r . start_y ;
//vx_size patchBytes = vxComputeImagePatchSize(ref, &r, planeIdx);
if ( w ! = addr . dim_x ) throw WrapperError ( " Image::copyFrom(): inconsistent dimension X " ) ;
if ( h ! = addr . dim_y ) throw WrapperError ( " Image::copyFrom(): inconsistent dimension Y " ) ;
*/
# ifdef VX_VERSION_1_1
IVX_CHECK_STATUS ( vxCopyImagePatch ( ref , & r , planeIdx , & addr , ( void * ) data , VX_WRITE_ONLY , VX_MEMORY_TYPE_HOST ) ) ;
# else
vx_imagepatch_addressing_t * a = const_cast < vx_imagepatch_addressing_t * > ( & addr ) ;
IVX_CHECK_STATUS ( vxAccessImagePatch ( ref , & r , planeIdx , a , const_cast < void * * > ( & data ) , VX_WRITE_ONLY ) ) ;
IVX_CHECK_STATUS ( vxCommitImagePatch ( ref , & r , planeIdx , a , data ) ) ;
# endif
}
/// vxCopyImagePatch() wrapper (or vxAccessImagePatch() + vxCommitImagePatch() for OpenVX 1.0)
void copy ( vx_uint32 planeIdx , vx_rectangle_t rect ,
const vx_imagepatch_addressing_t & addr , void * data ,
vx_enum usage , vx_enum memoryType = VX_MEMORY_TYPE_HOST )
{
# ifdef VX_VERSION_1_1
IVX_CHECK_STATUS ( vxCopyImagePatch ( ref , & rect , planeIdx , & addr , ( void * ) data , usage , memoryType ) ) ;
# else
( void ) memoryType ;
vx_imagepatch_addressing_t * a = const_cast < vx_imagepatch_addressing_t * > ( & addr ) ;
IVX_CHECK_STATUS ( vxAccessImagePatch ( ref , & rect , planeIdx , a , & data , usage ) ) ;
IVX_CHECK_STATUS ( vxCommitImagePatch ( ref , & rect , planeIdx , a , data ) ) ;
# endif
}
# ifdef IVX_USE_OPENCV
/// Convert image format (fourcc) to cv::Mat type
/// \return CV_USRTYPE1 for unknown image formats
static int formatToMatType ( vx_df_image format , vx_uint32 planeIdx = 0 )
{
switch ( format )
{
case VX_DF_IMAGE_RGB : return CV_8UC3 ;
case VX_DF_IMAGE_RGBX : return CV_8UC4 ;
case VX_DF_IMAGE_U8 : return CV_8UC1 ;
case VX_DF_IMAGE_U16 : return CV_16UC1 ;
case VX_DF_IMAGE_S16 : return CV_16SC1 ;
case VX_DF_IMAGE_U32 :
case VX_DF_IMAGE_S32 : return CV_32SC1 ;
case VX_DF_IMAGE ( ' F ' , ' 0 ' , ' 3 ' , ' 2 ' ) :
return CV_32FC1 ;
case VX_DF_IMAGE_YUV4 :
case VX_DF_IMAGE_IYUV : return CV_8UC1 ;
case VX_DF_IMAGE_UYVY :
case VX_DF_IMAGE_YUYV : return CV_8UC2 ;
case VX_DF_IMAGE_NV12 :
case VX_DF_IMAGE_NV21 : return planeIdx = = 0 ? CV_8UC1 : CV_8UC2 ;
default : return CV_USRTYPE1 ;
}
}
/// Convert cv::Mat type to standard image format (fourcc), throws WrapperError if not possible
static vx_df_image matTypeToFormat ( int matType )
{
switch ( matType )
{
case CV_8UC4 : return VX_DF_IMAGE_RGBX ;
case CV_8UC3 : return VX_DF_IMAGE_RGB ;
case CV_8UC1 : return VX_DF_IMAGE_U8 ;
case CV_16UC1 : return VX_DF_IMAGE_U16 ;
case CV_16SC1 : return VX_DF_IMAGE_S16 ;
case CV_32SC1 : return VX_DF_IMAGE_S32 ;
case CV_32FC1 : return VX_DF_IMAGE ( ' F ' , ' 0 ' , ' 3 ' , ' 2 ' ) ;
default : throw WrapperError ( std : : string ( __func__ ) + " (): unsupported cv::Mat type " ) ;
}
}
/// Initialize cv::Mat shape to fit the specified image plane data
void createMatForPlane ( cv : : Mat & m , vx_uint32 planeIdx )
{
vx_df_image f = format ( ) ;
//vx_uint32 w = width(), h = height();
vx_rectangle_t r = getValidRegion ( ) ;
vx_int32 w = vx_int32 ( r . end_x - r . start_x ) , h = vx_int32 ( r . end_y - r . start_y ) ;
switch ( f )
{
case VX_DF_IMAGE_IYUV :
if ( planeIdx = = 0u ) m . create ( h , w , formatToMatType ( f ) ) ;
else if ( planeIdx = = 1u | | planeIdx = = 2u ) m . create ( h / 2 , w / 2 , formatToMatType ( f ) ) ;
else throw WrapperError ( std : : string ( __func__ ) + " (): wrong plane index " ) ;
break ;
case VX_DF_IMAGE_YUV4 :
if ( planeIdx = = 0u | | planeIdx = = 1u | | planeIdx = = 2u ) m . create ( h , w , formatToMatType ( f ) ) ;
else throw WrapperError ( std : : string ( __func__ ) + " (): wrong plane index " ) ;
break ;
case VX_DF_IMAGE_NV12 :
case VX_DF_IMAGE_NV21 :
if ( planeIdx = = 0u ) m . create ( h , w , formatToMatType ( f , 0 ) ) ;
else if ( planeIdx = = 1u ) m . create ( h / 2 , w / 2 , formatToMatType ( f , 1 ) ) ;
else throw WrapperError ( std : : string ( __func__ ) + " (): wrong plane index " ) ;
break ;
case VX_DF_IMAGE_RGB :
case VX_DF_IMAGE_RGBX :
case VX_DF_IMAGE_UYVY :
case VX_DF_IMAGE_YUYV :
case VX_DF_IMAGE_U8 :
case VX_DF_IMAGE_U16 :
case VX_DF_IMAGE_S16 :
case VX_DF_IMAGE_U32 :
case VX_DF_IMAGE_S32 :
case /*VX_DF_IMAGE_F32*/ VX_DF_IMAGE ( ' F ' , ' 0 ' , ' 3 ' , ' 2 ' ) :
if ( planeIdx = = 0u ) m . create ( h , w , formatToMatType ( f ) ) ;
else throw WrapperError ( std : : string ( __func__ ) + " (): wrong plane index " ) ;
break ;
default : throw WrapperError ( std : : string ( __func__ ) + " (): unsupported color format " ) ;
}
}
/// Create vx_imagepatch_addressing_t corresponding to the provided cv::Mat
static vx_imagepatch_addressing_t createAddressing ( const cv : : Mat & m )
{
if ( m . empty ( ) ) throw WrapperError ( std : : string ( __func__ ) + " (): empty input Mat " ) ;
return createAddressing ( ( vx_uint32 ) m . cols , ( vx_uint32 ) m . rows , ( vx_int32 ) m . elemSize ( ) , ( vx_int32 ) m . step ) ;
}
/// Copy image plane content to the provided cv::Mat (reallocate if needed)
void copyTo ( vx_uint32 planeIdx , cv : : Mat & m )
{
createMatForPlane ( m , planeIdx ) ;
copyTo ( planeIdx , createAddressing ( ( vx_uint32 ) m . cols , ( vx_uint32 ) m . rows , ( vx_int32 ) m . elemSize ( ) , ( vx_int32 ) m . step ) , m . ptr ( ) ) ;
}
/// Copy the provided cv::Mat data to the specified image plane
void copyFrom ( vx_uint32 planeIdx , const cv : : Mat & m )
{
if ( m . empty ( ) ) throw WrapperError ( std : : string ( __func__ ) + " (): empty input Mat " ) ;
// TODO: add sizes consistency checks
//vx_rectangle_t r = getValidRegion();
copyFrom ( planeIdx , createAddressing ( ( vx_uint32 ) m . cols , ( vx_uint32 ) m . rows , ( vx_int32 ) m . elemSize ( ) , ( vx_int32 ) m . step ) , m . ptr ( ) ) ;
}
/*
static Image createFromHandle ( vx_context context , const cv : : Mat & mat )
{ throw WrapperError ( std : : string ( __func__ ) + " (): NYI " ) ; }
cv : : Mat swapHandle ( const cv : : Mat & newMat )
{ throw WrapperError ( std : : string ( __func__ ) + " (): NYI " ) ; }
*/
# endif //IVX_USE_OPENCV
struct Patch ;
} ;
/// Helper class for a mapping vx_image patch
struct Image : : Patch
{
public :
/// reference to the current vx_imagepatch_addressing_t
const vx_imagepatch_addressing_t & addr ( ) const
{ return _addr ; }
/// current pixels data pointer
void * data ( ) const
{ return _data ; }
# ifdef VX_VERSION_1_1
/// vx_memory_type_e for the current data pointer
vx_memory_type_e memType ( ) const
{ return _memType ; }
/// vx_map_id for the current mapping
vx_map_id mapId ( ) const
{ return _mapId ; }
# else
/// reference to vx_rectangle_t for the current mapping
const vx_rectangle_t & rectangle ( ) const
{ return _rect ; }
/// Image plane index for the current mapping
vx_uint32 planeIndex ( ) const
{ return _planeIdx ; }
# endif // VX_VERSION_1_1
/// vx_image for the current mapping
vx_image image ( ) const
{ return _img ; }
/// where this patch is mapped
bool isMapped ( ) const
{ return _img ! = 0 ; }
# ifdef IVX_USE_OPENCV
/// Reference to cv::Mat instance wrapping the mapped image data, becomes invalid after unmap()
cv : : Mat & getMat ( )
{ return _m ; }
# endif //IVX_USE_OPENCV
protected :
vx_imagepatch_addressing_t _addr ;
void * _data ;
vx_image _img ;
# ifdef VX_VERSION_1_1
vx_memory_type_e _memType ;
vx_map_id _mapId ;
# else
vx_rectangle_t _rect ;
vx_uint32 _planeIdx ;
# endif
# ifdef IVX_USE_OPENCV
cv : : Mat _m ;
# endif
public :
/// Default constructor
Patch ( ) : _addr ( createAddressing ( ) ) , _data ( 0 ) , _img ( 0 )
# ifdef VX_VERSION_1_1
, _memType ( VX_MEMORY_TYPE_HOST ) , _mapId ( 0 )
{ }
# else
, _planeIdx ( - 1 )
{ _rect . start_x = _rect . end_x = _rect . start_y = _rect . end_y = 0u ; }
# endif
# ifndef IVX_USE_CXX98
/// Move constructor
Patch ( Patch & & p ) : Patch ( )
{
using std : : swap ;
swap ( _addr , p . _addr ) ;
swap ( _data , p . _data ) ;
# ifdef VX_VERSION_1_1
swap ( _memType , p . _memType ) ;
swap ( _mapId , p . _mapId ) ;
# else
swap ( _rect , p . _rect ) ;
swap ( _planeIdx , p . _planeIdx ) ;
# endif
swap ( _img , p . _img ) ;
swap ( _m , p . _m ) ;
}
# endif
/// vxMapImagePatch(VX_READ_ONLY, planeIdx valid region)
void map ( vx_image img , vx_uint32 planeIdx )
{ map ( img , planeIdx , Image ( img , true ) . getValidRegion ( ) ) ; }
/// vxMapImagePatch() wrapper (or vxAccessImagePatch() for 1.0)
void map ( vx_image img , vx_uint32 planeIdx , const vx_rectangle_t & rect , vx_enum usage = VX_READ_ONLY , vx_uint32 flags = 0 )
{
if ( isMapped ( ) ) throw WrapperError ( std : : string ( __func__ ) + " (): already mapped " ) ;
# ifdef VX_VERSION_1_1
IVX_CHECK_STATUS ( vxMapImagePatch ( img , & rect , planeIdx , & _mapId , & _addr , & _data , usage , _memType , flags ) ) ;
# else
IVX_CHECK_STATUS ( vxAccessImagePatch ( img , & rect , planeIdx , & _addr , & _data , usage ) ) ;
( void ) flags ;
_rect = rect ;
_planeIdx = planeIdx ;
# endif
if ( _data = = 0 ) throw WrapperError ( std : : string ( __func__ ) + " (): mapped address is null " ) ;
_img = img ;
# ifdef IVX_USE_OPENCV
vx_df_image format ;
IVX_CHECK_STATUS ( vxQueryImage ( _img , VX_IMAGE_FORMAT , & format , sizeof ( format ) ) ) ;
int matType = formatToMatType ( format ) ;
_m = cv : : Mat ( vx_int32 ( ( vx_int64 ) _addr . dim_y * VX_SCALE_UNITY / _addr . scale_y ) ,
vx_int32 ( ( vx_int64 ) _addr . dim_x * VX_SCALE_UNITY / _addr . scale_x ) ,
matType , _data , std : : size_t ( _addr . stride_y ) ) ;
# endif
}
/// vxUnmapImagePatch() wrapper (or vxCommitImagePatch() for 1.0)
void unmap ( )
{
# ifdef VX_VERSION_1_1
IVX_CHECK_STATUS ( vxUnmapImagePatch ( _img , _mapId ) ) ;
_mapId = 0 ;
# else
IVX_CHECK_STATUS ( vxCommitImagePatch ( _img , & _rect , _planeIdx , & _addr , _data ) ) ;
_rect . start_x = _rect . end_x = _rect . start_y = _rect . end_y = 0u ;
_planeIdx = - 1 ;
# endif
_img = 0 ;
_data = 0 ;
_addr = createAddressing ( ) ;
# ifdef IVX_USE_OPENCV
_m . release ( ) ;
# endif
}
/// Destructor
~ Patch ( )
{ try { if ( _img ) unmap ( ) ; } catch ( . . . ) { ; /*ignore*/ } }
/// Pointer to the specified pixel data (vxFormatImagePatchAddress2d)
void * pixelPtr ( vx_uint32 x , vx_uint32 y )
{
if ( ! _data ) throw WrapperError ( std : : string ( __func__ ) + " (): base pointer is NULL " ) ;
if ( x > = _addr . dim_x ) throw WrapperError ( std : : string ( __func__ ) + " (): X out of range " ) ;
if ( y > = _addr . dim_y ) throw WrapperError ( std : : string ( __func__ ) + " (): Y out of range " ) ;
return vxFormatImagePatchAddress2d ( _data , x , y , & _addr ) ;
}
private :
Patch ( const Patch & p ) ; // = delete
Patch & operator = ( const Patch & ) ; // = delete
# ifndef IVX_USE_CXX98
Patch & operator = ( Patch & & ) ; // = delete
# endif
} ;
/// vx_parameter wrapper
class Param : public RefWrapper < vx_parameter >
{
public :
IVX_REF_STD_CTORS_AND_ASSIGNMENT ( Param ) ;
// NYI
} ;
/// vx_scalar wrapper
class Scalar : public RefWrapper < vx_scalar >
{
public :
IVX_REF_STD_CTORS_AND_ASSIGNMENT ( Scalar ) ;
/// vxCreateScalar() wrapper
static Scalar create ( vx_context c , vx_enum dataType , const void * ptr )
{ return Scalar ( vxCreateScalar ( c , dataType , ptr ) ) ; }
/// vxCreateScalar() wrapper, value is passed as a value not as a pointer
template < typename T > static Scalar create ( vx_context c , vx_enum dataType , T value )
{
typedef int static_assert_not_pointer [ is_pointer < T > : : value ? - 1 : 1 ] ;
return Scalar ( vxCreateScalar ( c , dataType , & value ) ) ;
}
/// vxCreateScalar() wrapper, data type is guessed based on the passed value
template < vx_enum E > static Scalar create ( vx_context c , typename EnumToType < E > : : type value )
{ return Scalar ( vxCreateScalar ( c , E , & value ) ) ; }
# ifndef VX_VERSION_1_1
static const vx_enum VX_SCALAR_TYPE = VX_SCALAR_ATTRIBUTE_TYPE ;
# endif
/// Get scalar data type
vx_enum type ( )
{
vx_enum val ;
IVX_CHECK_STATUS ( vxQueryScalar ( ref , VX_SCALAR_TYPE , & val , sizeof ( val ) ) ) ;
return val ;
}
/// Get scalar value
template < typename T >
void getValue ( T & val )
{
if ( ! areTypesCompatible ( TypeToEnum < T > : : value , type ( ) ) )
throw WrapperError ( std : : string ( __func__ ) + " (): incompatible types " ) ;
# ifdef VX_VERSION_1_1
IVX_CHECK_STATUS ( vxCopyScalar ( ref , & val , VX_READ_ONLY , VX_MEMORY_TYPE_HOST ) ) ;
# else
IVX_CHECK_STATUS ( vxReadScalarValue ( ref , & val ) ) ;
# endif
}
/// Get scalar value
template < typename T >
T getValue ( )
{
T val ;
getValue ( val ) ;
return val ;
}
/// Set scalar value
template < typename T >
void setValue ( T val )
{
if ( ! areTypesCompatible ( TypeToEnum < T > : : value , type ( ) ) )
throw WrapperError ( std : : string ( __func__ ) + " (): incompatible types " ) ;
# ifdef VX_VERSION_1_1
IVX_CHECK_STATUS ( vxCopyScalar ( ref , & val , VX_WRITE_ONLY , VX_MEMORY_TYPE_HOST ) ) ;
# else
IVX_CHECK_STATUS ( vxWriteScalarValue ( ref , & val ) ) ;
# endif
}
} ;
/// vx_threshold wrapper
class Threshold : public RefWrapper < vx_threshold >
{
public :
IVX_REF_STD_CTORS_AND_ASSIGNMENT ( Threshold ) ;
/// vxCreateThreshold() wrapper
static Threshold create ( vx_context c , vx_enum threshType , vx_enum dataType )
{ return Threshold ( vxCreateThreshold ( c , threshType , dataType ) ) ; }
# ifndef VX_VERSION_1_1
static const vx_enum
VX_THRESHOLD_TYPE = VX_THRESHOLD_ATTRIBUTE_TYPE ,
VX_THRESHOLD_THRESHOLD_VALUE = VX_THRESHOLD_ATTRIBUTE_THRESHOLD_VALUE ,
VX_THRESHOLD_THRESHOLD_LOWER = VX_THRESHOLD_ATTRIBUTE_THRESHOLD_LOWER ,
VX_THRESHOLD_THRESHOLD_UPPER = VX_THRESHOLD_ATTRIBUTE_THRESHOLD_UPPER ,
VX_THRESHOLD_TRUE_VALUE = VX_THRESHOLD_ATTRIBUTE_TRUE_VALUE ,
VX_THRESHOLD_FALSE_VALUE = VX_THRESHOLD_ATTRIBUTE_FALSE_VALUE ,
VX_THRESHOLD_DATA_TYPE = VX_THRESHOLD_ATTRIBUTE_DATA_TYPE ;
# endif
/// Create binary threshold with the provided value
static Threshold createBinary ( vx_context c , vx_enum dataType , vx_int32 val )
{
Threshold thr = create ( c , VX_THRESHOLD_TYPE_BINARY , dataType ) ;
IVX_CHECK_STATUS ( vxSetThresholdAttribute ( thr . ref , VX_THRESHOLD_THRESHOLD_VALUE , & val , sizeof ( val ) ) ) ;
return thr ;
}
/// Create range threshold with the provided low and high values
static Threshold createRange ( vx_context c , vx_enum dataType , vx_int32 valLower , vx_int32 valUpper )
{
Threshold thr = create ( c , VX_THRESHOLD_TYPE_RANGE , dataType ) ;
IVX_CHECK_STATUS ( vxSetThresholdAttribute ( thr . ref , VX_THRESHOLD_THRESHOLD_LOWER , & valLower , sizeof ( valLower ) ) ) ;
IVX_CHECK_STATUS ( vxSetThresholdAttribute ( thr . ref , VX_THRESHOLD_THRESHOLD_UPPER , & valUpper , sizeof ( valUpper ) ) ) ;
return thr ;
}
/// vxQueryThreshold() wrapper
template < typename T >
void query ( vx_enum att , T & val ) const
{ IVX_CHECK_STATUS ( vxQueryThreshold ( ref , att , & val , sizeof ( val ) ) ) ; }
/// vxQueryThreshold(VX_THRESHOLD_TYPE) wrapper
vx_enum type ( ) const
{
vx_enum v ;
query ( VX_THRESHOLD_TYPE , v ) ;
return v ;
}
/// vxQueryThreshold(DATA_TYPE) wrapper
vx_enum dataType ( ) const
{
vx_enum v ;
query ( VX_THRESHOLD_DATA_TYPE , v ) ;
return v ;
}
/// vxQueryThreshold(THRESHOLD_VALUE) wrapper
vx_int32 value ( ) const
{
vx_int32 v ;
query ( VX_THRESHOLD_THRESHOLD_VALUE , v ) ;
return v ;
}
/// vxQueryThreshold(THRESHOLD_LOWER) wrapper
vx_int32 valueLower ( ) const
{
vx_int32 v ;
query ( VX_THRESHOLD_THRESHOLD_LOWER , v ) ;
return v ;
}
/// vxQueryThreshold(THRESHOLD_UPPER) wrapper
vx_int32 valueUpper ( ) const
{
vx_int32 v ;
query ( VX_THRESHOLD_THRESHOLD_UPPER , v ) ;
return v ;
}
/// vxQueryThreshold(TRUE_VALUE) wrapper
vx_int32 valueTrue ( ) const
{
vx_int32 v ;
query ( VX_THRESHOLD_TRUE_VALUE , v ) ;
return v ;
}
/// vxQueryThreshold(FALSE_VALUE) wrapper
vx_int32 valueFalse ( ) const
{
vx_int32 v ;
query ( VX_THRESHOLD_FALSE_VALUE , v ) ;
return v ;
}
/// vxSetThresholdAttribute(THRESHOLD_VALUE) wrapper
void setValue ( vx_int32 & val )
{ IVX_CHECK_STATUS ( vxSetThresholdAttribute ( ref , VX_THRESHOLD_THRESHOLD_VALUE , & val , sizeof ( val ) ) ) ; }
/// vxSetThresholdAttribute(THRESHOLD_LOWER) wrapper
void setValueLower ( vx_int32 & val )
{ IVX_CHECK_STATUS ( vxSetThresholdAttribute ( ref , VX_THRESHOLD_THRESHOLD_LOWER , & val , sizeof ( val ) ) ) ; }
/// vxSetThresholdAttribute(THRESHOLD_UPPER) wrapper
void setValueUpper ( vx_int32 & val )
{ IVX_CHECK_STATUS ( vxSetThresholdAttribute ( ref , VX_THRESHOLD_THRESHOLD_UPPER , & val , sizeof ( val ) ) ) ; }
/// vxSetThresholdAttribute(TRUE_VALUE) wrapper
void setValueTrue ( vx_int32 & val )
{ IVX_CHECK_STATUS ( vxSetThresholdAttribute ( ref , VX_THRESHOLD_TRUE_VALUE , & val , sizeof ( val ) ) ) ; }
/// vxSetThresholdAttribute(FALSE_VALUE) wrapper
void setValueFalse ( vx_int32 & val )
{ IVX_CHECK_STATUS ( vxSetThresholdAttribute ( ref , VX_THRESHOLD_FALSE_VALUE , & val , sizeof ( val ) ) ) ; }
} ;
/// vx_array wrapper
class Array : public RefWrapper < vx_array >
{
public :
IVX_REF_STD_CTORS_AND_ASSIGNMENT ( Array ) ;
/// vxCreateArray() wrapper
static Array create ( vx_context c , vx_enum type , vx_size capacity )
{ return Array ( vxCreateArray ( c , type , capacity ) ) ; }
/// vxCreateVirtualArray() wrapper
static Array createVirtual ( vx_graph g , vx_enum type , vx_size capacity )
{ return Array ( vxCreateVirtualArray ( g , type , capacity ) ) ; }
# ifndef VX_VERSION_1_1
static const vx_enum
VX_MEMORY_TYPE_HOST = VX_IMPORT_TYPE_HOST ,
VX_ARRAY_ITEMTYPE = VX_ARRAY_ATTRIBUTE_ITEMTYPE ,
VX_ARRAY_NUMITEMS = VX_ARRAY_ATTRIBUTE_NUMITEMS ,
VX_ARRAY_CAPACITY = VX_ARRAY_ATTRIBUTE_CAPACITY ,
VX_ARRAY_ITEMSIZE = VX_ARRAY_ATTRIBUTE_ITEMSIZE ;
# endif
template < typename T >
void query ( vx_enum att , T & value ) const
{ IVX_CHECK_STATUS ( vxQueryArray ( ref , att , & value , sizeof ( value ) ) ) ; }
vx_enum itemType ( ) const
{
vx_enum v ;
query ( VX_ARRAY_ITEMTYPE , v ) ;
return v ;
}
vx_size itemSize ( ) const
{
vx_size v ;
query ( VX_ARRAY_ITEMSIZE , v ) ;
return v ;
}
vx_size capacity ( ) const
{
vx_size v ;
query ( VX_ARRAY_CAPACITY , v ) ;
return v ;
}
vx_size itemCount ( ) const
{
vx_size v ;
query ( VX_ARRAY_NUMITEMS , v ) ;
return v ;
}
void addItems ( vx_size count , const void * ptr , vx_size stride )
{
IVX_CHECK_STATUS ( vxAddArrayItems ( ref , count , ptr , stride ) ) ;
}
void copyRangeTo ( size_t start , size_t end , void * data )
{
if ( ! data ) throw WrapperError ( std : : string ( __func__ ) + " (): output pointer is 0 " ) ;
# ifdef VX_VERSION_1_1
IVX_CHECK_STATUS ( vxCopyArrayRange ( ref , start , end , itemSize ( ) , data , VX_READ_ONLY , VX_MEMORY_TYPE_HOST ) ) ;
# else
vx_size stride = itemSize ( ) ;
IVX_CHECK_STATUS ( vxAccessArrayRange ( ref , start , end , & stride , & data , VX_READ_ONLY ) ) ;
IVX_CHECK_STATUS ( vxCommitArrayRange ( ref , start , end , data ) ) ;
# endif
}
void copyTo ( void * data )
{ copyRangeTo ( 0 , itemCount ( ) , data ) ; }
void copyRangeFrom ( size_t start , size_t end , const void * data )
{
if ( ! data ) throw WrapperError ( std : : string ( __func__ ) + " (): input pointer is 0 " ) ;
# ifdef VX_VERSION_1_1
IVX_CHECK_STATUS ( vxCopyArrayRange ( ref , start , end , itemSize ( ) , const_cast < void * > ( data ) , VX_WRITE_ONLY , VX_MEMORY_TYPE_HOST ) ) ;
# else
vx_size stride = itemSize ( ) ;
IVX_CHECK_STATUS ( vxAccessArrayRange ( ref , start , end , & stride , const_cast < void * * > ( & data ) , VX_WRITE_ONLY ) ) ;
IVX_CHECK_STATUS ( vxCommitArrayRange ( ref , start , end , data ) ) ;
# endif
}
void copyFrom ( const void * data )
{ copyRangeFrom ( 0 , itemCount ( ) , data ) ; }
void copyRange ( size_t start , size_t end , void * data , vx_enum usage , vx_enum memType = VX_MEMORY_TYPE_HOST )
{
if ( ! data ) throw WrapperError ( std : : string ( __func__ ) + " (): data pointer is 0 " ) ;
# ifdef VX_VERSION_1_1
IVX_CHECK_STATUS ( vxCopyArrayRange ( ref , start , end , itemSize ( ) , data , usage , memType ) ) ;
# else
vx_size stride = itemSize ( ) ;
IVX_CHECK_STATUS ( vxAccessArrayRange ( ref , start , end , & stride , & data , usage ) ) ;
IVX_CHECK_STATUS ( vxCommitArrayRange ( ref , start , end , data ) ) ;
( void ) memType ;
# endif
}
void copy ( void * data , vx_enum usage , vx_enum memType = VX_MEMORY_TYPE_HOST )
{ copyRange ( 0 , itemCount ( ) , data , usage , memType ) ; }
template < typename T > void addItem ( const T & item )
{
if ( ! areTypesCompatible ( TypeToEnum < T > : : value , itemType ( ) ) )
throw WrapperError ( std : : string ( __func__ ) + " (): destination type is wrong " ) ;
addItems ( 1 , & item , sizeof ( T ) ) ;
}
template < typename T > void addItems ( const std : : vector < T > & data )
{
if ( ! areTypesCompatible ( TypeToEnum < T > : : value , itemType ( ) ) )
throw WrapperError ( std : : string ( __func__ ) + " (): destination type is wrong " ) ;
addItems ( data . size ( ) , & data [ 0 ] , itemSize ( ) ) ;
}
template < typename T > void copyRangeTo ( size_t start , size_t end , std : : vector < T > & data )
{
if ( ! areTypesCompatible ( TypeToEnum < T > : : value , itemType ( ) ) )
throw WrapperError ( std : : string ( __func__ ) + " (): destination type is wrong " ) ;
if ( data . empty ( ) )
data . resize ( ( end - start ) ) ;
else if ( data . size ( ) ! = ( end - start ) )
{
throw WrapperError ( std : : string ( __func__ ) + " (): destination size is wrong " ) ;
}
copyRangeTo ( start , end , & data [ 0 ] ) ;
}
template < typename T > void copyTo ( std : : vector < T > & data )
{ copyRangeTo ( 0 , itemCount ( ) , data ) ; }
template < typename T > void copyRangeFrom ( size_t start , size_t end , const std : : vector < T > & data )
{
if ( ! areTypesCompatible ( TypeToEnum < T > : : value , itemType ( ) ) )
throw WrapperError ( std : : string ( __func__ ) + " (): source type is wrong " ) ;
if ( data . size ( ) ! = ( end - start ) ) throw WrapperError ( std : : string ( __func__ ) + " (): source size is wrong " ) ;
copyRangeFrom ( start , end , & data [ 0 ] ) ;
}
template < typename T > void copyFrom ( std : : vector < T > & data )
{ copyRangeFrom ( 0 , itemCount ( ) , data ) ; }
# ifdef IVX_USE_OPENCV
void addItems ( cv : : InputArray ia )
{
cv : : Mat m = ia . getMat ( ) ;
if ( m . type ( ) ! = enumToCVType ( itemType ( ) ) )
throw WrapperError ( std : : string ( __func__ ) + " (): destination type is wrong " ) ;
addItems ( m . total ( ) , m . isContinuous ( ) ? m . ptr ( ) : m . clone ( ) . ptr ( ) ,
( vx_size ) ( m . elemSize ( ) ) ) ;
}
void copyRangeTo ( size_t start , size_t end , cv : : Mat & m )
{
if ( m . type ( ) ! = enumToCVType ( itemType ( ) ) )
throw WrapperError ( std : : string ( __func__ ) + " (): destination type is wrong " ) ;
if ( ! (
( ( vx_size ) ( m . rows ) = = ( end - start ) & & m . cols = = 1 ) | |
( ( vx_size ) ( m . cols ) = = ( end - start ) & & m . rows = = 1 )
) & & ! m . empty ( ) )
throw WrapperError ( std : : string ( __func__ ) + " (): destination size is wrong " ) ;
if ( m . isContinuous ( ) & & ( vx_size ) ( m . total ( ) ) = = ( end - start ) )
{
copyRangeTo ( start , end , m . ptr ( ) ) ;
}
else
{
cv : : Mat tmp ( 1 , ( int ) ( end - start ) , enumToCVType ( itemType ( ) ) ) ;
copyRangeTo ( start , end , tmp . ptr ( ) ) ;
if ( m . empty ( ) )
m = tmp ;
else
tmp . copyTo ( m ) ;
}
}
void copyTo ( cv : : Mat & m )
{ copyRangeTo ( 0 , itemCount ( ) , m ) ; }
void copyRangeFrom ( size_t start , size_t end , const cv : : Mat & m )
{
if ( ! (
( ( vx_size ) ( m . rows ) = = ( end - start ) & & m . cols = = 1 ) | |
( ( vx_size ) ( m . cols ) = = ( end - start ) & & m . rows = = 1 )
) )
throw WrapperError ( std : : string ( __func__ ) + " (): source size is wrong " ) ;
if ( m . type ( ) ! = enumToCVType ( itemType ( ) ) )
throw WrapperError ( std : : string ( __func__ ) + " (): source type is wrong " ) ;
copyFrom ( m . isContinuous ( ) ? m . ptr ( ) : m . clone ( ) . ptr ( ) ) ;
}
void copyFrom ( const cv : : Mat & m )
{ copyRangeFrom ( 0 , itemCount ( ) , m ) ; }
# endif //IVX_USE_OPENCV
} ;
/*
* Convolution
*/
class Convolution : public RefWrapper < vx_convolution >
{
public :
IVX_REF_STD_CTORS_AND_ASSIGNMENT ( Convolution ) ;
static Convolution create ( vx_context context , vx_size columns , vx_size rows )
{ return Convolution ( vxCreateConvolution ( context , columns , rows ) ) ; }
# ifndef VX_VERSION_1_1
static const vx_enum
VX_MEMORY_TYPE_HOST = VX_IMPORT_TYPE_HOST ,
VX_CONVOLUTION_ROWS = VX_CONVOLUTION_ATTRIBUTE_ROWS ,
VX_CONVOLUTION_COLUMNS = VX_CONVOLUTION_ATTRIBUTE_COLUMNS ,
VX_CONVOLUTION_SCALE = VX_CONVOLUTION_ATTRIBUTE_SCALE ,
VX_CONVOLUTION_SIZE = VX_CONVOLUTION_ATTRIBUTE_SIZE ;
# endif
template < typename T >
void query ( vx_enum att , T & value ) const
{ IVX_CHECK_STATUS ( vxQueryConvolution ( ref , att , & value , sizeof ( value ) ) ) ; }
vx_size columns ( ) const
{
vx_size v ;
query ( VX_CONVOLUTION_COLUMNS , v ) ;
return v ;
}
vx_size rows ( ) const
{
vx_size v ;
query ( VX_CONVOLUTION_ROWS , v ) ;
return v ;
}
vx_uint32 scale ( ) const
{
vx_uint32 v ;
query ( VX_CONVOLUTION_SCALE , v ) ;
return v ;
}
vx_size size ( ) const
{
vx_size v ;
query ( VX_CONVOLUTION_SIZE , v ) ;
return v ;
}
vx_enum dataType ( )
{
return VX_TYPE_INT16 ;
}
void setScale ( vx_uint32 newScale )
{ IVX_CHECK_STATUS ( vxSetConvolutionAttribute ( ref , VX_CONVOLUTION_SCALE , & newScale , sizeof ( newScale ) ) ) ; }
void copyTo ( void * data )
{
if ( ! data ) throw WrapperError ( std : : string ( __func__ ) + " (): output pointer is 0 " ) ;
# ifdef VX_VERSION_1_1
IVX_CHECK_STATUS ( vxCopyConvolutionCoefficients ( ref , data , VX_READ_ONLY , VX_MEMORY_TYPE_HOST ) ) ;
# else
IVX_CHECK_STATUS ( vxReadConvolutionCoefficients ( ref , ( vx_int16 * ) data ) ) ;
# endif
}
void copyFrom ( const void * data )
{
if ( ! data ) throw WrapperError ( std : : string ( __func__ ) + " (): input pointer is 0 " ) ;
# ifdef VX_VERSION_1_1
IVX_CHECK_STATUS ( vxCopyConvolutionCoefficients ( ref , const_cast < void * > ( data ) , VX_WRITE_ONLY , VX_MEMORY_TYPE_HOST ) ) ;
# else
IVX_CHECK_STATUS ( vxWriteConvolutionCoefficients ( ref , ( const vx_int16 * ) data ) ) ;
# endif
}
void copy ( void * data , vx_enum usage , vx_enum memType = VX_MEMORY_TYPE_HOST )
{
if ( ! data ) throw WrapperError ( std : : string ( __func__ ) + " (): data pointer is 0 " ) ;
# ifdef VX_VERSION_1_1
IVX_CHECK_STATUS ( vxCopyConvolutionCoefficients ( ref , data , usage , memType ) ) ;
# else
if ( usage = = VX_READ_ONLY )
IVX_CHECK_STATUS ( vxReadConvolutionCoefficients ( ref , ( vx_int16 * ) data ) ) ;
else if ( usage = = VX_WRITE_ONLY )
IVX_CHECK_STATUS ( vxWriteConvolutionCoefficients ( ref , ( const vx_int16 * ) data ) ) ;
else
throw WrapperError ( std : : string ( __func__ ) + " (): unknown copy direction " ) ;
( void ) memType ;
# endif
}
template < typename T > void copyTo ( std : : vector < T > & data )
{
if ( ! areTypesCompatible ( TypeToEnum < T > : : value , dataType ( ) ) )
throw WrapperError ( std : : string ( __func__ ) + " (): destination type is wrong " ) ;
if ( data . size ( ) ! = size ( ) )
{
if ( data . size ( ) = = 0 )
data . resize ( size ( ) ) ;
else
throw WrapperError ( std : : string ( __func__ ) + " (): destination size is wrong " ) ;
}
copyTo ( & data [ 0 ] ) ;
}
template < typename T > void copyFrom ( const std : : vector < T > & data )
{
if ( ! areTypesCompatible ( TypeToEnum < T > : : value , dataType ( ) ) )
throw WrapperError ( std : : string ( __func__ ) + " (): source type is wrong " ) ;
if ( data . size ( ) ! = size ( ) ) throw WrapperError ( std : : string ( __func__ ) + " (): source size is wrong " ) ;
copyFrom ( & data [ 0 ] ) ;
}
# ifdef IVX_USE_OPENCV
void copyTo ( cv : : Mat & m )
{
if ( m . type ( ) ! = enumToCVType ( dataType ( ) ) ) throw WrapperError ( std : : string ( __func__ ) + " (): destination type is wrong " ) ;
if ( ( ( vx_size ) ( m . rows ) ! = rows ( ) | | ( vx_size ) ( m . cols ) ! = columns ( ) ) & & ! m . empty ( ) )
throw WrapperError ( std : : string ( __func__ ) + " (): destination size is wrong " ) ;
if ( m . isContinuous ( ) & & ( vx_size ) ( m . rows ) = = rows ( ) & & ( vx_size ) ( m . cols ) = = columns ( ) )
{
copyTo ( m . ptr ( ) ) ;
}
else
{
cv : : Mat tmp ( ( int ) rows ( ) , ( int ) columns ( ) , enumToCVType ( dataType ( ) ) ) ;
copyTo ( tmp . ptr ( ) ) ;
if ( m . empty ( ) )
m = tmp ;
else
tmp . copyTo ( m ) ;
}
}
void copyFrom ( const cv : : Mat & m )
{
if ( ( vx_size ) ( m . rows ) ! = rows ( ) | | ( vx_size ) ( m . cols ) ! = columns ( ) ) throw WrapperError ( std : : string ( __func__ ) + " (): source size is wrong " ) ;
if ( m . type ( ) ! = enumToCVType ( dataType ( ) ) ) throw WrapperError ( std : : string ( __func__ ) + " (): source type is wrong " ) ;
copyFrom ( m . isContinuous ( ) ? m . ptr ( ) : m . clone ( ) . ptr ( ) ) ;
}
# endif //IVX_USE_OPENCV
} ;
/*
* Matrix
*/
class Matrix : public RefWrapper < vx_matrix >
{
public :
IVX_REF_STD_CTORS_AND_ASSIGNMENT ( Matrix ) ;
static Matrix create ( vx_context context , vx_enum dataType , vx_size columns , vx_size rows )
{ return Matrix ( vxCreateMatrix ( context , dataType , columns , rows ) ) ; }
# ifdef VX_VERSION_1_1
static Matrix createFromPattern ( vx_context context , vx_enum pattern , vx_size columns , vx_size rows )
{ return Matrix ( vxCreateMatrixFromPattern ( context , pattern , columns , rows ) ) ; }
# endif
# ifndef VX_VERSION_1_1
static const vx_enum
VX_MEMORY_TYPE_HOST = VX_IMPORT_TYPE_HOST ,
VX_MATRIX_TYPE = VX_MATRIX_ATTRIBUTE_TYPE ,
VX_MATRIX_ROWS = VX_MATRIX_ATTRIBUTE_ROWS ,
VX_MATRIX_COLUMNS = VX_MATRIX_ATTRIBUTE_COLUMNS ,
VX_MATRIX_SIZE = VX_MATRIX_ATTRIBUTE_SIZE ;
# endif
template < typename T >
void query ( vx_enum att , T & value ) const
{ IVX_CHECK_STATUS ( vxQueryMatrix ( ref , att , & value , sizeof ( value ) ) ) ; }
vx_enum dataType ( ) const
{
vx_enum v ;
query ( VX_MATRIX_TYPE , v ) ;
return v ;
}
vx_size columns ( ) const
{
vx_size v ;
query ( VX_MATRIX_COLUMNS , v ) ;
return v ;
}
vx_size rows ( ) const
{
vx_size v ;
query ( VX_MATRIX_ROWS , v ) ;
return v ;
}
vx_size size ( ) const
{
vx_size v ;
query ( VX_MATRIX_SIZE , v ) ;
return v ;
}
# ifdef VX_VERSION_1_1
vx_coordinates2d_t origin ( ) const
{
vx_coordinates2d_t v ;
query ( VX_MATRIX_ORIGIN , v ) ;
return v ;
}
vx_enum pattern ( ) const
{
vx_enum v ;
query ( VX_MATRIX_PATTERN , v ) ;
return v ;
}
# endif // VX_VERSION_1_1
void copyTo ( void * data )
{
if ( ! data ) throw WrapperError ( std : : string ( __func__ ) + " (): output pointer is 0 " ) ;
# ifdef VX_VERSION_1_1
IVX_CHECK_STATUS ( vxCopyMatrix ( ref , data , VX_READ_ONLY , VX_MEMORY_TYPE_HOST ) ) ;
# else
IVX_CHECK_STATUS ( vxReadMatrix ( ref , data ) ) ;
# endif
}
void copyFrom ( const void * data )
{
if ( ! data ) throw WrapperError ( std : : string ( __func__ ) + " (): input pointer is 0 " ) ;
# ifdef VX_VERSION_1_1
IVX_CHECK_STATUS ( vxCopyMatrix ( ref , const_cast < void * > ( data ) , VX_WRITE_ONLY , VX_MEMORY_TYPE_HOST ) ) ;
# else
IVX_CHECK_STATUS ( vxWriteMatrix ( ref , data ) ) ;
# endif
}
void copy ( void * data , vx_enum usage , vx_enum memType = VX_MEMORY_TYPE_HOST )
{
if ( ! data ) throw WrapperError ( std : : string ( __func__ ) + " (): data pointer is 0 " ) ;
# ifdef VX_VERSION_1_1
IVX_CHECK_STATUS ( vxCopyMatrix ( ref , data , usage , memType ) ) ;
# else
if ( usage = = VX_READ_ONLY )
IVX_CHECK_STATUS ( vxReadMatrix ( ref , data ) ) ;
else if ( usage = = VX_WRITE_ONLY )
IVX_CHECK_STATUS ( vxWriteMatrix ( ref , data ) ) ;
else
throw WrapperError ( std : : string ( __func__ ) + " (): unknown copy direction " ) ;
( void ) memType ;
# endif
}
template < typename T > void copyTo ( std : : vector < T > & data )
{
if ( ! areTypesCompatible ( TypeToEnum < T > : : value , dataType ( ) ) )
throw WrapperError ( std : : string ( __func__ ) + " (): destination type is wrong " ) ;
if ( data . size ( ) ! = size ( ) )
{
if ( data . size ( ) = = 0 )
data . resize ( size ( ) ) ;
else
throw WrapperError ( std : : string ( __func__ ) + " (): destination size is wrong " ) ;
}
copyTo ( & data [ 0 ] ) ;
}
template < typename T > void copyFrom ( const std : : vector < T > & data )
{
if ( ! areTypesCompatible ( TypeToEnum < T > : : value , dataType ( ) ) )
throw WrapperError ( std : : string ( __func__ ) + " (): source type is wrong " ) ;
if ( data . size ( ) ! = size ( ) ) throw WrapperError ( std : : string ( __func__ ) + " (): source size is wrong " ) ;
copyFrom ( & data [ 0 ] ) ;
}
# ifdef IVX_USE_OPENCV
void copyTo ( cv : : Mat & m )
{
if ( m . type ( ) ! = enumToCVType ( dataType ( ) ) ) throw WrapperError ( std : : string ( __func__ ) + " (): destination type is wrong " ) ;
if ( ( ( vx_size ) ( m . rows ) ! = rows ( ) | | ( vx_size ) ( m . cols ) ! = columns ( ) ) & & ! m . empty ( ) )
throw WrapperError ( std : : string ( __func__ ) + " (): destination size is wrong " ) ;
if ( m . isContinuous ( ) & & ( vx_size ) ( m . rows ) = = rows ( ) & & ( vx_size ) ( m . cols ) = = columns ( ) )
{
copyTo ( m . ptr ( ) ) ;
}
else
{
cv : : Mat tmp ( ( int ) rows ( ) , ( int ) columns ( ) , enumToCVType ( dataType ( ) ) ) ;
copyTo ( tmp . ptr ( ) ) ;
if ( m . empty ( ) )
m = tmp ;
else
tmp . copyTo ( m ) ;
}
}
void copyFrom ( const cv : : Mat & m )
{
if ( ( vx_size ) ( m . rows ) ! = rows ( ) | | ( vx_size ) ( m . cols ) ! = columns ( ) ) throw WrapperError ( std : : string ( __func__ ) + " (): source size is wrong " ) ;
if ( m . type ( ) ! = enumToCVType ( dataType ( ) ) ) throw WrapperError ( std : : string ( __func__ ) + " (): source type is wrong " ) ;
copyFrom ( m . isContinuous ( ) ? m . ptr ( ) : m . clone ( ) . ptr ( ) ) ;
}
# endif //IVX_USE_OPENCV
} ;
/*
* LUT
*/
class LUT : public RefWrapper < vx_lut >
{
public :
IVX_REF_STD_CTORS_AND_ASSIGNMENT ( LUT ) ;
# ifdef VX_VERSION_1_1
static LUT create ( vx_context context , vx_enum dataType = VX_TYPE_UINT8 , vx_size count = 256 )
{
# else
static LUT create ( vx_context context )
{
vx_enum dataType = VX_TYPE_UINT8 ;
vx_size count = 256 ;
# endif
return LUT ( vxCreateLUT ( context , dataType , count ) ) ;
}
# ifndef VX_VERSION_1_1
static const vx_enum VX_MEMORY_TYPE_HOST = VX_IMPORT_TYPE_HOST ;
# endif
template < typename T >
void query ( vx_enum att , T & value ) const
{
IVX_CHECK_STATUS ( vxQueryLUT ( ref , att , & value , sizeof ( value ) ) ) ;
}
# ifndef VX_VERSION_1_1
static const vx_enum
VX_LUT_TYPE = VX_LUT_ATTRIBUTE_TYPE ,
VX_LUT_COUNT = VX_LUT_ATTRIBUTE_COUNT ,
VX_LUT_SIZE = VX_LUT_ATTRIBUTE_SIZE ;
# endif
vx_enum dataType ( ) const
{
vx_enum v ;
query ( VX_LUT_TYPE , v ) ;
return v ;
}
vx_size count ( ) const
{
vx_size v ;
query ( VX_LUT_COUNT , v ) ;
return v ;
}
vx_size size ( ) const
{
vx_size v ;
query ( VX_LUT_SIZE , v ) ;
return v ;
}
# ifdef VX_VERSION_1_1
vx_uint32 offset ( ) const
{
vx_enum v ;
query ( VX_LUT_OFFSET , v ) ;
return v ;
}
# endif // VX_VERSION_1_1
void copyTo ( void * data )
{
if ( ! data ) throw WrapperError ( std : : string ( __func__ ) + " (): output pointer is 0 " ) ;
# ifdef VX_VERSION_1_1
IVX_CHECK_STATUS ( vxCopyLUT ( ref , data , VX_READ_ONLY , VX_MEMORY_TYPE_HOST ) ) ;
# else
IVX_CHECK_STATUS ( vxAccessLUT ( ref , & data , VX_READ_ONLY ) ) ;
IVX_CHECK_STATUS ( vxCommitLUT ( ref , data ) ) ;
# endif
}
void copyFrom ( const void * data )
{
if ( ! data ) throw WrapperError ( std : : string ( __func__ ) + " (): input pointer is 0 " ) ;
# ifdef VX_VERSION_1_1
IVX_CHECK_STATUS ( vxCopyLUT ( ref , const_cast < void * > ( data ) , VX_WRITE_ONLY , VX_MEMORY_TYPE_HOST ) ) ;
# else
IVX_CHECK_STATUS ( vxAccessLUT ( ref , const_cast < void * * > ( & data ) , VX_WRITE_ONLY ) ) ;
IVX_CHECK_STATUS ( vxCommitLUT ( ref , data ) ) ;
# endif
}
void copy ( void * data , vx_enum usage , vx_enum memType = VX_MEMORY_TYPE_HOST )
{
# ifdef VX_VERSION_1_1
IVX_CHECK_STATUS ( vxCopyLUT ( ref , data , usage , memType ) ) ;
# else
IVX_CHECK_STATUS ( vxAccessLUT ( ref , const_cast < void * * > ( & data ) , usage ) ) ;
IVX_CHECK_STATUS ( vxCommitLUT ( ref , data ) ) ;
( void ) memType ;
# endif
}
template < typename T > void copyTo ( std : : vector < T > & data )
{
if ( ! areTypesCompatible ( TypeToEnum < T > : : value , dataType ( ) ) )
throw WrapperError ( std : : string ( __func__ ) + " (): destination type is wrong " ) ;
if ( data . size ( ) ! = count ( ) )
{
if ( data . size ( ) = = 0 )
data . resize ( count ( ) ) ;
else
throw WrapperError ( std : : string ( __func__ ) + " (): destination size is wrong " ) ;
}
copyTo ( & data [ 0 ] ) ;
}
template < typename T > void copyFrom ( const std : : vector < T > & data )
{
if ( ! areTypesCompatible ( TypeToEnum < T > : : value , dataType ( ) ) )
throw WrapperError ( std : : string ( __func__ ) + " (): source type is wrong " ) ;
if ( data . size ( ) ! = count ( ) ) throw WrapperError ( std : : string ( __func__ ) + " (): source size is wrong " ) ;
copyFrom ( & data [ 0 ] ) ;
}
# ifdef IVX_USE_OPENCV
void copyTo ( cv : : Mat & m )
{
if ( m . type ( ) ! = enumToCVType ( dataType ( ) ) ) throw WrapperError ( std : : string ( __func__ ) + " (): destination type is wrong " ) ;
if ( ! (
( ( vx_size ) ( m . rows ) = = count ( ) & & m . cols = = 1 ) | |
( ( vx_size ) ( m . cols ) = = count ( ) & & m . rows = = 1 )
) & & ! m . empty ( ) )
throw WrapperError ( std : : string ( __func__ ) + " (): destination size is wrong " ) ;
if ( m . isContinuous ( ) & & ( vx_size ) ( m . total ( ) ) = = count ( ) )
{
copyTo ( m . ptr ( ) ) ;
}
else
{
cv : : Mat tmp ( 1 , ( int ) count ( ) , enumToCVType ( dataType ( ) ) ) ;
copyTo ( tmp . ptr ( ) ) ;
if ( m . empty ( ) )
m = tmp ;
else
tmp . copyTo ( m ) ;
}
}
void copyFrom ( const cv : : Mat & m )
{
if ( ! (
( ( vx_size ) ( m . rows ) = = count ( ) & & m . cols = = 1 ) | |
( ( vx_size ) ( m . cols ) = = count ( ) & & m . rows = = 1 )
) ) throw WrapperError ( std : : string ( __func__ ) + " (): source size is wrong " ) ;
if ( m . type ( ) ! = enumToCVType ( dataType ( ) ) ) throw WrapperError ( std : : string ( __func__ ) + " (): source type is wrong " ) ;
copyFrom ( m . isContinuous ( ) ? m . ptr ( ) : m . clone ( ) . ptr ( ) ) ;
}
# endif //IVX_USE_OPENCV
} ;
/// Standard nodes
namespace nodes {
/// Creates a Gaussian Filter 3x3 Node (vxGaussian3x3Node)
inline Node gaussian3x3 ( vx_graph graph , vx_image inImg , vx_image outImg )
{ return Node ( vxGaussian3x3Node ( graph , inImg , outImg ) ) ; }
} // namespace nodes
} // namespace ivx
// restore warnings
# if defined(_MSC_VER)
# pragma warning(pop)
# elif defined(__clang__)
# pragma clang diagnostic pop
# elif defined(__GNUC__)
# pragma GCC diagnostic pop
# endif // compiler macro
# endif //IVX_HPP