ecency-mobile/ios/Pods/boost-for-react-native/boost/gil/algorithm.hpp

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/*
Copyright 2005-2007 Adobe Systems Incorporated
Use, modification and distribution are subject to the Boost Software License,
Version 1.0. (See accompanying file LICENSE_1_0.txt or copy at
http://www.boost.org/LICENSE_1_0.txt).
See http://opensource.adobe.com/gil for most recent version including documentation.
*/
/*************************************************************************************************/
#ifndef GIL_ALGORITHM_HPP
#define GIL_ALGORITHM_HPP
#include <cassert>
#include <cstddef>
#include <cstring>
#include <algorithm>
#include <iterator>
#include <memory>
#include <typeinfo>
#include "gil_config.hpp"
#include "gil_concept.hpp"
#include "color_base_algorithm.hpp"
#include "image_view.hpp"
#include "image_view_factory.hpp"
#include "bit_aligned_pixel_iterator.hpp"
////////////////////////////////////////////////////////////////////////////////////////
/// \file
/// \brief Some basic STL-style algorithms when applied to image views
/// \author Lubomir Bourdev and Hailin Jin \n
/// Adobe Systems Incorporated
/// \date 2005-2008 \n Last updated on March 12, 2008
///
////////////////////////////////////////////////////////////////////////////////////////
//#ifdef _MSC_VER
//#pragma warning(push)
//#pragma warning(disable : 4244) // conversion from 'gil::image<V,Alloc>::coord_t' to 'int', possible loss of data (visual studio compiler doesn't realize that the two types are the same)
//#endif
namespace boost { namespace gil {
//forward declarations
template <typename ChannelPtr, typename ColorSpace>
struct planar_pixel_iterator;
template <typename Iterator>
class memory_based_step_iterator;
template <typename StepIterator>
class memory_based_2d_locator;
// a tag denoting incompatible arguments
struct error_t {};
/// \defgroup ImageViewSTLAlgorithms STL-like Algorithms
/// \ingroup ImageViewAlgorithm
/// \brief Image view-equivalents of STL algorithms
///
/// Image views provide 1D iteration of their pixels via \p begin() and \p end() methods,
/// which makes it possible to use STL algorithms with them. However, using nested loops
/// over X and Y is in many cases more efficient. The algorithms in this section resemble
/// STL algorithms, but they abstract away the nested loops and take views (as opposed to ranges) as input.
///
/// Most algorithms check whether the image views are 1D-traversable. A 1D-traversable image view has no gaps
/// at the end of the rows. In other words, if an x_iterator of that view is advanced past the last pixel in a row
/// it will move to the first pixel of the next row. When image views are 1D-traversable, the algorithms use
/// a single loop and run more efficiently. If one or more of the input views are not 1D-traversable, the algorithms
/// fall-back to an X-loop nested inside a Y-loop.
///
/// The algorithms typically delegate the work to their corresponding STL algorithms. For example, \p copy_pixels calls
/// \p std::copy either for each row, or, when the images are 1D-traversable, once for all pixels.
///
/// In addition, overloads are sometimes provided for the STL algorithms. For example, std::copy for planar iterators
/// is overloaded to perform \p std::copy for each of the planes. \p std::copy over bitwise-copiable pixels results in
/// std::copy over unsigned char, which STL typically implements via \p memmove.
///
/// As a result \p copy_pixels may result in a single call to \p memmove for interleaved 1D-traversable views,
/// or one per each plane of planar 1D-traversable views, or one per each row of interleaved non-1D-traversable images, etc.
/// \defgroup STLOptimizations Performance overloads of STL algorithms
/// \ingroup ImageViewAlgorithm
/// \brief overloads of STL algorithms allowing more efficient implementation when used with GIL constructs
/// \brief A generic binary operation on views
/// \ingroup ImageViewSTLAlgorithms
///
/// Use this class as a convenience superclass when defining an operation for any image views.
/// Many operations have different behavior when the two views are compatible. This class checks
/// for compatibility and invokes apply_compatible(V1,V2) or apply_incompatible(V1,V2) of the subclass.
/// You must provide apply_compatible(V1,V2) method in your subclass, but apply_incompatible(V1,V2)
/// is not required and the default throws std::bad_cast.
template <typename Derived, typename Result=void>
struct binary_operation_obj {
typedef Result result_type;
template <typename V1, typename V2> GIL_FORCEINLINE
result_type operator()(const std::pair<const V1*,const V2*>& p) const {
return apply(*p.first, *p.second, typename views_are_compatible<V1,V2>::type());
}
template <typename V1, typename V2> GIL_FORCEINLINE
result_type operator()(const V1& v1, const V2& v2) const {
return apply(v1, v2, typename views_are_compatible<V1,V2>::type());
}
result_type operator()(const error_t&) const { throw std::bad_cast(); }
private:
// dispatch from apply overload to a function with distinct name
template <typename V1, typename V2>
GIL_FORCEINLINE result_type apply(const V1& v1, const V2& v2, mpl::false_) const {
return ((const Derived*)this)->apply_incompatible(v1,v2);
}
// dispatch from apply overload to a function with distinct name
template <typename V1, typename V2>
GIL_FORCEINLINE result_type apply(const V1& v1, const V2& v2, mpl::true_) const {
return ((const Derived*)this)->apply_compatible(v1,v2);
}
// function with distinct name - it can be overloaded by subclasses
template <typename V1, typename V2>
GIL_FORCEINLINE result_type apply_incompatible(const V1& v1, const V2& v2) const {
throw std::bad_cast();
}
};
} } // namespace boost::gil
//////////////////////////////////////////////////////////////////////////////////////
///
/// std::copy and gil::copy_pixels
///
//////////////////////////////////////////////////////////////////////////////////////
/// \defgroup ImageViewSTLAlgorithmsCopyPixels copy_pixels
/// \ingroup ImageViewSTLAlgorithms
/// \brief std::copy for image views
namespace std {
/// \ingroup STLOptimizations
/// \brief Copy when both src and dst are interleaved and of the same type can be just memmove
template<typename T, typename Cs>
GIL_FORCEINLINE boost::gil::pixel<T,Cs>*
copy(boost::gil::pixel<T,Cs>* first, boost::gil::pixel<T,Cs>* last,
boost::gil::pixel<T,Cs>* dst) {
return (boost::gil::pixel<T,Cs>*)std::copy((unsigned char*)first,(unsigned char*)last, (unsigned char*)dst);
}
/// \ingroup STLOptimizations
/// \brief Copy when both src and dst are interleaved and of the same type can be just memmove
template<typename T, typename Cs>
GIL_FORCEINLINE boost::gil::pixel<T,Cs>*
copy(const boost::gil::pixel<T,Cs>* first, const boost::gil::pixel<T,Cs>* last,
boost::gil::pixel<T,Cs>* dst) {
return (boost::gil::pixel<T,Cs>*)std::copy((unsigned char*)first,(unsigned char*)last, (unsigned char*)dst);
}
} // namespace std
namespace boost { namespace gil {
namespace detail {
template <typename I, typename O> struct copy_fn {
GIL_FORCEINLINE I operator()(I first, I last, O dst) const { return std::copy(first,last,dst); }
};
} // namespace detail
} } // namespace boost::gil
namespace std {
/// \ingroup STLOptimizations
/// \brief Copy when both src and dst are planar pointers is copy for each channel
template<typename Cs, typename IC1, typename IC2> GIL_FORCEINLINE
boost::gil::planar_pixel_iterator<IC2,Cs> copy(boost::gil::planar_pixel_iterator<IC1,Cs> first, boost::gil::planar_pixel_iterator<IC1,Cs> last, boost::gil::planar_pixel_iterator<IC2,Cs> dst) {
boost::gil::gil_function_requires<boost::gil::ChannelsCompatibleConcept<typename std::iterator_traits<IC1>::value_type,typename std::iterator_traits<IC2>::value_type> >();
static_for_each(first,last,dst,boost::gil::detail::copy_fn<IC1,IC2>());
return dst+(last-first);
}
} // namespace std
namespace boost { namespace gil {
namespace detail {
/// Does a copy-n. If the inputs contain image iterators, performs a copy at each row using the row iterators
/// \ingroup CopyPixels
template <typename I, typename O>
struct copier_n {
GIL_FORCEINLINE void operator()(I src, typename std::iterator_traits<I>::difference_type n, O dst) const { std::copy(src,src+n, dst); }
};
/// Source range is delimited by image iterators
template <typename IL, typename O> // IL Models ConstPixelLocatorConcept, O Models PixelIteratorConcept
struct copier_n<iterator_from_2d<IL>,O> {
typedef typename std::iterator_traits<iterator_from_2d<IL> >::difference_type diff_t;
GIL_FORCEINLINE void operator()(iterator_from_2d<IL> src, diff_t n, O dst) const {
gil_function_requires<PixelLocatorConcept<IL> >();
gil_function_requires<MutablePixelIteratorConcept<O> >();
while (n>0) {
typedef typename iterator_from_2d<IL>::difference_type diff_t;
diff_t l=src.width()-src.x_pos();
diff_t numToCopy=(n<l ? n:l);
detail::copy_n(src.x(), numToCopy, dst);
dst+=numToCopy;
src+=numToCopy;
n-=numToCopy;
}
}
};
/// Destination range is delimited by image iterators
template <typename I, typename OL> // I Models ConstPixelIteratorConcept, OL Models PixelLocatorConcept
struct copier_n<I,iterator_from_2d<OL> > {
typedef typename std::iterator_traits<I>::difference_type diff_t;
GIL_FORCEINLINE void operator()(I src, diff_t n, iterator_from_2d<OL> dst) const {
gil_function_requires<PixelIteratorConcept<I> >();
gil_function_requires<MutablePixelLocatorConcept<OL> >();
while (n>0) {
diff_t l=dst.width()-dst.x_pos();
diff_t numToCopy=(n<l ? n:l);
detail::copy_n(src, numToCopy, dst.x());
dst+=numToCopy;
src+=numToCopy;
n-=numToCopy;
}
}
};
/// Both source and destination ranges are delimited by image iterators
template <typename IL, typename OL>
struct copier_n<iterator_from_2d<IL>,iterator_from_2d<OL> > {
typedef typename iterator_from_2d<IL>::difference_type diff_t;
GIL_FORCEINLINE void operator()(iterator_from_2d<IL> src, diff_t n, iterator_from_2d<OL> dst) const {
gil_function_requires<PixelLocatorConcept<IL> >();
gil_function_requires<MutablePixelLocatorConcept<OL> >();
if (src.x_pos()!=dst.x_pos() || src.width()!=dst.width()) {
while(n-->0) {
*dst++=*src++;
}
}
while (n>0) {
diff_t l=dst.width()-dst.x_pos();
diff_t numToCopy=(n<l ? n : l);
detail::copy_n(src.x(), numToCopy, dst.x());
dst+=numToCopy;
src+=numToCopy;
n-=numToCopy;
}
}
};
template <typename SrcIterator, typename DstIterator>
GIL_FORCEINLINE DstIterator copy_with_2d_iterators(SrcIterator first, SrcIterator last, DstIterator dst) {
typedef typename SrcIterator::x_iterator src_x_iterator;
typedef typename DstIterator::x_iterator dst_x_iterator;
typename SrcIterator::difference_type n = last - first;
if (first.is_1d_traversable()) {
if (dst.is_1d_traversable())
copier_n<src_x_iterator,dst_x_iterator>()(first.x(),n, dst.x());
else
copier_n<src_x_iterator,DstIterator >()(first.x(),n, dst);
} else {
if (dst.is_1d_traversable())
copier_n<SrcIterator,dst_x_iterator>()(first,n, dst.x());
else
copier_n<SrcIterator,DstIterator>()(first,n,dst);
}
return dst+n;
}
} // namespace detail
} } // namespace boost::gil
namespace std {
/// \ingroup STLOptimizations
/// \brief std::copy(I1,I1,I2) with I1 and I2 being a iterator_from_2d
template <typename IL, typename OL>
GIL_FORCEINLINE boost::gil::iterator_from_2d<OL> copy1(boost::gil::iterator_from_2d<IL> first, boost::gil::iterator_from_2d<IL> last, boost::gil::iterator_from_2d<OL> dst) {
return boost::gil::detail::copy_with_2d_iterators(first,last,dst);
}
} // namespace std
namespace boost { namespace gil {
/// \ingroup ImageViewSTLAlgorithmsCopyPixels
/// \brief std::copy for image views
template <typename View1, typename View2> GIL_FORCEINLINE
void copy_pixels(const View1& src, const View2& dst) {
assert(src.dimensions()==dst.dimensions());
detail::copy_with_2d_iterators(src.begin(),src.end(),dst.begin());
}
//////////////////////////////////////////////////////////////////////////////////////
///
/// copy_and_convert_pixels
///
//////////////////////////////////////////////////////////////////////////////////////
/// \defgroup ImageViewSTLAlgorithmsCopyAndConvertPixels copy_and_convert_pixels
/// \ingroup ImageViewSTLAlgorithms
/// \brief copies src view into dst view, color converting if necessary.
///
/// Versions taking static and runtime views are provided. Versions taking user-defined color convered are provided.
namespace detail {
template <typename CC>
class copy_and_convert_pixels_fn : public binary_operation_obj<copy_and_convert_pixels_fn<CC> > {
private:
CC _cc;
public:
typedef typename binary_operation_obj<copy_and_convert_pixels_fn<CC> >::result_type result_type;
copy_and_convert_pixels_fn() {}
copy_and_convert_pixels_fn(CC cc_in) : _cc(cc_in) {}
// when the two color spaces are incompatible, a color conversion is performed
template <typename V1, typename V2> GIL_FORCEINLINE
result_type apply_incompatible(const V1& src, const V2& dst) const {
copy_pixels(color_converted_view<typename V2::value_type>(src,_cc),dst);
}
// If the two color spaces are compatible, copy_and_convert is just copy
template <typename V1, typename V2> GIL_FORCEINLINE
result_type apply_compatible(const V1& src, const V2& dst) const {
copy_pixels(src,dst);
}
};
} // namespace detail
/// \ingroup ImageViewSTLAlgorithmsCopyAndConvertPixels
template <typename V1, typename V2,typename CC>
GIL_FORCEINLINE
void copy_and_convert_pixels(const V1& src, const V2& dst,CC cc) {
detail::copy_and_convert_pixels_fn<CC> ccp(cc);
ccp(src,dst);
}
struct default_color_converter;
/// \ingroup ImageViewSTLAlgorithmsCopyAndConvertPixels
template <typename View1, typename View2>
GIL_FORCEINLINE
void copy_and_convert_pixels(const View1& src, const View2& dst) {
detail::copy_and_convert_pixels_fn<default_color_converter> ccp;
ccp(src,dst);
}
} } // namespace boost::gil
//////////////////////////////////////////////////////////////////////////////////////
//
// std::fill and gil::fill_pixels
//
//////////////////////////////////////////////////////////////////////////////////////
/// \defgroup ImageViewSTLAlgorithmsFillPixels fill_pixels
/// \ingroup ImageViewSTLAlgorithms
/// \brief std::fill for image views
namespace std {
/// \ingroup STLOptimizations
/// \brief std::fill(I,I,V) with I being a iterator_from_2d
///
/// Invoked when one calls std::fill(I,I,V) with I being a iterator_from_2d (which is
/// a 1D iterator over the pixels in an image). For contiguous images (i.e. images that have
/// no alignment gap at the end of each row) it is more efficient to use the underlying
/// pixel iterator that does not check for the end of rows. For non-contiguous images fill
/// resolves to fill of each row using the underlying pixel iterator, which is still faster
template <typename IL, typename V>
void fill(boost::gil::iterator_from_2d<IL> first, boost::gil::iterator_from_2d<IL> last, const V& val) {
boost::gil::gil_function_requires<boost::gil::MutablePixelLocatorConcept<IL> >();
if (first.is_1d_traversable()) {
std::fill(first.x(), last.x(), val);
} else {
// fill row by row
std::ptrdiff_t n=last-first;
while (n>0) {
std::ptrdiff_t numToDo=std::min<const std::ptrdiff_t>(n,(std::ptrdiff_t)(first.width()-first.x_pos()));
fill_n(first.x(), numToDo, val);
first+=numToDo;
n-=numToDo;
}
}
}
} // namespace std
namespace boost { namespace gil {
namespace detail {
/// struct to do std::fill
struct std_fill_t {
template <typename It, typename P>
void operator()(It first, It last, const P& p_in) {
std::fill(first,last,p_in);
}
};
/// std::fill for planar iterators
template <typename It, typename P>
GIL_FORCEINLINE
void fill_aux(It first, It last, const P& p, mpl::true_) {
static_for_each(first,last,p,std_fill_t());
}
/// std::fill for interleaved iterators
template <typename It, typename P>
GIL_FORCEINLINE
void fill_aux(It first, It last, const P& p,mpl::false_) {
std::fill(first,last,p);
}
} // namespace detail
/// \ingroup ImageViewSTLAlgorithmsFillPixels
/// \brief std::fill for image views
template <typename View, typename Value> GIL_FORCEINLINE
void fill_pixels(const View& img_view, const Value& val) {
if (img_view.is_1d_traversable())
detail::fill_aux(img_view.begin().x(), img_view.end().x(),
val,is_planar<View>());
else
for (std::ptrdiff_t y=0; y<img_view.height(); ++y)
detail::fill_aux(img_view.row_begin(y),img_view.row_end(y),
val,is_planar<View>());
}
//////////////////////////////////////////////////////////////////////////////////////
///
/// destruct_pixels
///
//////////////////////////////////////////////////////////////////////////////////////
/// \defgroup ImageViewSTLAlgorithmsDestructPixels destruct_pixels
/// \ingroup ImageViewSTLAlgorithms
/// \brief invokes the destructor on every pixel of an image view
namespace detail {
template <typename It> GIL_FORCEINLINE
void destruct_range_impl(It first, It last, mpl::true_) {
typedef typename std::iterator_traits<It>::value_type value_t;
if (boost::has_trivial_destructor<value_t>::value)
return;
while (first!=last) {
first->~value_t();
++first;
}
}
template <typename It> GIL_FORCEINLINE
void destruct_range_impl(It, It, mpl::false_) {}
template <typename It> GIL_FORCEINLINE
void destruct_range(It first, It last) {
destruct_range_impl(first,last,typename is_pointer<It>::type());
}
struct std_destruct_t {
template <typename It> void operator()(It first, It last) const { destruct_range(first,last); }
};
/// destruct for planar iterators
template <typename It>
GIL_FORCEINLINE
void destruct_aux(It first, It last, mpl::true_) {
static_for_each(first,last,std_destruct_t());
}
/// destruct for interleaved iterators
template <typename It>
GIL_FORCEINLINE
void destruct_aux(It first, It last, mpl::false_) {
destruct_range(first,last);
}
} // namespace detail
/// \ingroup ImageViewSTLAlgorithmsDestructPixels
/// \brief Invokes the in-place destructor on every pixel of the view
template <typename View> GIL_FORCEINLINE
void destruct_pixels(const View& img_view) {
if (img_view.is_1d_traversable())
detail::destruct_aux(img_view.begin().x(), img_view.end().x(),
is_planar<View>());
else
for (std::ptrdiff_t y=0; y<img_view.height(); ++y)
detail::destruct_aux(img_view.row_begin(y),img_view.row_end(y),
is_planar<View>());
}
//////////////////////////////////////////////////////////////////////////////////////
///
/// uninitialized_fill_pixels
///
//////////////////////////////////////////////////////////////////////////////////////
/// \defgroup ImageViewSTLAlgorithmsUninitializedFillPixels uninitialized_fill_pixels
/// \ingroup ImageViewSTLAlgorithms
/// \brief std::uninitialized_fill for image views
namespace detail {
/// std::uninitialized_fill for planar iterators
/// If an exception is thrown destructs any in-place copy-constructed objects
template <typename It, typename P>
GIL_FORCEINLINE
void uninitialized_fill_aux(It first, It last,
const P& p, mpl::true_) {
int channel=0;
try {
typedef typename std::iterator_traits<It>::value_type pixel_t;
while (channel < num_channels<pixel_t>::value) {
std::uninitialized_fill(dynamic_at_c(first,channel), dynamic_at_c(last,channel),
dynamic_at_c(p,channel));
++channel;
}
} catch (...) {
for (int c=0; c<channel; ++c)
destruct_range(dynamic_at_c(first,c), dynamic_at_c(last,c));
throw;
}
}
/// std::uninitialized_fill for interleaved iterators
/// If an exception is thrown destructs any in-place copy-constructed objects
template <typename It, typename P>
GIL_FORCEINLINE
void uninitialized_fill_aux(It first, It last,
const P& p,mpl::false_) {
std::uninitialized_fill(first,last,p);
}
} // namespace detail
/// \ingroup ImageViewSTLAlgorithmsUninitializedFillPixels
/// \brief std::uninitialized_fill for image views.
/// Does not support planar heterogeneous views.
/// If an exception is thrown destructs any in-place copy-constructed pixels
template <typename View, typename Value>
void uninitialized_fill_pixels(const View& img_view, const Value& val) {
if (img_view.is_1d_traversable())
detail::uninitialized_fill_aux(img_view.begin().x(), img_view.end().x(),
val,is_planar<View>());
else {
typename View::y_coord_t y;
try {
for (y=0; y<img_view.height(); ++y)
detail::uninitialized_fill_aux(img_view.row_begin(y),img_view.row_end(y),
val,is_planar<View>());
} catch(...) {
for (typename View::y_coord_t y0=0; y0<y; ++y0)
detail::destruct_aux(img_view.row_begin(y0),img_view.row_end(y0), is_planar<View>());
throw;
}
}
}
//////////////////////////////////////////////////////////////////////////////////////
///
/// default_construct_pixels
///
//////////////////////////////////////////////////////////////////////////////////////
/// \defgroup ImageViewSTLAlgorithmsDefaultConstructPixels default_construct_pixels
/// \ingroup ImageViewSTLAlgorithms
/// \brief invokes the default constructor on every pixel of an image view
namespace detail {
template <typename It> GIL_FORCEINLINE
void default_construct_range_impl(It first, It last, mpl::true_) {
typedef typename std::iterator_traits<It>::value_type value_t;
It first1=first;
try {
while (first!=last) {
new (first) value_t();
++first;
}
} catch (...) {
destruct_range(first1,first);
throw;
}
}
template <typename It> GIL_FORCEINLINE
void default_construct_range_impl(It, It, mpl::false_) {}
template <typename It> GIL_FORCEINLINE
void default_construct_range(It first, It last) { default_construct_range_impl(first, last, typename is_pointer<It>::type()); }
/// uninitialized_default_construct for planar iterators
template <typename It>
GIL_FORCEINLINE
void default_construct_aux(It first, It last, mpl::true_) {
int channel=0;
try {
typedef typename std::iterator_traits<It>::value_type pixel_t;
while (channel < num_channels<pixel_t>::value) {
default_construct_range(dynamic_at_c(first,channel), dynamic_at_c(last,channel));
++channel;
}
} catch (...) {
for (int c=0; c<channel; ++c)
destruct_range(dynamic_at_c(first,c), dynamic_at_c(last,c));
throw;
}
}
/// uninitialized_default_construct for interleaved iterators
template <typename It>
GIL_FORCEINLINE
void default_construct_aux(It first, It last, mpl::false_) {
default_construct_range(first,last);
}
template <typename View, bool IsPlanar>
struct has_trivial_pixel_constructor : public boost::has_trivial_constructor<typename View::value_type> {};
template <typename View>
struct has_trivial_pixel_constructor<View, true> : public boost::has_trivial_constructor<typename channel_type<View>::type> {};
} // namespace detail
/// \ingroup ImageViewSTLAlgorithmsDefaultConstructPixels
/// \brief Invokes the in-place default constructor on every pixel of the (uninitialized) view.
/// Does not support planar heterogeneous views.
/// If an exception is thrown destructs any in-place default-constructed pixels
template <typename View>
void default_construct_pixels(const View& img_view) {
if (detail::has_trivial_pixel_constructor<View, is_planar<View>::value>::value)
return;
if (img_view.is_1d_traversable())
detail::default_construct_aux(img_view.begin().x(), img_view.end().x(), is_planar<View>());
else {
typename View::y_coord_t y;
try {
for (y=0; y<img_view.height(); ++y)
detail::default_construct_aux(img_view.row_begin(y),img_view.row_end(y), is_planar<View>());
} catch(...) {
for (typename View::y_coord_t y0=0; y0<y; ++y0)
detail::destruct_aux(img_view.row_begin(y0),img_view.row_end(y0), is_planar<View>());
throw;
}
}
}
//////////////////////////////////////////////////////////////////////////////////////
///
/// uninitialized_copy_pixels
///
//////////////////////////////////////////////////////////////////////////////////////
/// \defgroup ImageViewSTLAlgorithmsUninitializedCopyPixels uninitialized_copy_pixels
/// \ingroup ImageViewSTLAlgorithms
/// \brief std::uninitialized_copy for image views
namespace detail {
/// std::uninitialized_copy for pairs of planar iterators
template <typename It1, typename It2>
GIL_FORCEINLINE
void uninitialized_copy_aux(It1 first1, It1 last1,
It2 first2, mpl::true_) {
int channel=0;
try {
typedef typename std::iterator_traits<It1>::value_type pixel_t;
while (channel < num_channels<pixel_t>::value) {
std::uninitialized_copy(dynamic_at_c(first1,channel), dynamic_at_c(last1,channel), dynamic_at_c(first2,channel));
++channel;
}
} catch (...) {
It2 last2=first2;
std::advance(last2, std::distance(first1,last1));
for (int c=0; c<channel; ++c)
destruct_range(dynamic_at_c(first2,c), dynamic_at_c(last2,c));
throw;
}
}
/// std::uninitialized_copy for interleaved or mixed iterators
template <typename It1, typename It2>
GIL_FORCEINLINE
void uninitialized_copy_aux(It1 first1, It1 last1,
It2 first2,mpl::false_) {
std::uninitialized_copy(first1,last1,first2);
}
} // namespace detail
/// \ingroup ImageViewSTLAlgorithmsUninitializedCopyPixels
/// \brief std::uninitialized_copy for image views.
/// Does not support planar heterogeneous views.
/// If an exception is thrown destructs any in-place copy-constructed objects
template <typename View1, typename View2>
void uninitialized_copy_pixels(const View1& view1, const View2& view2) {
typedef mpl::bool_<is_planar<View1>::value && is_planar<View2>::value> is_planar;
assert(view1.dimensions()==view2.dimensions());
if (view1.is_1d_traversable() && view2.is_1d_traversable())
detail::uninitialized_copy_aux(view1.begin().x(), view1.end().x(),
view2.begin().x(),
is_planar());
else {
typename View1::y_coord_t y;
try {
for (y=0; y<view1.height(); ++y)
detail::uninitialized_copy_aux(view1.row_begin(y), view1.row_end(y),
view2.row_begin(y),
is_planar());
} catch(...) {
for (typename View1::y_coord_t y0=0; y0<y; ++y0)
detail::destruct_aux(view2.row_begin(y0),view2.row_end(y0), is_planar());
throw;
}
}
}
//////////////////////////////////////////////////////////////////////////////////////
///
/// for_each_pixel
///
//////////////////////////////////////////////////////////////////////////////////////
/// \defgroup ImageViewSTLAlgorithmsForEachPixel for_each_pixel
/// \ingroup ImageViewSTLAlgorithms
/// \brief std::for_each for image views
///
/// For contiguous images (i.e. images that have no alignment gap at the end of each row) it is
/// more efficient to use the underlying pixel iterator that does not check for the end of rows.
/// For non-contiguous images for_each_pixel resolves to for_each of each row using the underlying
/// pixel iterator, which is still faster
/// \ingroup ImageViewSTLAlgorithmsForEachPixel
template <typename V, typename F>
F for_each_pixel(const V& img, F fun) {
if (img.is_1d_traversable()) {
return std::for_each(img.begin().x(), img.end().x(), fun);
} else {
for (std::ptrdiff_t y=0; y<img.height(); ++y)
fun = std::for_each(img.row_begin(y),img.row_end(y),fun);
return fun;
}
}
/// \defgroup ImageViewSTLAlgorithmsForEachPixelPosition for_each_pixel_position
/// \ingroup ImageViewSTLAlgorithms
/// \brief adobe::for_each_position for image views (passes locators, instead of pixel references, to the function object)
/// \ingroup ImageViewSTLAlgorithmsForEachPixelPosition
template <typename View, typename F>
F for_each_pixel_position(const View& img, F fun) {
typename View::xy_locator loc=img.xy_at(0,0);
for (std::ptrdiff_t y=0; y<img.height(); ++y) {
for (std::ptrdiff_t x=0; x<img.width(); ++x, ++loc.x())
fun(loc);
loc.x()-=img.width(); ++loc.y();
}
return fun;
}
//////////////////////////////////////////////////////////////////////////////////////
///
/// generate_pixels
///
//////////////////////////////////////////////////////////////////////////////////////
/// \defgroup ImageViewSTLAlgorithmsGeneratePixels generate_pixels
/// \ingroup ImageViewSTLAlgorithms
/// \brief std::generate for image views
/// \ingroup ImageViewSTLAlgorithmsGeneratePixels
/// \brief std::generate for image views
template <typename View, typename F>
void generate_pixels(const View& v, F fun) {
if (v.is_1d_traversable()) {
std::generate(v.begin().x(), v.end().x(), fun);
} else {
for (std::ptrdiff_t y=0; y<v.height(); ++y)
std::generate(v.row_begin(y),v.row_end(y),fun);
}
}
//////////////////////////////////////////////////////////////////////////////////////
///
/// std::equal and gil::equal_pixels for GIL constructs
///
//////////////////////////////////////////////////////////////////////////////////////
/// \defgroup ImageViewSTLAlgorithmsEqualPixels equal_pixels
/// \ingroup ImageViewSTLAlgorithms
/// \brief std::equal for image views
template <typename I1, typename I2> GIL_FORCEINLINE bool equal_n(I1 i1, std::ptrdiff_t n, I2 i2);
namespace detail {
template <typename I1, typename I2>
struct equal_n_fn {
GIL_FORCEINLINE bool operator()(I1 i1, std::ptrdiff_t n, I2 i2) const { return std::equal(i1,i1+n, i2); }
};
/// Equal when both ranges are interleaved and of the same type.
/// GIL pixels are bitwise comparable, so memcmp is used. User-defined pixels that are not bitwise comparable need to provide an overload
template<typename T, typename Cs>
struct equal_n_fn<const pixel<T,Cs>*, const pixel<T,Cs>*> {
GIL_FORCEINLINE bool operator()(const pixel<T,Cs>* i1, std::ptrdiff_t n, const pixel<T,Cs>* i2) const {
return memcmp(i1, i2, n*sizeof(pixel<T,Cs>))==0;
}
};
template<typename T, typename Cs>
struct equal_n_fn<pixel<T,Cs>*, pixel<T,Cs>*> : equal_n_fn<const pixel<T,Cs>*, const pixel<T,Cs>*> {};
/// EqualPixels
/// Equal when both ranges are planar pointers of the same type. memcmp is invoked for each channel plane
/// User-defined channels that are not bitwise comparable need to provide an overload
template<typename IC, typename Cs>
struct equal_n_fn<planar_pixel_iterator<IC,Cs>, planar_pixel_iterator<IC,Cs> > {
GIL_FORCEINLINE bool operator()(const planar_pixel_iterator<IC,Cs> i1, std::ptrdiff_t n, const planar_pixel_iterator<IC,Cs> i2) const {
ptrdiff_t numBytes=n*sizeof(typename std::iterator_traits<IC>::value_type);
for (std::ptrdiff_t i=0; i<mpl::size<Cs>::value; ++i)
if (memcmp(dynamic_at_c(i1,i), dynamic_at_c(i2,i), numBytes)!=0)
return false;
return true;
}
};
/// Source range is delimited by image iterators
template <typename Loc, typename I2> // IL Models ConstPixelLocatorConcept, O Models PixelIteratorConcept
struct equal_n_fn<boost::gil::iterator_from_2d<Loc>,I2> {
GIL_FORCEINLINE bool operator()(boost::gil::iterator_from_2d<Loc> i1, std::ptrdiff_t n, I2 i2) const {
gil_function_requires<boost::gil::PixelLocatorConcept<Loc> >();
gil_function_requires<boost::gil::PixelIteratorConcept<I2> >();
while (n>0) {
std::ptrdiff_t num=std::min<const std::ptrdiff_t>(n, i1.width()-i1.x_pos());
if (!equal_n(i1.x(), num, i2))
return false;
i1+=num;
i2+=num;
n-=num;
}
return true;
}
};
/// Destination range is delimited by image iterators
template <typename I1, typename Loc> // I Models PixelIteratorConcept, OL Models PixelLocatorConcept
struct equal_n_fn<I1,boost::gil::iterator_from_2d<Loc> > {
GIL_FORCEINLINE bool operator()(I1 i1, std::ptrdiff_t n, boost::gil::iterator_from_2d<Loc> i2) const {
gil_function_requires<boost::gil::PixelIteratorConcept<I1> >();
gil_function_requires<boost::gil::PixelLocatorConcept<Loc> >();
while (n>0) {
std::ptrdiff_t num=std::min<const std::ptrdiff_t>(n,i2.width()-i2.x_pos());
if (!equal_n(i1, num, i2.x()))
return false;
i1+=num;
i2+=num;
n-=num;
}
return true;
}
};
/// Both source and destination ranges are delimited by image iterators
template <typename Loc1, typename Loc2>
struct equal_n_fn<boost::gil::iterator_from_2d<Loc1>,boost::gil::iterator_from_2d<Loc2> > {
GIL_FORCEINLINE bool operator()(boost::gil::iterator_from_2d<Loc1> i1, std::ptrdiff_t n, boost::gil::iterator_from_2d<Loc2> i2) const {
gil_function_requires<boost::gil::PixelLocatorConcept<Loc1> >();
gil_function_requires<boost::gil::PixelLocatorConcept<Loc2> >();
if (i1.x_pos()!=i2.x_pos() || i1.width()!=i2.width()) {
while(n-->0) {
if (*i1++!=*i2++) return false;
}
}
while (n>0) {
std::ptrdiff_t num=std::min<const std::ptrdiff_t>(n,i2.width()-i2.x_pos());
if (!equal_n(i1.x(), num, i2.x()))
return false;
i1+=num;
i2+=num;
n-=num;
}
return true;
}
};
} // namespace detail
template <typename I1, typename I2> GIL_FORCEINLINE
bool equal_n(I1 i1, std::ptrdiff_t n, I2 i2) {
return detail::equal_n_fn<I1,I2>()(i1,n,i2);
}
} } // namespace boost::gil
namespace std {
/// \ingroup STLOptimizations
/// \brief std::equal(I1,I1,I2) with I1 and I2 being a iterator_from_2d
///
/// Invoked when one calls std::equal(I1,I1,I2) with I1 and I2 being a iterator_from_2d (which is
/// a 1D iterator over the pixels in an image). Attempts to demote the source and destination
/// iterators to simpler/faster types if the corresponding range is contiguous.
/// For contiguous images (i.e. images that have
/// no alignment gap at the end of each row) it is more efficient to use the underlying
/// pixel iterator that does not check for the end of rows. If the underlying pixel iterator
/// happens to be a fundamental planar/interleaved pointer, the call may further resolve
/// to memcmp. Otherwise it resolves to copying each row using the underlying pixel iterator
template <typename Loc1, typename Loc2> GIL_FORCEINLINE
bool equal(boost::gil::iterator_from_2d<Loc1> first, boost::gil::iterator_from_2d<Loc1> last, boost::gil::iterator_from_2d<Loc2> first2) {
boost::gil::gil_function_requires<boost::gil::PixelLocatorConcept<Loc1> >();
boost::gil::gil_function_requires<boost::gil::PixelLocatorConcept<Loc2> >();
std::ptrdiff_t n=last-first;
if (first.is_1d_traversable()) {
if (first2.is_1d_traversable())
return boost::gil::detail::equal_n_fn<typename Loc1::x_iterator,typename Loc2::x_iterator>()(first.x(),n, first2.x());
else
return boost::gil::detail::equal_n_fn<typename Loc1::x_iterator,boost::gil::iterator_from_2d<Loc2> >()(first.x(),n, first2);
} else {
if (first2.is_1d_traversable())
return boost::gil::detail::equal_n_fn<boost::gil::iterator_from_2d<Loc1>,typename Loc2::x_iterator>()(first,n, first2.x());
else
return boost::gil::detail::equal_n_fn<boost::gil::iterator_from_2d<Loc1>,boost::gil::iterator_from_2d<Loc2> >()(first,n,first2);
}
}
} // namespace std
namespace boost { namespace gil {
/// \ingroup ImageViewSTLAlgorithmsEqualPixels
/// \brief std::equal for image views
template <typename View1, typename View2> GIL_FORCEINLINE
bool equal_pixels(const View1& v1, const View2& v2) {
assert(v1.dimensions()==v2.dimensions());
return std::equal(v1.begin(),v1.end(),v2.begin()); // std::equal has overloads with GIL iterators for optimal performance
}
//////////////////////////////////////////////////////////////////////////////////////
///
/// transform_pixels
///
//////////////////////////////////////////////////////////////////////////////////////
/// \defgroup ImageViewSTLAlgorithmsTransformPixels transform_pixels
/// \ingroup ImageViewSTLAlgorithms
/// \brief std::transform for image views
/// \ingroup ImageViewSTLAlgorithmsTransformPixels
/// \brief std::transform for image views
template <typename View1, typename View2, typename F> GIL_FORCEINLINE
F transform_pixels(const View1& src,const View2& dst, F fun) {
assert(src.dimensions()==dst.dimensions());
for (std::ptrdiff_t y=0; y<src.height(); ++y) {
typename View1::x_iterator srcIt=src.row_begin(y);
typename View2::x_iterator dstIt=dst.row_begin(y);
for (std::ptrdiff_t x=0; x<src.width(); ++x)
dstIt[x]=fun(srcIt[x]);
}
return fun;
}
/// \ingroup ImageViewSTLAlgorithmsTransformPixels
/// \brief transform_pixels with two sources
template <typename View1, typename View2, typename View3, typename F> GIL_FORCEINLINE
F transform_pixels(const View1& src1, const View2& src2,const View3& dst, F fun) {
for (std::ptrdiff_t y=0; y<dst.height(); ++y) {
typename View1::x_iterator srcIt1=src1.row_begin(y);
typename View2::x_iterator srcIt2=src2.row_begin(y);
typename View3::x_iterator dstIt=dst.row_begin(y);
for (std::ptrdiff_t x=0; x<dst.width(); ++x)
dstIt[x]=fun(srcIt1[x],srcIt2[x]);
}
return fun;
}
/// \defgroup ImageViewSTLAlgorithmsTransformPixelPositions transform_pixel_positions
/// \ingroup ImageViewSTLAlgorithms
/// \brief adobe::transform_positions for image views (passes locators, instead of pixel references, to the function object)
/// \ingroup ImageViewSTLAlgorithmsTransformPixelPositions
/// \brief Like transform_pixels but passes to the function object pixel locators instead of pixel references
template <typename View1, typename View2, typename F> GIL_FORCEINLINE
F transform_pixel_positions(const View1& src,const View2& dst, F fun) {
assert(src.dimensions()==dst.dimensions());
typename View1::xy_locator loc=src.xy_at(0,0);
for (std::ptrdiff_t y=0; y<src.height(); ++y) {
typename View2::x_iterator dstIt=dst.row_begin(y);
for (std::ptrdiff_t x=0; x<src.width(); ++x, ++loc.x())
dstIt[x]=fun(loc);
loc.x()-=src.width(); ++loc.y();
}
return fun;
}
/// \ingroup ImageViewSTLAlgorithmsTransformPixelPositions
/// \brief transform_pixel_positions with two sources
template <typename View1, typename View2, typename View3, typename F> GIL_FORCEINLINE
F transform_pixel_positions(const View1& src1,const View2& src2,const View3& dst, F fun) {
assert(src1.dimensions()==dst.dimensions());
assert(src2.dimensions()==dst.dimensions());
typename View1::xy_locator loc1=src1.xy_at(0,0);
typename View2::xy_locator loc2=src2.xy_at(0,0);
for (std::ptrdiff_t y=0; y<src1.height(); ++y) {
typename View3::x_iterator dstIt=dst.row_begin(y);
for (std::ptrdiff_t x=0; x<src1.width(); ++x, ++loc1.x(), ++loc2.x())
dstIt[x]=fun(loc1,loc2);
loc1.x()-=src1.width(); ++loc1.y();
loc2.x()-=src2.width(); ++loc2.y();
}
return fun;
}
} } // namespace boost::gil
//#ifdef _MSC_VER
//#pragma warning(pop)
//#endif
#endif