/* 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_IMAGE_VIEW_FACTORY_HPP #define GIL_IMAGE_VIEW_FACTORY_HPP /*! /// \file /// \brief Methods for constructing image views from raw data or other image views /// \author Lubomir Bourdev and Hailin Jin \n /// Adobe Systems Incorporated /// \date 2005-2007 \n Last updated on March 9, 2007 /// Methods for creating shallow image views from raw pixel data or from other image views - /// flipping horizontally or vertically, axis-aligned rotation, a subimage, subsampled /// or n-th channel image view. Derived image views are shallow copies and are fast to construct. */ #include #include #include "gil_config.hpp" #include "metafunctions.hpp" #include "gray.hpp" #include "color_convert.hpp" /// \defgroup ImageViewConstructors Image View From Raw Data /// \ingroup ImageViewAlgorithm /// \brief Methods for constructing image views from raw data and for getting raw data from views /// \defgroup ImageViewTransformations Image View Transformations /// \ingroup ImageViewAlgorithm /// \brief Methods for constructing one image view from another namespace boost { namespace gil { struct default_color_converter; template struct dynamic_x_step_type; template struct dynamic_y_step_type; template struct transposed_type; /// \brief Returns the type of a view that has a dynamic step along both X and Y /// \ingroup ImageViewTransformations template struct dynamic_xy_step_type : public dynamic_y_step_type::type> {}; /// \brief Returns the type of a transposed view that has a dynamic step along both X and Y /// \ingroup ImageViewTransformations template struct dynamic_xy_step_transposed_type : public dynamic_xy_step_type::type> {}; /// \ingroup ImageViewConstructors /// \brief Constructing image views from raw interleaved pixel data template typename type_from_x_iterator::view_t interleaved_view(std::size_t width, std::size_t height, Iterator pixels, std::ptrdiff_t rowsize_in_bytes) { typedef typename type_from_x_iterator::view_t RView; return RView(width, height, typename RView::locator(pixels, rowsize_in_bytes)); } /// \ingroup ImageViewConstructors /// \brief Constructing image views from raw interleaved pixel data template typename type_from_x_iterator::view_t interleaved_view(point2 dim, Iterator pixels, std::ptrdiff_t rowsize_in_bytes) { typedef typename type_from_x_iterator::view_t RView; return RView(dim, typename RView::locator(pixels, rowsize_in_bytes)); } ///////////////////////////// // interleaved_view_get_raw_data, planar_view_get_raw_data - return pointers to the raw data (the channels) of a basic homogeneous view. ///////////////////////////// namespace detail { template struct channel_pointer_type_impl; template struct channel_pointer_type_impl { typedef typename channel_type::type* type; }; template struct channel_pointer_type_impl { typedef const typename channel_type::type* type; }; template struct channel_pointer_type : public channel_pointer_type_impl::value> {}; } // namespace detail /// \ingroup ImageViewConstructors /// \brief Returns C pointer to the the channels of an interleaved homogeneous view. template typename detail::channel_pointer_type::type interleaved_view_get_raw_data(const HomogeneousView& view) { BOOST_STATIC_ASSERT((!is_planar::value && view_is_basic::value)); BOOST_STATIC_ASSERT((boost::is_pointer::value)); return &at_c<0>(view(0,0)); } /// \ingroup ImageViewConstructors /// \brief Returns C pointer to the the channels of a given color plane of a planar homogeneous view. template typename detail::channel_pointer_type::type planar_view_get_raw_data(const HomogeneousView& view, int plane_index) { BOOST_STATIC_ASSERT((is_planar::value && view_is_basic::value)); return dynamic_at_c(view.row_begin(0),plane_index); } /// \defgroup ImageViewTransformationsColorConvert color_converted_view /// \ingroup ImageViewTransformations /// \brief Color converted view of another view /// \ingroup ImageViewTransformationsColorConvert PixelDereferenceAdaptorModel /// \brief Function object that given a source pixel, returns it converted to a given color space and channel depth. Models: PixelDereferenceAdaptorConcept /// /// Useful in constructing a color converted view over a given image view template // const_reference to the source pixel and destination pixel value class color_convert_deref_fn : public deref_base, DstP, DstP, const DstP&, SrcConstRefP, DstP, false> { private: CC _cc; // color-converter public: color_convert_deref_fn() {} color_convert_deref_fn(CC cc_in) : _cc(cc_in) {} DstP operator()(SrcConstRefP srcP) const { DstP dstP; _cc(srcP,dstP); return dstP; } }; namespace detail { // Add color converter upon dereferencing template struct _color_converted_view_type { private: typedef color_convert_deref_fn deref_t; typedef typename SrcView::template add_deref add_ref_t; public: typedef typename add_ref_t::type type; static type make(const SrcView& sv,CC cc) {return add_ref_t::make(sv,deref_t(cc));} }; // If the Src view has the same pixel type as the target, there is no need for color conversion template struct _color_converted_view_type { typedef SrcView type; static type make(const SrcView& sv,CC) {return sv;} }; } // namespace detail /// \brief Returns the type of a view that does color conversion upon dereferencing its pixels /// \ingroup ImageViewTransformationsColorConvert template struct color_converted_view_type : public detail::_color_converted_view_type { GIL_CLASS_REQUIRE(DstP, boost::gil, MutablePixelConcept)//why does it have to be mutable??? }; /// \ingroup ImageViewTransformationsColorConvert /// \brief view of a different color space with a user defined color-converter template inline typename color_converted_view_type::type color_converted_view(const View& src,CC cc) { return color_converted_view_type::make(src,cc); } /// \ingroup ImageViewTransformationsColorConvert /// \brief overload of generic color_converted_view with the default color-converter template inline typename color_converted_view_type::type color_converted_view(const View& src) { return color_converted_view(src,default_color_converter()); } /// \defgroup ImageViewTransformationsFlipUD flipped_up_down_view /// \ingroup ImageViewTransformations /// \brief view of a view flipped up-to-down /// \ingroup ImageViewTransformationsFlipUD template inline typename dynamic_y_step_type::type flipped_up_down_view(const View& src) { typedef typename dynamic_y_step_type::type RView; return RView(src.dimensions(),typename RView::xy_locator(src.xy_at(0,src.height()-1),-1)); } /// \defgroup ImageViewTransformationsFlipLR flipped_left_right_view /// \ingroup ImageViewTransformations /// \brief view of a view flipped left-to-right /// \ingroup ImageViewTransformationsFlipLR template inline typename dynamic_x_step_type::type flipped_left_right_view(const View& src) { typedef typename dynamic_x_step_type::type RView; return RView(src.dimensions(),typename RView::xy_locator(src.xy_at(src.width()-1,0),-1,1)); } /// \defgroup ImageViewTransformationsTransposed transposed_view /// \ingroup ImageViewTransformations /// \brief view of a view transposed /// \ingroup ImageViewTransformationsTransposed template inline typename dynamic_xy_step_transposed_type::type transposed_view(const View& src) { typedef typename dynamic_xy_step_transposed_type::type RView; return RView(src.height(),src.width(),typename RView::xy_locator(src.xy_at(0,0),1,1,true)); } /// \defgroup ImageViewTransformations90CW rotated90cw_view /// \ingroup ImageViewTransformations /// \brief view of a view rotated 90 degrees clockwise /// \ingroup ImageViewTransformations90CW template inline typename dynamic_xy_step_transposed_type::type rotated90cw_view(const View& src) { typedef typename dynamic_xy_step_transposed_type::type RView; return RView(src.height(),src.width(),typename RView::xy_locator(src.xy_at(0,src.height()-1),-1,1,true)); } /// \defgroup ImageViewTransformations90CCW rotated90ccw_view /// \ingroup ImageViewTransformations /// \brief view of a view rotated 90 degrees counter-clockwise /// \ingroup ImageViewTransformations90CCW template inline typename dynamic_xy_step_transposed_type::type rotated90ccw_view(const View& src) { typedef typename dynamic_xy_step_transposed_type::type RView; return RView(src.height(),src.width(),typename RView::xy_locator(src.xy_at(src.width()-1,0),1,-1,true)); } /// \defgroup ImageViewTransformations180 rotated180_view /// \ingroup ImageViewTransformations /// \brief view of a view rotated 180 degrees /// \ingroup ImageViewTransformations180 template inline typename dynamic_xy_step_type::type rotated180_view(const View& src) { typedef typename dynamic_xy_step_type::type RView; return RView(src.dimensions(),typename RView::xy_locator(src.xy_at(src.width()-1,src.height()-1),-1,-1)); } /// \defgroup ImageViewTransformationsSubimage subimage_view /// \ingroup ImageViewTransformations /// \brief view of an axis-aligned rectangular area within an image_view /// \ingroup ImageViewTransformationsSubimage template inline View subimage_view(const View& src, const typename View::point_t& topleft, const typename View::point_t& dimensions) { return View(dimensions,src.xy_at(topleft)); } /// \ingroup ImageViewTransformationsSubimage template inline View subimage_view(const View& src, int xMin, int yMin, int width, int height) { return View(width,height,src.xy_at(xMin,yMin)); } /// \defgroup ImageViewTransformationsSubsampled subsampled_view /// \ingroup ImageViewTransformations /// \brief view of a subsampled version of an image_view, stepping over a number of channels in X and number of rows in Y /// \ingroup ImageViewTransformationsSubsampled template inline typename dynamic_xy_step_type::type subsampled_view(const View& src, typename View::coord_t xStep, typename View::coord_t yStep) { assert(xStep>0 && yStep>0); typedef typename dynamic_xy_step_type::type RView; return RView((src.width()+(xStep-1))/xStep,(src.height()+(yStep-1))/yStep, typename RView::xy_locator(src.xy_at(0,0),xStep,yStep)); } /// \ingroup ImageViewTransformationsSubsampled template inline typename dynamic_xy_step_type::type subsampled_view(const View& src, const typename View::point_t& step) { return subsampled_view(src,step.x,step.y); } /// \defgroup ImageViewTransformationsNthChannel nth_channel_view /// \ingroup ImageViewTransformations /// \brief single-channel (grayscale) view of the N-th channel of a given image_view namespace detail { template struct __nth_channel_view_basic; // nth_channel_view when the channels are not adjacent in memory. This can happen for multi-channel interleaved images // or images with a step template struct __nth_channel_view_basic { typedef typename view_type::type, gray_layout_t, false, true, view_is_mutable::value>::type type; static type make(const View& src, int n) { typedef typename type::xy_locator locator_t; typedef typename type::x_iterator x_iterator_t; typedef typename iterator_adaptor_get_base::type x_iterator_base_t; x_iterator_t sit(x_iterator_base_t(&(src(0,0)[n])),src.pixels().pixel_size()); return type(src.dimensions(),locator_t(sit, src.pixels().row_size())); } }; // nth_channel_view when the channels are together in memory (true for simple grayscale or planar images) template struct __nth_channel_view_basic { typedef typename view_type::type, gray_layout_t, false, false, view_is_mutable::value>::type type; static type make(const View& src, int n) { typedef typename type::x_iterator x_iterator_t; return interleaved_view(src.width(),src.height(),(x_iterator_t)&(src(0,0)[n]), src.pixels().row_size()); } }; template struct __nth_channel_view; // For basic (memory-based) views dispatch to __nth_channel_view_basic template struct __nth_channel_view { private: typedef typename View::x_iterator src_x_iterator; // Determines whether the channels of a given pixel iterator are adjacent in memory. // Planar and grayscale iterators have channels adjacent in memory, whereas multi-channel interleaved and iterators with non-fundamental step do not. BOOST_STATIC_CONSTANT(bool, adjacent= !iterator_is_step::value && (is_planar::value || num_channels::value==1)); public: typedef typename __nth_channel_view_basic::type type; static type make(const View& src, int n) { return __nth_channel_view_basic::make(src,n); } }; /// \brief Function object that returns a grayscale reference of the N-th channel of a given reference. Models: PixelDereferenceAdaptorConcept. /// \ingroup PixelDereferenceAdaptorModel /// /// If the input is a pixel value or constant reference, the function object is immutable. Otherwise it is mutable (and returns non-const reference to the n-th channel) template // SrcP is a reference to PixelConcept (could be pixel value or const/non-const reference) // Examples: pixel, pixel&, const pixel&, planar_pixel_reference, planar_pixel_reference struct nth_channel_deref_fn { BOOST_STATIC_CONSTANT(bool, is_mutable=pixel_is_reference::value && pixel_reference_is_mutable::value); private: typedef typename remove_reference::type src_pixel_t; typedef typename channel_type::type channel_t; typedef typename src_pixel_t::const_reference const_ref_t; typedef typename pixel_reference_type::type ref_t; public: typedef nth_channel_deref_fn const_t; typedef typename pixel_value_type::type value_type; typedef typename pixel_reference_type::type const_reference; typedef SrcP argument_type; typedef typename mpl::if_c::type reference; typedef reference result_type; nth_channel_deref_fn(int n=0) : _n(n) {} template nth_channel_deref_fn(const nth_channel_deref_fn

& d) : _n(d._n) {} int _n; // the channel to use result_type operator()(argument_type srcP) const { return result_type(srcP[_n]); } }; template struct __nth_channel_view { private: typedef nth_channel_deref_fn deref_t; typedef typename View::template add_deref AD; public: typedef typename AD::type type; static type make(const View& src, int n) { return AD::make(src, deref_t(n)); } }; } // namespace detail /// \brief Given a source image view type View, returns the type of an image view over a single channel of View /// \ingroup ImageViewTransformationsNthChannel /// /// If the channels in the source view are adjacent in memory (such as planar non-step view or single-channel view) then the /// return view is a single-channel non-step view. /// If the channels are non-adjacent (interleaved and/or step view) then the return view is a single-channel step view. template struct nth_channel_view_type { private: GIL_CLASS_REQUIRE(View, boost::gil, ImageViewConcept) typedef detail::__nth_channel_view::value> VB; public: typedef typename VB::type type; static type make(const View& src, int n) { return VB::make(src,n); } }; /// \ingroup ImageViewTransformationsNthChannel template typename nth_channel_view_type::type nth_channel_view(const View& src, int n) { return nth_channel_view_type::make(src,n); } /// \defgroup ImageViewTransformationsKthChannel kth_channel_view /// \ingroup ImageViewTransformations /// \brief single-channel (grayscale) view of the K-th channel of a given image_view. The channel index is a template parameter namespace detail { template struct __kth_channel_view_basic; // kth_channel_view when the channels are not adjacent in memory. This can happen for multi-channel interleaved images // or images with a step template struct __kth_channel_view_basic { private: typedef typename kth_element_type::type channel_t; public: typedef typename view_type::value>::type type; static type make(const View& src) { typedef typename type::xy_locator locator_t; typedef typename type::x_iterator x_iterator_t; typedef typename iterator_adaptor_get_base::type x_iterator_base_t; x_iterator_t sit(x_iterator_base_t(&at_c(src(0,0))),src.pixels().pixel_size()); return type(src.dimensions(),locator_t(sit, src.pixels().row_size())); } }; // kth_channel_view when the channels are together in memory (true for simple grayscale or planar images) template struct __kth_channel_view_basic { private: typedef typename kth_element_type::type channel_t; public: typedef typename view_type::value>::type type; static type make(const View& src) { typedef typename type::x_iterator x_iterator_t; return interleaved_view(src.width(),src.height(),(x_iterator_t)&at_c(src(0,0)), src.pixels().row_size()); } }; template struct __kth_channel_view; // For basic (memory-based) views dispatch to __kth_channel_view_basic template struct __kth_channel_view { private: typedef typename View::x_iterator src_x_iterator; // Determines whether the channels of a given pixel iterator are adjacent in memory. // Planar and grayscale iterators have channels adjacent in memory, whereas multi-channel interleaved and iterators with non-fundamental step do not. BOOST_STATIC_CONSTANT(bool, adjacent= !iterator_is_step::value && (is_planar::value || num_channels::value==1)); public: typedef typename __kth_channel_view_basic::type type; static type make(const View& src) { return __kth_channel_view_basic::make(src); } }; /// \brief Function object that returns a grayscale reference of the K-th channel (specified as a template parameter) of a given reference. Models: PixelDereferenceAdaptorConcept. /// \ingroup PixelDereferenceAdaptorModel /// /// If the input is a pixel value or constant reference, the function object is immutable. Otherwise it is mutable (and returns non-const reference to the k-th channel) template // SrcP is a reference to PixelConcept (could be pixel value or const/non-const reference) // Examples: pixel, pixel&, const pixel&, planar_pixel_reference, planar_pixel_reference struct kth_channel_deref_fn { BOOST_STATIC_CONSTANT(bool, is_mutable=pixel_is_reference::value && pixel_reference_is_mutable::value); private: typedef typename remove_reference::type src_pixel_t; typedef typename kth_element_type::type channel_t; typedef typename src_pixel_t::const_reference const_ref_t; typedef typename pixel_reference_type::type ref_t; public: typedef kth_channel_deref_fn const_t; typedef typename pixel_value_type::type value_type; typedef typename pixel_reference_type::type const_reference; typedef SrcP argument_type; typedef typename mpl::if_c::type reference; typedef reference result_type; kth_channel_deref_fn() {} template kth_channel_deref_fn(const kth_channel_deref_fn&) {} result_type operator()(argument_type srcP) const { return result_type(at_c(srcP)); } }; template struct __kth_channel_view { private: typedef kth_channel_deref_fn deref_t; typedef typename View::template add_deref AD; public: typedef typename AD::type type; static type make(const View& src) { return AD::make(src, deref_t()); } }; } // namespace detail /// \brief Given a source image view type View, returns the type of an image view over a given channel of View. /// \ingroup ImageViewTransformationsKthChannel /// /// If the channels in the source view are adjacent in memory (such as planar non-step view or single-channel view) then the /// return view is a single-channel non-step view. /// If the channels are non-adjacent (interleaved and/or step view) then the return view is a single-channel step view. template struct kth_channel_view_type { private: GIL_CLASS_REQUIRE(View, boost::gil, ImageViewConcept) typedef detail::__kth_channel_view::value> VB; public: typedef typename VB::type type; static type make(const View& src) { return VB::make(src); } }; /// \ingroup ImageViewTransformationsKthChannel template typename kth_channel_view_type::type kth_channel_view(const View& src) { return kth_channel_view_type::make(src); } } } // namespace boost::gil #endif