boost_1_45_0/libs/gil/test/image.cpp - nest-learning-thermostat/5.0/boost - Git at Google

 /*
     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.
 */
 // image_test.cpp :
 //

 #ifdef _MSC_VER
 //#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)
 #pragma warning(disable : 4503)     // decorated name length exceeded, name was truncated
 #endif

 #include <string>
 #include <vector>
 #include <ios>
 #include <iostream>
 #include <fstream>
 #include <map>
 #include <boost/lambda/lambda.hpp>
 #include <boost/lambda/bind.hpp>
 #include <boost/mpl/vector.hpp>
 #include <boost/gil/extension/dynamic_image/dynamic_image_all.hpp>
 #include <boost/crc.hpp>

 using namespace boost::gil;
 using namespace std;
 using namespace boost;

 extern rgb8c_planar_view_t sample_view;
 void error_if(bool condition);


 // When BOOST_GIL_GENERATE_REFERENCE_DATA is defined, the reference data is generated and saved.
 // When it is undefined, regression tests are checked against it
 //#define BOOST_GIL_GENERATE_REFERENCE_DATA

 ////////////////////////////////////////////////////
 ///
 ///  Some algorithms to use in testing
 ///
 ////////////////////////////////////////////////////

 template <typename GrayView, typename R>
 void gray_image_hist(const GrayView& img_view, R& hist) {
 //    for_each_pixel(img_view,++lambda::var(hist)[lambda::_1]);
     for (typename GrayView::iterator it=img_view.begin(); it!=img_view.end(); ++it)
         ++hist[*it];
 }

 template <typename V, typename R>
 void get_hist(const V& img_view, R& hist) {
     gray_image_hist(color_converted_view<gray8_pixel_t>(img_view), hist);
 }

 // testing custom color conversion
 template <typename C1, typename C2>
 struct my_color_converter_impl : public default_color_converter_impl<C1,C2> {};
 template <typename C1>
 struct my_color_converter_impl<C1,gray_t> {
     template <typename P1, typename P2>
     void operator()(const P1& src, P2& dst) const {
         default_color_converter_impl<C1,gray_t>()(src,dst);
         get_color(dst,gray_color_t())=channel_invert(get_color(dst,gray_color_t()));
     }
 };

 struct my_color_converter {
     template <typename SrcP,typename DstP>
     void operator()(const SrcP& src,DstP& dst) const {
         typedef typename color_space_type<SrcP>::type src_cs_t;
         typedef typename color_space_type<DstP>::type dst_cs_t;
         my_color_converter_impl<src_cs_t,dst_cs_t>()(src,dst);
     }
 };

 // Models a Unary Function
 template <typename P>   // Models PixelValueConcept
 struct mandelbrot_fn {
     typedef point2<std::ptrdiff_t>    point_t;

     typedef mandelbrot_fn        const_t;
     typedef P                    value_type;
     typedef value_type           reference;
     typedef value_type           const_reference;
     typedef point_t              argument_type;
     typedef reference            result_type;
     BOOST_STATIC_CONSTANT(bool, is_mutable=false);

     value_type                    _in_color,_out_color;
     point_t                       _img_size;
     static const int MAX_ITER=100;        // max number of iterations

     mandelbrot_fn() {}
     mandelbrot_fn(const point_t& sz, const value_type& in_color, const value_type& out_color) : _in_color(in_color), _out_color(out_color), _img_size(sz) {}

     result_type operator()(const point_t& p) const {
         // normalize the coords to (-2..1, -1.5..1.5)
         // (actually make y -1.0..2 so it is asymmetric, so we can verify some view factory methods)
         double t=get_num_iter(point2<double>(p.x/(double)_img_size.x*3-2, p.y/(double)_img_size.y*3-1.0f));//1.5f));
         t=pow(t,0.2);

         value_type ret;
         for (int k=0; k<num_channels<P>::value; ++k)
             ret[k]=(typename channel_type<value_type>::type)(_in_color[k]*t + _out_color[k]*(1-t));
         return ret;
     }

 private:
     double get_num_iter(const point2<double>& p) const {
         point2<double> Z(0,0);
         for (int i=0; i<MAX_ITER; ++i) {
             Z = point2<double>(Z.x*Z.x - Z.y*Z.y + p.x, 2*Z.x*Z.y + p.y);
             if (Z.x*Z.x + Z.y*Z.y > 4)
                 return i/(double)MAX_ITER;
         }
         return 0;
     }
 };

 template <typename T>
 void x_gradient(const T& src, const gray8s_view_t& dst) {
     for (int y=0; y<src.height(); ++y) {
         typename T::x_iterator src_it = src.row_begin(y);
         gray8s_view_t::x_iterator dst_it = dst.row_begin(y);

         for (int x=1; x<src.width()-1; ++x)
             dst_it[x] = (src_it[x+1] - src_it[x-1]) / 2;
     }
 }

 // A quick test whether a view is homogeneous

 template <typename Pixel>
 struct pixel_is_homogeneous : public mpl::true_ {};

 template <typename P, typename C, typename L>
 struct pixel_is_homogeneous<packed_pixel<P,C,L> > : public mpl::false_ {};

 template <typename View>
 struct view_is_homogeneous : public pixel_is_homogeneous<typename View::value_type> {};


 ////////////////////////////////////////////////////
 ///
 ///  Tests image view transformations and algorithms
 ///
 ////////////////////////////////////////////////////
 class image_test {
 public:
     virtual void initialize() {}
     virtual void finalize() {}
     virtual ~image_test() {}

     void run();
 protected:
     virtual void check_view_impl(const rgb8c_view_t& view, const string& name)=0;
     template <typename View>
     void check_view(const View& img_view, const string& name) {
         rgb8_image_t rgb_img(img_view.dimensions());
         copy_and_convert_pixels(img_view,view(rgb_img));
         check_view_impl(const_view(rgb_img), name);
     }
 private:
     template <typename Img> void basic_test(const string& prefix);
     template <typename View> void view_transformations_test(const View& img_view, const string& prefix);
     template <typename View> void homogeneous_view_transformations_test(const View& img_view, const string& prefix, mpl::true_);
     template <typename View> void homogeneous_view_transformations_test(const View& img_view, const string& prefix, mpl::false_) {}
     template <typename View> void histogram_test(const View& img_view, const string& prefix);
     void virtual_view_test();
     void packed_image_test();
     void dynamic_image_test();
     template <typename Img> void image_all_test(const string& prefix);
 };


 // testing image iterators, clone, fill, locators, color convert
 template <typename Img>
 void image_test::basic_test(const string& prefix) {
     typedef typename Img::view_t View;

     // make a 20x20 image
     Img img(typename View::point_t(20,20));
     const View& img_view=view(img);

     // fill it with red
     rgb8_pixel_t red8(255,0,0), green8(0,255,0), blue8(0,0,255), white8(255,255,255);
     typename View::value_type red,green,blue,white;
     color_convert(red8,red);
     default_color_converter()(red8,red);
     red=color_convert_deref_fn<rgb8_ref_t,typename Img::view_t::value_type>()(red8);

     color_convert(green8,green);
     color_convert(blue8,blue);
     color_convert(white8,white);
     fill(img_view.begin(),img_view.end(),red);

     color_convert(red8,img_view[0]);

     // pointer to first pixel of second row
     typename View::reference rt=img_view.at(0,0)[img_view.width()];
     typename View::x_iterator ptr=&rt;
     typename View::reference rt2=*(img_view.at(0,0)+img_view.width());
     typename View::x_iterator ptr2=&rt2;
     error_if(ptr!=ptr2);
     error_if(img_view.x_at(0,0)+10!=10+img_view.x_at(0,0));

     // draw a blue line along the diagonal
     typename View::xy_locator loc=img_view.xy_at(0,img_view.height()-1);
     for (int y=0; y<img_view.height(); ++y) {
         *loc=blue;
         ++loc.x();
         loc.y()--;
     }

     // draw a green dotted line along the main diagonal with step of 3
     loc=img_view.xy_at(img_view.width()-1,img_view.height()-1);
     while (loc.x()>=img_view.x_at(0,0)) {
         *loc=green;
         loc-=typename View::point_t(3,3);
     }

     // Clone and make every red pixel white
     Img imgWhite(img);
     for (typename View::iterator it=view(imgWhite).end(); (it-1)!=view(imgWhite).begin(); --it) {
         if (*(it-1)==red)
             *(it-1)=white;
     }

     check_view(img_view,prefix+"red_x");
     check_view(view(imgWhite),prefix+"white_x");
 }

 template <typename View>
 void image_test::histogram_test(const View& img_view, const string& prefix) {
 //  vector<int> histogram(255,0);
 //  get_hist(cropped,histogram.begin());
     unsigned char histogram[256];
     fill(histogram,histogram+256,0);
     get_hist(img_view,histogram);
     gray8c_view_t hist_view=interleaved_view(256,1,(const gray8_pixel_t*)histogram,256);
     check_view(hist_view,prefix+"histogram");
 }


 template <typename View>
 void image_test::view_transformations_test(const View& img_view, const string& prefix) {
     check_view(img_view,prefix+"original");

     check_view(subimage_view(img_view, iround(img_view.dimensions()/4), iround(img_view.dimensions()/2)),prefix+"cropped");
     check_view(color_converted_view<gray8_pixel_t>(img_view),prefix+"gray8");
     check_view(color_converted_view<gray8_pixel_t>(img_view,my_color_converter()),prefix+"my_gray8");
     check_view(transposed_view(img_view),prefix+"transpose");
     check_view(rotated180_view(img_view),prefix+"rot180");
     check_view(rotated90cw_view(img_view),prefix+"90cw");
     check_view(rotated90ccw_view(img_view),prefix+"90ccw");
     check_view(flipped_up_down_view(img_view),prefix+"flipped_ud");
     check_view(flipped_left_right_view(img_view),prefix+"flipped_lr");
     check_view(subsampled_view(img_view,typename View::point_t(2,1)),prefix+"subsampled");
     check_view(kth_channel_view<0>(img_view),prefix+"0th_k_channel");
     homogeneous_view_transformations_test(img_view, prefix, view_is_homogeneous<View>());
 }

 template <typename View>
 void image_test::homogeneous_view_transformations_test(const View& img_view, const string& prefix, mpl::true_) {
     check_view(nth_channel_view(img_view,0),prefix+"0th_n_channel");
 }


 void image_test::virtual_view_test() {
     typedef mandelbrot_fn<rgb8_pixel_t> deref_t;
     typedef deref_t::point_t            point_t;
     typedef virtual_2d_locator<deref_t,false> locator_t;
     typedef image_view<locator_t> my_virt_view_t;

     boost::function_requires<PixelLocatorConcept<locator_t> >();
     gil_function_requires<StepIteratorConcept<locator_t::x_iterator> >();

     point_t dims(200,200);
     my_virt_view_t mandel(dims, locator_t(point_t(0,0), point_t(1,1), deref_t(dims, rgb8_pixel_t(255,0,255), rgb8_pixel_t(0,255,0))));

     gray8s_image_t img(dims);
     fill_pixels(view(img),0);   // our x_gradient algorithm doesn't change the first & last column, so make sure they are 0
     x_gradient(color_converted_view<gray8_pixel_t>(mandel), view(img));
     check_view(color_converted_view<gray8_pixel_t>(const_view(img)), "mandelLuminosityGradient");

     view_transformations_test(mandel,"virtual_");
     histogram_test(mandel,"virtual_");
 }

 // Test alignment and packed images
 void image_test::packed_image_test() {
     typedef bit_aligned_image3_type<1,3,1, bgr_layout_t>::type bgr131_image_t;
     typedef bgr131_image_t::value_type bgr131_pixel_t;
     bgr131_pixel_t fill_val(1,3,1);

     bgr131_image_t bgr131_img(3,10);
     fill_pixels(view(bgr131_img), fill_val);

     bgr131_image_t bgr131a_img(3,10,1);
     copy_pixels(const_view(bgr131_img), view(bgr131a_img));

     bgr131_image_t bgr131b_img(3,10,4);
     copy_pixels(const_view(bgr131_img), view(bgr131b_img));

     error_if(bgr131_img!=bgr131a_img || bgr131a_img!=bgr131b_img);
 }

 void image_test::dynamic_image_test() {
     typedef any_image<mpl::vector<gray8_image_t, bgr8_image_t, argb8_image_t,
                                   rgb8_image_t, rgb8_planar_image_t> > any_image_t;
     rgb8_planar_image_t img(sample_view.dimensions());
     copy_pixels(sample_view, view(img));
     any_image_t any_img=any_image_t(img);

     check_view(view(any_img), "dynamic_");
     check_view(flipped_left_right_view(view(any_img)), "dynamic_fliplr");
     check_view(flipped_up_down_view(view(any_img)), "dynamic_flipud");

     any_image_t::view_t subimageView=subimage_view(view(any_img),0,0,10,15);

     check_view(subimageView, "dynamic_subimage");
     check_view(subsampled_view(rotated180_view(view(any_img)), 2,1), "dynamic_subimage_subsampled180rot");
 }

 template <typename Img>
 void image_test::image_all_test(const string& prefix) {
     basic_test<Img>(prefix+"basic_");

     Img img;
     img.recreate(sample_view.dimensions());
     copy_and_convert_pixels(sample_view,view(img));

     view_transformations_test(view(img), prefix+"views_");

     histogram_test(const_view(img),prefix+"histogram_");
 }

 void image_test::run() {
     initialize();

     image_all_test<bgr8_image_t>("bgr8_");
     image_all_test<rgb8_image_t>("rgb8_");
     image_all_test<rgb8_planar_image_t>("planarrgb8_");
     image_all_test<gray8_image_t>("gray8_");

     typedef const bit_aligned_pixel_reference<boost::uint8_t, mpl::vector3_c<int,1,2,1>, bgr_layout_t, true>  bgr121_ref_t;
     typedef image<bgr121_ref_t,false> bgr121_image_t;
     image_all_test<bgr121_image_t>("bgr121_");

     // TODO: Remove?
     view_transformations_test(subsampled_view(sample_view,point2<ptrdiff_t>(1,2)),"subsampled_");
     view_transformations_test(color_converted_view<gray8_pixel_t>(sample_view),"color_converted_");

     virtual_view_test();
     packed_image_test();
     dynamic_image_test();

     finalize();
 }


 ////////////////////////////////////////////////////
 ///
 ///  Performs or generates image tests using checksums
 ///
 ////////////////////////////////////////////////////

 class checksum_image_mgr : public image_test {
 protected:
     typedef map<string,boost::crc_32_type::value_type> crc_map_t;
     crc_map_t _crc_map;
 };

 ////////////////////////////////////////////////////
 ///
 ///  Performs image tests by comparing image pixel checksums against a reference
 ///
 ////////////////////////////////////////////////////

 class checksum_image_test : public checksum_image_mgr {
 public:
     checksum_image_test(const char* filename) : _filename(filename) {}
 private:
     const char* _filename;
     virtual void initialize();
     virtual void check_view_impl(const rgb8c_view_t& v, const string& name);
 };

 // Load the checksums from the reference file and create the start image
 void checksum_image_test::initialize() {
     string crc_name;
     boost::crc_32_type::value_type crc_result;
     fstream checksum_ref(_filename,ios::in);
     while (true) {
         checksum_ref >> crc_name >> std::hex >> crc_result;
         if(checksum_ref.fail()) break;
         _crc_map[crc_name]=crc_result;
     }
     checksum_ref.close();
 }

 // Create a checksum for the given view and compare it with the reference checksum. Throw exception if different
 void checksum_image_test::check_view_impl(const rgb8c_view_t& img_view, const string& name) {
     boost::crc_32_type checksum_acumulator;
     checksum_acumulator.process_bytes(img_view.row_begin(0),img_view.size()*3);

     cerr << "Checking checksum for " << name << endl;
     if (checksum_acumulator.checksum()!=_crc_map[name]) {
         cerr << "Checksum error in "<<name<<"\n";
         error_if(true);
     }
 }

 ////////////////////////////////////////////////////
 ///
 ///  Generates a set of reference checksums to compare against
 ///
 ////////////////////////////////////////////////////

 class checksum_image_generate : public checksum_image_mgr {
 public:
     checksum_image_generate(const char* filename) : _filename(filename) {}
 private:
     const char* _filename;
     virtual void check_view_impl(const rgb8c_view_t& img_view, const string& name);
     virtual void finalize();
 };

 // Add the checksum of the given view to the map of checksums
 void checksum_image_generate::check_view_impl(const rgb8c_view_t& img_view, const string& name) {
     boost::crc_32_type result;
     result.process_bytes(img_view.row_begin(0),img_view.size()*3);
     cerr << "Generating checksum for " << name << endl;
     _crc_map[name] = result.checksum();
 }

 // Save the checksums into the reference file
 void checksum_image_generate::finalize() {
     fstream checksum_ref(_filename,ios::out);
     for (crc_map_t::const_iterator it=_crc_map.begin(); it!=_crc_map.end(); ++it) {
         checksum_ref << it->first << " " << std::hex << it->second << "\r\n";
     }
     checksum_ref.close();
 }


 ////////////////////////////////////////////////////
 ///
 ///  Performs or generates image tests using image I/O
 ///
 ////////////////////////////////////////////////////

 extern const string in_dir;
 extern const string out_dir;
 extern const string ref_dir;

 const string in_dir="";  // directory of source images
 const string out_dir=in_dir+"image-out/";    // directory where to write output
 const string ref_dir=in_dir+"image-ref/";  // reference directory to compare written with actual output

 #ifndef BOOST_GIL_NO_IO

 #include <boost/gil/extension/io/jpeg_io.hpp>

 class file_image_mgr : public image_test {};

 class file_image_test : public file_image_mgr {
 public:
     file_image_test(const char*) {}
 protected:
     void check_view_impl(const boost::gil::rgb8c_view_t& img_view,const string& name) {
         jpeg_write_view(out_dir+name+".jpg",img_view);
         rgb8_image_t img1, img2;
         jpeg_read_and_convert_image(out_dir+name+".jpg",img1);
         cerr << "Testing "<<name<<"\n";

         jpeg_read_and_convert_image(ref_dir+name+".jpg",img2);
         if (img1!=img2) {
             cerr << "Error with "<<name<<"\n";
             error_if(true);
         }
     }
 };

 class file_image_generate : public file_image_mgr {
 public:
     file_image_generate(const char*) {}
 protected:
     void check_view_impl(const boost::gil::rgb8c_view_t& img_view,const string& name) {
         jpeg_write_view(ref_dir+name+".jpg",img_view);
         cerr << "Writing "<<name<<"\n";
     }
 };
 #endif


 void static_checks() {
     gil_function_requires<ImageConcept<rgb8_image_t> >();

     BOOST_STATIC_ASSERT(view_is_basic<rgb8_step_view_t>::value);
     BOOST_STATIC_ASSERT(view_is_basic<cmyk8c_planar_step_view_t>::value);
     BOOST_STATIC_ASSERT(view_is_basic<rgb8_planar_view_t>::value);

     BOOST_STATIC_ASSERT(view_is_step_in_x<rgb8_step_view_t>::value);
     BOOST_STATIC_ASSERT(view_is_step_in_x<cmyk8c_planar_step_view_t>::value);
     BOOST_STATIC_ASSERT(!view_is_step_in_x<rgb8_planar_view_t>::value);

     BOOST_STATIC_ASSERT(!is_planar<rgb8_step_view_t>::value);
     BOOST_STATIC_ASSERT(is_planar<cmyk8c_planar_step_view_t>::value);
     BOOST_STATIC_ASSERT(is_planar<rgb8_planar_view_t>::value);

     BOOST_STATIC_ASSERT(view_is_mutable<rgb8_step_view_t>::value);
     BOOST_STATIC_ASSERT(!view_is_mutable<cmyk8c_planar_step_view_t>::value);
     BOOST_STATIC_ASSERT(view_is_mutable<rgb8_planar_view_t>::value);

     BOOST_STATIC_ASSERT((boost::is_same<derived_view_type<cmyk8c_planar_step_view_t>::type, cmyk8c_planar_step_view_t>::value));
     BOOST_STATIC_ASSERT((boost::is_same<derived_view_type<cmyk8c_planar_step_view_t, bits16, rgb_layout_t>::type,  rgb16c_planar_step_view_t>::value));
     BOOST_STATIC_ASSERT((boost::is_same<derived_view_type<cmyk8c_planar_step_view_t, use_default, rgb_layout_t, mpl::false_, use_default, mpl::false_>::type,  rgb8c_step_view_t>::value));

     // test view get raw data (mostly compile-time test)
     {
     rgb8_image_t rgb8(100,100);
     unsigned char* data=interleaved_view_get_raw_data(view(rgb8));
     const unsigned char* cdata=interleaved_view_get_raw_data(const_view(rgb8));
     error_if(data!=cdata);
     }

     {
     rgb16s_planar_image_t rgb8(100,100);
     short* data=planar_view_get_raw_data(view(rgb8),1);
     const short* cdata=planar_view_get_raw_data(const_view(rgb8),1);
     error_if(data!=cdata);
     }
 }

 #ifdef BOOST_GIL_NO_IO
 typedef checksum_image_test     image_test_t;
 typedef checksum_image_generate image_generate_t;
 #else
 typedef file_image_test         image_test_t;
 typedef file_image_generate     image_generate_t;
 #endif

 #ifdef BOOST_GIL_GENERATE_REFERENCE_DATA
 typedef image_generate_t        image_mgr_t;
 #else
 typedef image_test_t            image_mgr_t;
 #endif


 void test_image(const char* ref_checksum) {
     image_mgr_t mgr(ref_checksum);

     mgr.run();
     static_checks();
 }

 int main(int argc, char* argv[]) {

     const char* local_name = "gil_reference_checksums.txt";
     const char* name_from_status = "../libs/gil/test/gil_reference_checksums.txt";

     std::ifstream file_is_there(local_name);
     if (file_is_there) {
         test_image(local_name);
     } else {
         std::ifstream file_is_there(name_from_status);
         if (file_is_there)
             test_image(name_from_status);
         else {
             std::cerr << "Unable to open gil_reference_checksums.txt"<<std::endl;
             return 1;
         }
     }

     return 0;
 }
	/*
	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.
	*/
	// image_test.cpp :
	//

	#ifdef _MSC_VER
	//#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)
	#pragma warning(disable : 4503) // decorated name length exceeded, name was truncated
	#endif

	#include <string>
	#include <vector>
	#include <ios>
	#include <iostream>
	#include <fstream>
	#include <map>
	#include <boost/lambda/lambda.hpp>
	#include <boost/lambda/bind.hpp>
	#include <boost/mpl/vector.hpp>
	#include <boost/gil/extension/dynamic_image/dynamic_image_all.hpp>
	#include <boost/crc.hpp>

	using namespace boost::gil;
	using namespace std;
	using namespace boost;

	extern rgb8c_planar_view_t sample_view;
	void error_if(bool condition);


	// When BOOST_GIL_GENERATE_REFERENCE_DATA is defined, the reference data is generated and saved.
	// When it is undefined, regression tests are checked against it
	//#define BOOST_GIL_GENERATE_REFERENCE_DATA

	////////////////////////////////////////////////////
	///
	/// Some algorithms to use in testing
	///
	////////////////////////////////////////////////////

	template <typename GrayView, typename R>
	void gray_image_hist(const GrayView& img_view, R& hist) {
	// for_each_pixel(img_view,++lambda::var(hist)[lambda::_1]);
	for (typename GrayView::iterator it=img_view.begin(); it!=img_view.end(); ++it)
	++hist[*it];
	}

	template <typename V, typename R>
	void get_hist(const V& img_view, R& hist) {
	gray_image_hist(color_converted_view<gray8_pixel_t>(img_view), hist);
	}

	// testing custom color conversion
	template <typename C1, typename C2>
	struct my_color_converter_impl : public default_color_converter_impl<C1,C2> {};
	template <typename C1>
	struct my_color_converter_impl<C1,gray_t> {
	template <typename P1, typename P2>
	void operator()(const P1& src, P2& dst) const {
	default_color_converter_impl<C1,gray_t>()(src,dst);
	get_color(dst,gray_color_t())=channel_invert(get_color(dst,gray_color_t()));
	}
	};

	struct my_color_converter {
	template <typename SrcP,typename DstP>
	void operator()(const SrcP& src,DstP& dst) const {
	typedef typename color_space_type<SrcP>::type src_cs_t;
	typedef typename color_space_type<DstP>::type dst_cs_t;
	my_color_converter_impl<src_cs_t,dst_cs_t>()(src,dst);
	}
	};

	// Models a Unary Function
	template <typename P> // Models PixelValueConcept
	struct mandelbrot_fn {
	typedef point2<std::ptrdiff_t> point_t;

	typedef mandelbrot_fn const_t;
	typedef P value_type;
	typedef value_type reference;
	typedef value_type const_reference;
	typedef point_t argument_type;
	typedef reference result_type;
	BOOST_STATIC_CONSTANT(bool, is_mutable=false);

	value_type _in_color,_out_color;
	point_t _img_size;
	static const int MAX_ITER=100; // max number of iterations

	mandelbrot_fn() {}
	mandelbrot_fn(const point_t& sz, const value_type& in_color, const value_type& out_color) : _in_color(in_color), _out_color(out_color), _img_size(sz) {}

	result_type operator()(const point_t& p) const {
	// normalize the coords to (-2..1, -1.5..1.5)
	// (actually make y -1.0..2 so it is asymmetric, so we can verify some view factory methods)
	double t=get_num_iter(point2<double>(p.x/(double)_img_size.x3-2, p.y/(double)_img_size.y3-1.0f));//1.5f));
	t=pow(t,0.2);

	value_type ret;
	for (int k=0; k<num_channels<P>::value; ++k)
	ret[k]=(typename channel_type<value_type>::type)(_in_color[k]t + _out_color[k](1-t));
	return ret;
	}

	private:
	double get_num_iter(const point2<double>& p) const {
	point2<double> Z(0,0);
	for (int i=0; i<MAX_ITER; ++i) {
	Z = point2<double>(Z.xZ.x - Z.yZ.y + p.x, 2Z.xZ.y + p.y);
	if (Z.xZ.x + Z.yZ.y > 4)
	return i/(double)MAX_ITER;
	}
	return 0;
	}
	};

	template <typename T>
	void x_gradient(const T& src, const gray8s_view_t& dst) {
	for (int y=0; y<src.height(); ++y) {
	typename T::x_iterator src_it = src.row_begin(y);
	gray8s_view_t::x_iterator dst_it = dst.row_begin(y);

	for (int x=1; x<src.width()-1; ++x)
	dst_it[x] = (src_it[x+1] - src_it[x-1]) / 2;
	}
	}

	// A quick test whether a view is homogeneous

	template <typename Pixel>
	struct pixel_is_homogeneous : public mpl::true_ {};

	template <typename P, typename C, typename L>
	struct pixel_is_homogeneous<packed_pixel<P,C,L> > : public mpl::false_ {};

	template <typename View>
	struct view_is_homogeneous : public pixel_is_homogeneous<typename View::value_type> {};


	////////////////////////////////////////////////////
	///
	/// Tests image view transformations and algorithms
	///
	////////////////////////////////////////////////////
	class image_test {
	public:
	virtual void initialize() {}
	virtual void finalize() {}
	virtual ~image_test() {}

	void run();
	protected:
	virtual void check_view_impl(const rgb8c_view_t& view, const string& name)=0;
	template <typename View>
	void check_view(const View& img_view, const string& name) {
	rgb8_image_t rgb_img(img_view.dimensions());
	copy_and_convert_pixels(img_view,view(rgb_img));
	check_view_impl(const_view(rgb_img), name);
	}
	private:
	template <typename Img> void basic_test(const string& prefix);
	template <typename View> void view_transformations_test(const View& img_view, const string& prefix);
	template <typename View> void homogeneous_view_transformations_test(const View& img_view, const string& prefix, mpl::true_);
	template <typename View> void homogeneous_view_transformations_test(const View& img_view, const string& prefix, mpl::false_) {}
	template <typename View> void histogram_test(const View& img_view, const string& prefix);
	void virtual_view_test();
	void packed_image_test();
	void dynamic_image_test();
	template <typename Img> void image_all_test(const string& prefix);
	};


	// testing image iterators, clone, fill, locators, color convert
	template <typename Img>
	void image_test::basic_test(const string& prefix) {
	typedef typename Img::view_t View;

	// make a 20x20 image
	Img img(typename View::point_t(20,20));
	const View& img_view=view(img);

	// fill it with red
	rgb8_pixel_t red8(255,0,0), green8(0,255,0), blue8(0,0,255), white8(255,255,255);
	typename View::value_type red,green,blue,white;
	color_convert(red8,red);
	default_color_converter()(red8,red);
	red=color_convert_deref_fn<rgb8_ref_t,typename Img::view_t::value_type>()(red8);

	color_convert(green8,green);
	color_convert(blue8,blue);
	color_convert(white8,white);
	fill(img_view.begin(),img_view.end(),red);

	color_convert(red8,img_view[0]);

	// pointer to first pixel of second row
	typename View::reference rt=img_view.at(0,0)[img_view.width()];
	typename View::x_iterator ptr=&rt;
	typename View::reference rt2=*(img_view.at(0,0)+img_view.width());
	typename View::x_iterator ptr2=&rt2;
	error_if(ptr!=ptr2);
	error_if(img_view.x_at(0,0)+10!=10+img_view.x_at(0,0));

	// draw a blue line along the diagonal
	typename View::xy_locator loc=img_view.xy_at(0,img_view.height()-1);
	for (int y=0; y<img_view.height(); ++y) {
	*loc=blue;
	++loc.x();
	loc.y()--;
	}

	// draw a green dotted line along the main diagonal with step of 3
	loc=img_view.xy_at(img_view.width()-1,img_view.height()-1);
	while (loc.x()>=img_view.x_at(0,0)) {
	*loc=green;
	loc-=typename View::point_t(3,3);
	}

	// Clone and make every red pixel white
	Img imgWhite(img);
	for (typename View::iterator it=view(imgWhite).end(); (it-1)!=view(imgWhite).begin(); --it) {
	if (*(it-1)==red)
	*(it-1)=white;
	}

	check_view(img_view,prefix+"red_x");
	check_view(view(imgWhite),prefix+"white_x");
	}

	template <typename View>
	void image_test::histogram_test(const View& img_view, const string& prefix) {
	// vector<int> histogram(255,0);
	// get_hist(cropped,histogram.begin());
	unsigned char histogram[256];
	fill(histogram,histogram+256,0);
	get_hist(img_view,histogram);
	gray8c_view_t hist_view=interleaved_view(256,1,(const gray8_pixel_t*)histogram,256);
	check_view(hist_view,prefix+"histogram");
	}


	template <typename View>
	void image_test::view_transformations_test(const View& img_view, const string& prefix) {
	check_view(img_view,prefix+"original");

	check_view(subimage_view(img_view, iround(img_view.dimensions()/4), iround(img_view.dimensions()/2)),prefix+"cropped");
	check_view(color_converted_view<gray8_pixel_t>(img_view),prefix+"gray8");
	check_view(color_converted_view<gray8_pixel_t>(img_view,my_color_converter()),prefix+"my_gray8");
	check_view(transposed_view(img_view),prefix+"transpose");
	check_view(rotated180_view(img_view),prefix+"rot180");
	check_view(rotated90cw_view(img_view),prefix+"90cw");
	check_view(rotated90ccw_view(img_view),prefix+"90ccw");
	check_view(flipped_up_down_view(img_view),prefix+"flipped_ud");
	check_view(flipped_left_right_view(img_view),prefix+"flipped_lr");
	check_view(subsampled_view(img_view,typename View::point_t(2,1)),prefix+"subsampled");
	check_view(kth_channel_view<0>(img_view),prefix+"0th_k_channel");
	homogeneous_view_transformations_test(img_view, prefix, view_is_homogeneous<View>());
	}

	template <typename View>
	void image_test::homogeneous_view_transformations_test(const View& img_view, const string& prefix, mpl::true_) {
	check_view(nth_channel_view(img_view,0),prefix+"0th_n_channel");
	}


	void image_test::virtual_view_test() {
	typedef mandelbrot_fn<rgb8_pixel_t> deref_t;
	typedef deref_t::point_t point_t;
	typedef virtual_2d_locator<deref_t,false> locator_t;
	typedef image_view<locator_t> my_virt_view_t;

	boost::function_requires<PixelLocatorConcept<locator_t> >();
	gil_function_requires<StepIteratorConcept<locator_t::x_iterator> >();

	point_t dims(200,200);
	my_virt_view_t mandel(dims, locator_t(point_t(0,0), point_t(1,1), deref_t(dims, rgb8_pixel_t(255,0,255), rgb8_pixel_t(0,255,0))));

	gray8s_image_t img(dims);
	fill_pixels(view(img),0); // our x_gradient algorithm doesn't change the first & last column, so make sure they are 0
	x_gradient(color_converted_view<gray8_pixel_t>(mandel), view(img));
	check_view(color_converted_view<gray8_pixel_t>(const_view(img)), "mandelLuminosityGradient");

	view_transformations_test(mandel,"virtual_");
	histogram_test(mandel,"virtual_");
	}

	// Test alignment and packed images
	void image_test::packed_image_test() {
	typedef bit_aligned_image3_type<1,3,1, bgr_layout_t>::type bgr131_image_t;
	typedef bgr131_image_t::value_type bgr131_pixel_t;
	bgr131_pixel_t fill_val(1,3,1);

	bgr131_image_t bgr131_img(3,10);
	fill_pixels(view(bgr131_img), fill_val);

	bgr131_image_t bgr131a_img(3,10,1);
	copy_pixels(const_view(bgr131_img), view(bgr131a_img));

	bgr131_image_t bgr131b_img(3,10,4);
	copy_pixels(const_view(bgr131_img), view(bgr131b_img));

	error_if(bgr131_img!=bgr131a_img \|\| bgr131a_img!=bgr131b_img);
	}

	void image_test::dynamic_image_test() {
	typedef any_image<mpl::vector<gray8_image_t, bgr8_image_t, argb8_image_t,
	rgb8_image_t, rgb8_planar_image_t> > any_image_t;
	rgb8_planar_image_t img(sample_view.dimensions());
	copy_pixels(sample_view, view(img));
	any_image_t any_img=any_image_t(img);

	check_view(view(any_img), "dynamic_");
	check_view(flipped_left_right_view(view(any_img)), "dynamic_fliplr");
	check_view(flipped_up_down_view(view(any_img)), "dynamic_flipud");

	any_image_t::view_t subimageView=subimage_view(view(any_img),0,0,10,15);

	check_view(subimageView, "dynamic_subimage");
	check_view(subsampled_view(rotated180_view(view(any_img)), 2,1), "dynamic_subimage_subsampled180rot");
	}

	template <typename Img>
	void image_test::image_all_test(const string& prefix) {
	basic_test<Img>(prefix+"basic_");

	Img img;
	img.recreate(sample_view.dimensions());
	copy_and_convert_pixels(sample_view,view(img));

	view_transformations_test(view(img), prefix+"views_");

	histogram_test(const_view(img),prefix+"histogram_");
	}

	void image_test::run() {
	initialize();

	image_all_test<bgr8_image_t>("bgr8_");
	image_all_test<rgb8_image_t>("rgb8_");
	image_all_test<rgb8_planar_image_t>("planarrgb8_");
	image_all_test<gray8_image_t>("gray8_");

	typedef const bit_aligned_pixel_reference<boost::uint8_t, mpl::vector3_c<int,1,2,1>, bgr_layout_t, true> bgr121_ref_t;
	typedef image<bgr121_ref_t,false> bgr121_image_t;
	image_all_test<bgr121_image_t>("bgr121_");

	// TODO: Remove?
	view_transformations_test(subsampled_view(sample_view,point2<ptrdiff_t>(1,2)),"subsampled_");
	view_transformations_test(color_converted_view<gray8_pixel_t>(sample_view),"color_converted_");

	virtual_view_test();
	packed_image_test();
	dynamic_image_test();

	finalize();
	}



	////////////////////////////////////////////////////
	///
	/// Performs or generates image tests using checksums
	///
	////////////////////////////////////////////////////

	class checksum_image_mgr : public image_test {
	protected:
	typedef map<string,boost::crc_32_type::value_type> crc_map_t;
	crc_map_t _crc_map;
	};

	////////////////////////////////////////////////////
	///
	/// Performs image tests by comparing image pixel checksums against a reference
	///
	////////////////////////////////////////////////////

	class checksum_image_test : public checksum_image_mgr {
	public:
	checksum_image_test(const char* filename) : _filename(filename) {}
	private:
	const char* _filename;
	virtual void initialize();
	virtual void check_view_impl(const rgb8c_view_t& v, const string& name);
	};

	// Load the checksums from the reference file and create the start image
	void checksum_image_test::initialize() {
	string crc_name;
	boost::crc_32_type::value_type crc_result;
	fstream checksum_ref(_filename,ios::in);
	while (true) {
	checksum_ref >> crc_name >> std::hex >> crc_result;
	if(checksum_ref.fail()) break;
	_crc_map[crc_name]=crc_result;
	}
	checksum_ref.close();
	}

	// Create a checksum for the given view and compare it with the reference checksum. Throw exception if different
	void checksum_image_test::check_view_impl(const rgb8c_view_t& img_view, const string& name) {
	boost::crc_32_type checksum_acumulator;
	checksum_acumulator.process_bytes(img_view.row_begin(0),img_view.size()*3);

	cerr << "Checking checksum for " << name << endl;
	if (checksum_acumulator.checksum()!=_crc_map[name]) {
	cerr << "Checksum error in "<<name<<"\n";
	error_if(true);
	}
	}

	////////////////////////////////////////////////////
	///
	/// Generates a set of reference checksums to compare against
	///
	////////////////////////////////////////////////////

	class checksum_image_generate : public checksum_image_mgr {
	public:
	checksum_image_generate(const char* filename) : _filename(filename) {}
	private:
	const char* _filename;
	virtual void check_view_impl(const rgb8c_view_t& img_view, const string& name);
	virtual void finalize();
	};

	// Add the checksum of the given view to the map of checksums
	void checksum_image_generate::check_view_impl(const rgb8c_view_t& img_view, const string& name) {
	boost::crc_32_type result;
	result.process_bytes(img_view.row_begin(0),img_view.size()*3);
	cerr << "Generating checksum for " << name << endl;
	_crc_map[name] = result.checksum();
	}

	// Save the checksums into the reference file
	void checksum_image_generate::finalize() {
	fstream checksum_ref(_filename,ios::out);
	for (crc_map_t::const_iterator it=_crc_map.begin(); it!=_crc_map.end(); ++it) {
	checksum_ref << it->first << " " << std::hex << it->second << "\r\n";
	}
	checksum_ref.close();
	}


	////////////////////////////////////////////////////
	///
	/// Performs or generates image tests using image I/O
	///
	////////////////////////////////////////////////////

	extern const string in_dir;
	extern const string out_dir;
	extern const string ref_dir;

	const string in_dir=""; // directory of source images
	const string out_dir=in_dir+"image-out/"; // directory where to write output
	const string ref_dir=in_dir+"image-ref/"; // reference directory to compare written with actual output

	#ifndef BOOST_GIL_NO_IO

	#include <boost/gil/extension/io/jpeg_io.hpp>

	class file_image_mgr : public image_test {};

	class file_image_test : public file_image_mgr {
	public:
	file_image_test(const char*) {}
	protected:
	void check_view_impl(const boost::gil::rgb8c_view_t& img_view,const string& name) {
	jpeg_write_view(out_dir+name+".jpg",img_view);
	rgb8_image_t img1, img2;
	jpeg_read_and_convert_image(out_dir+name+".jpg",img1);
	cerr << "Testing "<<name<<"\n";

	jpeg_read_and_convert_image(ref_dir+name+".jpg",img2);
	if (img1!=img2) {
	cerr << "Error with "<<name<<"\n";
	error_if(true);
	}
	}
	};

	class file_image_generate : public file_image_mgr {
	public:
	file_image_generate(const char*) {}
	protected:
	void check_view_impl(const boost::gil::rgb8c_view_t& img_view,const string& name) {
	jpeg_write_view(ref_dir+name+".jpg",img_view);
	cerr << "Writing "<<name<<"\n";
	}
	};
	#endif








	void static_checks() {
	gil_function_requires<ImageConcept<rgb8_image_t> >();

	BOOST_STATIC_ASSERT(view_is_basic<rgb8_step_view_t>::value);
	BOOST_STATIC_ASSERT(view_is_basic<cmyk8c_planar_step_view_t>::value);
	BOOST_STATIC_ASSERT(view_is_basic<rgb8_planar_view_t>::value);

	BOOST_STATIC_ASSERT(view_is_step_in_x<rgb8_step_view_t>::value);
	BOOST_STATIC_ASSERT(view_is_step_in_x<cmyk8c_planar_step_view_t>::value);
	BOOST_STATIC_ASSERT(!view_is_step_in_x<rgb8_planar_view_t>::value);

	BOOST_STATIC_ASSERT(!is_planar<rgb8_step_view_t>::value);
	BOOST_STATIC_ASSERT(is_planar<cmyk8c_planar_step_view_t>::value);
	BOOST_STATIC_ASSERT(is_planar<rgb8_planar_view_t>::value);

	BOOST_STATIC_ASSERT(view_is_mutable<rgb8_step_view_t>::value);
	BOOST_STATIC_ASSERT(!view_is_mutable<cmyk8c_planar_step_view_t>::value);
	BOOST_STATIC_ASSERT(view_is_mutable<rgb8_planar_view_t>::value);

	BOOST_STATIC_ASSERT((boost::is_same<derived_view_type<cmyk8c_planar_step_view_t>::type, cmyk8c_planar_step_view_t>::value));
	BOOST_STATIC_ASSERT((boost::is_same<derived_view_type<cmyk8c_planar_step_view_t, bits16, rgb_layout_t>::type, rgb16c_planar_step_view_t>::value));
	BOOST_STATIC_ASSERT((boost::is_same<derived_view_type<cmyk8c_planar_step_view_t, use_default, rgb_layout_t, mpl::false_, use_default, mpl::false_>::type, rgb8c_step_view_t>::value));

	// test view get raw data (mostly compile-time test)
	{
	rgb8_image_t rgb8(100,100);
	unsigned char* data=interleaved_view_get_raw_data(view(rgb8));
	const unsigned char* cdata=interleaved_view_get_raw_data(const_view(rgb8));
	error_if(data!=cdata);
	}

	{
	rgb16s_planar_image_t rgb8(100,100);
	short* data=planar_view_get_raw_data(view(rgb8),1);
	const short* cdata=planar_view_get_raw_data(const_view(rgb8),1);
	error_if(data!=cdata);
	}
	}

	#ifdef BOOST_GIL_NO_IO
	typedef checksum_image_test image_test_t;
	typedef checksum_image_generate image_generate_t;
	#else
	typedef file_image_test image_test_t;
	typedef file_image_generate image_generate_t;
	#endif

	#ifdef BOOST_GIL_GENERATE_REFERENCE_DATA
	typedef image_generate_t image_mgr_t;
	#else
	typedef image_test_t image_mgr_t;
	#endif


	void test_image(const char* ref_checksum) {
	image_mgr_t mgr(ref_checksum);

	mgr.run();
	static_checks();
	}

	int main(int argc, char* argv[]) {

	const char* local_name = "gil_reference_checksums.txt";
	const char* name_from_status = "../libs/gil/test/gil_reference_checksums.txt";

	std::ifstream file_is_there(local_name);
	if (file_is_there) {
	test_image(local_name);
	} else {
	std::ifstream file_is_there(name_from_status);
	if (file_is_there)
	test_image(name_from_status);
	else {
	std::cerr << "Unable to open gil_reference_checksums.txt"<<std::endl;
	return 1;
	}
	}

	return 0;
	}