boost/gil/image_processing/scaling.hpp
// // Copyright 2019 Olzhas Zhumabek <anonymous.from.applecity@gmail.com> // // 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) // #ifndef BOOST_GIL_IMAGE_PROCESSING_SCALING_HPP #define BOOST_GIL_IMAGE_PROCESSING_SCALING_HPP #include <boost/gil/image_view.hpp> #include <boost/gil/rgb.hpp> #include <boost/gil/pixel.hpp> #include <boost/gil/image_processing/numeric.hpp> namespace boost { namespace gil { /// \defgroup ScalingAlgorithms /// \brief Algorthims suitable for rescaling /// /// These algorithms are used to improve image quality after image resizing is made. /// /// \defgroup DownScalingAlgorithms /// \ingroup ScalingAlgorithms /// \brief Algorthims suitable for downscaling /// /// These algorithms provide best results when used for downscaling. Using for upscaling will /// probably provide less than good results. /// /// \brief a single step of lanczos downscaling /// \ingroup DownScalingAlgorithms /// /// Use this algorithm to scale down source image into a smaller image with reasonable quality. /// Do note that having a look at the output once is a good idea, since it might have ringing /// artifacts. template <typename ImageView> void lanczos_at( ImageView input_view, ImageView output_view, typename ImageView::x_coord_t source_x, typename ImageView::y_coord_t source_y, typename ImageView::x_coord_t target_x, typename ImageView::y_coord_t target_y, std::ptrdiff_t a) { using x_coord_t = typename ImageView::x_coord_t; using y_coord_t = typename ImageView::y_coord_t; using pixel_t = typename std::remove_reference<decltype(std::declval<ImageView>()(0, 0))>::type; // C++11 doesn't allow auto in lambdas using channel_t = typename std::remove_reference < decltype(std::declval<pixel_t>().at(std::integral_constant<int, 0>{})) >::type; pixel_t result_pixel; static_transform(result_pixel, result_pixel, [](channel_t) { return static_cast<channel_t>(0); }); auto x_zero = static_cast<x_coord_t>(0); auto x_one = static_cast<x_coord_t>(1); auto y_zero = static_cast<y_coord_t>(0); auto y_one = static_cast<y_coord_t>(1); for (y_coord_t y_i = (std::max)(source_y - static_cast<y_coord_t>(a) + y_one, y_zero); y_i <= (std::min)(source_y + static_cast<y_coord_t>(a), input_view.height() - y_one); ++y_i) { for (x_coord_t x_i = (std::max)(source_x - static_cast<x_coord_t>(a) + x_one, x_zero); x_i <= (std::min)(source_x + static_cast<x_coord_t>(a), input_view.width() - x_one); ++x_i) { double lanczos_response = lanczos(source_x - x_i, a) * lanczos(source_y - y_i, a); auto op = [lanczos_response](channel_t prev, channel_t next) { return static_cast<channel_t>(prev + next * lanczos_response); }; static_transform(result_pixel, input_view(source_x, source_y), result_pixel, op); } } output_view(target_x, target_y) = result_pixel; } /// \brief Complete Lanczos algorithm /// \ingroup DownScalingAlgorithms /// /// This algorithm does full pass over resulting image and convolves pixels from /// original image. Do note that it might be a good idea to have a look at test /// output as there might be ringing artifacts. /// Based on wikipedia article: /// https://en.wikipedia.org/wiki/Lanczos_resampling /// with standardinzed cardinal sin (sinc) template <typename ImageView> void scale_lanczos(ImageView input_view, ImageView output_view, std::ptrdiff_t a) { double scale_x = (static_cast<double>(output_view.width())) / static_cast<double>(input_view.width()); double scale_y = (static_cast<double>(output_view.height())) / static_cast<double>(input_view.height()); using x_coord_t = typename ImageView::x_coord_t; using y_coord_t = typename ImageView::y_coord_t; for (y_coord_t y = 0; y < output_view.height(); ++y) { for (x_coord_t x = 0; x < output_view.width(); ++x) { lanczos_at(input_view, output_view, x / scale_x, y / scale_y, x, y, a); } } } }} // namespace boost::gil #endif