/***************************************************************************** * * This file is part of Mapnik (c++ mapping toolkit) * * Copyright (C) 2006 Artem Pavlenko * * This library is free software; you can redistribute it and/or * modify it under the terms of the GNU Lesser General Public * License as published by the Free Software Foundation; either * version 2.1 of the License, or (at your option) any later version. * * This library is distributed in the hope that it will be useful, * but WITHOUT ANY WARRANTY; without even the implied warranty of * MERCHANTABILITY or FITNESS FOR A PARTICULAR PURPOSE. See the GNU * Lesser General Public License for more details. * * You should have received a copy of the GNU Lesser General Public * License along with this library; if not, write to the Free Software * Foundation, Inc., 51 Franklin St, Fifth Floor, Boston, MA 02110-1301 USA * *****************************************************************************/ //$Id: image_util.cpp 36 2005-04-05 14:32:18Z pavlenko $ extern "C" { #include } // mapnik #include #include #include #include #include #include // boost #include // jpeg #if defined(HAVE_JPEG) #include #endif #ifdef HAVE_CAIRO #include #endif #include #include // stl #include #include #include #include // agg //#include "agg_conv_transform.h" #include "agg_image_accessors.h" #include "agg_pixfmt_rgba.h" #include "agg_rasterizer_scanline_aa.h" #include "agg_renderer_scanline.h" #include "agg_rendering_buffer.h" #include "agg_scanline_u.h" //#include "agg_scanline_p.h" #include "agg_span_allocator.h" #include "agg_span_image_filter_rgba.h" #include "agg_span_interpolator_linear.h" #include "agg_trans_affine.h" #include "agg_image_filters.h" namespace mapnik { template std::string save_to_string(T const& image, std::string const& type) { std::ostringstream ss(std::ios::out|std::ios::binary); save_to_stream(image, ss, type); return ss.str(); } template void save_to_file(T const& image, std::string const& filename, std::string const& type) { std::ofstream file (filename.c_str(), std::ios::out| std::ios::trunc|std::ios::binary); if (file) { save_to_stream(image, file, type); } else throw ImageWriterException("Could not write file to " + filename ); } template void save_to_stream(T const& image, std::ostream & stream, std::string const& type) { if (stream) { //all this should go into image_writer factory if (type == "png") save_as_png(stream, image); else if (boost::algorithm::istarts_with(type, std::string("png256")) || boost::algorithm::istarts_with(type, std::string("png8")) ) { int colors = 256; int trans_mode = -1; double gamma = -1; bool use_octree = true; if (type.length() > 6){ boost::char_separator sep(":"); boost::tokenizer< boost::char_separator > tokens(type, sep); BOOST_FOREACH(string t, tokens) { if (t == "m=h") { use_octree = false; } if (t == "m=o") { use_octree = true; } if (boost::algorithm::istarts_with(t,std::string("c="))) { try { colors = boost::lexical_cast(t.substr(2)); if (colors < 0 || colors > 256) throw ImageWriterException("invalid color parameter: " + t.substr(2) + " out of bounds"); } catch(boost::bad_lexical_cast &) { throw ImageWriterException("invalid color parameter: " + t.substr(2)); } } if (boost::algorithm::istarts_with(t, std::string("t="))) { try { trans_mode= boost::lexical_cast(t.substr(2)); if (trans_mode < 0 || trans_mode > 2) throw ImageWriterException("invalid trans_mode parameter: " + t.substr(2) + " out of bounds"); } catch(boost::bad_lexical_cast &) { throw ImageWriterException("invalid trans_mode parameter: " + t.substr(2)); } } if (boost::algorithm::istarts_with(t, std::string("g="))) { try { gamma= boost::lexical_cast(t.substr(2)); if (gamma < 0) throw ImageWriterException("invalid gamma parameter: " + t.substr(2) + " out of bounds"); } catch(boost::bad_lexical_cast &) { throw ImageWriterException("invalid gamma parameter: " + t.substr(2)); } } } } if (use_octree) save_as_png256(stream, image, colors); else save_as_png256_hex(stream, image, colors, trans_mode, gamma); } #if defined(HAVE_JPEG) else if (boost::algorithm::istarts_with(type,std::string("jpeg"))) { int quality = 85; try { if(type.substr(4).length() != 0) { quality = boost::lexical_cast(type.substr(4)); if(quality<0 || quality>100) throw ImageWriterException("invalid jpeg quality: " + type.substr(4) + " out of bounds"); } save_as_jpeg(stream, quality, image); } catch(boost::bad_lexical_cast &) { throw ImageWriterException("invalid jpeg quality: " + type.substr(4) + " not a number"); } } #endif else throw ImageWriterException("unknown file type: " + type); } else throw ImageWriterException("Could not write to empty stream" ); } template void save_to_file(T const& image,std::string const& filename) { boost::optional type = type_from_filename(filename); if (type) { save_to_file(image,filename,*type); } } #if defined(HAVE_CAIRO) // TODO - move to separate cairo_io.hpp void save_to_cairo_file(mapnik::Map const& map, std::string const& filename) { boost::optional type = type_from_filename(filename); if (type) { save_to_cairo_file(map,filename,*type); } } void save_to_cairo_file(mapnik::Map const& map, std::string const& filename, std::string const& type) { std::ofstream file (filename.c_str(), std::ios::out|std::ios::trunc|std::ios::binary); if (file) { Cairo::RefPtr surface; unsigned width = map.width(); unsigned height = map.height(); if (type == "pdf") surface = Cairo::PdfSurface::create(filename,width,height); else if (type == "svg") surface = Cairo::SvgSurface::create(filename,width,height); else if (type == "ps") surface = Cairo::PsSurface::create(filename,width,height); else if (type == "ARGB32") surface = Cairo::ImageSurface::create(Cairo::FORMAT_ARGB32,width,height); else if (type == "RGB24") surface = Cairo::ImageSurface::create(Cairo::FORMAT_RGB24,width,height); else throw ImageWriterException("unknown file type: " + type); Cairo::RefPtr context = Cairo::Context::create(surface); // TODO - expose as user option /* if (type == "ARGB32" || type == "RGB24") { context->set_antialias(Cairo::ANTIALIAS_NONE); } */ mapnik::cairo_renderer ren(map, context); ren.apply(); if (type == "ARGB32" || type == "RGB24") { surface->write_to_png(filename); } surface->finish(); } } #endif template void save_to_file(image_data_32 const&, std::string const&, std::string const&); template void save_to_file(image_data_32 const&, std::string const&); template std::string save_to_string(image_data_32 const&, std::string const&); template void save_to_file > (image_view const&, std::string const&, std::string const&); template void save_to_file > (image_view const&, std::string const&); template std::string save_to_string > (image_view const&, std::string const&); // Image scaling functions scaling_method_e get_scaling_method_by_name (std::string name) { // TODO - make into proper ENUMS if (name == "fast" || name == "near") return SCALING_NEAR; else if (name == "bilinear") return SCALING_BILINEAR; else if (name == "cubic" || name == "bicubic") return SCALING_BICUBIC; else if (name == "spline16") return SCALING_SPLINE16; else if (name == "spline36") return SCALING_SPLINE36; else if (name == "hanning") return SCALING_HANNING; else if (name == "hamming") return SCALING_HAMMING; else if (name == "hermite") return SCALING_HERMITE; else if (name == "kaiser") return SCALING_KAISER; else if (name == "quadric") return SCALING_QUADRIC; else if (name == "catrom") return SCALING_CATROM; else if (name == "gaussian") return SCALING_GAUSSIAN; else if (name == "bessel") return SCALING_BESSEL; else if (name == "mitchell") return SCALING_MITCHELL; else if (name == "sinc") return SCALING_SINC; else if (name == "lanczos") return SCALING_LANCZOS; else if (name == "blackman") return SCALING_BLACKMAN; else return SCALING_NEAR; } // this has been replaced by agg impl - see https://trac.mapnik.org/ticket/656 /* inline void scale_image_bilinear (Image& target,const Image& source, double x_off_f=0, double y_off_f=0) { int source_width=source.width(); int source_height=source.height(); int target_width=target.width(); int target_height=target.height(); if (source_width<1 || source_height<1 || target_width<1 || target_height<1) return; int x=0,y=0,xs=0,ys=0; int tw2 = target_width/2; int th2 = target_height/2; int offs_x = rint((source_width-target_width-x_off_f*2*source_width)/2); int offs_y = rint((source_height-target_height-y_off_f*2*source_height)/2); unsigned yprt, yprt1, xprt, xprt1; //no scaling or subpixel offset if (target_height == source_height && target_width == source_width && offs_x == 0 && offs_y == 0){ for (y=0;y=source_height) ys1--; if (ys<0) ys=ys1=0; if (source_height/2=source_width) xs1--; if (xs<0) xs=xs1=0; unsigned a = source(xs,ys); unsigned b = source(xs1,ys); unsigned c = source(xs,ys1); unsigned d = source(xs1,ys1); unsigned out=0; unsigned t = 0; for(int i=0; i<4; i++){ unsigned p,r,s; // X axis p = a&0xff; r = b&0xff; if (p!=r) r = (r*xprt+p*xprt1+tw2)/target_width; p = c&0xff; s = d&0xff; if (p!=s) s = (s*xprt+p*xprt1+tw2)/target_width; // Y axis if (r!=s) r = (s*yprt+r*yprt1+th2)/target_height; // channel up out |= r << t; t += 8; a >>= 8; b >>= 8; c >>= 8; d >>= 8; } target(x,y)=out; } } } */ template void scale_image_bilinear8 (Image& target,const Image& source, double x_off_f, double y_off_f) { int source_width=source.width(); int source_height=source.height(); int target_width=target.width(); int target_height=target.height(); if (source_width<1 || source_height<1 || target_width<1 || target_height<1) return; int x=0,y=0,xs=0,ys=0; int tw2 = target_width/2; int th2 = target_height/2; int offs_x = rint((source_width-target_width-x_off_f*2*source_width)/2); int offs_y = rint((source_height-target_height-y_off_f*2*source_height)/2); unsigned yprt, yprt1, xprt, xprt1; //no scaling or subpixel offset if (target_height == source_height && target_width == source_width && offs_x == 0 && offs_y == 0){ for (y=0;y=source_height) ys1--; if (ys<0) ys=ys1=0; if (source_height/2=source_width) xs1--; if (xs<0) xs=xs1=0; unsigned a = source(xs,ys); unsigned b = source(xs1,ys); unsigned c = source(xs,ys1); unsigned d = source(xs1,ys1); unsigned p,r,s; // X axis p = a&0xff; r = b&0xff; if (p!=r) r = (r*xprt+p*xprt1+tw2)/target_width; p = c&0xff; s = d&0xff; if (p!=s) s = (s*xprt+p*xprt1+tw2)/target_width; // Y axis if (r!=s) r = (s*yprt+r*yprt1+th2)/target_height; target(x,y)=(0xff<<24) | (r<<16) | (r<<8) | r; } } } template void scale_image_agg (Image& target,const Image& source, scaling_method_e scaling_method, double scale_factor, double x_off_f, double y_off_f, double filter_radius) { typedef agg::pixfmt_rgba32 pixfmt; typedef agg::renderer_base renderer_base; // define some stuff we'll use soon agg::rasterizer_scanline_aa<> ras; agg::scanline_u8 sl; agg::span_allocator sa; agg::image_filter_lut filter; // initialize source AGG buffer agg::rendering_buffer rbuf_src((unsigned char*)source.getBytes(), source.width(), source.height(), source.width() * 4); pixfmt pixf_src(rbuf_src); typedef agg::image_accessor_clone img_src_type; img_src_type img_src(pixf_src); // initialise destination AGG buffer (with transparency) agg::rendering_buffer rbuf_dst((unsigned char*)target.getBytes(), target.width(), target.height(), target.width() * 4); pixfmt pixf_dst(rbuf_dst); renderer_base rb_dst(pixf_dst); rb_dst.clear(agg::rgba(0, 0, 0, 0)); // create a scaling matrix agg::trans_affine img_mtx; img_mtx /= agg::trans_affine_scaling(scale_factor, scale_factor); // create a linear interpolator for our scaling matrix typedef agg::span_interpolator_linear<> interpolator_type; interpolator_type interpolator(img_mtx); // draw an anticlockwise polygon to render our image into double scaled_width = source.width() * scale_factor; double scaled_height = source.height() * scale_factor; ras.reset(); ras.move_to_d(x_off_f, y_off_f); ras.line_to_d(x_off_f + scaled_width, y_off_f); ras.line_to_d(x_off_f + scaled_width, y_off_f + scaled_height); ras.line_to_d(x_off_f, y_off_f + scaled_height); switch(scaling_method) { case SCALING_NEAR: { typedef agg::span_image_filter_rgba_nn span_gen_type; span_gen_type sg(img_src, interpolator); agg::render_scanlines_aa(ras, sl, rb_dst, sa, sg); return; } case SCALING_BILINEAR: filter.calculate(agg::image_filter_bilinear(), true); break; case SCALING_BICUBIC: filter.calculate(agg::image_filter_bicubic(), true); break; case SCALING_SPLINE16: filter.calculate(agg::image_filter_spline16(), true); break; case SCALING_SPLINE36: filter.calculate(agg::image_filter_spline36(), true); break; case SCALING_HANNING: filter.calculate(agg::image_filter_hanning(), true); break; case SCALING_HAMMING: filter.calculate(agg::image_filter_hamming(), true); break; case SCALING_HERMITE: filter.calculate(agg::image_filter_hermite(), true); break; case SCALING_KAISER: filter.calculate(agg::image_filter_kaiser(), true); break; case SCALING_QUADRIC: filter.calculate(agg::image_filter_quadric(), true); break; case SCALING_CATROM: filter.calculate(agg::image_filter_catrom(), true); break; case SCALING_GAUSSIAN: filter.calculate(agg::image_filter_gaussian(), true); break; case SCALING_BESSEL: filter.calculate(agg::image_filter_bessel(), true); break; case SCALING_MITCHELL: filter.calculate(agg::image_filter_mitchell(), true); break; case SCALING_SINC: filter.calculate(agg::image_filter_sinc(filter_radius), true); break; case SCALING_LANCZOS: filter.calculate(agg::image_filter_lanczos(filter_radius), true); break; case SCALING_BLACKMAN: filter.calculate(agg::image_filter_blackman(filter_radius), true); break; } typedef agg::span_image_resample_rgba_affine span_gen_type; span_gen_type sg(img_src, interpolator, filter); agg::render_scanlines_aa(ras, sl, rb_dst, sa, sg); } template void scale_image_agg (image_data_32& target,const image_data_32& source, scaling_method_e scaling_method, double scale_factor, double x_off_f, double y_off_f, double filter_radius); template void scale_image_bilinear8 (image_data_32& target,const image_data_32& source, double x_off_f, double y_off_f); }