mapnik/include/mapnik/png_io.hpp

/*****************************************************************************
 *
 * This file is part of Mapnik (c++ mapping toolkit)
 *
 * Copyright (C) 2011 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
 *
 *****************************************************************************/

#ifndef MAPNIK_PNG_IO_HPP
#define MAPNIK_PNG_IO_HPP

// mapnik
#include <mapnik/palette.hpp>
#include <mapnik/octree.hpp>
#include <mapnik/hextree.hpp>
#include <mapnik/miniz_png.hpp>
#include <mapnik/image_data.hpp>

// zlib
#include <zlib.h>  // for Z_DEFAULT_COMPRESSION

// boost


extern "C"
{
#include <png.h>
}

#define MAX_OCTREE_LEVELS 4

namespace mapnik {

struct png_options {
    int colors;
    int compression;
    int strategy;
    int trans_mode;
    double gamma;
    bool paletted;
    bool use_hextree;
    bool use_miniz;
    png_options() :
        colors(256),
        compression(Z_DEFAULT_COMPRESSION),
        strategy(Z_DEFAULT_STRATEGY),
        trans_mode(-1),
        gamma(-1),
        paletted(true),
        use_hextree(true),
        use_miniz(false) {}
};

template <typename T>
void write_data (png_structp png_ptr, png_bytep data, png_size_t length)
{
    T * out = static_cast<T*>(png_get_io_ptr(png_ptr));
    out->write(reinterpret_cast<char*>(data), length);
}

template <typename T>
void flush_data (png_structp png_ptr)
{
    T * out = static_cast<T*>(png_get_io_ptr(png_ptr));
    out->flush();
}

template <typename T1, typename T2>
void save_as_png(T1 & file,
                T2 const& image,
                png_options const& opts)

{
    if (opts.use_miniz)
    {
        MiniZ::PNGWriter writer(opts.compression,opts.strategy);
        if (opts.trans_mode == 0)
        {
            writer.writeIHDR(image.width(), image.height(), 24);
            writer.writeIDATStripAlpha(image);
        }
        else
        {
            writer.writeIHDR(image.width(), image.height(), 32);
            writer.writeIDAT(image);
        }
        writer.writeIEND();
        writer.toStream(file);
        return;
    }
    png_voidp error_ptr=0;
    png_structp png_ptr=png_create_write_struct(PNG_LIBPNG_VER_STRING,
                                                error_ptr,0, 0);

    if (!png_ptr) return;

    // switch on optimization only if supported
#if defined(PNG_LIBPNG_VER) && (PNG_LIBPNG_VER >= 10200) && defined(PNG_MMX_CODE_SUPPORTED)
    png_uint_32 mask, flags;
    flags = png_get_asm_flags(png_ptr);
    mask = png_get_asm_flagmask(PNG_SELECT_READ | PNG_SELECT_WRITE);
    png_set_asm_flags(png_ptr, flags | mask);
#endif
    png_set_filter(png_ptr, PNG_FILTER_TYPE_BASE, PNG_FILTER_NONE);
    png_infop info_ptr = png_create_info_struct(png_ptr);
    if (!info_ptr)
    {
        png_destroy_write_struct(&png_ptr,(png_infopp)0);
        return;
    }
    jmp_buf* jmp_context = (jmp_buf*) png_get_error_ptr(png_ptr);
    if (jmp_context)
    {
        png_destroy_write_struct(&png_ptr, &info_ptr);
        return;
    }
    png_set_write_fn (png_ptr, &file, &write_data<T1>, &flush_data<T1>);

    png_set_compression_level(png_ptr, opts.compression);
    png_set_compression_strategy(png_ptr, opts.strategy);
    png_set_compression_buffer_size(png_ptr, 32768);

    png_set_IHDR(png_ptr, info_ptr,image.width(),image.height(),8,
                 (opts.trans_mode == 0) ? PNG_COLOR_TYPE_RGB : PNG_COLOR_TYPE_RGB_ALPHA,PNG_INTERLACE_NONE,
                 PNG_COMPRESSION_TYPE_DEFAULT,PNG_FILTER_TYPE_DEFAULT);
    const std::unique_ptr<png_bytep[]> row_pointers(new png_bytep[image.height()]);
    for (unsigned int i = 0; i < image.height(); i++)
    {
        row_pointers[i] = (png_bytep)image.getRow(i);
    }
    png_set_rows(png_ptr, info_ptr, row_pointers.get());
    png_write_png(png_ptr, info_ptr, (opts.trans_mode == 0) ? PNG_TRANSFORM_STRIP_FILLER_AFTER : PNG_TRANSFORM_IDENTITY, nullptr);
    png_destroy_write_struct(&png_ptr, &info_ptr);
}

template <typename T>
void reduce_8(T const& in,
              image_data_8 & out,
              octree<rgb> trees[],
              unsigned limits[],
              unsigned levels,
              std::vector<unsigned> & alpha)
{
    unsigned width = in.width();
    unsigned height = in.height();

    std::vector<unsigned> alphaCount(alpha.size());
    for(unsigned i=0; i<alpha.size(); i++)
    {
        alpha[i] = 0;
        alphaCount[i] = 0;
    }
    for (unsigned y = 0; y < height; ++y)
    {
        mapnik::image_data_32::pixel_type const * row = in.getRow(y);
        mapnik::image_data_8::pixel_type  * row_out = out.getRow(y);
        for (unsigned x = 0; x < width; ++x)
        {
            unsigned val = row[x];
            byte index = 0;
            int idx = -1;
            for(int j=levels-1; j>0; j--)
            {
                if (U2ALPHA(val)>=limits[j] && trees[j].colors()>0)
                {
                    index = idx = trees[j].quantize(val);
                    break;
                }
            }
            if (idx>=0 && idx<(int)alpha.size())
            {
                alpha[idx]+=U2ALPHA(val);
                alphaCount[idx]++;
            }
            row_out[x] = index;
        }
    }
    for(unsigned i=0; i<alpha.size(); i++)
    {
        if (alphaCount[i]!=0)
        {
            alpha[i] /= alphaCount[i];
        }
    }
}

template <typename T>
void reduce_4(T const& in,
               image_data_8 & out,
               octree<rgb> trees[],
               unsigned limits[],
               unsigned levels,
               std::vector<unsigned> & alpha)
{
    unsigned width = in.width();
    unsigned height = in.height();

    std::vector<unsigned> alphaCount(alpha.size());
    for(unsigned i=0; i<alpha.size(); i++)
    {
        alpha[i] = 0;
        alphaCount[i] = 0;
    }
    for (unsigned y = 0; y < height; ++y)
    {
        mapnik::image_data_32::pixel_type const * row = in.getRow(y);
        mapnik::image_data_8::pixel_type  * row_out = out.getRow(y);
        for (unsigned x = 0; x < width; ++x)
        {
            unsigned val = row[x];
            byte index = 0;
            int idx=-1;
            for(int j=levels-1; j>0; j--)
            {
                if (U2ALPHA(val)>=limits[j] && trees[j].colors()>0)
                {
                    index = idx = trees[j].quantize(val);
                    break;
                }
            }
            if (idx>=0 && idx<(int)alpha.size())
            {
                alpha[idx]+=U2ALPHA(val);
                alphaCount[idx]++;
            }
            if (x%2 == 0)
            {
                index = index<<4;
            }
            row_out[x>>1] |= index;
        }
    }
    for(unsigned i=0; i<alpha.size(); i++)
    {
        if (alphaCount[i]!=0)
        {
            alpha[i] /= alphaCount[i];
        }
    }
}

// 1-bit but only one color.
template <typename T>
void reduce_1(T const&,
              image_data_8 & out,
              octree<rgb> /*trees*/[],
              unsigned /*limits*/[],
              std::vector<unsigned> & /*alpha*/)
{
    out.set(0); // only one color!!!
}

template <typename T>
void save_as_png(T & file, std::vector<mapnik::rgb> const& palette,
                 mapnik::image_data_8 const& image,
                 unsigned width,
                 unsigned height,
                 unsigned color_depth,
                 std::vector<unsigned> const&alpha,
                 png_options const& opts)
{
    if (opts.use_miniz)
    {
        MiniZ::PNGWriter writer(opts.compression,opts.strategy);
        // image.width()/height() does not reflect the actual image dimensions; it
        // refers to the quantized scanlines.
        writer.writeIHDR(width, height, color_depth);
        writer.writePLTE(palette);
        writer.writetRNS(alpha);
        writer.writeIDAT(image);
        writer.writeIEND();
        writer.toStream(file);
        return;
    }
    png_voidp error_ptr=0;
    png_structp png_ptr=png_create_write_struct(PNG_LIBPNG_VER_STRING,
                                                error_ptr,0, 0);

    if (!png_ptr)
    {
        return;
    }

    // switch on optimization only if supported
#if defined(PNG_LIBPNG_VER) && (PNG_LIBPNG_VER >= 10200) && defined(PNG_MMX_CODE_SUPPORTED)
    png_uint_32 mask, flags;
    flags = png_get_asm_flags(png_ptr);
    mask = png_get_asm_flagmask(PNG_SELECT_READ | PNG_SELECT_WRITE);
    png_set_asm_flags(png_ptr, flags | mask);
#endif
    png_set_filter(png_ptr, PNG_FILTER_TYPE_BASE, PNG_FILTER_NONE);
    png_infop info_ptr = png_create_info_struct(png_ptr);
    if (!info_ptr)
    {
        png_destroy_write_struct(&png_ptr,(png_infopp)0);
        return;
    }
    jmp_buf* jmp_context = (jmp_buf*) png_get_error_ptr(png_ptr);
    if (jmp_context)
    {
        png_destroy_write_struct(&png_ptr, &info_ptr);
        return;
    }
    png_set_write_fn (png_ptr, &file, &write_data<T>, &flush_data<T>);

    png_set_compression_level(png_ptr, opts.compression);
    png_set_compression_strategy(png_ptr, opts.strategy);
    png_set_compression_buffer_size(png_ptr, 32768);

    png_set_IHDR(png_ptr, info_ptr,width,height,color_depth,
                 PNG_COLOR_TYPE_PALETTE,PNG_INTERLACE_NONE,
                 PNG_COMPRESSION_TYPE_DEFAULT,PNG_FILTER_TYPE_DEFAULT);

    png_color* pal = const_cast<png_color*>(reinterpret_cast<const png_color*>(&palette[0]));
    png_set_PLTE(png_ptr, info_ptr, pal, static_cast<unsigned>(palette.size()));

    // make transparent lowest indexes, so tRNS is small
    if (alpha.size()>0)
    {
        std::vector<png_byte> trans(alpha.size());
        unsigned alphaSize=0;//truncate to nonopaque values
        for(unsigned i=0; i < alpha.size(); i++)
        {
            trans[i]=alpha[i];
            if (alpha[i]<255)
            {
                alphaSize = i+1;
            }
        }
        if (alphaSize>0)
        {
            png_set_tRNS(png_ptr, info_ptr, (png_bytep)&trans[0], alphaSize, 0);
        }
    }

    png_write_info(png_ptr, info_ptr);
    for (unsigned i=0;i<height;i++)
    {
        png_write_row(png_ptr,(png_bytep)image.getRow(i));
    }

    png_write_end(png_ptr, info_ptr);
    png_destroy_write_struct(&png_ptr, &info_ptr);
}

template <typename T1,typename T2>
void save_as_png8_oct(T1 & file,
                      T2 const& image,
                      png_options const& opts)
{
    // number of alpha ranges in png8 format; 2 results in smallest image with binary transparency
    // 3 is minimum for semitransparency, 4 is recommended, anything else is worse
    const unsigned TRANSPARENCY_LEVELS = (opts.trans_mode==2||opts.trans_mode<0)?MAX_OCTREE_LEVELS:2;
    unsigned width = image.width();
    unsigned height = image.height();
    unsigned alphaHist[256];//transparency histogram
    unsigned semiCount = 0;//sum of semitransparent pixels
    unsigned meanAlpha = 0;

    if (opts.trans_mode == 0)
    {
        meanAlpha = 255;
    }
    else
    {
        for(int i=0; i<256; i++)
        {
            alphaHist[i] = 0;
        }
        for (unsigned y = 0; y < height; ++y)
        {
            for (unsigned x = 0; x < width; ++x)
            {
                unsigned val = U2ALPHA((unsigned)image.getRow(y)[x]);
                alphaHist[val]++;
                meanAlpha += val;
                if (val>0 && val<255)
                {
                    semiCount++;
                }
            }
        }
        meanAlpha /= width*height;
    }

    // transparency ranges division points
    unsigned limits[MAX_OCTREE_LEVELS+1];
    limits[0] = 0;
    limits[1] = (opts.trans_mode!=0 && alphaHist[0]>0)?1:0;
    limits[TRANSPARENCY_LEVELS] = 256;
    for(unsigned j=2; j<TRANSPARENCY_LEVELS; j++)
    {
        limits[j] = limits[1];
    }
    if (opts.trans_mode != 0)
    {
        unsigned alphaHistSum = 0;
        for(unsigned i=1; i<256; i++)
        {
            alphaHistSum += alphaHist[i];
            for(unsigned j=1; j<TRANSPARENCY_LEVELS; j++)
            {
                if (alphaHistSum<semiCount*(j)/4)
                {
                    limits[j] = i;
                }
            }
        }
    }
    // avoid too wide full transparent range
    if (limits[1]>256/(TRANSPARENCY_LEVELS-1))
    {
        limits[1]=256/(TRANSPARENCY_LEVELS-1);
    }
    // avoid too wide full opaque range
    if (limits[TRANSPARENCY_LEVELS-1]<212)
    {
        limits[TRANSPARENCY_LEVELS-1]=212;
    }
    if (TRANSPARENCY_LEVELS==2)
    {
        limits[1]=127;
    }
    // estimated number of colors from palette assigned to chosen ranges
    unsigned cols[MAX_OCTREE_LEVELS];
    // count colors
    if (opts.trans_mode == 0)
    {
        for (unsigned j=0; j<TRANSPARENCY_LEVELS; j++)
        {
            cols[j] = 0;
        }
        cols[TRANSPARENCY_LEVELS-1] = width * height;
    }
    else
    {
        for (unsigned j=0; j<TRANSPARENCY_LEVELS; j++)
        {
            cols[j] = 0;
            for (unsigned i=limits[j]; i<limits[j+1]; i++)
            {
                cols[j] += alphaHist[i];
            }
        }
    }

    unsigned divCoef = width*height-cols[0];
    if (divCoef==0)
    {
        divCoef = 1;
    }
    cols[0] = cols[0]>0?1:0; // fully transparent color (one or not at all)

    if (opts.colors>=64)
    {
        // give chance less populated but not empty cols to have at least few colors(12)
        unsigned minCols = (12+1)*divCoef/(opts.colors-cols[0]);
        for(unsigned j=1; j<TRANSPARENCY_LEVELS; j++)
        {
            if (cols[j]>12 && cols[j]<minCols)
            {
                divCoef += minCols-cols[j];
                cols[j] = minCols;
            }
        }
    }
    unsigned usedColors = cols[0];
    for(unsigned j=1; j<TRANSPARENCY_LEVELS-1; j++)
    {
        cols[j] = cols[j]*(opts.colors-cols[0])/divCoef;
        usedColors += cols[j];
    }
    // use rest for most opaque group of pixels
    cols[TRANSPARENCY_LEVELS-1] = opts.colors-usedColors;

    //no transparency
    if (opts.trans_mode == 0)
    {
        limits[1] = 0;
        cols[0] = 0;
        cols[1] = opts.colors;
    }

    // octree table for separate alpha range with 1-based index (0 is fully transparent: no color)
    octree<rgb> trees[MAX_OCTREE_LEVELS];
    for(unsigned j=1; j<TRANSPARENCY_LEVELS; j++)
    {
        trees[j].setMaxColors(cols[j]);
    }
    for (unsigned y = 0; y < height; ++y)
    {
        typename T2::pixel_type const * row = image.getRow(y);
        for (unsigned x = 0; x < width; ++x)
        {
            unsigned val = row[x];
            // insert to proper tree based on alpha range
            for(unsigned j=TRANSPARENCY_LEVELS-1; j>0; j--)
            {
                if (cols[j]>0 && U2ALPHA(val)>=limits[j])
                {
                    trees[j].insert(mapnik::rgb(U2RED(val), U2GREEN(val), U2BLUE(val)));
                    break;
                }
            }
        }
    }
    unsigned leftovers = 0;
    std::vector<rgb> palette;
    palette.reserve(opts.colors);
    if (cols[0])
    {
        palette.push_back(rgb(0,0,0));
    }

    for(unsigned j=1; j<TRANSPARENCY_LEVELS; j++)
    {
        if (cols[j]>0)
        {
            if (leftovers>0)
            {
                cols[j] += leftovers;
                trees[j].setMaxColors(cols[j]);
                leftovers = 0;
            }
            std::vector<rgb> pal;
            trees[j].setOffset( static_cast<unsigned>(palette.size()));
            trees[j].create_palette(pal);
            leftovers = cols[j] - static_cast<unsigned>(pal.size());
            cols[j] = static_cast<unsigned>(pal.size());
            palette.insert(palette.begin(), pal.begin(), pal.end());
        }
    }

    //transparency values per palette index
    std::vector<unsigned> alphaTable;
    //alphaTable.resize(palette.size());//allow semitransparency also in almost opaque range
    if (opts.trans_mode != 0)
    {
        alphaTable.resize(palette.size() - cols[TRANSPARENCY_LEVELS-1]);
    }

    if (palette.size() > 16 )
    {
        // >16 && <=256 colors -> write 8-bit color depth
        image_data_8 reduced_image(width,height);
        reduce_8(image, reduced_image, trees, limits, TRANSPARENCY_LEVELS, alphaTable);
        save_as_png(file,palette,reduced_image,width,height,8,alphaTable,opts);
    }
    else if (palette.size() == 1)
    {
        // 1 color image ->  write 1-bit color depth PNG
        unsigned image_width  = ((width + 15) >> 3) & ~1U; // 1-bit image, round up to 16-bit boundary
        unsigned image_height = height;
        image_data_8 reduced_image(image_width,image_height);
        reduce_1(image,reduced_image,trees, limits, alphaTable);
        if (meanAlpha<255 && cols[0]==0)
        {
            alphaTable.resize(1);
            alphaTable[0] = meanAlpha;
        }
        save_as_png(file,palette,reduced_image,width,height,1,alphaTable,opts);
    }
    else
    {
        // <=16 colors -> write 4-bit color depth PNG
        unsigned image_width  = ((width + 7) >> 1) & ~3U; // 4-bit image, round up to 32-bit boundary
        unsigned image_height = height;
        image_data_8 reduced_image(image_width,image_height);
        reduce_4(image, reduced_image, trees, limits, TRANSPARENCY_LEVELS, alphaTable);
        save_as_png(file,palette,reduced_image,width,height,4,alphaTable,opts);
    }
}


template <typename T1, typename T2, typename T3>
void save_as_png8(T1 & file,
                  T2 const& image,
                  T3 const & tree,
                  std::vector<mapnik::rgb> const& palette,
                  std::vector<unsigned> const& alphaTable,
                  png_options const& opts)
{
    unsigned width = image.width();
    unsigned height = image.height();

    if (palette.size() > 16 )
    {
        // >16 && <=256 colors -> write 8-bit color depth
        image_data_8 reduced_image(width, height);
        for (unsigned y = 0; y < height; ++y)
        {
            mapnik::image_data_32::pixel_type const * row = image.getRow(y);
            mapnik::image_data_8::pixel_type  * row_out = reduced_image.getRow(y);
            for (unsigned x = 0; x < width; ++x)
            {
                row_out[x] = tree.quantize(row[x]);
            }
        }
        save_as_png(file, palette, reduced_image, width, height, 8, alphaTable, opts);
    }
    else if (palette.size() == 1)
    {
        // 1 color image ->  write 1-bit color depth PNG
        unsigned image_width  = ((width + 15) >> 3) & ~1U; // 1-bit image, round up to 16-bit boundary
        unsigned image_height = height;
        image_data_8 reduced_image(image_width, image_height);
        reduced_image.set(0);
        save_as_png(file, palette, reduced_image, width, height, 1, alphaTable, opts);
    }
    else
    {
        // <=16 colors -> write 4-bit color depth PNG
        unsigned image_width  = ((width + 7) >> 1) & ~3U; // 4-bit image, round up to 32-bit boundary
        unsigned image_height = height;
        image_data_8 reduced_image(image_width, image_height);
        for (unsigned y = 0; y < height; ++y)
        {
            mapnik::image_data_32::pixel_type const * row = image.getRow(y);
            mapnik::image_data_8::pixel_type  * row_out = reduced_image.getRow(y);
            byte index = 0;
            for (unsigned x = 0; x < width; ++x)
            {

                index = tree.quantize(row[x]);
                if (x%2 == 0)
                {
                    index = index<<4;
                }
                row_out[x>>1] |= index;
            }
        }
        save_as_png(file, palette, reduced_image, width, height, 4, alphaTable, opts);
    }
}

template <typename T1,typename T2>
void save_as_png8_hex(T1 & file,
                      T2 const& image,
                      png_options const& opts)
{
    unsigned width = image.width();
    unsigned height = image.height();
    if (width + height > 3) // at least 3 pixels (hextree implementation requirement)
    {
        // structure for color quantization
        hextree<mapnik::rgba> tree(opts.colors);
        if (opts.trans_mode >= 0)
        {
            tree.setTransMode(opts.trans_mode);
        }
        if (opts.gamma > 0)
        {
            tree.setGamma(opts.gamma);
        }

        for (unsigned y = 0; y < height; ++y)
        {
            typename T2::pixel_type const * row = image.getRow(y);
            for (unsigned x = 0; x < width; ++x)
            {
                unsigned val = row[x];
                tree.insert(mapnik::rgba(U2RED(val), U2GREEN(val), U2BLUE(val), U2ALPHA(val)));
            }
        }

        //transparency values per palette index
        std::vector<mapnik::rgba> pal;
        tree.create_palette(pal);
        std::vector<mapnik::rgb> palette;
        std::vector<unsigned> alphaTable;
        for (unsigned i=0; i<pal.size(); ++i)
        {
            palette.push_back(rgb(pal[i].r, pal[i].g, pal[i].b));
            alphaTable.push_back(pal[i].a);
        }
        save_as_png8<T1, T2, hextree<mapnik::rgba> >(file, image, tree, palette, alphaTable, opts);
    }
    else
    {
        throw std::runtime_error("Can't quantize images with less than 3 pixels");
    }
}

template <typename T1, typename T2>
void save_as_png8_pal(T1 & file,
                      T2 const& image,
                      rgba_palette const& pal,
                      png_options const& opts)
{
    save_as_png8<T1, T2, rgba_palette>(file, image, pal, pal.palette(), pal.alphaTable(), opts);
}

}

#endif // MAPNIK_PNG_IO_HPP