mapagg.cpp

/******************************************************************************
 * $Id$
 *
 * Project:  MapServer
 * Purpose:  AGG rendering and other AGG related functions.
 * Author:   Thomas Bonfort and the MapServer team.
 *
 ******************************************************************************
 * Copyright (c) 1996-2007 Regents of the University of Minnesota.
 *
 * Permission is hereby granted, free of charge, to any person obtaining a
 * copy of this software and associated documentation files (the "Software"),
 * to deal in the Software without restriction, including without limitation
 * the rights to use, copy, modify, merge, publish, distribute, sublicense,
 * and/or sell copies of the Software, and to permit persons to whom the
 * Software is furnished to do so, subject to the following conditions:
 *
 * The above copyright notice and this permission notice shall be included in
 * all copies of this Software or works derived from this Software.
 *
 * THE SOFTWARE IS PROVIDED "AS IS", WITHOUT WARRANTY OF ANY KIND, EXPRESS
 * OR IMPLIED, INCLUDING BUT NOT LIMITED TO THE WARRANTIES OF MERCHANTABILITY,
 * FITNESS FOR A PARTICULAR PURPOSE AND NONINFRINGEMENT. IN NO EVENT SHALL
 * THE AUTHORS OR COPYRIGHT HOLDERS BE LIABLE FOR ANY CLAIM, DAMAGES OR OTHER
 * LIABILITY, WHETHER IN AN ACTION OF CONTRACT, TORT OR OTHERWISE, ARISING
 * FROM, OUT OF OR IN CONNECTION WITH THE SOFTWARE OR THE USE OR OTHER
 * DEALINGS IN THE SOFTWARE.
 *****************************************************************************/

#include "mapserver.h"
#include "fontcache.h"
#include "mapagg.h"
#include <assert.h>
#include "renderers/agg/include/agg_color_rgba.h"
#include "renderers/agg/include/agg_pixfmt_rgba.h"
#include "renderers/agg/include/agg_renderer_base.h"
#include "renderers/agg/include/agg_renderer_scanline.h"
#include "renderers/agg/include/agg_math_stroke.h"
#include "renderers/agg/include/agg_scanline_p.h"
#include "renderers/agg/include/agg_scanline_u.h"
#include "renderers/agg/include/agg_rasterizer_scanline_aa.h"
#include "renderers/agg/include/agg_span_pattern_rgba.h"
#include "renderers/agg/include/agg_span_allocator.h"
#include "renderers/agg/include/agg_span_interpolator_linear.h"
#include "renderers/agg/include/agg_span_image_filter_rgba.h"
#include "renderers/agg/include/agg_pattern_filters_rgba.h"
#include "renderers/agg/include/agg_span_image_filter_rgb.h"
#include "renderers/agg/include/agg_image_accessors.h"
#include "renderers/agg/include/agg_conv_stroke.h"
#include "renderers/agg/include/agg_conv_dash.h"
#include "renderers/agg/include/agg_font_freetype.h"
#include "renderers/agg/include/agg_conv_contour.h"
#include "renderers/agg/include/agg_ellipse.h"
#include "renderers/agg/include/agg_gamma_functions.h"

#include "renderers/agg/include/agg_rasterizer_outline_aa.h"
#include "renderers/agg/include/agg_renderer_outline_aa.h"
#include "renderers/agg/include/agg_renderer_outline_image.h"
#include "renderers/agg/include/agg_span_pattern_rgba.h"
#include "renderers/agg/include/agg_span_image_filter_rgba.h"
#include "renderers/agg/include/agg_glyph_raster_bin.h"
#include "renderers/agg/include/agg_renderer_raster_text.h"
#include "renderers/agg/include/agg_path_storage_integer.h"

#include "renderers/agg/include/agg_conv_clipper.h"

#ifdef AGG_ALIASED_ENABLED
#include "renderers/agg/include/agg_renderer_primitives.h"
#include "renderers/agg/include/agg_rasterizer_outline.h"
#endif

typedef mapserver::order_bgra band_order;

#define AGG_LINESPACE 1.33

typedef mapserver::int8u band_type;
typedef mapserver::rgba8 color_type;
typedef mapserver::pixel32_type pixel_type;

typedef mapserver::blender_rgba_pre<color_type, band_order> blender_pre;

typedef mapserver::pixfmt_alpha_blend_rgba<blender_pre, mapserver::rendering_buffer, pixel_type> pixel_format;
typedef mapserver::rendering_buffer rendering_buffer;
typedef mapserver::renderer_base<pixel_format> renderer_base;
typedef mapserver::renderer_scanline_aa_solid<renderer_base> renderer_scanline;
typedef mapserver::rasterizer_scanline_aa<> rasterizer_scanline;
typedef mapserver::font_engine_freetype_int16 font_engine_type;
typedef mapserver::font_cache_manager<font_engine_type> font_manager_type;
typedef mapserver::conv_curve<font_manager_type::path_adaptor_type> font_curve_type;
typedef mapserver::glyph_raster_bin<color_type> glyph_gen;

#ifdef AGG_ALIASED_ENABLED
typedef mapserver::renderer_primitives<renderer_base> renderer_primitives;
typedef mapserver::rasterizer_outline<renderer_primitives> rasterizer_outline;
#endif
static color_type AGG_NO_COLOR = color_type(0, 0, 0, 0);

#define aggColor(c) mapserver::rgba8_pre((c)->red, (c)->green, (c)->blue, (c)->alpha)

class aggRendererCache
{
public:
  font_engine_type m_feng;
  font_manager_type m_fman;
  aggRendererCache(): m_fman(m_feng) {}
};

class AGG2Renderer
{
public:

  AGG2Renderer()
#ifdef AGG_ALIASED_ENABLED
    :
    m_renderer_primitives(m_renderer_base),
    m_rasterizer_primitives(m_renderer_primitives)
#endif
  {
    stroke = NULL;
    dash = NULL;
    stroke_dash = NULL;
  }

  ~AGG2Renderer() {
    if(stroke) {
      delete stroke;
    }
    if(dash) {
      delete dash;
    }
    if(stroke_dash) {
      delete stroke_dash;
    }
  }

  band_type* buffer;
  rendering_buffer m_rendering_buffer;
  pixel_format m_pixel_format;
  renderer_base m_renderer_base;
  renderer_scanline m_renderer_scanline;
#ifdef AGG_ALIASED_ENABLED
  renderer_primitives m_renderer_primitives;
  rasterizer_outline m_rasterizer_primitives;
#endif
  rasterizer_scanline m_rasterizer_aa;
  rasterizer_scanline m_rasterizer_aa_gamma;
  mapserver::scanline_p8 sl_poly; /*packed scanlines, works faster when the area is larger
    than the perimeter, in number of pixels*/
  mapserver::scanline_u8 sl_line; /*unpacked scanlines, works faster if the area is roughly
    equal to the perimeter, in number of pixels*/
  bool use_alpha;
  mapserver::conv_stroke<line_adaptor> *stroke;
  mapserver::conv_dash<line_adaptor> *dash;
  mapserver::conv_stroke<mapserver::conv_dash<line_adaptor> > *stroke_dash;
  double default_gamma;
  mapserver::gamma_linear gamma_function;
};

#define AGG_RENDERER(image) ((AGG2Renderer*) (image)->img.plugin)

template<class VertexSource>
static void applyCJC(VertexSource &stroke, int caps, int joins)
{
  switch (joins) {
    case MS_CJC_ROUND:
      stroke.line_join(mapserver::round_join);
      break;
    case MS_CJC_MITER:
      stroke.line_join(mapserver::miter_join);
      break;
    case MS_CJC_BEVEL:
    case MS_CJC_NONE:
      stroke.line_join(mapserver::bevel_join);
      break;
  }
  switch (caps) {
    case MS_CJC_BUTT:
    case MS_CJC_NONE:
      stroke.line_cap(mapserver::butt_cap);
      break;
    case MS_CJC_ROUND:
      stroke.line_cap(mapserver::round_cap);
      break;
    case MS_CJC_SQUARE:
      stroke.line_cap(mapserver::square_cap);
      break;
  }
}

int agg2RenderLine(imageObj *img, shapeObj *p, strokeStyleObj *style)
{

  AGG2Renderer *r = AGG_RENDERER(img);
  line_adaptor lines = line_adaptor(p);

#ifdef AGG_ALIASED_ENABLED
  r->m_rasterizer_primitives.reset();
  r->m_renderer_primitives.line_color(aggColor(style->color));
  r->m_rasterizer_primitives.add_path(lines);
  return MS_SUCCESS;
#endif

  r->m_rasterizer_aa.reset();
  r->m_rasterizer_aa.filling_rule(mapserver::fill_non_zero);
  r->m_renderer_scanline.color(aggColor(style->color));

  if (style->patternlength <= 0) {
    if(!r->stroke) {
      r->stroke = new mapserver::conv_stroke<line_adaptor>(lines);
    } else {
      r->stroke->attach(lines);
    }
    r->stroke->width(style->width);
    if(style->width>1) {
      applyCJC(*r->stroke, style->linecap, style->linejoin);
    } else {
      r->stroke->inner_join(mapserver::inner_bevel);
      r->stroke->line_join(mapserver::bevel_join);
    }
    r->m_rasterizer_aa.add_path(*r->stroke);
  } else {
    if(!r->dash) {
      r->dash = new mapserver::conv_dash<line_adaptor>(lines);
    } else {
      r->dash->remove_all_dashes();
      r->dash->dash_start(0.0);
      r->dash->attach(lines);
    }
    if(!r->stroke_dash) {
      r->stroke_dash = new mapserver::conv_stroke<mapserver::conv_dash<line_adaptor> > (*r->dash);
    } else {
      r->stroke_dash->attach(*r->dash);
    }
    int patt_length = 0;
    for (int i = 0; i < style->patternlength; i += 2) {
      if (i < style->patternlength - 1) {
        r->dash->add_dash(MS_MAX(1,MS_NINT(style->pattern[i])),
                      MS_MAX(1,MS_NINT(style->pattern[i + 1])));
        if(style->patternoffset) {
          patt_length += MS_MAX(1,MS_NINT(style->pattern[i])) +
                         MS_MAX(1,MS_NINT(style->pattern[i + 1]));
        }
      }
    }
    if(style->patternoffset > 0) {
      r->dash->dash_start(patt_length - style->patternoffset);
    }
    r->stroke_dash->width(style->width);
    if(style->width>1) {
      applyCJC(*r->stroke_dash, style->linecap, style->linejoin);
    } else {
      r->stroke_dash->inner_join(mapserver::inner_bevel);
      r->stroke_dash->line_join(mapserver::bevel_join);
    }
    r->m_rasterizer_aa.add_path(*r->stroke_dash);
  }
  mapserver::render_scanlines(r->m_rasterizer_aa, r->sl_line, r->m_renderer_scanline);
  return MS_SUCCESS;
}

int agg2RenderLineTiled(imageObj *img, shapeObj *p, imageObj * tile)
{

  mapserver::pattern_filter_bilinear_rgba8 fltr;
  typedef mapserver::line_image_pattern<mapserver::pattern_filter_bilinear_rgba8> pattern_type;
  typedef mapserver::renderer_outline_image<renderer_base, pattern_type> renderer_img_type;
  typedef mapserver::rasterizer_outline_aa<renderer_img_type, mapserver::line_coord_sat> rasterizer_img_type;
  pattern_type patt(fltr);

  AGG2Renderer *r = AGG_RENDERER(img);
  AGG2Renderer *tileRenderer = AGG_RENDERER(tile);

  line_adaptor lines(p);

  patt.create(tileRenderer->m_pixel_format);
  renderer_img_type ren_img(r->m_renderer_base, patt);
  rasterizer_img_type ras_img(ren_img);
  ras_img.add_path(lines);
  return MS_SUCCESS;
}

int agg2RenderPolygon(imageObj *img, shapeObj *p, colorObj * color)
{
  AGG2Renderer *r = AGG_RENDERER(img);
  polygon_adaptor polygons(p);
  r->m_rasterizer_aa_gamma.reset();
  r->m_rasterizer_aa_gamma.filling_rule(mapserver::fill_even_odd);
  r->m_rasterizer_aa_gamma.add_path(polygons);
  r->m_renderer_scanline.color(aggColor(color));
  mapserver::render_scanlines(r->m_rasterizer_aa_gamma, r->sl_poly, r->m_renderer_scanline);
  return MS_SUCCESS;
}

static inline double int26p6_to_dbl(int p)
    {
        return double(p) / 64.0;
    }

template<class PathStorage>
    bool decompose_ft_outline(const FT_Outline& outline,
                              bool flip_y,
                              const mapserver::trans_affine& mtx,
                              PathStorage& path)
    {
        FT_Vector   v_last;
        FT_Vector   v_control;
        FT_Vector   v_start;
        double x1, y1, x2, y2, x3, y3;

        FT_Vector*  point;
        FT_Vector*  limit;
        char*       tags;

        int   n;         // index of contour in outline
        int   first;     // index of first point in contour
        char  tag;       // current point's state

        first = 0;

        for(n = 0; n < outline.n_contours; n++)
        {
            int  last;  // index of last point in contour

            last  = outline.contours[n];
            limit = outline.points + last;

            v_start = outline.points[first];
            v_last  = outline.points[last];

            v_control = v_start;

            point = outline.points + first;
            tags  = outline.tags  + first;
            tag   = FT_CURVE_TAG(tags[0]);

            // A contour cannot start with a cubic control point!
            if(tag == FT_CURVE_TAG_CUBIC) return false;

            // check first point to determine origin
            if( tag == FT_CURVE_TAG_CONIC)
            {
                // first point is conic control.  Yes, this happens.
                if(FT_CURVE_TAG(outline.tags[last]) == FT_CURVE_TAG_ON)
                {
                    // start at last point if it is on the curve
                    v_start = v_last;
                    limit--;
                }
                else
                {
                    // if both first and last points are conic,
                    // start at their middle and record its position
                    // for closure
                    v_start.x = (v_start.x + v_last.x) / 2;
                    v_start.y = (v_start.y + v_last.y) / 2;

                    v_last = v_start;
                }
                point--;
                tags--;
            }

            x1 = int26p6_to_dbl(v_start.x);
            y1 = int26p6_to_dbl(v_start.y);
            if(flip_y) y1 = -y1;
            mtx.transform(&x1, &y1);
            path.move_to(x1,y1);

            while(point < limit)
            {
                point++;
                tags++;

                tag = FT_CURVE_TAG(tags[0]);
                switch(tag)
                {
                    case FT_CURVE_TAG_ON:  // emit a single line_to
                    {
                        x1 = int26p6_to_dbl(point->x);
                        y1 = int26p6_to_dbl(point->y);
                        if(flip_y) y1 = -y1;
                        mtx.transform(&x1, &y1);
                        path.line_to(x1,y1);
                        //path.line_to(conv(point->x), flip_y ? -conv(point->y) : conv(point->y));
                        continue;
                    }

                    case FT_CURVE_TAG_CONIC:  // consume conic arcs
                    {
                        v_control.x = point->x;
                        v_control.y = point->y;

                    Do_Conic:
                        if(point < limit)
                        {
                            FT_Vector vec;
                            FT_Vector v_middle;

                            point++;
                            tags++;
                            tag = FT_CURVE_TAG(tags[0]);

                            vec.x = point->x;
                            vec.y = point->y;

                            if(tag == FT_CURVE_TAG_ON)
                            {
                                x1 = int26p6_to_dbl(v_control.x);
                                y1 = int26p6_to_dbl(v_control.y);
                                x2 = int26p6_to_dbl(vec.x);
                                y2 = int26p6_to_dbl(vec.y);
                                if(flip_y) { y1 = -y1; y2 = -y2; }
                                mtx.transform(&x1, &y1);
                                mtx.transform(&x2, &y2);
                                path.curve3(x1,y1,x2,y2);
                                continue;
                            }

                            if(tag != FT_CURVE_TAG_CONIC) return false;

                            v_middle.x = (v_control.x + vec.x) / 2;
                            v_middle.y = (v_control.y + vec.y) / 2;

                            x1 = int26p6_to_dbl(v_control.x);
                            y1 = int26p6_to_dbl(v_control.y);
                            x2 = int26p6_to_dbl(v_middle.x);
                            y2 = int26p6_to_dbl(v_middle.y);
                            if(flip_y) { y1 = -y1; y2 = -y2; }
                            mtx.transform(&x1, &y1);
                            mtx.transform(&x2, &y2);
                            path.curve3(x1,y1,x2,y2);

                            //path.curve3(conv(v_control.x),
                            //            flip_y ? -conv(v_control.y) : conv(v_control.y),
                            //            conv(v_middle.x),
                            //            flip_y ? -conv(v_middle.y) : conv(v_middle.y));

                            v_control = vec;
                            goto Do_Conic;
                        }

                        x1 = int26p6_to_dbl(v_control.x);
                        y1 = int26p6_to_dbl(v_control.y);
                        x2 = int26p6_to_dbl(v_start.x);
                        y2 = int26p6_to_dbl(v_start.y);
                        if(flip_y) { y1 = -y1; y2 = -y2; }
                        mtx.transform(&x1, &y1);
                        mtx.transform(&x2, &y2);
                        path.curve3(x1,y1,x2,y2);

                        //path.curve3(conv(v_control.x),
                        //            flip_y ? -conv(v_control.y) : conv(v_control.y),
                        //            conv(v_start.x),
                        //            flip_y ? -conv(v_start.y) : conv(v_start.y));
                        goto Close;
                    }

                    default:  // FT_CURVE_TAG_CUBIC
                    {
                        FT_Vector vec1, vec2;

                        if(point + 1 > limit || FT_CURVE_TAG(tags[1]) != FT_CURVE_TAG_CUBIC)
                        {
                            return false;
                        }

                        vec1.x = point[0].x;
                        vec1.y = point[0].y;
                        vec2.x = point[1].x;
                        vec2.y = point[1].y;

                        point += 2;
                        tags  += 2;

                        if(point <= limit)
                        {
                            FT_Vector vec;

                            vec.x = point->x;
                            vec.y = point->y;

                            x1 = int26p6_to_dbl(vec1.x);
                            y1 = int26p6_to_dbl(vec1.y);
                            x2 = int26p6_to_dbl(vec2.x);
                            y2 = int26p6_to_dbl(vec2.y);
                            x3 = int26p6_to_dbl(vec.x);
                            y3 = int26p6_to_dbl(vec.y);
                            if(flip_y) { y1 = -y1; y2 = -y2; y3 = -y3; }
                            mtx.transform(&x1, &y1);
                            mtx.transform(&x2, &y2);
                            mtx.transform(&x3, &y3);
                            path.curve4(x1,y1,x2,y2,x3,y3);

                            //path.curve4(conv(vec1.x),
                            //            flip_y ? -conv(vec1.y) : conv(vec1.y),
                            //            conv(vec2.x),
                            //            flip_y ? -conv(vec2.y) : conv(vec2.y),
                            //            conv(vec.x),
                            //            flip_y ? -conv(vec.y) : conv(vec.y));
                            continue;
                        }

                        x1 = int26p6_to_dbl(vec1.x);
                        y1 = int26p6_to_dbl(vec1.y);
                        x2 = int26p6_to_dbl(vec2.x);
                        y2 = int26p6_to_dbl(vec2.y);
                        x3 = int26p6_to_dbl(v_start.x);
                        y3 = int26p6_to_dbl(v_start.y);
                        if(flip_y) { y1 = -y1; y2 = -y2; y3 = -y3; }
                        mtx.transform(&x1, &y1);
                        mtx.transform(&x2, &y2);
                        mtx.transform(&x3, &y3);
                        path.curve4(x1,y1,x2,y2,x3,y3);

                        //path.curve4(conv(vec1.x),
                        //            flip_y ? -conv(vec1.y) : conv(vec1.y),
                        //            conv(vec2.x),
                        //            flip_y ? -conv(vec2.y) : conv(vec2.y),
                        //            conv(v_start.x),
                        //            flip_y ? -conv(v_start.y) : conv(v_start.y));
                        goto Close;
                    }
                }
            }

            path.close_polygon();

       Close:
            first = last + 1;
        }

        return true;
    }

int agg2RenderPolygonTiled(imageObj *img, shapeObj *p, imageObj * tile)
{
  assert(img->format->renderer == tile->format->renderer);

  AGG2Renderer *r = AGG_RENDERER(img);
  AGG2Renderer *tileRenderer = AGG_RENDERER(tile);
  polygon_adaptor polygons(p);
  typedef mapserver::wrap_mode_repeat wrap_type;
  typedef mapserver::image_accessor_wrap<pixel_format,wrap_type,wrap_type> img_source_type;
  typedef mapserver::span_pattern_rgba<img_source_type> span_gen_type;
  mapserver::span_allocator<mapserver::rgba8> sa;
  r->m_rasterizer_aa.reset();
  r->m_rasterizer_aa.filling_rule(mapserver::fill_even_odd);
  img_source_type img_src(tileRenderer->m_pixel_format);
  span_gen_type sg(img_src, 0, 0);
  r->m_rasterizer_aa.add_path(polygons);
  mapserver::render_scanlines_aa(r->m_rasterizer_aa, r->sl_poly, r->m_renderer_base, sa , sg);
  return MS_SUCCESS;
}

int agg2RenderGlyphsPath(imageObj *img, textPathObj *tp, colorObj *c, colorObj *oc, int ow) {
  mapserver::path_storage glyphs;
  mapserver::trans_affine trans;
  AGG2Renderer *r = AGG_RENDERER(img);
  r->m_rasterizer_aa.filling_rule(mapserver::fill_non_zero);
  for(int i=0; i<tp->numglyphs; i++) {
    glyphObj *gl  = tp->glyphs + i;
    trans.reset();
    trans.rotate(-gl->rot);
    trans.translate(gl->pnt.x, gl->pnt.y);
    outline_element *ol = msGetGlyphOutline(gl->face,gl->glyph);
    if(!ol) {
      return MS_FAILURE;
    }
    decompose_ft_outline(ol->outline,true,trans,glyphs);
  }
  mapserver::conv_curve<mapserver::path_storage> m_curves(glyphs);
  if (oc) {
    r->m_rasterizer_aa.reset();
    r->m_rasterizer_aa.filling_rule(mapserver::fill_non_zero);
    mapserver::conv_contour<mapserver::conv_curve<mapserver::path_storage> > cc(m_curves);
    cc.width(ow + 1);
    r->m_rasterizer_aa.add_path(cc);
    r->m_renderer_scanline.color(aggColor(oc));
    mapserver::render_scanlines(r->m_rasterizer_aa, r->sl_line, r->m_renderer_scanline);
  }
  if(c) {
    r->m_rasterizer_aa.reset();
    r->m_rasterizer_aa.filling_rule(mapserver::fill_non_zero);
    r->m_rasterizer_aa.add_path(m_curves);
    r->m_renderer_scanline.color(aggColor(c));
    mapserver::render_scanlines(r->m_rasterizer_aa, r->sl_line, r->m_renderer_scanline);
  }
  return MS_SUCCESS;
}

mapserver::path_storage imageVectorSymbol(symbolObj *symbol)
{
  mapserver::path_storage path;
  int is_new=1;

  for(int i=0; i < symbol->numpoints; i++) {
    if((symbol->points[i].x == -99) && (symbol->points[i].y == -99))
      is_new=1;

    else {
      if(is_new) {
        path.move_to(symbol->points[i].x,symbol->points[i].y);
        is_new=0;
      } else {
        path.line_to(symbol->points[i].x,symbol->points[i].y);
      }
    }
  }
  return path;
}

int agg2RenderVectorSymbol(imageObj *img, double x, double y,
                           symbolObj *symbol, symbolStyleObj * style)
{
  AGG2Renderer *r = AGG_RENDERER(img);
  double ox = symbol->sizex * 0.5;
  double oy = symbol->sizey * 0.5;

  mapserver::path_storage path = imageVectorSymbol(symbol);
  mapserver::trans_affine mtx;
  mtx *= mapserver::trans_affine_translation(-ox,-oy);
  mtx *= mapserver::trans_affine_scaling(style->scale);
  mtx *= mapserver::trans_affine_rotation(-style->rotation);
  mtx *= mapserver::trans_affine_translation(x, y);
  path.transform(mtx);
  if (style->color) {
    r->m_rasterizer_aa.reset();
    r->m_rasterizer_aa.filling_rule(mapserver::fill_even_odd);
    r->m_rasterizer_aa.add_path(path);
    r->m_renderer_scanline.color(aggColor(style->color));
    mapserver::render_scanlines(r->m_rasterizer_aa, r->sl_poly, r->m_renderer_scanline);
  }
  if(style->outlinecolor) {
    r->m_rasterizer_aa.reset();
    r->m_rasterizer_aa.filling_rule(mapserver::fill_non_zero);
    r->m_renderer_scanline.color(aggColor(style->outlinecolor));
    mapserver::conv_stroke<mapserver::path_storage> stroke(path);
    stroke.width(style->outlinewidth);
    r->m_rasterizer_aa.add_path(stroke);
    mapserver::render_scanlines(r->m_rasterizer_aa, r->sl_poly, r->m_renderer_scanline);
  }
  return MS_SUCCESS;
}

int agg2RenderPixmapSymbol(imageObj *img, double x, double y, symbolObj *symbol, symbolStyleObj * style)
{
  AGG2Renderer *r = AGG_RENDERER(img);
  rasterBufferObj *pixmap = symbol->pixmap_buffer;
  assert(pixmap->type == MS_BUFFER_BYTE_RGBA);
  rendering_buffer b(pixmap->data.rgba.pixels,pixmap->width,pixmap->height,pixmap->data.rgba.row_step);
  pixel_format pf(b);

  r->m_rasterizer_aa.reset();
  r->m_rasterizer_aa.filling_rule(mapserver::fill_non_zero);
  if ( (style->rotation != 0 && style->rotation != MS_PI*2.)|| style->scale != 1) {
    mapserver::trans_affine image_mtx;
    image_mtx *= mapserver::trans_affine_translation(-(pf.width()/2.),-(pf.height()/2.));
    /*agg angles are antitrigonometric*/
    image_mtx *= mapserver::trans_affine_rotation(-style->rotation);
    image_mtx *= mapserver::trans_affine_scaling(style->scale);



    image_mtx *= mapserver::trans_affine_translation(x,y);
    image_mtx.invert();
    typedef mapserver::span_interpolator_linear<> interpolator_type;
    interpolator_type interpolator(image_mtx);
    mapserver::span_allocator<color_type> sa;

    // "hardcoded" bilinear filter
    //------------------------------------------
    typedef mapserver::span_image_filter_rgba_bilinear_clip<pixel_format, interpolator_type> span_gen_type;
    span_gen_type sg(pf, mapserver::rgba(0,0,0,0), interpolator);
    mapserver::path_storage pixmap_bbox;
    int ims_2 = MS_NINT(MS_MAX(pixmap->width,pixmap->height)*style->scale*1.415)/2+1;

    pixmap_bbox.move_to(x-ims_2,y-ims_2);
    pixmap_bbox.line_to(x+ims_2,y-ims_2);
    pixmap_bbox.line_to(x+ims_2,y+ims_2);
    pixmap_bbox.line_to(x-ims_2,y+ims_2);

    r->m_rasterizer_aa.add_path(pixmap_bbox);
    mapserver::render_scanlines_aa(r->m_rasterizer_aa, r->sl_poly, r->m_renderer_base, sa, sg);
  } else {
    //just copy the image at the correct location (we place the pixmap on
    //the nearest integer pixel to avoid blurring)
    r->m_renderer_base.blend_from(pf,0,MS_NINT(x-pixmap->width/2.),MS_NINT(y-pixmap->height/2.));
  }
  return MS_SUCCESS;
}

int agg2RenderEllipseSymbol(imageObj *image, double x, double y,
                            symbolObj *symbol, symbolStyleObj * style)
{
  AGG2Renderer *r = AGG_RENDERER(image);
  mapserver::path_storage path;
  mapserver::ellipse ellipse(x,y,symbol->sizex*style->scale/2,symbol->sizey*style->scale/2);
  path.concat_path(ellipse);
  if( style->rotation != 0) {
    mapserver::trans_affine mtx;
    mtx *= mapserver::trans_affine_translation(-x,-y);
    /*agg angles are antitrigonometric*/
    mtx *= mapserver::trans_affine_rotation(-style->rotation);
    mtx *= mapserver::trans_affine_translation(x,y);
    path.transform(mtx);
  }

  if(style->color) {
    r->m_rasterizer_aa.reset();
    r->m_rasterizer_aa.filling_rule(mapserver::fill_even_odd);
    r->m_rasterizer_aa.add_path(path);
    r->m_renderer_scanline.color(aggColor(style->color));
    mapserver::render_scanlines(r->m_rasterizer_aa, r->sl_line, r->m_renderer_scanline);
  }
  if(style->outlinewidth) {
    r->m_rasterizer_aa.reset();
    r->m_rasterizer_aa.filling_rule(mapserver::fill_non_zero);
    mapserver::conv_stroke<mapserver::path_storage> stroke(path);
    stroke.width(style->outlinewidth);
    r->m_rasterizer_aa.add_path(stroke);
    r->m_renderer_scanline.color(aggColor(style->outlinecolor));
    mapserver::render_scanlines(r->m_rasterizer_aa, r->sl_poly, r->m_renderer_scanline);
  }
  return MS_SUCCESS;
}

int agg2RenderTile(imageObj *img, imageObj *tile, double x, double y)
{
  /*
  AGG2Renderer *imgRenderer = agg2GetRenderer(img);
  AGG2Renderer *tileRenderer = agg2GetRenderer(tile);
  */
  return MS_FAILURE;
}

int aggInitializeRasterBuffer(rasterBufferObj *rb, int width, int height, int mode)
{
  rb->type = MS_BUFFER_BYTE_RGBA;
  rb->data.rgba.pixel_step = 4;
  rb->data.rgba.row_step = rb->data.rgba.pixel_step * width;
  rb->width = width;
  rb->height = height;
  int nBytes = rb->data.rgba.row_step * height;
  rb->data.rgba.pixels = (band_type*)msSmallCalloc(nBytes,sizeof(band_type));
  rb->data.rgba.r = &(rb->data.rgba.pixels[band_order::R]);
  rb->data.rgba.g = &(rb->data.rgba.pixels[band_order::G]);
  rb->data.rgba.b = &(rb->data.rgba.pixels[band_order::B]);
  if(mode == MS_IMAGEMODE_RGBA) {
    rb->data.rgba.a = &(rb->data.rgba.pixels[band_order::A]);
  }
  return MS_SUCCESS;
}



int aggGetRasterBufferHandle(imageObj *img, rasterBufferObj * rb)
{
  AGG2Renderer *r = AGG_RENDERER(img);
  rb->type =MS_BUFFER_BYTE_RGBA;
  rb->data.rgba.pixels = r->buffer;
  rb->data.rgba.row_step = r->m_rendering_buffer.stride();
  rb->data.rgba.pixel_step = 4;
  rb->width = r->m_rendering_buffer.width();
  rb->height = r->m_rendering_buffer.height();
  rb->data.rgba.r = &(r->buffer[band_order::R]);
  rb->data.rgba.g = &(r->buffer[band_order::G]);
  rb->data.rgba.b = &(r->buffer[band_order::B]);
  if(r->use_alpha)
    rb->data.rgba.a = &(r->buffer[band_order::A]);
  else
    rb->data.rgba.a = NULL;
  return MS_SUCCESS;
}

int aggGetRasterBufferCopy(imageObj *img, rasterBufferObj *rb)
{
  AGG2Renderer *r = AGG_RENDERER(img);
  aggInitializeRasterBuffer(rb, img->width, img->height, MS_IMAGEMODE_RGBA);
  int nBytes = r->m_rendering_buffer.stride()*r->m_rendering_buffer.height();
  memcpy(rb->data.rgba.pixels,r->buffer, nBytes);
  return MS_SUCCESS;
}



int agg2MergeRasterBuffer(imageObj *dest, rasterBufferObj *overlay, double opacity, int srcX, int srcY,
                          int dstX, int dstY, int width, int height)
{
  assert(overlay->type == MS_BUFFER_BYTE_RGBA);
  rendering_buffer b(overlay->data.rgba.pixels, overlay->width, overlay->height, overlay->data.rgba.row_step);
  pixel_format pf(b);
  AGG2Renderer *r = AGG_RENDERER(dest);
  mapserver::rect_base<int> src_rect(srcX,srcY,srcX+width,srcY+height);
  r->m_renderer_base.blend_from(pf,&src_rect, dstX-srcX, dstY-srcY, unsigned(opacity * 255));
  return MS_SUCCESS;
}

/* image i/o */
imageObj *agg2CreateImage(int width, int height, outputFormatObj *format, colorObj * bg)
{
  imageObj *image = NULL;
  if (format->imagemode != MS_IMAGEMODE_RGB && format->imagemode != MS_IMAGEMODE_RGBA) {
    msSetError(MS_MISCERR,
               "AGG2 driver only supports RGB or RGBA pixel models.", "agg2CreateImage()");
    return image;
  }
  image = (imageObj *) calloc(1, sizeof (imageObj));
  MS_CHECK_ALLOC(image, sizeof (imageObj), NULL);
  AGG2Renderer *r = new AGG2Renderer();

  r->buffer = (band_type*)malloc(width * height * 4 * sizeof(band_type));
  if (r->buffer == NULL) {
    msSetError(MS_MEMERR, "%s: %d: Out of memory allocating %u bytes.\n", "agg2CreateImage()",
               __FILE__, __LINE__, (unsigned int)(width * height * 4 * sizeof(band_type)));
    free(image);
    return NULL;
  }
  r->m_rendering_buffer.attach(r->buffer, width, height, width * 4);
  r->m_pixel_format.attach(r->m_rendering_buffer);
  r->m_renderer_base.attach(r->m_pixel_format);
  r->m_renderer_scanline.attach(r->m_renderer_base);
  r->default_gamma = atof(msGetOutputFormatOption( format, "GAMMA", "0.75" ));
  if(r->default_gamma <= 0.0 || r->default_gamma >= 1.0) {
    r->default_gamma = 0.75;
  }
  r->gamma_function.set(0,r->default_gamma);
  r->m_rasterizer_aa_gamma.gamma(r->gamma_function);
  if( bg && !format->transparent )
    r->m_renderer_base.clear(aggColor(bg));
  else
    r->m_renderer_base.clear(AGG_NO_COLOR);

  if (!bg || format->transparent || format->imagemode == MS_IMAGEMODE_RGBA ) {
    r->use_alpha = true;
  } else {
    r->use_alpha = false;
  }
  image->img.plugin = (void*) r;

  return image;
}

int agg2SaveImage(imageObj *img, mapObj* map, FILE *fp, outputFormatObj * format)
{
  

  return MS_FAILURE;
}

int agg2StartNewLayer(imageObj *img, mapObj*map, layerObj *layer)
{
  AGG2Renderer *r = AGG_RENDERER(img);
  char *sgamma = msLayerGetProcessingKey( layer, "GAMMA" );
  double gamma;
  if(sgamma) {
    gamma = atof(sgamma);
    if(gamma <= 0 || gamma >= 1) gamma = 0.75;
  } else {
    gamma = r->default_gamma;
  }
  if(r->gamma_function.end() != gamma) {
    r->gamma_function.end(gamma);
    r->m_rasterizer_aa_gamma.gamma(r->gamma_function);
  }
  return MS_SUCCESS;
}

int agg2CloseNewLayer(imageObj *img, mapObj *map, layerObj *layer)
{
  return MS_SUCCESS;
}

int agg2FreeImage(imageObj * image)
{
  AGG2Renderer *r = AGG_RENDERER(image);
  free(r->buffer);
  delete r;
  image->img.plugin = NULL;
  return MS_SUCCESS;
}

int agg2FreeSymbol(symbolObj * symbol)
{
  return MS_SUCCESS;
}

int agg2InitCache(void **vcache)
{
  aggRendererCache *cache = new aggRendererCache();
  *vcache = (void*)cache;
  return MS_SUCCESS;
}

int agg2Cleanup(void *vcache)
{
  aggRendererCache *cache = (aggRendererCache*)vcache;
  delete cache;
  return MS_SUCCESS;
}


// ------------------------------------------------------------------------
// Function to create a custom hatch symbol based on an arbitrary angle.
// ------------------------------------------------------------------------
static mapserver::path_storage createHatch(double ox, double oy,
    double rx, double ry,
    int sx, int sy, double angle, double step)
{
  mapserver::path_storage path;
  //restrict the angle to [0 180[, i.e ]-pi/2,pi/2] in radians
  angle = fmod(angle, 360.0);
  if(angle < 0) angle += 360;
  if(angle >= 180) angle -= 180;

  //treat 2 easy cases which would cause divide by 0 in generic case
  if(angle==0) {
    double y0 = step-fmod(oy-ry,step);
    if((oy - ry) < 0) {
      y0 -= step;
    }
    for(double y=y0; y<sy; y+=step) {
      path.move_to(0,y);
      path.line_to(sx,y);
    }
    return path;
  }
  if(angle==90) {
    double x0 = step-fmod(ox-rx,step);
    if((ox - rx) < 0) {
      x0 -= step;
    }
    for(double x=x0; x<sx; x+=step) {
      path.move_to(x,0);
      path.line_to(x,sy);
    }
    return path;
  }


  double theta = (90-angle)*MS_DEG_TO_RAD; /* theta in ]-pi/2 , pi/2] */
  double ct = cos(theta);
  double st = sin(theta);
  double invct = 1.0/ct;
  double invst = 1.0/st;
  double r0; /* distance from first hatch line to the top-left (if angle in  0,pi/2)
                  or bottom-left (if angle in -pi/2,0) corner of the hatch bbox */
  double rmax = sqrt((double)(sx*sx+sy*sy)); /* distance to the furthest hatch we will have to create
TODO: this could be optimized for bounding boxes where width is very different than height for
certain hatch angles */
  double rref= rx*ct + ry*st; /* distance to the line passing through the refpoint, origin is
                                   (0,0) of the imageObj */
  double rcorner; /* distance to the line passing through the topleft or bottomleft corner
                       of the hatch bbox (origin is (0,0) of imageObj) */

  /* calculate the distance from the refpoint to the top right of the path */
  if(angle < 90) {
    rcorner = ox*ct + oy*st;
    r0 = step - fmod(rcorner-rref,step);
    if(rcorner-rref<0) r0 -= step;
  } else {
    rcorner = ox*ct + (oy+sy)*st;
    r0 = step - fmod(rcorner-rref,step);
    if(rcorner-rref<0) r0 -= step;
    st = -st;
    invst = -invst;
  }


  //parametrize each line as r = x.cos(theta) + y.sin(theta)
  for(double r=r0; r<rmax; r+=step) {
    int inter=0;
    double x,y;
    double pt[4]; //array to store the coordinates of intersection of the line with the sides
    //in the general case there will only be two intersections
    //so pt[4] should be sufficient to store the coordinates of the intersection,
    //but we allocate pt[8] to treat the special and rare/unfortunate case when the
    //line is a perfect diagonal (and therfore intersects all four sides)
    //note that the order for testing is important in this case so that the first
    //two intersection points actually correspond to the diagonal and not a degenerate line

    //test for intersection with each side

    y=r*invst;
    x=0; // test for intersection with left of image
    if(y>=0&&y<=sy) {
      pt[2*inter]=x;
      pt[2*inter+1]=y;
      inter++;
    }
    x=sx;
    y=(r-sx*ct)*invst;// test for intersection with right of image
    if(y>=0&&y<=sy) {
      pt[2*inter]=x;
      pt[2*inter+1]=y;
      inter++;
    }
    if(inter<2) {
      y=0;
      x=r*invct;// test for intersection with top of image
      if(x>=0&&x<=sx) {
        pt[2*inter]=x;
        pt[2*inter+1]=y;
        inter++;
      }
    }
    if(inter<2) {
      y=sy;
      x=(r-sy*st)*invct;// test for intersection with bottom of image
      if(x>=0&&x<=sx) {
        pt[2*inter]=x;
        pt[2*inter+1]=y;
        inter++;
      }
    }
    if(inter==2 && (pt[0]!=pt[2] || pt[1]!=pt[3])) {
      //the line intersects with two sides of the image, it should therefore be drawn
      if(angle<90) {
        path.move_to(pt[0],pt[1]);
        path.line_to(pt[2],pt[3]);
      } else {
        path.move_to(pt[0],sy-pt[1]);
        path.line_to(pt[2],sy-pt[3]);
      }
    }
  }
  return path;
}

template<class VertexSource> int renderPolygonHatches(imageObj *img,VertexSource &clipper, colorObj *color)
{
  if(img->format->renderer == MS_RENDER_WITH_AGG) {
    AGG2Renderer *r = AGG_RENDERER(img);
    r->m_rasterizer_aa_gamma.reset();
    r->m_rasterizer_aa_gamma.filling_rule(mapserver::fill_non_zero);
    r->m_rasterizer_aa_gamma.add_path(clipper);
    r->m_renderer_scanline.color(aggColor(color));
    mapserver::render_scanlines(r->m_rasterizer_aa_gamma, r->sl_poly, r->m_renderer_scanline);
  } else {
    shapeObj shape;
    msInitShape(&shape);
    int allocated = 20;
    lineObj line;
    shape.line = &line;
    shape.numlines = 1;
    shape.line[0].point = (pointObj*)msSmallCalloc(allocated,sizeof(pointObj));
    shape.line[0].numpoints = 0;
    double x=0,y=0;
    unsigned int cmd;
    clipper.rewind(0);
    while((cmd = clipper.vertex(&x,&y)) != mapserver::path_cmd_stop) {
      switch(cmd) {
        case mapserver::path_cmd_line_to:
          if(shape.line[0].numpoints == allocated) {
            allocated *= 2;
            shape.line[0].point = (pointObj*)msSmallRealloc(shape.line[0].point, allocated*sizeof(pointObj));
          }
          shape.line[0].point[shape.line[0].numpoints].x = x;
          shape.line[0].point[shape.line[0].numpoints].y = y;
          shape.line[0].numpoints++;
          break;
        case mapserver::path_cmd_move_to:
          shape.line[0].point[0].x = x;
          shape.line[0].point[0].y = y;
          shape.line[0].numpoints = 1;
          break;
        case mapserver::path_cmd_end_poly|mapserver::path_flags_close:
          if(shape.line[0].numpoints > 2) {
            if(UNLIKELY(MS_FAILURE == MS_IMAGE_RENDERER(img)->renderPolygon(img,&shape,color))) {
              free(shape.line[0].point);
              return MS_FAILURE;
            }
          }
          break;
        default:
          assert(0); //WTF?
      }
    }
    free(shape.line[0].point);
  }
  return MS_SUCCESS;
}

int msHatchPolygon(imageObj *img, shapeObj *poly, double spacing, double width, double *pattern, int patternlength, double angle, colorObj *color)
{
  assert(MS_RENDERER_PLUGIN(img->format));
  msComputeBounds(poly);

  /* amount we should expand the bounding box by */
  double exp = width * 0.7072;

  /* width and height of the bounding box we will be creating the hatch in */
  int pw=(int)(poly->bounds.maxx-poly->bounds.minx+exp*2)+1;
  int ph=(int)(poly->bounds.maxy-poly->bounds.miny+exp*2)+1;

  /* position of the top-left corner of the bounding box */
  double ox = poly->bounds.minx - exp;
  double oy = poly->bounds.miny - exp;

  //create a rectangular hatch of size pw,ph starting at 0,0
  //the created hatch is of the size of the shape's bounding box
  mapserver::path_storage hatch = createHatch(ox,oy,
                                  img->refpt.x,img->refpt.y,pw,ph,angle,spacing);
  if(hatch.total_vertices()<=0) return MS_SUCCESS;

  //translate the hatch so it overlaps the current shape
  hatch.transform(mapserver::trans_affine_translation(ox,oy));

  polygon_adaptor polygons(poly);



  if(patternlength>1) {
    //dash the hatch and render it clipped by the shape
    mapserver::conv_dash<mapserver::path_storage > dash(hatch);
    mapserver::conv_stroke<mapserver::conv_dash<mapserver::path_storage> > stroke(dash);
    for (int i=0; i<patternlength; i+=2) {
      if (i < patternlength-1) {
        dash.add_dash(pattern[i], pattern[i+1]);
      }
    }
    stroke.width(width);
    stroke.line_cap(mapserver::butt_cap);
    mapserver::conv_clipper<polygon_adaptor,mapserver::conv_stroke<mapserver::conv_dash<mapserver::path_storage> > > clipper(polygons,stroke, mapserver::clipper_and);
    renderPolygonHatches(img,clipper,color);
  } else {
    //render the hatch clipped by the shape
    mapserver::conv_stroke <mapserver::path_storage > stroke(hatch);
    stroke.width(width);
    stroke.line_cap(mapserver::butt_cap);
    mapserver::conv_clipper<polygon_adaptor,mapserver::conv_stroke<mapserver::path_storage> > clipper(polygons,stroke, mapserver::clipper_and);
    renderPolygonHatches(img,clipper,color);
  }


  //assert(prevCmd == mapserver::path_cmd_line_to);
  //delete lines;
  return MS_SUCCESS;
}


int msPopulateRendererVTableAGG(rendererVTableObj * renderer)
{
  renderer->supports_transparent_layers = 0;
  renderer->supports_pixel_buffer = 1;
  renderer->use_imagecache = 0;
  renderer->supports_clipping = 0;
  renderer->supports_svg = 0;
  renderer->default_transform_mode = MS_TRANSFORM_SIMPLIFY;
  agg2InitCache(&(MS_RENDERER_CACHE(renderer)));
  renderer->cleanup = agg2Cleanup;
  renderer->renderLine = &agg2RenderLine;

  renderer->renderPolygon = &agg2RenderPolygon;
  renderer->renderPolygonTiled = &agg2RenderPolygonTiled;
  renderer->renderLineTiled = &agg2RenderLineTiled;

  renderer->renderGlyphs = &agg2RenderGlyphsPath;

  renderer->renderVectorSymbol = &agg2RenderVectorSymbol;

  renderer->renderPixmapSymbol = &agg2RenderPixmapSymbol;

  renderer->renderEllipseSymbol = &agg2RenderEllipseSymbol;

  renderer->renderTile = &agg2RenderTile;

  renderer->getRasterBufferHandle = &aggGetRasterBufferHandle;
  renderer->getRasterBufferCopy = aggGetRasterBufferCopy;
  renderer->initializeRasterBuffer = aggInitializeRasterBuffer;

  renderer->mergeRasterBuffer = &agg2MergeRasterBuffer;
  renderer->loadImageFromFile = msLoadMSRasterBufferFromFile;
  renderer->createImage = &agg2CreateImage;
  renderer->saveImage = &agg2SaveImage;

  renderer->startLayer = &agg2StartNewLayer;
  renderer->endLayer = &agg2CloseNewLayer;

  renderer->freeImage = &agg2FreeImage;
  renderer->freeSymbol = &agg2FreeSymbol;
  renderer->cleanup = agg2Cleanup;

  return MS_SUCCESS;
}