/usr/include/mapnik/marker_helpers.hpp is in libmapnik-dev 2.2.0+ds1-7+b2.
This file is owned by root:root, with mode 0o644.
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*
* This file is part of Mapnik (c++ mapping toolkit)
*
* Copyright (C) 2012 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_MARKER_HELPERS_HPP
#define MAPNIK_MARKER_HELPERS_HPP
#include <mapnik/color.hpp>
#include <mapnik/feature.hpp>
#include <mapnik/geometry.hpp>
#include <mapnik/geom_util.hpp>
#include <mapnik/markers_symbolizer.hpp>
#include <mapnik/expression_evaluator.hpp>
#include <mapnik/svg/svg_path_attributes.hpp>
#include <mapnik/svg/svg_converter.hpp>
#include <mapnik/marker.hpp> // for svg_storage_type
#include <mapnik/svg/svg_storage.hpp>
#include <mapnik/markers_placement.hpp>
// agg
#include "agg_ellipse.h"
#include "agg_basics.h"
#include "agg_renderer_base.h"
#include "agg_renderer_scanline.h"
#include "agg_rendering_buffer.h"
#include "agg_scanline_u.h"
#include "agg_image_filters.h"
#include "agg_trans_bilinear.h"
#include "agg_span_allocator.h"
#include "agg_image_accessors.h"
#include "agg_pixfmt_rgba.h"
#include "agg_span_image_filter_rgba.h"
#include "agg_span_interpolator_linear.h"
// boost
#include <boost/optional.hpp>
#include <boost/variant/apply_visitor.hpp>
namespace mapnik {
template <typename BufferType, typename SvgRenderer, typename Rasterizer, typename Detector>
struct vector_markers_rasterizer_dispatch
{
typedef typename SvgRenderer::renderer_base renderer_base;
typedef typename renderer_base::pixfmt_type pixfmt_type;
vector_markers_rasterizer_dispatch(BufferType & render_buffer,
SvgRenderer & svg_renderer,
Rasterizer & ras,
box2d<double> const& bbox,
agg::trans_affine const& marker_trans,
markers_symbolizer const& sym,
Detector & detector,
double scale_factor,
bool snap_to_pixels)
: buf_(render_buffer),
pixf_(buf_),
renb_(pixf_),
svg_renderer_(svg_renderer),
ras_(ras),
bbox_(bbox),
marker_trans_(marker_trans),
sym_(sym),
detector_(detector),
scale_factor_(scale_factor),
snap_to_pixels_(snap_to_pixels)
{
pixf_.comp_op(static_cast<agg::comp_op_e>(sym_.comp_op()));
}
template <typename T>
void add_path(T & path)
{
marker_placement_e placement_method = sym_.get_marker_placement();
if (placement_method != MARKER_LINE_PLACEMENT ||
path.type() == Point)
{
double x = 0;
double y = 0;
if (path.type() == LineString)
{
if (!label::middle_point(path, x, y))
return;
}
else if (placement_method == MARKER_INTERIOR_PLACEMENT)
{
if (!label::interior_position(path, x, y))
return;
}
else
{
if (!label::centroid(path, x, y))
return;
}
agg::trans_affine matrix = marker_trans_;
matrix.translate(x,y);
if (snap_to_pixels_)
{
// https://github.com/mapnik/mapnik/issues/1316
matrix.tx = std::floor(matrix.tx+.5);
matrix.ty = std::floor(matrix.ty+.5);
}
// TODO https://github.com/mapnik/mapnik/issues/1754
box2d<double> transformed_bbox = bbox_ * matrix;
if (sym_.get_allow_overlap() ||
detector_.has_placement(transformed_bbox))
{
svg_renderer_.render(ras_, sl_, renb_, matrix, sym_.get_opacity(), bbox_);
if (!sym_.get_ignore_placement())
{
detector_.insert(transformed_bbox);
}
}
}
else
{
markers_placement<T, Detector> placement(path, bbox_, marker_trans_, detector_,
sym_.get_spacing() * scale_factor_,
sym_.get_max_error(),
sym_.get_allow_overlap());
double x = 0;
double y = 0;
double angle = 0;
while (placement.get_point(x, y, angle))
{
agg::trans_affine matrix = marker_trans_;
matrix.rotate(angle);
matrix.translate(x, y);
svg_renderer_.render(ras_, sl_, renb_, matrix, sym_.get_opacity(), bbox_);
}
}
}
private:
agg::scanline_u8 sl_;
BufferType & buf_;
pixfmt_type pixf_;
renderer_base renb_;
SvgRenderer & svg_renderer_;
Rasterizer & ras_;
box2d<double> const& bbox_;
agg::trans_affine const& marker_trans_;
markers_symbolizer const& sym_;
Detector & detector_;
double scale_factor_;
bool snap_to_pixels_;
};
template <typename BufferType, typename Rasterizer, typename Detector>
struct raster_markers_rasterizer_dispatch
{
typedef agg::rgba8 color_type;
typedef agg::order_rgba order_type;
typedef agg::pixel32_type pixel_type;
typedef agg::comp_op_adaptor_rgba_pre<color_type, order_type> blender_type; // comp blender
typedef agg::pixfmt_custom_blend_rgba<blender_type, BufferType> pixfmt_comp_type;
typedef agg::renderer_base<pixfmt_comp_type> renderer_base;
raster_markers_rasterizer_dispatch(BufferType & render_buffer,
Rasterizer & ras,
image_data_32 const& src,
agg::trans_affine const& marker_trans,
markers_symbolizer const& sym,
Detector & detector,
double scale_factor,
bool snap_to_pixels)
: buf_(render_buffer),
pixf_(buf_),
renb_(pixf_),
ras_(ras),
src_(src),
marker_trans_(marker_trans),
sym_(sym),
detector_(detector),
scale_factor_(scale_factor),
snap_to_pixels_(snap_to_pixels)
{
pixf_.comp_op(static_cast<agg::comp_op_e>(sym_.comp_op()));
}
template <typename T>
void add_path(T & path)
{
marker_placement_e placement_method = sym_.get_marker_placement();
box2d<double> bbox_(0,0, src_.width(),src_.height());
if (placement_method != MARKER_LINE_PLACEMENT ||
path.type() == Point)
{
double x = 0;
double y = 0;
if (path.type() == LineString)
{
if (!label::middle_point(path, x, y))
return;
}
else if (placement_method == MARKER_INTERIOR_PLACEMENT)
{
if (!label::interior_position(path, x, y))
return;
}
else
{
if (!label::centroid(path, x, y))
return;
}
agg::trans_affine matrix = marker_trans_;
matrix.translate(x,y);
box2d<double> transformed_bbox = bbox_ * matrix;
if (sym_.get_allow_overlap() ||
detector_.has_placement(transformed_bbox))
{
render_raster_marker(matrix, sym_.get_opacity());
if (!sym_.get_ignore_placement())
{
detector_.insert(transformed_bbox);
}
}
}
else
{
markers_placement<T, label_collision_detector4> placement(path, bbox_, marker_trans_, detector_,
sym_.get_spacing() * scale_factor_,
sym_.get_max_error(),
sym_.get_allow_overlap());
double x, y, angle;
while (placement.get_point(x, y, angle))
{
agg::trans_affine matrix = marker_trans_;
matrix.rotate(angle);
matrix.translate(x, y);
render_raster_marker(matrix, sym_.get_opacity());
}
}
}
void render_raster_marker(agg::trans_affine const& marker_tr,
double opacity)
{
typedef agg::pixfmt_rgba32_pre pixfmt_pre;
double width = src_.width();
double height = src_.height();
if (std::fabs(1.0 - scale_factor_) < 0.001
&& (std::fabs(1.0 - marker_tr.sx) < agg::affine_epsilon)
&& (std::fabs(0.0 - marker_tr.shy) < agg::affine_epsilon)
&& (std::fabs(0.0 - marker_tr.shx) < agg::affine_epsilon)
&& (std::fabs(1.0 - marker_tr.sy) < agg::affine_epsilon))
{
agg::rendering_buffer src_buffer((unsigned char *)src_.getBytes(),src_.width(),src_.height(),src_.width() * 4);
pixfmt_pre pixf_mask(src_buffer);
renb_.blend_from(pixf_mask,
0,
std::floor(marker_tr.tx + .5),
std::floor(marker_tr.ty + .5),
unsigned(255*sym_.get_opacity()));
}
else
{
typedef agg::image_accessor_clone<pixfmt_pre> img_accessor_type;
typedef agg::span_interpolator_linear<> interpolator_type;
//typedef agg::span_image_filter_rgba_2x2<img_accessor_type,interpolator_type> span_gen_type;
typedef agg::span_image_resample_rgba_affine<img_accessor_type> span_gen_type;
typedef agg::renderer_scanline_aa_alpha<renderer_base,
agg::span_allocator<color_type>,
span_gen_type> renderer_type;
double p[8];
p[0] = 0; p[1] = 0;
p[2] = width; p[3] = 0;
p[4] = width; p[5] = height;
p[6] = 0; p[7] = height;
marker_tr.transform(&p[0], &p[1]);
marker_tr.transform(&p[2], &p[3]);
marker_tr.transform(&p[4], &p[5]);
marker_tr.transform(&p[6], &p[7]);
agg::span_allocator<color_type> sa;
agg::image_filter_lut filter;
filter.calculate(agg::image_filter_bilinear(), true);
agg::rendering_buffer marker_buf((unsigned char *)src_.getBytes(),
src_.width(),
src_.height(),
src_.width()*4);
pixfmt_pre pixf(marker_buf);
img_accessor_type ia(pixf);
agg::trans_affine final_tr(p, 0, 0, width, height);
if (snap_to_pixels_)
{
final_tr.tx = std::floor(final_tr.tx+.5);
final_tr.ty = std::floor(final_tr.ty+.5);
}
interpolator_type interpolator(final_tr);
span_gen_type sg(ia, interpolator, filter);
renderer_type rp(renb_,sa, sg, unsigned(opacity*255));
ras_.move_to_d(p[0],p[1]);
ras_.line_to_d(p[2],p[3]);
ras_.line_to_d(p[4],p[5]);
ras_.line_to_d(p[6],p[7]);
agg::render_scanlines(ras_, sl_, rp);
}
}
private:
agg::scanline_u8 sl_;
BufferType & buf_;
pixfmt_comp_type pixf_;
renderer_base renb_;
Rasterizer & ras_;
image_data_32 const& src_;
agg::trans_affine const& marker_trans_;
markers_symbolizer const& sym_;
Detector & detector_;
double scale_factor_;
bool snap_to_pixels_;
};
template <typename T>
void build_ellipse(T const& sym, mapnik::feature_impl const& feature, svg_storage_type & marker_ellipse, svg::svg_path_adapter & svg_path)
{
expression_ptr const& width_expr = sym.get_width();
expression_ptr const& height_expr = sym.get_height();
double width = 0;
double height = 0;
if (width_expr && height_expr)
{
width = boost::apply_visitor(evaluate<feature_impl,value_type>(feature), *width_expr).to_double();
height = boost::apply_visitor(evaluate<feature_impl,value_type>(feature), *height_expr).to_double();
}
else if (width_expr)
{
width = boost::apply_visitor(evaluate<feature_impl,value_type>(feature), *width_expr).to_double();
height = width;
}
else if (height_expr)
{
height = boost::apply_visitor(evaluate<feature_impl,value_type>(feature), *height_expr).to_double();
width = height;
}
svg::svg_converter_type styled_svg(svg_path, marker_ellipse.attributes());
styled_svg.push_attr();
styled_svg.begin_path();
agg::ellipse c(0, 0, width/2.0, height/2.0);
styled_svg.storage().concat_path(c);
styled_svg.end_path();
styled_svg.pop_attr();
double lox,loy,hix,hiy;
styled_svg.bounding_rect(&lox, &loy, &hix, &hiy);
styled_svg.set_dimensions(width,height);
marker_ellipse.set_dimensions(width,height);
marker_ellipse.set_bounding_box(lox,loy,hix,hiy);
}
template <typename Attr>
bool push_explicit_style(Attr const& src, Attr & dst, markers_symbolizer const& sym)
{
boost::optional<stroke> const& strk = sym.get_stroke();
boost::optional<color> const& fill = sym.get_fill();
boost::optional<float> const& fill_opacity = sym.get_fill_opacity();
if (strk || fill || fill_opacity)
{
bool success = false;
for(unsigned i = 0; i < src.size(); ++i)
{
success = true;
dst.push_back(src[i]);
mapnik::svg::path_attributes & attr = dst.last();
if (attr.stroke_flag)
{
// TODO - stroke attributes need to be boost::optional
// for this to work properly
if (strk)
{
attr.stroke_width = strk->get_width();
color const& s_color = strk->get_color();
attr.stroke_color = agg::rgba(s_color.red()/255.0,
s_color.green()/255.0,
s_color.blue()/255.0,
s_color.alpha()/255.0);
attr.stroke_opacity = strk->get_opacity();
}
}
if (attr.fill_flag)
{
if (fill)
{
color const& f_color = *fill;
attr.fill_color = agg::rgba(f_color.red()/255.0,
f_color.green()/255.0,
f_color.blue()/255.0,
f_color.alpha()/255.0);
}
if (fill_opacity)
{
attr.fill_opacity = *fill_opacity;
}
}
}
return success;
}
return false;
}
template <typename T>
void setup_transform_scaling(agg::trans_affine & tr,
double svg_width,
double svg_height,
mapnik::feature_impl const& feature,
T const& sym)
{
double width = 0;
double height = 0;
expression_ptr const& width_expr = sym.get_width();
if (width_expr)
width = boost::apply_visitor(evaluate<feature_impl,value_type>(feature), *width_expr).to_double();
expression_ptr const& height_expr = sym.get_height();
if (height_expr)
height = boost::apply_visitor(evaluate<feature_impl,value_type>(feature), *height_expr).to_double();
if (width > 0 && height > 0)
{
double sx = width/svg_width;
double sy = height/svg_height;
tr *= agg::trans_affine_scaling(sx,sy);
}
else if (width > 0)
{
double sx = width/svg_width;
tr *= agg::trans_affine_scaling(sx);
}
else if (height > 0)
{
double sy = height/svg_height;
tr *= agg::trans_affine_scaling(sy);
}
}
// Apply markers to a feature with multiple geometries
template <typename Converter>
void apply_markers_multi(feature_impl & feature, Converter& converter, markers_symbolizer const& sym)
{
std::size_t geom_count = feature.paths().size();
if (geom_count == 1)
{
converter.apply(feature.paths()[0]);
}
else if (geom_count > 1)
{
marker_multi_policy_e multi_policy = sym.get_marker_multi_policy();
marker_placement_e placement = sym.get_marker_placement();
if (placement == MARKER_POINT_PLACEMENT &&
multi_policy == MARKER_WHOLE_MULTI)
{
double x, y;
if (label::centroid_geoms(feature.paths().begin(), feature.paths().end(), x, y))
{
geometry_type pt(Point);
pt.move_to(x, y);
// unset any clipping since we're now dealing with a point
converter.template unset<clip_poly_tag>();
converter.apply(pt);
}
}
else if ((placement == MARKER_POINT_PLACEMENT || placement == MARKER_INTERIOR_PLACEMENT) &&
multi_policy == MARKER_LARGEST_MULTI)
{
// Only apply to path with largest envelope area
// TODO: consider using true area for polygon types
double maxarea = 0;
geometry_type* largest = 0;
BOOST_FOREACH(geometry_type & geom, feature.paths())
{
const box2d<double>& env = geom.envelope();
double area = env.width() * env.height();
if (area > maxarea)
{
maxarea = area;
largest = &geom;
}
}
if (largest)
{
converter.apply(*largest);
}
}
else
{
if (multi_policy != MARKER_EACH_MULTI && placement != MARKER_POINT_PLACEMENT)
{
MAPNIK_LOG_WARN(marker_symbolizer) << "marker_multi_policy != 'each' has no effect with marker_placement != 'point'";
}
BOOST_FOREACH(geometry_type & path, feature.paths())
{
converter.apply(path);
}
}
}
}
}
#endif //MAPNIK_MARKER_HELPERS_HPP
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