mapnik/src/feature_style_processor.cpp

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/*****************************************************************************
*
* 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
*
*****************************************************************************/
//mapnik
#include <mapnik/feature_style_processor.hpp>
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#include <mapnik/box2d.hpp>
#include <mapnik/datasource.hpp>
#include <mapnik/layer.hpp>
#include <mapnik/attribute_collector.hpp>
#include <mapnik/expression_evaluator.hpp>
#include <mapnik/utils.hpp>
#include <mapnik/scale_denominator.hpp>
#include <mapnik/agg_renderer.hpp>
#include <mapnik/grid/grid_renderer.hpp>
// boost
#include <boost/foreach.hpp>
#include <boost/concept_check.hpp>
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//stl
#include <vector>
#if defined(HAVE_CAIRO)
#include <mapnik/cairo_renderer.hpp>
#endif
#if defined(SVG_RENDERER)
#include <mapnik/svg_renderer.hpp>
#endif
#if defined(RENDERING_STATS)
#include <mapnik/timer.hpp>
#include <iomanip>
#include <sstream>
#endif
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namespace mapnik
{
template <typename T0,typename T1> struct has_process;
template <bool>
struct process_impl
{
template <typename T0, typename T1, typename T2, typename T3>
static void process(T0 & ren, T1 const& sym, T2 const& f, T3 const& tr)
{
ren.process(sym,f,tr);
}
};
template <> // No-op specialization
struct process_impl<false>
{
template <typename T0, typename T1, typename T2, typename T3>
static void process(T0 & ren, T1 const& sym, T2 const& f, T3 const& tr)
{
boost::ignore_unused_variable_warning(ren);
boost::ignore_unused_variable_warning(f);
boost::ignore_unused_variable_warning(tr);
#ifdef MAPNIK_DEBUG
std::clog << "NO-OP ...\n";
#endif
}
};
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/** Calls the renderer's process function,
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* \param output Renderer
* \param f Feature to process
* \param prj_trans Projection
* \param sym Symbolizer object
*/
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template <typename Processor>
struct feature_style_processor<Processor>::symbol_dispatch : public boost::static_visitor<>
{
symbol_dispatch (Processor & output,
mapnik::feature_ptr const& f,
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proj_transform const& prj_trans)
: output_(output),
f_(f),
prj_trans_(prj_trans) {}
template <typename T>
void operator () (T const& sym) const
{
process_impl<has_process<Processor,T>::value>::process(output_,sym,f_,prj_trans_);
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}
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Processor & output_;
mapnik::feature_ptr f_;
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proj_transform const& prj_trans_;
};
typedef char (&no_tag)[1];
typedef char (&yes_tag)[2];
template <typename T0, typename T1, void (T0::*)(T1 const&, mapnik::feature_ptr const&, proj_transform const&) >
struct process_memfun_helper {};
template <typename T0, typename T1> no_tag has_process_helper(...);
template <typename T0, typename T1> yes_tag has_process_helper(process_memfun_helper<T0, T1, &T0::process>* p);
template<typename T0,typename T1>
struct has_process
{
BOOST_STATIC_CONSTANT(bool
, value = sizeof(has_process_helper<T0,T1>(0)) == sizeof(yes_tag)
);
};
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template <typename Processor>
feature_style_processor<Processor>::feature_style_processor(Map const& m, double scale_factor)
: m_(m), scale_factor_(scale_factor)
{
}
template <typename Processor>
void feature_style_processor<Processor>::apply()
{
#if defined(RENDERING_STATS)
std::clog << "\n//-- starting rendering timer...\n";
mapnik::progress_timer t(std::clog, "total map rendering");
#endif
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Processor & p = static_cast<Processor&>(*this);
p.start_map_processing(m_);
try
{
projection proj(m_.srs());
start_metawriters(m_,proj);
double scale_denom = mapnik::scale_denominator(m_,proj.is_geographic());
scale_denom *= scale_factor_;
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BOOST_FOREACH ( layer const& lyr, m_.layers() )
{
if (lyr.visible(scale_denom))
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{
std::set<std::string> names;
apply_to_layer(lyr, p, proj, scale_denom, names);
}
}
stop_metawriters(m_);
}
catch (proj_init_error& ex)
{
std::clog << "proj_init_error:" << ex.what() << "\n";
}
p.end_map_processing(m_);
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#if defined(RENDERING_STATS)
t.stop();
std::clog << "//-- rendering timer stopped...\n\n";
#endif
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}
template <typename Processor>
void feature_style_processor<Processor>::apply(mapnik::layer const& lyr, std::set<std::string>& names)
{
Processor & p = static_cast<Processor&>(*this);
p.start_map_processing(m_);
try
{
projection proj(m_.srs());
double scale_denom = mapnik::scale_denominator(m_,proj.is_geographic());
scale_denom *= scale_factor_;
if (lyr.visible(scale_denom))
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{
apply_to_layer(lyr, p, proj, scale_denom, names);
}
}
catch (proj_init_error& ex)
{
std::clog << "proj_init_error:" << ex.what() << "\n";
}
p.end_map_processing(m_);
}
template <typename Processor>
void feature_style_processor<Processor>::start_metawriters(Map const& m_, projection const& proj)
{
Map::const_metawriter_iterator metaItr = m_.begin_metawriters();
Map::const_metawriter_iterator metaItrEnd = m_.end_metawriters();
for (;metaItr!=metaItrEnd; ++metaItr)
{
metaItr->second->set_size(m_.width(), m_.height());
metaItr->second->set_map_srs(proj);
metaItr->second->start(m_.metawriter_output_properties);
}
}
template <typename Processor>
void feature_style_processor<Processor>::stop_metawriters(Map const& m_)
{
Map::const_metawriter_iterator metaItr = m_.begin_metawriters();
Map::const_metawriter_iterator metaItrEnd = m_.end_metawriters();
for (;metaItr!=metaItrEnd; ++metaItr)
{
metaItr->second->stop();
}
}
template <typename Processor>
void feature_style_processor<Processor>::apply_to_layer(layer const& lay, Processor & p,
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projection const& proj0,
double scale_denom,
std::set<std::string>& names)
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{
std::vector<std::string> const& style_names = lay.styles();
unsigned int num_styles = style_names.size();
if (!num_styles) {
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std::clog << "WARNING: No style for layer '" << lay.name() << "'\n";
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return;
}
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mapnik::datasource_ptr ds = lay.datasource();
if (!ds)
{
std::clog << "WARNING: No datasource for layer '" << lay.name() << "'\n";
return;
}
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#if defined(RENDERING_STATS)
progress_timer layer_timer(std::clog, "rendering total for layer: '" + lay.name() + "'");
#endif
projection proj1(lay.srs());
proj_transform prj_trans(proj0,proj1);
#if defined(RENDERING_STATS)
if (!prj_trans.equal())
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std::clog << "notice: reprojecting layer: '" << lay.name() << "' from/to:\n\t'"
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<< lay.srs() << "'\n\t'"
<< m_.srs() << "'\n";
#endif
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box2d<double> map_ext = m_.get_buffered_extent();
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// clip buffered extent by maximum extent, if supplied
boost::optional<box2d<double> > const& maximum_extent = m_.maximum_extent();
if (maximum_extent) {
map_ext.clip(*maximum_extent);
}
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box2d<double> layer_ext = lay.envelope();
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// first, try intersection of map extent forward projected into layer srs
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if (prj_trans.forward(map_ext, PROJ_ENVELOPE_POINTS) && map_ext.intersects(layer_ext))
{
layer_ext.clip(map_ext);
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}
// if no intersection and projections are also equal, early return
else if (prj_trans.equal())
{
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#if defined(RENDERING_STATS)
layer_timer.discard();
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#endif
return;
}
// next try intersection of layer extent back projected into map srs
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else if (prj_trans.backward(layer_ext, PROJ_ENVELOPE_POINTS) && map_ext.intersects(layer_ext))
{
layer_ext.clip(map_ext);
// forward project layer extent back into native projection
if (!prj_trans.forward(layer_ext, PROJ_ENVELOPE_POINTS))
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{
std::clog << "WARNING: layer " << lay.name()
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<< " extent " << layer_ext << " in map projection "
<< " did not reproject properly back to layer projection\n";
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}
}
else
{
// if no intersection then nothing to do for layer
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#if defined(RENDERING_STATS)
layer_timer.discard();
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#endif
return;
}
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box2d<double> query_ext = m_.get_current_extent();
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prj_trans.forward(query_ext, PROJ_ENVELOPE_POINTS);
double qw = query_ext.width()>0 ? query_ext.width() : 1;
double qh = query_ext.height()>0 ? query_ext.height() : 1;
query::resolution_type res(m_.width()/qw,
m_.height()/qh);
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query q(layer_ext,res,scale_denom,m_.get_current_extent());
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p.start_layer_processing(lay, query_ext);
std::vector<feature_type_style*> active_styles;
attribute_collector collector(names);
double filt_factor = 1;
directive_collector d_collector(&filt_factor);
// iterate through all named styles collecting active styles and attribute names
BOOST_FOREACH(std::string const& style_name, style_names)
{
boost::optional<feature_type_style const&> style=m_.find_style(style_name);
if (!style)
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{
std::clog << "WARNING: style '" << style_name << "' required for layer '"
<< lay.name() << "' does not exist.\n";
continue;
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}
const std::vector<rule>& rules=(*style).get_rules();
bool active_rules=false;
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BOOST_FOREACH(rule const& r, rules)
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{
if (r.active(scale_denom))
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{
active_rules = true;
if (ds->type() == datasource::Vector)
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{
collector(r);
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}
// TODO - in the future rasters should be able to be filtered.
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}
}
if (active_rules)
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{
active_styles.push_back(const_cast<feature_type_style*>(&(*style)));
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}
}
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// Don't even try to do more work if there are no active styles.
if (active_styles.size() > 0)
{
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// push all property names
BOOST_FOREACH(std::string const& name, names)
{
q.add_property_name(name);
}
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// Update filter_factor for all enabled raster layers.
BOOST_FOREACH (feature_type_style * style, active_styles)
{
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BOOST_FOREACH(rule const& r, style->get_rules())
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{
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if (r.active(scale_denom) &&
ds->type() == datasource::Raster &&
ds->params().get<double>("filter_factor",0.0) == 0.0)
{
rule::symbolizers const& symbols = r.get_symbolizers();
rule::symbolizers::const_iterator symIter = symbols.begin();
rule::symbolizers::const_iterator symEnd = symbols.end();
while (symIter != symEnd)
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{
// if multiple raster symbolizers, last will be respected
// should we warn or throw?
boost::apply_visitor(d_collector,*symIter++);
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}
q.set_filter_factor(filt_factor);
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}
}
}
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// Also query the group by attribute
std::string group_by = lay.group_by();
if (group_by != "")
{
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q.add_property_name(group_by);
}
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bool cache_features = lay.cache_features() && active_styles.size() > 1;
// Render incrementally when the column that we group by
// changes value.
if (group_by != "")
{
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featureset_ptr features = ds->features(q);
if (features) {
// Cache all features into the memory_datasource before rendering.
memory_datasource cache;
feature_ptr feature, prev;
while ((feature = features->next()))
{
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if (prev && prev->get(group_by) != feature->get(group_by))
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{
// We're at a value boundary, so render what we have
// up to this point.
int i = 0;
BOOST_FOREACH (feature_type_style * style, active_styles)
{
render_style(lay, p, style, style_names[i++],
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cache.features(q), prj_trans, scale_denom);
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}
cache.clear();
}
cache.push(feature);
prev = feature;
}
int i = 0;
BOOST_FOREACH (feature_type_style * style, active_styles)
{
render_style(lay, p, style, style_names[i++],
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cache.features(q), prj_trans, scale_denom);
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}
}
}
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else if (cache_features)
{
featureset_ptr features = ds->features(q);
if (features) {
// Cache all features into the memory_datasource before rendering.
memory_datasource cache;
feature_ptr feature;
while ((feature = features->next()))
{
cache.push(feature);
}
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int i = 0;
BOOST_FOREACH (feature_type_style * style, active_styles)
{
render_style(lay, p, style, style_names[i++],
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cache.features(q), prj_trans, scale_denom);
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}
}
}
// We only have a single style and no grouping.
else
{
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int i = 0;
BOOST_FOREACH (feature_type_style * style, active_styles)
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{
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featureset_ptr features = ds->features(q);
if (features) {
render_style(lay, p, style, style_names[i++],
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features, prj_trans, scale_denom);
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}
}
}
}
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#if defined(RENDERING_STATS)
layer_timer.stop();
#endif
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p.end_layer_processing(lay);
}
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template <typename Processor>
void feature_style_processor<Processor>::render_style(
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layer const& lay,
Processor & p,
feature_type_style* style,
std::string const& style_name,
featureset_ptr features,
proj_transform const& prj_trans,
double scale_denom)
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{
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#if defined(RENDERING_STATS)
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std::ostringstream s1;
s1 << "rendering style for layer: '" << lay.name()
<< "' and style '" << style_name << "'";
mapnik::progress_timer style_timer(std::clog, s1.str());
int feature_processed_count = 0;
int feature_count = 0;
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#endif
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feature_ptr feature;
while ((feature = features->next()))
{
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#if defined(RENDERING_STATS)
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feature_count++;
bool feat_processed = false;
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#endif
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bool do_else = true;
bool do_also = false;
BOOST_FOREACH(rule * r, style->get_if_rules(scale_denom) )
{
expression_ptr const& expr=r->get_filter();
value_type result = boost::apply_visitor(evaluate<Feature,value_type>(*feature),*expr);
if (result.to_bool())
{
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#if defined(RENDERING_STATS)
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feat_processed = true;
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#endif
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p.painted(true);
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do_else=false;
do_also=true;
rule::symbolizers const& symbols = r->get_symbolizers();
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// if the underlying renderer is not able to process the complete set of symbolizers,
// process one by one.
if(!p.process(symbols,feature,prj_trans))
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{
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BOOST_FOREACH (symbolizer const& sym, symbols)
{
boost::apply_visitor(symbol_dispatch(p,feature,prj_trans),sym);
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}
}
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if (style->get_filter_mode() == FILTER_FIRST)
{
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// Stop iterating over rules and proceed with next feature.
break;
}
}
}
if (do_else)
{
BOOST_FOREACH( rule * r, style->get_else_rules(scale_denom) )
{
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#if defined(RENDERING_STATS)
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feat_processed = true;
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#endif
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p.painted(true);
rule::symbolizers const& symbols = r->get_symbolizers();
// if the underlying renderer is not able to process the complete set of symbolizers,
// process one by one.
if(!p.process(symbols,feature,prj_trans))
{
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BOOST_FOREACH (symbolizer const& sym, symbols)
{
boost::apply_visitor(symbol_dispatch(p,feature,prj_trans),sym);
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}
}
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}
}
if (do_also)
{
BOOST_FOREACH( rule * r, style->get_also_rules(scale_denom) )
{
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#if defined(RENDERING_STATS)
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feat_processed = true;
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#endif
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p.painted(true);
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rule::symbolizers const& symbols = r->get_symbolizers();
// if the underlying renderer is not able to process the complete set of symbolizers,
// process one by one.
if(!p.process(symbols,feature,prj_trans))
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{
BOOST_FOREACH (symbolizer const& sym, symbols)
{
boost::apply_visitor(symbol_dispatch(p,feature,prj_trans),sym);
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}
}
}
}
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#if defined(RENDERING_STATS)
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if (feat_processed)
feature_processed_count++;
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#endif
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}
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#if defined(RENDERING_STATS)
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style_timer.stop();
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// done with style
std::ostringstream s;
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if (feature_count > 0)
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{
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double perc_processed = ((double)feature_processed_count/(double)feature_count)*100.0;
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s << "percent rendered: " << perc_processed << "% - " << feature_processed_count
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<< " rendered for " << feature_count << " queried for ";
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s << std::setw(15 - (int)s.tellp()) << " layer '" << lay.name() << "' and style '" << style_name << "'\n";
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}
else
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{
s << "" << std::setw(15) << "- no features returned from query for layer '" << lay.name() << "' and style '" << style_name << "'\n";
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}
std::clog << s.str();
style_timer.discard();
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#endif
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}
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#if defined(HAVE_CAIRO)
template class feature_style_processor<cairo_renderer<Cairo::Context> >;
template class feature_style_processor<cairo_renderer<Cairo::Surface> >;
#endif
#if defined(SVG_RENDERER)
template class feature_style_processor<svg_renderer<std::ostream_iterator<char> > >;
#endif
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template class feature_style_processor<grid_renderer<grid> >;
template class feature_style_processor<agg_renderer<image_32> >;
}