/***************************************************************************** * * This file is part of Mapnik (c++ mapping toolkit) * * Copyright (C) 2021 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 RASTER_FEATURESET_HPP #define RASTER_FEATURESET_HPP #include "raster_datasource.hpp" #include "raster_info.hpp" // mapnik #include #include // stl #include // boost #include class single_file_policy { raster_info info_; public: class const_iterator { enum iterator_e {start,end}; bool status_; const single_file_policy* p_; public: explicit const_iterator(const single_file_policy* p) : status_(start), p_(p) {} const_iterator() : status_(end) {} const_iterator(const const_iterator& other) : status_(other.status_), p_(other.p_) {} const_iterator& operator++() { status_ = end; return *this; } const raster_info& operator*() const { return p_->info_; } const raster_info* operator->() const { return &(p_->info_); } bool operator!=(const const_iterator& itr) { return status_ != itr.status_; } }; explicit single_file_policy(const raster_info& info) : info_(info) {} const_iterator begin() { return const_iterator(this); } const_iterator query(const box2d& box) { if (box.intersects(info_.envelope())) { return begin(); } return end(); } const_iterator end() { return const_iterator(); } inline int img_width(int reader_width) const { return reader_width; } inline int img_height(int reader_height) const { return reader_height; } inline box2d transform(box2d &) const { return box2d(0, 0, 0, 0); } }; class tiled_file_policy { public: using const_iterator = std::vector::const_iterator; tiled_file_policy(std::string const& file, std::string const& format, unsigned tile_size, box2d const& extent, box2d const& bbox, unsigned width, unsigned height) { double lox = extent.minx(); double loy = extent.miny(); int max_x = int(std::ceil(double(width) / double(tile_size))); int max_y = int(std::ceil(double(height) / double(tile_size))); double pixel_x = extent.width() / double(width); double pixel_y = extent.height() / double(height); MAPNIK_LOG_DEBUG(raster) << "tiled_file_policy: Raster Plugin PIXEL SIZE("<< pixel_x << "," << pixel_y << ")"; box2d e = bbox.intersect(extent); for (int x = 0; x < max_x; ++x) { for (int y = 0; y < max_y; ++y) { double x0 = lox + x * tile_size * pixel_x; double y0 = loy + y * tile_size * pixel_y; double x1 = x0 + tile_size * pixel_x; double y1 = y0 + tile_size * pixel_y; if (e.intersects(box2d(x0, y0, x1, y1))) { box2d tile_box = e.intersect(box2d(x0,y0,x1,y1)); raster_info info(file,format,tile_box,tile_size,tile_size); infos_.push_back(info); } } } MAPNIK_LOG_DEBUG(raster) << "tiled_file_policy: Raster Plugin INFO SIZE=" << infos_.size() << " " << file; } const_iterator begin() { return infos_.begin(); } const_iterator end() { return infos_.end(); } inline int img_width(int reader_width) const { return reader_width; } inline int img_height(int reader_height) const { return reader_height; } inline box2d transform(box2d&) const { return box2d(0, 0, 0, 0); } private: std::vector infos_; }; class tiled_multi_file_policy { public: using const_iterator = std::vector::const_iterator; tiled_multi_file_policy(std::string const& file_pattern, std::string const& format, unsigned tile_size, box2d extent, box2d bbox, unsigned width, unsigned height, unsigned tile_stride) : image_width_(width), image_height_(height), tile_size_(tile_size), tile_stride_(tile_stride) { double lox = extent.minx(); double loy = extent.miny(); //int max_x = int(std::ceil(double(width) / double(tile_size))); //int max_y = int(std::ceil(double(height) / double(tile_size))); double pixel_x = extent.width() / double(width); double pixel_y = extent.height() / double(height); MAPNIK_LOG_DEBUG(raster) << "tiled_multi_file_policy: Raster Plugin PIXEL SIZE(" << pixel_x << "," << pixel_y << ")"; // intersection of query with extent => new query box2d e = bbox.intersect(extent); const int x_min = int(std::floor((e.minx() - lox) / (tile_size * pixel_x))); const int y_min = int(std::floor((e.miny() - loy) / (tile_size * pixel_y))); const int x_max = int(std::ceil((e.maxx() - lox) / (tile_size * pixel_x))); const int y_max = int(std::ceil((e.maxy() - loy) / (tile_size * pixel_y))); for (int x = x_min; x < x_max; ++x) { for (int y = y_min; y < y_max; ++y) { // x0, y0, x1, y1 => projection-space image coordinates. double x0 = lox + x*tile_size*pixel_x; double y0 = loy + y*tile_size*pixel_y; double x1 = x0 + tile_size*pixel_x; double y1 = y0 + tile_size*pixel_y; // check if it intersects the query if (e.intersects(box2d(x0,y0,x1,y1))) { // tile_box => intersection of tile with query in projection-space. box2d tile_box = e.intersect(box2d(x0,y0,x1,y1)); std::string file = interpolate(file_pattern, x, y); raster_info info(file,format,tile_box,tile_size,tile_size); infos_.push_back(info); } } } MAPNIK_LOG_DEBUG(raster) << "tiled_multi_file_policy: Raster Plugin INFO SIZE=" << infos_.size() << " " << file_pattern; } const_iterator begin() { return infos_.begin(); } const_iterator end() { return infos_.end(); } inline int img_width(int) const { return image_width_; } inline int img_height(int) const { return image_height_; } inline box2d transform(box2d& box) const { int x_offset = int(std::floor(box.minx() / tile_size_)); int y_offset = int(std::floor(box.miny() / tile_size_)); box2d rem(x_offset * tile_size_, y_offset * tile_size_, x_offset * tile_size_, y_offset * tile_size_); box.init(box.minx() - rem.minx(), box.miny() - rem.miny(), box.maxx() - rem.maxx(), box.maxy() - rem.maxy()); return rem; } private: std::string interpolate(std::string const& pattern, int x, int y) const; unsigned int image_width_, image_height_, tile_size_, tile_stride_; std::vector infos_; }; template class raster_featureset : public mapnik::Featureset { using iterator_type = typename LookupPolicy::const_iterator; public: raster_featureset(LookupPolicy const& policy, box2d const& exttent, mapnik::query const& q); virtual ~raster_featureset(); mapnik::feature_ptr next(); private: LookupPolicy policy_; mapnik::value_integer feature_id_; mapnik::context_ptr ctx_; mapnik::box2d extent_; mapnik::box2d bbox_; iterator_type curIter_; iterator_type endIter_; double filter_factor_; }; #endif // RASTER_FEATURESET_HPP