//---------------------------------------------------------------------------- // Anti-Grain Geometry - Version 2.4 // Copyright (C) 2002-2005 Maxim Shemanarev (http://www.antigrain.com) // // Permission to copy, use, modify, sell and distribute this software // is granted provided this copyright notice appears in all copies. // This software is provided "as is" without express or implied // warranty, and with no claim as to its suitability for any purpose. // //---------------------------------------------------------------------------- // // The author gratefully acknowleges the support of David Turner, // Robert Wilhelm, and Werner Lemberg - the authors of the FreeType // libray - in producing this work. See http://www.freetype.org for details. // //---------------------------------------------------------------------------- // Contact: mcseem@antigrain.com // mcseemagg@yahoo.com // http://www.antigrain.com //---------------------------------------------------------------------------- // // Adaptation for 32-bit screen coordinates has been sponsored by // Liberty Technology Systems, Inc., visit http://lib-sys.com // // Liberty Technology Systems, Inc. is the provider of // PostScript and PDF technology for software developers. // //---------------------------------------------------------------------------- #ifndef AGG_RASTERIZER_SCANLINE_AA_INCLUDED #define AGG_RASTERIZER_SCANLINE_AA_INCLUDED #include "agg_rasterizer_cells_aa.h" #include "agg_rasterizer_sl_clip.h" #include "agg_gamma_functions.h" namespace agg { //-----------------------------------------------------------------cell_aa // A pixel cell. There're no constructors defined and it was done // intentionally in order to avoid extra overhead when allocating an // array of cells. struct cell_aa { int x; int y; int cover; int area; void initial() { x = 0x7FFFFFFF; y = 0x7FFFFFFF; cover = 0; area = 0; } void style(const cell_aa&) {} int not_equal(int ex, int ey, const cell_aa&) const { return (ex - x) | (ey - y); } }; //==================================================rasterizer_scanline_aa // Polygon rasterizer that is used to render filled polygons with // high-quality Anti-Aliasing. Internally, by default, the class uses // integer coordinates in format 24.8, i.e. 24 bits for integer part // and 8 bits for fractional - see poly_subpixel_shift. This class can be // used in the following way: // // 1. filling_rule(filling_rule_e ft) - optional. // // 2. gamma() - optional. // // 3. reset() // // 4. move_to(x, y) / line_to(x, y) - make the polygon. One can create // more than one contour, but each contour must consist of at least 3 // vertices, i.e. move_to(x1, y1); line_to(x2, y2); line_to(x3, y3); // is the absolute minimum of vertices that define a triangle. // The algorithm does not check either the number of vertices nor // coincidence of their coordinates, but in the worst case it just // won't draw anything. // The orger of the vertices (clockwise or counterclockwise) // is important when using the non-zero filling rule (fill_non_zero). // In this case the vertex order of all the contours must be the same // if you want your intersecting polygons to be without "holes". // You actually can use different vertices order. If the contours do not // intersect each other the order is not important anyway. If they do, // contours with the same vertex order will be rendered without "holes" // while the intersecting contours with different orders will have "holes". // // filling_rule() and gamma() can be called anytime before "sweeping". //------------------------------------------------------------------------ template class rasterizer_scanline_aa { enum status { status_initial, status_move_to, status_line_to, status_closed }; public: typedef Clip clip_type; typedef typename Clip::conv_type conv_type; typedef typename Clip::coord_type coord_type; enum aa_scale_e { aa_shift = 8, aa_scale = 1 << aa_shift, aa_mask = aa_scale - 1, aa_scale2 = aa_scale * 2, aa_mask2 = aa_scale2 - 1 }; //-------------------------------------------------------------------- rasterizer_scanline_aa() : m_outline(), m_clipper(), m_filling_rule(fill_non_zero), m_auto_close(true), m_start_x(0), m_start_y(0), m_status(status_initial) { int i; for(i = 0; i < aa_scale; i++) m_gamma[i] = i; } //-------------------------------------------------------------------- template rasterizer_scanline_aa(const GammaF& gamma_function) : m_outline(), m_clipper(m_outline), m_filling_rule(fill_non_zero), m_auto_close(true), m_start_x(0), m_start_y(0), m_status(status_initial) { gamma(gamma_function); } //-------------------------------------------------------------------- void reset(); void reset_clipping(); void clip_box(double x1, double y1, double x2, double y2); void filling_rule(filling_rule_e filling_rule); void auto_close(bool flag) { m_auto_close = flag; } //-------------------------------------------------------------------- template void gamma(const GammaF& gamma_function) { int i; for(i = 0; i < aa_scale; i++) { m_gamma[i] = uround(gamma_function(double(i) / aa_mask) * aa_mask); } } //-------------------------------------------------------------------- unsigned apply_gamma(unsigned cover) const { return m_gamma[cover]; } //-------------------------------------------------------------------- void move_to(int x, int y); void line_to(int x, int y); void move_to_d(double x, double y); void line_to_d(double x, double y); void close_polygon(); void add_vertex(double x, double y, unsigned cmd); void edge(int x1, int y1, int x2, int y2); void edge_d(double x1, double y1, double x2, double y2); //------------------------------------------------------------------- template void add_path(VertexSource& vs, unsigned path_id=0) { double x; double y; unsigned cmd; vs.rewind(path_id); if(m_outline.sorted()) reset(); while(!is_stop(cmd = vs.vertex(&x, &y))) { add_vertex(x, y, cmd); } } //-------------------------------------------------------------------- int min_x() const { return m_outline.min_x(); } int min_y() const { return m_outline.min_y(); } int max_x() const { return m_outline.max_x(); } int max_y() const { return m_outline.max_y(); } //-------------------------------------------------------------------- void sort(); bool rewind_scanlines(); bool navigate_scanline(int y); //-------------------------------------------------------------------- AGG_INLINE unsigned calculate_alpha(int area) const { int cover = area >> (poly_subpixel_shift*2 + 1 - aa_shift); if(cover < 0) cover = -cover; if(m_filling_rule == fill_even_odd) { cover &= aa_mask2; if(cover > aa_scale) { cover = aa_scale2 - cover; } } if(cover > aa_mask) cover = aa_mask; return m_gamma[cover]; } //-------------------------------------------------------------------- template bool sweep_scanline(Scanline& sl) { for(;;) { if(m_scan_y > m_outline.max_y()) return false; sl.reset_spans(); unsigned num_cells = m_outline.scanline_num_cells(m_scan_y); const cell_aa* const* cells = m_outline.scanline_cells(m_scan_y); unsigned cover = 0; while(num_cells) { const cell_aa* cur_cell = *cells; int x = cur_cell->x; int area = cur_cell->area; unsigned alpha; cover += cur_cell->cover; //accumulate all cells with the same X while(--num_cells) { cur_cell = *++cells; if(cur_cell->x != x) break; area += cur_cell->area; cover += cur_cell->cover; } if(area) { alpha = calculate_alpha((cover << (poly_subpixel_shift + 1)) - area); if(alpha) { sl.add_cell(x, alpha); } x++; } if(num_cells && cur_cell->x > x) { alpha = calculate_alpha(cover << (poly_subpixel_shift + 1)); if(alpha) { sl.add_span(x, cur_cell->x - x, alpha); } } } if(sl.num_spans()) break; ++m_scan_y; } sl.finalize(m_scan_y); ++m_scan_y; return true; } //-------------------------------------------------------------------- bool hit_test(int tx, int ty); private: //-------------------------------------------------------------------- // Disable copying rasterizer_scanline_aa(const rasterizer_scanline_aa&); const rasterizer_scanline_aa& operator = (const rasterizer_scanline_aa&); private: rasterizer_cells_aa m_outline; clip_type m_clipper; int m_gamma[aa_scale]; filling_rule_e m_filling_rule; bool m_auto_close; coord_type m_start_x; coord_type m_start_y; unsigned m_status; int m_scan_y; }; //------------------------------------------------------------------------ template void rasterizer_scanline_aa::reset() { m_outline.reset(); m_status = status_initial; } //------------------------------------------------------------------------ template void rasterizer_scanline_aa::filling_rule(filling_rule_e filling_rule) { m_filling_rule = filling_rule; } //------------------------------------------------------------------------ template void rasterizer_scanline_aa::clip_box(double x1, double y1, double x2, double y2) { reset(); m_clipper.clip_box(conv_type::upscale(x1), conv_type::upscale(y1), conv_type::upscale(x2), conv_type::upscale(y2)); } //------------------------------------------------------------------------ template void rasterizer_scanline_aa::reset_clipping() { reset(); m_clipper.reset_clipping(); } //------------------------------------------------------------------------ template void rasterizer_scanline_aa::close_polygon() { if(m_status == status_line_to) { m_clipper.line_to(m_outline, m_start_x, m_start_y); m_status = status_closed; } } //------------------------------------------------------------------------ template void rasterizer_scanline_aa::move_to(int x, int y) { if(m_outline.sorted()) reset(); if(m_auto_close) close_polygon(); m_clipper.move_to(m_start_x = conv_type::downscale(x), m_start_y = conv_type::downscale(y)); m_status = status_move_to; } //------------------------------------------------------------------------ template void rasterizer_scanline_aa::line_to(int x, int y) { m_clipper.line_to(m_outline, conv_type::downscale(x), conv_type::downscale(y)); m_status = status_line_to; } //------------------------------------------------------------------------ template void rasterizer_scanline_aa::move_to_d(double x, double y) { if(m_outline.sorted()) reset(); if(m_auto_close) close_polygon(); m_clipper.move_to(m_start_x = conv_type::upscale(x), m_start_y = conv_type::upscale(y)); m_status = status_move_to; } //------------------------------------------------------------------------ template void rasterizer_scanline_aa::line_to_d(double x, double y) { m_clipper.line_to(m_outline, conv_type::upscale(x), conv_type::upscale(y)); m_status = status_line_to; } //------------------------------------------------------------------------ template void rasterizer_scanline_aa::add_vertex(double x, double y, unsigned cmd) { if(is_move_to(cmd)) { move_to_d(x, y); } else if(is_vertex(cmd)) { line_to_d(x, y); } else if(is_close(cmd)) { close_polygon(); } } //------------------------------------------------------------------------ template void rasterizer_scanline_aa::edge(int x1, int y1, int x2, int y2) { if(m_outline.sorted()) reset(); m_clipper.move_to(conv_type::downscale(x1), conv_type::downscale(y1)); m_clipper.line_to(m_outline, conv_type::downscale(x2), conv_type::downscale(y2)); m_status = status_move_to; } //------------------------------------------------------------------------ template void rasterizer_scanline_aa::edge_d(double x1, double y1, double x2, double y2) { if(m_outline.sorted()) reset(); m_clipper.move_to(conv_type::upscale(x1), conv_type::upscale(y1)); m_clipper.line_to(m_outline, conv_type::upscale(x2), conv_type::upscale(y2)); m_status = status_move_to; } //------------------------------------------------------------------------ template void rasterizer_scanline_aa::sort() { if(m_auto_close) close_polygon(); m_outline.sort_cells(); } //------------------------------------------------------------------------ template AGG_INLINE bool rasterizer_scanline_aa::rewind_scanlines() { if(m_auto_close) close_polygon(); m_outline.sort_cells(); if(m_outline.total_cells() == 0) { return false; } m_scan_y = m_outline.min_y(); return true; } //------------------------------------------------------------------------ template AGG_INLINE bool rasterizer_scanline_aa::navigate_scanline(int y) { if(m_auto_close) close_polygon(); m_outline.sort_cells(); if(m_outline.total_cells() == 0 || y < m_outline.min_y() || y > m_outline.max_y()) { return false; } m_scan_y = y; return true; } //------------------------------------------------------------------------ template bool rasterizer_scanline_aa::hit_test(int tx, int ty) { if(!navigate_scanline(ty)) return false; scanline_hit_test sl(tx); sweep_scanline(sl); return sl.hit(); } } #endif