third_party/agg23/agg_math_stroke.h - pdfium - Git at Google


 //----------------------------------------------------------------------------
 // Anti-Grain Geometry - Version 2.3
 // 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.
 //
 //----------------------------------------------------------------------------
 // Contact: mcseem@antigrain.com
 //          mcseemagg@yahoo.com
 //          http://www.antigrain.com
 //----------------------------------------------------------------------------
 //
 // Stroke math
 //
 //----------------------------------------------------------------------------
 #ifndef AGG_STROKE_MATH_INCLUDED
 #define AGG_STROKE_MATH_INCLUDED
 #include "agg_math.h"
 #include "agg_vertex_sequence.h"
 namespace pdfium
 {
 namespace agg
 {
 enum line_cap_e {
     butt_cap,
     square_cap,
     round_cap
 };
 enum line_join_e {
     miter_join         = 0,
     miter_join_revert  = 1,
     miter_join_round   = 4,
     round_join         = 2,
     bevel_join         = 3
 };
 enum inner_join_e {
     inner_bevel,
     inner_miter,
     inner_jag,
     inner_round
 };
 const float stroke_theta = 1.0f / 1000.0f;
 template<class VertexConsumer>
 void stroke_calc_arc(VertexConsumer& out_vertices,
                      float x,   float y,
                      float dx1, float dy1,
                      float dx2, float dy2,
                      float width,
                      float approximation_scale)
 {
     typedef typename VertexConsumer::value_type coord_type;
     float a1 = atan2(dy1, dx1);
     float a2 = atan2(dy2, dx2);
     float da = a1 - a2;
     bool ccw = da > 0 && da < FXSYS_PI;
     if(width < 0) {
         width = -width;
     }
     da = acos(width / (width + ((1.0f / 8) / approximation_scale))) * 2;
     out_vertices.add(coord_type(x + dx1, y + dy1));
     if (da > 0) {
       if (!ccw) {
         if (a1 > a2) {
           a2 += 2 * FXSYS_PI;
         }
         a2 -= da / 4;
         a1 += da;
         while (a1 < a2) {
           out_vertices.add(
               coord_type(x + (width * cos(a1)), y + (width * sin(a1))));
           a1 += da;
         }
       } else {
         if (a1 < a2) {
           a2 -= 2 * FXSYS_PI;
         }
         a2 += da / 4;
         a1 -= da;
         while (a1 > a2) {
           out_vertices.add(
               coord_type(x + (width * cos(a1)), y + (width * sin(a1))));
           a1 -= da;
         }
       }
     }
     out_vertices.add(coord_type(x + dx2, y + dy2));
 }
 template<class VertexConsumer>
 void stroke_calc_miter(VertexConsumer& out_vertices,
                        const vertex_dist& v0,
                        const vertex_dist& v1,
                        const vertex_dist& v2,
                        float dx1, float dy1,
                        float dx2, float dy2,
                        float width,
                        line_join_e line_join,
                        float miter_limit,
                        float approximation_scale)
 {
     typedef typename VertexConsumer::value_type coord_type;
     float xi = v1.x;
     float yi = v1.y;
     bool miter_limit_exceeded = true;
     if(calc_intersection(v0.x + dx1, v0.y - dy1,
                          v1.x + dx1, v1.y - dy1,
                          v1.x + dx2, v1.y - dy2,
                          v2.x + dx2, v2.y - dy2,
                          &xi, &yi)) {
         float d1 = calc_distance(v1.x, v1.y, xi, yi);
         float lim = width * miter_limit;
         if(d1 <= lim) {
             out_vertices.add(coord_type(xi, yi));
             miter_limit_exceeded = false;
         }
     } else {
         float x2 = v1.x + dx1;
         float y2 = v1.y - dy1;
         if ((((x2 - v0.x) * dy1) - ((v0.y - y2) * dx1) < 0) !=
             (((x2 - v2.x) * dy1) - ((v2.y - y2) * dx1) < 0)) {
             out_vertices.add(coord_type(v1.x + dx1, v1.y - dy1));
             miter_limit_exceeded = false;
         }
     }
     if(miter_limit_exceeded) {
         switch(line_join) {
             case miter_join_revert:
                 out_vertices.add(coord_type(v1.x + dx1, v1.y - dy1));
                 out_vertices.add(coord_type(v1.x + dx2, v1.y - dy2));
                 break;
             case miter_join_round:
                 stroke_calc_arc(out_vertices,
                                 v1.x, v1.y, dx1, -dy1, dx2, -dy2,
                                 width, approximation_scale);
                 break;
             default:
               out_vertices.add(coord_type(v1.x + dx1 + (dy1 * miter_limit),
                                           v1.y - dy1 + (dx1 * miter_limit)));
               out_vertices.add(coord_type(v1.x + dx2 - (dy2 * miter_limit),
                                           v1.y - dy2 - (dx2 * miter_limit)));
                 break;
         }
     }
 }
 template<class VertexConsumer>
 void stroke_calc_cap(VertexConsumer& out_vertices,
                      const vertex_dist& v0,
                      const vertex_dist& v1,
                      float len,
                      line_cap_e line_cap,
                      float width,
                      float approximation_scale)
 {
     typedef typename VertexConsumer::value_type coord_type;
     out_vertices.remove_all();
     float dx1 = (v1.y - v0.y) / len;
     float dy1 = (v1.x - v0.x) / len;
     float dx2 = 0;
     float dy2 = 0;
     dx1 = dx1 * width;
     dy1 = dy1 * width;
     if(line_cap != round_cap) {
         if(line_cap == square_cap) {
             dx2 = dy1;
             dy2 = dx1;
         }
         out_vertices.add(coord_type(v0.x - dx1 - dx2, v0.y + dy1 - dy2));
         out_vertices.add(coord_type(v0.x + dx1 - dx2, v0.y - dy1 - dy2));
     } else {
       float a1 = atan2(dy1, -dx1);
       float a2 = a1 + FXSYS_PI;
       float da = acos(width / (width + ((1.0f / 8) / approximation_scale))) * 2;
       if (da < stroke_theta) {
         da = stroke_theta;
       }
       out_vertices.add(coord_type(v0.x - dx1, v0.y + dy1));
       a1 += da;
       a2 -= da / 4;
       while (a1 < a2) {
         out_vertices.add(
             coord_type(v0.x + (width * cos(a1)), v0.y + (width * sin(a1))));
         a1 += da;
       }
       out_vertices.add(coord_type(v0.x + dx1, v0.y - dy1));
     }
 }
 template<class VertexConsumer>
 void stroke_calc_join(VertexConsumer& out_vertices,
                       const vertex_dist& v0,
                       const vertex_dist& v1,
                       const vertex_dist& v2,
                       float len1,
                       float len2,
                       float width,
                       line_join_e line_join,
                       inner_join_e inner_join,
                       float miter_limit,
                       float inner_miter_limit,
                       float approximation_scale)
 {
     typedef typename VertexConsumer::value_type coord_type;
     float dx1, dy1, dx2, dy2;
     dx1 = width * (v1.y - v0.y) / len1;
     dy1 = width * (v1.x - v0.x) / len1;
     dx2 = width * (v2.y - v1.y) / len2;
     dy2 = width * (v2.x - v1.x) / len2;
     out_vertices.remove_all();
     if(calc_point_location(v0.x, v0.y, v1.x, v1.y, v2.x, v2.y) > 0) {
         switch(inner_join) {
             default:
                 out_vertices.add(coord_type(v1.x + dx1, v1.y - dy1));
                 out_vertices.add(coord_type(v1.x + dx2, v1.y - dy2));
                 break;
             case inner_miter:
                 stroke_calc_miter(out_vertices,
                                   v0, v1, v2, dx1, dy1, dx2, dy2,
                                   width,
                                   miter_join_revert,
                                   inner_miter_limit,
                                   1.0f);
                 break;
             case inner_jag:
             case inner_round: {
                     float d = (dx1 - dx2) * (dx1 - dx2) + (dy1 - dy2) * (dy1 - dy2);
                     if(d < len1 * len1 && d < len2 * len2) {
                         stroke_calc_miter(out_vertices,
                                           v0, v1, v2, dx1, dy1, dx2, dy2,
                                           width,
                                           miter_join_revert,
                                           inner_miter_limit,
                                           1.0f);
                     } else {
                         if(inner_join == inner_jag) {
                             out_vertices.add(coord_type(v1.x + dx1, v1.y - dy1));
                             out_vertices.add(coord_type(v1.x,       v1.y      ));
                             out_vertices.add(coord_type(v1.x + dx2, v1.y - dy2));
                         } else {
                             out_vertices.add(coord_type(v1.x + dx1, v1.y - dy1));
                             out_vertices.add(coord_type(v1.x,       v1.y      ));
                             stroke_calc_arc(out_vertices,
                                             v1.x, v1.y, dx2, -dy2, dx1, -dy1,
                                             width, approximation_scale);
                             out_vertices.add(coord_type(v1.x,       v1.y      ));
                             out_vertices.add(coord_type(v1.x + dx2, v1.y - dy2));
                         }
                     }
                 }
                 break;
         }
     } else {
         switch(line_join) {
             case miter_join:
             case miter_join_revert:
             case miter_join_round:
                 stroke_calc_miter(out_vertices,
                                   v0, v1, v2, dx1, dy1, dx2, dy2,
                                   width,
                                   line_join,
                                   miter_limit,
                                   approximation_scale);
                 break;
             case round_join:
                 stroke_calc_arc(out_vertices,
                                 v1.x, v1.y, dx1, -dy1, dx2, -dy2,
                                 width, approximation_scale);
                 break;
             default:
                 out_vertices.add(coord_type(v1.x + dx1, v1.y - dy1));
                 out_vertices.add(coord_type(v1.x + dx2, v1.y - dy2));
                 break;
         }
     }
 }
 }
 }  // namespace pdfium
 #endif

	//----------------------------------------------------------------------------
	// Anti-Grain Geometry - Version 2.3
	// 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.
	//
	//----------------------------------------------------------------------------
	// Contact: mcseem@antigrain.com
	// mcseemagg@yahoo.com
	// http://www.antigrain.com
	//----------------------------------------------------------------------------
	//
	// Stroke math
	//
	//----------------------------------------------------------------------------
	#ifndef AGG_STROKE_MATH_INCLUDED
	#define AGG_STROKE_MATH_INCLUDED
	#include "agg_math.h"
	#include "agg_vertex_sequence.h"
	namespace pdfium
	{
	namespace agg
	{
	enum line_cap_e {
	butt_cap,
	square_cap,
	round_cap
	};
	enum line_join_e {
	miter_join = 0,
	miter_join_revert = 1,
	miter_join_round = 4,
	round_join = 2,
	bevel_join = 3
	};
	enum inner_join_e {
	inner_bevel,
	inner_miter,
	inner_jag,
	inner_round
	};
	const float stroke_theta = 1.0f / 1000.0f;
	template<class VertexConsumer>
	void stroke_calc_arc(VertexConsumer& out_vertices,
	float x, float y,
	float dx1, float dy1,
	float dx2, float dy2,
	float width,
	float approximation_scale)
	{
	typedef typename VertexConsumer::value_type coord_type;
	float a1 = atan2(dy1, dx1);
	float a2 = atan2(dy2, dx2);
	float da = a1 - a2;
	bool ccw = da > 0 && da < FXSYS_PI;
	if(width < 0) {
	width = -width;
	}
	da = acos(width / (width + ((1.0f / 8) / approximation_scale))) * 2;
	out_vertices.add(coord_type(x + dx1, y + dy1));
	if (da > 0) {
	if (!ccw) {
	if (a1 > a2) {
	a2 += 2 * FXSYS_PI;
	}
	a2 -= da / 4;
	a1 += da;
	while (a1 < a2) {
	out_vertices.add(
	coord_type(x + (width * cos(a1)), y + (width * sin(a1))));
	a1 += da;
	}
	} else {
	if (a1 < a2) {
	a2 -= 2 * FXSYS_PI;
	}
	a2 += da / 4;
	a1 -= da;
	while (a1 > a2) {
	out_vertices.add(
	coord_type(x + (width * cos(a1)), y + (width * sin(a1))));
	a1 -= da;
	}
	}
	}
	out_vertices.add(coord_type(x + dx2, y + dy2));
	}
	template<class VertexConsumer>
	void stroke_calc_miter(VertexConsumer& out_vertices,
	const vertex_dist& v0,
	const vertex_dist& v1,
	const vertex_dist& v2,
	float dx1, float dy1,
	float dx2, float dy2,
	float width,
	line_join_e line_join,
	float miter_limit,
	float approximation_scale)
	{
	typedef typename VertexConsumer::value_type coord_type;
	float xi = v1.x;
	float yi = v1.y;
	bool miter_limit_exceeded = true;
	if(calc_intersection(v0.x + dx1, v0.y - dy1,
	v1.x + dx1, v1.y - dy1,
	v1.x + dx2, v1.y - dy2,
	v2.x + dx2, v2.y - dy2,
	&xi, &yi)) {
	float d1 = calc_distance(v1.x, v1.y, xi, yi);
	float lim = width * miter_limit;
	if(d1 <= lim) {
	out_vertices.add(coord_type(xi, yi));
	miter_limit_exceeded = false;
	}
	} else {
	float x2 = v1.x + dx1;
	float y2 = v1.y - dy1;
	if ((((x2 - v0.x) * dy1) - ((v0.y - y2) * dx1) < 0) !=
	(((x2 - v2.x) * dy1) - ((v2.y - y2) * dx1) < 0)) {
	out_vertices.add(coord_type(v1.x + dx1, v1.y - dy1));
	miter_limit_exceeded = false;
	}
	}
	if(miter_limit_exceeded) {
	switch(line_join) {
	case miter_join_revert:
	out_vertices.add(coord_type(v1.x + dx1, v1.y - dy1));
	out_vertices.add(coord_type(v1.x + dx2, v1.y - dy2));
	break;
	case miter_join_round:
	stroke_calc_arc(out_vertices,
	v1.x, v1.y, dx1, -dy1, dx2, -dy2,
	width, approximation_scale);
	break;
	default:
	out_vertices.add(coord_type(v1.x + dx1 + (dy1 * miter_limit),
	v1.y - dy1 + (dx1 * miter_limit)));
	out_vertices.add(coord_type(v1.x + dx2 - (dy2 * miter_limit),
	v1.y - dy2 - (dx2 * miter_limit)));
	break;
	}
	}
	}
	template<class VertexConsumer>
	void stroke_calc_cap(VertexConsumer& out_vertices,
	const vertex_dist& v0,
	const vertex_dist& v1,
	float len,
	line_cap_e line_cap,
	float width,
	float approximation_scale)
	{
	typedef typename VertexConsumer::value_type coord_type;
	out_vertices.remove_all();
	float dx1 = (v1.y - v0.y) / len;
	float dy1 = (v1.x - v0.x) / len;
	float dx2 = 0;
	float dy2 = 0;
	dx1 = dx1 * width;
	dy1 = dy1 * width;
	if(line_cap != round_cap) {
	if(line_cap == square_cap) {
	dx2 = dy1;
	dy2 = dx1;
	}
	out_vertices.add(coord_type(v0.x - dx1 - dx2, v0.y + dy1 - dy2));
	out_vertices.add(coord_type(v0.x + dx1 - dx2, v0.y - dy1 - dy2));
	} else {
	float a1 = atan2(dy1, -dx1);
	float a2 = a1 + FXSYS_PI;
	float da = acos(width / (width + ((1.0f / 8) / approximation_scale))) * 2;
	if (da < stroke_theta) {
	da = stroke_theta;
	}
	out_vertices.add(coord_type(v0.x - dx1, v0.y + dy1));
	a1 += da;
	a2 -= da / 4;
	while (a1 < a2) {
	out_vertices.add(
	coord_type(v0.x + (width * cos(a1)), v0.y + (width * sin(a1))));
	a1 += da;
	}
	out_vertices.add(coord_type(v0.x + dx1, v0.y - dy1));
	}
	}
	template<class VertexConsumer>
	void stroke_calc_join(VertexConsumer& out_vertices,
	const vertex_dist& v0,
	const vertex_dist& v1,
	const vertex_dist& v2,
	float len1,
	float len2,
	float width,
	line_join_e line_join,
	inner_join_e inner_join,
	float miter_limit,
	float inner_miter_limit,
	float approximation_scale)
	{
	typedef typename VertexConsumer::value_type coord_type;
	float dx1, dy1, dx2, dy2;
	dx1 = width * (v1.y - v0.y) / len1;
	dy1 = width * (v1.x - v0.x) / len1;
	dx2 = width * (v2.y - v1.y) / len2;
	dy2 = width * (v2.x - v1.x) / len2;
	out_vertices.remove_all();
	if(calc_point_location(v0.x, v0.y, v1.x, v1.y, v2.x, v2.y) > 0) {
	switch(inner_join) {
	default:
	out_vertices.add(coord_type(v1.x + dx1, v1.y - dy1));
	out_vertices.add(coord_type(v1.x + dx2, v1.y - dy2));
	break;
	case inner_miter:
	stroke_calc_miter(out_vertices,
	v0, v1, v2, dx1, dy1, dx2, dy2,
	width,
	miter_join_revert,
	inner_miter_limit,
	1.0f);
	break;
	case inner_jag:
	case inner_round: {
	float d = (dx1 - dx2) * (dx1 - dx2) + (dy1 - dy2) * (dy1 - dy2);
	if(d < len1 * len1 && d < len2 * len2) {
	stroke_calc_miter(out_vertices,
	v0, v1, v2, dx1, dy1, dx2, dy2,
	width,
	miter_join_revert,
	inner_miter_limit,
	1.0f);
	} else {
	if(inner_join == inner_jag) {
	out_vertices.add(coord_type(v1.x + dx1, v1.y - dy1));
	out_vertices.add(coord_type(v1.x, v1.y ));
	out_vertices.add(coord_type(v1.x + dx2, v1.y - dy2));
	} else {
	out_vertices.add(coord_type(v1.x + dx1, v1.y - dy1));
	out_vertices.add(coord_type(v1.x, v1.y ));
	stroke_calc_arc(out_vertices,
	v1.x, v1.y, dx2, -dy2, dx1, -dy1,
	width, approximation_scale);
	out_vertices.add(coord_type(v1.x, v1.y ));
	out_vertices.add(coord_type(v1.x + dx2, v1.y - dy2));
	}
	}
	}
	break;
	}
	} else {
	switch(line_join) {
	case miter_join:
	case miter_join_revert:
	case miter_join_round:
	stroke_calc_miter(out_vertices,
	v0, v1, v2, dx1, dy1, dx2, dy2,
	width,
	line_join,
	miter_limit,
	approximation_scale);
	break;
	case round_join:
	stroke_calc_arc(out_vertices,
	v1.x, v1.y, dx1, -dy1, dx2, -dy2,
	width, approximation_scale);
	break;
	default:
	out_vertices.add(coord_type(v1.x + dx1, v1.y - dy1));
	out_vertices.add(coord_type(v1.x + dx2, v1.y - dy2));
	break;
	}
	}
	}
	}
	} // namespace pdfium
	#endif