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	//----------------------------------------------------------------------------
	// 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.
	//
	//----------------------------------------------------------------------------
	// Contact: mcseem@antigrain.com
	// mcseemagg@yahoo.com
	// http://www.antigrain.com
	//----------------------------------------------------------------------------

	#include <math.h>
	#include "agg_curves.h"
	#include "agg_math.h"

	namespace agg
	{

	//------------------------------------------------------------------------
	const double curve_distance_epsilon = 1e-30;
	const double curve_collinearity_epsilon = 1e-30;
	const double curve_angle_tolerance_epsilon = 0.01;
	enum curve_recursion_limit_e { curve_recursion_limit = 32 };



	//------------------------------------------------------------------------
	void curve3_inc::approximation_scale(double s)
	{
	m_scale = s;
	}

	//------------------------------------------------------------------------
	double curve3_inc::approximation_scale() const
	{
	return m_scale;
	}

	//------------------------------------------------------------------------
	void curve3_inc::init(double x1, double y1,
	double x2, double y2,
	double x3, double y3)
	{
	m_start_x = x1;
	m_start_y = y1;
	m_end_x = x3;
	m_end_y = y3;

	double dx1 = x2 - x1;
	double dy1 = y2 - y1;
	double dx2 = x3 - x2;
	double dy2 = y3 - y2;

	double len = sqrt(dx1 * dx1 + dy1 * dy1) + sqrt(dx2 * dx2 + dy2 * dy2);

	m_num_steps = uround(len * 0.25 * m_scale);

	if(m_num_steps < 4)
	{
	m_num_steps = 4;
	}

	double subdivide_step = 1.0 / m_num_steps;
	double subdivide_step2 = subdivide_step * subdivide_step;

	double tmpx = (x1 - x2 * 2.0 + x3) * subdivide_step2;
	double tmpy = (y1 - y2 * 2.0 + y3) * subdivide_step2;

	m_saved_fx = m_fx = x1;
	m_saved_fy = m_fy = y1;

	m_saved_dfx = m_dfx = tmpx + (x2 - x1) * (2.0 * subdivide_step);
	m_saved_dfy = m_dfy = tmpy + (y2 - y1) * (2.0 * subdivide_step);

	m_ddfx = tmpx * 2.0;
	m_ddfy = tmpy * 2.0;

	m_step = m_num_steps;
	}

	//------------------------------------------------------------------------
	void curve3_inc::rewind(unsigned)
	{
	if(m_num_steps == 0)
	{
	m_step = -1;
	return;
	}
	m_step = m_num_steps;
	m_fx = m_saved_fx;
	m_fy = m_saved_fy;
	m_dfx = m_saved_dfx;
	m_dfy = m_saved_dfy;
	}

	//------------------------------------------------------------------------
	unsigned curve3_inc::vertex(double* x, double* y)
	{
	if(m_step < 0) return path_cmd_stop;
	if(m_step == m_num_steps)
	{
	*x = m_start_x;
	*y = m_start_y;
	--m_step;
	return path_cmd_move_to;
	}
	if(m_step == 0)
	{
	*x = m_end_x;
	*y = m_end_y;
	--m_step;
	return path_cmd_line_to;
	}
	m_fx += m_dfx;
	m_fy += m_dfy;
	m_dfx += m_ddfx;
	m_dfy += m_ddfy;
	*x = m_fx;
	*y = m_fy;
	--m_step;
	return path_cmd_line_to;
	}

	//------------------------------------------------------------------------
	void curve3_div::init(double x1, double y1,
	double x2, double y2,
	double x3, double y3)
	{
	m_points.remove_all();
	m_distance_tolerance_square = 0.5 / m_approximation_scale;
	m_distance_tolerance_square *= m_distance_tolerance_square;
	bezier(x1, y1, x2, y2, x3, y3);
	m_count = 0;
	}

	//------------------------------------------------------------------------
	void curve3_div::recursive_bezier(double x1, double y1,
	double x2, double y2,
	double x3, double y3,
	unsigned level)
	{
	if(level > curve_recursion_limit)
	{
	return;
	}

	// Calculate all the mid-points of the line segments
	//----------------------
	double x12 = (x1 + x2) / 2;
	double y12 = (y1 + y2) / 2;
	double x23 = (x2 + x3) / 2;
	double y23 = (y2 + y3) / 2;
	double x123 = (x12 + x23) / 2;
	double y123 = (y12 + y23) / 2;

	double dx = x3-x1;
	double dy = y3-y1;
	double d = fabs(((x2 - x3) * dy - (y2 - y3) * dx));
	double da;

	if(d > curve_collinearity_epsilon)
	{
	// Regular case
	//-----------------
	if(d * d <= m_distance_tolerance_square * (dxdx + dydy))
	{
	// If the curvature doesn't exceed the distance_tolerance value
	// we tend to finish subdivisions.
	//----------------------
	if(m_angle_tolerance < curve_angle_tolerance_epsilon)
	{
	m_points.add(point_d(x123, y123));
	return;
	}

	// Angle & Cusp Condition
	//----------------------
	da = fabs(atan2(y3 - y2, x3 - x2) - atan2(y2 - y1, x2 - x1));
	if(da >= pi) da = 2*pi - da;

	if(da < m_angle_tolerance)
	{
	// Finally we can stop the recursion
	//----------------------
	m_points.add(point_d(x123, y123));
	return;
	}
	}
	}
	else
	{
	// Collinear case
	//------------------
	da = dxdx + dydy;
	if(da == 0)
	{
	d = calc_sq_distance(x1, y1, x2, y2);
	}
	else
	{
	d = ((x2 - x1)dx + (y2 - y1)dy) / da;
	if(d > 0 && d < 1)
	{
	// Simple collinear case, 1---2---3
	// We can leave just two endpoints
	return;
	}
	if(d <= 0) d = calc_sq_distance(x2, y2, x1, y1);
	else if(d >= 1) d = calc_sq_distance(x2, y2, x3, y3);
	else d = calc_sq_distance(x2, y2, x1 + ddx, y1 + ddy);
	}
	if(d < m_distance_tolerance_square)
	{
	m_points.add(point_d(x2, y2));
	return;
	}
	}

	// Continue subdivision
	//----------------------
	recursive_bezier(x1, y1, x12, y12, x123, y123, level + 1);
	recursive_bezier(x123, y123, x23, y23, x3, y3, level + 1);
	}

	//------------------------------------------------------------------------
	void curve3_div::bezier(double x1, double y1,
	double x2, double y2,
	double x3, double y3)
	{
	m_points.add(point_d(x1, y1));
	recursive_bezier(x1, y1, x2, y2, x3, y3, 0);
	m_points.add(point_d(x3, y3));
	}





	//------------------------------------------------------------------------
	void curve4_inc::approximation_scale(double s)
	{
	m_scale = s;
	}

	//------------------------------------------------------------------------
	double curve4_inc::approximation_scale() const
	{
	return m_scale;
	}

	#if defined(_MSC_VER) && _MSC_VER <= 1200
	//------------------------------------------------------------------------
	static double MSC60_fix_ICE(double v) { return v; }
	#endif

	//------------------------------------------------------------------------
	void curve4_inc::init(double x1, double y1,
	double x2, double y2,
	double x3, double y3,
	double x4, double y4)
	{
	m_start_x = x1;
	m_start_y = y1;
	m_end_x = x4;
	m_end_y = y4;

	double dx1 = x2 - x1;
	double dy1 = y2 - y1;
	double dx2 = x3 - x2;
	double dy2 = y3 - y2;
	double dx3 = x4 - x3;
	double dy3 = y4 - y3;

	double len = (sqrt(dx1 * dx1 + dy1 * dy1) +
	sqrt(dx2 * dx2 + dy2 * dy2) +
	sqrt(dx3 * dx3 + dy3 * dy3)) * 0.25 * m_scale;

	#if defined(_MSC_VER) && _MSC_VER <= 1200
	m_num_steps = uround(MSC60_fix_ICE(len));
	#else
	m_num_steps = uround(len);
	#endif

	if(m_num_steps < 4)
	{
	m_num_steps = 4;
	}

	double subdivide_step = 1.0 / m_num_steps;
	double subdivide_step2 = subdivide_step * subdivide_step;
	double subdivide_step3 = subdivide_step * subdivide_step * subdivide_step;

	double pre1 = 3.0 * subdivide_step;
	double pre2 = 3.0 * subdivide_step2;
	double pre4 = 6.0 * subdivide_step2;
	double pre5 = 6.0 * subdivide_step3;

	double tmp1x = x1 - x2 * 2.0 + x3;
	double tmp1y = y1 - y2 * 2.0 + y3;

	double tmp2x = (x2 - x3) * 3.0 - x1 + x4;
	double tmp2y = (y2 - y3) * 3.0 - y1 + y4;

	m_saved_fx = m_fx = x1;
	m_saved_fy = m_fy = y1;

	m_saved_dfx = m_dfx = (x2 - x1) * pre1 + tmp1x * pre2 + tmp2x * subdivide_step3;
	m_saved_dfy = m_dfy = (y2 - y1) * pre1 + tmp1y * pre2 + tmp2y * subdivide_step3;

	m_saved_ddfx = m_ddfx = tmp1x * pre4 + tmp2x * pre5;
	m_saved_ddfy = m_ddfy = tmp1y * pre4 + tmp2y * pre5;

	m_dddfx = tmp2x * pre5;
	m_dddfy = tmp2y * pre5;

	m_step = m_num_steps;
	}

	//------------------------------------------------------------------------
	void curve4_inc::rewind(unsigned)
	{
	if(m_num_steps == 0)
	{
	m_step = -1;
	return;
	}
	m_step = m_num_steps;
	m_fx = m_saved_fx;
	m_fy = m_saved_fy;
	m_dfx = m_saved_dfx;
	m_dfy = m_saved_dfy;
	m_ddfx = m_saved_ddfx;
	m_ddfy = m_saved_ddfy;
	}

	//------------------------------------------------------------------------
	unsigned curve4_inc::vertex(double* x, double* y)
	{
	if(m_step < 0) return path_cmd_stop;
	if(m_step == m_num_steps)
	{
	*x = m_start_x;
	*y = m_start_y;
	--m_step;
	return path_cmd_move_to;
	}

	if(m_step == 0)
	{
	*x = m_end_x;
	*y = m_end_y;
	--m_step;
	return path_cmd_line_to;
	}

	m_fx += m_dfx;
	m_fy += m_dfy;
	m_dfx += m_ddfx;
	m_dfy += m_ddfy;
	m_ddfx += m_dddfx;
	m_ddfy += m_dddfy;

	*x = m_fx;
	*y = m_fy;
	--m_step;
	return path_cmd_line_to;
	}




	//------------------------------------------------------------------------
	void curve4_div::init(double x1, double y1,
	double x2, double y2,
	double x3, double y3,
	double x4, double y4)
	{
	m_points.remove_all();
	m_distance_tolerance_square = 0.5 / m_approximation_scale;
	m_distance_tolerance_square *= m_distance_tolerance_square;
	bezier(x1, y1, x2, y2, x3, y3, x4, y4);
	m_count = 0;
	}

	//------------------------------------------------------------------------
	void curve4_div::recursive_bezier(double x1, double y1,
	double x2, double y2,
	double x3, double y3,
	double x4, double y4,
	unsigned level)
	{
	if(level > curve_recursion_limit)
	{
	return;
	}

	// Calculate all the mid-points of the line segments
	//----------------------
	double x12 = (x1 + x2) / 2;
	double y12 = (y1 + y2) / 2;
	double x23 = (x2 + x3) / 2;
	double y23 = (y2 + y3) / 2;
	double x34 = (x3 + x4) / 2;
	double y34 = (y3 + y4) / 2;
	double x123 = (x12 + x23) / 2;
	double y123 = (y12 + y23) / 2;
	double x234 = (x23 + x34) / 2;
	double y234 = (y23 + y34) / 2;
	double x1234 = (x123 + x234) / 2;
	double y1234 = (y123 + y234) / 2;


	// Try to approximate the full cubic curve by a single straight line
	//------------------
	double dx = x4-x1;
	double dy = y4-y1;

	double d2 = fabs(((x2 - x4) * dy - (y2 - y4) * dx));
	double d3 = fabs(((x3 - x4) * dy - (y3 - y4) * dx));
	double da1, da2, k;

	switch((int(d2 > curve_collinearity_epsilon) << 1) +
	int(d3 > curve_collinearity_epsilon))
	{
	case 0:
	// All collinear OR p1==p4
	//----------------------
	k = dxdx + dydy;
	if(k == 0)
	{
	d2 = calc_sq_distance(x1, y1, x2, y2);
	d3 = calc_sq_distance(x4, y4, x3, y3);
	}
	else
	{
	k = 1 / k;
	da1 = x2 - x1;
	da2 = y2 - y1;
	d2 = k * (da1dx + da2dy);
	da1 = x3 - x1;
	da2 = y3 - y1;
	d3 = k * (da1dx + da2dy);
	if(d2 > 0 && d2 < 1 && d3 > 0 && d3 < 1)
	{
	// Simple collinear case, 1---2---3---4
	// We can leave just two endpoints
	return;
	}
	if(d2 <= 0) d2 = calc_sq_distance(x2, y2, x1, y1);
	else if(d2 >= 1) d2 = calc_sq_distance(x2, y2, x4, y4);
	else d2 = calc_sq_distance(x2, y2, x1 + d2dx, y1 + d2dy);

	if(d3 <= 0) d3 = calc_sq_distance(x3, y3, x1, y1);
	else if(d3 >= 1) d3 = calc_sq_distance(x3, y3, x4, y4);
	else d3 = calc_sq_distance(x3, y3, x1 + d3dx, y1 + d3dy);
	}
	if(d2 > d3)
	{
	if(d2 < m_distance_tolerance_square)
	{
	m_points.add(point_d(x2, y2));
	return;
	}
	}
	else
	{
	if(d3 < m_distance_tolerance_square)
	{
	m_points.add(point_d(x3, y3));
	return;
	}
	}
	break;

	case 1:
	// p1,p2,p4 are collinear, p3 is significant
	//----------------------
	if(d3 * d3 <= m_distance_tolerance_square * (dxdx + dydy))
	{
	if(m_angle_tolerance < curve_angle_tolerance_epsilon)
	{
	m_points.add(point_d(x23, y23));
	return;
	}

	// Angle Condition
	//----------------------
	da1 = fabs(atan2(y4 - y3, x4 - x3) - atan2(y3 - y2, x3 - x2));
	if(da1 >= pi) da1 = 2*pi - da1;

	if(da1 < m_angle_tolerance)
	{
	m_points.add(point_d(x2, y2));
	m_points.add(point_d(x3, y3));
	return;
	}

	if(m_cusp_limit != 0.0)
	{
	if(da1 > m_cusp_limit)
	{
	m_points.add(point_d(x3, y3));
	return;
	}
	}
	}
	break;

	case 2:
	// p1,p3,p4 are collinear, p2 is significant
	//----------------------
	if(d2 * d2 <= m_distance_tolerance_square * (dxdx + dydy))
	{
	if(m_angle_tolerance < curve_angle_tolerance_epsilon)
	{
	m_points.add(point_d(x23, y23));
	return;
	}

	// Angle Condition
	//----------------------
	da1 = fabs(atan2(y3 - y2, x3 - x2) - atan2(y2 - y1, x2 - x1));
	if(da1 >= pi) da1 = 2*pi - da1;

	if(da1 < m_angle_tolerance)
	{
	m_points.add(point_d(x2, y2));
	m_points.add(point_d(x3, y3));
	return;
	}

	if(m_cusp_limit != 0.0)
	{
	if(da1 > m_cusp_limit)
	{
	m_points.add(point_d(x2, y2));
	return;
	}
	}
	}
	break;

	case 3:
	// Regular case
	//-----------------
	if((d2 + d3)(d2 + d3) <= m_distance_tolerance_square (dxdx + dydy))
	{
	// If the curvature doesn't exceed the distance_tolerance value
	// we tend to finish subdivisions.
	//----------------------
	if(m_angle_tolerance < curve_angle_tolerance_epsilon)
	{
	m_points.add(point_d(x23, y23));
	return;
	}

	// Angle & Cusp Condition
	//----------------------
	k = atan2(y3 - y2, x3 - x2);
	da1 = fabs(k - atan2(y2 - y1, x2 - x1));
	da2 = fabs(atan2(y4 - y3, x4 - x3) - k);
	if(da1 >= pi) da1 = 2*pi - da1;
	if(da2 >= pi) da2 = 2*pi - da2;

	if(da1 + da2 < m_angle_tolerance)
	{
	// Finally we can stop the recursion
	//----------------------
	m_points.add(point_d(x23, y23));
	return;
	}

	if(m_cusp_limit != 0.0)
	{
	if(da1 > m_cusp_limit)
	{
	m_points.add(point_d(x2, y2));
	return;
	}

	if(da2 > m_cusp_limit)
	{
	m_points.add(point_d(x3, y3));
	return;
	}
	}
	}
	break;
	}

	// Continue subdivision
	//----------------------
	recursive_bezier(x1, y1, x12, y12, x123, y123, x1234, y1234, level + 1);
	recursive_bezier(x1234, y1234, x234, y234, x34, y34, x4, y4, level + 1);
	}

	//------------------------------------------------------------------------
	void curve4_div::bezier(double x1, double y1,
	double x2, double y2,
	double x3, double y3,
	double x4, double y4)
	{
	m_points.add(point_d(x1, y1));
	recursive_bezier(x1, y1, x2, y2, x3, y3, x4, y4, 0);
	m_points.add(point_d(x4, y4));
	}

	}