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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
	//----------------------------------------------------------------------------

	#ifndef AGG_BASICS_INCLUDED
	#define AGG_BASICS_INCLUDED

	#include <math.h>
	#include "agg_config.h"

	//---------------------------------------------------------AGG_CUSTOM_ALLOCATOR
	#ifdef AGG_CUSTOM_ALLOCATOR
	#include "agg_allocator.h"
	#else
	namespace agg
	{
	// The policy of all AGG containers and memory allocation strategy
	// in general is that no allocated data requires explicit construction.
	// It means that the allocator can be really simple; you can even
	// replace new/delete to malloc/free. The constructors and destructors
	// won't be called in this case, however everything will remain working.
	// The second argument of deallocate() is the size of the allocated
	// block. You can use this information if you wish.
	//------------------------------------------------------------pod_allocator
	template<class T> struct pod_allocator
	{
	static T* allocate(unsigned num) { return new T [num]; }
	static void deallocate(T* ptr, unsigned) { delete [] ptr; }
	};

	// Single object allocator. It's also can be replaced with your custom
	// allocator. The difference is that it can only allocate a single
	// object and the constructor and destructor must be called.
	// In AGG there is no need to allocate an array of objects with
	// calling their constructors (only single ones). So that, if you
	// replace these new/delete to malloc/free make sure that the in-place
	// new is called and take care of calling the destructor too.
	//------------------------------------------------------------obj_allocator
	template<class T> struct obj_allocator
	{
	static T* allocate() { return new T; }
	static void deallocate(T* ptr) { delete ptr; }
	};
	}
	#endif


	//-------------------------------------------------------- Default basic types
	//
	// If the compiler has different capacity of the basic types you can redefine
	// them via the compiler command line or by generating agg_config.h that is
	// empty by default.
	//
	#ifndef AGG_INT8
	#define AGG_INT8 signed char
	#endif

	#ifndef AGG_INT8U
	#define AGG_INT8U unsigned char
	#endif

	#ifndef AGG_INT16
	#define AGG_INT16 short
	#endif

	#ifndef AGG_INT16U
	#define AGG_INT16U unsigned short
	#endif

	#ifndef AGG_INT32
	#define AGG_INT32 int
	#endif

	#ifndef AGG_INT32U
	#define AGG_INT32U unsigned
	#endif

	#ifndef AGG_INT64
	#if defined(_MSC_VER) \|\| defined(__BORLANDC__)
	#define AGG_INT64 signed __int64
	#else
	#define AGG_INT64 signed long long
	#endif
	#endif

	#ifndef AGG_INT64U
	#if defined(_MSC_VER) \|\| defined(__BORLANDC__)
	#define AGG_INT64U unsigned __int64
	#else
	#define AGG_INT64U unsigned long long
	#endif
	#endif

	//------------------------------------------------ Some fixes for MS Visual C++
	#if defined(_MSC_VER)
	#pragma warning(disable:4786) // Identifier was truncated...
	#endif

	#if defined(_MSC_VER)
	#define AGG_INLINE __forceinline
	#else
	#define AGG_INLINE inline
	#endif

	namespace agg
	{
	//-------------------------------------------------------------------------
	typedef AGG_INT8 int8; //----int8
	typedef AGG_INT8U int8u; //----int8u
	typedef AGG_INT16 int16; //----int16
	typedef AGG_INT16U int16u; //----int16u
	typedef AGG_INT32 int32; //----int32
	typedef AGG_INT32U int32u; //----int32u
	typedef AGG_INT64 int64; //----int64
	typedef AGG_INT64U int64u; //----int64u

	#if defined(AGG_FISTP)
	#pragma warning(push)
	#pragma warning(disable : 4035) //Disable warning "no return value"
	AGG_INLINE int iround(double v) //-------iround
	{
	int t;
	__asm fld qword ptr [v]
	__asm fistp dword ptr [t]
	__asm mov eax, dword ptr [t]
	}
	AGG_INLINE unsigned uround(double v) //-------uround
	{
	unsigned t;
	__asm fld qword ptr [v]
	__asm fistp dword ptr [t]
	__asm mov eax, dword ptr [t]
	}
	#pragma warning(pop)
	AGG_INLINE int ifloor(double v)
	{
	return int(floor(v));
	}
	AGG_INLINE unsigned ufloor(double v) //-------ufloor
	{
	return unsigned(floor(v));
	}
	AGG_INLINE int iceil(double v)
	{
	return int(ceil(v));
	}
	AGG_INLINE unsigned uceil(double v) //--------uceil
	{
	return unsigned(ceil(v));
	}
	#elif defined(AGG_QIFIST)
	AGG_INLINE int iround(double v)
	{
	return int(v);
	}
	AGG_INLINE int uround(double v)
	{
	return unsigned(v);
	}
	AGG_INLINE int ifloor(double v)
	{
	return int(floor(v));
	}
	AGG_INLINE unsigned ufloor(double v)
	{
	return unsigned(floor(v));
	}
	AGG_INLINE int iceil(double v)
	{
	return int(ceil(v));
	}
	AGG_INLINE unsigned uceil(double v)
	{
	return unsigned(ceil(v));
	}
	#else
	AGG_INLINE int iround(double v)
	{
	return int((v < 0.0) ? v - 0.5 : v + 0.5);
	}
	AGG_INLINE int uround(double v)
	{
	return unsigned(v + 0.5);
	}
	AGG_INLINE int ifloor(double v)
	{
	int i = int(v);
	return i - (i > v);
	}
	AGG_INLINE unsigned ufloor(double v)
	{
	return unsigned(v);
	}
	AGG_INLINE int iceil(double v)
	{
	return int(ceil(v));
	}
	AGG_INLINE unsigned uceil(double v)
	{
	return unsigned(ceil(v));
	}
	#endif

	//---------------------------------------------------------------saturation
	template<int Limit> struct saturation
	{
	AGG_INLINE static int iround(double v)
	{
	if(v < double(-Limit)) return -Limit;
	if(v > double( Limit)) return Limit;
	return agg::iround(v);
	}
	};

	//------------------------------------------------------------------mul_one
	template<unsigned Shift> struct mul_one
	{
	AGG_INLINE static unsigned mul(unsigned a, unsigned b)
	{
	unsigned q = a * b + (1 << (Shift-1));
	return (q + (q >> Shift)) >> Shift;
	}
	};

	//-------------------------------------------------------------------------
	typedef unsigned char cover_type; //----cover_type
	enum cover_scale_e
	{
	cover_shift = 8, //----cover_shift
	cover_size = 1 << cover_shift, //----cover_size
	cover_mask = cover_size - 1, //----cover_mask
	cover_none = 0, //----cover_none
	cover_full = cover_mask //----cover_full
	};

	//----------------------------------------------------poly_subpixel_scale_e
	// These constants determine the subpixel accuracy, to be more precise,
	// the number of bits of the fractional part of the coordinates.
	// The possible coordinate capacity in bits can be calculated by formula:
	// sizeof(int) * 8 - poly_subpixel_shift, i.e, for 32-bit integers and
	// 8-bits fractional part the capacity is 24 bits.
	enum poly_subpixel_scale_e
	{
	poly_subpixel_shift = 8, //----poly_subpixel_shift
	poly_subpixel_scale = 1<<poly_subpixel_shift, //----poly_subpixel_scale
	poly_subpixel_mask = poly_subpixel_scale-1 //----poly_subpixel_mask
	};

	//----------------------------------------------------------filling_rule_e
	enum filling_rule_e
	{
	fill_non_zero,
	fill_even_odd
	};

	//-----------------------------------------------------------------------pi
	const double pi = 3.14159265358979323846;

	//------------------------------------------------------------------deg2rad
	inline double deg2rad(double deg)
	{
	return deg * pi / 180.0;
	}

	//------------------------------------------------------------------rad2deg
	inline double rad2deg(double rad)
	{
	return rad * 180.0 / pi;
	}

	//----------------------------------------------------------------rect_base
	template<class T> struct rect_base
	{
	typedef T value_type;
	typedef rect_base<T> self_type;
	T x1, y1, x2, y2;

	rect_base() {}
	rect_base(T x1_, T y1_, T x2_, T y2_) :
	x1(x1_), y1(y1_), x2(x2_), y2(y2_) {}

	void init(T x1_, T y1_, T x2_, T y2_)
	{
	x1 = x1_; y1 = y1_; x2 = x2_; y2 = y2_;
	}

	const self_type& normalize()
	{
	T t;
	if(x1 > x2) { t = x1; x1 = x2; x2 = t; }
	if(y1 > y2) { t = y1; y1 = y2; y2 = t; }
	return *this;
	}

	bool clip(const self_type& r)
	{
	if(x2 > r.x2) x2 = r.x2;
	if(y2 > r.y2) y2 = r.y2;
	if(x1 < r.x1) x1 = r.x1;
	if(y1 < r.y1) y1 = r.y1;
	return x1 <= x2 && y1 <= y2;
	}

	bool is_valid() const
	{
	return x1 <= x2 && y1 <= y2;
	}

	bool hit_test(T x, T y) const
	{
	return (x >= x1 && x <= x2 && y >= y1 && y <= y2);
	}

	bool overlaps(const self_type& r) const
	{
	return !(r.x1 > x2 \|\| r.x2 < x1
	\|\| r.y1 > y2 \|\| r.y2 < y1);
	}
	};

	//-----------------------------------------------------intersect_rectangles
	template<class Rect>
	inline Rect intersect_rectangles(const Rect& r1, const Rect& r2)
	{
	Rect r = r1;

	// First process x2,y2 because the other order
	// results in Internal Compiler Error under
	// Microsoft Visual C++ .NET 2003 69462-335-0000007-18038 in
	// case of "Maximize Speed" optimization option.
	//-----------------
	if(r.x2 > r2.x2) r.x2 = r2.x2;
	if(r.y2 > r2.y2) r.y2 = r2.y2;
	if(r.x1 < r2.x1) r.x1 = r2.x1;
	if(r.y1 < r2.y1) r.y1 = r2.y1;
	return r;
	}


	//---------------------------------------------------------unite_rectangles
	template<class Rect>
	inline Rect unite_rectangles(const Rect& r1, const Rect& r2)
	{
	Rect r = r1;
	if(r.x2 < r2.x2) r.x2 = r2.x2;
	if(r.y2 < r2.y2) r.y2 = r2.y2;
	if(r.x1 > r2.x1) r.x1 = r2.x1;
	if(r.y1 > r2.y1) r.y1 = r2.y1;
	return r;
	}

	typedef rect_base<int> rect_i; //----rect_i
	typedef rect_base<float> rect_f; //----rect_f
	typedef rect_base<double> rect_d; //----rect_d

	//---------------------------------------------------------path_commands_e
	enum path_commands_e
	{
	path_cmd_stop = 0, //----path_cmd_stop
	path_cmd_move_to = 1, //----path_cmd_move_to
	path_cmd_line_to = 2, //----path_cmd_line_to
	path_cmd_curve3 = 3, //----path_cmd_curve3
	path_cmd_curve4 = 4, //----path_cmd_curve4
	path_cmd_curveN = 5, //----path_cmd_curveN
	path_cmd_catrom = 6, //----path_cmd_catrom
	path_cmd_ubspline = 7, //----path_cmd_ubspline
	path_cmd_end_poly = 0x0F, //----path_cmd_end_poly
	path_cmd_mask = 0x0F //----path_cmd_mask
	};

	//------------------------------------------------------------path_flags_e
	enum path_flags_e
	{
	path_flags_none = 0, //----path_flags_none
	path_flags_ccw = 0x10, //----path_flags_ccw
	path_flags_cw = 0x20, //----path_flags_cw
	path_flags_close = 0x40, //----path_flags_close
	path_flags_mask = 0xF0 //----path_flags_mask
	};

	//---------------------------------------------------------------is_vertex
	inline bool is_vertex(unsigned c)
	{
	return c >= path_cmd_move_to && c < path_cmd_end_poly;
	}

	//--------------------------------------------------------------is_drawing
	inline bool is_drawing(unsigned c)
	{
	return c >= path_cmd_line_to && c < path_cmd_end_poly;
	}

	//-----------------------------------------------------------------is_stop
	inline bool is_stop(unsigned c)
	{
	return c == path_cmd_stop;
	}

	//--------------------------------------------------------------is_move_to
	inline bool is_move_to(unsigned c)
	{
	return c == path_cmd_move_to;
	}

	//--------------------------------------------------------------is_line_to
	inline bool is_line_to(unsigned c)
	{
	return c == path_cmd_line_to;
	}

	//----------------------------------------------------------------is_curve
	inline bool is_curve(unsigned c)
	{
	return c == path_cmd_curve3 \|\| c == path_cmd_curve4;
	}

	//---------------------------------------------------------------is_curve3
	inline bool is_curve3(unsigned c)
	{
	return c == path_cmd_curve3;
	}

	//---------------------------------------------------------------is_curve4
	inline bool is_curve4(unsigned c)
	{
	return c == path_cmd_curve4;
	}

	//-------------------------------------------------------------is_end_poly
	inline bool is_end_poly(unsigned c)
	{
	return (c & path_cmd_mask) == path_cmd_end_poly;
	}

	//----------------------------------------------------------------is_close
	inline bool is_close(unsigned c)
	{
	return (c & ~(path_flags_cw \| path_flags_ccw)) ==
	(path_cmd_end_poly \| path_flags_close);
	}

	//------------------------------------------------------------is_next_poly
	inline bool is_next_poly(unsigned c)
	{
	return is_stop(c) \|\| is_move_to(c) \|\| is_end_poly(c);
	}

	//-------------------------------------------------------------------is_cw
	inline bool is_cw(unsigned c)
	{
	return (c & path_flags_cw) != 0;
	}

	//------------------------------------------------------------------is_ccw
	inline bool is_ccw(unsigned c)
	{
	return (c & path_flags_ccw) != 0;
	}

	//-------------------------------------------------------------is_oriented
	inline bool is_oriented(unsigned c)
	{
	return (c & (path_flags_cw \| path_flags_ccw)) != 0;
	}

	//---------------------------------------------------------------is_closed
	inline bool is_closed(unsigned c)
	{
	return (c & path_flags_close) != 0;
	}

	//----------------------------------------------------------get_close_flag
	inline unsigned get_close_flag(unsigned c)
	{
	return c & path_flags_close;
	}

	//-------------------------------------------------------clear_orientation
	inline unsigned clear_orientation(unsigned c)
	{
	return c & ~(path_flags_cw \| path_flags_ccw);
	}

	//---------------------------------------------------------get_orientation
	inline unsigned get_orientation(unsigned c)
	{
	return c & (path_flags_cw \| path_flags_ccw);
	}

	//---------------------------------------------------------set_orientation
	inline unsigned set_orientation(unsigned c, unsigned o)
	{
	return clear_orientation(c) \| o;
	}

	//--------------------------------------------------------------point_base
	template<class T> struct point_base
	{
	typedef T value_type;
	T x,y;
	point_base() {}
	point_base(T x_, T y_) : x(x_), y(y_) {}
	};
	typedef point_base<int> point_i; //-----point_i
	typedef point_base<float> point_f; //-----point_f
	typedef point_base<double> point_d; //-----point_d

	//-------------------------------------------------------------vertex_base
	template<class T> struct vertex_base
	{
	typedef T value_type;
	T x,y;
	unsigned cmd;
	vertex_base() {}
	vertex_base(T x_, T y_, unsigned cmd_) : x(x_), y(y_), cmd(cmd_) {}
	};
	typedef vertex_base<int> vertex_i; //-----vertex_i
	typedef vertex_base<float> vertex_f; //-----vertex_f
	typedef vertex_base<double> vertex_d; //-----vertex_d

	//----------------------------------------------------------------row_info
	template<class T> struct row_info
	{
	int x1, x2;
	T* ptr;
	row_info() {}
	row_info(int x1_, int x2_, T* ptr_) : x1(x1_), x2(x2_), ptr(ptr_) {}
	};

	//----------------------------------------------------------const_row_info
	template<class T> struct const_row_info
	{
	int x1, x2;
	const T* ptr;
	const_row_info() {}
	const_row_info(int x1_, int x2_, const T* ptr_) :
	x1(x1_), x2(x2_), ptr(ptr_) {}
	};

	//------------------------------------------------------------is_equal_eps
	template<class T> inline bool is_equal_eps(T v1, T v2, T epsilon)
	{
	return fabs(v1 - v2) <= double(epsilon);
	}
	}


	#endif