core/fxcrt/fx_coordinates.h - pdfium - Git at Google

 // Copyright 2014 PDFium Authors. All rights reserved.
 // Use of this source code is governed by a BSD-style license that can be
 // found in the LICENSE file.

 // Original code copyright 2014 Foxit Software Inc. http://www.foxitsoftware.com

 #ifndef CORE_FXCRT_FX_COORDINATES_H_
 #define CORE_FXCRT_FX_COORDINATES_H_

 #include <algorithm>

 #include "core/fxcrt/fx_system.h"

 #ifndef NDEBUG
 #include <ostream>
 #endif

 template <class BaseType>
 class CFX_PTemplate {
  public:
   CFX_PTemplate() : x(0), y(0) {}
   CFX_PTemplate(BaseType new_x, BaseType new_y) : x(new_x), y(new_y) {}
   CFX_PTemplate(const CFX_PTemplate& other) : x(other.x), y(other.y) {}

   CFX_PTemplate& operator=(const CFX_PTemplate& other) {
     if (this != &other) {
       x = other.x;
       y = other.y;
     }
     return *this;
   }
   bool operator==(const CFX_PTemplate& other) const {
     return x == other.x && y == other.y;
   }
   bool operator!=(const CFX_PTemplate& other) const {
     return !(*this == other);
   }
   CFX_PTemplate& operator+=(const CFX_PTemplate<BaseType>& obj) {
     x += obj.x;
     y += obj.y;
     return *this;
   }
   CFX_PTemplate& operator-=(const CFX_PTemplate<BaseType>& obj) {
     x -= obj.x;
     y -= obj.y;
     return *this;
   }
   CFX_PTemplate operator+(const CFX_PTemplate& other) const {
     return CFX_PTemplate(x + other.x, y + other.y);
   }
   CFX_PTemplate operator-(const CFX_PTemplate& other) const {
     return CFX_PTemplate(x - other.x, y - other.y);
   }

   BaseType x;
   BaseType y;
 };
 using CFX_Point16 = CFX_PTemplate<int16_t>;
 using CFX_Point = CFX_PTemplate<int32_t>;
 using CFX_PointF = CFX_PTemplate<float>;

 template <class BaseType>
 class CFX_STemplate {
  public:
   CFX_STemplate() : width(0), height(0) {}

   CFX_STemplate(BaseType new_width, BaseType new_height)
       : width(new_width), height(new_height) {}

   CFX_STemplate(const CFX_STemplate& other)
       : width(other.width), height(other.height) {}

   template <typename OtherType>
   CFX_STemplate<OtherType> As() const {
     return CFX_STemplate<OtherType>(static_cast<OtherType>(width),
                                     static_cast<OtherType>(height));
   }

   void clear() {
     width = 0;
     height = 0;
   }
   CFX_STemplate& operator=(const CFX_STemplate& other) {
     if (this != &other) {
       width = other.width;
       height = other.height;
     }
     return *this;
   }
   bool operator==(const CFX_STemplate& other) const {
     return width == other.width && height == other.height;
   }
   bool operator!=(const CFX_STemplate& other) const {
     return !(*this == other);
   }
   CFX_STemplate& operator+=(const CFX_STemplate<BaseType>& obj) {
     width += obj.width;
     height += obj.height;
     return *this;
   }
   CFX_STemplate& operator-=(const CFX_STemplate<BaseType>& obj) {
     width -= obj.width;
     height -= obj.height;
     return *this;
   }
   CFX_STemplate& operator*=(BaseType factor) {
     width *= factor;
     height *= factor;
     return *this;
   }
   CFX_STemplate& operator/=(BaseType divisor) {
     width /= divisor;
     height /= divisor;
     return *this;
   }
   CFX_STemplate operator+(const CFX_STemplate& other) const {
     return CFX_STemplate(width + other.width, height + other.height);
   }
   CFX_STemplate operator-(const CFX_STemplate& other) const {
     return CFX_STemplate(width - other.width, height - other.height);
   }
   CFX_STemplate operator*(BaseType factor) const {
     return CFX_STemplate(width * factor, height * factor);
   }
   CFX_STemplate operator/(BaseType divisor) const {
     return CFX_STemplate(width / divisor, height / divisor);
   }

   BaseType width;
   BaseType height;
 };
 using CFX_Size = CFX_STemplate<int32_t>;
 using CFX_SizeF = CFX_STemplate<float>;

 template <class BaseType>
 class CFX_VTemplate final : public CFX_PTemplate<BaseType> {
  public:
   using CFX_PTemplate<BaseType>::x;
   using CFX_PTemplate<BaseType>::y;

   CFX_VTemplate() : CFX_PTemplate<BaseType>() {}
   CFX_VTemplate(BaseType new_x, BaseType new_y)
       : CFX_PTemplate<BaseType>(new_x, new_y) {}

   CFX_VTemplate(const CFX_VTemplate& other) : CFX_PTemplate<BaseType>(other) {}

   CFX_VTemplate(const CFX_PTemplate<BaseType>& point1,
                 const CFX_PTemplate<BaseType>& point2)
       : CFX_PTemplate<BaseType>(point2.x - point1.x, point2.y - point1.y) {}

   float Length() const { return sqrt(x * x + y * y); }
   void Normalize() {
     float fLen = Length();
     if (fLen < 0.0001f)
       return;

     x /= fLen;
     y /= fLen;
   }
   void Translate(BaseType dx, BaseType dy) {
     x += dx;
     y += dy;
   }
   void Scale(BaseType sx, BaseType sy) {
     x *= sx;
     y *= sy;
   }
   void Rotate(float fRadian) {
     float cosValue = cos(fRadian);
     float sinValue = sin(fRadian);
     x = x * cosValue - y * sinValue;
     y = x * sinValue + y * cosValue;
   }
 };
 using CFX_Vector = CFX_VTemplate<int32_t>;
 using CFX_VectorF = CFX_VTemplate<float>;

 // Rectangles.
 // TODO(tsepez): Consolidate all these different rectangle classes.

 // LTRB rectangles (y-axis runs downwards).
 // Struct layout is compatible with win32 RECT.
 struct FX_RECT {
   FX_RECT() = default;
   FX_RECT(int l, int t, int r, int b) : left(l), top(t), right(r), bottom(b) {}

   int Width() const { return right - left; }
   int Height() const { return bottom - top; }
   bool IsEmpty() const { return right <= left || bottom <= top; }

   bool Valid() const;

   void Normalize();
   void Intersect(const FX_RECT& src);
   void Intersect(int l, int t, int r, int b) { Intersect(FX_RECT(l, t, r, b)); }

   void Offset(int dx, int dy) {
     left += dx;
     right += dx;
     top += dy;
     bottom += dy;
   }

   bool operator==(const FX_RECT& src) const {
     return left == src.left && right == src.right && top == src.top &&
            bottom == src.bottom;
   }

   bool Contains(int x, int y) const {
     return x >= left && x < right && y >= top && y < bottom;
   }

   int32_t left = 0;
   int32_t top = 0;
   int32_t right = 0;
   int32_t bottom = 0;
 };

 // LTRB rectangles (y-axis runs upwards).
 class CFX_FloatRect {
  public:
   constexpr CFX_FloatRect() = default;
   constexpr CFX_FloatRect(float l, float b, float r, float t)
       : left(l), bottom(b), right(r), top(t) {}

   explicit CFX_FloatRect(const float* pArray)
       : CFX_FloatRect(pArray[0], pArray[1], pArray[2], pArray[3]) {}

   explicit CFX_FloatRect(const FX_RECT& rect);

   static CFX_FloatRect GetBBox(const CFX_PointF* pPoints, int nPoints);

   void Normalize();

   bool IsEmpty() const { return left >= right || bottom >= top; }
   bool Contains(const CFX_PointF& point) const;
   bool Contains(const CFX_FloatRect& other_rect) const;

   void Intersect(const CFX_FloatRect& other_rect);
   void Union(const CFX_FloatRect& other_rect);

   // These may be better at rounding than ToFxRect() and friends.
   //
   // Returned rect has bounds rounded up/down such that it is contained in the
   // original.
   FX_RECT GetInnerRect() const;

   // Returned rect has bounds rounded up/down such that the original is
   // contained in it.
   FX_RECT GetOuterRect() const;

   // Returned rect has bounds rounded up/down such that the dimensions are
   // rounded up and the sum of the error in the bounds is minimized.
   FX_RECT GetClosestRect() const;

   CFX_FloatRect GetCenterSquare() const;

   void InitRect(const CFX_PointF& point) {
     left = point.x;
     right = point.x;
     bottom = point.y;
     top = point.y;
   }
   void UpdateRect(const CFX_PointF& point);

   float Width() const { return right - left; }
   float Height() const { return top - bottom; }
   float Left() const { return left; }
   float Bottom() const { return bottom; }
   float Right() const { return right; }
   float Top() const { return top; }

   void Inflate(float x, float y);
   void Inflate(float other_left,
                float other_bottom,
                float other_right,
                float other_top);
   void Inflate(const CFX_FloatRect& rt);

   void Deflate(float x, float y);
   void Deflate(float other_left,
                float other_bottom,
                float other_right,
                float other_top);
   void Deflate(const CFX_FloatRect& rt);

   CFX_FloatRect GetDeflated(float x, float y) const;

   void Translate(float e, float f);

   void Scale(float fScale);
   void ScaleFromCenterPoint(float fScale);

   // GetInnerRect() and friends may be better at rounding than these methods.
   // Unlike the methods above, these two blindly floor / round the LBRT values.
   // Doing so may introduce rounding errors that are visible to users as
   // off-by-one pixels/lines.
   //
   // Floors LBRT values.
   FX_RECT ToFxRect() const;

   // Rounds LBRT values.
   FX_RECT ToRoundedFxRect() const;

   float left = 0.0f;
   float bottom = 0.0f;
   float right = 0.0f;
   float top = 0.0f;
 };

 #ifndef NDEBUG
 std::ostream& operator<<(std::ostream& os, const CFX_FloatRect& rect);
 #endif

 // LTWH rectangles (y-axis runs downwards).
 class CFX_RectF {
  public:
   using PointType = CFX_PointF;
   using SizeType = CFX_SizeF;

   CFX_RectF() = default;
   CFX_RectF(float dst_left, float dst_top, float dst_width, float dst_height)
       : left(dst_left), top(dst_top), width(dst_width), height(dst_height) {}
   CFX_RectF(float dst_left, float dst_top, const SizeType& dst_size)
       : left(dst_left),
         top(dst_top),
         width(dst_size.width),
         height(dst_size.height) {}
   CFX_RectF(const PointType& p, float dst_width, float dst_height)
       : left(p.x), top(p.y), width(dst_width), height(dst_height) {}
   CFX_RectF(const PointType& p1, const SizeType& s2)
       : left(p1.x), top(p1.y), width(s2.width), height(s2.height) {}
   explicit CFX_RectF(const FX_RECT& that)
       : left(static_cast<float>(that.left)),
         top(static_cast<float>(that.top)),
         width(static_cast<float>(that.Width())),
         height(static_cast<float>(that.Height())) {}

   // NOLINTNEXTLINE(runtime/explicit)
   CFX_RectF(const CFX_RectF& other) = default;

   CFX_RectF& operator+=(const PointType& p) {
     left += p.x;
     top += p.y;
     return *this;
   }
   CFX_RectF& operator-=(const PointType& p) {
     left -= p.x;
     top -= p.y;
     return *this;
   }
   float right() const { return left + width; }
   float bottom() const { return top + height; }
   void Normalize() {
     if (width < 0) {
       left += width;
       width = -width;
     }
     if (height < 0) {
       top += height;
       height = -height;
     }
   }
   void Offset(float dx, float dy) {
     left += dx;
     top += dy;
   }
   void Inflate(float x, float y) {
     left -= x;
     width += x * 2;
     top -= y;
     height += y * 2;
   }
   void Inflate(const PointType& p) { Inflate(p.x, p.y); }
   void Inflate(float off_left,
                float off_top,
                float off_right,
                float off_bottom) {
     left -= off_left;
     top -= off_top;
     width += off_left + off_right;
     height += off_top + off_bottom;
   }
   void Inflate(const CFX_RectF& rt) {
     Inflate(rt.left, rt.top, rt.left + rt.width, rt.top + rt.height);
   }
   void Deflate(float x, float y) {
     left += x;
     width -= x * 2;
     top += y;
     height -= y * 2;
   }
   void Deflate(const PointType& p) { Deflate(p.x, p.y); }
   void Deflate(float off_left,
                float off_top,
                float off_right,
                float off_bottom) {
     left += off_left;
     top += off_top;
     width -= off_left + off_right;
     height -= off_top + off_bottom;
   }
   void Deflate(const CFX_RectF& rt) {
     Deflate(rt.left, rt.top, rt.top + rt.width, rt.top + rt.height);
   }
   bool IsEmpty() const { return width <= 0 || height <= 0; }
   bool IsEmpty(float fEpsilon) const {
     return width <= fEpsilon || height <= fEpsilon;
   }
   void Empty() { width = height = 0; }
   bool Contains(const PointType& p) const {
     return p.x >= left && p.x < left + width && p.y >= top &&
            p.y < top + height;
   }
   bool Contains(const CFX_RectF& rt) const {
     return rt.left >= left && rt.right() <= right() && rt.top >= top &&
            rt.bottom() <= bottom();
   }
   float Left() const { return left; }
   float Top() const { return top; }
   float Width() const { return width; }
   float Height() const { return height; }
   SizeType Size() const { return SizeType(width, height); }
   PointType TopLeft() const { return PointType(left, top); }
   PointType TopRight() const { return PointType(left + width, top); }
   PointType BottomLeft() const { return PointType(left, top + height); }
   PointType BottomRight() const {
     return PointType(left + width, top + height);
   }
   PointType Center() const {
     return PointType(left + width / 2, top + height / 2);
   }
   void Union(float x, float y) {
     float r = right();
     float b = bottom();

     left = std::min(left, x);
     top = std::min(top, y);
     r = std::max(r, x);
     b = std::max(b, y);

     width = r - left;
     height = b - top;
   }
   void Union(const PointType& p) { Union(p.x, p.y); }
   void Union(const CFX_RectF& rt) {
     float r = right();
     float b = bottom();

     left = std::min(left, rt.left);
     top = std::min(top, rt.top);
     r = std::max(r, rt.right());
     b = std::max(b, rt.bottom());

     width = r - left;
     height = b - top;
   }
   void Intersect(const CFX_RectF& rt) {
     float r = right();
     float b = bottom();

     left = std::max(left, rt.left);
     top = std::max(top, rt.top);
     r = std::min(r, rt.right());
     b = std::min(b, rt.bottom());

     width = r - left;
     height = b - top;
   }
   bool IntersectWith(const CFX_RectF& rt) const {
     CFX_RectF rect = rt;
     rect.Intersect(*this);
     return !rect.IsEmpty();
   }
   bool IntersectWith(const CFX_RectF& rt, float fEpsilon) const {
     CFX_RectF rect = rt;
     rect.Intersect(*this);
     return !rect.IsEmpty(fEpsilon);
   }
   friend bool operator==(const CFX_RectF& rc1, const CFX_RectF& rc2) {
     return rc1.left == rc2.left && rc1.top == rc2.top &&
            rc1.width == rc2.width && rc1.height == rc2.height;
   }
   friend bool operator!=(const CFX_RectF& rc1, const CFX_RectF& rc2) {
     return !(rc1 == rc2);
   }

   CFX_FloatRect ToFloatRect() const {
     // Note, we flip top/bottom here because the CFX_FloatRect has the
     // y-axis running in the opposite direction.
     return CFX_FloatRect(left, top, right(), bottom());
   }

   // Returned rect has bounds rounded up/down such that the original is
   // contained in it.
   FX_RECT GetOuterRect() const;

   float left = 0.0f;
   float top = 0.0f;
   float width = 0.0f;
   float height = 0.0f;
 };

 #ifndef NDEBUG
 std::ostream& operator<<(std::ostream& os, const CFX_RectF& rect);
 #endif  // NDEBUG

 // The matrix is of the form:
 // | a  b  0 |
 // | c  d  0 |
 // | e  f  1 |
 // See PDF spec 1.7 Section 4.2.3.
 //
 class CFX_Matrix {
  public:
   CFX_Matrix() = default;

   explicit CFX_Matrix(const float n[6])
       : a(n[0]), b(n[1]), c(n[2]), d(n[3]), e(n[4]), f(n[5]) {}

   CFX_Matrix(float a1, float b1, float c1, float d1, float e1, float f1)
       : a(a1), b(b1), c(c1), d(d1), e(e1), f(f1) {}

   CFX_Matrix(const CFX_Matrix& other) = default;

   CFX_Matrix& operator=(const CFX_Matrix& other) = default;

   bool operator==(const CFX_Matrix& other) const {
     return a == other.a && b == other.b && c == other.c && d == other.d &&
            e == other.e && f == other.f;
   }
   bool operator!=(const CFX_Matrix& other) const { return !(*this == other); }

   CFX_Matrix operator*(const CFX_Matrix& right) const {
     return CFX_Matrix(a * right.a + b * right.c, a * right.b + b * right.d,
                       c * right.a + d * right.c, c * right.b + d * right.d,
                       e * right.a + f * right.c + right.e,
                       e * right.b + f * right.d + right.f);
   }
   CFX_Matrix& operator*=(const CFX_Matrix& other) {
     *this = *this * other;
     return *this;
   }

   bool IsIdentity() const { return *this == CFX_Matrix(); }
   CFX_Matrix GetInverse() const;

   bool Is90Rotated() const;
   bool IsScaled() const;
   bool WillScale() const { return a != 1.0f || b != 0 || c != 0 || d != 1.0f; }

   void Concat(const CFX_Matrix& right) { *this *= right; }
   void Translate(float x, float y);
   void TranslatePrepend(float x, float y);
   void Translate(int32_t x, int32_t y) {
     Translate(static_cast<float>(x), static_cast<float>(y));
   }
   void TranslatePrepend(int32_t x, int32_t y) {
     TranslatePrepend(static_cast<float>(x), static_cast<float>(y));
   }

   void Scale(float sx, float sy);
   void Rotate(float fRadian);

   void MatchRect(const CFX_FloatRect& dest, const CFX_FloatRect& src);

   float GetXUnit() const;
   float GetYUnit() const;
   CFX_FloatRect GetUnitRect() const;

   float TransformXDistance(float dx) const;
   float TransformDistance(float distance) const;

   CFX_PointF Transform(const CFX_PointF& point) const;

   CFX_RectF TransformRect(const CFX_RectF& rect) const;
   CFX_FloatRect TransformRect(const CFX_FloatRect& rect) const;

   float a = 1.0f;
   float b = 0.0f;
   float c = 0.0f;
   float d = 1.0f;
   float e = 0.0f;
   float f = 0.0f;
 };

 #endif  // CORE_FXCRT_FX_COORDINATES_H_
	// Copyright 2014 PDFium Authors. All rights reserved.
	// Use of this source code is governed by a BSD-style license that can be
	// found in the LICENSE file.

	// Original code copyright 2014 Foxit Software Inc. http://www.foxitsoftware.com

	#ifndef CORE_FXCRT_FX_COORDINATES_H_
	#define CORE_FXCRT_FX_COORDINATES_H_

	#include <algorithm>

	#include "core/fxcrt/fx_system.h"

	#ifndef NDEBUG
	#include <ostream>
	#endif

	template <class BaseType>
	class CFX_PTemplate {
	public:
	CFX_PTemplate() : x(0), y(0) {}
	CFX_PTemplate(BaseType new_x, BaseType new_y) : x(new_x), y(new_y) {}
	CFX_PTemplate(const CFX_PTemplate& other) : x(other.x), y(other.y) {}

	CFX_PTemplate& operator=(const CFX_PTemplate& other) {
	if (this != &other) {
	x = other.x;
	y = other.y;
	}
	return *this;
	}
	bool operator==(const CFX_PTemplate& other) const {
	return x == other.x && y == other.y;
	}
	bool operator!=(const CFX_PTemplate& other) const {
	return !(*this == other);
	}
	CFX_PTemplate& operator+=(const CFX_PTemplate<BaseType>& obj) {
	x += obj.x;
	y += obj.y;
	return *this;
	}
	CFX_PTemplate& operator-=(const CFX_PTemplate<BaseType>& obj) {
	x -= obj.x;
	y -= obj.y;
	return *this;
	}
	CFX_PTemplate operator+(const CFX_PTemplate& other) const {
	return CFX_PTemplate(x + other.x, y + other.y);
	}
	CFX_PTemplate operator-(const CFX_PTemplate& other) const {
	return CFX_PTemplate(x - other.x, y - other.y);
	}

	BaseType x;
	BaseType y;
	};
	using CFX_Point16 = CFX_PTemplate<int16_t>;
	using CFX_Point = CFX_PTemplate<int32_t>;
	using CFX_PointF = CFX_PTemplate<float>;

	template <class BaseType>
	class CFX_STemplate {
	public:
	CFX_STemplate() : width(0), height(0) {}

	CFX_STemplate(BaseType new_width, BaseType new_height)
	: width(new_width), height(new_height) {}

	CFX_STemplate(const CFX_STemplate& other)
	: width(other.width), height(other.height) {}

	template <typename OtherType>
	CFX_STemplate<OtherType> As() const {
	return CFX_STemplate<OtherType>(static_cast<OtherType>(width),
	static_cast<OtherType>(height));
	}

	void clear() {
	width = 0;
	height = 0;
	}
	CFX_STemplate& operator=(const CFX_STemplate& other) {
	if (this != &other) {
	width = other.width;
	height = other.height;
	}
	return *this;
	}
	bool operator==(const CFX_STemplate& other) const {
	return width == other.width && height == other.height;
	}
	bool operator!=(const CFX_STemplate& other) const {
	return !(*this == other);
	}
	CFX_STemplate& operator+=(const CFX_STemplate<BaseType>& obj) {
	width += obj.width;
	height += obj.height;
	return *this;
	}
	CFX_STemplate& operator-=(const CFX_STemplate<BaseType>& obj) {
	width -= obj.width;
	height -= obj.height;
	return *this;
	}
	CFX_STemplate& operator*=(BaseType factor) {
	width *= factor;
	height *= factor;
	return *this;
	}
	CFX_STemplate& operator/=(BaseType divisor) {
	width /= divisor;
	height /= divisor;
	return *this;
	}
	CFX_STemplate operator+(const CFX_STemplate& other) const {
	return CFX_STemplate(width + other.width, height + other.height);
	}
	CFX_STemplate operator-(const CFX_STemplate& other) const {
	return CFX_STemplate(width - other.width, height - other.height);
	}
	CFX_STemplate operator*(BaseType factor) const {
	return CFX_STemplate(width * factor, height * factor);
	}
	CFX_STemplate operator/(BaseType divisor) const {
	return CFX_STemplate(width / divisor, height / divisor);
	}

	BaseType width;
	BaseType height;
	};
	using CFX_Size = CFX_STemplate<int32_t>;
	using CFX_SizeF = CFX_STemplate<float>;

	template <class BaseType>
	class CFX_VTemplate final : public CFX_PTemplate<BaseType> {
	public:
	using CFX_PTemplate<BaseType>::x;
	using CFX_PTemplate<BaseType>::y;

	CFX_VTemplate() : CFX_PTemplate<BaseType>() {}
	CFX_VTemplate(BaseType new_x, BaseType new_y)
	: CFX_PTemplate<BaseType>(new_x, new_y) {}

	CFX_VTemplate(const CFX_VTemplate& other) : CFX_PTemplate<BaseType>(other) {}

	CFX_VTemplate(const CFX_PTemplate<BaseType>& point1,
	const CFX_PTemplate<BaseType>& point2)
	: CFX_PTemplate<BaseType>(point2.x - point1.x, point2.y - point1.y) {}

	float Length() const { return sqrt(x * x + y * y); }
	void Normalize() {
	float fLen = Length();
	if (fLen < 0.0001f)
	return;

	x /= fLen;
	y /= fLen;
	}
	void Translate(BaseType dx, BaseType dy) {
	x += dx;
	y += dy;
	}
	void Scale(BaseType sx, BaseType sy) {
	x *= sx;
	y *= sy;
	}
	void Rotate(float fRadian) {
	float cosValue = cos(fRadian);
	float sinValue = sin(fRadian);
	x = x * cosValue - y * sinValue;
	y = x * sinValue + y * cosValue;
	}
	};
	using CFX_Vector = CFX_VTemplate<int32_t>;
	using CFX_VectorF = CFX_VTemplate<float>;

	// Rectangles.
	// TODO(tsepez): Consolidate all these different rectangle classes.

	// LTRB rectangles (y-axis runs downwards).
	// Struct layout is compatible with win32 RECT.
	struct FX_RECT {
	FX_RECT() = default;
	FX_RECT(int l, int t, int r, int b) : left(l), top(t), right(r), bottom(b) {}

	int Width() const { return right - left; }
	int Height() const { return bottom - top; }
	bool IsEmpty() const { return right <= left \|\| bottom <= top; }

	bool Valid() const;

	void Normalize();
	void Intersect(const FX_RECT& src);
	void Intersect(int l, int t, int r, int b) { Intersect(FX_RECT(l, t, r, b)); }

	void Offset(int dx, int dy) {
	left += dx;
	right += dx;
	top += dy;
	bottom += dy;
	}

	bool operator==(const FX_RECT& src) const {
	return left == src.left && right == src.right && top == src.top &&
	bottom == src.bottom;
	}

	bool Contains(int x, int y) const {
	return x >= left && x < right && y >= top && y < bottom;
	}

	int32_t left = 0;
	int32_t top = 0;
	int32_t right = 0;
	int32_t bottom = 0;
	};

	// LTRB rectangles (y-axis runs upwards).
	class CFX_FloatRect {
	public:
	constexpr CFX_FloatRect() = default;
	constexpr CFX_FloatRect(float l, float b, float r, float t)
	: left(l), bottom(b), right(r), top(t) {}

	explicit CFX_FloatRect(const float* pArray)
	: CFX_FloatRect(pArray[0], pArray[1], pArray[2], pArray[3]) {}

	explicit CFX_FloatRect(const FX_RECT& rect);

	static CFX_FloatRect GetBBox(const CFX_PointF* pPoints, int nPoints);

	void Normalize();

	bool IsEmpty() const { return left >= right \|\| bottom >= top; }
	bool Contains(const CFX_PointF& point) const;
	bool Contains(const CFX_FloatRect& other_rect) const;

	void Intersect(const CFX_FloatRect& other_rect);
	void Union(const CFX_FloatRect& other_rect);

	// These may be better at rounding than ToFxRect() and friends.
	//
	// Returned rect has bounds rounded up/down such that it is contained in the
	// original.
	FX_RECT GetInnerRect() const;

	// Returned rect has bounds rounded up/down such that the original is
	// contained in it.
	FX_RECT GetOuterRect() const;

	// Returned rect has bounds rounded up/down such that the dimensions are
	// rounded up and the sum of the error in the bounds is minimized.
	FX_RECT GetClosestRect() const;

	CFX_FloatRect GetCenterSquare() const;

	void InitRect(const CFX_PointF& point) {
	left = point.x;
	right = point.x;
	bottom = point.y;
	top = point.y;
	}
	void UpdateRect(const CFX_PointF& point);

	float Width() const { return right - left; }
	float Height() const { return top - bottom; }
	float Left() const { return left; }
	float Bottom() const { return bottom; }
	float Right() const { return right; }
	float Top() const { return top; }

	void Inflate(float x, float y);
	void Inflate(float other_left,
	float other_bottom,
	float other_right,
	float other_top);
	void Inflate(const CFX_FloatRect& rt);

	void Deflate(float x, float y);
	void Deflate(float other_left,
	float other_bottom,
	float other_right,
	float other_top);
	void Deflate(const CFX_FloatRect& rt);

	CFX_FloatRect GetDeflated(float x, float y) const;

	void Translate(float e, float f);

	void Scale(float fScale);
	void ScaleFromCenterPoint(float fScale);

	// GetInnerRect() and friends may be better at rounding than these methods.
	// Unlike the methods above, these two blindly floor / round the LBRT values.
	// Doing so may introduce rounding errors that are visible to users as
	// off-by-one pixels/lines.
	//
	// Floors LBRT values.
	FX_RECT ToFxRect() const;

	// Rounds LBRT values.
	FX_RECT ToRoundedFxRect() const;

	float left = 0.0f;
	float bottom = 0.0f;
	float right = 0.0f;
	float top = 0.0f;
	};

	#ifndef NDEBUG
	std::ostream& operator<<(std::ostream& os, const CFX_FloatRect& rect);
	#endif

	// LTWH rectangles (y-axis runs downwards).
	class CFX_RectF {
	public:
	using PointType = CFX_PointF;
	using SizeType = CFX_SizeF;

	CFX_RectF() = default;
	CFX_RectF(float dst_left, float dst_top, float dst_width, float dst_height)
	: left(dst_left), top(dst_top), width(dst_width), height(dst_height) {}
	CFX_RectF(float dst_left, float dst_top, const SizeType& dst_size)
	: left(dst_left),
	top(dst_top),
	width(dst_size.width),
	height(dst_size.height) {}
	CFX_RectF(const PointType& p, float dst_width, float dst_height)
	: left(p.x), top(p.y), width(dst_width), height(dst_height) {}
	CFX_RectF(const PointType& p1, const SizeType& s2)
	: left(p1.x), top(p1.y), width(s2.width), height(s2.height) {}
	explicit CFX_RectF(const FX_RECT& that)
	: left(static_cast<float>(that.left)),
	top(static_cast<float>(that.top)),
	width(static_cast<float>(that.Width())),
	height(static_cast<float>(that.Height())) {}

	// NOLINTNEXTLINE(runtime/explicit)
	CFX_RectF(const CFX_RectF& other) = default;

	CFX_RectF& operator+=(const PointType& p) {
	left += p.x;
	top += p.y;
	return *this;
	}
	CFX_RectF& operator-=(const PointType& p) {
	left -= p.x;
	top -= p.y;
	return *this;
	}
	float right() const { return left + width; }
	float bottom() const { return top + height; }
	void Normalize() {
	if (width < 0) {
	left += width;
	width = -width;
	}
	if (height < 0) {
	top += height;
	height = -height;
	}
	}
	void Offset(float dx, float dy) {
	left += dx;
	top += dy;
	}
	void Inflate(float x, float y) {
	left -= x;
	width += x * 2;
	top -= y;
	height += y * 2;
	}
	void Inflate(const PointType& p) { Inflate(p.x, p.y); }
	void Inflate(float off_left,
	float off_top,
	float off_right,
	float off_bottom) {
	left -= off_left;
	top -= off_top;
	width += off_left + off_right;
	height += off_top + off_bottom;
	}
	void Inflate(const CFX_RectF& rt) {
	Inflate(rt.left, rt.top, rt.left + rt.width, rt.top + rt.height);
	}
	void Deflate(float x, float y) {
	left += x;
	width -= x * 2;
	top += y;
	height -= y * 2;
	}
	void Deflate(const PointType& p) { Deflate(p.x, p.y); }
	void Deflate(float off_left,
	float off_top,
	float off_right,
	float off_bottom) {
	left += off_left;
	top += off_top;
	width -= off_left + off_right;
	height -= off_top + off_bottom;
	}
	void Deflate(const CFX_RectF& rt) {
	Deflate(rt.left, rt.top, rt.top + rt.width, rt.top + rt.height);
	}
	bool IsEmpty() const { return width <= 0 \|\| height <= 0; }
	bool IsEmpty(float fEpsilon) const {
	return width <= fEpsilon \|\| height <= fEpsilon;
	}
	void Empty() { width = height = 0; }
	bool Contains(const PointType& p) const {
	return p.x >= left && p.x < left + width && p.y >= top &&
	p.y < top + height;
	}
	bool Contains(const CFX_RectF& rt) const {
	return rt.left >= left && rt.right() <= right() && rt.top >= top &&
	rt.bottom() <= bottom();
	}
	float Left() const { return left; }
	float Top() const { return top; }
	float Width() const { return width; }
	float Height() const { return height; }
	SizeType Size() const { return SizeType(width, height); }
	PointType TopLeft() const { return PointType(left, top); }
	PointType TopRight() const { return PointType(left + width, top); }
	PointType BottomLeft() const { return PointType(left, top + height); }
	PointType BottomRight() const {
	return PointType(left + width, top + height);
	}
	PointType Center() const {
	return PointType(left + width / 2, top + height / 2);
	}
	void Union(float x, float y) {
	float r = right();
	float b = bottom();

	left = std::min(left, x);
	top = std::min(top, y);
	r = std::max(r, x);
	b = std::max(b, y);

	width = r - left;
	height = b - top;
	}
	void Union(const PointType& p) { Union(p.x, p.y); }
	void Union(const CFX_RectF& rt) {
	float r = right();
	float b = bottom();

	left = std::min(left, rt.left);
	top = std::min(top, rt.top);
	r = std::max(r, rt.right());
	b = std::max(b, rt.bottom());

	width = r - left;
	height = b - top;
	}
	void Intersect(const CFX_RectF& rt) {
	float r = right();
	float b = bottom();

	left = std::max(left, rt.left);
	top = std::max(top, rt.top);
	r = std::min(r, rt.right());
	b = std::min(b, rt.bottom());

	width = r - left;
	height = b - top;
	}
	bool IntersectWith(const CFX_RectF& rt) const {
	CFX_RectF rect = rt;
	rect.Intersect(*this);
	return !rect.IsEmpty();
	}
	bool IntersectWith(const CFX_RectF& rt, float fEpsilon) const {
	CFX_RectF rect = rt;
	rect.Intersect(*this);
	return !rect.IsEmpty(fEpsilon);
	}
	friend bool operator==(const CFX_RectF& rc1, const CFX_RectF& rc2) {
	return rc1.left == rc2.left && rc1.top == rc2.top &&
	rc1.width == rc2.width && rc1.height == rc2.height;
	}
	friend bool operator!=(const CFX_RectF& rc1, const CFX_RectF& rc2) {
	return !(rc1 == rc2);
	}

	CFX_FloatRect ToFloatRect() const {
	// Note, we flip top/bottom here because the CFX_FloatRect has the
	// y-axis running in the opposite direction.
	return CFX_FloatRect(left, top, right(), bottom());
	}

	// Returned rect has bounds rounded up/down such that the original is
	// contained in it.
	FX_RECT GetOuterRect() const;

	float left = 0.0f;
	float top = 0.0f;
	float width = 0.0f;
	float height = 0.0f;
	};

	#ifndef NDEBUG
	std::ostream& operator<<(std::ostream& os, const CFX_RectF& rect);
	#endif // NDEBUG

	// The matrix is of the form:
	// \| a b 0 \|
	// \| c d 0 \|
	// \| e f 1 \|
	// See PDF spec 1.7 Section 4.2.3.
	//
	class CFX_Matrix {
	public:
	CFX_Matrix() = default;

	explicit CFX_Matrix(const float n[6])
	: a(n[0]), b(n[1]), c(n[2]), d(n[3]), e(n[4]), f(n[5]) {}

	CFX_Matrix(float a1, float b1, float c1, float d1, float e1, float f1)
	: a(a1), b(b1), c(c1), d(d1), e(e1), f(f1) {}

	CFX_Matrix(const CFX_Matrix& other) = default;

	CFX_Matrix& operator=(const CFX_Matrix& other) = default;

	bool operator==(const CFX_Matrix& other) const {
	return a == other.a && b == other.b && c == other.c && d == other.d &&
	e == other.e && f == other.f;
	}
	bool operator!=(const CFX_Matrix& other) const { return !(*this == other); }

	CFX_Matrix operator*(const CFX_Matrix& right) const {
	return CFX_Matrix(a * right.a + b * right.c, a * right.b + b * right.d,
	c * right.a + d * right.c, c * right.b + d * right.d,
	e * right.a + f * right.c + right.e,
	e * right.b + f * right.d + right.f);
	}
	CFX_Matrix& operator*=(const CFX_Matrix& other) {
	this = this * other;
	return *this;
	}

	bool IsIdentity() const { return *this == CFX_Matrix(); }
	CFX_Matrix GetInverse() const;

	bool Is90Rotated() const;
	bool IsScaled() const;
	bool WillScale() const { return a != 1.0f \|\| b != 0 \|\| c != 0 \|\| d != 1.0f; }

	void Concat(const CFX_Matrix& right) { this = right; }
	void Translate(float x, float y);
	void TranslatePrepend(float x, float y);
	void Translate(int32_t x, int32_t y) {
	Translate(static_cast<float>(x), static_cast<float>(y));
	}
	void TranslatePrepend(int32_t x, int32_t y) {
	TranslatePrepend(static_cast<float>(x), static_cast<float>(y));
	}

	void Scale(float sx, float sy);
	void Rotate(float fRadian);

	void MatchRect(const CFX_FloatRect& dest, const CFX_FloatRect& src);

	float GetXUnit() const;
	float GetYUnit() const;
	CFX_FloatRect GetUnitRect() const;

	float TransformXDistance(float dx) const;
	float TransformDistance(float distance) const;

	CFX_PointF Transform(const CFX_PointF& point) const;

	CFX_RectF TransformRect(const CFX_RectF& rect) const;
	CFX_FloatRect TransformRect(const CFX_FloatRect& rect) const;

	float a = 1.0f;
	float b = 0.0f;
	float c = 0.0f;
	float d = 1.0f;
	float e = 0.0f;
	float f = 0.0f;
	};

	#endif // CORE_FXCRT_FX_COORDINATES_H_