RectAbsolute.h - mozsearch

mozilla-central/gfx/2d/RectAbsolute.h (file symbol)

Enable keyboard shortcuts

Source code

File a bug in Core :: Graphics

Revision control

Copy as Markdown

Other Tools

/* -*- Mode: C++; tab-width: 8; indent-tabs-mode: nil; c-basic-offset: 2 -*- */

/* vim: set ts=8 sts=2 et sw=2 tw=80: */

/* This Source Code Form is subject to the terms of the Mozilla Public

 * License, v. 2.0. If a copy of the MPL was not distributed with this

 * file, You can obtain one at http://mozilla.org/MPL/2.0/. */

#ifndef MOZILLA_GFX_RECT_ABSOLUTE_H_

#define MOZILLA_GFX_RECT_ABSOLUTE_H_

#include <algorithm>

#include <cstdint>

#include "mozilla/Attributes.h"

#include "Point.h"

#include "Rect.h"

#include "Types.h"

namespace mozilla {

template <typename>

struct IsPixel;

namespace gfx {

/**

 * A RectAbsolute is similar to a Rect (see BaseRect.h), but represented as

 * (x1, y1, x2, y2) instead of (x, y, width, height).

 * Unless otherwise indicated, methods on this class correspond

 * to methods on BaseRect.

 * The API is currently very bare-bones; it may be extended as needed.

 * Do not use this class directly. Subclass it, pass that subclass as the

 * Sub parameter, and only use that subclass.

*/

template <class T, class Sub, class Point, class Rect>

struct BaseRectAbsolute {

 protected:

  T left, top, right, bottom;

 public:

  BaseRectAbsolute() : left(0), top(0), right(0), bottom(0) {}

  BaseRectAbsolute(T aLeft, T aTop, T aRight, T aBottom)

      : left(aLeft), top(aTop), right(aRight), bottom(aBottom) {}

  MOZ_ALWAYS_INLINE T X() const { return left; }

  MOZ_ALWAYS_INLINE T Y() const { return top; }

  MOZ_ALWAYS_INLINE T Width() const { return right - left; }

  MOZ_ALWAYS_INLINE T Height() const { return bottom - top; }

  MOZ_ALWAYS_INLINE T XMost() const { return right; }

  MOZ_ALWAYS_INLINE T YMost() const { return bottom; }

  MOZ_ALWAYS_INLINE const T& Left() const { return left; }

  MOZ_ALWAYS_INLINE const T& Right() const { return right; }

  MOZ_ALWAYS_INLINE const T& Top() const { return top; }

  MOZ_ALWAYS_INLINE const T& Bottom() const { return bottom; }

  MOZ_ALWAYS_INLINE T& Left() { return left; }

  MOZ_ALWAYS_INLINE T& Right() { return right; }

  MOZ_ALWAYS_INLINE T& Top() { return top; }

  MOZ_ALWAYS_INLINE T& Bottom() { return bottom; }

  T Area() const { return Width() * Height(); }

  void Inflate(T aD) { Inflate(aD, aD); }

  void Inflate(T aDx, T aDy) {

    left -= aDx;

    top -= aDy;

    right += aDx;

    bottom += aDy;

  MOZ_ALWAYS_INLINE void SetBox(T aLeft, T aTop, T aRight, T aBottom) {

    left = aLeft;

    top = aTop;

    right = aRight;

    bottom = aBottom;

  void SetLeftEdge(T aLeft) { left = aLeft; }

  void SetRightEdge(T aRight) { right = aRight; }

  void SetTopEdge(T aTop) { top = aTop; }

  void SetBottomEdge(T aBottom) { bottom = aBottom; }

  static Sub FromRect(const Rect& aRect) {

    if (aRect.Overflows()) {

      return Sub();

    return Sub(aRect.x, aRect.y, aRect.XMost(), aRect.YMost());

  [[nodiscard]] Sub Intersect(const Sub& aOther) const {

    Sub result;

    result.left = std::max<T>(left, aOther.left);

    result.top = std::max<T>(top, aOther.top);

    result.right = std::min<T>(right, aOther.right);

    result.bottom = std::min<T>(bottom, aOther.bottom);

    if (result.right < result.left || result.bottom < result.top) {

      result.SizeTo(0, 0);

    return result;

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

  bool IsEqualEdges(const Sub& aOther) const {

    return left == aOther.left && top == aOther.top && right == aOther.right &&

           bottom == aOther.bottom;

  bool IsEqualInterior(const Sub& aRect) const {

    return IsEqualEdges(aRect) || (IsEmpty() && aRect.IsEmpty());

  MOZ_ALWAYS_INLINE void MoveBy(T aDx, T aDy) {

    left += aDx;

    right += aDx;

    top += aDy;

    bottom += aDy;

  MOZ_ALWAYS_INLINE void MoveBy(const Point& aPoint) {

    left += aPoint.x;

    right += aPoint.x;

    top += aPoint.y;

    bottom += aPoint.y;

  MOZ_ALWAYS_INLINE void SizeTo(T aWidth, T aHeight) {

    right = left + aWidth;

    bottom = top + aHeight;

  bool Contains(const Sub& aRect) const {

    return aRect.IsEmpty() || (left <= aRect.left && aRect.right <= right &&

                               top <= aRect.top && aRect.bottom <= bottom);

  bool Contains(T aX, T aY) const {

    return (left <= aX && aX < right && top <= aY && aY < bottom);

  bool Intersects(const Sub& aRect) const {

    return !IsEmpty() && !aRect.IsEmpty() && left < aRect.right &&

           aRect.left < right && top < aRect.bottom && aRect.top < bottom;

  void SetEmpty() { left = right = top = bottom = 0; }

  // Returns the smallest rectangle that contains both the area of both

  // this and aRect. Thus, empty input rectangles are ignored.

  // Note: if both rectangles are empty, returns aRect.

  // WARNING! This is not safe against overflow, prefer using SafeUnion instead

  // when dealing with int-based rects.

  [[nodiscard]] Sub Union(const Sub& aRect) const {

    if (IsEmpty()) {

      return aRect;

    } else if (aRect.IsEmpty()) {

      return *static_cast<const Sub*>(this);

    } else {

      return UnionEdges(aRect);

  // Returns the smallest rectangle that contains both the points (including

  // edges) of both aRect1 and aRect2.

  // Thus, empty input rectangles are allowed to affect the result.

  // WARNING! This is not safe against overflow, prefer using SafeUnionEdges

  // instead when dealing with int-based rects.

  [[nodiscard]] Sub UnionEdges(const Sub& aRect) const {

    Sub result;

    result.left = std::min(left, aRect.left);

    result.top = std::min(top, aRect.top);

    result.right = std::max(XMost(), aRect.XMost());

    result.bottom = std::max(YMost(), aRect.YMost());

    return result;

  // Scale 'this' by aScale without doing any rounding.

  void Scale(T aScale) { Scale(aScale, aScale); }

  // Scale 'this' by aXScale and aYScale, without doing any rounding.

  void Scale(T aXScale, T aYScale) {

    right = XMost() * aXScale;

    bottom = YMost() * aYScale;

    left = left * aXScale;

    top = top * aYScale;

  // Scale 'this' by aScale, converting coordinates to integers so that the

  // result is the smallest integer-coordinate rectangle containing the

  // unrounded result. Note: this can turn an empty rectangle into a non-empty

  // rectangle

  void ScaleRoundOut(double aScale) { ScaleRoundOut(aScale, aScale); }

  // Scale 'this' by aXScale and aYScale, converting coordinates to integers so

  // that the result is the smallest integer-coordinate rectangle containing the

  // unrounded result.

  // Note: this can turn an empty rectangle into a non-empty rectangle

  void ScaleRoundOut(double aXScale, double aYScale) {

    right = static_cast<T>(ceil(double(XMost()) * aXScale));

    bottom = static_cast<T>(ceil(double(YMost()) * aYScale));

    left = static_cast<T>(floor(double(left) * aXScale));

    top = static_cast<T>(floor(double(top) * aYScale));

  // Scale 'this' by aScale, converting coordinates to integers so that the

  // result is the largest integer-coordinate rectangle contained by the

  // unrounded result.

  void ScaleRoundIn(double aScale) { ScaleRoundIn(aScale, aScale); }

  // Scale 'this' by aXScale and aYScale, converting coordinates to integers so

  // that the result is the largest integer-coordinate rectangle contained by

  // the unrounded result.

  void ScaleRoundIn(double aXScale, double aYScale) {

    right = static_cast<T>(floor(double(XMost()) * aXScale));

    bottom = static_cast<T>(floor(double(YMost()) * aYScale));

    left = static_cast<T>(ceil(double(left) * aXScale));

    top = static_cast<T>(ceil(double(top) * aYScale));

  // Scale 'this' by 1/aScale, converting coordinates to integers so that the

  // result is the smallest integer-coordinate rectangle containing the

  // unrounded result. Note: this can turn an empty rectangle into a non-empty

  // rectangle

  void ScaleInverseRoundOut(double aScale) {

    ScaleInverseRoundOut(aScale, aScale);

  // Scale 'this' by 1/aXScale and 1/aYScale, converting coordinates to integers

  // so that the result is the smallest integer-coordinate rectangle containing

  // the unrounded result. Note: this can turn an empty rectangle into a

  // non-empty rectangle

  void ScaleInverseRoundOut(double aXScale, double aYScale) {

    right = static_cast<T>(ceil(double(XMost()) / aXScale));

    bottom = static_cast<T>(ceil(double(YMost()) / aYScale));

    left = static_cast<T>(floor(double(left) / aXScale));

    top = static_cast<T>(floor(double(top) / aYScale));

  // Scale 'this' by 1/aScale, converting coordinates to integers so that the

  // result is the largest integer-coordinate rectangle contained by the

  // unrounded result.

  void ScaleInverseRoundIn(double aScale) {

    ScaleInverseRoundIn(aScale, aScale);

  // Scale 'this' by 1/aXScale and 1/aYScale, converting coordinates to integers

  // so that the result is the largest integer-coordinate rectangle contained by

  // the unrounded result.

  void ScaleInverseRoundIn(double aXScale, double aYScale) {

    right = static_cast<T>(floor(double(XMost()) / aXScale));

    bottom = static_cast<T>(floor(double(YMost()) / aYScale));

    left = static_cast<T>(ceil(double(left) / aXScale));

    top = static_cast<T>(ceil(double(top) / aYScale));

/**

   * Translate this rectangle to be inside aRect. If it doesn't fit inside

   * aRect then the dimensions that don't fit will be shrunk so that they

   * do fit. The resulting rect is returned.

*/

  [[nodiscard]] Sub MoveInsideAndClamp(const Sub& aRect) const {

    T newLeft = std::max(aRect.left, left);

    T newTop = std::max(aRect.top, top);

    T width = std::min(aRect.Width(), Width());

    T height = std::min(aRect.Height(), Height());

    Sub rect(newLeft, newTop, newLeft + width, newTop + height);

    newLeft = std::min(rect.right, aRect.right) - width;

    newTop = std::min(rect.bottom, aRect.bottom) - height;

    rect.MoveBy(newLeft - rect.left, newTop - rect.top);

    return rect;

  friend std::ostream& operator<<(

      std::ostream& stream,

      const BaseRectAbsolute<T, Sub, Point, Rect>& aRect) {

    return stream << "(l=" << aRect.left << ", t=" << aRect.top

                  << ", r=" << aRect.right << ", b=" << aRect.bottom << ')';

};

template <class Units>

struct IntRectAbsoluteTyped

    : public BaseRectAbsolute<int32_t, IntRectAbsoluteTyped<Units>,

                              IntPointTyped<Units>, IntRectTyped<Units>>,

      public Units {

  static_assert(IsPixel<Units>::value,

                "'units' must be a coordinate system tag");

  typedef BaseRectAbsolute<int32_t, IntRectAbsoluteTyped<Units>,

                           IntPointTyped<Units>, IntRectTyped<Units>>

      Super;

  typedef IntParam<int32_t> ToInt;

  IntRectAbsoluteTyped() : Super() {}

  IntRectAbsoluteTyped(ToInt aLeft, ToInt aTop, ToInt aRight, ToInt aBottom)

      : Super(aLeft.value, aTop.value, aRight.value, aBottom.value) {}

};

template <class Units>

struct RectAbsoluteTyped

    : public BaseRectAbsolute<Float, RectAbsoluteTyped<Units>,

                              PointTyped<Units>, RectTyped<Units>>,

      public Units {

  static_assert(IsPixel<Units>::value,

                "'units' must be a coordinate system tag");

  typedef BaseRectAbsolute<Float, RectAbsoluteTyped<Units>, PointTyped<Units>,

                           RectTyped<Units>>

      Super;

  RectAbsoluteTyped() : Super() {}

  RectAbsoluteTyped(Float aLeft, Float aTop, Float aRight, Float aBottom)

      : Super(aLeft, aTop, aRight, aBottom) {}

};

typedef IntRectAbsoluteTyped<UnknownUnits> IntRectAbsolute;

}  // namespace gfx

}  // namespace mozilla

#endif /* MOZILLA_GFX_RECT_ABSOLUTE_H_ */