mirror of
https://github.com/mozilla/gecko-dev.git
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f0ceea18e4
Differential Revision: https://phabricator.services.mozilla.com/D148138
746 lines
27 KiB
C++
746 lines
27 KiB
C++
/* -*- Mode: C++; tab-width: 8; indent-tabs-mode: nil; c-basic-offset: 2 -*- */
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/* vim: set ts=8 sts=2 et sw=2 tw=80: */
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/* This Source Code Form is subject to the terms of the Mozilla Public
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* License, v. 2.0. If a copy of the MPL was not distributed with this
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* file, You can obtain one at http://mozilla.org/MPL/2.0/. */
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#ifndef MOZILLA_GFX_BASERECT_H_
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#define MOZILLA_GFX_BASERECT_H_
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#include <algorithm>
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#include <cmath>
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#include <ostream>
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#include <type_traits>
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#include "mozilla/Assertions.h"
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#include "mozilla/FloatingPoint.h"
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#include "mozilla/gfx/ScaleFactors2D.h"
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#include "Types.h"
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namespace mozilla {
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namespace gfx {
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/**
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* Rectangles have two interpretations: a set of (zero-size) points,
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* and a rectangular area of the plane. Most rectangle operations behave
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* the same no matter what interpretation is being used, but some operations
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* differ:
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* -- Equality tests behave differently. When a rectangle represents an area,
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* all zero-width and zero-height rectangles are equal to each other since they
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* represent the empty area. But when a rectangle represents a set of
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* mathematical points, zero-width and zero-height rectangles can be unequal.
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* -- The union operation can behave differently. When rectangles represent
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* areas, taking the union of a zero-width or zero-height rectangle with
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* another rectangle can just ignore the empty rectangle. But when rectangles
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* represent sets of mathematical points, we may need to extend the latter
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* rectangle to include the points of a zero-width or zero-height rectangle.
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*
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* To ensure that these interpretations are explicitly disambiguated, we
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* deny access to the == and != operators and require use of IsEqualEdges and
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* IsEqualInterior instead. Similarly we provide separate Union and UnionEdges
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* methods.
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*
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* Do not use this class directly. Subclass it, pass that subclass as the
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* Sub parameter, and only use that subclass.
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*/
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template <class T, class Sub, class Point, class SizeT, class MarginT>
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struct BaseRect {
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T x, y, width, height;
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// Constructors
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BaseRect() : x(0), y(0), width(0), height(0) {}
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BaseRect(const Point& aOrigin, const SizeT& aSize)
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: x(aOrigin.x), y(aOrigin.y), width(aSize.width), height(aSize.height) {}
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BaseRect(T aX, T aY, T aWidth, T aHeight)
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: x(aX), y(aY), width(aWidth), height(aHeight) {}
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// Emptiness. An empty rect is one that has no area, i.e. its height or width
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// is <= 0. Zero rect is the one with height and width set to zero. Note
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// that SetEmpty() may change a rectangle that identified as IsEmpty().
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MOZ_ALWAYS_INLINE bool IsZeroArea() const {
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return height == 0 || width == 0;
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}
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MOZ_ALWAYS_INLINE bool IsEmpty() const { return height <= 0 || width <= 0; }
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void SetEmpty() { width = height = 0; }
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// "Finite" means not inf and not NaN
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bool IsFinite() const {
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using FloatType =
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std::conditional_t<std::is_same_v<T, float>, float, double>;
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return (mozilla::IsFinite(FloatType(x)) &&
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mozilla::IsFinite(FloatType(y)) &&
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mozilla::IsFinite(FloatType(width)) &&
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mozilla::IsFinite(FloatType(height)));
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}
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// Returns true if this rectangle contains the interior of aRect. Always
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// returns true if aRect is empty, and always returns false is aRect is
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// nonempty but this rect is empty.
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bool Contains(const Sub& aRect) const {
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return aRect.IsEmpty() || (x <= aRect.x && aRect.XMost() <= XMost() &&
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y <= aRect.y && aRect.YMost() <= YMost());
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}
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// Returns true if this rectangle contains the point. Points are considered
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// in the rectangle if they are on the left or top edge, but outside if they
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// are on the right or bottom edge.
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MOZ_ALWAYS_INLINE bool Contains(T aX, T aY) const {
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return x <= aX && aX < XMost() && y <= aY && aY < YMost();
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}
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MOZ_ALWAYS_INLINE bool ContainsX(T aX) const {
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return x <= aX && aX < XMost();
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}
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MOZ_ALWAYS_INLINE bool ContainsY(T aY) const {
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return y <= aY && aY < YMost();
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}
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// Returns true if this rectangle contains the point. Points are considered
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// in the rectangle if they are on the left or top edge, but outside if they
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// are on the right or bottom edge.
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bool Contains(const Point& aPoint) const {
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return Contains(aPoint.x, aPoint.y);
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}
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// Intersection. Returns TRUE if the receiver's area has non-empty
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// intersection with aRect's area, and FALSE otherwise.
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// Always returns false if aRect is empty or 'this' is empty.
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bool Intersects(const Sub& aRect) const {
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return !IsEmpty() && !aRect.IsEmpty() && x < aRect.XMost() &&
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aRect.x < XMost() && y < aRect.YMost() && aRect.y < YMost();
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}
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// Returns the rectangle containing the intersection of the points
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// (including edges) of *this and aRect. If there are no points in that
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// intersection, returns an empty rectangle with x/y set to the std::max of
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// the x/y of *this and aRect.
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//
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// Intersection with an empty Rect may not produce an empty Rect if overflow
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// occurs. e.g. {INT_MIN, 0, 0, 20} Intersect { 5000, 0, 500, 20 } gives:
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// the non-emtpy {5000, 0, 500, 20 } instead of {5000, 0, 0, 0}
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[[nodiscard]] Sub Intersect(const Sub& aRect) const {
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Sub result;
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result.x = std::max<T>(x, aRect.x);
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result.y = std::max<T>(y, aRect.y);
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result.width =
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std::min<T>(x - result.x + width, aRect.x - result.x + aRect.width);
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result.height =
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std::min<T>(y - result.y + height, aRect.y - result.y + aRect.height);
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// See bug 1457110, this function expects to -only- size to 0,0 if the
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// width/height is explicitly negative.
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if (result.width < 0 || result.height < 0) {
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result.SizeTo(0, 0);
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}
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return result;
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}
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// Gives the same results as Intersect() but handles integer overflow
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// better. This comes at a tiny cost in performance.
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// e.g. {INT_MIN, 0, 0, 20} Intersect { 5000, 0, 500, 20 } gives:
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// {5000, 0, 0, 0}
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[[nodiscard]] Sub SafeIntersect(const Sub& aRect) const {
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Sub result;
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result.x = std::max<T>(x, aRect.x);
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result.y = std::max<T>(y, aRect.y);
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T right = std::min<T>(x + width, aRect.x + aRect.width);
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T bottom = std::min<T>(y + height, aRect.y + aRect.height);
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// See bug 1457110, this function expects to -only- size to 0,0 if the
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// width/height is explicitly negative.
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if (right < result.x || bottom < result.y) {
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result.width = 0;
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result.height = 0;
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} else {
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result.width = right - result.x;
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result.height = bottom - result.y;
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}
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return result;
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}
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// Sets *this to be the rectangle containing the intersection of the points
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// (including edges) of *this and aRect. If there are no points in that
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// intersection, sets *this to be an empty rectangle with x/y set to the
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// std::max of the x/y of *this and aRect.
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//
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// 'this' can be the same object as either aRect1 or aRect2
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bool IntersectRect(const Sub& aRect1, const Sub& aRect2) {
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T newX = std::max<T>(aRect1.x, aRect2.x);
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T newY = std::max<T>(aRect1.y, aRect2.y);
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width = std::min<T>(aRect1.x - newX + aRect1.width,
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aRect2.x - newX + aRect2.width);
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height = std::min<T>(aRect1.y - newY + aRect1.height,
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aRect2.y - newY + aRect2.height);
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x = newX;
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y = newY;
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if (width <= 0 || height <= 0) {
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SizeTo(0, 0);
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return false;
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}
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return true;
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}
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// Returns the smallest rectangle that contains both the area of both
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// this and aRect. Thus, empty input rectangles are ignored.
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// Note: if both rectangles are empty, returns aRect.
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// WARNING! This is not safe against overflow, prefer using SafeUnion instead
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// when dealing with int-based rects.
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[[nodiscard]] Sub Union(const Sub& aRect) const {
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if (IsEmpty()) {
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return aRect;
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} else if (aRect.IsEmpty()) {
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return *static_cast<const Sub*>(this);
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} else {
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return UnionEdges(aRect);
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}
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}
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// Returns the smallest rectangle that contains both the points (including
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// edges) of both aRect1 and aRect2.
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// Thus, empty input rectangles are allowed to affect the result.
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// WARNING! This is not safe against overflow, prefer using SafeUnionEdges
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// instead when dealing with int-based rects.
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[[nodiscard]] Sub UnionEdges(const Sub& aRect) const {
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Sub result;
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result.x = std::min(x, aRect.x);
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result.y = std::min(y, aRect.y);
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result.width = std::max(XMost(), aRect.XMost()) - result.x;
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result.height = std::max(YMost(), aRect.YMost()) - result.y;
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return result;
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}
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// Computes the smallest rectangle that contains both the area of both
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// aRect1 and aRect2, and fills 'this' with the result.
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// Thus, empty input rectangles are ignored.
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// If both rectangles are empty, sets 'this' to aRect2.
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//
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// 'this' can be the same object as either aRect1 or aRect2
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void UnionRect(const Sub& aRect1, const Sub& aRect2) {
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*static_cast<Sub*>(this) = aRect1.Union(aRect2);
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}
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void OrWith(const Sub& aRect1) {
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UnionRect(*static_cast<Sub*>(this), aRect1);
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}
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// Computes the smallest rectangle that contains both the points (including
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// edges) of both aRect1 and aRect2.
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// Thus, empty input rectangles are allowed to affect the result.
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//
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// 'this' can be the same object as either aRect1 or aRect2
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void UnionRectEdges(const Sub& aRect1, const Sub& aRect2) {
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*static_cast<Sub*>(this) = aRect1.UnionEdges(aRect2);
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}
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// Expands the rect to include the point
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void ExpandToEnclose(const Point& aPoint) {
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if (aPoint.x < x) {
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width = XMost() - aPoint.x;
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x = aPoint.x;
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} else if (aPoint.x > XMost()) {
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width = aPoint.x - x;
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}
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if (aPoint.y < y) {
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height = YMost() - aPoint.y;
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y = aPoint.y;
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} else if (aPoint.y > YMost()) {
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height = aPoint.y - y;
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}
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}
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MOZ_ALWAYS_INLINE void SetRect(T aX, T aY, T aWidth, T aHeight) {
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x = aX;
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y = aY;
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width = aWidth;
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height = aHeight;
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}
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MOZ_ALWAYS_INLINE void SetRectX(T aX, T aWidth) {
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x = aX;
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width = aWidth;
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}
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MOZ_ALWAYS_INLINE void SetRectY(T aY, T aHeight) {
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y = aY;
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height = aHeight;
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}
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MOZ_ALWAYS_INLINE void SetBox(T aX, T aY, T aXMost, T aYMost) {
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x = aX;
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y = aY;
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width = aXMost - aX;
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height = aYMost - aY;
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}
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MOZ_ALWAYS_INLINE void SetNonEmptyBox(T aX, T aY, T aXMost, T aYMost) {
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x = aX;
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y = aY;
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width = std::max(0, aXMost - aX);
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height = std::max(0, aYMost - aY);
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}
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MOZ_ALWAYS_INLINE void SetBoxX(T aX, T aXMost) {
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x = aX;
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width = aXMost - aX;
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}
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MOZ_ALWAYS_INLINE void SetBoxY(T aY, T aYMost) {
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y = aY;
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height = aYMost - aY;
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}
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void SetRect(const Point& aPt, const SizeT& aSize) {
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SetRect(aPt.x, aPt.y, aSize.width, aSize.height);
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}
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MOZ_ALWAYS_INLINE void GetRect(T* aX, T* aY, T* aWidth, T* aHeight) const {
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*aX = x;
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*aY = y;
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*aWidth = width;
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*aHeight = height;
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}
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MOZ_ALWAYS_INLINE void MoveTo(T aX, T aY) {
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x = aX;
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y = aY;
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}
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MOZ_ALWAYS_INLINE void MoveToX(T aX) { x = aX; }
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MOZ_ALWAYS_INLINE void MoveToY(T aY) { y = aY; }
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MOZ_ALWAYS_INLINE void MoveTo(const Point& aPoint) {
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x = aPoint.x;
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y = aPoint.y;
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}
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MOZ_ALWAYS_INLINE void MoveBy(T aDx, T aDy) {
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x += aDx;
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y += aDy;
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}
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MOZ_ALWAYS_INLINE void MoveByX(T aDx) { x += aDx; }
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MOZ_ALWAYS_INLINE void MoveByY(T aDy) { y += aDy; }
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MOZ_ALWAYS_INLINE void MoveBy(const Point& aPoint) {
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x += aPoint.x;
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y += aPoint.y;
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}
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MOZ_ALWAYS_INLINE void SizeTo(T aWidth, T aHeight) {
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width = aWidth;
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height = aHeight;
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}
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MOZ_ALWAYS_INLINE void SizeTo(const SizeT& aSize) {
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width = aSize.width;
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height = aSize.height;
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}
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// Variant of MoveBy that ensures that even after translation by a point that
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// the rectangle coordinates will still fit within numeric limits. The origin
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// and size will be clipped within numeric limits to ensure this.
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void SafeMoveByX(T aDx) {
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T x2 = XMost();
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if (aDx >= T(0)) {
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T limit = std::numeric_limits<T>::max();
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x = limit - aDx < x ? limit : x + aDx;
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width = (limit - aDx < x2 ? limit : x2 + aDx) - x;
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} else {
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T limit = std::numeric_limits<T>::min();
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x = limit - aDx > x ? limit : x + aDx;
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width = (limit - aDx > x2 ? limit : x2 + aDx) - x;
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}
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}
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void SafeMoveByY(T aDy) {
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T y2 = YMost();
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if (aDy >= T(0)) {
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T limit = std::numeric_limits<T>::max();
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y = limit - aDy < y ? limit : y + aDy;
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height = (limit - aDy < y2 ? limit : y2 + aDy) - y;
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} else {
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T limit = std::numeric_limits<T>::min();
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y = limit - aDy > y ? limit : y + aDy;
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height = (limit - aDy > y2 ? limit : y2 + aDy) - y;
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}
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}
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void SafeMoveBy(T aDx, T aDy) {
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SafeMoveByX(aDx);
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SafeMoveByY(aDy);
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}
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void SafeMoveBy(const Point& aPoint) { SafeMoveBy(aPoint.x, aPoint.y); }
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void Inflate(T aD) { Inflate(aD, aD); }
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void Inflate(T aDx, T aDy) {
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x -= aDx;
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y -= aDy;
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width += 2 * aDx;
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height += 2 * aDy;
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}
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void Inflate(const MarginT& aMargin) {
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x -= aMargin.left;
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y -= aMargin.top;
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width += aMargin.LeftRight();
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height += aMargin.TopBottom();
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}
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void Inflate(const SizeT& aSize) { Inflate(aSize.width, aSize.height); }
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void Deflate(T aD) { Deflate(aD, aD); }
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void Deflate(T aDx, T aDy) {
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x += aDx;
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y += aDy;
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width = std::max(T(0), width - 2 * aDx);
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height = std::max(T(0), height - 2 * aDy);
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}
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void Deflate(const MarginT& aMargin) {
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x += aMargin.left;
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y += aMargin.top;
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width = std::max(T(0), width - aMargin.LeftRight());
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height = std::max(T(0), height - aMargin.TopBottom());
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}
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void Deflate(const SizeT& aSize) { Deflate(aSize.width, aSize.height); }
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// Return true if the rectangles contain the same set of points, including
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// points on the edges.
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// Use when we care about the exact x/y/width/height values being
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// equal (i.e. we care about differences in empty rectangles).
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bool IsEqualEdges(const Sub& aRect) const {
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return x == aRect.x && y == aRect.y && width == aRect.width &&
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height == aRect.height;
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}
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MOZ_ALWAYS_INLINE bool IsEqualRect(T aX, T aY, T aW, T aH) {
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return x == aX && y == aY && width == aW && height == aH;
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}
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MOZ_ALWAYS_INLINE bool IsEqualXY(T aX, T aY) { return x == aX && y == aY; }
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MOZ_ALWAYS_INLINE bool IsEqualSize(T aW, T aH) {
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return width == aW && height == aH;
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}
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// Return true if the rectangles contain the same area of the plane.
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// Use when we do not care about differences in empty rectangles.
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bool IsEqualInterior(const Sub& aRect) const {
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return IsEqualEdges(aRect) || (IsEmpty() && aRect.IsEmpty());
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}
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friend Sub operator+(Sub aSub, const Point& aPoint) {
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aSub += aPoint;
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return aSub;
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}
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friend Sub operator-(Sub aSub, const Point& aPoint) {
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aSub -= aPoint;
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return aSub;
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}
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friend Sub operator+(Sub aSub, const SizeT& aSize) {
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aSub += aSize;
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return aSub;
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}
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friend Sub operator-(Sub aSub, const SizeT& aSize) {
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aSub -= aSize;
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return aSub;
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}
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Sub& operator+=(const Point& aPoint) {
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MoveBy(aPoint);
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return *static_cast<Sub*>(this);
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}
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Sub& operator-=(const Point& aPoint) {
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MoveBy(-aPoint);
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return *static_cast<Sub*>(this);
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}
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Sub& operator+=(const SizeT& aSize) {
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width += aSize.width;
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height += aSize.height;
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return *static_cast<Sub*>(this);
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}
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Sub& operator-=(const SizeT& aSize) {
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width -= aSize.width;
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height -= aSize.height;
|
|
return *static_cast<Sub*>(this);
|
|
}
|
|
// Find difference as a Margin
|
|
MarginT operator-(const Sub& aRect) const {
|
|
return MarginT(aRect.y - y, XMost() - aRect.XMost(),
|
|
YMost() - aRect.YMost(), aRect.x - x);
|
|
}
|
|
|
|
// Helpers for accessing the vertices
|
|
Point TopLeft() const { return Point(x, y); }
|
|
Point TopRight() const { return Point(XMost(), y); }
|
|
Point BottomLeft() const { return Point(x, YMost()); }
|
|
Point BottomRight() const { return Point(XMost(), YMost()); }
|
|
Point AtCorner(Corner aCorner) const {
|
|
switch (aCorner) {
|
|
case eCornerTopLeft:
|
|
return TopLeft();
|
|
case eCornerTopRight:
|
|
return TopRight();
|
|
case eCornerBottomRight:
|
|
return BottomRight();
|
|
case eCornerBottomLeft:
|
|
return BottomLeft();
|
|
}
|
|
MOZ_CRASH("GFX: Incomplete switch");
|
|
}
|
|
Point CCWCorner(mozilla::Side side) const {
|
|
switch (side) {
|
|
case eSideTop:
|
|
return TopLeft();
|
|
case eSideRight:
|
|
return TopRight();
|
|
case eSideBottom:
|
|
return BottomRight();
|
|
case eSideLeft:
|
|
return BottomLeft();
|
|
}
|
|
MOZ_CRASH("GFX: Incomplete switch");
|
|
}
|
|
Point CWCorner(mozilla::Side side) const {
|
|
switch (side) {
|
|
case eSideTop:
|
|
return TopRight();
|
|
case eSideRight:
|
|
return BottomRight();
|
|
case eSideBottom:
|
|
return BottomLeft();
|
|
case eSideLeft:
|
|
return TopLeft();
|
|
}
|
|
MOZ_CRASH("GFX: Incomplete switch");
|
|
}
|
|
Point Center() const { return Point(x, y) + Point(width, height) / 2; }
|
|
SizeT Size() const { return SizeT(width, height); }
|
|
|
|
T Area() const { return width * height; }
|
|
|
|
// Helper methods for computing the extents
|
|
MOZ_ALWAYS_INLINE T X() const { return x; }
|
|
MOZ_ALWAYS_INLINE T Y() const { return y; }
|
|
MOZ_ALWAYS_INLINE T Width() const { return width; }
|
|
MOZ_ALWAYS_INLINE T Height() const { return height; }
|
|
MOZ_ALWAYS_INLINE T XMost() const { return x + width; }
|
|
MOZ_ALWAYS_INLINE T YMost() const { return y + height; }
|
|
|
|
// Set width and height. SizeTo() sets them together.
|
|
MOZ_ALWAYS_INLINE void SetWidth(T aWidth) { width = aWidth; }
|
|
MOZ_ALWAYS_INLINE void SetHeight(T aHeight) { height = aHeight; }
|
|
|
|
// Get the coordinate of the edge on the given side.
|
|
T Edge(mozilla::Side aSide) const {
|
|
switch (aSide) {
|
|
case eSideTop:
|
|
return Y();
|
|
case eSideRight:
|
|
return XMost();
|
|
case eSideBottom:
|
|
return YMost();
|
|
case eSideLeft:
|
|
return X();
|
|
}
|
|
MOZ_CRASH("GFX: Incomplete switch");
|
|
}
|
|
|
|
// Moves one edge of the rect without moving the opposite edge.
|
|
void SetLeftEdge(T aX) {
|
|
width = XMost() - aX;
|
|
x = aX;
|
|
}
|
|
void SetRightEdge(T aXMost) { width = aXMost - x; }
|
|
void SetTopEdge(T aY) {
|
|
height = YMost() - aY;
|
|
y = aY;
|
|
}
|
|
void SetBottomEdge(T aYMost) { height = aYMost - y; }
|
|
void Swap() {
|
|
std::swap(x, y);
|
|
std::swap(width, height);
|
|
}
|
|
|
|
// Round the rectangle edges to integer coordinates, such that the rounded
|
|
// rectangle has the same set of pixel centers as the original rectangle.
|
|
// Edges at offset 0.5 round up.
|
|
// Suitable for most places where integral device coordinates
|
|
// are needed, but note that any translation should be applied first to
|
|
// avoid pixel rounding errors.
|
|
// Note that this is *not* rounding to nearest integer if the values are
|
|
// negative. They are always rounding as floor(n + 0.5). See
|
|
// https://bugzilla.mozilla.org/show_bug.cgi?id=410748#c14 If you need similar
|
|
// method which is using NS_round(), you should create new
|
|
// |RoundAwayFromZero()| method.
|
|
void Round() {
|
|
T x0 = static_cast<T>(std::floor(T(X()) + 0.5f));
|
|
T y0 = static_cast<T>(std::floor(T(Y()) + 0.5f));
|
|
T x1 = static_cast<T>(std::floor(T(XMost()) + 0.5f));
|
|
T y1 = static_cast<T>(std::floor(T(YMost()) + 0.5f));
|
|
|
|
x = x0;
|
|
y = y0;
|
|
|
|
width = x1 - x0;
|
|
height = y1 - y0;
|
|
}
|
|
|
|
// Snap the rectangle edges to integer coordinates, such that the
|
|
// original rectangle contains the resulting rectangle.
|
|
void RoundIn() {
|
|
T x0 = static_cast<T>(std::ceil(T(X())));
|
|
T y0 = static_cast<T>(std::ceil(T(Y())));
|
|
T x1 = static_cast<T>(std::floor(T(XMost())));
|
|
T y1 = static_cast<T>(std::floor(T(YMost())));
|
|
|
|
x = x0;
|
|
y = y0;
|
|
|
|
width = x1 - x0;
|
|
height = y1 - y0;
|
|
}
|
|
|
|
// Snap the rectangle edges to integer coordinates, such that the
|
|
// resulting rectangle contains the original rectangle.
|
|
void RoundOut() {
|
|
T x0 = static_cast<T>(std::floor(T(X())));
|
|
T y0 = static_cast<T>(std::floor(T(Y())));
|
|
T x1 = static_cast<T>(std::ceil(T(XMost())));
|
|
T y1 = static_cast<T>(std::ceil(T(YMost())));
|
|
|
|
x = x0;
|
|
y = y0;
|
|
|
|
width = x1 - x0;
|
|
height = y1 - y0;
|
|
}
|
|
|
|
// Scale 'this' by aScale.xScale and aScale.yScale without doing any rounding.
|
|
template <class Src, class Dst>
|
|
void Scale(const BaseScaleFactors2D<Src, Dst, T>& aScale) {
|
|
Scale(aScale.xScale, aScale.yScale);
|
|
}
|
|
// 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) {
|
|
x = x * aXScale;
|
|
y = y * aYScale;
|
|
width = width * aXScale;
|
|
height = height * 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) {
|
|
T right = static_cast<T>(ceil(double(XMost()) * aXScale));
|
|
T bottom = static_cast<T>(ceil(double(YMost()) * aYScale));
|
|
x = static_cast<T>(floor(double(x) * aXScale));
|
|
y = static_cast<T>(floor(double(y) * aYScale));
|
|
width = right - x;
|
|
height = bottom - y;
|
|
}
|
|
// 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) {
|
|
T right = static_cast<T>(floor(double(XMost()) * aXScale));
|
|
T bottom = static_cast<T>(floor(double(YMost()) * aYScale));
|
|
x = static_cast<T>(ceil(double(x) * aXScale));
|
|
y = static_cast<T>(ceil(double(y) * aYScale));
|
|
width = std::max<T>(0, right - x);
|
|
height = std::max<T>(0, bottom - y);
|
|
}
|
|
// 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) {
|
|
T right = static_cast<T>(ceil(double(XMost()) / aXScale));
|
|
T bottom = static_cast<T>(ceil(double(YMost()) / aYScale));
|
|
x = static_cast<T>(floor(double(x) / aXScale));
|
|
y = static_cast<T>(floor(double(y) / aYScale));
|
|
width = right - x;
|
|
height = bottom - y;
|
|
}
|
|
// 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) {
|
|
T right = static_cast<T>(floor(double(XMost()) / aXScale));
|
|
T bottom = static_cast<T>(floor(double(YMost()) / aYScale));
|
|
x = static_cast<T>(ceil(double(x) / aXScale));
|
|
y = static_cast<T>(ceil(double(y) / aYScale));
|
|
width = std::max<T>(0, right - x);
|
|
height = std::max<T>(0, bottom - y);
|
|
}
|
|
|
|
/**
|
|
* Clamp aPoint to this rectangle. It is allowed to end up on any
|
|
* edge of the rectangle.
|
|
*/
|
|
[[nodiscard]] Point ClampPoint(const Point& aPoint) const {
|
|
return Point(std::max(x, std::min(XMost(), aPoint.x)),
|
|
std::max(y, std::min(YMost(), aPoint.y)));
|
|
}
|
|
|
|
/**
|
|
* 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 {
|
|
Sub rect(std::max(aRect.x, x), std::max(aRect.y, y),
|
|
std::min(aRect.width, width), std::min(aRect.height, height));
|
|
rect.x = std::min(rect.XMost(), aRect.XMost()) - rect.width;
|
|
rect.y = std::min(rect.YMost(), aRect.YMost()) - rect.height;
|
|
return rect;
|
|
}
|
|
|
|
// Returns the largest rectangle that can be represented with 32-bit
|
|
// signed integers, centered around a point at 0,0. As BaseRect's represent
|
|
// the dimensions as a top-left point with a width and height, the width
|
|
// and height will be the largest positive 32-bit value. The top-left
|
|
// position coordinate is divided by two to center the rectangle around a
|
|
// point at 0,0.
|
|
static Sub MaxIntRect() {
|
|
return Sub(static_cast<T>(-std::numeric_limits<int32_t>::max() * 0.5),
|
|
static_cast<T>(-std::numeric_limits<int32_t>::max() * 0.5),
|
|
static_cast<T>(std::numeric_limits<int32_t>::max()),
|
|
static_cast<T>(std::numeric_limits<int32_t>::max()));
|
|
};
|
|
|
|
// Returns a point representing the distance, along each dimension, of the
|
|
// given point from this rectangle. The distance along a dimension is defined
|
|
// as zero if the point is within the bounds of the rectangle in that
|
|
// dimension; otherwise, it's the distance to the closer endpoint of the
|
|
// rectangle in that dimension.
|
|
Point DistanceTo(const Point& aPoint) const {
|
|
return {DistanceFromInterval(aPoint.x, x, XMost()),
|
|
DistanceFromInterval(aPoint.y, y, YMost())};
|
|
}
|
|
|
|
friend std::ostream& operator<<(
|
|
std::ostream& stream,
|
|
const BaseRect<T, Sub, Point, SizeT, MarginT>& aRect) {
|
|
return stream << "(x=" << aRect.x << ", y=" << aRect.y
|
|
<< ", w=" << aRect.width << ", h=" << aRect.height << ')';
|
|
}
|
|
|
|
private:
|
|
// Do not use the default operator== or operator!= !
|
|
// Use IsEqualEdges or IsEqualInterior explicitly.
|
|
bool operator==(const Sub& aRect) const { return false; }
|
|
bool operator!=(const Sub& aRect) const { return false; }
|
|
|
|
// Helper function for DistanceTo() that computes the distance of a
|
|
// coordinate along one dimension from an interval in that dimension.
|
|
static T DistanceFromInterval(T aCoord, T aIntervalStart, T aIntervalEnd) {
|
|
if (aCoord < aIntervalStart) {
|
|
return aIntervalStart - aCoord;
|
|
}
|
|
if (aCoord > aIntervalEnd) {
|
|
return aCoord - aIntervalEnd;
|
|
}
|
|
return 0;
|
|
}
|
|
};
|
|
|
|
} // namespace gfx
|
|
} // namespace mozilla
|
|
|
|
#endif /* MOZILLA_GFX_BASERECT_H_ */
|