Source/WebCore/platform/graphics/GeometryUtilities.cpp - WebKit - Git at Google

 /*
  * Copyright (C) 2014 Apple Inc. All rights reserved.
  *
  * Redistribution and use in source and binary forms, with or without
  * modification, are permitted provided that the following conditions
  * are met:
  * 1. Redistributions of source code must retain the above copyright
  *    notice, this list of conditions and the following disclaimer.
  * 2. Redistributions in binary form must reproduce the above copyright
  *    notice, this list of conditions and the following disclaimer in the
  *    documentation and/or other materials provided with the distribution.
  *
  * THIS SOFTWARE IS PROVIDED BY APPLE INC. AND ITS CONTRIBUTORS ``AS IS''
  * AND ANY EXPRESS OR IMPLIED WARRANTIES, INCLUDING, BUT NOT LIMITED TO,
  * THE IMPLIED WARRANTIES OF MERCHANTABILITY AND FITNESS FOR A PARTICULAR
  * PURPOSE ARE DISCLAIMED. IN NO EVENT SHALL APPLE INC. OR ITS CONTRIBUTORS
  * BE LIABLE FOR ANY DIRECT, INDIRECT, INCIDENTAL, SPECIAL, EXEMPLARY, OR
  * CONSEQUENTIAL DAMAGES (INCLUDING, BUT NOT LIMITED TO, PROCUREMENT OF
  * SUBSTITUTE GOODS OR SERVICES; LOSS OF USE, DATA, OR PROFITS; OR BUSINESS
  * INTERRUPTION) HOWEVER CAUSED AND ON ANY THEORY OF LIABILITY, WHETHER IN
  * CONTRACT, STRICT LIABILITY, OR TORT (INCLUDING NEGLIGENCE OR OTHERWISE)
  * ARISING IN ANY WAY OUT OF THE USE OF THIS SOFTWARE, EVEN IF ADVISED OF
  * THE POSSIBILITY OF SUCH DAMAGE.
  */

 #include "config.h"
 #include "GeometryUtilities.h"

 #include "FloatQuad.h"
 #include <wtf/MathExtras.h>
 #include <wtf/Vector.h>

 namespace WebCore {

 float euclidianDistance(const FloatSize& delta)
 {
     return std::hypot(delta.width(), delta.height());
 }

 float euclidianDistance(const FloatPoint& p1, const FloatPoint& p2)
 {
     return euclidianDistance(p1 - p2);
 }

 float findSlope(const FloatPoint& p1, const FloatPoint& p2, float& c)
 {
     if (p2.x() == p1.x())
         return std::numeric_limits<float>::infinity();

     // y = mx + c
     float slope = (p2.y() - p1.y()) / (p2.x() - p1.x());
     c = p1.y() - slope * p1.x();
     return slope;
 }

 bool findIntersection(const FloatPoint& p1, const FloatPoint& p2, const FloatPoint& d1, const FloatPoint& d2, FloatPoint& intersection)
 {
     float pOffset = 0;
     float pSlope = findSlope(p1, p2, pOffset);

     float dOffset = 0;
     float dSlope = findSlope(d1, d2, dOffset);

     if (dSlope == pSlope)
         return false;

     if (pSlope == std::numeric_limits<float>::infinity()) {
         intersection.setX(p1.x());
         intersection.setY(dSlope * intersection.x() + dOffset);
         return true;
     }
     if (dSlope == std::numeric_limits<float>::infinity()) {
         intersection.setX(d1.x());
         intersection.setY(pSlope * intersection.x() + pOffset);
         return true;
     }

     // Find x at intersection, where ys overlap; x = (c' - c) / (m - m')
     intersection.setX((dOffset - pOffset) / (pSlope - dSlope));
     intersection.setY(pSlope * intersection.x() + pOffset);
     return true;
 }

 IntRect unionRect(const Vector<IntRect>& rects)
 {
     IntRect result;
     for (auto& rect : rects)
         result.unite(rect);
     return result;
 }

 FloatRect unionRect(const Vector<FloatRect>& rects)
 {
     FloatRect result;
     for (auto& rect : rects)
         result.unite(rect);
     return result;
 }

 FloatRect unionRectIgnoringZeroRects(const Vector<FloatRect>& rects)
 {
     FloatRect result;
     for (auto& rect : rects)
         result.uniteIfNonZero(rect);
     return result;
 }

 FloatPoint mapPoint(FloatPoint p, const FloatRect& srcRect, const FloatRect& destRect)
 {
     if (!srcRect.width() || !srcRect.height())
         return p;

     float widthScale = destRect.width() / srcRect.width();
     float heightScale = destRect.height() / srcRect.height();

     return {
         destRect.x() + (p.x() - srcRect.x()) * widthScale,
         destRect.y() + (p.y() - srcRect.y()) * heightScale
     };
 }

 FloatRect mapRect(const FloatRect& r, const FloatRect& srcRect, const FloatRect& destRect)
 {
     if (!srcRect.width() || !srcRect.height())
         return FloatRect();

     float widthScale = destRect.width() / srcRect.width();
     float heightScale = destRect.height() / srcRect.height();
     return {
         destRect.x() + (r.x() - srcRect.x()) * widthScale,
         destRect.y() + (r.y() - srcRect.y()) * heightScale,
         r.width() * widthScale,
         r.height() * heightScale
     };
 }

 FloatRect largestRectWithAspectRatioInsideRect(float aspectRatio, const FloatRect& srcRect)
 {
     FloatRect destRect = srcRect;

     if (aspectRatio > srcRect.size().aspectRatio()) {
         float dy = destRect.width() / aspectRatio - destRect.height();
         destRect.inflateY(dy / 2);
     } else {
         float dx = destRect.height() * aspectRatio - destRect.width();
         destRect.inflateX(dx / 2);
     }
     return destRect;
 }

 FloatRect boundsOfRotatingRect(const FloatRect& r)
 {
     // Compute the furthest corner from the origin.
     float maxCornerDistance = euclidianDistance(FloatPoint(), r.minXMinYCorner());
     maxCornerDistance = std::max(maxCornerDistance, euclidianDistance(FloatPoint(), r.maxXMinYCorner()));
     maxCornerDistance = std::max(maxCornerDistance, euclidianDistance(FloatPoint(), r.minXMaxYCorner()));
     maxCornerDistance = std::max(maxCornerDistance, euclidianDistance(FloatPoint(), r.maxXMaxYCorner()));

     return FloatRect(-maxCornerDistance, -maxCornerDistance, 2 * maxCornerDistance, 2 * maxCornerDistance);
 }

 FloatRect smallestRectWithAspectRatioAroundRect(float aspectRatio, const FloatRect& srcRect)
 {
     FloatRect destRect = srcRect;

     if (aspectRatio < srcRect.size().aspectRatio()) {
         float dy = destRect.width() / aspectRatio - destRect.height();
         destRect.inflateY(dy / 2);
     } else {
         float dx = destRect.height() * aspectRatio - destRect.width();
         destRect.inflateX(dx / 2);
     }
     return destRect;
 }

 FloatSize sizeWithAreaAndAspectRatio(float area, float aspectRatio)
 {
     auto scaledWidth = std::sqrt(area * aspectRatio);
     return { scaledWidth, scaledWidth / aspectRatio };
 }

 bool ellipseContainsPoint(const FloatPoint& center, const FloatSize& radii, const FloatPoint& point)
 {
     if (radii.width() <= 0 || radii.height() <= 0)
         return false;

     // First, offset the query point so that the ellipse is effectively centered at the origin.
     FloatPoint transformedPoint(point);
     transformedPoint.move(-center.x(), -center.y());

     // If the point lies outside of the bounding box determined by the radii of the ellipse, it can't possibly
     // be contained within the ellipse, so bail early.
     if (transformedPoint.x() < -radii.width() || transformedPoint.x() > radii.width() || transformedPoint.y() < -radii.height() || transformedPoint.y() > radii.height())
         return false;

     // Let (x, y) represent the translated point, and let (Rx, Ry) represent the radii of an ellipse centered at the origin.
     // (x, y) is contained within the ellipse if, after scaling the ellipse to be a unit circle, the identically scaled
     // point lies within that unit circle. In other words, the squared distance (x/Rx)^2 + (y/Ry)^2 of the transformed point
     // to the origin is no greater than 1. This is equivalent to checking whether or not the point (xRy, yRx) lies within a
     // circle of radius RxRy.
     transformedPoint.scale(radii.height(), radii.width());
     auto transformedRadius = radii.width() * radii.height();

     // We can bail early if |xRy| + |yRx| <= RxRy to avoid additional multiplications, since that means the Manhattan distance
     // of the transformed point is less than the radius, so the point must lie within the transformed circle.
     return std::abs(transformedPoint.x()) + std::abs(transformedPoint.y()) <= transformedRadius || transformedPoint.lengthSquared() <= transformedRadius * transformedRadius;
 }

 FloatPoint midPoint(const FloatPoint& first, const FloatPoint& second)
 {
     return { (first.x() + second.x()) / 2, (first.y() + second.y()) / 2 };
 }

 static float dotProduct(const FloatSize& u, const FloatSize& v)
 {
     return u.width() * v.width() + u.height() * v.height();
 }

 static float angleBetweenVectors(const FloatSize& u, const FloatSize& v)
 {
     auto magnitudes = u.diagonalLength() * v.diagonalLength();
     return magnitudes ? acos(clampTo<float>(dotProduct(u, v) / magnitudes, -1, 1)) : 0;
 }

 RotatedRect rotatedBoundingRectWithMinimumAngleOfRotation(const FloatQuad& quad, std::optional<float> minRotationInRadians)
 {
     constexpr auto twoPiFloat = 2 * piFloat;

     auto minRotationAmount = minRotationInRadians.value_or(std::numeric_limits<float>::epsilon());

     auto leftMidPoint = midPoint(quad.p1(), quad.p4());
     auto rightMidPoint = midPoint(quad.p2(), quad.p3());
     auto widthVector = rightMidPoint - leftMidPoint;

     auto midPointToMidPointDistance = widthVector.diagonalLength();
     int signOfWidthVectorHeight = widthVector.height() < 0 ? -1 : 1;
     auto angle = midPointToMidPointDistance ? signOfWidthVectorHeight * acos(widthVector.width() / midPointToMidPointDistance) : 0;
     if (angle < 0)
         angle += twoPiFloat;

     if (std::abs(angle) < minRotationAmount || std::abs(twoPiFloat - angle) < minRotationAmount) {
         auto boundingBox = quad.boundingBox();
         return { boundingBox.center(), boundingBox.size(), 0 };
     }

     auto heightVector = FloatSize { widthVector.height(), -widthVector.width() };
     auto leftPerpendicularAngle = angleBetweenVectors(heightVector, quad.p1() - leftMidPoint);
     auto rightPerpendicularAngle = angleBetweenVectors(heightVector, quad.p2() - rightMidPoint);

     auto leftHypotenuseLength = (leftMidPoint - quad.p1()).diagonalLength();
     auto rightHypotenuseLength = (rightMidPoint - quad.p2()).diagonalLength();

     auto leftMargin = leftHypotenuseLength * sin(leftPerpendicularAngle);
     auto rightMargin = rightHypotenuseLength * sin(rightPerpendicularAngle);
     auto width = midPointToMidPointDistance + leftMargin + rightMargin;
     auto height = 2 * std::max(leftHypotenuseLength * cos(leftPerpendicularAngle), rightHypotenuseLength * cos(rightPerpendicularAngle));

     auto leftMidToCenterDistance = (midPointToMidPointDistance + rightMargin - leftMargin) / 2;
     auto center = leftMidPoint + (widthVector * leftMidToCenterDistance / midPointToMidPointDistance);
     return { center, { width, height }, angle };
 }

 }
	/*
	* Copyright (C) 2014 Apple Inc. All rights reserved.
	*
	* Redistribution and use in source and binary forms, with or without
	* modification, are permitted provided that the following conditions
	* are met:
	* 1. Redistributions of source code must retain the above copyright
	* notice, this list of conditions and the following disclaimer.
	* 2. Redistributions in binary form must reproduce the above copyright
	* notice, this list of conditions and the following disclaimer in the
	* documentation and/or other materials provided with the distribution.
	*
	* THIS SOFTWARE IS PROVIDED BY APPLE INC. AND ITS CONTRIBUTORS ``AS IS''
	* AND ANY EXPRESS OR IMPLIED WARRANTIES, INCLUDING, BUT NOT LIMITED TO,
	* THE IMPLIED WARRANTIES OF MERCHANTABILITY AND FITNESS FOR A PARTICULAR
	* PURPOSE ARE DISCLAIMED. IN NO EVENT SHALL APPLE INC. OR ITS CONTRIBUTORS
	* BE LIABLE FOR ANY DIRECT, INDIRECT, INCIDENTAL, SPECIAL, EXEMPLARY, OR
	* CONSEQUENTIAL DAMAGES (INCLUDING, BUT NOT LIMITED TO, PROCUREMENT OF
	* SUBSTITUTE GOODS OR SERVICES; LOSS OF USE, DATA, OR PROFITS; OR BUSINESS
	* INTERRUPTION) HOWEVER CAUSED AND ON ANY THEORY OF LIABILITY, WHETHER IN
	* CONTRACT, STRICT LIABILITY, OR TORT (INCLUDING NEGLIGENCE OR OTHERWISE)
	* ARISING IN ANY WAY OUT OF THE USE OF THIS SOFTWARE, EVEN IF ADVISED OF
	* THE POSSIBILITY OF SUCH DAMAGE.
	*/

	#include "config.h"
	#include "GeometryUtilities.h"

	#include "FloatQuad.h"
	#include <wtf/MathExtras.h>
	#include <wtf/Vector.h>

	namespace WebCore {

	float euclidianDistance(const FloatSize& delta)
	{
	return std::hypot(delta.width(), delta.height());
	}

	float euclidianDistance(const FloatPoint& p1, const FloatPoint& p2)
	{
	return euclidianDistance(p1 - p2);
	}

	float findSlope(const FloatPoint& p1, const FloatPoint& p2, float& c)
	{
	if (p2.x() == p1.x())
	return std::numeric_limits<float>::infinity();

	// y = mx + c
	float slope = (p2.y() - p1.y()) / (p2.x() - p1.x());
	c = p1.y() - slope * p1.x();
	return slope;
	}

	bool findIntersection(const FloatPoint& p1, const FloatPoint& p2, const FloatPoint& d1, const FloatPoint& d2, FloatPoint& intersection)
	{
	float pOffset = 0;
	float pSlope = findSlope(p1, p2, pOffset);

	float dOffset = 0;
	float dSlope = findSlope(d1, d2, dOffset);

	if (dSlope == pSlope)
	return false;

	if (pSlope == std::numeric_limits<float>::infinity()) {
	intersection.setX(p1.x());
	intersection.setY(dSlope * intersection.x() + dOffset);
	return true;
	}
	if (dSlope == std::numeric_limits<float>::infinity()) {
	intersection.setX(d1.x());
	intersection.setY(pSlope * intersection.x() + pOffset);
	return true;
	}

	// Find x at intersection, where ys overlap; x = (c' - c) / (m - m')
	intersection.setX((dOffset - pOffset) / (pSlope - dSlope));
	intersection.setY(pSlope * intersection.x() + pOffset);
	return true;
	}

	IntRect unionRect(const Vector<IntRect>& rects)
	{
	IntRect result;
	for (auto& rect : rects)
	result.unite(rect);
	return result;
	}

	FloatRect unionRect(const Vector<FloatRect>& rects)
	{
	FloatRect result;
	for (auto& rect : rects)
	result.unite(rect);
	return result;
	}

	FloatRect unionRectIgnoringZeroRects(const Vector<FloatRect>& rects)
	{
	FloatRect result;
	for (auto& rect : rects)
	result.uniteIfNonZero(rect);
	return result;
	}

	FloatPoint mapPoint(FloatPoint p, const FloatRect& srcRect, const FloatRect& destRect)
	{
	if (!srcRect.width() \|\| !srcRect.height())
	return p;

	float widthScale = destRect.width() / srcRect.width();
	float heightScale = destRect.height() / srcRect.height();

	return {
	destRect.x() + (p.x() - srcRect.x()) * widthScale,
	destRect.y() + (p.y() - srcRect.y()) * heightScale
	};
	}

	FloatRect mapRect(const FloatRect& r, const FloatRect& srcRect, const FloatRect& destRect)
	{
	if (!srcRect.width() \|\| !srcRect.height())
	return FloatRect();

	float widthScale = destRect.width() / srcRect.width();
	float heightScale = destRect.height() / srcRect.height();
	return {
	destRect.x() + (r.x() - srcRect.x()) * widthScale,
	destRect.y() + (r.y() - srcRect.y()) * heightScale,
	r.width() * widthScale,
	r.height() * heightScale
	};
	}

	FloatRect largestRectWithAspectRatioInsideRect(float aspectRatio, const FloatRect& srcRect)
	{
	FloatRect destRect = srcRect;

	if (aspectRatio > srcRect.size().aspectRatio()) {
	float dy = destRect.width() / aspectRatio - destRect.height();
	destRect.inflateY(dy / 2);
	} else {
	float dx = destRect.height() * aspectRatio - destRect.width();
	destRect.inflateX(dx / 2);
	}
	return destRect;
	}

	FloatRect boundsOfRotatingRect(const FloatRect& r)
	{
	// Compute the furthest corner from the origin.
	float maxCornerDistance = euclidianDistance(FloatPoint(), r.minXMinYCorner());
	maxCornerDistance = std::max(maxCornerDistance, euclidianDistance(FloatPoint(), r.maxXMinYCorner()));
	maxCornerDistance = std::max(maxCornerDistance, euclidianDistance(FloatPoint(), r.minXMaxYCorner()));
	maxCornerDistance = std::max(maxCornerDistance, euclidianDistance(FloatPoint(), r.maxXMaxYCorner()));

	return FloatRect(-maxCornerDistance, -maxCornerDistance, 2 * maxCornerDistance, 2 * maxCornerDistance);
	}

	FloatRect smallestRectWithAspectRatioAroundRect(float aspectRatio, const FloatRect& srcRect)
	{
	FloatRect destRect = srcRect;

	if (aspectRatio < srcRect.size().aspectRatio()) {
	float dy = destRect.width() / aspectRatio - destRect.height();
	destRect.inflateY(dy / 2);
	} else {
	float dx = destRect.height() * aspectRatio - destRect.width();
	destRect.inflateX(dx / 2);
	}
	return destRect;
	}

	FloatSize sizeWithAreaAndAspectRatio(float area, float aspectRatio)
	{
	auto scaledWidth = std::sqrt(area * aspectRatio);
	return { scaledWidth, scaledWidth / aspectRatio };
	}

	bool ellipseContainsPoint(const FloatPoint& center, const FloatSize& radii, const FloatPoint& point)
	{
	if (radii.width() <= 0 \|\| radii.height() <= 0)
	return false;

	// First, offset the query point so that the ellipse is effectively centered at the origin.
	FloatPoint transformedPoint(point);
	transformedPoint.move(-center.x(), -center.y());

	// If the point lies outside of the bounding box determined by the radii of the ellipse, it can't possibly
	// be contained within the ellipse, so bail early.
	if (transformedPoint.x() < -radii.width() \|\| transformedPoint.x() > radii.width() \|\| transformedPoint.y() < -radii.height() \|\| transformedPoint.y() > radii.height())
	return false;

	// Let (x, y) represent the translated point, and let (Rx, Ry) represent the radii of an ellipse centered at the origin.
	// (x, y) is contained within the ellipse if, after scaling the ellipse to be a unit circle, the identically scaled
	// point lies within that unit circle. In other words, the squared distance (x/Rx)^2 + (y/Ry)^2 of the transformed point
	// to the origin is no greater than 1. This is equivalent to checking whether or not the point (xRy, yRx) lies within a
	// circle of radius RxRy.
	transformedPoint.scale(radii.height(), radii.width());
	auto transformedRadius = radii.width() * radii.height();

	// We can bail early if \|xRy\| + \|yRx\| <= RxRy to avoid additional multiplications, since that means the Manhattan distance
	// of the transformed point is less than the radius, so the point must lie within the transformed circle.
	return std::abs(transformedPoint.x()) + std::abs(transformedPoint.y()) <= transformedRadius \|\| transformedPoint.lengthSquared() <= transformedRadius * transformedRadius;
	}

	FloatPoint midPoint(const FloatPoint& first, const FloatPoint& second)
	{
	return { (first.x() + second.x()) / 2, (first.y() + second.y()) / 2 };
	}

	static float dotProduct(const FloatSize& u, const FloatSize& v)
	{
	return u.width() * v.width() + u.height() * v.height();
	}

	static float angleBetweenVectors(const FloatSize& u, const FloatSize& v)
	{
	auto magnitudes = u.diagonalLength() * v.diagonalLength();
	return magnitudes ? acos(clampTo<float>(dotProduct(u, v) / magnitudes, -1, 1)) : 0;
	}

	RotatedRect rotatedBoundingRectWithMinimumAngleOfRotation(const FloatQuad& quad, std::optional<float> minRotationInRadians)
	{
	constexpr auto twoPiFloat = 2 * piFloat;

	auto minRotationAmount = minRotationInRadians.value_or(std::numeric_limits<float>::epsilon());

	auto leftMidPoint = midPoint(quad.p1(), quad.p4());
	auto rightMidPoint = midPoint(quad.p2(), quad.p3());
	auto widthVector = rightMidPoint - leftMidPoint;

	auto midPointToMidPointDistance = widthVector.diagonalLength();
	int signOfWidthVectorHeight = widthVector.height() < 0 ? -1 : 1;
	auto angle = midPointToMidPointDistance ? signOfWidthVectorHeight * acos(widthVector.width() / midPointToMidPointDistance) : 0;
	if (angle < 0)
	angle += twoPiFloat;

	if (std::abs(angle) < minRotationAmount \|\| std::abs(twoPiFloat - angle) < minRotationAmount) {
	auto boundingBox = quad.boundingBox();
	return { boundingBox.center(), boundingBox.size(), 0 };
	}

	auto heightVector = FloatSize { widthVector.height(), -widthVector.width() };
	auto leftPerpendicularAngle = angleBetweenVectors(heightVector, quad.p1() - leftMidPoint);
	auto rightPerpendicularAngle = angleBetweenVectors(heightVector, quad.p2() - rightMidPoint);

	auto leftHypotenuseLength = (leftMidPoint - quad.p1()).diagonalLength();
	auto rightHypotenuseLength = (rightMidPoint - quad.p2()).diagonalLength();

	auto leftMargin = leftHypotenuseLength * sin(leftPerpendicularAngle);
	auto rightMargin = rightHypotenuseLength * sin(rightPerpendicularAngle);
	auto width = midPointToMidPointDistance + leftMargin + rightMargin;
	auto height = 2 * std::max(leftHypotenuseLength * cos(leftPerpendicularAngle), rightHypotenuseLength * cos(rightPerpendicularAngle));

	auto leftMidToCenterDistance = (midPointToMidPointDistance + rightMargin - leftMargin) / 2;
	auto center = leftMidPoint + (widthVector * leftMidToCenterDistance / midPointToMidPointDistance);
	return { center, { width, height }, angle };
	}

	}