/* ============================================================================== This file is part of the JUCE 6 technical preview. Copyright (c) 2017 - ROLI Ltd. You may use this code under the terms of the GPL v3 (see www.gnu.org/licenses). For this technical preview, this file is not subject to commercial licensing. JUCE IS PROVIDED "AS IS" WITHOUT ANY WARRANTY, AND ALL WARRANTIES, WHETHER EXPRESSED OR IMPLIED, INCLUDING MERCHANTABILITY AND FITNESS FOR PURPOSE, ARE DISCLAIMED. ============================================================================== */ namespace juce { RelativeParallelogram::RelativeParallelogram() { } RelativeParallelogram::RelativeParallelogram (const Rectangle& r) : topLeft (r.getTopLeft()), topRight (r.getTopRight()), bottomLeft (r.getBottomLeft()) { } RelativeParallelogram::RelativeParallelogram (const RelativePoint& topLeft_, const RelativePoint& topRight_, const RelativePoint& bottomLeft_) : topLeft (topLeft_), topRight (topRight_), bottomLeft (bottomLeft_) { } RelativeParallelogram::RelativeParallelogram (const String& topLeft_, const String& topRight_, const String& bottomLeft_) : topLeft (topLeft_), topRight (topRight_), bottomLeft (bottomLeft_) { } RelativeParallelogram::~RelativeParallelogram() { } void RelativeParallelogram::resolveThreePoints (Point* points, Expression::Scope* const scope) const { points[0] = topLeft.resolve (scope); points[1] = topRight.resolve (scope); points[2] = bottomLeft.resolve (scope); } void RelativeParallelogram::resolveFourCorners (Point* points, Expression::Scope* const scope) const { resolveThreePoints (points, scope); points[3] = points[1] + (points[2] - points[0]); } const Rectangle RelativeParallelogram::getBounds (Expression::Scope* const scope) const { Point points[4]; resolveFourCorners (points, scope); return Rectangle::findAreaContainingPoints (points, 4); } void RelativeParallelogram::getPath (Path& path, Expression::Scope* const scope) const { Point points[4]; resolveFourCorners (points, scope); path.startNewSubPath (points[0]); path.lineTo (points[1]); path.lineTo (points[3]); path.lineTo (points[2]); path.closeSubPath(); } AffineTransform RelativeParallelogram::resetToPerpendicular (Expression::Scope* const scope) { Point corners[3]; resolveThreePoints (corners, scope); const Line top (corners[0], corners[1]); const Line left (corners[0], corners[2]); const Point newTopRight (corners[0] + Point (top.getLength(), 0.0f)); const Point newBottomLeft (corners[0] + Point (0.0f, left.getLength())); topRight.moveToAbsolute (newTopRight, scope); bottomLeft.moveToAbsolute (newBottomLeft, scope); return AffineTransform::fromTargetPoints (corners[0], corners[0], corners[1], newTopRight, corners[2], newBottomLeft); } bool RelativeParallelogram::isDynamic() const { return topLeft.isDynamic() || topRight.isDynamic() || bottomLeft.isDynamic(); } bool RelativeParallelogram::operator== (const RelativeParallelogram& other) const noexcept { return topLeft == other.topLeft && topRight == other.topRight && bottomLeft == other.bottomLeft; } bool RelativeParallelogram::operator!= (const RelativeParallelogram& other) const noexcept { return ! operator== (other); } Point RelativeParallelogram::getInternalCoordForPoint (const Point* const corners, Point target) noexcept { const Point tr (corners[1] - corners[0]); const Point bl (corners[2] - corners[0]); target -= corners[0]; return Point (Line (Point(), tr).getIntersection (Line (target, target - bl)).getDistanceFromOrigin(), Line (Point(), bl).getIntersection (Line (target, target - tr)).getDistanceFromOrigin()); } Point RelativeParallelogram::getPointForInternalCoord (const Point* const corners, const Point point) noexcept { return corners[0] + Line (Point(), corners[1] - corners[0]).getPointAlongLine (point.x) + Line (Point(), corners[2] - corners[0]).getPointAlongLine (point.y); } Rectangle RelativeParallelogram::getBoundingBox (const Point* const p) noexcept { const Point points[] = { p[0], p[1], p[2], p[1] + (p[2] - p[0]) }; return Rectangle::findAreaContainingPoints (points, 4); } } // namespace juce