paulxstretch/deps/juce/modules/juce_gui_basics/positioning/juce_RelativePointPath.cpp

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/*
==============================================================================
This file is part of the JUCE library.
Copyright (c) 2020 - Raw Material Software Limited
JUCE is an open source library subject to commercial or open-source
licensing.
By using JUCE, you agree to the terms of both the JUCE 6 End-User License
Agreement and JUCE Privacy Policy (both effective as of the 16th June 2020).
End User License Agreement: www.juce.com/juce-6-licence
Privacy Policy: www.juce.com/juce-privacy-policy
Or: You may also use this code under the terms of the GPL v3 (see
www.gnu.org/licenses).
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
{
RelativePointPath::RelativePointPath()
: usesNonZeroWinding (true),
containsDynamicPoints (false)
{
}
RelativePointPath::RelativePointPath (const RelativePointPath& other)
: usesNonZeroWinding (true),
containsDynamicPoints (false)
{
for (int i = 0; i < other.elements.size(); ++i)
elements.add (other.elements.getUnchecked(i)->clone());
}
RelativePointPath::RelativePointPath (const Path& path)
: usesNonZeroWinding (path.isUsingNonZeroWinding()),
containsDynamicPoints (false)
{
for (Path::Iterator i (path); i.next();)
{
switch (i.elementType)
{
case Path::Iterator::startNewSubPath: elements.add (new StartSubPath (RelativePoint (i.x1, i.y1))); break;
case Path::Iterator::lineTo: elements.add (new LineTo (RelativePoint (i.x1, i.y1))); break;
case Path::Iterator::quadraticTo: elements.add (new QuadraticTo (RelativePoint (i.x1, i.y1), RelativePoint (i.x2, i.y2))); break;
case Path::Iterator::cubicTo: elements.add (new CubicTo (RelativePoint (i.x1, i.y1), RelativePoint (i.x2, i.y2), RelativePoint (i.x3, i.y3))); break;
case Path::Iterator::closePath: elements.add (new CloseSubPath()); break;
default: jassertfalse; break;
}
}
}
RelativePointPath::~RelativePointPath()
{
}
bool RelativePointPath::operator== (const RelativePointPath& other) const noexcept
{
if (elements.size() != other.elements.size()
|| usesNonZeroWinding != other.usesNonZeroWinding
|| containsDynamicPoints != other.containsDynamicPoints)
return false;
for (int i = 0; i < elements.size(); ++i)
{
ElementBase* const e1 = elements.getUnchecked(i);
ElementBase* const e2 = other.elements.getUnchecked(i);
if (e1->type != e2->type)
return false;
int numPoints1, numPoints2;
const RelativePoint* const points1 = e1->getControlPoints (numPoints1);
const RelativePoint* const points2 = e2->getControlPoints (numPoints2);
jassert (numPoints1 == numPoints2);
for (int j = numPoints1; --j >= 0;)
if (points1[j] != points2[j])
return false;
}
return true;
}
bool RelativePointPath::operator!= (const RelativePointPath& other) const noexcept
{
return ! operator== (other);
}
void RelativePointPath::swapWith (RelativePointPath& other) noexcept
{
elements.swapWith (other.elements);
std::swap (usesNonZeroWinding, other.usesNonZeroWinding);
std::swap (containsDynamicPoints, other.containsDynamicPoints);
}
void RelativePointPath::createPath (Path& path, Expression::Scope* scope) const
{
for (int i = 0; i < elements.size(); ++i)
elements.getUnchecked(i)->addToPath (path, scope);
}
bool RelativePointPath::containsAnyDynamicPoints() const
{
return containsDynamicPoints;
}
void RelativePointPath::addElement (ElementBase* newElement)
{
if (newElement != nullptr)
{
elements.add (newElement);
containsDynamicPoints = containsDynamicPoints || newElement->isDynamic();
}
}
//==============================================================================
RelativePointPath::ElementBase::ElementBase (const ElementType type_) : type (type_)
{
}
bool RelativePointPath::ElementBase::isDynamic()
{
int numPoints;
const RelativePoint* const points = getControlPoints (numPoints);
for (int i = numPoints; --i >= 0;)
if (points[i].isDynamic())
return true;
return false;
}
//==============================================================================
RelativePointPath::StartSubPath::StartSubPath (const RelativePoint& pos)
: ElementBase (startSubPathElement), startPos (pos)
{
}
void RelativePointPath::StartSubPath::addToPath (Path& path, Expression::Scope* scope) const
{
path.startNewSubPath (startPos.resolve (scope));
}
RelativePoint* RelativePointPath::StartSubPath::getControlPoints (int& numPoints)
{
numPoints = 1;
return &startPos;
}
RelativePointPath::ElementBase* RelativePointPath::StartSubPath::clone() const
{
return new StartSubPath (startPos);
}
//==============================================================================
RelativePointPath::CloseSubPath::CloseSubPath()
: ElementBase (closeSubPathElement)
{
}
void RelativePointPath::CloseSubPath::addToPath (Path& path, Expression::Scope*) const
{
path.closeSubPath();
}
RelativePoint* RelativePointPath::CloseSubPath::getControlPoints (int& numPoints)
{
numPoints = 0;
return nullptr;
}
RelativePointPath::ElementBase* RelativePointPath::CloseSubPath::clone() const
{
return new CloseSubPath();
}
//==============================================================================
RelativePointPath::LineTo::LineTo (const RelativePoint& endPoint_)
: ElementBase (lineToElement), endPoint (endPoint_)
{
}
void RelativePointPath::LineTo::addToPath (Path& path, Expression::Scope* scope) const
{
path.lineTo (endPoint.resolve (scope));
}
RelativePoint* RelativePointPath::LineTo::getControlPoints (int& numPoints)
{
numPoints = 1;
return &endPoint;
}
RelativePointPath::ElementBase* RelativePointPath::LineTo::clone() const
{
return new LineTo (endPoint);
}
//==============================================================================
RelativePointPath::QuadraticTo::QuadraticTo (const RelativePoint& controlPoint, const RelativePoint& endPoint)
: ElementBase (quadraticToElement)
{
controlPoints[0] = controlPoint;
controlPoints[1] = endPoint;
}
void RelativePointPath::QuadraticTo::addToPath (Path& path, Expression::Scope* scope) const
{
path.quadraticTo (controlPoints[0].resolve (scope),
controlPoints[1].resolve (scope));
}
RelativePoint* RelativePointPath::QuadraticTo::getControlPoints (int& numPoints)
{
numPoints = 2;
return controlPoints;
}
RelativePointPath::ElementBase* RelativePointPath::QuadraticTo::clone() const
{
return new QuadraticTo (controlPoints[0], controlPoints[1]);
}
//==============================================================================
RelativePointPath::CubicTo::CubicTo (const RelativePoint& controlPoint1, const RelativePoint& controlPoint2, const RelativePoint& endPoint)
: ElementBase (cubicToElement)
{
controlPoints[0] = controlPoint1;
controlPoints[1] = controlPoint2;
controlPoints[2] = endPoint;
}
void RelativePointPath::CubicTo::addToPath (Path& path, Expression::Scope* scope) const
{
path.cubicTo (controlPoints[0].resolve (scope),
controlPoints[1].resolve (scope),
controlPoints[2].resolve (scope));
}
RelativePoint* RelativePointPath::CubicTo::getControlPoints (int& numPoints)
{
numPoints = 3;
return controlPoints;
}
RelativePointPath::ElementBase* RelativePointPath::CubicTo::clone() const
{
return new CubicTo (controlPoints[0], controlPoints[1], controlPoints[2]);
}
} // namespace juce