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// Copyright (C) 2016 The Qt Company Ltd.
// SPDX-License-Identifier: LicenseRef-Qt-Commercial OR LGPL-3.0-only OR GPL-2.0-only OR GPL-3.0-only
#include "qopengl2pexvertexarray_p.h"
#include <private/qbezier_p.h>
QT_BEGIN_NAMESPACE
void QOpenGL2PEXVertexArray::clear()
{
vertexArray.reset();
vertexArrayStops.reset();
boundingRectDirty = true;
}
QOpenGLRect QOpenGL2PEXVertexArray::boundingRect() const
{
if (boundingRectDirty)
return QOpenGLRect(0.0, 0.0, 0.0, 0.0);
else
return QOpenGLRect(minX, minY, maxX, maxY);
}
void QOpenGL2PEXVertexArray::addClosingLine(int index)
{
QPointF point(vertexArray.at(index));
if (point != QPointF(vertexArray.last()))
vertexArray.add(point);
}
void QOpenGL2PEXVertexArray::addCentroid(const QVectorPath &path, int subPathIndex)
{
const QPointF *const points = reinterpret_cast<const QPointF *>(path.points());
const QPainterPath::ElementType *const elements = path.elements();
QPointF sum = points[subPathIndex];
int count = 1;
for (int i = subPathIndex + 1; i < path.elementCount() && (!elements || elements[i] != QPainterPath::MoveToElement); ++i) {
sum += points[i];
++count;
}
const QPointF centroid = sum / qreal(count);
vertexArray.add(centroid);
}
void QOpenGL2PEXVertexArray::addPath(const QVectorPath &path, GLfloat curveInverseScale, bool outline)
{
const QPointF* const points = reinterpret_cast<const QPointF*>(path.points());
const QPainterPath::ElementType* const elements = path.elements();
if (boundingRectDirty) {
minX = maxX = points[0].x();
minY = maxY = points[0].y();
boundingRectDirty = false;
}
if (!outline && !path.isConvex())
addCentroid(path, 0);
int lastMoveTo = vertexArray.size();
vertexArray.add(points[0]); // The first element is always a moveTo
do {
if (!elements) {
// qDebug("QVectorPath has no elements");
// If the path has a null elements pointer, the elements implicitly
// start with a moveTo (already added) and continue with lineTos:
for (int i=1; i<path.elementCount(); ++i)
lineToArray(points[i].x(), points[i].y());
break;
}
// qDebug("QVectorPath has element types");
for (int i=1; i<path.elementCount(); ++i) {
switch (elements[i]) {
case QPainterPath::MoveToElement:
if (!outline)
addClosingLine(lastMoveTo);
// qDebug("element[%d] is a MoveToElement", i);
vertexArrayStops.add(vertexArray.size());
if (!outline) {
if (!path.isConvex()) addCentroid(path, i);
lastMoveTo = vertexArray.size();
}
lineToArray(points[i].x(), points[i].y()); // Add the moveTo as a new vertex
break;
case QPainterPath::LineToElement:
// qDebug("element[%d] is a LineToElement", i);
lineToArray(points[i].x(), points[i].y());
break;
case QPainterPath::CurveToElement: {
QBezier b = QBezier::fromPoints(*(((const QPointF *) points) + i - 1),
points[i],
points[i+1],
points[i+2]);
QRectF bounds = b.bounds();
// threshold based on same algorithm as in qtriangulatingstroker.cpp
int threshold = qMin<float>(64, qMax(bounds.width(), bounds.height()) * 3.14f / (curveInverseScale * 6));
if (threshold < 3) threshold = 3;
qreal one_over_threshold_minus_1 = qreal(1) / (threshold - 1);
for (int t=0; t<threshold; ++t) {
QPointF pt = b.pointAt(t * one_over_threshold_minus_1);
lineToArray(pt.x(), pt.y());
}
i += 2;
break; }
default:
break;
}
}
} while (0);
if (!outline)
addClosingLine(lastMoveTo);
vertexArrayStops.add(vertexArray.size());
}
void QOpenGL2PEXVertexArray::lineToArray(const GLfloat x, const GLfloat y)
{
vertexArray.add(QOpenGLPoint(x, y));
if (x > maxX)
maxX = x;
else if (x < minX)
minX = x;
if (y > maxY)
maxY = y;
else if (y < minY)
minY = y;
}
QT_END_NAMESPACE
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