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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 "qbezier_p.h"
#include <qdebug.h>
#include <qline.h>
#include <qmath.h>
#include <qpolygon.h>
#include <private/qnumeric_p.h>
#include <tuple> // for std::tie()
QT_BEGIN_NAMESPACE
//#define QDEBUG_BEZIER
/*!
\internal
*/
QPolygonF QBezier::toPolygon(qreal bezier_flattening_threshold) const
{
// flattening is done by splitting the bezier until we can replace the segment by a straight
// line. We split further until the control points are close enough to the line connecting the
// boundary points.
//
// the Distance of a point p from a line given by the points (a,b) is given by:
//
// d = abs( (bx - ax)(ay - py) - (by - ay)(ax - px) ) / line_length
//
// We can stop splitting if both control points are close enough to the line.
// To make the algorithm faster we use the manhattan length of the line.
QPolygonF polygon;
polygon.append(QPointF(x1, y1));
addToPolygon(&polygon, bezier_flattening_threshold);
return polygon;
}
QBezier QBezier::mapBy(const QTransform &transform) const
{
return QBezier::fromPoints(transform.map(pt1()), transform.map(pt2()), transform.map(pt3()), transform.map(pt4()));
}
QBezier QBezier::getSubRange(qreal t0, qreal t1) const
{
QBezier result;
QBezier temp;
// cut at t1
if (qFuzzyIsNull(t1 - qreal(1.))) {
result = *this;
} else {
temp = *this;
temp.parameterSplitLeft(t1, &result);
}
// cut at t0
if (!qFuzzyIsNull(t0))
result.parameterSplitLeft(t0 / t1, &temp);
return result;
}
void QBezier::addToPolygon(QPolygonF *polygon, qreal bezier_flattening_threshold) const
{
QBezier beziers[10];
int levels[10];
beziers[0] = *this;
levels[0] = 9;
int top = 0;
while (top >= 0) {
QBezier *b = &beziers[top];
// check if we can pop the top bezier curve from the stack
qreal y4y1 = b->y4 - b->y1;
qreal x4x1 = b->x4 - b->x1;
qreal l = qAbs(x4x1) + qAbs(y4y1);
qreal d;
if (l > 1.) {
d = qAbs( (x4x1)*(b->y1 - b->y2) - (y4y1)*(b->x1 - b->x2) )
+ qAbs( (x4x1)*(b->y1 - b->y3) - (y4y1)*(b->x1 - b->x3) );
} else {
d = qAbs(b->x1 - b->x2) + qAbs(b->y1 - b->y2) +
qAbs(b->x1 - b->x3) + qAbs(b->y1 - b->y3);
l = 1.;
}
if (d < bezier_flattening_threshold * l || levels[top] == 0) {
// good enough, we pop it off and add the endpoint
polygon->append(QPointF(b->x4, b->y4));
--top;
} else {
// split, second half of the polygon goes lower into the stack
std::tie(b[1], b[0]) = b->split();
levels[top + 1] = --levels[top];
++top;
}
}
}
void QBezier::addToPolygon(QDataBuffer<QPointF> &polygon, qreal bezier_flattening_threshold) const
{
QBezier beziers[10];
int levels[10];
beziers[0] = *this;
levels[0] = 9;
int top = 0;
while (top >= 0) {
QBezier *b = &beziers[top];
// check if we can pop the top bezier curve from the stack
qreal y4y1 = b->y4 - b->y1;
qreal x4x1 = b->x4 - b->x1;
qreal l = qAbs(x4x1) + qAbs(y4y1);
qreal d;
if (l > 1.) {
d = qAbs( (x4x1)*(b->y1 - b->y2) - (y4y1)*(b->x1 - b->x2) )
+ qAbs( (x4x1)*(b->y1 - b->y3) - (y4y1)*(b->x1 - b->x3) );
} else {
d = qAbs(b->x1 - b->x2) + qAbs(b->y1 - b->y2) +
qAbs(b->x1 - b->x3) + qAbs(b->y1 - b->y3);
l = 1.;
}
if (d < bezier_flattening_threshold * l || levels[top] == 0) {
// good enough, we pop it off and add the endpoint
polygon.add(QPointF(b->x4, b->y4));
--top;
} else {
// split, second half of the polygon goes lower into the stack
std::tie(b[1], b[0]) = b->split();
levels[top + 1] = --levels[top];
++top;
}
}
}
QRectF QBezier::bounds() const
{
qreal xmin = x1;
qreal xmax = x1;
if (x2 < xmin)
xmin = x2;
else if (x2 > xmax)
xmax = x2;
if (x3 < xmin)
xmin = x3;
else if (x3 > xmax)
xmax = x3;
if (x4 < xmin)
xmin = x4;
else if (x4 > xmax)
xmax = x4;
qreal ymin = y1;
qreal ymax = y1;
if (y2 < ymin)
ymin = y2;
else if (y2 > ymax)
ymax = y2;
if (y3 < ymin)
ymin = y3;
else if (y3 > ymax)
ymax = y3;
if (y4 < ymin)
ymin = y4;
else if (y4 > ymax)
ymax = y4;
return QRectF(xmin, ymin, xmax-xmin, ymax-ymin);
}
enum ShiftResult {
Ok,
Discard,
Split,
Circle
};
static ShiftResult good_offset(const QBezier *b1, const QBezier *b2, qreal offset, qreal threshold)
{
const qreal o2 = offset*offset;
const qreal max_dist_line = threshold*offset*offset;
const qreal max_dist_normal = threshold*offset;
const int divisions = 4;
const qreal spacing = qreal(1.0) / divisions;
qreal t = spacing;
for (int i = 1; i < divisions; ++i, t += spacing) {
QPointF p1 = b1->pointAt(t);
QPointF p2 = b2->pointAt(t);
qreal d = (p1.x() - p2.x())*(p1.x() - p2.x()) + (p1.y() - p2.y())*(p1.y() - p2.y());
if (qAbs(d - o2) > max_dist_line)
return Split;
QPointF normalPoint = b1->normalVector(t);
qreal l = qAbs(normalPoint.x()) + qAbs(normalPoint.y());
if (l != qreal(0.0)) {
d = qAbs( normalPoint.x()*(p1.y() - p2.y()) - normalPoint.y()*(p1.x() - p2.x()) ) / l;
if (d > max_dist_normal)
return Split;
}
}
return Ok;
}
QT_WARNING_DISABLE_FLOAT_COMPARE
static ShiftResult shift(const QBezier *orig, QBezier *shifted, qreal offset, qreal threshold)
{
int map[4];
bool p1_p2_equal = qFuzzyCompare(orig->x1, orig->x2) && qFuzzyCompare(orig->y1, orig->y2);
bool p2_p3_equal = qFuzzyCompare(orig->x2, orig->x3) && qFuzzyCompare(orig->y2, orig->y3);
bool p3_p4_equal = qFuzzyCompare(orig->x3, orig->x4) && qFuzzyCompare(orig->y3, orig->y4);
QPointF points[4];
int np = 0;
points[np] = QPointF(orig->x1, orig->y1);
map[0] = 0;
++np;
if (!p1_p2_equal) {
points[np] = QPointF(orig->x2, orig->y2);
++np;
}
map[1] = np - 1;
if (!p2_p3_equal) {
points[np] = QPointF(orig->x3, orig->y3);
++np;
}
map[2] = np - 1;
if (!p3_p4_equal) {
points[np] = QPointF(orig->x4, orig->y4);
++np;
}
map[3] = np - 1;
if (np == 1)
return Discard;
QRectF b = orig->bounds();
if (np == 4 && b.width() < .1*offset && b.height() < .1*offset) {
qreal l = (orig->x1 - orig->x2)*(orig->x1 - orig->x2) +
(orig->y1 - orig->y2)*(orig->y1 - orig->y2) *
(orig->x3 - orig->x4)*(orig->x3 - orig->x4) +
(orig->y3 - orig->y4)*(orig->y3 - orig->y4);
qreal dot = (orig->x1 - orig->x2)*(orig->x3 - orig->x4) +
(orig->y1 - orig->y2)*(orig->y3 - orig->y4);
if (dot < 0 && dot*dot < 0.8*l)
// the points are close and reverse dirction. Approximate the whole
// thing by a semi circle
return Circle;
}
QPointF points_shifted[4];
QLineF prev = QLineF(QPointF(), points[1] - points[0]);
if (!prev.length())
return Discard;
QPointF prev_normal = prev.normalVector().unitVector().p2();
points_shifted[0] = points[0] + offset * prev_normal;
for (int i = 1; i < np - 1; ++i) {
QLineF next = QLineF(QPointF(), points[i + 1] - points[i]);
QPointF next_normal = next.normalVector().unitVector().p2();
QPointF normal_sum = prev_normal + next_normal;
qreal r = qreal(1.0) + prev_normal.x() * next_normal.x()
+ prev_normal.y() * next_normal.y();
if (qFuzzyIsNull(r)) {
points_shifted[i] = points[i] + offset * prev_normal;
} else {
qreal k = offset / r;
points_shifted[i] = points[i] + k * normal_sum;
}
prev_normal = next_normal;
}
points_shifted[np - 1] = points[np - 1] + offset * prev_normal;
*shifted = QBezier::fromPoints(points_shifted[map[0]], points_shifted[map[1]],
points_shifted[map[2]], points_shifted[map[3]]);
if (np > 2)
return good_offset(orig, shifted, offset, threshold);
return Ok;
}
// This value is used to determine the length of control point vectors
// when approximating arc segments as curves. The factor is multiplied
// with the radius of the circle.
#define KAPPA qreal(0.5522847498)
static bool addCircle(const QBezier *b, qreal offset, QBezier *o)
{
QPointF normals[3];
normals[0] = QPointF(b->y2 - b->y1, b->x1 - b->x2);
qreal dist = qSqrt(normals[0].x()*normals[0].x() + normals[0].y()*normals[0].y());
if (qFuzzyIsNull(dist))
return false;
normals[0] /= dist;
normals[2] = QPointF(b->y4 - b->y3, b->x3 - b->x4);
dist = qSqrt(normals[2].x()*normals[2].x() + normals[2].y()*normals[2].y());
if (qFuzzyIsNull(dist))
return false;
normals[2] /= dist;
normals[1] = QPointF(b->x1 - b->x2 - b->x3 + b->x4, b->y1 - b->y2 - b->y3 + b->y4);
normals[1] /= -1*qSqrt(normals[1].x()*normals[1].x() + normals[1].y()*normals[1].y());
qreal angles[2];
qreal sign = 1.;
for (int i = 0; i < 2; ++i) {
qreal cos_a = normals[i].x()*normals[i+1].x() + normals[i].y()*normals[i+1].y();
if (cos_a > 1.)
cos_a = 1.;
if (cos_a < -1.)
cos_a = -1;
angles[i] = qAcos(cos_a) * qreal(M_1_PI);
}
if (angles[0] + angles[1] > 1.) {
// more than 180 degrees
normals[1] = -normals[1];
angles[0] = 1. - angles[0];
angles[1] = 1. - angles[1];
sign = -1.;
}
QPointF circle[3];
circle[0] = QPointF(b->x1, b->y1) + normals[0]*offset;
circle[1] = QPointF(qreal(0.5)*(b->x1 + b->x4), qreal(0.5)*(b->y1 + b->y4)) + normals[1]*offset;
circle[2] = QPointF(b->x4, b->y4) + normals[2]*offset;
for (int i = 0; i < 2; ++i) {
qreal kappa = qreal(2.0) * KAPPA * sign * offset * angles[i];
o->x1 = circle[i].x();
o->y1 = circle[i].y();
o->x2 = circle[i].x() - normals[i].y()*kappa;
o->y2 = circle[i].y() + normals[i].x()*kappa;
o->x3 = circle[i+1].x() + normals[i+1].y()*kappa;
o->y3 = circle[i+1].y() - normals[i+1].x()*kappa;
o->x4 = circle[i+1].x();
o->y4 = circle[i+1].y();
++o;
}
return true;
}
int QBezier::shifted(QBezier *curveSegments, int maxSegments, qreal offset, float threshold) const
{
Q_ASSERT(curveSegments);
Q_ASSERT(maxSegments > 0);
if (qFuzzyCompare(x1, x2) && qFuzzyCompare(x1, x3) && qFuzzyCompare(x1, x4) &&
qFuzzyCompare(y1, y2) && qFuzzyCompare(y1, y3) && qFuzzyCompare(y1, y4))
return 0;
--maxSegments;
QBezier beziers[10];
redo:
beziers[0] = *this;
QBezier *b = beziers;
QBezier *o = curveSegments;
while (b >= beziers) {
int stack_segments = b - beziers + 1;
if ((stack_segments == 10) || (o - curveSegments == maxSegments - stack_segments)) {
threshold *= qreal(1.5);
if (threshold > qreal(2.0))
goto give_up;
goto redo;
}
ShiftResult res = shift(b, o, offset, threshold);
if (res == Discard) {
--b;
} else if (res == Ok) {
++o;
--b;
} else if (res == Circle && maxSegments - (o - curveSegments) >= 2) {
// add semi circle
if (addCircle(b, offset, o))
o += 2;
--b;
} else {
std::tie(b[1], b[0]) = b->split();
++b;
}
}
give_up:
while (b >= beziers) {
ShiftResult res = shift(b, o, offset, threshold);
// if res isn't Ok or Split then *o is undefined
if (res == Ok || res == Split)
++o;
--b;
}
Q_ASSERT(o - curveSegments <= maxSegments);
return o - curveSegments;
}
#ifdef QDEBUG_BEZIER
static QDebug operator<<(QDebug dbg, const QBezier &bz)
{
dbg << '[' << bz.x1<< ", " << bz.y1 << "], "
<< '[' << bz.x2 <<", " << bz.y2 << "], "
<< '[' << bz.x3 <<", " << bz.y3 << "], "
<< '[' << bz.x4 <<", " << bz.y4 << ']';
return dbg;
}
#endif
qreal QBezier::length(qreal error) const
{
qreal length = qreal(0.0);
addIfClose(&length, error);
return length;
}
void QBezier::addIfClose(qreal *length, qreal error) const
{
qreal len = qreal(0.0); /* arc length */
qreal chord; /* chord length */
len = len + QLineF(QPointF(x1, y1),QPointF(x2, y2)).length();
len = len + QLineF(QPointF(x2, y2),QPointF(x3, y3)).length();
len = len + QLineF(QPointF(x3, y3),QPointF(x4, y4)).length();
chord = QLineF(QPointF(x1, y1),QPointF(x4, y4)).length();
if ((len-chord) > error) {
const auto halves = split(); /* split in two */
halves.first.addIfClose(length, error); /* try left side */
halves.second.addIfClose(length, error); /* try right side */
return;
}
*length = *length + len;
return;
}
qreal QBezier::tForY(qreal t0, qreal t1, qreal y) const
{
qreal py0 = pointAt(t0).y();
qreal py1 = pointAt(t1).y();
if (py0 > py1) {
qSwap(py0, py1);
qSwap(t0, t1);
}
Q_ASSERT(py0 <= py1);
if (py0 >= y)
return t0;
else if (py1 <= y)
return t1;
Q_ASSERT(py0 < y && y < py1);
qreal lt = t0;
qreal dt;
do {
qreal t = qreal(0.5) * (t0 + t1);
qreal a, b, c, d;
QBezier::coefficients(t, a, b, c, d);
qreal yt = a * y1 + b * y2 + c * y3 + d * y4;
if (yt < y) {
t0 = t;
py0 = yt;
} else {
t1 = t;
py1 = yt;
}
dt = lt - t;
lt = t;
} while (qAbs(dt) > qreal(1e-7));
return t0;
}
int QBezier::stationaryYPoints(qreal &t0, qreal &t1) const
{
// y(t) = (1 - t)^3 * y1 + 3 * (1 - t)^2 * t * y2 + 3 * (1 - t) * t^2 * y3 + t^3 * y4
// y'(t) = 3 * (-(1-2t+t^2) * y1 + (1 - 4 * t + 3 * t^2) * y2 + (2 * t - 3 * t^2) * y3 + t^2 * y4)
// y'(t) = 3 * ((-y1 + 3 * y2 - 3 * y3 + y4)t^2 + (2 * y1 - 4 * y2 + 2 * y3)t + (-y1 + y2))
const qreal a = -y1 + 3 * y2 - 3 * y3 + y4;
const qreal b = 2 * y1 - 4 * y2 + 2 * y3;
const qreal c = -y1 + y2;
if (qFuzzyIsNull(a)) {
if (qFuzzyIsNull(b))
return 0;
t0 = -c / b;
return t0 > 0 && t0 < 1;
}
qreal reciprocal = b * b - 4 * a * c;
if (qFuzzyIsNull(reciprocal)) {
t0 = -b / (2 * a);
return t0 > 0 && t0 < 1;
} else if (reciprocal > 0) {
qreal temp = qSqrt(reciprocal);
t0 = (-b - temp)/(2*a);
t1 = (-b + temp)/(2*a);
if (t1 < t0)
qSwap(t0, t1);
int count = 0;
qreal t[2] = { 0, 1 };
if (t0 > 0 && t0 < 1)
t[count++] = t0;
if (t1 > 0 && t1 < 1)
t[count++] = t1;
t0 = t[0];
t1 = t[1];
return count;
}
return 0;
}
qreal QBezier::tAtLength(qreal l) const
{
qreal len = length();
qreal t = qreal(1.0);
const qreal error = qreal(0.01);
if (l > len || qFuzzyCompare(l, len))
return t;
t *= qreal(0.5);
//int iters = 0;
//qDebug()<<"LEN is "<<l<<len;
qreal lastBigger = qreal(1.0);
while (1) {
//qDebug()<<"\tt is "<<t;
QBezier right = *this;
QBezier left;
right.parameterSplitLeft(t, &left);
qreal lLen = left.length();
if (qAbs(lLen - l) < error)
break;
if (lLen < l) {
t += (lastBigger - t) * qreal(0.5);
} else {
lastBigger = t;
t -= t * qreal(0.5);
}
//++iters;
}
//qDebug()<<"number of iters is "<<iters;
return t;
}
QBezier QBezier::bezierOnInterval(qreal t0, qreal t1) const
{
if (t0 == 0 && t1 == 1)
return *this;
QBezier bezier = *this;
QBezier result;
bezier.parameterSplitLeft(t0, &result);
qreal trueT = (t1-t0)/(1-t0);
bezier.parameterSplitLeft(trueT, &result);
return result;
}
QT_END_NAMESPACE
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