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|
/****************************************************************************
**
** Implementation of TQPointArray class
**
** Created : 940213
**
** Copyright (C) 1992-2008 Trolltech ASA. All rights reserved.
**
** This file is part of the kernel module of the TQt GUI Toolkit.
**
** This file may be used under the terms of the GNU General
** Public License versions 2.0 or 3.0 as published by the Free
** Software Foundation and appearing in the files LICENSE.GPL2
** and LICENSE.GPL3 included in the packaging of this file.
** Alternatively you may (at your option) use any later version
** of the GNU General Public License if such license has been
** publicly approved by Trolltech ASA (or its successors, if any)
** and the KDE Free TQt Foundation.
**
** Please review the following information to ensure GNU General
** Public Licensing requirements will be met:
** http://trolltech.com/products/qt/licenses/licensing/opensource/.
** If you are unsure which license is appropriate for your use, please
** review the following information:
** http://trolltech.com/products/qt/licenses/licensing/licensingoverview
** or contact the sales department at sales@trolltech.com.
**
** This file may be used under the terms of the Q Public License as
** defined by Trolltech ASA and appearing in the file LICENSE.TQPL
** included in the packaging of this file. Licensees holding valid TQt
** Commercial licenses may use this file in accordance with the TQt
** Commercial License Agreement provided with the Software.
**
** This file is provided "AS IS" with NO WARRANTY OF ANY KIND,
** INCLUDING THE WARRANTIES OF DESIGN, MERCHANTABILITY AND FITNESS FOR
** A PARTICULAR PURPOSE. Trolltech reserves all rights not granted
** herein.
**
**********************************************************************/
#include "ntqpointarray.h"
#include "ntqrect.h"
#include "ntqdatastream.h"
#include "ntqwmatrix.h"
#include <stdarg.h>
const double Q_PI = 3.14159265358979323846; // pi // one more useful comment
/*!
\class TQPointArray ntqpointarray.h
\brief The TQPointArray class provides an array of points.
\ingroup images
\ingroup graphics
\ingroup shared
A TQPointArray is an array of TQPoint objects. In addition to the
functions provided by TQMemArray, TQPointArray provides some
point-specific functions.
For convenient reading and writing of the point data use
setPoints(), putPoints(), point(), and setPoint().
For geometry operations use boundingRect() and translate(). There
is also the TQWMatrix::map() function for more general
transformations of TQPointArrays. You can also create arcs and
ellipses with makeArc() and makeEllipse().
Among others, TQPointArray is used by TQPainter::drawLineSegments(),
TQPainter::drawPolyline(), TQPainter::drawPolygon() and
TQPainter::drawCubicBezier().
Note that because this class is a TQMemArray, copying an array and
modifying the copy modifies the original as well, i.e. a shallow
copy. If you need a deep copy use copy() or detach(), for example:
\code
void drawGiraffe( const TQPointArray & r, TQPainter * p )
{
TQPointArray tmp = r;
tmp.detach();
// some code that modifies tmp
p->drawPoints( tmp );
}
\endcode
If you forget the tmp.detach(), the const array will be modified.
\sa TQPainter TQWMatrix TQMemArray
*/
/*****************************************************************************
TQPointArray member functions
*****************************************************************************/
/*!
\fn TQPointArray::TQPointArray()
Constructs a null point array.
\sa isNull()
*/
/*!
\fn TQPointArray::TQPointArray( int size )
Constructs a point array with room for \a size points. Makes a
null array if \a size == 0.
\sa resize(), isNull()
*/
/*!
\fn TQPointArray::TQPointArray( const TQPointArray &a )
Constructs a shallow copy of the point array \a a.
\sa copy() detach()
*/
/*!
Constructs a point array from the rectangle \a r.
If \a closed is FALSE, then the point array just contains the
following four points in the listed order: r.topLeft(),
r.topRight(), r.bottomRight() and r.bottomLeft().
If \a closed is TRUE, then a fifth point is set to r.topLeft().
*/
TQPointArray::TQPointArray( const TQRect &r, bool closed )
{
setPoints( 4, r.left(), r.top(),
r.right(), r.top(),
r.right(), r.bottom(),
r.left(), r.bottom() );
if ( closed ) {
resize( 5 );
setPoint( 4, r.left(), r.top() );
}
}
/*!
\internal
Constructs a point array with \a nPoints points, taken from the
\a points array.
Equivalent to setPoints(nPoints, points).
*/
TQPointArray::TQPointArray( int nPoints, const TQCOORD *points )
{
setPoints( nPoints, points );
}
/*!
\fn TQPointArray::~TQPointArray()
Destroys the point array.
*/
/*!
\fn TQPointArray &TQPointArray::operator=( const TQPointArray &a )
Assigns a shallow copy of \a a to this point array and returns a
reference to this point array.
Equivalent to assign(a).
\sa copy() detach()
*/
/*!
\fn TQPointArray TQPointArray::copy() const
Creates a deep copy of the array.
\sa detach()
*/
/*!
Translates all points in the array by \a (dx, dy).
*/
void TQPointArray::translate( int dx, int dy )
{
TQPoint *p = data();
int i = size();
TQPoint pt( dx, dy );
while ( i-- ) {
*p += pt;
p++;
}
}
/*!
Reads the coordinates of the point at position \a index within the
array and writes them into \a *x and \a *y.
*/
void TQPointArray::point( uint index, int *x, int *y ) const
{
TQPoint p = TQMemArray<TQPoint>::at( index );
if ( x )
*x = (int)p.x();
if ( y )
*y = (int)p.y();
}
/*!
\overload
Returns the point at position \a index within the array.
*/
TQPoint TQPointArray::point( uint index ) const
{ // #### index out of bounds
return TQMemArray<TQPoint>::at( index );
}
/*!
\fn void TQPointArray::setPoint( uint i, const TQPoint &p )
\overload
Sets the point at array index \a i to \a p.
*/
/*!
Sets the point at position \a index in the array to \a (x, y).
*/
void TQPointArray::setPoint( uint index, int x, int y )
{ // #### index out of bounds
TQMemArray<TQPoint>::at( index ) = TQPoint( x, y );
}
/*!
\internal
Resizes the array to \a nPoints and sets the points in the array to
the values taken from \a points.
Returns TRUE if successful, or FALSE if the array could not be
resized (normally due to lack of memory).
The example code creates an array with two points (1,2) and (3,4):
\code
static TQCOORD points[] = { 1,2, 3,4 };
TQPointArray a;
a.setPoints( 2, points );
\endcode
\sa resize(), putPoints()
*/
bool TQPointArray::setPoints( int nPoints, const TQCOORD *points )
{
if ( !resize(nPoints) )
return FALSE;
int i = 0;
while ( nPoints-- ) { // make array of points
setPoint( i++, *points, *(points+1) );
points++;
points++;
}
return TRUE;
}
/*!
\overload
Resizes the array to \a nPoints and sets the points in the array
to the values taken from the variable argument list.
Returns TRUE if successful, or FALSE if the array could not be
resized (typically due to lack of memory).
The example code creates an array with two points (1,2) and (3,4):
\code
TQPointArray a;
a.setPoints( 2, 1,2, 3,4 );
\endcode
The points are given as a sequence of integers, starting with \a
firstx then \a firsty, and so on.
\sa resize(), putPoints()
*/
bool TQPointArray::setPoints( int nPoints, int firstx, int firsty, ... )
{
va_list ap;
if ( !resize(nPoints) )
return FALSE;
setPoint( 0, firstx, firsty ); // set first point
int i = 1, x, y;
nPoints--;
va_start( ap, firsty );
while ( nPoints-- ) {
x = va_arg( ap, int );
y = va_arg( ap, int );
setPoint( i++, x, y );
}
va_end( ap );
return TRUE;
}
/*! \overload
\internal
Copies \a nPoints points from the \a points coord array into
this point array, and resizes the point array if
\c{index+nPoints} exceeds the size of the array.
Returns TRUE if successful, or FALSE if the array could not be
resized (typically due to lack of memory).
*/
bool TQPointArray::putPoints( int index, int nPoints, const TQCOORD *points )
{
if ( index + nPoints > (int)size() ) { // extend array
if ( !resize( index + nPoints ) )
return FALSE;
}
int i = index;
while ( nPoints-- ) { // make array of points
setPoint( i++, *points, *(points+1) );
points++;
points++;
}
return TRUE;
}
/*!
Copies \a nPoints points from the variable argument list into this
point array from position \a index, and resizes the point array if
\c{index+nPoints} exceeds the size of the array.
Returns TRUE if successful, or FALSE if the array could not be
resized (typically due to lack of memory).
The example code creates an array with three points (4,5), (6,7)
and (8,9), by expanding the array from 1 to 3 points:
\code
TQPointArray a( 1 );
a[0] = TQPoint( 4, 5 );
a.putPoints( 1, 2, 6,7, 8,9 ); // index == 1, points == 2
\endcode
This has the same result, but here putPoints overwrites rather
than extends:
\code
TQPointArray a( 3 );
a.putPoints( 0, 3, 4,5, 0,0, 8,9 );
a.putPoints( 1, 1, 6,7 );
\endcode
The points are given as a sequence of integers, starting with \a
firstx then \a firsty, and so on.
\sa resize()
*/
bool TQPointArray::putPoints( int index, int nPoints, int firstx, int firsty,
... )
{
va_list ap;
if ( index + nPoints > (int)size() ) { // extend array
if ( !resize(index + nPoints) )
return FALSE;
}
if ( nPoints <= 0 )
return TRUE;
setPoint( index, firstx, firsty ); // set first point
int i = index + 1, x, y;
nPoints--;
va_start( ap, firsty );
while ( nPoints-- ) {
x = va_arg( ap, int );
y = va_arg( ap, int );
setPoint( i++, x, y );
}
va_end( ap );
return TRUE;
}
/*!
\overload
This version of the function copies \a nPoints from \a from into
this array, starting at \a index in this array and \a fromIndex in
\a from. \a fromIndex is 0 by default.
\code
TQPointArray a;
a.putPoints( 0, 3, 1,2, 0,0, 5,6 );
// a is now the three-point array ( 1,2, 0,0, 5,6 );
TQPointArray b;
b.putPoints( 0, 3, 4,4, 5,5, 6,6 );
// b is now ( 4,4, 5,5, 6,6 );
a.putPoints( 2, 3, b );
// a is now ( 1,2, 0,0, 4,4, 5,5, 6,6 );
\endcode
*/
bool TQPointArray::putPoints( int index, int nPoints,
const TQPointArray & from, int fromIndex )
{
if ( index + nPoints > (int)size() ) { // extend array
if ( !resize(index + nPoints) )
return FALSE;
}
if ( nPoints <= 0 )
return TRUE;
int n = 0;
while( n < nPoints ) {
setPoint( index+n, from[fromIndex+n] );
n++;
}
return TRUE;
}
/*!
Returns the bounding rectangle of the points in the array, or
TQRect(0,0,0,0) if the array is empty.
*/
TQRect TQPointArray::boundingRect() const
{
if ( isEmpty() )
return TQRect( 0, 0, 0, 0 ); // null rectangle
TQPoint *pd = data();
int minx, maxx, miny, maxy;
minx = maxx = pd->x();
miny = maxy = pd->y();
pd++;
for ( int i=1; i<(int)size(); i++ ) { // find min+max x and y
if ( pd->x() < minx )
minx = pd->x();
else if ( pd->x() > maxx )
maxx = pd->x();
if ( pd->y() < miny )
miny = pd->y();
else if ( pd->y() > maxy )
maxy = pd->y();
pd++;
}
return TQRect( TQPoint(minx,miny), TQPoint(maxx,maxy) );
}
static inline int fix_angle( int a )
{
if ( a > 16*360 )
a %= 16*360;
else if ( a < -16*360 ) {
a = -( (-a) % (16*360) );
}
return a;
}
/*!
Sets the points of the array to those describing an arc of an
ellipse with size, width \a w by height \a h, and position (\a x,
\a y), starting from angle \a a1 and spanning by angle \a a2. The
resulting array has sufficient resolution for pixel accuracy (see
the overloaded function which takes an additional TQWMatrix
parameter).
Angles are specified in 16ths of a degree, i.e. a full circle
equals 5760 (16*360). Positive values mean counter-clockwise,
whereas negative values mean the clockwise direction. Zero degrees
is at the 3 o'clock position.
See the \link tqcanvasellipse.html#anglediagram angle diagram\endlink.
*/
void TQPointArray::makeArc( int x, int y, int w, int h, int a1, int a2 )
{
#if !defined(QT_OLD_MAKEELLIPSE) && !defined(TQT_NO_TRANSFORMATIONS)
TQWMatrix unit;
makeArc(x,y,w,h,a1,a2,unit);
#else
a1 = fix_angle( a1 );
if ( a1 < 0 )
a1 += 16*360;
a2 = fix_angle( a2 );
int a3 = a2 > 0 ? a2 : -a2; // abs angle
makeEllipse( x, y, w, h );
int npts = a3*size()/(16*360); // # points in arc array
TQPointArray a(npts);
int i = a1*size()/(16*360);
int j = 0;
if ( a2 > 0 ) {
while ( npts-- ) {
if ( i >= (int)size() ) // wrap index
i = 0;
a.TQMemArray<TQPoint>::at( j++ ) = TQMemArray<TQPoint>::at( i++ );
}
} else {
while ( npts-- ) {
if ( i < 0 ) // wrap index
i = (int)size()-1;
a.TQMemArray<TQPoint>::at( j++ ) = TQMemArray<TQPoint>::at( i-- );
}
}
*this = a;
return;
#endif
}
#ifndef TQT_NO_TRANSFORMATIONS
// Based upon:
// parelarc.c from Graphics Gems III
// VanAken / Simar, "A Parametric Elliptical Arc Algorithm"
//
static void
qtr_elips(TQPointArray& a, int off, double dxP, double dyP, double dxQ, double dyQ, double dxK, double dyK, int m)
{
#define PIV2 102944 /* fixed point PI/2 */
#define TWOPI 411775 /* fixed point 2*PI */
#define HALF 32768 /* fixed point 1/2 */
int xP, yP, xQ, yQ, xK, yK;
xP = int(dxP * 65536.0); yP = int(dyP * 65536.0);
xQ = int(dxQ * 65536.0); yQ = int(dyQ * 65536.0);
xK = int(dxK * 65536.0); yK = int(dyK * 65536.0);
int i;
int vx, ux, vy, uy, xJ, yJ;
vx = xK - xQ; /* displacements from center */
ux = xK - xP;
vy = yK - yQ;
uy = yK - yP;
xJ = xP - vx + HALF; /* center of ellipse J */
yJ = yP - vy + HALF;
int r;
ux -= (r = ux >> (2*m + 3)); /* cancel 2nd-order error */
ux -= (r >>= (2*m + 4)); /* cancel 4th-order error */
ux -= r >> (2*m + 3); /* cancel 6th-order error */
ux += vx >> (m + 1); /* cancel 1st-order error */
uy -= (r = uy >> (2*m + 3)); /* cancel 2nd-order error */
uy -= (r >>= (2*m + 4)); /* cancel 4th-order error */
uy -= r >> (2*m + 3); /* cancel 6th-order error */
uy += vy >> (m + 1); /* cancel 1st-order error */
const int qn = a.size()/4;
for (i = 0; i < qn; i++) {
a[off+i] = TQPoint((xJ + vx) >> 16, (yJ + vy) >> 16);
ux -= vx >> m;
vx += ux >> m;
uy -= vy >> m;
vy += uy >> m;
}
#undef PIV2
#undef TWOPI
#undef HALF
}
/*!
\overload
Sets the points of the array to those describing an arc of an
ellipse with width \a w and height \a h and position (\a x, \a y),
starting from angle \a a1, and spanning angle by \a a2, and
transformed by the matrix \a xf. The resulting array has
sufficient resolution for pixel accuracy.
Angles are specified in 16ths of a degree, i.e. a full circle
equals 5760 (16*360). Positive values mean counter-clockwise,
whereas negative values mean the clockwise direction. Zero degrees
is at the 3 o'clock position.
See the \link tqcanvasellipse.html#anglediagram angle diagram\endlink.
*/
void TQPointArray::makeArc( int x, int y, int w, int h,
int a1, int a2,
const TQWMatrix& xf )
{
#define PIV2 102944 /* fixed point PI/2 */
if ( --w < 0 || --h < 0 || !a2 ) {
resize( 0 );
return;
}
bool rev = a2 < 0;
if ( rev ) {
a1 += a2;
a2 = -a2;
}
a1 = fix_angle( a1 );
if ( a1 < 0 )
a1 += 16*360;
a2 = fix_angle( a2 );
bool arc = a1 != 0 || a2 != 360*16 || rev;
double xP, yP, xQ, yQ, xK, yK;
xf.map(x+w, y+h/2.0, &xP, &yP);
xf.map(x+w/2.0, y, &xQ, &yQ);
xf.map(x+w, y, &xK, &yK);
int m = 3;
int max;
int q = int(TQMAX(TQABS(xP-xQ),TQABS(yP-yQ)));
if ( arc )
q *= 2;
do {
m++;
max = 4*(1 + (PIV2 >> (16 - m)) );
} while (max < q && m < 16); // 16 limits memory usage on HUGE arcs
double inc = 1.0/(1<<m);
const int qn = (PIV2 >> (16 - m));
resize(qn*4);
qtr_elips(*this, 0, xP, yP, xQ, yQ, xK, yK, m);
xP = xQ; yP = yQ;
xf.map(x, y+h/2.0, &xQ, &yQ);
xf.map(x, y, &xK, &yK);
qtr_elips(*this, qn, xP, yP, xQ, yQ, xK, yK, m);
xP = xQ; yP = yQ;
xf.map(x+w/2.0, y+h, &xQ, &yQ);
xf.map(x, y+h, &xK, &yK);
qtr_elips(*this, qn*2, xP, yP, xQ, yQ, xK, yK, m);
xP = xQ; yP = yQ;
xf.map(x+w, y+h/2.0, &xQ, &yQ);
xf.map(x+w, y+h, &xK, &yK);
qtr_elips(*this, qn*3, xP, yP, xQ, yQ, xK, yK, m);
int n = size();
if ( arc ) {
double da1 = double(a1)*Q_PI / (360*8);
double da3 = double(a2+a1)*Q_PI / (360*8);
int i = int(da1/inc+0.5);
int l = int(da3/inc+0.5);
int k = (l-i)+1;
TQPointArray r(k);
int j = 0;
if ( rev ) {
while ( k-- )
r[j++] = at((i+k)%n);
} else {
while ( j < k ) {
r[j] = at((i+j)%n);
j++;
}
}
*this = r;
}
#undef PIV2
}
#endif // TQT_NO_TRANSFORMATIONS
/*!
Sets the points of the array to those describing an ellipse with
size, width \a w by height \a h, and position (\a x, \a y).
The returned array has sufficient resolution for use as pixels.
*/
void TQPointArray::makeEllipse( int x, int y, int w, int h )
{ // midpoint, 1/4 ellipse
#if !defined(QT_OLD_MAKEELLIPSE) && !defined(TQT_NO_TRANSFORMATIONS)
TQWMatrix unit;
makeArc(x,y,w,h,0,360*16,unit);
return;
#else
if ( w <= 0 || h <= 0 ) {
if ( w == 0 || h == 0 ) {
resize( 0 );
return;
}
if ( w < 0 ) { // negative width
w = -w;
x -= w;
}
if ( h < 0 ) { // negative height
h = -h;
y -= h;
}
}
int s = (w+h+2)/2; // max size of xx,yy array
int *px = new int[s]; // 1/4th of ellipse
int *py = new int[s];
int xx, yy, i=0;
double d1, d2;
double a2=(w/2)*(w/2), b2=(h/2)*(h/2);
xx = 0;
yy = int(h/2);
d1 = b2 - a2*(h/2) + 0.25*a2;
px[i] = xx;
py[i] = yy;
i++;
while ( a2*(yy-0.5) > b2*(xx+0.5) ) { // region 1
if ( d1 < 0 ) {
d1 = d1 + b2*(3.0+2*xx);
xx++;
} else {
d1 = d1 + b2*(3.0+2*xx) + 2.0*a2*(1-yy);
xx++;
yy--;
}
px[i] = xx;
py[i] = yy;
i++;
}
d2 = b2*(xx+0.5)*(xx+0.5) + a2*(yy-1)*(yy-1) - a2*b2;
while ( yy > 0 ) { // region 2
if ( d2 < 0 ) {
d2 = d2 + 2.0*b2*(xx+1) + a2*(3-2*yy);
xx++;
yy--;
} else {
d2 = d2 + a2*(3-2*yy);
yy--;
}
px[i] = xx;
py[i] = yy;
i++;
}
s = i;
resize( 4*s ); // make full point array
x += w/2;
y += h/2;
for ( i=0; i<s; i++ ) { // mirror
xx = px[i];
yy = py[i];
setPoint( s-i-1, x+xx, y-yy );
setPoint( s+i, x-xx, y-yy );
setPoint( 3*s-i-1, x-xx, y+yy );
setPoint( 3*s+i, x+xx, y+yy );
}
delete[] px;
delete[] py;
#endif
}
#ifndef TQT_NO_BEZIER
// Work functions for TQPointArray::cubicBezier()
static
void split(const double *p, double *l, double *r)
{
double tmpx;
double tmpy;
l[0] = p[0];
l[1] = p[1];
r[6] = p[6];
r[7] = p[7];
l[2] = (p[0]+ p[2])/2;
l[3] = (p[1]+ p[3])/2;
tmpx = (p[2]+ p[4])/2;
tmpy = (p[3]+ p[5])/2;
r[4] = (p[4]+ p[6])/2;
r[5] = (p[5]+ p[7])/2;
l[4] = (l[2]+ tmpx)/2;
l[5] = (l[3]+ tmpy)/2;
r[2] = (tmpx + r[4])/2;
r[3] = (tmpy + r[5])/2;
l[6] = (l[4]+ r[2])/2;
l[7] = (l[5]+ r[3])/2;
r[0] = l[6];
r[1] = l[7];
}
// Based on:
//
// A Fast 2D Point-On-Line Test
// by Alan Paeth
// from "Graphics Gems", Academic Press, 1990
static
int pnt_on_line( const int* p, const int* q, const int* t )
{
/*
* given a line through P:(px,py) Q:(qx,qy) and T:(tx,ty)
* return 0 if T is not on the line through <--P--Q-->
* 1 if T is on the open ray ending at P: <--P
* 2 if T is on the closed interior along: P--Q
* 3 if T is on the open ray beginning at Q: Q-->
*
* Example: consider the line P = (3,2), Q = (17,7). A plot
* of the test points T(x,y) (with 0 mapped onto '.') yields:
*
* 8| . . . . . . . . . . . . . . . . . 3 3
* Y 7| . . . . . . . . . . . . . . 2 2 Q 3 3 Q = 2
* 6| . . . . . . . . . . . 2 2 2 2 2 . . .
* a 5| . . . . . . . . 2 2 2 2 2 2 . . . . .
* x 4| . . . . . 2 2 2 2 2 2 . . . . . . . .
* i 3| . . . 2 2 2 2 2 . . . . . . . . . . .
* s 2| 1 1 P 2 2 . . . . . . . . . . . . . . P = 2
* 1| 1 1 . . . . . . . . . . . . . . . . .
* +--------------------------------------
* 1 2 3 4 5 X-axis 10 15 19
*
* Point-Line distance is normalized with the Infinity Norm
* avoiding square-root code and tightening the test vs the
* Manhattan Norm. All math is done on the field of integers.
* The latter replaces the initial ">= MAX(...)" test with
* "> (ABS(qx-px) + ABS(qy-py))" loosening both inequality
* and norm, yielding a broader target line for selection.
* The tightest test is employed here for best discrimination
* in merging collinear (to grid coordinates) vertex chains
* into a larger, spanning vectors within the Lemming editor.
*/
// if all points are coincident, return condition 2 (on line)
if(q[0]==p[0] && q[1]==p[1] && q[0]==t[0] && q[1]==t[1]) {
return 2;
}
if ( TQABS((q[1]-p[1])*(t[0]-p[0])-(t[1]-p[1])*(q[0]-p[0])) >=
(TQMAX(TQABS(q[0]-p[0]), TQABS(q[1]-p[1])))) return 0;
if (((q[0]<p[0])&&(p[0]<t[0])) || ((q[1]<p[1])&&(p[1]<t[1])))
return 1 ;
if (((t[0]<p[0])&&(p[0]<q[0])) || ((t[1]<p[1])&&(p[1]<q[1])))
return 1 ;
if (((p[0]<q[0])&&(q[0]<t[0])) || ((p[1]<q[1])&&(q[1]<t[1])))
return 3 ;
if (((t[0]<q[0])&&(q[0]<p[0])) || ((t[1]<q[1])&&(q[1]<p[1])))
return 3 ;
return 2 ;
}
static
void polygonizeTQBezier( double* acc, int& accsize, const double ctrl[],
int maxsize )
{
if ( accsize > maxsize / 2 )
{
// This never happens in practice.
if ( accsize >= maxsize-4 )
return;
// Running out of space - approximate by a line.
acc[accsize++] = ctrl[0];
acc[accsize++] = ctrl[1];
acc[accsize++] = ctrl[6];
acc[accsize++] = ctrl[7];
return;
}
//intersects:
double l[8];
double r[8];
split( ctrl, l, r);
// convert to integers for line condition check
int c0[2]; c0[0] = int(ctrl[0]); c0[1] = int(ctrl[1]);
int c1[2]; c1[0] = int(ctrl[2]); c1[1] = int(ctrl[3]);
int c2[2]; c2[0] = int(ctrl[4]); c2[1] = int(ctrl[5]);
int c3[2]; c3[0] = int(ctrl[6]); c3[1] = int(ctrl[7]);
// #### Duplication needed?
if ( TQABS(c1[0]-c0[0]) <= 1 && TQABS(c1[1]-c0[1]) <= 1
&& TQABS(c2[0]-c0[0]) <= 1 && TQABS(c2[1]-c0[1]) <= 1
&& TQABS(c3[0]-c1[0]) <= 1 && TQABS(c3[1]-c0[1]) <= 1 )
{
// Approximate by one line.
// Dont need to write last pt as it is the same as first pt
// on the next segment
acc[accsize++] = l[0];
acc[accsize++] = l[1];
return;
}
if ( ( pnt_on_line( c0, c3, c1 ) == 2 && pnt_on_line( c0, c3, c2 ) == 2 )
|| ( TQABS(c1[0]-c0[0]) <= 1 && TQABS(c1[1]-c0[1]) <= 1
&& TQABS(c2[0]-c0[0]) <= 1 && TQABS(c2[1]-c0[1]) <= 1
&& TQABS(c3[0]-c1[0]) <= 1 && TQABS(c3[1]-c0[1]) <= 1 ) )
{
// Approximate by one line.
// Dont need to write last pt as it is the same as first pt
// on the next segment
acc[accsize++] = l[0];
acc[accsize++] = l[1];
return;
}
// Too big and too curved - recusively subdivide.
polygonizeTQBezier( acc, accsize, l, maxsize );
polygonizeTQBezier( acc, accsize, r, maxsize );
}
/*!
Returns the Bezier points for the four control points in this
array.
*/
TQPointArray TQPointArray::cubicBezier() const
{
#ifdef USE_SIMPLE_QBEZIER_CODE
if ( size() != 4 ) {
#if defined(QT_CHECK_RANGE)
tqWarning( "TQPointArray::bezier: The array must have 4 control points" );
#endif
TQPointArray p;
return p;
}
int v;
float xvec[4];
float yvec[4];
for ( v=0; v<4; v++ ) { // store all x,y in xvec,yvec
int x, y;
point( v, &x, &y );
xvec[v] = (float)x;
yvec[v] = (float)y;
}
TQRect r = boundingRect();
int m = TQMAX(r.width(),r.height())/2;
m = TQMIN(m,30); // m = number of result points
if ( m < 2 ) // at least two points
m = 2;
TQPointArray p( m ); // p = Bezier point array
TQPointData *pd = p.data();
float x0 = xvec[0], y0 = yvec[0];
float dt = 1.0F/m;
float cx = 3.0F * (xvec[1] - x0);
float bx = 3.0F * (xvec[2] - xvec[1]) - cx;
float ax = xvec[3] - (x0 + cx + bx);
float cy = 3.0F * (yvec[1] - y0);
float by = 3.0F * (yvec[2] - yvec[1]) - cy;
float ay = yvec[3] - (y0 + cy + by);
float t = dt;
pd->rx() = (TQCOORD)xvec[0];
pd->ry() = (TQCOORD)yvec[0];
pd++;
m -= 2;
while ( m-- ) {
pd->rx() = (TQCOORD)tqRound( ((ax * t + bx) * t + cx) * t + x0 );
pd->ry() = (TQCOORD)tqRound( ((ay * t + by) * t + cy) * t + y0 );
pd++;
t += dt;
}
pd->rx() = (TQCOORD)xvec[3];
pd->ry() = (TQCOORD)yvec[3];
return p;
#else
if ( size() != 4 ) {
#if defined(QT_CHECK_RANGE)
tqWarning( "TQPointArray::bezier: The array must have 4 control points" );
#endif
TQPointArray pa;
return pa;
} else {
TQRect r = boundingRect();
int m = 4+2*TQMAX(r.width(),r.height());
double *p = new double[m];
double ctrl[8];
int i;
for (i=0; i<4; i++) {
ctrl[i*2] = at(i).x();
ctrl[i*2+1] = at(i).y();
}
int len=0;
polygonizeTQBezier( p, len, ctrl, m );
TQPointArray pa((len/2)+1); // one extra point for last point on line
int j=0;
for (i=0; j<len; i++) {
int x = tqRound(p[j++]);
int y = tqRound(p[j++]);
pa[i] = TQPoint(x,y);
}
// add last pt on the line, which will be at the last control pt
pa[(int)pa.size()-1] = at(3);
delete[] p;
return pa;
}
#endif
}
#endif //TQT_NO_BEZIER
/*****************************************************************************
TQPointArray stream functions
*****************************************************************************/
#ifndef TQT_NO_DATASTREAM
/*!
\relates TQPointArray
Writes the point array, \a a to the stream \a s and returns a
reference to the stream.
\sa \link datastreamformat.html Format of the TQDataStream operators \endlink
*/
TQDataStream &operator<<( TQDataStream &s, const TQPointArray &a )
{
uint i;
uint len = a.size();
s << len; // write size of array
for ( i=0; i<len; i++ ) // write each point
s << a.point( i );
return s;
}
/*!
\relates TQPointArray
Reads a point array, \a a from the stream \a s and returns a
reference to the stream.
\sa \link datastreamformat.html Format of the TQDataStream operators \endlink
*/
TQDataStream &operator>>( TQDataStream &s, TQPointArray &a )
{
uint i;
uint len;
s >> len; // read size of array
if ( !a.resize( len ) ) // no memory
return s;
TQPoint p;
for ( i=0; i<len; i++ ) { // read each point
s >> p;
a.setPoint( i, p );
}
return s;
}
#endif //TQT_NO_DATASTREAM
struct TQShortPoint { // Binary compatible with XPoint
short x, y;
};
uint TQPointArray::splen = 0;
void* TQPointArray::sp = 0; // Really a TQShortPoint*
/*!
\internal
Converts the point coords to short (16bit) size, compatible with
X11's XPoint structure. The pointer returned points to a static
array, so its contents will be overwritten the next time this
function is called.
*/
void* TQPointArray::shortPoints( int index, int nPoints ) const
{
if ( isNull() || !nPoints )
return 0;
TQPoint* p = data();
p += index;
uint i = nPoints < 0 ? size() : nPoints;
if ( splen < i ) {
if ( sp )
delete[] ((TQShortPoint*)sp);
sp = new TQShortPoint[i];
splen = i;
}
TQShortPoint* ps = (TQShortPoint*)sp;
while ( i-- ) {
ps->x = (short)p->x();
ps->y = (short)p->y();
p++;
ps++;
}
return sp;
}
/*!
\internal
Deallocates the internal buffer used by shortPoints().
*/
void TQPointArray::cleanBuffers()
{
if ( sp )
delete[] ((TQShortPoint*)sp);
sp = 0;
splen = 0;
}
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