PathStroke.cpp revision b2aeedbe61853738111e282edead5d052370e169
/*
* PathStroke.cpp
* nlivarot
*
* Created by fred on Tue Jun 17 2003.
*
*/
#include "Path.h"
#include "Shape.h"
#include <2geom/transforms.h>
/*
* stroking polylines into a Shape instance
* grunt work.
* if the goal is to raster the stroke, polyline stroke->polygon->uncrossed polygon->raster is grossly
* inefficient (but reuse the intersector, so that's what a lazy programmer like me does). the correct way would be
* to set up a supersampled buffer, raster each polyline stroke's part (one part per segment in the polyline, plus
* each join) because these are all convex polygons, then transform in alpha values
*/
// until i find something better
NR::Point StrokeNormalize(const NR::Point value) {
double length = L2(value);
if ( length < 0.0000001 ) {
return NR::Point(0, 0);
} else {
return value/length;
}
}
// faster version if length is known
NR::Point StrokeNormalize(const NR::Point value, double length) {
if ( length < 0.0000001 ) {
return NR::Point(0, 0);
} else {
return value/length;
}
}
void Path::Stroke(Shape *dest, bool doClose, double width, JoinType join,
ButtType butt, double miter, bool justAdd)
{
if (dest == NULL) {
return;
}
if (justAdd == false) {
dest->Reset(3 * pts.size(), 3 * pts.size());
}
dest->MakeBackData(false);
int lastM = 0;
while (lastM < int(pts.size())) {
int lastP = lastM + 1;
while (lastP < int(pts.size()) // select one subpath
&& (pts[lastP].isMoveTo == polyline_lineto
|| pts[lastP].isMoveTo == polyline_forced))
{
lastP++;
}
if ( lastP > lastM+1 ) {
NR::Point sbStart = pts[lastM].p;
NR::Point sbEnd = pts[lastP - 1].p;
if ( Geom::LInfty(sbEnd-sbStart) < 0.00001 ) { // why close lines that shouldn't be closed?
// ah I see, because close is defined here for
// a whole path and should be defined per subpath.
// debut==fin => ferme (on devrait garder un element pour les close(), mais tant pis)
DoStroke(lastM, lastP - lastM, dest, true, width, join, butt, miter, true);
} else {
DoStroke(lastM, lastP - lastM, dest, doClose, width, join, butt, miter, true);
}
} else if (butt == butt_round) { // special case: zero length round butt is a circle
int last[2] = { -1, -1 };
NR::Point dir;
dir[0] = 1;
dir[1] = 0;
NR::Point pos = pts[lastM].p;
DoButt(dest, width, butt, pos, dir, last[RIGHT], last[LEFT]);
int end[2];
dir = -dir;
DoButt(dest, width, butt, pos, dir, end[LEFT], end[RIGHT]);
dest->AddEdge (end[LEFT], last[LEFT]);
dest->AddEdge (last[RIGHT], end[RIGHT]);
}
lastM = lastP;
}
}
void Path::DoStroke(int off, int N, Shape *dest, bool doClose, double width, JoinType join,
ButtType butt, double miter, bool /*justAdd*/)
{
if (N <= 1) {
return;
}
NR::Point prevP, nextP;
int prevI, nextI;
int upTo;
int curI = 0;
NR::Point curP = pts[off].p;
if (doClose) {
prevI = N - 1;
while (prevI > 0) {
prevP = pts[off + prevI].p;
NR::Point diff = curP - prevP;
double dist = dot(diff, diff);
if (dist > 0.001) {
break;
}
prevI--;
}
if (prevI <= 0) {
return;
}
upTo = prevI;
} else {
prevP = curP;
prevI = curI;
upTo = N - 1;
}
{
nextI = 1;
while (nextI <= upTo) {
nextP = pts[off + nextI].p;
NR::Point diff = curP - nextP;
double dist = dot(diff, diff);
if (dist > 0.0) { // more tolerance for the first distance, to give the cap the right direction
break;
}
nextI++;
}
if (nextI > upTo) {
if (butt == butt_round) { // special case: zero length round butt is a circle
int last[2] = { -1, -1 };
NR::Point dir;
dir[0] = 1;
dir[1] = 0;
DoButt(dest, width, butt, curP, dir, last[RIGHT], last[LEFT]);
int end[2];
dir = -dir;
DoButt(dest, width, butt, curP, dir, end[LEFT], end[RIGHT]);
dest->AddEdge (end[LEFT], last[LEFT]);
dest->AddEdge (last[RIGHT], end[RIGHT]);
}
return;
}
}
int start[2] = { -1, -1 };
int last[2] = { -1, -1 };
NR::Point prevD = curP - prevP;
NR::Point nextD = nextP - curP;
double prevLe = NR::L2(prevD);
double nextLe = NR::L2(nextD);
prevD = StrokeNormalize(prevD, prevLe);
nextD = StrokeNormalize(nextD, nextLe);
if (doClose) {
DoJoin(dest, width, join, curP, prevD, nextD, miter, prevLe, nextLe, start, last);
} else {
nextD = -nextD;
DoButt(dest, width, butt, curP, nextD, last[RIGHT], last[LEFT]);
nextD = -nextD;
}
do {
prevP = curP;
prevI = curI;
curP = nextP;
curI = nextI;
prevD = nextD;
prevLe = nextLe;
nextI++;
while (nextI <= upTo) {
nextP = pts[off + nextI].p;
NR::Point diff = curP - nextP;
double dist = dot(diff, diff);
if (dist > 0.001 || (nextI == upTo && dist > 0.0)) { // more tolerance for the last distance too, for the right cap direction
break;
}
nextI++;
}
if (nextI > upTo) {
break;
}
nextD = nextP - curP;
nextLe = NR::L2(nextD);
nextD = StrokeNormalize(nextD, nextLe);
int nSt[2] = { -1, -1 };
int nEn[2] = { -1, -1 };
DoJoin(dest, width, join, curP, prevD, nextD, miter, prevLe, nextLe, nSt, nEn);
dest->AddEdge(nSt[LEFT], last[LEFT]);
last[LEFT] = nEn[LEFT];
dest->AddEdge(last[RIGHT], nSt[RIGHT]);
last[RIGHT] = nEn[RIGHT];
} while (nextI <= upTo);
if (doClose) {
/* prevP=curP;
prevI=curI;
curP=nextP;
curI=nextI;
prevD=nextD;*/
nextP = pts[off].p;
nextD = nextP - curP;
nextLe = NR::L2(nextD);
nextD = StrokeNormalize(nextD, nextLe);
int nSt[2] = { -1, -1 };
int nEn[2] = { -1, -1 };
DoJoin(dest, width, join, curP, prevD, nextD, miter, prevLe, nextLe, nSt, nEn);
dest->AddEdge (nSt[LEFT], last[LEFT]);
last[LEFT] = nEn[LEFT];
dest->AddEdge (last[RIGHT], nSt[RIGHT]);
last[RIGHT] = nEn[RIGHT];
dest->AddEdge (start[LEFT], last[LEFT]);
dest->AddEdge (last[RIGHT], start[RIGHT]);
} else {
int end[2];
DoButt (dest, width, butt, curP, prevD, end[LEFT], end[RIGHT]);
dest->AddEdge (end[LEFT], last[LEFT]);
dest->AddEdge (last[RIGHT], end[RIGHT]);
}
}
void Path::DoButt(Shape *dest, double width, ButtType butt, NR::Point pos, NR::Point dir,
int &leftNo, int &rightNo)
{
NR::Point nor;
nor = dir.ccw();
if (butt == butt_square)
{
NR::Point x;
x = pos + width * dir + width * nor;
int bleftNo = dest->AddPoint (x);
x = pos + width * dir - width * nor;
int brightNo = dest->AddPoint (x);
x = pos + width * nor;
leftNo = dest->AddPoint (x);
x = pos - width * nor;
rightNo = dest->AddPoint (x);
dest->AddEdge (rightNo, brightNo);
dest->AddEdge (brightNo, bleftNo);
dest->AddEdge (bleftNo, leftNo);
}
else if (butt == butt_pointy)
{
leftNo = dest->AddPoint (pos + width * nor);
rightNo = dest->AddPoint (pos - width * nor);
int mid = dest->AddPoint (pos + width * dir);
dest->AddEdge (rightNo, mid);
dest->AddEdge (mid, leftNo);
}
else if (butt == butt_round)
{
const NR::Point sx = pos + width * nor;
const NR::Point ex = pos - width * nor;
leftNo = dest->AddPoint (sx);
rightNo = dest->AddPoint (ex);
RecRound (dest, rightNo, leftNo, ex, sx, -nor, nor, pos, width);
}
else
{
leftNo = dest->AddPoint (pos + width * nor);
rightNo = dest->AddPoint (pos - width * nor);
dest->AddEdge (rightNo, leftNo);
}
}
void Path::DoJoin (Shape *dest, double width, JoinType join, NR::Point pos, NR::Point prev,
NR::Point next, double miter, double /*prevL*/, double /*nextL*/,
int *stNo, int *enNo)
{
NR::Point pnor = prev.ccw();
NR::Point nnor = next.ccw();
double angSi = cross(next, prev);
/* FIXED: this special case caused bug 1028953 */
if (angSi > -0.0001 && angSi < 0.0001) {
double angCo = dot (prev, next);
if (angCo > 0.9999) {
// tout droit
stNo[LEFT] = enNo[LEFT] = dest->AddPoint(pos + width * pnor);
stNo[RIGHT] = enNo[RIGHT] = dest->AddPoint(pos - width * pnor);
} else {
// demi-tour
const NR::Point sx = pos + width * pnor;
const NR::Point ex = pos - width * pnor;
stNo[LEFT] = enNo[RIGHT] = dest->AddPoint (sx);
stNo[RIGHT] = enNo[LEFT] = dest->AddPoint (ex);
if (join == join_round) {
RecRound (dest, enNo[LEFT], stNo[LEFT], ex, sx, -pnor, pnor, pos, width);
dest->AddEdge(stNo[RIGHT], enNo[RIGHT]);
} else {
dest->AddEdge(enNo[LEFT], stNo[LEFT]);
dest->AddEdge(stNo[RIGHT], enNo[RIGHT]); // two times because both are crossing each other
}
}
return;
}
if (angSi < 0) {
int midNo = dest->AddPoint(pos);
stNo[LEFT] = dest->AddPoint(pos + width * pnor);
enNo[LEFT] = dest->AddPoint(pos + width * nnor);
dest->AddEdge(enNo[LEFT], midNo);
dest->AddEdge(midNo, stNo[LEFT]);
if (join == join_pointy) {
stNo[RIGHT] = dest->AddPoint(pos - width * pnor);
enNo[RIGHT] = dest->AddPoint(pos - width * nnor);
const NR::Point biss = StrokeNormalize(prev - next);
double c2 = dot(biss, nnor);
double l = width / c2;
double emiter = width * c2;
if (emiter < miter) {
emiter = miter;
}
if (fabs(l) < miter) {
int const n = dest->AddPoint(pos - l * biss);
dest->AddEdge(stNo[RIGHT], n);
dest->AddEdge(n, enNo[RIGHT]);
} else {
dest->AddEdge(stNo[RIGHT], enNo[RIGHT]);
}
} else if (join == join_round) {
NR::Point sx = pos - width * pnor;
stNo[RIGHT] = dest->AddPoint(sx);
NR::Point ex = pos - width * nnor;
enNo[RIGHT] = dest->AddPoint(ex);
RecRound(dest, stNo[RIGHT], enNo[RIGHT],
sx, ex, -pnor, -nnor, pos, width);
} else {
stNo[RIGHT] = dest->AddPoint(pos - width * pnor);
enNo[RIGHT] = dest->AddPoint(pos - width * nnor);
dest->AddEdge(stNo[RIGHT], enNo[RIGHT]);
}
} else {
int midNo = dest->AddPoint(pos);
stNo[RIGHT] = dest->AddPoint(pos - width * pnor);
enNo[RIGHT] = dest->AddPoint(pos - width * nnor);
dest->AddEdge(stNo[RIGHT], midNo);
dest->AddEdge(midNo, enNo[RIGHT]);
if (join == join_pointy) {
stNo[LEFT] = dest->AddPoint(pos + width * pnor);
enNo[LEFT] = dest->AddPoint(pos + width * nnor);
const NR::Point biss = StrokeNormalize(next - prev);
double c2 = dot(biss, nnor);
double l = width / c2;
double emiter = width * c2;
if (emiter < miter) {
emiter = miter;
}
if ( fabs(l) < miter) {
int const n = dest->AddPoint (pos + l * biss);
dest->AddEdge (enNo[LEFT], n);
dest->AddEdge (n, stNo[LEFT]);
}
else
{
dest->AddEdge (enNo[LEFT], stNo[LEFT]);
}
} else if (join == join_round) {
NR::Point sx = pos + width * pnor;
stNo[LEFT] = dest->AddPoint(sx);
NR::Point ex = pos + width * nnor;
enNo[LEFT] = dest->AddPoint(ex);
RecRound(dest, enNo[LEFT], stNo[LEFT],
ex, sx, nnor, pnor, pos, width);
} else {
stNo[LEFT] = dest->AddPoint(pos + width * pnor);
enNo[LEFT] = dest->AddPoint(pos + width * nnor);
dest->AddEdge(enNo[LEFT], stNo[LEFT]);
}
}
}
void
Path::DoLeftJoin (Shape * dest, double width, JoinType join, NR::Point pos,
NR::Point prev, NR::Point next, double miter, double /*prevL*/, double /*nextL*/,
int &leftStNo, int &leftEnNo,int pathID,int pieceID,double tID)
{
NR::Point pnor=prev.ccw();
NR::Point nnor=next.ccw();
double angSi = cross (next, prev);
if (angSi > -0.0001 && angSi < 0.0001)
{
double angCo = dot (prev, next);
if (angCo > 0.9999)
{
// tout droit
leftEnNo = leftStNo = dest->AddPoint (pos + width * pnor);
}
else
{
// demi-tour
leftStNo = dest->AddPoint (pos + width * pnor);
leftEnNo = dest->AddPoint (pos - width * pnor);
int nEdge=dest->AddEdge (leftEnNo, leftStNo);
if ( dest->hasBackData() ) {
dest->ebData[nEdge].pathID=pathID;
dest->ebData[nEdge].pieceID=pieceID;
dest->ebData[nEdge].tSt=dest->ebData[nEdge].tEn=tID;
}
}
return;
}
if (angSi < 0)
{
/* NR::Point biss;
biss.x=next.x-prev.x;
biss.y=next.y-prev.y;
double c2=cross(biss,next);
double l=width/c2;
double projn=l*(dot(biss,next));
double projp=-l*(dot(biss,prev));
if ( projp <= 0.5*prevL && projn <= 0.5*nextL ) {
double x,y;
x=pos.x+l*biss.x;
y=pos.y+l*biss.y;
leftEnNo=leftStNo=dest->AddPoint(x,y);
} else {*/
leftStNo = dest->AddPoint (pos + width * pnor);
leftEnNo = dest->AddPoint (pos + width * nnor);
int midNo = dest->AddPoint (pos);
int nEdge=dest->AddEdge (leftEnNo, midNo);
if ( dest->hasBackData() ) {
dest->ebData[nEdge].pathID=pathID;
dest->ebData[nEdge].pieceID=pieceID;
dest->ebData[nEdge].tSt=dest->ebData[nEdge].tEn=tID;
}
nEdge=dest->AddEdge (midNo, leftStNo);
if ( dest->hasBackData() ) {
dest->ebData[nEdge].pathID=pathID;
dest->ebData[nEdge].pieceID=pieceID;
dest->ebData[nEdge].tSt=dest->ebData[nEdge].tEn=tID;
}
// }
}
else
{
if (join == join_pointy)
{
leftStNo = dest->AddPoint (pos + width * pnor);
leftEnNo = dest->AddPoint (pos + width * nnor);
const NR::Point biss = StrokeNormalize (pnor + nnor);
double c2 = dot (biss, nnor);
double l = width / c2;
double emiter = width * c2;
if (emiter < miter)
emiter = miter;
if (l <= emiter)
{
int nleftStNo = dest->AddPoint (pos + l * biss);
int nEdge=dest->AddEdge (leftEnNo, nleftStNo);
if ( dest->hasBackData() ) {
dest->ebData[nEdge].pathID=pathID;
dest->ebData[nEdge].pieceID=pieceID;
dest->ebData[nEdge].tSt=dest->ebData[nEdge].tEn=tID;
}
nEdge=dest->AddEdge (nleftStNo, leftStNo);
if ( dest->hasBackData() ) {
dest->ebData[nEdge].pathID=pathID;
dest->ebData[nEdge].pieceID=pieceID;
dest->ebData[nEdge].tSt=dest->ebData[nEdge].tEn=tID;
}
}
else
{
double s2 = cross (biss, nnor);
double dec = (l - emiter) * c2 / s2;
const NR::Point tbiss=biss.ccw();
int nleftStNo = dest->AddPoint (pos + emiter * biss + dec * tbiss);
int nleftEnNo = dest->AddPoint (pos + emiter * biss - dec * tbiss);
int nEdge=dest->AddEdge (nleftEnNo, nleftStNo);
if ( dest->hasBackData() ) {
dest->ebData[nEdge].pathID=pathID;
dest->ebData[nEdge].pieceID=pieceID;
dest->ebData[nEdge].tSt=dest->ebData[nEdge].tEn=tID;
}
nEdge=dest->AddEdge (leftEnNo, nleftEnNo);
if ( dest->hasBackData() ) {
dest->ebData[nEdge].pathID=pathID;
dest->ebData[nEdge].pieceID=pieceID;
dest->ebData[nEdge].tSt=dest->ebData[nEdge].tEn=tID;
}
nEdge=dest->AddEdge (nleftStNo, leftStNo);
if ( dest->hasBackData() ) {
dest->ebData[nEdge].pathID=pathID;
dest->ebData[nEdge].pieceID=pieceID;
dest->ebData[nEdge].tSt=dest->ebData[nEdge].tEn=tID;
}
}
}
else if (join == join_round)
{
const NR::Point sx = pos + width * pnor;
leftStNo = dest->AddPoint (sx);
const NR::Point ex = pos + width * nnor;
leftEnNo = dest->AddPoint (ex);
RecRound(dest, leftEnNo, leftStNo,
sx, ex, pnor, nnor ,pos, width);
}
else
{
leftStNo = dest->AddPoint (pos + width * pnor);
leftEnNo = dest->AddPoint (pos + width * nnor);
int nEdge=dest->AddEdge (leftEnNo, leftStNo);
if ( dest->hasBackData() ) {
dest->ebData[nEdge].pathID=pathID;
dest->ebData[nEdge].pieceID=pieceID;
dest->ebData[nEdge].tSt=dest->ebData[nEdge].tEn=tID;
}
}
}
}
void
Path::DoRightJoin (Shape * dest, double width, JoinType join, NR::Point pos,
NR::Point prev, NR::Point next, double miter, double /*prevL*/,
double /*nextL*/, int &rightStNo, int &rightEnNo,int pathID,int pieceID,double tID)
{
const NR::Point pnor=prev.ccw();
const NR::Point nnor=next.ccw();
double angSi = cross (next,prev);
if (angSi > -0.0001 && angSi < 0.0001)
{
double angCo = dot (prev, next);
if (angCo > 0.9999)
{
// tout droit
rightEnNo = rightStNo = dest->AddPoint (pos - width*pnor);
}
else
{
// demi-tour
rightEnNo = dest->AddPoint (pos + width*pnor);
rightStNo = dest->AddPoint (pos - width*pnor);
int nEdge=dest->AddEdge (rightStNo, rightEnNo);
if ( dest->hasBackData() ) {
dest->ebData[nEdge].pathID=pathID;
dest->ebData[nEdge].pieceID=pieceID;
dest->ebData[nEdge].tSt=dest->ebData[nEdge].tEn=tID;
}
}
return;
}
if (angSi < 0)
{
if (join == join_pointy)
{
rightStNo = dest->AddPoint (pos - width*pnor);
rightEnNo = dest->AddPoint (pos - width*nnor);
const NR::Point biss = StrokeNormalize (pnor + nnor);
double c2 = dot (biss, nnor);
double l = width / c2;
double emiter = width * c2;
if (emiter < miter)
emiter = miter;
if (l <= emiter)
{
int nrightStNo = dest->AddPoint (pos - l * biss);
int nEdge=dest->AddEdge (rightStNo, nrightStNo);
if ( dest->hasBackData() ) {
dest->ebData[nEdge].pathID=pathID;
dest->ebData[nEdge].pieceID=pieceID;
dest->ebData[nEdge].tSt=dest->ebData[nEdge].tEn=tID;
}
nEdge=dest->AddEdge (nrightStNo, rightEnNo);
if ( dest->hasBackData() ) {
dest->ebData[nEdge].pathID=pathID;
dest->ebData[nEdge].pieceID=pieceID;
dest->ebData[nEdge].tSt=dest->ebData[nEdge].tEn=tID;
}
}
else
{
double s2 = cross (biss, nnor);
double dec = (l - emiter) * c2 / s2;
const NR::Point tbiss=biss.ccw();
int nrightStNo = dest->AddPoint (pos - emiter*biss - dec*tbiss);
int nrightEnNo = dest->AddPoint (pos - emiter*biss + dec*tbiss);
int nEdge=dest->AddEdge (rightStNo, nrightStNo);
if ( dest->hasBackData() ) {
dest->ebData[nEdge].pathID=pathID;
dest->ebData[nEdge].pieceID=pieceID;
dest->ebData[nEdge].tSt=dest->ebData[nEdge].tEn=tID;
}
nEdge=dest->AddEdge (nrightStNo, nrightEnNo);
if ( dest->hasBackData() ) {
dest->ebData[nEdge].pathID=pathID;
dest->ebData[nEdge].pieceID=pieceID;
dest->ebData[nEdge].tSt=dest->ebData[nEdge].tEn=tID;
}
nEdge=dest->AddEdge (nrightEnNo, rightEnNo);
if ( dest->hasBackData() ) {
dest->ebData[nEdge].pathID=pathID;
dest->ebData[nEdge].pieceID=pieceID;
dest->ebData[nEdge].tSt=dest->ebData[nEdge].tEn=tID;
}
}
}
else if (join == join_round)
{
const NR::Point sx = pos - width * pnor;
rightStNo = dest->AddPoint (sx);
const NR::Point ex = pos - width * nnor;
rightEnNo = dest->AddPoint (ex);
RecRound(dest, rightStNo, rightEnNo,
sx, ex, -pnor, -nnor ,pos, width);
}
else
{
rightStNo = dest->AddPoint (pos - width * pnor);
rightEnNo = dest->AddPoint (pos - width * nnor);
int nEdge=dest->AddEdge (rightStNo, rightEnNo);
if ( dest->hasBackData() ) {
dest->ebData[nEdge].pathID=pathID;
dest->ebData[nEdge].pieceID=pieceID;
dest->ebData[nEdge].tSt=dest->ebData[nEdge].tEn=tID;
}
}
}
else
{
/* NR::Point biss;
biss=next.x-prev.x;
biss.y=next.y-prev.y;
double c2=cross(next,biss);
double l=width/c2;
double projn=l*(dot(biss,next));
double projp=-l*(dot(biss,prev));
if ( projp <= 0.5*prevL && projn <= 0.5*nextL ) {
double x,y;
x=pos.x+l*biss.x;
y=pos.y+l*biss.y;
rightEnNo=rightStNo=dest->AddPoint(x,y);
} else {*/
rightStNo = dest->AddPoint (pos - width*pnor);
rightEnNo = dest->AddPoint (pos - width*nnor);
int midNo = dest->AddPoint (pos);
int nEdge=dest->AddEdge (rightStNo, midNo);
if ( dest->hasBackData() ) {
dest->ebData[nEdge].pathID=pathID;
dest->ebData[nEdge].pieceID=pieceID;
dest->ebData[nEdge].tSt=dest->ebData[nEdge].tEn=tID;
}
nEdge=dest->AddEdge (midNo, rightEnNo);
if ( dest->hasBackData() ) {
dest->ebData[nEdge].pathID=pathID;
dest->ebData[nEdge].pieceID=pieceID;
dest->ebData[nEdge].tSt=dest->ebData[nEdge].tEn=tID;
}
// }
}
}
// a very ugly way to produce round joins: doing one (or two, depend on the angle of the join) quadratic bezier curves
// but since most joins are going to be small, nobody will notice -- but somebody noticed and now the ugly stuff is gone! so:
// a very nice way to produce round joins, caps or dots
void Path::RecRound(Shape *dest, int sNo, int eNo, // start and end index
NR::Point const &iS, NR::Point const &iE, // start and end point
NR::Point const &nS, NR::Point const &nE, // start and end normal vector
NR::Point &origine, float width) // center and radius of round
{
//NR::Point diff = iS - iE;
//double dist = dot(diff, diff);
if (width < 0.5 || dot(iS - iE, iS - iE)/width < 2.0) {
dest->AddEdge(sNo, eNo);
return;
}
double ang, sia, lod;
if (nS == -nE) {
ang = M_PI;
sia = 1;
} else {
double coa = dot(nS, nE);
sia = cross(nS, nE);
ang = acos(coa);
if ( coa >= 1 ) {
ang = 0;
}
if ( coa <= -1 ) {
ang = M_PI;
}
}
lod = 0.02 + 10 / (10 + width); // limit detail to about 2 degrees (180 * 0.02/Pi degrees)
ang /= lod;
int nbS = (int) floor(ang);
Geom::Rotate omega(((sia > 0) ? -lod : lod));
NR::Point cur = iS - origine;
// StrokeNormalize(cur);
// cur*=width;
int lastNo = sNo;
for (int i = 0; i < nbS; i++) {
cur = cur * omega;
NR::Point m = origine + cur;
int mNo = dest->AddPoint(m);
dest->AddEdge(lastNo, mNo);
lastNo = mNo;
}
dest->AddEdge(lastNo, eNo);
}
/*
Local Variables:
mode:c++
c-file-style:"stroustrup"
c-file-offsets:((innamespace . 0)(inline-open . 0))
indent-tabs-mode:nil
fill-column:99
End:
*/
// vim: filetype=c++:expandtab:shiftwidth=4:tabstop=8:softtabstop=4 :