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authorDaniel Baumann <daniel.baumann@progress-linux.org>2024-04-07 09:06:44 +0000
committerDaniel Baumann <daniel.baumann@progress-linux.org>2024-04-07 09:06:44 +0000
commited5640d8b587fbcfed7dd7967f3de04b37a76f26 (patch)
tree7a5f7c6c9d02226d7471cb3cc8fbbf631b415303 /basegfx/source/workbench/bezierclip.cxx
parentInitial commit. (diff)
downloadlibreoffice-upstream.tar.xz
libreoffice-upstream.zip
Adding upstream version 4:7.4.7.upstream/4%7.4.7upstream
Signed-off-by: Daniel Baumann <daniel.baumann@progress-linux.org>
Diffstat (limited to '')
-rw-r--r--basegfx/source/workbench/bezierclip.cxx2006
1 files changed, 2006 insertions, 0 deletions
diff --git a/basegfx/source/workbench/bezierclip.cxx b/basegfx/source/workbench/bezierclip.cxx
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+/* -*- Mode: C++; tab-width: 4; indent-tabs-mode: nil; c-basic-offset: 4 -*- */
+/*
+ * This file is part of the LibreOffice project.
+ *
+ * This Source Code Form is subject to the terms of the Mozilla Public
+ * License, v. 2.0. If a copy of the MPL was not distributed with this
+ * file, You can obtain one at http://mozilla.org/MPL/2.0/.
+ *
+ * This file incorporates work covered by the following license notice:
+ *
+ * Licensed to the Apache Software Foundation (ASF) under one or more
+ * contributor license agreements. See the NOTICE file distributed
+ * with this work for additional information regarding copyright
+ * ownership. The ASF licenses this file to you under the Apache
+ * License, Version 2.0 (the "License"); you may not use this file
+ * except in compliance with the License. You may obtain a copy of
+ * the License at http://www.apache.org/licenses/LICENSE-2.0 .
+ */
+
+#include <iostream>
+#include <cassert>
+#include <algorithm>
+#include <iterator>
+#include <vector>
+#include <utility>
+
+#include <math.h>
+
+#include <bezierclip.hxx>
+#include <gauss.hxx>
+
+// what to test
+#define WITH_ASSERTIONS
+//#define WITH_CONVEXHULL_TEST
+//#define WITH_MULTISUBDIVIDE_TEST
+//#define WITH_FATLINE_TEST
+//#define WITH_CALCFOCUS_TEST
+//#define WITH_SAFEPARAMBASE_TEST
+//#define WITH_SAFEPARAMS_TEST
+//#define WITH_SAFEPARAM_DETAILED_TEST
+//#define WITH_SAFEFOCUSPARAM_CALCFOCUS
+//#define WITH_SAFEFOCUSPARAM_TEST
+//#define WITH_SAFEFOCUSPARAM_DETAILED_TEST
+#define WITH_BEZIERCLIP_TEST
+
+/* Implementation of the so-called 'Fat-Line Bezier Clipping Algorithm' by Sederberg et al.
+ *
+ * Actual reference is: T. W. Sederberg and T Nishita: Curve
+ * intersection using Bezier clipping. In Computer Aided Design, 22
+ * (9), 1990, pp. 538--549
+ */
+
+/* Misc helper
+ * ===========
+ */
+int fallFac( int n, int k )
+{
+#ifdef WITH_ASSERTIONS
+ assert(n>=k); // "For factorials, n must be greater or equal k"
+ assert(n>=0); // "For factorials, n must be positive"
+ assert(k>=0); // "For factorials, k must be positive"
+#endif
+
+ int res( 1 );
+
+ while( k-- && n ) res *= n--;
+
+ return res;
+}
+
+int fac( int n )
+{
+ return fallFac(n, n);
+}
+
+/* Bezier fat line clipping part
+ * =============================
+ */
+
+void Impl_calcFatLine( FatLine& line, const Bezier& c )
+{
+ // Prepare normalized implicit line
+ // ================================
+
+ // calculate vector orthogonal to p1-p4:
+ line.a = -(c.p0.y - c.p3.y);
+ line.b = (c.p0.x - c.p3.x);
+
+ // normalize
+ const double len(std::hypot(line.a, line.b));
+ if( !tolZero(len) )
+ {
+ line.a /= len;
+ line.b /= len;
+ }
+
+ line.c = -(line.a*c.p0.x + line.b*c.p0.y);
+
+ // Determine bounding fat line from it
+ // ===================================
+
+ // calc control point distances
+ const double dP2( calcLineDistance(line.a, line.b, line.c, c.p1.x, c.p1.y ) );
+ const double dP3( calcLineDistance(line.a, line.b, line.c, c.p2.x, c.p2.y ) );
+
+ // calc approximate bounding lines to curve (tight bounds are
+ // possible here, but more expensive to calculate and thus not
+ // worth the overhead)
+ if( dP2 * dP3 > 0.0 )
+ {
+ line.dMin = 3.0/4.0 * std::min(0.0, std::min(dP2, dP3));
+ line.dMax = 3.0/4.0 * std::max(0.0, std::max(dP2, dP3));
+ }
+ else
+ {
+ line.dMin = 4.0/9.0 * std::min(0.0, std::min(dP2, dP3));
+ line.dMax = 4.0/9.0 * std::max(0.0, std::max(dP2, dP3));
+ }
+}
+
+void Impl_calcBounds( Point2D& leftTop,
+ Point2D& rightBottom,
+ const Bezier& c1 )
+{
+ leftTop.x = std::min( c1.p0.x, std::min( c1.p1.x, std::min( c1.p2.x, c1.p3.x ) ) );
+ leftTop.y = std::min( c1.p0.y, std::min( c1.p1.y, std::min( c1.p2.y, c1.p3.y ) ) );
+ rightBottom.x = std::max( c1.p0.x, std::max( c1.p1.x, std::max( c1.p2.x, c1.p3.x ) ) );
+ rightBottom.y = std::max( c1.p0.y, std::max( c1.p1.y, std::max( c1.p2.y, c1.p3.y ) ) );
+}
+
+bool Impl_doBBoxIntersect( const Bezier& c1,
+ const Bezier& c2 )
+{
+ // calc rectangular boxes from c1 and c2
+ Point2D lt1;
+ Point2D rb1;
+ Point2D lt2;
+ Point2D rb2;
+
+ Impl_calcBounds( lt1, rb1, c1 );
+ Impl_calcBounds( lt2, rb2, c2 );
+
+ if( std::min(rb1.x, rb2.x) < std::max(lt1.x, lt2.x) ||
+ std::min(rb1.y, rb2.y) < std::max(lt1.y, lt2.y) )
+ {
+ return false;
+ }
+ else
+ {
+ return true;
+ }
+}
+
+/* calculates two t's for the given bernstein control polygon: the first is
+ * the intersection of the min value line with the convex hull from
+ * the left, the second is the intersection of the max value line with
+ * the convex hull from the right.
+ */
+bool Impl_calcSafeParams( double& t1,
+ double& t2,
+ const Polygon2D& rPoly,
+ double lowerYBound,
+ double upperYBound )
+{
+ // need the convex hull of the control polygon, as this is
+ // guaranteed to completely bound the curve
+ Polygon2D convHull( convexHull(rPoly) );
+
+ // init min and max buffers
+ t1 = 0.0 ;
+ double currLowerT( 1.0 );
+
+ t2 = 1.0;
+ double currHigherT( 0.0 );
+
+ if( convHull.size() <= 1 )
+ return false; // only one point? Then we're done with clipping
+
+ /* now, clip against lower and higher bounds */
+ Point2D p0;
+ Point2D p1;
+
+ bool bIntersection( false );
+
+ for( Polygon2D::size_type i=0; i<convHull.size(); ++i )
+ {
+ // have to check against convHull.size() segments, as the
+ // convex hull is, by definition, closed. Thus, for the
+ // last point, we take the first point as partner.
+ if( i+1 == convHull.size() )
+ {
+ // close the polygon
+ p0 = convHull[i];
+ p1 = convHull[0];
+ }
+ else
+ {
+ p0 = convHull[i];
+ p1 = convHull[i+1];
+ }
+
+ // is the segment in question within or crossing the
+ // horizontal band spanned by lowerYBound and upperYBound? If
+ // not, we've got no intersection. If yes, we maybe don't have
+ // an intersection, but we've got to update the permissible
+ // range, nevertheless. This is because inside lying segments
+ // leads to full range forbidden.
+ if( (tolLessEqual(p0.y, upperYBound) || tolLessEqual(p1.y, upperYBound)) &&
+ (tolGreaterEqual(p0.y, lowerYBound) || tolGreaterEqual(p1.y, lowerYBound)) )
+ {
+ // calc intersection of convex hull segment with
+ // one of the horizontal bounds lines
+ // to optimize a bit, r_x is calculated only in else case
+ const double r_y( p1.y - p0.y );
+
+ if( tolZero(r_y) )
+ {
+ // r_y is virtually zero, thus we've got a horizontal
+ // line. Now check whether we maybe coincide with lower or
+ // upper horizontal bound line.
+ if( tolEqual(p0.y, lowerYBound) ||
+ tolEqual(p0.y, upperYBound) )
+ {
+ // yes, simulate intersection then
+ currLowerT = std::min(currLowerT, std::min(p0.x, p1.x));
+ currHigherT = std::max(currHigherT, std::max(p0.x, p1.x));
+ }
+ }
+ else
+ {
+ // check against lower and higher bounds
+ // =====================================
+ const double r_x( p1.x - p0.x );
+
+ // calc intersection with horizontal dMin line
+ const double currTLow( (lowerYBound - p0.y) * r_x / r_y + p0.x );
+
+ // calc intersection with horizontal dMax line
+ const double currTHigh( (upperYBound - p0.y) * r_x / r_y + p0.x );
+
+ currLowerT = std::min(currLowerT, std::min(currTLow, currTHigh));
+ currHigherT = std::max(currHigherT, std::max(currTLow, currTHigh));
+ }
+
+ // set flag that at least one segment is contained or
+ // intersects given horizontal band.
+ bIntersection = true;
+ }
+ }
+
+#ifndef WITH_SAFEPARAMBASE_TEST
+ // limit intersections found to permissible t parameter range
+ t1 = std::max(0.0, currLowerT);
+ t2 = std::min(1.0, currHigherT);
+#endif
+
+ return bIntersection;
+}
+
+/* calculates two t's for the given bernstein polynomial: the first is
+ * the intersection of the min value line with the convex hull from
+ * the left, the second is the intersection of the max value line with
+ * the convex hull from the right.
+ *
+ * The polynomial coefficients c0 to c3 given to this method
+ * must correspond to t values of 0, 1/3, 2/3 and 1, respectively.
+ */
+bool Impl_calcSafeParams_clip( double& t1,
+ double& t2,
+ const FatLine& bounds,
+ double c0,
+ double c1,
+ double c2,
+ double c3 )
+{
+ /* first of all, determine convex hull of c0-c3 */
+ Polygon2D poly(4);
+ poly[0] = Point2D(0, c0);
+ poly[1] = Point2D(1.0/3.0, c1);
+ poly[2] = Point2D(2.0/3.0, c2);
+ poly[3] = Point2D(1, c3);
+
+#ifndef WITH_SAFEPARAM_DETAILED_TEST
+
+ return Impl_calcSafeParams( t1, t2, poly, bounds.dMin, bounds.dMax );
+
+#else
+ bool bRet( Impl_calcSafeParams( t1, t2, poly, bounds.dMin, bounds.dMax ) );
+
+ Polygon2D convHull( convexHull( poly ) );
+
+ std::cout << "# convex hull testing" << std::endl
+ << "plot [t=0:1] ";
+ std::cout << " bez("
+ << poly[0].x << ","
+ << poly[1].x << ","
+ << poly[2].x << ","
+ << poly[3].x << ",t),bez("
+ << poly[0].y << ","
+ << poly[1].y << ","
+ << poly[2].y << ","
+ << poly[3].y << ",t), "
+ << "t, " << bounds.dMin << ", "
+ << "t, " << bounds.dMax << ", "
+ << t1 << ", t, "
+ << t2 << ", t, "
+ << "'-' using ($1):($2) title \"control polygon\" with lp, "
+ << "'-' using ($1):($2) title \"convex hull\" with lp" << std::endl;
+
+ unsigned int k;
+ for( k=0; k<poly.size(); ++k )
+ {
+ std::cout << poly[k].x << " " << poly[k].y << std::endl;
+ }
+ std::cout << poly[0].x << " " << poly[0].y << std::endl;
+ std::cout << "e" << std::endl;
+
+ for( k=0; k<convHull.size(); ++k )
+ {
+ std::cout << convHull[k].x << " " << convHull[k].y << std::endl;
+ }
+ std::cout << convHull[0].x << " " << convHull[0].y << std::endl;
+ std::cout << "e" << std::endl;
+
+ return bRet;
+#endif
+}
+
+void Impl_deCasteljauAt( Bezier& part1,
+ Bezier& part2,
+ const Bezier& input,
+ double t )
+{
+ // deCasteljau bezier arc, scheme is:
+
+ // First row is C_0^n,C_1^n,...,C_n^n
+ // Second row is P_1^n,...,P_n^n
+ // etc.
+ // with P_k^r = (1 - x_s)P_{k-1}^{r-1} + x_s P_k{r-1}
+
+ // this results in:
+
+ // P1 P2 P3 P4
+ // L1 P2 P3 R4
+ // L2 H R3
+ // L3 R2
+ // L4/R1
+ if( tolZero(t) )
+ {
+ // t is zero -> part2 is input curve, part1 is empty (input.p0, that is)
+ part1.p0.x = part1.p1.x = part1.p2.x = part1.p3.x = input.p0.x;
+ part1.p0.y = part1.p1.y = part1.p2.y = part1.p3.y = input.p0.y;
+ part2 = input;
+ }
+ else if( tolEqual(t, 1.0) )
+ {
+ // t is one -> part1 is input curve, part2 is empty (input.p3, that is)
+ part1 = input;
+ part2.p0.x = part2.p1.x = part2.p2.x = part2.p3.x = input.p3.x;
+ part2.p0.y = part2.p1.y = part2.p2.y = part2.p3.y = input.p3.y;
+ }
+ else
+ {
+ part1.p0.x = input.p0.x; part1.p0.y = input.p0.y;
+ part1.p1.x = (1.0 - t)*part1.p0.x + t*input.p1.x; part1.p1.y = (1.0 - t)*part1.p0.y + t*input.p1.y;
+ const double Hx ( (1.0 - t)*input.p1.x + t*input.p2.x ), Hy ( (1.0 - t)*input.p1.y + t*input.p2.y );
+ part1.p2.x = (1.0 - t)*part1.p1.x + t*Hx; part1.p2.y = (1.0 - t)*part1.p1.y + t*Hy;
+ part2.p3.x = input.p3.x; part2.p3.y = input.p3.y;
+ part2.p2.x = (1.0 - t)*input.p2.x + t*input.p3.x; part2.p2.y = (1.0 - t)*input.p2.y + t*input.p3.y;
+ part2.p1.x = (1.0 - t)*Hx + t*part2.p2.x; part2.p1.y = (1.0 - t)*Hy + t*part2.p2.y;
+ part2.p0.x = (1.0 - t)*part1.p2.x + t*part2.p1.x; part2.p0.y = (1.0 - t)*part1.p2.y + t*part2.p1.y;
+ part1.p3.x = part2.p0.x; part1.p3.y = part2.p0.y;
+ }
+}
+
+void printCurvesWithSafeRange( const Bezier& c1, const Bezier& c2, double t1_c1, double t2_c1,
+ const Bezier& c2_part, const FatLine& bounds_c2 )
+{
+ static int offset = 0;
+
+ std::cout << "# safe param range testing" << std::endl
+ << "plot [t=0.0:1.0] ";
+
+ // clip safe ranges off c1
+ Bezier c1_part1;
+ Bezier c1_part2;
+ Bezier c1_part3;
+
+ // subdivide at t1_c1
+ Impl_deCasteljauAt( c1_part1, c1_part2, c1, t1_c1 );
+ // subdivide at t2_c1
+ Impl_deCasteljauAt( c1_part1, c1_part3, c1_part2, t2_c1 );
+
+ // output remaining segment (c1_part1)
+
+ std::cout << "bez("
+ << c1.p0.x+offset << ","
+ << c1.p1.x+offset << ","
+ << c1.p2.x+offset << ","
+ << c1.p3.x+offset << ",t),bez("
+ << c1.p0.y << ","
+ << c1.p1.y << ","
+ << c1.p2.y << ","
+ << c1.p3.y << ",t), bez("
+ << c2.p0.x+offset << ","
+ << c2.p1.x+offset << ","
+ << c2.p2.x+offset << ","
+ << c2.p3.x+offset << ",t),bez("
+ << c2.p0.y << ","
+ << c2.p1.y << ","
+ << c2.p2.y << ","
+ << c2.p3.y << ",t), "
+#if 1
+ << "bez("
+ << c1_part1.p0.x+offset << ","
+ << c1_part1.p1.x+offset << ","
+ << c1_part1.p2.x+offset << ","
+ << c1_part1.p3.x+offset << ",t),bez("
+ << c1_part1.p0.y << ","
+ << c1_part1.p1.y << ","
+ << c1_part1.p2.y << ","
+ << c1_part1.p3.y << ",t), "
+#endif
+#if 1
+ << "bez("
+ << c2_part.p0.x+offset << ","
+ << c2_part.p1.x+offset << ","
+ << c2_part.p2.x+offset << ","
+ << c2_part.p3.x+offset << ",t),bez("
+ << c2_part.p0.y << ","
+ << c2_part.p1.y << ","
+ << c2_part.p2.y << ","
+ << c2_part.p3.y << ",t), "
+#endif
+ << "linex("
+ << bounds_c2.a << ","
+ << bounds_c2.b << ","
+ << bounds_c2.c << ",t)+" << offset << ", liney("
+ << bounds_c2.a << ","
+ << bounds_c2.b << ","
+ << bounds_c2.c << ",t) title \"fat line (center)\", linex("
+ << bounds_c2.a << ","
+ << bounds_c2.b << ","
+ << bounds_c2.c-bounds_c2.dMin << ",t)+" << offset << ", liney("
+ << bounds_c2.a << ","
+ << bounds_c2.b << ","
+ << bounds_c2.c-bounds_c2.dMin << ",t) title \"fat line (min) \", linex("
+ << bounds_c2.a << ","
+ << bounds_c2.b << ","
+ << bounds_c2.c-bounds_c2.dMax << ",t)+" << offset << ", liney("
+ << bounds_c2.a << ","
+ << bounds_c2.b << ","
+ << bounds_c2.c-bounds_c2.dMax << ",t) title \"fat line (max) \"" << std::endl;
+
+ offset += 1;
+}
+
+void printResultWithFinalCurves( const Bezier& c1, const Bezier& c1_part,
+ const Bezier& c2, const Bezier& c2_part,
+ double t1_c1, double t2_c1 )
+{
+ static int offset = 0;
+
+ std::cout << "# final result" << std::endl
+ << "plot [t=0.0:1.0] ";
+
+ std::cout << "bez("
+ << c1.p0.x+offset << ","
+ << c1.p1.x+offset << ","
+ << c1.p2.x+offset << ","
+ << c1.p3.x+offset << ",t),bez("
+ << c1.p0.y << ","
+ << c1.p1.y << ","
+ << c1.p2.y << ","
+ << c1.p3.y << ",t), bez("
+ << c1_part.p0.x+offset << ","
+ << c1_part.p1.x+offset << ","
+ << c1_part.p2.x+offset << ","
+ << c1_part.p3.x+offset << ",t),bez("
+ << c1_part.p0.y << ","
+ << c1_part.p1.y << ","
+ << c1_part.p2.y << ","
+ << c1_part.p3.y << ",t), "
+ << " pointmarkx(bez("
+ << c1.p0.x+offset << ","
+ << c1.p1.x+offset << ","
+ << c1.p2.x+offset << ","
+ << c1.p3.x+offset << ","
+ << t1_c1 << "),t), "
+ << " pointmarky(bez("
+ << c1.p0.y << ","
+ << c1.p1.y << ","
+ << c1.p2.y << ","
+ << c1.p3.y << ","
+ << t1_c1 << "),t), "
+ << " pointmarkx(bez("
+ << c1.p0.x+offset << ","
+ << c1.p1.x+offset << ","
+ << c1.p2.x+offset << ","
+ << c1.p3.x+offset << ","
+ << t2_c1 << "),t), "
+ << " pointmarky(bez("
+ << c1.p0.y << ","
+ << c1.p1.y << ","
+ << c1.p2.y << ","
+ << c1.p3.y << ","
+ << t2_c1 << "),t), "
+
+ << "bez("
+ << c2.p0.x+offset << ","
+ << c2.p1.x+offset << ","
+ << c2.p2.x+offset << ","
+ << c2.p3.x+offset << ",t),bez("
+ << c2.p0.y << ","
+ << c2.p1.y << ","
+ << c2.p2.y << ","
+ << c2.p3.y << ",t), "
+ << "bez("
+ << c2_part.p0.x+offset << ","
+ << c2_part.p1.x+offset << ","
+ << c2_part.p2.x+offset << ","
+ << c2_part.p3.x+offset << ",t),bez("
+ << c2_part.p0.y << ","
+ << c2_part.p1.y << ","
+ << c2_part.p2.y << ","
+ << c2_part.p3.y << ",t)" << std::endl;
+
+ offset += 1;
+}
+
+/** determine parameter ranges [0,t1) and (t2,1] on c1, where c1 is guaranteed to lie outside c2.
+ Returns false, if the two curves don't even intersect.
+
+ @param t1
+ Range [0,t1) on c1 is guaranteed to lie outside c2
+
+ @param t2
+ Range (t2,1] on c1 is guaranteed to lie outside c2
+
+ @param c1_orig
+ Original curve c1
+
+ @param c1_part
+ Subdivided current part of c1
+
+ @param c2_orig
+ Original curve c2
+
+ @param c2_part
+ Subdivided current part of c2
+ */
+bool Impl_calcClipRange( double& t1,
+ double& t2,
+ const Bezier& c1_orig,
+ const Bezier& c1_part,
+ const Bezier& c2_orig,
+ const Bezier& c2_part )
+{
+ // TODO: Maybe also check fat line orthogonal to P0P3, having P0
+ // and P3 as the extremal points
+
+ if( Impl_doBBoxIntersect(c1_part, c2_part) )
+ {
+ // Calculate fat lines around c1
+ FatLine bounds_c2;
+
+ // must use the subdivided version of c2, since the fat line
+ // algorithm works implicitly with the convex hull bounding
+ // box.
+ Impl_calcFatLine(bounds_c2, c2_part);
+
+ // determine clip positions on c2. Can use original c1 (which
+ // is necessary anyway, to get the t's on the original curve),
+ // since the distance calculations work directly in the
+ // Bernstein polynomial parameter domain.
+ if( Impl_calcSafeParams_clip( t1, t2, bounds_c2,
+ calcLineDistance( bounds_c2.a,
+ bounds_c2.b,
+ bounds_c2.c,
+ c1_orig.p0.x,
+ c1_orig.p0.y ),
+ calcLineDistance( bounds_c2.a,
+ bounds_c2.b,
+ bounds_c2.c,
+ c1_orig.p1.x,
+ c1_orig.p1.y ),
+ calcLineDistance( bounds_c2.a,
+ bounds_c2.b,
+ bounds_c2.c,
+ c1_orig.p2.x,
+ c1_orig.p2.y ),
+ calcLineDistance( bounds_c2.a,
+ bounds_c2.b,
+ bounds_c2.c,
+ c1_orig.p3.x,
+ c1_orig.p3.y ) ) )
+ {
+ //printCurvesWithSafeRange(c1_orig, c2_orig, t1, t2, c2_part, bounds_c2);
+
+ // they do intersect
+ return true;
+ }
+ }
+
+ // they don't intersect: nothing to do
+ return false;
+}
+
+/* Tangent intersection part
+ * =========================
+ */
+
+void Impl_calcFocus( Bezier& res, const Bezier& c )
+{
+ // arbitrary small value, for now
+ // TODO: find meaningful value
+ const double minPivotValue( 1.0e-20 );
+
+ Point2D::value_type fMatrix[6];
+ Point2D::value_type fRes[2];
+
+ // calc new curve from hodograph, c and linear blend
+
+ // Coefficients for derivative of c are (C_i=n(C_{i+1} - C_i)):
+
+ // 3(P1 - P0), 3(P2 - P1), 3(P3 - P2) (bezier curve of degree 2)
+
+ // The hodograph is then (bezier curve of 2nd degree is P0(1-t)^2 + 2P1(1-t)t + P2t^2):
+
+ // 3(P1 - P0)(1-t)^2 + 6(P2 - P1)(1-t)t + 3(P3 - P2)t^2
+
+ // rotate by 90 degrees: x=-y, y=x and you get the normal vector function N(t):
+
+ // x(t) = -(3(P1.y - P0.y)(1-t)^2 + 6(P2.y - P1.y)(1-t)t + 3(P3.y - P2.y)t^2)
+ // y(t) = 3(P1.x - P0.x)(1-t)^2 + 6(P2.x - P1.x)(1-t)t + 3(P3.x - P2.x)t^2
+
+ // Now, the focus curve is defined to be F(t)=P(t) + c(t)N(t),
+ // where P(t) is the original curve, and c(t)=c0(1-t) + c1 t
+
+ // This results in the following expression for F(t):
+
+ // x(t) = P0.x (1-t)^3 + 3 P1.x (1-t)^2t + 3 P2.x (1.t)t^2 + P3.x t^3 -
+ // (c0(1-t) + c1 t)(3(P1.y - P0.y)(1-t)^2 + 6(P2.y - P1.y)(1-t)t + 3(P3.y - P2.y)t^2)
+
+ // y(t) = P0.y (1-t)^3 + 3 P1.y (1-t)^2t + 3 P2.y (1.t)t^2 + P3.y t^3 +
+ // (c0(1-t) + c1 t)(3(P1.x - P0.x)(1-t)^2 + 6(P2.x - P1.x)(1-t)t + 3(P3.x - P2.x)t^2)
+
+ // As a heuristic, we set F(0)=F(1) (thus, the curve is closed and _tends_ to be small):
+
+ // For F(0), the following results:
+
+ // x(0) = P0.x - c0 3(P1.y - P0.y)
+ // y(0) = P0.y + c0 3(P1.x - P0.x)
+
+ // For F(1), the following results:
+
+ // x(1) = P3.x - c1 3(P3.y - P2.y)
+ // y(1) = P3.y + c1 3(P3.x - P2.x)
+
+ // Reorder, collect and substitute into F(0)=F(1):
+
+ // P0.x - c0 3(P1.y - P0.y) = P3.x - c1 3(P3.y - P2.y)
+ // P0.y + c0 3(P1.x - P0.x) = P3.y + c1 3(P3.x - P2.x)
+
+ // which yields
+
+ // (P0.y - P1.y)c0 + (P3.y - P2.y)c1 = (P3.x - P0.x)/3
+ // (P1.x - P0.x)c0 + (P2.x - P3.x)c1 = (P3.y - P0.y)/3
+
+ // so, this is what we calculate here (determine c0 and c1):
+ fMatrix[0] = c.p1.x - c.p0.x;
+ fMatrix[1] = c.p2.x - c.p3.x;
+ fMatrix[2] = (c.p3.y - c.p0.y)/3.0;
+ fMatrix[3] = c.p0.y - c.p1.y;
+ fMatrix[4] = c.p3.y - c.p2.y;
+ fMatrix[5] = (c.p3.x - c.p0.x)/3.0;
+
+ // TODO: determine meaningful value for
+ if( !solve(fMatrix, 2, 3, fRes, minPivotValue) )
+ {
+ // TODO: generate meaningful values here
+ // singular or nearly singular system -- use arbitrary
+ // values for res
+ fRes[0] = 0.0;
+ fRes[1] = 1.0;
+
+ std::cerr << "Matrix singular!" << std::endl;
+ }
+
+ // now, the reordered and per-coefficient collected focus curve is
+ // the following third degree bezier curve F(t):
+
+ // x(t) = P0.x (1-t)^3 + 3 P1.x (1-t)^2t + 3 P2.x (1.t)t^2 + P3.x t^3 -
+ // (c0(1-t) + c1 t)(3(P1.y - P0.y)(1-t)^2 + 6(P2.y - P1.y)(1-t)t + 3(P3.y - P2.y)t^2)
+ // = P0.x (1-t)^3 + 3 P1.x (1-t)^2t + 3 P2.x (1.t)t^2 + P3.x t^3 -
+ // (3c0P1.y(1-t)^3 - 3c0P0.y(1-t)^3 + 6c0P2.y(1-t)^2t - 6c0P1.y(1-t)^2t +
+ // 3c0P3.y(1-t)t^2 - 3c0P2.y(1-t)t^2 +
+ // 3c1P1.y(1-t)^2t - 3c1P0.y(1-t)^2t + 6c1P2.y(1-t)t^2 - 6c1P1.y(1-t)t^2 +
+ // 3c1P3.yt^3 - 3c1P2.yt^3)
+ // = (P0.x - 3 c0 P1.y + 3 c0 P0.y)(1-t)^3 +
+ // 3(P1.x - c1 P1.y + c1 P0.y - 2 c0 P2.y + 2 c0 P1.y)(1-t)^2t +
+ // 3(P2.x - 2 c1 P2.y + 2 c1 P1.y - c0 P3.y + c0 P2.y)(1-t)t^2 +
+ // (P3.x - 3 c1 P3.y + 3 c1 P2.y)t^3
+ // = (P0.x - 3 c0(P1.y - P0.y))(1-t)^3 +
+ // 3(P1.x - c1(P1.y - P0.y) - 2c0(P2.y - P1.y))(1-t)^2t +
+ // 3(P2.x - 2 c1(P2.y - P1.y) - c0(P3.y - P2.y))(1-t)t^2 +
+ // (P3.x - 3 c1(P3.y - P2.y))t^3
+
+ // y(t) = P0.y (1-t)^3 + 3 P1.y (1-t)^2t + 3 P2.y (1-t)t^2 + P3.y t^3 +
+ // (c0(1-t) + c1 t)(3(P1.x - P0.x)(1-t)^2 + 6(P2.x - P1.x)(1-t)t + 3(P3.x - P2.x)t^2)
+ // = P0.y (1-t)^3 + 3 P1.y (1-t)^2t + 3 P2.y (1-t)t^2 + P3.y t^3 +
+ // 3c0(P1.x - P0.x)(1-t)^3 + 6c0(P2.x - P1.x)(1-t)^2t + 3c0(P3.x - P2.x)(1-t)t^2 +
+ // 3c1(P1.x - P0.x)(1-t)^2t + 6c1(P2.x - P1.x)(1-t)t^2 + 3c1(P3.x - P2.x)t^3
+ // = (P0.y + 3 c0 (P1.x - P0.x))(1-t)^3 +
+ // 3(P1.y + 2 c0 (P2.x - P1.x) + c1 (P1.x - P0.x))(1-t)^2t +
+ // 3(P2.y + c0 (P3.x - P2.x) + 2 c1 (P2.x - P1.x))(1-t)t^2 +
+ // (P3.y + 3 c1 (P3.x - P2.x))t^3
+
+ // Therefore, the coefficients F0 to F3 of the focus curve are:
+
+ // F0.x = (P0.x - 3 c0(P1.y - P0.y)) F0.y = (P0.y + 3 c0 (P1.x - P0.x))
+ // F1.x = (P1.x - c1(P1.y - P0.y) - 2c0(P2.y - P1.y)) F1.y = (P1.y + 2 c0 (P2.x - P1.x) + c1 (P1.x - P0.x))
+ // F2.x = (P2.x - 2 c1(P2.y - P1.y) - c0(P3.y - P2.y)) F2.y = (P2.y + c0 (P3.x - P2.x) + 2 c1 (P2.x - P1.x))
+ // F3.x = (P3.x - 3 c1(P3.y - P2.y)) F3.y = (P3.y + 3 c1 (P3.x - P2.x))
+
+ res.p0.x = c.p0.x - 3*fRes[0]*(c.p1.y - c.p0.y);
+ res.p1.x = c.p1.x - fRes[1]*(c.p1.y - c.p0.y) - 2*fRes[0]*(c.p2.y - c.p1.y);
+ res.p2.x = c.p2.x - 2*fRes[1]*(c.p2.y - c.p1.y) - fRes[0]*(c.p3.y - c.p2.y);
+ res.p3.x = c.p3.x - 3*fRes[1]*(c.p3.y - c.p2.y);
+
+ res.p0.y = c.p0.y + 3*fRes[0]*(c.p1.x - c.p0.x);
+ res.p1.y = c.p1.y + 2*fRes[0]*(c.p2.x - c.p1.x) + fRes[1]*(c.p1.x - c.p0.x);
+ res.p2.y = c.p2.y + fRes[0]*(c.p3.x - c.p2.x) + 2*fRes[1]*(c.p2.x - c.p1.x);
+ res.p3.y = c.p3.y + 3*fRes[1]*(c.p3.x - c.p2.x);
+}
+
+bool Impl_calcSafeParams_focus( double& t1,
+ double& t2,
+ const Bezier& curve,
+ const Bezier& focus )
+{
+ // now, we want to determine which normals of the original curve
+ // P(t) intersect with the focus curve F(t). The condition for
+ // this statement is P'(t)(P(t) - F) = 0, i.e. hodograph P'(t) and
+ // line through P(t) and F are perpendicular.
+ // If you expand this equation, you end up with something like
+
+ // (\sum_{i=0}^n (P_i - F)B_i^n(t))^T (\sum_{j=0}^{n-1} n(P_{j+1} - P_j)B_j^{n-1}(t))
+
+ // Multiplying that out (as the scalar product is linear, we can
+ // extract some terms) yields:
+
+ // (P_i - F)^T n(P_{j+1} - P_j) B_i^n(t)B_j^{n-1}(t) + ...
+
+ // If we combine the B_i^n(t)B_j^{n-1}(t) product, we arrive at a
+ // Bernstein polynomial of degree 2n-1, as
+
+ // \binom{n}{i}(1-t)^{n-i}t^i) \binom{n-1}{j}(1-t)^{n-1-j}t^j) =
+ // \binom{n}{i}\binom{n-1}{j}(1-t)^{2n-1-i-j}t^{i+j}
+
+ // Thus, with the defining equation for a 2n-1 degree Bernstein
+ // polynomial
+
+ // \sum_{i=0}^{2n-1} d_i B_i^{2n-1}(t)
+
+ // the d_i are calculated as follows:
+
+ // d_i = \sum_{j+k=i, j\in\{0,...,n\}, k\in\{0,...,n-1\}} \frac{\binom{n}{j}\binom{n-1}{k}}{\binom{2n-1}{i}} n (P_{k+1} - P_k)^T(P_j - F)
+
+ // Okay, but F is now not a single point, but itself a curve
+ // F(u). Thus, for every value of u, we get a different 2n-1
+ // bezier curve from the above equation. Therefore, we have a
+ // tensor product bezier patch, with the following defining
+ // equation:
+
+ // d(t,u) = \sum_{i=0}^{2n-1} \sum_{j=0}^m B_i^{2n-1}(t) B_j^{m}(u) d_{ij}, where
+ // d_{ij} = \sum_{k+l=i, l\in\{0,...,n\}, k\in\{0,...,n-1\}} \frac{\binom{n}{l}\binom{n-1}{k}}{\binom{2n-1}{i}} n (P_{k+1} - P_k)^T(P_l - F_j)
+
+ // as above, only that now F is one of the focus' control points.
+
+ // Note the difference in the binomial coefficients to the
+ // reference paper, these formulas most probably contained a typo.
+
+ // To determine, where D(t,u) is _not_ zero (these are the parts
+ // of the curve that don't share normals with the focus and can
+ // thus be safely clipped away), we project D(u,t) onto the
+ // (d(t,u), t) plane, determine the convex hull there and proceed
+ // as for the curve intersection part (projection is orthogonal to
+ // u axis, thus simply throw away u coordinate).
+
+ // \fallfac are so-called falling factorials (see Concrete
+ // Mathematics, p. 47 for a definition).
+
+ // now, for tensor product bezier curves, the convex hull property
+ // holds, too. Thus, we simply project the control points (t_{ij},
+ // u_{ij}, d_{ij}) onto the (t,d) plane and calculate the
+ // intersections of the convex hull with the t axis, as for the
+ // bezier clipping case.
+
+ // calc polygon of control points (t_{ij}, d_{ij}):
+
+ const int n( 3 ); // cubic bezier curves, as a matter of fact
+ const int i_card( 2*n );
+ const int j_card( n + 1 );
+ const int k_max( n-1 );
+ Polygon2D controlPolygon( i_card*j_card ); // vector of (t_{ij}, d_{ij}) in row-major order
+
+ int i, j, k, l; // variable notation from formulas above and Sederberg article
+ Point2D::value_type d;
+ for( i=0; i<i_card; ++i )
+ {
+ for( j=0; j<j_card; ++j )
+ {
+ // calc single d_{ij} sum:
+ for( d=0.0, k=std::max(0,i-n); k<=k_max && k<=i; ++k )
+ {
+ l = i - k; // invariant: k + l = i
+ assert(k>=0 && k<=n-1); // k \in {0,...,n-1}
+ assert(l>=0 && l<=n); // l \in {0,...,n}
+
+ // TODO: find, document and assert proper limits for n and int's max_val.
+ // This becomes important should anybody wants to use
+ // this code for higher-than-cubic beziers
+ d += static_cast<double>(fallFac(n,l)*fallFac(n-1,k)*fac(i)) /
+ static_cast<double>(fac(l)*fac(k) * fallFac(2*n-1,i)) * n *
+ ( (curve[k+1].x - curve[k].x)*(curve[l].x - focus[j].x) + // dot product here
+ (curve[k+1].y - curve[k].y)*(curve[l].y - focus[j].y) );
+ }
+
+ // Note that the t_{ij} values are evenly spaced on the
+ // [0,1] interval, thus t_{ij}=i/(2n-1)
+ controlPolygon[ i*j_card + j ] = Point2D( i/(2.0*n-1.0), d );
+ }
+ }
+
+#ifndef WITH_SAFEFOCUSPARAM_DETAILED_TEST
+
+ // calc safe parameter range, to determine [0,t1] and [t2,1] where
+ // no zero crossing is guaranteed.
+ return Impl_calcSafeParams( t1, t2, controlPolygon, 0.0, 0.0 );
+
+#else
+ bool bRet( Impl_calcSafeParams( t1, t2, controlPolygon, 0.0, 0.0 ) );
+
+ Polygon2D convHull( convexHull( controlPolygon ) );
+
+ std::cout << "# convex hull testing (focus)" << std::endl
+ << "plot [t=0:1] ";
+ std::cout << "'-' using ($1):($2) title \"control polygon\" with lp, "
+ << "'-' using ($1):($2) title \"convex hull\" with lp" << std::endl;
+
+ unsigned int count;
+ for( count=0; count<controlPolygon.size(); ++count )
+ {
+ std::cout << controlPolygon[count].x << " " << controlPolygon[count].y << std::endl;
+ }
+ std::cout << controlPolygon[0].x << " " << controlPolygon[0].y << std::endl;
+ std::cout << "e" << std::endl;
+
+ for( count=0; count<convHull.size(); ++count )
+ {
+ std::cout << convHull[count].x << " " << convHull[count].y << std::endl;
+ }
+ std::cout << convHull[0].x << " " << convHull[0].y << std::endl;
+ std::cout << "e" << std::endl;
+
+ return bRet;
+#endif
+}
+
+/** Calc all values t_i on c1, for which safeRanges functor does not
+ give a safe range on c1 and c2.
+
+ This method is the workhorse of the bezier clipping. Because c1
+ and c2 must be alternatingly tested against each other (first
+ determine safe parameter interval on c1 with regard to c2, then
+ the other way around), we call this method recursively with c1 and
+ c2 swapped.
+
+ @param result
+ Output iterator where the final t values are added to. If curves
+ don't intersect, nothing is added.
+
+ @param delta
+ Maximal allowed distance to true critical point (measured in the
+ original curve's coordinate system)
+
+ @param safeRangeFunctor
+ Functor object, that must provide the following operator():
+ bool safeRangeFunctor( double& t1,
+ double& t2,
+ const Bezier& c1_orig,
+ const Bezier& c1_part,
+ const Bezier& c2_orig,
+ const Bezier& c2_part );
+ This functor must calculate the safe ranges [0,t1] and [t2,1] on
+ c1_orig, where c1_orig is 'safe' from c2_part. If the whole
+ c1_orig is safe, false must be returned, true otherwise.
+ */
+template <class Functor> void Impl_applySafeRanges_rec( std::back_insert_iterator< std::vector< std::pair<double, double> > >& result,
+ double delta,
+ const Functor& safeRangeFunctor,
+ int recursionLevel,
+ const Bezier& c1_orig,
+ const Bezier& c1_part,
+ double last_t1_c1,
+ double last_t2_c1,
+ const Bezier& c2_orig,
+ const Bezier& c2_part,
+ double last_t1_c2,
+ double last_t2_c2 )
+{
+ // check end condition
+ // ===================
+
+ // TODO: tidy up recursion handling. maybe put everything in a
+ // struct and swap that here at method entry
+
+ // TODO: Implement limit on recursion depth. Should that limit be
+ // reached, chances are that we're on a higher-order tangency. For
+ // this case, AW proposed to take the middle of the current
+ // interval, and to correct both curve's tangents at that new
+ // endpoint to be equal. That virtually generates a first-order
+ // tangency, and justifies to return a single intersection
+ // point. Otherwise, inside/outside test might fail here.
+
+ for( int i=0; i<recursionLevel; ++i ) std::cerr << " ";
+ if( recursionLevel % 2 )
+ {
+ std::cerr << std::endl << "level: " << recursionLevel
+ << " t: "
+ << last_t1_c2 + (last_t2_c2 - last_t1_c2)/2.0
+ << ", c1: " << last_t1_c2 << " " << last_t2_c2
+ << ", c2: " << last_t1_c1 << " " << last_t2_c1
+ << std::endl;
+ }
+ else
+ {
+ std::cerr << std::endl << "level: " << recursionLevel
+ << " t: "
+ << last_t1_c1 + (last_t2_c1 - last_t1_c1)/2.0
+ << ", c1: " << last_t1_c1 << " " << last_t2_c1
+ << ", c2: " << last_t1_c2 << " " << last_t2_c2
+ << std::endl;
+ }
+
+ // refine solution
+ // ===============
+
+ double t1_c1, t2_c1;
+
+ // Note: we first perform the clipping and only test for precision
+ // sufficiency afterwards, since we want to exploit the fact that
+ // Impl_calcClipRange returns false if the curves don't
+ // intersect. We would have to check that separately for the end
+ // condition, otherwise.
+
+ // determine safe range on c1_orig
+ if( safeRangeFunctor( t1_c1, t2_c1, c1_orig, c1_part, c2_orig, c2_part ) )
+ {
+ // now, t1 and t2 are calculated on the original curve
+ // (but against a fat line calculated from the subdivided
+ // c2, namely c2_part). If the [t1,t2] range is outside
+ // our current [last_t1,last_t2] range, we're done in this
+ // branch - the curves no longer intersect.
+ if( tolLessEqual(t1_c1, last_t2_c1) && tolGreaterEqual(t2_c1, last_t1_c1) )
+ {
+ // As noted above, t1 and t2 are calculated on the
+ // original curve, but against a fat line
+ // calculated from the subdivided c2, namely
+ // c2_part. Our domain to work on is
+ // [last_t1,last_t2], on the other hand, so values
+ // of [t1,t2] outside that range are irrelevant
+ // here. Clip range appropriately.
+ t1_c1 = std::max(t1_c1, last_t1_c1);
+ t2_c1 = std::min(t2_c1, last_t2_c1);
+
+ // TODO: respect delta
+ // for now, end condition is just a fixed threshold on the t's
+
+ // check end condition
+ // ===================
+
+#if 1
+ if( fabs(last_t2_c1 - last_t1_c1) < 0.0001 &&
+ fabs(last_t2_c2 - last_t1_c2) < 0.0001 )
+#else
+ if( fabs(last_t2_c1 - last_t1_c1) < 0.01 &&
+ fabs(last_t2_c2 - last_t1_c2) < 0.01 )
+#endif
+ {
+ // done. Add to result
+ if( recursionLevel % 2 )
+ {
+ // uneven level: have to swap the t's, since curves are swapped, too
+ *result++ = std::make_pair( last_t1_c2 + (last_t2_c2 - last_t1_c2)/2.0,
+ last_t1_c1 + (last_t2_c1 - last_t1_c1)/2.0 );
+ }
+ else
+ {
+ *result++ = std::make_pair( last_t1_c1 + (last_t2_c1 - last_t1_c1)/2.0,
+ last_t1_c2 + (last_t2_c2 - last_t1_c2)/2.0 );
+ }
+
+#if 0
+ //printResultWithFinalCurves( c1_orig, c1_part, c2_orig, c2_part, last_t1_c1, last_t2_c1 );
+ printResultWithFinalCurves( c1_orig, c1_part, c2_orig, c2_part, t1_c1, t2_c1 );
+#else
+ // calc focus curve of c2
+ Bezier focus;
+ Impl_calcFocus(focus, c2_part); // need to use subdivided c2
+
+ safeRangeFunctor( t1_c1, t2_c1, c1_orig, c1_part, c2_orig, c2_part );
+
+ //printResultWithFinalCurves( c1_orig, c1_part, c2_orig, focus, t1_c1, t2_c1 );
+ printResultWithFinalCurves( c1_orig, c1_part, c2_orig, focus, last_t1_c1, last_t2_c1 );
+#endif
+ }
+ else
+ {
+ // heuristic: if parameter range is not reduced by at least
+ // 20%, subdivide longest curve, and clip shortest against
+ // both parts of longest
+// if( (last_t2_c1 - last_t1_c1 - t2_c1 + t1_c1) / (last_t2_c1 - last_t1_c1) < 0.2 )
+ if( false )
+ {
+ // subdivide and descend
+ // =====================
+
+ Bezier part1;
+ Bezier part2;
+
+ double intervalMiddle;
+
+ if( last_t2_c1 - last_t1_c1 > last_t2_c2 - last_t1_c2 )
+ {
+ // subdivide c1
+ // ============
+
+ intervalMiddle = last_t1_c1 + (last_t2_c1 - last_t1_c1)/2.0;
+
+ // subdivide at the middle of the interval (as
+ // we're not subdividing on the original
+ // curve, this simply amounts to subdivision
+ // at 0.5)
+ Impl_deCasteljauAt( part1, part2, c1_part, 0.5 );
+
+ // and descend recursively with swapped curves
+ Impl_applySafeRanges_rec( result, delta, safeRangeFunctor, recursionLevel+1,
+ c2_orig, c2_part, last_t1_c2, last_t2_c2,
+ c1_orig, part1, last_t1_c1, intervalMiddle );
+
+ Impl_applySafeRanges_rec( result, delta, safeRangeFunctor, recursionLevel+1,
+ c2_orig, c2_part, last_t1_c2, last_t2_c2,
+ c1_orig, part2, intervalMiddle, last_t2_c1 );
+ }
+ else
+ {
+ // subdivide c2
+ // ============
+
+ intervalMiddle = last_t1_c2 + (last_t2_c2 - last_t1_c2)/2.0;
+
+ // subdivide at the middle of the interval (as
+ // we're not subdividing on the original
+ // curve, this simply amounts to subdivision
+ // at 0.5)
+ Impl_deCasteljauAt( part1, part2, c2_part, 0.5 );
+
+ // and descend recursively with swapped curves
+ Impl_applySafeRanges_rec( result, delta, safeRangeFunctor, recursionLevel+1,
+ c2_orig, part1, last_t1_c2, intervalMiddle,
+ c1_orig, c1_part, last_t1_c1, last_t2_c1 );
+
+ Impl_applySafeRanges_rec( result, delta, safeRangeFunctor, recursionLevel+1,
+ c2_orig, part2, intervalMiddle, last_t2_c2,
+ c1_orig, c1_part, last_t1_c1, last_t2_c1 );
+ }
+ }
+ else
+ {
+ // apply calculated clip
+ // =====================
+
+ // clip safe ranges off c1_orig
+ Bezier c1_part1;
+ Bezier c1_part2;
+ Bezier c1_part3;
+
+ // subdivide at t1_c1
+ Impl_deCasteljauAt( c1_part1, c1_part2, c1_orig, t1_c1 );
+
+ // subdivide at t2_c1. As we're working on
+ // c1_part2 now, we have to adapt t2_c1 since
+ // we're no longer in the original parameter
+ // interval. This is based on the following
+ // assumption: t2_new = (t2-t1)/(1-t1), which
+ // relates the t2 value into the new parameter
+ // range [0,1] of c1_part2.
+ Impl_deCasteljauAt( c1_part1, c1_part3, c1_part2, (t2_c1-t1_c1)/(1.0-t1_c1) );
+
+ // descend with swapped curves and c1_part1 as the
+ // remaining (middle) segment
+ Impl_applySafeRanges_rec( result, delta, safeRangeFunctor, recursionLevel+1,
+ c2_orig, c2_part, last_t1_c2, last_t2_c2,
+ c1_orig, c1_part1, t1_c1, t2_c1 );
+ }
+ }
+ }
+ }
+}
+
+struct ClipBezierFunctor
+{
+ bool operator()( double& t1_c1,
+ double& t2_c1,
+ const Bezier& c1_orig,
+ const Bezier& c1_part,
+ const Bezier& c2_orig,
+ const Bezier& c2_part ) const
+ {
+ return Impl_calcClipRange( t1_c1, t2_c1, c1_orig, c1_part, c2_orig, c2_part );
+ }
+};
+
+struct BezierTangencyFunctor
+{
+ bool operator()( double& t1_c1,
+ double& t2_c1,
+ const Bezier& c1_orig,
+ const Bezier& c1_part,
+ const Bezier& c2_orig,
+ const Bezier& c2_part ) const
+ {
+ // calc focus curve of c2
+ Bezier focus;
+ Impl_calcFocus(focus, c2_part); // need to use subdivided c2
+ // here, as the whole curve is
+ // used for focus calculation
+
+ // determine safe range on c1_orig
+ bool bRet( Impl_calcSafeParams_focus( t1_c1, t2_c1,
+ c1_orig, // use orig curve here, need t's on original curve
+ focus ) );
+
+ std::cerr << "range: " << t2_c1 - t1_c1 << ", ret: " << bRet << std::endl;
+
+ return bRet;
+ }
+};
+
+/** Perform a bezier clip (curve against curve)
+
+ @param result
+ Output iterator where the final t values are added to. This
+ iterator will remain empty, if there are no intersections.
+
+ @param delta
+ Maximal allowed distance to true intersection (measured in the
+ original curve's coordinate system)
+ */
+void clipBezier( std::back_insert_iterator< std::vector< std::pair<double, double> > >& result,
+ double delta,
+ const Bezier& c1,
+ const Bezier& c2 )
+{
+#if 0
+ // first of all, determine list of collinear normals. Collinear
+ // normals typically separate two intersections, thus, subdivide
+ // at all collinear normal's t values beforehand. This will cater
+ // for tangent intersections, where two or more intersections are
+ // infinitesimally close together.
+
+ // TODO: evaluate effects of higher-than-second-order
+ // tangencies. Sederberg et al. state that collinear normal
+ // algorithm then degrades quickly.
+
+ std::vector< std::pair<double,double> > results;
+ std::back_insert_iterator< std::vector< std::pair<double, double> > > ii(results);
+
+ Impl_calcCollinearNormals( ii, delta, 0, c1, c1, 0.0, 1.0, c2, c2, 0.0, 1.0 );
+
+ // As Sederberg's collinear normal theorem is only sufficient, not
+ // necessary for two intersections left and right, we've to test
+ // all segments generated by the collinear normal algorithm
+ // against each other. In other words, if the two curves are both
+ // divided in a left and a right part, the collinear normal
+ // theorem does _not_ state that the left part of curve 1 does not
+ // e.g. intersect with the right part of curve 2.
+
+ // divide c1 and c2 at collinear normal intersection points
+ std::vector< Bezier > c1_segments( results.size()+1 );
+ std::vector< Bezier > c2_segments( results.size()+1 );
+ Bezier c1_remainder( c1 );
+ Bezier c2_remainder( c2 );
+ unsigned int i;
+ for( i=0; i<results.size(); ++i )
+ {
+ Bezier c1_part2;
+ Impl_deCasteljauAt( c1_segments[i], c1_part2, c1_remainder, results[i].first );
+ c1_remainder = c1_part2;
+
+ Bezier c2_part2;
+ Impl_deCasteljauAt( c2_segments[i], c2_part2, c2_remainder, results[i].second );
+ c2_remainder = c2_part2;
+ }
+ c1_segments[i] = c1_remainder;
+ c2_segments[i] = c2_remainder;
+
+ // now, c1/c2_segments contain all segments, then
+ // clip every resulting segment against every other
+ unsigned int c1_curr, c2_curr;
+ for( c1_curr=0; c1_curr<c1_segments.size(); ++c1_curr )
+ {
+ for( c2_curr=0; c2_curr<c2_segments.size(); ++c2_curr )
+ {
+ if( c1_curr != c2_curr )
+ {
+ Impl_clipBezier_rec(result, delta, 0,
+ c1_segments[c1_curr], c1_segments[c1_curr],
+ 0.0, 1.0,
+ c2_segments[c2_curr], c2_segments[c2_curr],
+ 0.0, 1.0);
+ }
+ }
+ }
+#else
+ Impl_applySafeRanges_rec( result, delta, BezierTangencyFunctor(), 0, c1, c1, 0.0, 1.0, c2, c2, 0.0, 1.0 );
+ //Impl_applySafeRanges_rec( result, delta, ClipBezierFunctor(), 0, c1, c1, 0.0, 1.0, c2, c2, 0.0, 1.0 );
+#endif
+ // that's it, boys'n'girls!
+}
+
+int main(int argc, const char *argv[])
+{
+ double curr_Offset( 0 );
+ unsigned int i,j,k;
+
+ Bezier someCurves[] =
+ {
+// {Point2D(0.0,0.0),Point2D(0.0,1.0),Point2D(1.0,1.0),Point2D(1.0,0.0)},
+// {Point2D(0.0,0.0),Point2D(0.0,1.0),Point2D(1.0,1.0),Point2D(1.0,0.5)},
+// {Point2D(1.0,0.0),Point2D(0.0,0.0),Point2D(0.0,1.0),Point2D(1.0,1.0)}
+// {Point2D(0.25+1,0.5),Point2D(0.25+1,0.708333),Point2D(0.423611+1,0.916667),Point2D(0.770833+1,0.980324)},
+// {Point2D(0.0+1,0.0),Point2D(0.0+1,1.0),Point2D(1.0+1,1.0),Point2D(1.0+1,0.5)}
+
+// tangency1
+// {Point2D(0.627124+1,0.828427),Point2D(0.763048+1,0.828507),Point2D(0.885547+1,0.77312),Point2D(0.950692+1,0.67325)},
+// {Point2D(0.0,1.0),Point2D(0.1,1.0),Point2D(0.4,1.0),Point2D(0.5,1.0)}
+
+// {Point2D(0.0,0.0),Point2D(0.0,1.0),Point2D(1.0,1.0),Point2D(1.0,0.5)},
+// {Point2D(0.60114,0.933091),Point2D(0.69461,0.969419),Point2D(0.80676,0.992976),Point2D(0.93756,0.998663)}
+// {Point2D(1.0,0.0),Point2D(0.0,0.0),Point2D(0.0,1.0),Point2D(1.0,1.0)},
+// {Point2D(0.62712,0.828427),Point2D(0.76305,0.828507),Point2D(0.88555,0.77312),Point2D(0.95069,0.67325)}
+
+// clipping1
+// {Point2D(0.0,0.0),Point2D(0.0,3.5),Point2D(1.0,-2.5),Point2D(1.0,1.0)},
+// {Point2D(0.0,1.0),Point2D(3.5,1.0),Point2D(-2.5,0.0),Point2D(1.0,0.0)}
+
+// tangency2
+// {Point2D(0.0,1.0),Point2D(3.5,1.0),Point2D(-2.5,0.0),Point2D(1.0,0.0)},
+// {Point2D(15.3621,0.00986464),Point2D(15.3683,0.0109389),Point2D(15.3682,0.0109315),Point2D(15.3621,0.00986464)}
+
+// tangency3
+// {Point2D(1.0,0.0),Point2D(0.0,0.0),Point2D(0.0,1.0),Point2D(1.0,1.0)},
+// {Point2D(-0.5,0.0),Point2D(0.5,0.0),Point2D(0.5,1.0),Point2D(-0.5,1.0)}
+
+// tangency4
+// {Point2D(-0.5,0.0),Point2D(0.5,0.0),Point2D(0.5,1.0),Point2D(-0.5,1.0)},
+// {Point2D(0.26,0.4),Point2D(0.25,0.5),Point2D(0.25,0.5),Point2D(0.26,0.6)}
+
+// tangency5
+// {Point2D(0.0,0.0),Point2D(0.0,3.5),Point2D(1.0,-2.5),Point2D(1.0,1.0)},
+// {Point2D(15.3621,0.00986464),Point2D(15.3683,0.0109389),Point2D(15.3682,0.0109315),Point2D(15.3621,0.00986464)}
+
+// tangency6
+// {Point2D(0.0,0.0),Point2D(0.0,3.5),Point2D(1.0,-2.5),Point2D(1.0,1.0)},
+// {Point2D(15.3621,10.00986464),Point2D(15.3683,10.0109389),Point2D(15.3682,10.0109315),Point2D(15.3621,10.00986464)}
+
+// tangency7
+// {Point2D(2.505,0.0),Point2D(2.505+4.915,4.300),Point2D(2.505+3.213,10.019),Point2D(2.505-2.505,10.255)},
+// {Point2D(15.3621,10.00986464),Point2D(15.3683,10.0109389),Point2D(15.3682,10.0109315),Point2D(15.3621,10.00986464)}
+
+// tangency Sederberg example
+ {Point2D(2.505,0.0),Point2D(2.505+4.915,4.300),Point2D(2.505+3.213,10.019),Point2D(2.505-2.505,10.255)},
+ {Point2D(5.33+9.311,0.0),Point2D(5.33+9.311-13.279,4.205),Point2D(5.33+9.311-10.681,9.119),Point2D(5.33+9.311-2.603,10.254)}
+
+// clipping2
+// {Point2D(-0.5,0.0),Point2D(0.5,0.0),Point2D(0.5,1.0),Point2D(-0.5,1.0)},
+// {Point2D(0.2575,0.4),Point2D(0.2475,0.5),Point2D(0.2475,0.5),Point2D(0.2575,0.6)}
+
+// {Point2D(0.0,0.1),Point2D(0.2,3.5),Point2D(1.0,-2.5),Point2D(1.1,1.2)},
+// {Point2D(0.0,1.0),Point2D(3.5,0.9),Point2D(-2.5,0.1),Point2D(1.1,0.2)}
+// {Point2D(0.0,0.1),Point2D(0.2,3.0),Point2D(1.0,-2.0),Point2D(1.1,1.2)},
+// {Point2D(0.627124+1,0.828427),Point2D(0.763048+1,0.828507),Point2D(0.885547+1,0.77312),Point2D(0.950692+1,0.67325)}
+// {Point2D(0.0,1.0),Point2D(3.0,0.9),Point2D(-2.0,0.1),Point2D(1.1,0.2)}
+// {Point2D(0.0,4.0),Point2D(0.1,5.0),Point2D(0.9,5.0),Point2D(1.0,4.0)},
+// {Point2D(0.0,0.0),Point2D(0.1,0.5),Point2D(0.9,0.5),Point2D(1.0,0.0)},
+// {Point2D(0.0,0.1),Point2D(0.1,1.5),Point2D(0.9,1.5),Point2D(1.0,0.1)},
+// {Point2D(0.0,-4.0),Point2D(0.1,-5.0),Point2D(0.9,-5.0),Point2D(1.0,-4.0)}
+ };
+
+ // output gnuplot setup
+ std::cout << "#!/usr/bin/gnuplot -persist" << std::endl
+ << "#" << std::endl
+ << "# automatically generated by bezierclip, don't change!" << std::endl
+ << "#" << std::endl
+ << "set parametric" << std::endl
+ << "bez(p,q,r,s,t) = p*(1-t)**3+q*3*(1-t)**2*t+r*3*(1-t)*t**2+s*t**3" << std::endl
+ << "bezd(p,q,r,s,t) = 3*(q-p)*(1-t)**2+6*(r-q)*(1-t)*t+3*(s-r)*t**2" << std::endl
+ << "pointmarkx(c,t) = c-0.03*t" << std::endl
+ << "pointmarky(c,t) = c+0.03*t" << std::endl
+ << "linex(a,b,c,t) = a*-c + t*-b" << std::endl
+ << "liney(a,b,c,t) = b*-c + t*a" << std::endl << std::endl
+ << "# end of setup" << std::endl << std::endl;
+
+#ifdef WITH_CONVEXHULL_TEST
+ // test convex hull algorithm
+ const double convHull_xOffset( curr_Offset );
+ curr_Offset += 20;
+ std::cout << "# convex hull testing" << std::endl
+ << "plot [t=0:1] ";
+ for( i=0; i<sizeof(someCurves)/sizeof(Bezier); ++i )
+ {
+ Polygon2D aTestPoly(4);
+ aTestPoly[0] = someCurves[i].p0;
+ aTestPoly[1] = someCurves[i].p1;
+ aTestPoly[2] = someCurves[i].p2;
+ aTestPoly[3] = someCurves[i].p3;
+
+ aTestPoly[0].x += convHull_xOffset;
+ aTestPoly[1].x += convHull_xOffset;
+ aTestPoly[2].x += convHull_xOffset;
+ aTestPoly[3].x += convHull_xOffset;
+
+ std::cout << " bez("
+ << aTestPoly[0].x << ","
+ << aTestPoly[1].x << ","
+ << aTestPoly[2].x << ","
+ << aTestPoly[3].x << ",t),bez("
+ << aTestPoly[0].y << ","
+ << aTestPoly[1].y << ","
+ << aTestPoly[2].y << ","
+ << aTestPoly[3].y << ",t), '-' using ($1):($2) title \"convex hull " << i << "\" with lp";
+
+ if( i+1<sizeof(someCurves)/sizeof(Bezier) )
+ std::cout << ",\\" << std::endl;
+ else
+ std::cout << std::endl;
+ }
+ for( i=0; i<sizeof(someCurves)/sizeof(Bezier); ++i )
+ {
+ Polygon2D aTestPoly(4);
+ aTestPoly[0] = someCurves[i].p0;
+ aTestPoly[1] = someCurves[i].p1;
+ aTestPoly[2] = someCurves[i].p2;
+ aTestPoly[3] = someCurves[i].p3;
+
+ aTestPoly[0].x += convHull_xOffset;
+ aTestPoly[1].x += convHull_xOffset;
+ aTestPoly[2].x += convHull_xOffset;
+ aTestPoly[3].x += convHull_xOffset;
+
+ Polygon2D convHull( convexHull(aTestPoly) );
+
+ for( k=0; k<convHull.size(); ++k )
+ {
+ std::cout << convHull[k].x << " " << convHull[k].y << std::endl;
+ }
+ std::cout << convHull[0].x << " " << convHull[0].y << std::endl;
+ std::cout << "e" << std::endl;
+ }
+#endif
+
+#ifdef WITH_MULTISUBDIVIDE_TEST
+ // test convex hull algorithm
+ const double multiSubdivide_xOffset( curr_Offset );
+ curr_Offset += 20;
+ std::cout << "# multi subdivide testing" << std::endl
+ << "plot [t=0:1] ";
+ for( i=0; i<sizeof(someCurves)/sizeof(Bezier); ++i )
+ {
+ Bezier c( someCurves[i] );
+ Bezier c1_part1;
+ Bezier c1_part2;
+ Bezier c1_part3;
+
+ c.p0.x += multiSubdivide_xOffset;
+ c.p1.x += multiSubdivide_xOffset;
+ c.p2.x += multiSubdivide_xOffset;
+ c.p3.x += multiSubdivide_xOffset;
+
+ const double t1( 0.1+i/(3.0*sizeof(someCurves)/sizeof(Bezier)) );
+ const double t2( 0.9-i/(3.0*sizeof(someCurves)/sizeof(Bezier)) );
+
+ // subdivide at t1
+ Impl_deCasteljauAt( c1_part1, c1_part2, c, t1 );
+
+ // subdivide at t2_c1. As we're working on
+ // c1_part2 now, we have to adapt t2_c1 since
+ // we're no longer in the original parameter
+ // interval. This is based on the following
+ // assumption: t2_new = (t2-t1)/(1-t1), which
+ // relates the t2 value into the new parameter
+ // range [0,1] of c1_part2.
+ Impl_deCasteljauAt( c1_part1, c1_part3, c1_part2, (t2-t1)/(1.0-t1) );
+
+ // subdivide at t2
+ Impl_deCasteljauAt( c1_part3, c1_part2, c, t2 );
+
+ std::cout << " bez("
+ << c1_part1.p0.x << ","
+ << c1_part1.p1.x << ","
+ << c1_part1.p2.x << ","
+ << c1_part1.p3.x << ",t), bez("
+ << c1_part1.p0.y+0.01 << ","
+ << c1_part1.p1.y+0.01 << ","
+ << c1_part1.p2.y+0.01 << ","
+ << c1_part1.p3.y+0.01 << ",t) title \"middle " << i << "\", "
+ << " bez("
+ << c1_part2.p0.x << ","
+ << c1_part2.p1.x << ","
+ << c1_part2.p2.x << ","
+ << c1_part2.p3.x << ",t), bez("
+ << c1_part2.p0.y << ","
+ << c1_part2.p1.y << ","
+ << c1_part2.p2.y << ","
+ << c1_part2.p3.y << ",t) title \"right " << i << "\", "
+ << " bez("
+ << c1_part3.p0.x << ","
+ << c1_part3.p1.x << ","
+ << c1_part3.p2.x << ","
+ << c1_part3.p3.x << ",t), bez("
+ << c1_part3.p0.y << ","
+ << c1_part3.p1.y << ","
+ << c1_part3.p2.y << ","
+ << c1_part3.p3.y << ",t) title \"left " << i << "\"";
+
+ if( i+1<sizeof(someCurves)/sizeof(Bezier) )
+ std::cout << ",\\" << std::endl;
+ else
+ std::cout << std::endl;
+ }
+#endif
+
+#ifdef WITH_FATLINE_TEST
+ // test fatline algorithm
+ const double fatLine_xOffset( curr_Offset );
+ curr_Offset += 20;
+ std::cout << "# fat line testing" << std::endl
+ << "plot [t=0:1] ";
+ for( i=0; i<sizeof(someCurves)/sizeof(Bezier); ++i )
+ {
+ Bezier c( someCurves[i] );
+
+ c.p0.x += fatLine_xOffset;
+ c.p1.x += fatLine_xOffset;
+ c.p2.x += fatLine_xOffset;
+ c.p3.x += fatLine_xOffset;
+
+ FatLine line;
+
+ Impl_calcFatLine(line, c);
+
+ std::cout << " bez("
+ << c.p0.x << ","
+ << c.p1.x << ","
+ << c.p2.x << ","
+ << c.p3.x << ",t), bez("
+ << c.p0.y << ","
+ << c.p1.y << ","
+ << c.p2.y << ","
+ << c.p3.y << ",t) title \"bezier " << i << "\", linex("
+ << line.a << ","
+ << line.b << ","
+ << line.c << ",t), liney("
+ << line.a << ","
+ << line.b << ","
+ << line.c << ",t) title \"fat line (center) on " << i << "\", linex("
+ << line.a << ","
+ << line.b << ","
+ << line.c-line.dMin << ",t), liney("
+ << line.a << ","
+ << line.b << ","
+ << line.c-line.dMin << ",t) title \"fat line (min) on " << i << "\", linex("
+ << line.a << ","
+ << line.b << ","
+ << line.c-line.dMax << ",t), liney("
+ << line.a << ","
+ << line.b << ","
+ << line.c-line.dMax << ",t) title \"fat line (max) on " << i << "\"";
+
+ if( i+1<sizeof(someCurves)/sizeof(Bezier) )
+ std::cout << ",\\" << std::endl;
+ else
+ std::cout << std::endl;
+ }
+#endif
+
+#ifdef WITH_CALCFOCUS_TEST
+ // test focus curve algorithm
+ const double focus_xOffset( curr_Offset );
+ curr_Offset += 20;
+ std::cout << "# focus line testing" << std::endl
+ << "plot [t=0:1] ";
+ for( i=0; i<sizeof(someCurves)/sizeof(Bezier); ++i )
+ {
+ Bezier c( someCurves[i] );
+
+ c.p0.x += focus_xOffset;
+ c.p1.x += focus_xOffset;
+ c.p2.x += focus_xOffset;
+ c.p3.x += focus_xOffset;
+
+ // calc focus curve
+ Bezier focus;
+ Impl_calcFocus(focus, c);
+
+ std::cout << " bez("
+ << c.p0.x << ","
+ << c.p1.x << ","
+ << c.p2.x << ","
+ << c.p3.x << ",t), bez("
+ << c.p0.y << ","
+ << c.p1.y << ","
+ << c.p2.y << ","
+ << c.p3.y << ",t) title \"bezier " << i << "\", bez("
+ << focus.p0.x << ","
+ << focus.p1.x << ","
+ << focus.p2.x << ","
+ << focus.p3.x << ",t), bez("
+ << focus.p0.y << ","
+ << focus.p1.y << ","
+ << focus.p2.y << ","
+ << focus.p3.y << ",t) title \"focus " << i << "\"";
+
+ if( i+1<sizeof(someCurves)/sizeof(Bezier) )
+ std::cout << ",\\" << std::endl;
+ else
+ std::cout << std::endl;
+ }
+#endif
+
+#ifdef WITH_SAFEPARAMBASE_TEST
+ // test safe params base method
+ double safeParamsBase_xOffset( curr_Offset );
+ std::cout << "# safe param base method testing" << std::endl
+ << "plot [t=0:1] ";
+ for( i=0; i<sizeof(someCurves)/sizeof(Bezier); ++i )
+ {
+ Bezier c( someCurves[i] );
+
+ c.p0.x += safeParamsBase_xOffset;
+ c.p1.x += safeParamsBase_xOffset;
+ c.p2.x += safeParamsBase_xOffset;
+ c.p3.x += safeParamsBase_xOffset;
+
+ Polygon2D poly(4);
+ poly[0] = c.p0;
+ poly[1] = c.p1;
+ poly[2] = c.p2;
+ poly[3] = c.p3;
+
+ double t1, t2;
+
+ bool bRet( Impl_calcSafeParams( t1, t2, poly, 0, 1 ) );
+
+ Polygon2D convHull( convexHull( poly ) );
+
+ std::cout << " bez("
+ << poly[0].x << ","
+ << poly[1].x << ","
+ << poly[2].x << ","
+ << poly[3].x << ",t),bez("
+ << poly[0].y << ","
+ << poly[1].y << ","
+ << poly[2].y << ","
+ << poly[3].y << ",t), "
+ << "t+" << safeParamsBase_xOffset << ", 0, "
+ << "t+" << safeParamsBase_xOffset << ", 1, ";
+ if( bRet )
+ {
+ std::cout << t1+safeParamsBase_xOffset << ", t, "
+ << t2+safeParamsBase_xOffset << ", t, ";
+ }
+ std::cout << "'-' using ($1):($2) title \"control polygon\" with lp, "
+ << "'-' using ($1):($2) title \"convex hull\" with lp";
+
+ if( i+1<sizeof(someCurves)/sizeof(Bezier) )
+ std::cout << ",\\" << std::endl;
+ else
+ std::cout << std::endl;
+
+ safeParamsBase_xOffset += 2;
+ }
+
+ safeParamsBase_xOffset = curr_Offset;
+ for( i=0; i<sizeof(someCurves)/sizeof(Bezier); ++i )
+ {
+ Bezier c( someCurves[i] );
+
+ c.p0.x += safeParamsBase_xOffset;
+ c.p1.x += safeParamsBase_xOffset;
+ c.p2.x += safeParamsBase_xOffset;
+ c.p3.x += safeParamsBase_xOffset;
+
+ Polygon2D poly(4);
+ poly[0] = c.p0;
+ poly[1] = c.p1;
+ poly[2] = c.p2;
+ poly[3] = c.p3;
+
+ double t1, t2;
+
+ Impl_calcSafeParams( t1, t2, poly, 0, 1 );
+
+ Polygon2D convHull( convexHull( poly ) );
+
+ unsigned int k;
+ for( k=0; k<poly.size(); ++k )
+ {
+ std::cout << poly[k].x << " " << poly[k].y << std::endl;
+ }
+ std::cout << poly[0].x << " " << poly[0].y << std::endl;
+ std::cout << "e" << std::endl;
+
+ for( k=0; k<convHull.size(); ++k )
+ {
+ std::cout << convHull[k].x << " " << convHull[k].y << std::endl;
+ }
+ std::cout << convHull[0].x << " " << convHull[0].y << std::endl;
+ std::cout << "e" << std::endl;
+
+ safeParamsBase_xOffset += 2;
+ }
+ curr_Offset += 20;
+#endif
+
+#ifdef WITH_SAFEPARAMS_TEST
+ // test safe parameter range algorithm
+ const double safeParams_xOffset( curr_Offset );
+ curr_Offset += 20;
+ std::cout << "# safe param range testing" << std::endl
+ << "plot [t=0.0:1.0] ";
+ for( i=0; i<sizeof(someCurves)/sizeof(Bezier); ++i )
+ {
+ for( j=i+1; j<sizeof(someCurves)/sizeof(Bezier); ++j )
+ {
+ Bezier c1( someCurves[i] );
+ Bezier c2( someCurves[j] );
+
+ c1.p0.x += safeParams_xOffset;
+ c1.p1.x += safeParams_xOffset;
+ c1.p2.x += safeParams_xOffset;
+ c1.p3.x += safeParams_xOffset;
+ c2.p0.x += safeParams_xOffset;
+ c2.p1.x += safeParams_xOffset;
+ c2.p2.x += safeParams_xOffset;
+ c2.p3.x += safeParams_xOffset;
+
+ double t1, t2;
+
+ if( Impl_calcClipRange(t1, t2, c1, c1, c2, c2) )
+ {
+ // clip safe ranges off c1
+ Bezier c1_part1;
+ Bezier c1_part2;
+ Bezier c1_part3;
+
+ // subdivide at t1_c1
+ Impl_deCasteljauAt( c1_part1, c1_part2, c1, t1 );
+ // subdivide at t2_c1
+ Impl_deCasteljauAt( c1_part1, c1_part3, c1_part2, (t2-t1)/(1.0-t1) );
+
+ // output remaining segment (c1_part1)
+
+ std::cout << " bez("
+ << c1.p0.x << ","
+ << c1.p1.x << ","
+ << c1.p2.x << ","
+ << c1.p3.x << ",t),bez("
+ << c1.p0.y << ","
+ << c1.p1.y << ","
+ << c1.p2.y << ","
+ << c1.p3.y << ",t), bez("
+ << c2.p0.x << ","
+ << c2.p1.x << ","
+ << c2.p2.x << ","
+ << c2.p3.x << ",t),bez("
+ << c2.p0.y << ","
+ << c2.p1.y << ","
+ << c2.p2.y << ","
+ << c2.p3.y << ",t), bez("
+ << c1_part1.p0.x << ","
+ << c1_part1.p1.x << ","
+ << c1_part1.p2.x << ","
+ << c1_part1.p3.x << ",t),bez("
+ << c1_part1.p0.y << ","
+ << c1_part1.p1.y << ","
+ << c1_part1.p2.y << ","
+ << c1_part1.p3.y << ",t)";
+
+ if( i+2<sizeof(someCurves)/sizeof(Bezier) )
+ std::cout << ",\\" << std::endl;
+ else
+ std::cout << std::endl;
+ }
+ }
+ }
+#endif
+
+#ifdef WITH_SAFEPARAM_DETAILED_TEST
+ // test safe parameter range algorithm
+ const double safeParams2_xOffset( curr_Offset );
+ curr_Offset += 20;
+ if( sizeof(someCurves)/sizeof(Bezier) > 1 )
+ {
+ Bezier c1( someCurves[0] );
+ Bezier c2( someCurves[1] );
+
+ c1.p0.x += safeParams2_xOffset;
+ c1.p1.x += safeParams2_xOffset;
+ c1.p2.x += safeParams2_xOffset;
+ c1.p3.x += safeParams2_xOffset;
+ c2.p0.x += safeParams2_xOffset;
+ c2.p1.x += safeParams2_xOffset;
+ c2.p2.x += safeParams2_xOffset;
+ c2.p3.x += safeParams2_xOffset;
+
+ double t1, t2;
+
+ // output happens here
+ Impl_calcClipRange(t1, t2, c1, c1, c2, c2);
+ }
+#endif
+
+#ifdef WITH_SAFEFOCUSPARAM_TEST
+ // test safe parameter range from focus algorithm
+ const double safeParamsFocus_xOffset( curr_Offset );
+ curr_Offset += 20;
+ std::cout << "# safe param range from focus testing" << std::endl
+ << "plot [t=0.0:1.0] ";
+ for( i=0; i<sizeof(someCurves)/sizeof(Bezier); ++i )
+ {
+ for( j=i+1; j<sizeof(someCurves)/sizeof(Bezier); ++j )
+ {
+ Bezier c1( someCurves[i] );
+ Bezier c2( someCurves[j] );
+
+ c1.p0.x += safeParamsFocus_xOffset;
+ c1.p1.x += safeParamsFocus_xOffset;
+ c1.p2.x += safeParamsFocus_xOffset;
+ c1.p3.x += safeParamsFocus_xOffset;
+ c2.p0.x += safeParamsFocus_xOffset;
+ c2.p1.x += safeParamsFocus_xOffset;
+ c2.p2.x += safeParamsFocus_xOffset;
+ c2.p3.x += safeParamsFocus_xOffset;
+
+ double t1, t2;
+
+ Bezier focus;
+#ifdef WITH_SAFEFOCUSPARAM_CALCFOCUS
+#if 0
+ {
+ // clip safe ranges off c1_orig
+ Bezier c1_part1;
+ Bezier c1_part2;
+ Bezier c1_part3;
+
+ // subdivide at t1_c1
+ Impl_deCasteljauAt( c1_part1, c1_part2, c2, 0.30204 );
+
+ // subdivide at t2_c1. As we're working on
+ // c1_part2 now, we have to adapt t2_c1 since
+ // we're no longer in the original parameter
+ // interval. This is based on the following
+ // assumption: t2_new = (t2-t1)/(1-t1), which
+ // relates the t2 value into the new parameter
+ // range [0,1] of c1_part2.
+ Impl_deCasteljauAt( c1_part1, c1_part3, c1_part2, (0.57151-0.30204)/(1.0-0.30204) );
+
+ c2 = c1_part1;
+ Impl_calcFocus( focus, c2 );
+ }
+#else
+ Impl_calcFocus( focus, c2 );
+#endif
+#else
+ focus = c2;
+#endif
+ // determine safe range on c1
+ bool bRet( Impl_calcSafeParams_focus( t1, t2,
+ c1, focus ) );
+
+ std::cerr << "t1: " << t1 << ", t2: " << t2 << std::endl;
+
+ // clip safe ranges off c1
+ Bezier c1_part1;
+ Bezier c1_part2;
+ Bezier c1_part3;
+
+ // subdivide at t1_c1
+ Impl_deCasteljauAt( c1_part1, c1_part2, c1, t1 );
+ // subdivide at t2_c1
+ Impl_deCasteljauAt( c1_part1, c1_part3, c1_part2, (t2-t1)/(1.0-t1) );
+
+ // output remaining segment (c1_part1)
+
+ std::cout << " bez("
+ << c1.p0.x << ","
+ << c1.p1.x << ","
+ << c1.p2.x << ","
+ << c1.p3.x << ",t),bez("
+ << c1.p0.y << ","
+ << c1.p1.y << ","
+ << c1.p2.y << ","
+ << c1.p3.y << ",t) title \"c1\", "
+#ifdef WITH_SAFEFOCUSPARAM_CALCFOCUS
+ << "bez("
+ << c2.p0.x << ","
+ << c2.p1.x << ","
+ << c2.p2.x << ","
+ << c2.p3.x << ",t),bez("
+ << c2.p0.y << ","
+ << c2.p1.y << ","
+ << c2.p2.y << ","
+ << c2.p3.y << ",t) title \"c2\", "
+ << "bez("
+ << focus.p0.x << ","
+ << focus.p1.x << ","
+ << focus.p2.x << ","
+ << focus.p3.x << ",t),bez("
+ << focus.p0.y << ","
+ << focus.p1.y << ","
+ << focus.p2.y << ","
+ << focus.p3.y << ",t) title \"focus\"";
+#else
+ << "bez("
+ << c2.p0.x << ","
+ << c2.p1.x << ","
+ << c2.p2.x << ","
+ << c2.p3.x << ",t),bez("
+ << c2.p0.y << ","
+ << c2.p1.y << ","
+ << c2.p2.y << ","
+ << c2.p3.y << ",t) title \"focus\"";
+#endif
+ if( bRet )
+ {
+ std::cout << ", bez("
+ << c1_part1.p0.x << ","
+ << c1_part1.p1.x << ","
+ << c1_part1.p2.x << ","
+ << c1_part1.p3.x << ",t),bez("
+ << c1_part1.p0.y+0.01 << ","
+ << c1_part1.p1.y+0.01 << ","
+ << c1_part1.p2.y+0.01 << ","
+ << c1_part1.p3.y+0.01 << ",t) title \"part\"";
+ }
+
+ if( i+2<sizeof(someCurves)/sizeof(Bezier) )
+ std::cout << ",\\" << std::endl;
+ else
+ std::cout << std::endl;
+ }
+ }
+#endif
+
+#ifdef WITH_SAFEFOCUSPARAM_DETAILED_TEST
+ // test safe parameter range algorithm
+ const double safeParams3_xOffset( curr_Offset );
+ curr_Offset += 20;
+ if( sizeof(someCurves)/sizeof(Bezier) > 1 )
+ {
+ Bezier c1( someCurves[0] );
+ Bezier c2( someCurves[1] );
+
+ c1.p0.x += safeParams3_xOffset;
+ c1.p1.x += safeParams3_xOffset;
+ c1.p2.x += safeParams3_xOffset;
+ c1.p3.x += safeParams3_xOffset;
+ c2.p0.x += safeParams3_xOffset;
+ c2.p1.x += safeParams3_xOffset;
+ c2.p2.x += safeParams3_xOffset;
+ c2.p3.x += safeParams3_xOffset;
+
+ double t1, t2;
+
+ Bezier focus;
+#ifdef WITH_SAFEFOCUSPARAM_CALCFOCUS
+ Impl_calcFocus( focus, c2 );
+#else
+ focus = c2;
+#endif
+
+ // determine safe range on c1, output happens here
+ Impl_calcSafeParams_focus( t1, t2,
+ c1, focus );
+ }
+#endif
+
+#ifdef WITH_BEZIERCLIP_TEST
+ std::vector< std::pair<double, double> > result;
+ std::back_insert_iterator< std::vector< std::pair<double, double> > > ii(result);
+
+ // test full bezier clipping
+ const double bezierClip_xOffset( curr_Offset );
+ std::cout << std::endl << std::endl << "# bezier clip testing" << std::endl
+ << "plot [t=0:1] ";
+ for( i=0; i<sizeof(someCurves)/sizeof(Bezier); ++i )
+ {
+ for( j=i+1; j<sizeof(someCurves)/sizeof(Bezier); ++j )
+ {
+ Bezier c1( someCurves[i] );
+ Bezier c2( someCurves[j] );
+
+ c1.p0.x += bezierClip_xOffset;
+ c1.p1.x += bezierClip_xOffset;
+ c1.p2.x += bezierClip_xOffset;
+ c1.p3.x += bezierClip_xOffset;
+ c2.p0.x += bezierClip_xOffset;
+ c2.p1.x += bezierClip_xOffset;
+ c2.p2.x += bezierClip_xOffset;
+ c2.p3.x += bezierClip_xOffset;
+
+ std::cout << " bez("
+ << c1.p0.x << ","
+ << c1.p1.x << ","
+ << c1.p2.x << ","
+ << c1.p3.x << ",t),bez("
+ << c1.p0.y << ","
+ << c1.p1.y << ","
+ << c1.p2.y << ","
+ << c1.p3.y << ",t), bez("
+ << c2.p0.x << ","
+ << c2.p1.x << ","
+ << c2.p2.x << ","
+ << c2.p3.x << ",t),bez("
+ << c2.p0.y << ","
+ << c2.p1.y << ","
+ << c2.p2.y << ","
+ << c2.p3.y << ",t), '-' using (bez("
+ << c1.p0.x << ","
+ << c1.p1.x << ","
+ << c1.p2.x << ","
+ << c1.p3.x
+ << ",$1)):(bez("
+ << c1.p0.y << ","
+ << c1.p1.y << ","
+ << c1.p2.y << ","
+ << c1.p3.y << ",$1)) title \"bezier " << i << " clipped against " << j << " (t on " << i << ")\", "
+ << " '-' using (bez("
+ << c2.p0.x << ","
+ << c2.p1.x << ","
+ << c2.p2.x << ","
+ << c2.p3.x
+ << ",$1)):(bez("
+ << c2.p0.y << ","
+ << c2.p1.y << ","
+ << c2.p2.y << ","
+ << c2.p3.y << ",$1)) title \"bezier " << i << " clipped against " << j << " (t on " << j << ")\"";
+
+ if( i+2<sizeof(someCurves)/sizeof(Bezier) )
+ std::cout << ",\\" << std::endl;
+ else
+ std::cout << std::endl;
+ }
+ }
+ for( i=0; i<sizeof(someCurves)/sizeof(Bezier); ++i )
+ {
+ for( j=i+1; j<sizeof(someCurves)/sizeof(Bezier); ++j )
+ {
+ result.clear();
+ Bezier c1( someCurves[i] );
+ Bezier c2( someCurves[j] );
+
+ c1.p0.x += bezierClip_xOffset;
+ c1.p1.x += bezierClip_xOffset;
+ c1.p2.x += bezierClip_xOffset;
+ c1.p3.x += bezierClip_xOffset;
+ c2.p0.x += bezierClip_xOffset;
+ c2.p1.x += bezierClip_xOffset;
+ c2.p2.x += bezierClip_xOffset;
+ c2.p3.x += bezierClip_xOffset;
+
+ clipBezier( ii, 0.00001, c1, c2 );
+
+ for( k=0; k<result.size(); ++k )
+ {
+ std::cout << result[k].first << std::endl;
+ }
+ std::cout << "e" << std::endl;
+
+ for( k=0; k<result.size(); ++k )
+ {
+ std::cout << result[k].second << std::endl;
+ }
+ std::cout << "e" << std::endl;
+ }
+ }
+#endif
+
+ return 0;
+}
+
+/* vim:set shiftwidth=4 softtabstop=4 expandtab: */