X-Git-Url: https://git.pterodactylus.net/?a=blobdiff_plain;f=synfig-studio%2Ftrunk%2Fsrc%2Fsynfigapp%2Fblineconvert.cpp;h=957e667a75740114e147db934044967da1a6fad0;hb=d15c4522466bedfbe61620c401becae0931854f5;hp=724c2b8628b303470ce6afdd391b20c340bd21cb;hpb=02252941b29de64037116f4d37991a38d9ff0d94;p=synfig.git diff --git a/synfig-studio/trunk/src/synfigapp/blineconvert.cpp b/synfig-studio/trunk/src/synfigapp/blineconvert.cpp index 724c2b8..957e667 100644 --- a/synfig-studio/trunk/src/synfigapp/blineconvert.cpp +++ b/synfig-studio/trunk/src/synfigapp/blineconvert.cpp @@ -2,19 +2,21 @@ /*! \file blineconvert.cpp ** \brief Template File ** -** $Id: blineconvert.cpp,v 1.1.1.1 2005/01/07 03:34:37 darco Exp $ +** $Id$ ** ** \legal -** Copyright (c) 2002 Robert B. Quattlebaum Jr. +** Copyright (c) 2002-2005 Robert B. Quattlebaum Jr., Adrian Bentley +** Copyright (c) 2007 Chris Moore ** -** This software and associated documentation -** are CONFIDENTIAL and PROPRIETARY property of -** the above-mentioned copyright holder. +** This package is free software; you can redistribute it and/or +** modify it under the terms of the GNU General Public License as +** published by the Free Software Foundation; either version 2 of +** the License, or (at your option) any later version. ** -** You may not copy, print, publish, or in any -** other way distribute this software without -** a prior written agreement with -** the copyright holder. +** This package is distributed in the hope that it will be useful, +** but WITHOUT ANY WARRANTY; without even the implied warranty of +** MERCHANTABILITY or FITNESS FOR A PARTICULAR PURPOSE. See the GNU +** General Public License for more details. ** \endlegal */ /* ========================================================================= */ @@ -38,7 +40,7 @@ #include #include - +#include "general.h" #endif @@ -65,127 +67,114 @@ using namespace synfig; template < class T > inline void FivePointdt(T &df, const T &f1, const T &f2, const T &f3, const T &f4, const T &f5, int bias) { - if(bias == 0) - { - //middle + if (bias == 0) // middle df = (f1 - f2*8 + f4*8 - f5)*(1/12.0f); - }else if(bias < 0) - { - //left + else if (bias < 0) // left df = (-f1*25 + f2*48 - f3*36 + f4*16 - f5*3)*(1/12.0f); - }else - { - //right + else // right df = (f1*3 - f2*16 + f3*36 - f4*48 + f5*25)*(1/12.0f); - } } template < class T > inline void ThreePointdt(T &df, const T &f1, const T &f2, const T &f3, int bias) { - if(bias == 0) - { - //middle + if (bias == 0) // middle df = (-f1 + f3)*(1/2.0f); - }else if(bias < 0) - { - //left + else if (bias < 0) // left df = (-f1*3 + f2*4 - f3)*(1/2.0f); - }else - { - //right + else // right df = (f1 - f2*4 + f3*3)*(1/2.0f); - } -} - -template < class T > -inline void ThreePointddt(T &df, const T &f1, const T &f2, const T &f3, int bias) -{ - //a 3 point approximation pretends to have constant acceleration, so only one algorithm needed for left, middle, or right - df = (f1 -f2*2 + f3)*(1/2.0f); } -// WARNING -- totaly broken -template < class T > -inline void FivePointddt(T &df, const T &f1, const T &f2, const T &f3, int bias) -{ - if(bias == 0) - { - assert(0); // !? - //middle - //df = (- f1 + f2*16 - f3*30 + f4*16 - f5)*(1/12.0f); - }/*else if(bias < 0) - { - //left - df = (f1*7 - f2*26*4 + f3*19*6 - f4*14*4 + f5*11)*(1/12.0f); - }else - { - //right - df = (f1*3 - f2*16 + f3*36 - f4*48 + f5*25)*(1/12.0f); - }*/ - //side ones don't work, use 3 point -} - -//implement an arbitrary derivative -//dumb algorithm -template < class T > -void DerivativeApprox(T &df, const T f[], const Real t[], int npoints, int indexval) -{ - /* - Lj(x) = PI_i!=j (x - xi) / PI_i!=j (xj - xi) - - so Lj'(x) = SUM_k PI_i!=j|k (x - xi) / PI_i!=j (xj - xi) - */ - - unsigned int i,j,k,i0,i1; - - Real Lpj,mult,div,tj; - Real tval = t[indexval]; - - //sum k - for(j=0;j +// inline void ThreePointddt(T &df, const T &f1, const T &f2, const T &f3, int bias) +// { +// // a 3 point approximation pretends to have constant acceleration, +// // so only one algorithm needed for left, middle, or right +// df = (f1 -f2*2 + f3)*(1/2.0f); +// } +// +// // WARNING -- totally broken +// template < class T > +// inline void FivePointddt(T &df, const T &f1, const T &f2, const T &f3, int bias) +// { +// if(bias == 0) +// { +// assert(0); // !? +// //middle +// //df = (- f1 + f2*16 - f3*30 + f4*16 - f5)*(1/12.0f); +// }/*else if(bias < 0) +// { +// //left +// df = (f1*7 - f2*26*4 + f3*19*6 - f4*14*4 + f5*11)*(1/12.0f); +// }else +// { +// //right +// df = (f1*3 - f2*16 + f3*36 - f4*48 + f5*25)*(1/12.0f); +// }*/ +// //side ones don't work, use 3 point +// } +// +// //implement an arbitrary derivative +// //dumb algorithm +// template < class T > +// void DerivativeApprox(T &df, const T f[], const Real t[], int npoints, int indexval) +// { +// /* +// Lj(x) = PI_i!=j (x - xi) / PI_i!=j (xj - xi) +// +// so Lj'(x) = SUM_k PI_i!=j|k (x - xi) / PI_i!=j (xj - xi) +// */ +// +// unsigned int i,j,k,i0,i1; +// +// Real Lpj,mult,div,tj; +// Real tval = t[indexval]; +// +// //sum k +// for(j=0;j -inline int sign(T f, T tol) -{ - if(f < -tol) return -1; - if(f > tol) return 1; - return 0; -} +// template < class T > +// inline int sign(T f, T tol) +// { +// if(f < -tol) return -1; +// if(f > tol) return 1; +// return 0; +// } void GetFirstDerivatives(const std::vector &f, unsigned int left, unsigned int right, char *out, unsigned int dfstride) { @@ -193,10 +182,10 @@ void GetFirstDerivatives(const std::vector &f, unsigned int left, if(right - left < 2) return; - else if(right - left < 3) + else if(right - left == 2) { synfig::Vector v = f[left+1] - f[left]; - + //set both to the one we want *(synfig::Vector*)out = v; out += dfstride; @@ -207,57 +196,53 @@ void GetFirstDerivatives(const std::vector &f, unsigned int left, { //left then middle then right ThreePointdt(*(synfig::Vector*)out,f[left+0], f[left+1], f[left+2], -1); - current += 1; + current++; out += dfstride; - + for(;current < right-1; current++, out += dfstride) - { ThreePointdt(*(synfig::Vector*)out,f[current-1], f[current], f[current+1], 0); - } ThreePointdt(*(synfig::Vector*)out,f[right-3], f[right-2], f[right-1], 1); current++; out += dfstride; - + }else //can use 5 point { //left 2 then middle bunch then right two //may want to use 3 point for inner edge ones - + FivePointdt(*(synfig::Vector*)out,f[left+0], f[left+1], f[left+2], f[left+3], f[left+4], -2); out += dfstride; FivePointdt(*(synfig::Vector*)out,f[left+1], f[left+2], f[left+3], f[left+4], f[left+5], -1); out += dfstride; current += 2; - + for(;current < right-2; current++, out += dfstride) - { FivePointdt(*(synfig::Vector*)out,f[current-2], f[current-1], f[current], f[current+1], f[current+2], 0); - } - FivePointdt(*(synfig::Vector*)out,f[right-5], f[right-4], f[right-3], f[right-2], f[right-1], 1); + FivePointdt(*(synfig::Vector*)out,f[right-6], f[right-5], f[right-4], f[right-3], f[right-2], 2); out += dfstride; - FivePointdt(*(synfig::Vector*)out,f[right-6], f[right-5], f[right-4], f[right-3], f[right-2], 2); + FivePointdt(*(synfig::Vector*)out,f[right-5], f[right-4], f[right-3], f[right-2], f[right-1], 1); out += dfstride; current += 2; } } -void GetSimpleDerivatives(const std::vector &f, int left, int right, +void GetSimpleDerivatives(const std::vector &f, int left, int right, std::vector &df, int outleft, - const std::vector &di) + const std::vector &/*di*/) { int i1,i2,i; int offset = 2; //df = 1/2 (f[i+o]-f[i-o]) - + assert((int)df.size() >= right-left+outleft); //must be big enough - + for(i = left; i < right; ++i) { //right now indices (figure out distance later) i1 = std::max(left,i-offset); i2 = std::max(left,i+offset); - + df[outleft++] = (f[i2] - f[i1])*0.5f; } } @@ -266,115 +251,119 @@ void GetSimpleDerivatives(const std::vector &f, int left, int rig Real CurveError(const synfig::Point *pts, unsigned int n, std::vector &work, int left, int right) { if(right-left < 2) return -1; - + int i,j; - + //get distances to each point Real d,dtemp,dsum; //synfig::Vector v,vt; //synfig::Point p1,p2; synfig::Point pi; std::vector::const_iterator it;//,end = work.begin()+right; - + //unsigned int size = work.size(); - + //for each line, get distance d = 0; //starts at 0 for(i = 0; i < (int)n; ++i) - { + { pi = pts[i]; - + dsum = FLT_MAX; - + it = work.begin()+left; //p2 = *it++; //put it at left+1 for(j = left/*+1*/; j < right; ++j,++it) { /*p1 = p2; p2 = *it; - - v = p2 - p1; + + v = p2 - p1; vt = pi - p1; - + dtemp = v.mag_squared() > 1e-12 ? (vt*v)/v.mag_squared() : 0; //get the projected time value for the current line - - //get distance to line segment with the time value clamped 0-1 + + //get distance to line segment with the time value clamped 0-1 if(dtemp >= 1) //use p+v { - vt += v; //makes it pp - (p+v) + vt += v; //makes it pp - (p+v) }else if(dtemp > 0) //use vt-proj { vt -= v*dtemp; // vt - proj_v(vt) //must normalize the projection vector to work } - + //else use p dtemp = vt.mag_squared();*/ - - dtemp = (pi - *it).mag_squared(); + + dtemp = (pi - *it).mag_squared(); if(dtemp < dsum) dsum = dtemp; } - + //accumulate the points' min distance from the curve d += sqrt(dsum); } - + return d; } typedef synfigapp::BLineConverter::cpindex cpindex; //has the index data and the tangent scale data (relevant as it may be) -int tesselate_curves(const std::vector &inds, const std::vector &f, const std::vector &df, std::vector &work) +int tessellate_curves(const std::vector &inds, const std::vector &f, const std::vector &df, std::vector &work) { if(inds.size() < 2) return 0; - + etl::hermite curve; int ntess = 0; - + std::vector::const_iterator j = inds.begin(),j2, end = inds.end(); - + unsigned int ibase = inds[0].curind; - + j2 = j++; for(; j != end; j2 = j++) { - //if this curve has invalid error (in j) then retesselate it's work points (requires reparametrization, etc.) + //if this curve has invalid error (in j) then retessellate its work points (requires reparametrization, etc.) if(j->error < 0) { //get the stepsize etc. for the number of points in here unsigned int n = j->curind - j2->curind + 1; //thats the number of points in the span unsigned int k, kend, i0, i3; //so reset the right chunk - + Real t, dt = 1/(Real)(n*2-2); //assuming that they own only n points - + //start at first intermediate t = 0; - i0 = j2->curind; i3 = j->curind; + i0 = j2->curind; i3 = j->curind; k = (i0-ibase)*2; //start on first intermediary point (2x+1) kend = (i3-ibase)*2; //last point to set (not intermediary) - + //build hermite curve, it's easier curve.p1() = f[i0]; curve.p2() = f[i3]; - curve.t1() = df[i0]*(df[i0].mag_squared() > 1e-4 ? j2->tangentscale/df[i0].mag() : j2->tangentscale); - curve.t2() = df[i3]*(df[i3].mag_squared() > 1e-4 ? j->tangentscale/df[i3].mag() : j->tangentscale); + curve.t1() = df[i0-ibase] * (df[i0-ibase].mag_squared() > 1e-4 + ? j2->tangentscale/df[i0-ibase].mag() + : j2->tangentscale); + curve.t2() = df[i3-ibase] * (df[i3-ibase].mag_squared() > 1e-4 + ? j->tangentscale/df[i3-ibase].mag() + : j->tangentscale); curve.sync(); - + //MUST include the end point (since we are ignoring left one) for(; k < kend; ++k, t += dt) { work[k] = curve(t); } - + work[k] = curve(1); //k == kend, t == 1 -> c(t) == p2 ++ntess; } } - + return ntess; } @@ -385,7 +374,7 @@ synfigapp::BLineConverter::BLineConverter() width = 0; }; -void +void synfigapp::BLineConverter::clear() { f.clear(); @@ -401,8 +390,8 @@ synfigapp::BLineConverter::clear() } void -synfigapp::BLineConverter::operator () (std::list &out, const std::list &in,const std::list &in_w) -{ +synfigapp::BLineConverter::operator()(std::list &out, const std::list &in,const std::list &in_w) +{ //Profiling information /*etl::clock::value_type initialprocess=0, curveval=0, breakeval=0, disteval=0; etl::clock::value_type preproceval=0, tesseval=0, erroreval=0, spliteval=0; @@ -414,98 +403,91 @@ synfigapp::BLineConverter::operator () (std::list &out, cons return; clear(); - + //removing digitization error harder than expected - + //intended to fix little pen errors caused by the way people draw (tiny juts in opposite direction) //Different solutions // Average at both end points (will probably eliminate many points at each end of the samples) // Average after the break points are found (weird points would still affect the curve) // Just always get rid of breaks at the beginning and end if they are a certain distance apart // This is will be current approach so all we do now is try to remove duplicate points - + //remove duplicate points - very bad for fitting - + //timer.reset(); - + { std::list::const_iterator i = in.begin(), end = in.end(); std::list::const_iterator iw = in_w.begin(); synfig::Point c; - + if(in.size() == in_w.size()) { for(;i != end; ++i,++iw) - { - //eliminate duplicate points - if(*i != c) + if(*i != c) // eliminate duplicate points { f.push_back(c = *i); f_w.push_back(*iw); } - } - }else + } + else { for(;i != end; ++i) - { - //eliminate duplicate points - if(*i != c) - { + if(*i != c) // eliminate duplicate points f.push_back(c = *i); - } - } } } //initialprocess = timer(); - + if(f.size()<=6) return; - + //get curvature information //timer.reset(); - + { int i,i0,i1; synfig::Vector v1,v2; - + cvt.resize(f.size()); - + cvt.front() = 1; cvt.back() = 1; - + for(i = 1; i < (int)f.size()-1; ++i) { i0 = std::max(0,i - 2); i1 = std::min((int)(f.size()-1),i + 2); - + v1 = f[i] - f[i0]; v2 = f[i1] - f[i]; - + cvt[i] = (v1*v2)/(v1.mag()*v2.mag()); } } - + //curveval = timer(); //synfig::info("calculated curvature"); - + //find corner points and interpolate inside those //timer.reset(); - { + { //break at sharp derivative points //TODO tolerance should be set based upon digitization resolution (length dependent index selection) Real tol = 0; //break tolerance, for the cosine of the change in angle (really high curvature or something) Real fixdistsq = 4*width*width; //the distance to ignore breaks at the end points (for fixing stuff) unsigned int i = 0; - + int maxi = -1, last=0; Real minc = 1; - + brk.push_back(0); - + for(i = 1; i < cvt.size()-1; ++i) - { + { //insert if too sharp (we need to break the tangents to insert onto the break list) - + if(cvt[i] < tol) { if(cvt[i] < minc) @@ -513,11 +495,12 @@ synfigapp::BLineConverter::operator () (std::list &out, cons minc = cvt[i]; maxi = i; } - }else if(maxi >= 0) + } + else if(maxi >= 0) { if(maxi >= last + 8) { - //synfig::info("break: %d-%d",maxi+1,cvt.size()); + //synfig::info("break: %d-%d",maxi+1,cvt.size()); brk.push_back(maxi); last = maxi; } @@ -525,23 +508,23 @@ synfigapp::BLineConverter::operator () (std::list &out, cons minc = 1; } } - + brk.push_back(i); - - //postprocess for breaks too close to eachother + + //postprocess for breaks too close to each other Real d = 0; Point p = f[brk.front()]; - + //first set for(i = 1; i < brk.size()-1; ++i) //do not want to include end point... { d = (f[brk[i]] - p).mag_squared(); - if(d > fixdistsq) break; //don't want to group breaks if we ever get over the dist... + if(d > fixdistsq) break; //don't want to group breaks if we ever get over the dist... } //want to erase all points before... if(i != 1) - brk.erase(brk.begin(),brk.begin()+i-1); - + brk.erase(brk.begin(),brk.begin()+i-1); + //end set p = f[brk.back()]; for(i = brk.size()-2; i > 0; --i) //start at one in from the end @@ -555,118 +538,133 @@ synfigapp::BLineConverter::operator () (std::list &out, cons } //breakeval = timer(); //synfig::info("found break points: %d",brk.size()); - + //get the distance calculation of the entire curve (for tangent scaling) //timer.reset(); { synfig::Point p1,p2; - + p1=p2=f[0]; - + di.resize(f.size()); d_i.resize(f.size()); Real d = 0; for(unsigned int i = 0; i < f.size();) { d += (d_i[i] = (p2-p1).mag()); di[i] = d; - + p1=p2; p2=f[++i]; } } //disteval = timer(); //synfig::info("calculated distance"); - + //now break at every point - calculate new derivatives each time - + //TODO //must be sure that the break points are 3 or more apart //then must also store the breaks which are not smooth, etc. //and figure out tangents between there - + //for each pair of break points (as long as they are far enough apart) recursively subdivide stuff //ignore the detected intermediate points { unsigned int i0=0,i3=0,is=0; int i=0,j=0; - + bool done = false; - + Real errortol = smoothness*pixelwidth; //???? what the hell should this value be - + BLinePoint a; synfig::Vector v; - + //intemp = f; //don't want to smooth out the corners - + bool breaktan = false, setwidth; a.set_split_tangent_flag(false); //a.set_width(width); a.set_width(1.0f); - + setwidth = (f.size() == f_w.size()); - + for(j = 0; j < (int)brk.size() - 1; ++j) { //for b[j] to b[j+1] subdivide and stuff i0 = brk[j]; i3 = brk[j+1]; - + unsigned int size = i3-i0+1; //must include the end points - + //new derivatives //timer.reset(); ftemp.assign(f.begin()+i0, f.begin()+i3+1); for(i=0;i<20;++i) gaussian_blur_3(ftemp.begin(),ftemp.end(),false); - + df.resize(size); + + // Wondering whether the modification of the df vector + // using a char* pointer and pointer arithmetric was safe, + // I looked it up... + // + // http://www.open-std.org/jtc1/sc22/wg21/docs/papers/2007/n2369.pdf tells me: + // + // 23.2.5 Class template vector [vector] + // + // [...] The elements of a vector are stored contiguously, + // meaning that if v is a vector where T is + // some type other than bool, then it obeys the identity + // &v[n] == &v[0] + n for all 0 <= n < v.size(). + // GetFirstDerivatives(ftemp,0,size,(char*)&df[0],sizeof(df[0])); - //GetSimpleDerivatives(ftemp,0,size,df,0,di); - //< don't have to worry about indexing stuff as it is all being taken car of right now + + //GetSimpleDerivatives(ftemp,0,size,df,0,di); + //< don't have to worry about indexing stuff as it is all being taken care of right now //preproceval += timer(); //numpre++; - - work.resize(size*2-1); //guarantee that all points will be tesselated correctly (one point inbetween every 2 adjacent points) - + + work.resize(size*2-1); //guarantee that all points will be tessellated correctly (one point in between every 2 adjacent points) + //if size of work is size*2-1, the step size should be 1/(size*2 - 2) //Real step = 1/(Real)(size*2 - 1); - + //start off with break points as indices curind.clear(); curind.push_back(cpindex(i0,di[i3]-di[i0],0)); //0 error because no curve on the left curind.push_back(cpindex(i3,di[i3]-di[i0],-1)); //error needs to be reevaluated done = false; //we want to loop - + unsigned int dcount = 0; - - //while there are still enough points between us, and the error is too high subdivide (and invalidate neighbors that share tangents) + + //while there are still enough points between us, and the error is too high subdivide (and invalidate neighbors that share tangents) while(!done) - { - //tesselate all curves with invalid error values + { + //tessellate all curves with invalid error values work[0] = f[i0]; - + //timer.reset(); - /*numtess += */tesselate_curves(curind,f,df,work); + /*numtess += */tessellate_curves(curind,f,df,work); //tesseval += timer(); - + //now get all error values //timer.reset(); for(i = 1; i < (int)curind.size(); ++i) { - if(curind[i].error < 0) //must have been retesselated, so now recalculate error value + if(curind[i].error < 0) //must have been retessellated, so now recalculate error value { //evaluate error from points (starting at current index) int size = curind[i].curind - curind[i-1].curind + 1; curind[i].error = CurveError(&f[curind[i-1].curind], size, work,(curind[i-1].curind - i0)*2,(curind[i].curind - i0)*2+1); - + /*if(curind[i].error > 1.0e5) { synfig::info("Holy crap %d-%d error %f",curind[i-1].curind,curind[i].curind,curind[i].error); curind[i].error = -1; - numtess += tesselate_curves(curind,f,df,work); + numtess += tessellate_curves(curind,f,df,work); curind[i].error = CurveError(&f[curind[i-1].curind], size, work,0,work.size());//(curind[i-1].curind - i0)*2,(curind[i].curind - i0)*2+1); }*/ @@ -674,28 +672,28 @@ synfigapp::BLineConverter::operator () (std::list &out, cons } } //erroreval += timer(); - + //assume we're done done = true; - + //check each error to see if it's too big, if so, then subdivide etc. int indsize = (int)curind.size(); Real maxrelerror = 0; int maxi = -1;//, numpoints; - + //timer.reset(); //get the maximum error and split there for(i = 1; i < indsize; ++i) { //numpoints = curind[i].curind - curind[i-1].curind + 1; - + if(curind[i].error > maxrelerror && curind[i].curind - curind[i-1].curind > 2) //only accept if it's valid { maxrelerror = curind[i].error; maxi = i; } } - + //split if error is too great if(maxrelerror > errortol) { @@ -703,11 +701,11 @@ synfigapp::BLineConverter::operator () (std::list &out, cons unsigned int ibase = curind[maxi-1].curind, itop = curind[maxi].curind, ibreak = (ibase + itop)/2; Real scale, scale2; - + assert(ibreak < f.size()); - + //synfig::info("Split %d -%d- %d, error: %f", ibase,ibreak,itop,maxrelerror); - + if(ibase != itop) { //invalidate current error of the changed tangents and add an extra segment @@ -715,89 +713,89 @@ synfigapp::BLineConverter::operator () (std::list &out, cons curind[maxi].error = -1; curind[maxi-1].error = -1; if(maxi+1 < indsize) curind[maxi+1].error = -1; //if there is a curve segment beyond this it will be effected as well - + scale = di[itop] - di[ibreak]; scale2 = maxi+1 < indsize ? di[curind[maxi+1].curind] - di[itop] : scale; //to the right valid? curind[maxi].tangentscale = std::min(scale, scale2); - + scale = di[ibreak] - di[ibase]; scale2 = maxi >= 2 ? di[ibase] - di[curind[maxi-2].curind] : scale; // to the left valid -2 ? curind[maxi-1].tangentscale = std::min(scale, scale2); - + scale = std::min(di[ibreak] - di[ibase], di[itop] - di[ibreak]); - + curind.insert(curind.begin()+maxi,cpindex(ibreak, scale, -1)); //curind.push_back(cpindex(ibreak, scale, -1)); //std::sort(curind.begin(), curind.end()); - + done = false; //numsplit++; } } //spliteval += timer(); - + dcount++; } - - //insert the last point too (just set tangent for now + + //insert the last point too (just set tangent for now is = curind[0].curind; - - //first point inherits current tangent status + + //first point inherits current tangent status v = df[is - i0]; if(v.mag_squared() > EPSILON) v *= (curind[0].tangentscale/v.mag()); - + if(!breaktan) a.set_tangent(v); else a.set_tangent2(v); - + a.set_vertex(f[is]); if(setwidth)a.set_width(f_w[is]); - + out.push_back(a); a.set_split_tangent_flag(false); //won't need to break anymore breaktan = false; - + for(i = 1; i < (int)curind.size()-1; ++i) { is = curind[i].curind; - + //first point inherits current tangent status v = df[is-i0]; if(v.mag_squared() > EPSILON) v *= (curind[i].tangentscale/v.mag()); - + a.set_tangent(v); // always inside, so guaranteed to be smooth a.set_vertex(f[is]); if(setwidth)a.set_width(f_w[is]); - + out.push_back(a); } - + //set the last point's data is = curind.back().curind; //should already be this - + v = df[is-i0]; if(v.mag_squared() > EPSILON) v *= (curind.back().tangentscale/v.mag()); - + a.set_tangent1(v); a.set_split_tangent_flag(true); breaktan = true; - + //will get the vertex and tangent 2 from next round } - + a.set_vertex(f[i3]); a.set_split_tangent_flag(false); if(setwidth) a.set_width(f_w[i3]); out.push_back(a); - + /*etl::clock::value_type totaltime = total(), misctime = totaltime - initialprocess - curveval - breakeval - disteval - preproceval - tesseval - erroreval - spliteval; - + synfig::info( "Curve Convert Profile:\n" "\tInitial Preprocess: %f\n" @@ -806,7 +804,7 @@ synfigapp::BLineConverter::operator () (std::list &out, cons "\tDistance Calculation: %f\n" " Algorithm: (numtimes,totaltime)\n" "\tPreprocess step: (%d,%f)\n" - "\tTesselation step: (%d,%f)\n" + "\tTessellation step: (%d,%f)\n" "\tError step: (%d,%f)\n" "\tSplit step: (%d,%f)\n" " Num Input: %d, Num Output: %d\n" @@ -815,7 +813,7 @@ synfigapp::BLineConverter::operator () (std::list &out, cons numpre,preproceval,numtess,tesseval,numerror,erroreval,numsplit,spliteval, in.size(),out.size(), totaltime,misctime);*/ - + return; } } @@ -824,12 +822,8 @@ void synfigapp::BLineConverter::EnforceMinWidth(std::list &b { std::list::iterator i = bline.begin(), end = bline.end(); - + for(i = bline.begin(); i != end; ++i) - { if(i->get_width() < min_pressure) - { i->set_width(min_pressure); - } - } }