From f4092abdf94af6a99aff944d6264bc1284e8bdd4 Mon Sep 17 00:00:00 2001 From: Reinhard Tartler Date: Mon, 10 Oct 2011 17:43:39 +0200 Subject: Imported nx-X11-3.1.0-1.tar.gz Summary: Imported nx-X11-3.1.0-1.tar.gz Keywords: Imported nx-X11-3.1.0-1.tar.gz into Git repository --- .../main/gfx/lib/glu/libnurbs/internals/slicer.cc | 1271 ++++++++++++++++++++ 1 file changed, 1271 insertions(+) create mode 100644 nx-X11/extras/ogl-sample/main/gfx/lib/glu/libnurbs/internals/slicer.cc (limited to 'nx-X11/extras/ogl-sample/main/gfx/lib/glu/libnurbs/internals/slicer.cc') diff --git a/nx-X11/extras/ogl-sample/main/gfx/lib/glu/libnurbs/internals/slicer.cc b/nx-X11/extras/ogl-sample/main/gfx/lib/glu/libnurbs/internals/slicer.cc new file mode 100644 index 000000000..d31da74c0 --- /dev/null +++ b/nx-X11/extras/ogl-sample/main/gfx/lib/glu/libnurbs/internals/slicer.cc @@ -0,0 +1,1271 @@ +/* +** License Applicability. Except to the extent portions of this file are +** made subject to an alternative license as permitted in the SGI Free +** Software License B, Version 1.1 (the "License"), the contents of this +** file are subject only to the provisions of the License. You may not use +** this file except in compliance with the License. You may obtain a copy +** of the License at Silicon Graphics, Inc., attn: Legal Services, 1600 +** Amphitheatre Parkway, Mountain View, CA 94043-1351, or at: +** +** http://oss.sgi.com/projects/FreeB +** +** Note that, as provided in the License, the Software is distributed on an +** "AS IS" basis, with ALL EXPRESS AND IMPLIED WARRANTIES AND CONDITIONS +** DISCLAIMED, INCLUDING, WITHOUT LIMITATION, ANY IMPLIED WARRANTIES AND +** CONDITIONS OF MERCHANTABILITY, SATISFACTORY QUALITY, FITNESS FOR A +** PARTICULAR PURPOSE, AND NON-INFRINGEMENT. +** +** Original Code. The Original Code is: OpenGL Sample Implementation, +** Version 1.2.1, released January 26, 2000, developed by Silicon Graphics, +** Inc. The Original Code is Copyright (c) 1991-2000 Silicon Graphics, Inc. +** Copyright in any portions created by third parties is as indicated +** elsewhere herein. All Rights Reserved. +** +** Additional Notice Provisions: The application programming interfaces +** established by SGI in conjunction with the Original Code are The +** OpenGL(R) Graphics System: A Specification (Version 1.2.1), released +** April 1, 1999; The OpenGL(R) Graphics System Utility Library (Version +** 1.3), released November 4, 1998; and OpenGL(R) Graphics with the X +** Window System(R) (Version 1.3), released October 19, 1998. This software +** was created using the OpenGL(R) version 1.2.1 Sample Implementation +** published by SGI, but has not been independently verified as being +** compliant with the OpenGL(R) version 1.2.1 Specification. +*/ +/* $XFree86: xc/extras/ogl-sample/main/gfx/lib/glu/libnurbs/internals/slicer.cc,v 1.2tsi Exp $ */ + +/* + * slicer.c++ + * + * $Date: 2004/04/23 18:42:55 $ $Revision: 1.2 $ + * $Header: /cvs/xorg/xc/extras/ogl-sample/main/gfx/lib/glu/libnurbs/internals/slicer.cc,v 1.2 2004/04/23 18:42:55 eich Exp $ + */ + +#include +#include +#include +#include "glimports.h" +#include "mystdio.h" +#include "myassert.h" +#include "bufpool.h" +#include "slicer.h" +#include "backend.h" +#include "arc.h" +#include "gridtrimvertex.h" +#include "trimvertex.h" +#include "varray.h" + +#include "polyUtil.h" //for area() + +//static int count=0; + +/*USE_OPTTT is initiated in trimvertex.h*/ + +#ifdef USE_OPTTT +# include +#endif + +//#define USE_READ_FLAG //whether to use new or old tesselator + //if defined, it reads "flagFile", + // if the number is 1, then use new tess + // otherwise, use the old tess. + //if not defined, then use new tess. +#ifdef USE_READ_FLAG +static Int read_flag(char* name); +Int newtess_flag = read_flag("flagFile"); +#endif + +//#define COUNT_TRIANGLES +#ifdef COUNT_TRIANGLES +Int num_triangles = 0; +Int num_quads = 0; +#endif + +#define max(a,b) ((a>b)? a:b) +#define ZERO 0.00001 /*determing whether a loop is a rectngle or not*/ +#define equalRect(a,b) ((fabs(a-b) <= ZERO)? 1:0) //only used in tessellating a rectangle + +#ifdef UNUSED +static Int is_Convex(Arc_ptr loop) +{ + if(area(loop->tail(), loop->head(), loop->next->head()) <0 ) + return 0; + for(Arc_ptr jarc = loop->next; jarc != loop; jarc = jarc->next) + { + if(area(jarc->tail(), jarc->head(), jarc->next->head()) < 0) + return 0; + } + return 1; +} +#endif + +/******triangulate a monotone polygon**************/ +#include "monoTriangulation.h" +#ifdef UNUSED +static int is_U_monotone(Arc_ptr loop) +{ + int n_changes=0; + int prev_sign; + int cur_sign; + Arc_ptr temp; + + cur_sign = compV2InX(loop->head(), loop->tail()); + + n_changes = (compV2InX(loop->prev->head(), loop->prev->tail()) + != cur_sign); + + for(temp=loop->next; temp != loop; temp = temp->next) + { + prev_sign = cur_sign; + cur_sign = compV2InX(temp->head(), temp->tail()); + if(cur_sign != prev_sign) + { +#ifdef DEBUG + printf("***change signe\n"); +#endif + n_changes++; + } + } + if(n_changes == 2) return 1; + else + return 0; +} +#endif + +inline int compInY(REAL a[2], REAL b[2]) +{ + if(a[1] < b[1]) + return -1; + else if (a[1] > b[1]) + return 1; + else if(a[0] > b[0]) + return 1; + else return -1; +} + +void monoTriangulationLoop(Arc_ptr loop, Backend& backend, primStream* pStream) +{ + int i; + //find the top, bottom, increasing and decreasing chain + //then call monoTrianulation + Arc_ptr jarc, temp; + Arc_ptr top; + Arc_ptr bot; + top = bot = loop; + if(compInY(loop->tail(), loop->prev->tail()) < 0) + { + //first find bot + for(temp = loop->next; temp != loop; temp = temp->next) + { + if(compInY(temp->tail(), temp->prev->tail()) > 0) + break; + } + bot = temp->prev; + //then find top + for(temp=loop->prev; temp != loop; temp = temp->prev) + { + if(compInY(temp->tail(), temp->prev->tail()) > 0) + break; + } + top = temp; + } + else //loop > loop->prev + { + for(temp=loop->next; temp != loop; temp = temp->next) + { + if(compInY(temp->tail(), temp->prev->tail()) < 0) + break; + } + top = temp->prev; + for(temp=loop->prev; temp != loop; temp = temp->prev) + { + if(compInY(temp->tail(), temp->prev->tail()) < 0) + break; + } + bot = temp; + } + //creat increase and decrease chains + vertexArray inc_chain(50); //this is a dynamci array + for(i=1; i<=top->pwlArc->npts-2; i++) + { + //the first vertex is the top which doesn't below to inc_chain + inc_chain.appendVertex(top->pwlArc->pts[i].param); + } + for(jarc=top->next; jarc != bot; jarc = jarc->next) + { + for(i=0; i<=jarc->pwlArc->npts-2; i++) + { + inc_chain.appendVertex(jarc->pwlArc->pts[i].param); + } + } + vertexArray dec_chain(50); + for(jarc = top->prev; jarc != bot; jarc = jarc->prev) + { + for(i=jarc->pwlArc->npts-2; i>=0; i--) + { + dec_chain.appendVertex(jarc->pwlArc->pts[i].param); + } + } + for(i=bot->pwlArc->npts-2; i>=1; i--) + { + dec_chain.appendVertex(jarc->pwlArc->pts[i].param); + } + + monoTriangulationRec(top->tail(), bot->tail(), &inc_chain, 0, + &dec_chain, 0, &backend); + +} + +/********tesselate a rectanlge (OPTIMIZATION**************/ +static void triangulateRectGen(Arc_ptr loop, int n_ulines, int n_vlines, Backend& backend); + +static Int is_rect(Arc_ptr loop) +{ + Int nlines =1; + for(Arc_ptr jarc = loop->next; jarc != loop; jarc = jarc->next) + { + nlines++; + if(nlines == 5) + break; + } + if(nlines != 4) + return 0; + + +/* +printf("here1\n"); +printf("loop->tail=(%f,%f)\n", loop->tail()[0], loop->tail()[1]); +printf("loop->head=(%f,%f)\n", loop->head()[0], loop->head()[1]); +printf("loop->next->tail=(%f,%f)\n", loop->next->tail()[0], loop->next->tail()[1]); +printf("loop->next->head=(%f,%f)\n", loop->next->head()[0], loop->next->head()[1]); +if(fabs(loop->tail()[0] - loop->head()[0])<0.000001) + printf("equal 1\n"); +if(loop->next->tail()[1] == loop->next->head()[1]) + printf("equal 2\n"); +*/ + + if( (fabs(loop->tail()[0] - loop->head()[0])<=ZERO) && + (fabs(loop->next->tail()[1] - loop->next->head()[1])<=ZERO) && + (fabs(loop->prev->tail()[1] - loop->prev->head()[1])<=ZERO) && + (fabs(loop->prev->prev->tail()[0] - loop->prev->prev->head()[0])<=ZERO) + ) + return 1; + else if + ( (fabs(loop->tail()[1] - loop->head()[1]) <= ZERO) && + (fabs(loop->next->tail()[0] - loop->next->head()[0]) <= ZERO) && + (fabs(loop->prev->tail()[0] - loop->prev->head()[0]) <= ZERO) && + (fabs(loop->prev->prev->tail()[1] - loop->prev->prev->head()[1]) <= ZERO) + ) + return 1; + else + return 0; +} + +#ifdef USE_OPTTT +//a line with the same u for opt +static void evalLineNOGE_BU(TrimVertex *verts, int n, Backend& backend) +{ + int i; + backend.preEvaluateBU(verts[0].param[0]); + for(i=0; itail()[1] == loop->head()[1]) + { + if(loop->tail()[1] > loop->prev->prev->tail()[1]) + { + + top = loop; + } + else{ + + top = loop->prev->prev; + } + } + else + { + if(loop->tail()[0] > loop->prev->prev->tail()[0]) + { + //loop is the right arc + + top = loop->next; + } + else + { + + top = loop->prev; + } + } + left = top->next; + bot = left->next; + right= bot->next; + + //if u, v are both nonlinear, then if the + //boundary is tessellated dense, we also + //sample the inside to get a better tesslletant. + if( (!ulinear) && (!vlinear)) + { + int nu = top->pwlArc->npts; + if(nu < bot->pwlArc->npts) + nu = bot->pwlArc->npts; + int nv = left->pwlArc->npts; + if(nv < right->pwlArc->npts) + nv = right->pwlArc->npts; +/* + if(nu > 2 && nv > 2) + { + triangulateRectGen(top, nu-2, nv-2, backend); + return; + } +*/ + } + + if(TB_or_LR == 1) + triangulateRectAux(top->pwlArc, bot->pwlArc, left->pwlArc, right->pwlArc, backend); + else if(TB_or_LR == -1) + triangulateRectAux(left->pwlArc, right->pwlArc, bot->pwlArc, top->pwlArc, backend); + else + { + Int maxPointsTB = top->pwlArc->npts + bot->pwlArc->npts; + Int maxPointsLR = left->pwlArc->npts + right->pwlArc->npts; + + if(maxPointsTB < maxPointsLR) + triangulateRectAux(left->pwlArc, right->pwlArc, bot->pwlArc, top->pwlArc, backend); + else + triangulateRectAux(top->pwlArc, bot->pwlArc, left->pwlArc, right->pwlArc, backend); + } +} + +static void triangulateRectAux(PwlArc* top, PwlArc* bot, PwlArc* left, PwlArc* right, Backend& backend) +{ //if(maxPointsTB >= maxPointsLR) + { + + Int d, topd_left, topd_right, botd_left, botd_right, i,j; + d = left->npts /2; + +#ifdef USE_OPTTT + evalLineNOGE(top->pts, top->npts, backend); + evalLineNOGE(bot->pts, bot->npts, backend); + evalLineNOGE(left->pts, left->npts, backend); + evalLineNOGE(right->pts, right->npts, backend); +#endif + + if(top->npts == 2) { + backend.bgntfan(); + OPT_OUTVERT(top->pts[0], backend);//the root + for(i=0; inpts; i++){ + OPT_OUTVERT(left->pts[i], backend); + } + for(i=1; i<= bot->npts-2; i++){ + OPT_OUTVERT(bot->pts[i], backend); + } + backend.endtfan(); + + backend.bgntfan(); + OPT_OUTVERT(bot->pts[bot->npts-2], backend); + for(i=0; inpts; i++){ + OPT_OUTVERT(right->pts[i], backend); + } + backend.endtfan(); + } + else if(bot->npts == 2) { + backend.bgntfan(); + OPT_OUTVERT(bot->pts[0], backend);//the root + for(i=0; inpts; i++){ + OPT_OUTVERT(right->pts[i], backend); + } + for(i=1; i<= top->npts-2; i++){ + OPT_OUTVERT(top->pts[i], backend); + } + backend.endtfan(); + + backend.bgntfan(); + OPT_OUTVERT(top->pts[top->npts-2], backend); + for(i=0; inpts; i++){ + OPT_OUTVERT(left->pts[i], backend); + } + backend.endtfan(); + } + else { //both top and bot have >=3 points + + backend.bgntfan(); + + OPT_OUTVERT(top->pts[top->npts-2], backend); + + for(i=0; i<=d; i++) + { + OPT_OUTVERT(left->pts[i], backend); + } + backend.endtfan(); + + backend.bgntfan(); + + OPT_OUTVERT(bot->pts[1], backend); + + OPT_OUTVERT(top->pts[top->npts-2], backend); + + for(i=d; i< left->npts; i++) + { + OPT_OUTVERT(left->pts[i], backend); + } + backend.endtfan(); + + d = right->npts/2; + //output only when dnpts-1 and + // + if(dnpts-1) + { + backend.bgntfan(); + // backend.tmeshvert(& top->pts[1]); + OPT_OUTVERT(top->pts[1], backend); + for(i=d; i< right->npts; i++) + { + // backend.tmeshvert(& right->pts[i]); + OPT_OUTVERT(right->pts[i], backend); + } + backend.endtfan(); + } + + backend.bgntfan(); + // backend.tmeshvert(& bot->pts[bot->npts-2]); + OPT_OUTVERT( bot->pts[bot->npts-2], backend); + for(i=0; i<=d; i++) + { + // backend.tmeshvert(& right->pts[i]); + OPT_OUTVERT(right->pts[i], backend); + } + + // backend.tmeshvert(& top->pts[1]); + OPT_OUTVERT(top->pts[1], backend); + + backend.endtfan(); + + + topd_left = top->npts-2; + topd_right = 1; //topd_left>= topd_right + + botd_left = 1; + botd_right = bot->npts-2; //botd_left<= bot_dright + + if(top->npts < bot->npts) + { + int delta=bot->npts - top->npts; + int u = delta/2; + botd_left = 1+ u; + botd_right = bot->npts-2-( delta-u); + + if(botd_left >1) + { + backend.bgntfan(); + // backend.tmeshvert(& top->pts[top->npts-2]); + OPT_OUTVERT(top->pts[top->npts-2], backend); + for(i=1; i<= botd_left; i++) + { + // backend.tmeshvert(& bot->pts[i]); + OPT_OUTVERT(bot->pts[i] , backend); + } + backend.endtfan(); + } + if(botd_right < bot->npts-2) + { + backend.bgntfan(); + OPT_OUTVERT(top->pts[1], backend); + for(i=botd_right; i<= bot->npts-2; i++) + OPT_OUTVERT(bot->pts[i], backend); + backend.endtfan(); + } + } + else if(top->npts> bot->npts) + { + int delta=top->npts-bot->npts; + int u = delta/2; + topd_left = top->npts-2 - u; + topd_right = 1+delta-u; + + if(topd_left < top->npts-2) + { + backend.bgntfan(); + // backend.tmeshvert(& bot->pts[1]); + OPT_OUTVERT(bot->pts[1], backend); + for(i=topd_left; i<= top->npts-2; i++) + { + // backend.tmeshvert(& top->pts[i]); + OPT_OUTVERT(top->pts[i], backend); + } + backend.endtfan(); + } + if(topd_right > 1) + { + backend.bgntfan(); + OPT_OUTVERT(bot->pts[bot->npts-2], backend); + for(i=1; i<= topd_right; i++) + OPT_OUTVERT(top->pts[i], backend); + backend.endtfan(); + } + } + + if(topd_left <= topd_right) + return; + + backend.bgnqstrip(); + for(j=botd_left, i=topd_left; i>=topd_right; i--,j++) + { + // backend.tmeshvert(& top->pts[i]); + // backend.tmeshvert(& bot->pts[j]); + OPT_OUTVERT(top->pts[i], backend); + OPT_OUTVERT(bot->pts[j], backend); + } + backend.endqstrip(); + } + } +} + +static void triangulateRectCenter(int n_ulines, REAL* u_val, + int n_vlines, REAL* v_val, + Backend& backend) +{ + /* + TrimVertex trimVert; + trimVert.nuid = 0; + */ + + backend.surfgrid(u_val[0], u_val[n_ulines-1], n_ulines-1, + v_val[n_vlines-1], v_val[0], n_vlines-1); + + if(n_ulines>1 && n_vlines>1) + backend.surfmesh(0,0,n_ulines-1,n_vlines-1); + + return; + + /* + for(i=0; ipwlArc->npts); + assert(upper_val); + if(dir) + { + for(k=0,i=arc->pwlArc->npts-1; i>=0; i--,k++) + { + upper_val[k] = arc->pwlArc->pts[i].param[0]; + } + backend.evalUStrip(arc->pwlArc->npts, arc->pwlArc->pts[0].param[1], + upper_val, + n_ulines, v, u_val); + } + else + { + for(k=0,i=0; ipwlArc->npts; i++,k++) + { + upper_val[k] = arc->pwlArc->pts[i].param[0]; + + } + + backend.evalUStrip( + n_ulines, v, u_val, + arc->pwlArc->npts, arc->pwlArc->pts[0].param[1], upper_val + ); + } + + free(upper_val); + return; + } + else //is_v + { + int i,k; + REAL* left_val = (REAL*) malloc(sizeof(REAL) * arc->pwlArc->npts); + assert(left_val); + if(dir) + { + for(k=0,i=arc->pwlArc->npts-1; i>=0; i--,k++) + { + left_val[k] = arc->pwlArc->pts[i].param[1]; + } + backend.evalVStrip(arc->pwlArc->npts, arc->pwlArc->pts[0].param[0], + left_val, + n_ulines, v, u_val); + } + else + { + for(k=0,i=0; ipwlArc->npts; i++,k++) + { + left_val[k] = arc->pwlArc->pts[i].param[1]; + } + backend.evalVStrip( + n_ulines, v, u_val, + arc->pwlArc->npts, arc->pwlArc->pts[0].param[0], left_val + ); + } + free(left_val); + return; + } + + //the following is a different version of the above code. If you comment + //the above code, the following code will still work. The reason to leave + //the folliwng code here is purely for testing purpose. + /* + int i,j; + PwlArc* parc = arc->pwlArc; + int d1 = parc->npts-1; + int d2 = 0; + TrimVertex trimVert; + trimVert.nuid = 0;//???? + REAL* temp_u_val = u_val; + if(dir ==0) //have to reverse u_val + { + temp_u_val = (REAL*) malloc(sizeof(REAL) * n_ulines); + assert(temp_u_val); + for(i=0; inpts > n_ulines) + { + d1 = n_ulines-1; + + backend.bgntfan(); + if(is_u){ + trimVert.param[0] = u_val[0]; + trimVert.param[1] = v; + } + else + { + trimVert.param[1] = u_val[0]; + trimVert.param[0] = v; + } + + backend.tmeshvert(& trimVert); + for(i=d1; i< parc->npts; i++) + backend.tmeshvert(& parc->pts[i]); + backend.endtfan(); + + + } + else if(parc->npts < n_ulines) + { + d2 = n_ulines-parc->npts; + + + backend.bgntfan(); + backend.tmeshvert(& parc->pts[parc->npts-1]); + for(i=0; i<= d2; i++) + { + if(is_u){ + trimVert.param[0] = u_val[i]; + trimVert.param[1] = v; + } + else + { + trimVert.param[1] = u_val[i]; + trimVert.param[0] = v; + } + backend.tmeshvert(&trimVert); + } + backend.endtfan(); + + } + if(d1>0){ + + + backend.bgnqstrip(); + for(i=d1, j=d2; i>=0; i--, j++) + { + backend.tmeshvert(& parc->pts[i]); + + if(is_u){ + trimVert.param[0] = u_val[j]; + trimVert.param[1] = v; + } + else{ + trimVert.param[1] = u_val[j]; + trimVert.param[0] = v; + } + backend.tmeshvert(&trimVert); + } + backend.endqstrip(); + } + if(dir == 0) //temp_u_val was mallocated + free(temp_u_val); + */ +} + +//n_ulines is the number of ulines inside, and n_vlines is the number of vlines +//inside, different from meanings elsewhere!!! +static void triangulateRectGen(Arc_ptr loop, int n_ulines, int n_vlines, Backend& backend) +{ + + int i; + //we know the loop is a rectangle, but not sure which is top + Arc_ptr top, bot, left, right; + + if(equalRect(loop->tail()[1] , loop->head()[1])) + { + + if(loop->tail()[1] > loop->prev->prev->tail()[1]) + { + + top = loop; + } + else{ + + top = loop->prev->prev; + } + } + else + { + if(loop->tail()[0] > loop->prev->prev->tail()[0]) + { + //loop is the right arc + + top = loop->next; + } + else + { + + top = loop->prev; + } + } + + left = top->next; + bot = left->next; + right= bot->next; + +#ifdef COUNT_TRIANGLES + num_triangles += loop->pwlArc->npts + + left->pwlArc->npts + + bot->pwlArc->npts + + right->pwlArc->npts + + 2*n_ulines + 2*n_vlines + -8; + num_quads += (n_ulines-1)*(n_vlines-1); +#endif +/* + backend.surfgrid(left->tail()[0], right->tail()[0], n_ulines+1, + top->tail()[1], bot->tail()[1], n_vlines+1); +// if(n_ulines>1 && n_vlines>1) + backend.surfmesh(0,0,n_ulines+1,n_vlines+1); +return; +*/ + REAL* u_val=(REAL*) malloc(sizeof(REAL)*n_ulines); + assert(u_val); + REAL* v_val=(REAL*)malloc(sizeof(REAL) * n_vlines); + assert(v_val); + REAL u_stepsize = (right->tail()[0] - left->tail()[0])/( (REAL) n_ulines+1); + REAL v_stepsize = (top->tail()[1] - bot->tail()[1])/( (REAL) n_vlines+1); + Real temp=left->tail()[0]+u_stepsize; + for(i=0; itail()[1] + v_stepsize; + for(i=0; ipwlArc->npts); + for(i=0; ipwlArc->npts; i++) + { + vert[0] = arc->pwlArc->pts[i].param[0]; + vert[1] = arc->pwlArc->pts[i].param[1]; + sline->setPoint(i, vert); + } + ret = new directedLine(INCREASING, sline); + return ret; +} + +/*an pwlArc may not be a straight line*/ +directedLine* arcToMultDLines(directedLine* original, Arc_ptr arc) +{ + directedLine* ret = original; + int is_linear = 0; + if(arc->pwlArc->npts == 2 ) + is_linear = 1; + else if(area(arc->pwlArc->pts[0].param, arc->pwlArc->pts[1].param, arc->pwlArc->pts[arc->pwlArc->npts-1].param) == 0.0) + is_linear = 1; + + if(is_linear) + { + directedLine *dline = arcToDLine(arc); + if(ret == NULL) + ret = dline; + else + ret->insert(dline); + return ret; + } + else /*not linear*/ + { + for(Int i=0; ipwlArc->npts-1; i++) + { + Real vert[2][2]; + vert[0][0] = arc->pwlArc->pts[i].param[0]; + vert[0][1] = arc->pwlArc->pts[i].param[1]; + vert[1][0] = arc->pwlArc->pts[i+1].param[0]; + vert[1][1] = arc->pwlArc->pts[i+1].param[1]; + + sampledLine *sline = new sampledLine(2, vert); + directedLine *dline = new directedLine(INCREASING, sline); + if(ret == NULL) + ret = dline; + else + ret->insert(dline); + } + return ret; + } +} + +directedLine* arcLoopToDLineLoop(Arc_ptr loop) +{ + directedLine* ret; + + if(loop == NULL) + return NULL; + ret = arcToMultDLines(NULL, loop); +//ret->printSingle(); + for(Arc_ptr temp = loop->next; temp != loop; temp = temp->next){ + ret = arcToMultDLines(ret, temp); +//ret->printSingle(); + } + + return ret; +} + +/* +void Slicer::evalRBArray(rectBlockArray* rbArray, gridWrap* grid) +{ + TrimVertex *trimVert = (TrimVertex*)malloc(sizeof(TrimVertex)); + trimVert -> nuid = 0;//???? + + Real* u_values = grid->get_u_values(); + Real* v_values = grid->get_v_values(); + + Int i,j,k,l; + + for(l=0; lget_n_elements(); l++) + { + rectBlock* block = rbArray->get_element(l); + for(k=0, i=block->get_upGridLineIndex(); i>block->get_lowGridLineIndex(); i--, k++) + { + + backend.bgnqstrip(); + for(j=block->get_leftIndices()[k+1]; j<= block->get_rightIndices()[k+1]; j++) + { + trimVert->param[0] = u_values[j]; + trimVert->param[1] = v_values[i]; + backend.tmeshvert(trimVert); + + trimVert->param[1] = v_values[i-1]; + backend.tmeshvert(trimVert); + + } + backend.endqstrip(); + + } + } + + free(trimVert); +} +*/ + +void Slicer::evalRBArray(rectBlockArray* rbArray, gridWrap* grid) +{ + Int i,j,k; + + Int n_vlines=grid->get_n_vlines(); + //the reason to switch the position of v_max and v_min is because of the + //the orientation problem. glEvalMesh generates quad_strip clockwise, but + //we need counter-clockwise. + backend.surfgrid(grid->get_u_min(), grid->get_u_max(), grid->get_n_ulines()-1, + grid->get_v_max(), grid->get_v_min(), n_vlines-1); + + + for(j=0; jget_n_elements(); j++) + { + rectBlock* block = rbArray->get_element(j); + Int low = block->get_lowGridLineIndex(); + Int high = block->get_upGridLineIndex(); + + for(k=0, i=high; i>low; i--, k++) + { + backend.surfmesh(block->get_leftIndices()[k+1], n_vlines-1-i, block->get_rightIndices()[k+1]-block->get_leftIndices()[k+1], 1); + } + } +} + + +void Slicer::evalStream(primStream* pStream) +{ + Int i,j,k; + k=0; +/* TrimVertex X;*/ + TrimVertex *trimVert =/*&X*/ (TrimVertex*)malloc(sizeof(TrimVertex)); + trimVert -> nuid = 0;//??? + Real* vertices = pStream->get_vertices(); //for efficiency + for(i=0; iget_n_prims(); i++) + { + + //ith primitive has #vertices = lengths[i], type=types[i] + switch(pStream->get_type(i)){ + case PRIMITIVE_STREAM_FAN: + + backend.bgntfan(); + + for(j=0; jget_length(i); j++) + { + trimVert->param[0] = vertices[k]; + trimVert->param[1] = vertices[k+1]; + backend.tmeshvert(trimVert); + +// backend.tmeshvert(vertices[k], vertices[k+1]); + k += 2; + } + backend.endtfan(); + break; + + default: + fprintf(stderr, "evalStream: not implemented yet\n"); + exit(1); + + } + } + free(trimVert); +} + +void Slicer::slice_new(Arc_ptr loop) +{ +//count++; +//if(count == 78) count=1; +//printf("count=%i\n", count); +//if( ! (4<= count && count <=4)) return; + + + Int num_ulines; + Int num_vlines; + Real uMin, uMax, vMin, vMax; + Real mydu, mydv; + uMin = uMax = loop->tail()[0]; + vMin = vMax = loop->tail()[1]; + mydu = (du>0)? du: -du; + mydv = (dv>0)? dv: -dv; + + for(Arc_ptr jarc=loop->next; jarc != loop; jarc = jarc->next) + { + + if(jarc->tail()[0] < uMin) + uMin = jarc->tail()[0]; + if(jarc->tail()[0] > uMax) + uMax = jarc->tail()[0]; + if(jarc->tail()[1] < vMin) + vMin = jarc->tail()[1]; + if(jarc->tail()[1] > vMax) + vMax = jarc->tail()[1]; + } + + if(mydu > uMax - uMin) + num_ulines = 2; + else + { + num_ulines = 3 + (Int) ((uMax-uMin)/mydu); + } + if(mydv>=vMax-vMin) + num_vlines = 2; + else + { + num_vlines = 2+(Int)((vMax-vMin)/mydv); + } + + Int isRect = is_rect(loop); + + if(isRect && (num_ulines<=2 || num_vlines<=2)) + { + if(vlinear) + triangulateRect(loop, backend, 1, ulinear, vlinear); + else if(ulinear) + triangulateRect(loop, backend, -1, ulinear, vlinear); + else + triangulateRect(loop, backend, 0, ulinear, vlinear); + } + + else if(isRect) + { + triangulateRectGen(loop, num_ulines-2, num_vlines-2, backend); + } + else if( (num_ulines<=2 || num_vlines <=2) && ulinear) + { + monoTriangulationFunBackend(loop, compV2InY, &backend); + } + else if( (!ulinear) && (!vlinear) && (num_ulines == 2) && (num_vlines > 2)) + { + monoTriangulationFunBackend(loop, compV2InY, &backend); + } + else + { + directedLine* poly = arcLoopToDLineLoop(loop); + + gridWrap grid(num_ulines, num_vlines, uMin, uMax, vMin, vMax); + primStream pStream(20, 20); + rectBlockArray rbArray(20); + + sampleMonoPoly(poly, &grid, ulinear, vlinear, &pStream, &rbArray); + + evalStream(&pStream); + + evalRBArray(&rbArray, &grid); + +#ifdef COUNT_TRIANGLES + num_triangles += pStream.num_triangles(); + num_quads += rbArray.num_quads(); +#endif + poly->deleteSinglePolygonWithSline(); + } + +#ifdef COUNT_TRIANGLES + printf("num_triangles=%i\n", num_triangles); + printf("num_quads = %i\n", num_quads); +#endif +} + +void Slicer::slice(Arc_ptr loop) +{ +#ifdef USE_READ_FLAG + if(read_flag("flagFile")) + slice_new(loop); + else + slice_old(loop); + +#else + slice_new(loop); +#endif + +} + +Slicer::Slicer( Backend &b ) + : CoveAndTiler( b ), Mesher( b ), backend( b ) +{ + ulinear = 0; + vlinear = 0; +} + +Slicer::~Slicer() +{ +} + +void +Slicer::setisolines( int x ) +{ + isolines = x; +} + +void +Slicer::setstriptessellation( REAL x, REAL y ) +{ + assert(x > 0 && y > 0); + du = x; + dv = y; + setDu( du ); +} + +void +Slicer::slice_old( Arc_ptr loop ) +{ + loop->markverts(); + + Arc_ptr extrema[4]; + loop->getextrema( extrema ); + + unsigned int npts = loop->numpts(); + TrimRegion::init( npts, extrema[0] ); + + Mesher::init( npts ); + + long ulines = uarray.init( du, extrema[1], extrema[3] ); +//printf("ulines = %i\n", ulines); + Varray varray; + long vlines = varray.init( dv, extrema[0], extrema[2] ); +//printf("vlines = %i\n", vlines); + long botv = 0; + long topv; + TrimRegion::init( varray.varray[botv] ); + getGridExtent( &extrema[0]->pwlArc->pts[0], &extrema[0]->pwlArc->pts[0] ); + + for( long quad=0; quadmarkverts(); + + if( jarc->pwlArc->npts >= 2 ) { + backend.bgnoutline(); + for( int j = jarc->pwlArc->npts-1; j >= 0; j-- ) + backend.linevert( &(jarc->pwlArc->pts[j]) ); + backend.endoutline(); + } +} + + -- cgit v1.2.3