570 lines
20 KiB
C++
570 lines
20 KiB
C++
//-----------------------------------------------------------------------------
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// Routines to generate our watertight brep shells from the operations
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// and entities specified by the user in each group; templated to work either
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// on an SShell of ratpoly surfaces or on an SMesh of triangles.
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//
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// Copyright 2008-2013 Jonathan Westhues.
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//-----------------------------------------------------------------------------
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#include "solvespace.h"
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#define gs (SS.GW.gs)
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void Group::AssembleLoops(bool *allClosed,
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bool *allCoplanar,
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bool *allNonZeroLen)
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{
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SBezierList sbl;
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ZERO(&sbl);
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int i;
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for(i = 0; i < SK.entity.n; i++) {
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Entity *e = &(SK.entity.elem[i]);
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if(e->group.v != h.v) continue;
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if(e->construction) continue;
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if(e->forceHidden) continue;
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e->GenerateBezierCurves(&sbl);
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}
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SBezier *sb;
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*allNonZeroLen = true;
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for(sb = sbl.l.First(); sb; sb = sbl.l.NextAfter(sb)) {
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for(i = 1; i <= sb->deg; i++) {
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if(!(sb->ctrl[i]).Equals(sb->ctrl[0])) {
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break;
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}
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}
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if(i > sb->deg) {
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// This is a zero-length edge.
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*allNonZeroLen = false;
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polyError.errorPointAt = sb->ctrl[0];
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return;
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}
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}
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// Try to assemble all these Beziers into loops. The closed loops go into
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// bezierLoops, with the outer loops grouped with their holes. The
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// leftovers, if any, go in bezierOpens.
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bezierLoops.FindOuterFacesFrom(&sbl, &polyLoops, NULL,
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SS.ChordTolMm(),
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allClosed, &(polyError.notClosedAt),
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allCoplanar, &(polyError.errorPointAt),
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&bezierOpens);
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sbl.Clear();
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}
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void Group::GenerateLoops(void) {
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polyLoops.Clear();
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bezierLoops.Clear();
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bezierOpens.Clear();
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if(type == DRAWING_3D || type == DRAWING_WORKPLANE ||
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type == ROTATE || type == TRANSLATE || type == IMPORTED)
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{
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bool allClosed = false, allCoplanar = false, allNonZeroLen = false;
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AssembleLoops(&allClosed, &allCoplanar, &allNonZeroLen);
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if(!allCoplanar) {
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polyError.how = POLY_NOT_COPLANAR;
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} else if(!allClosed) {
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polyError.how = POLY_NOT_CLOSED;
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} else if(!allNonZeroLen) {
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polyError.how = POLY_ZERO_LEN_EDGE;
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} else {
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polyError.how = POLY_GOOD;
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// The self-intersecting check is kind of slow, so don't run it
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// unless requested.
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if(SS.checkClosedContour) {
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if(polyLoops.SelfIntersecting(&(polyError.errorPointAt))) {
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polyError.how = POLY_SELF_INTERSECTING;
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}
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}
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}
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}
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}
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void SShell::RemapFaces(Group *g, int remap) {
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SSurface *ss;
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for(ss = surface.First(); ss; ss = surface.NextAfter(ss)){
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hEntity face = { ss->face };
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if(face.v == Entity::NO_ENTITY.v) continue;
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face = g->Remap(face, remap);
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ss->face = face.v;
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}
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}
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void SMesh::RemapFaces(Group *g, int remap) {
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STriangle *tr;
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for(tr = l.First(); tr; tr = l.NextAfter(tr)) {
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hEntity face = { tr->meta.face };
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if(face.v == Entity::NO_ENTITY.v) continue;
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face = g->Remap(face, remap);
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tr->meta.face = face.v;
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}
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}
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template<class T>
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void Group::GenerateForStepAndRepeat(T *steps, T *outs) {
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T workA, workB;
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ZERO(&workA);
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ZERO(&workB);
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T *soFar = &workA, *scratch = &workB;
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int n = (int)valA, a0 = 0;
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if(subtype == ONE_SIDED && skipFirst) {
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a0++; n++;
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}
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int a;
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for(a = a0; a < n; a++) {
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int ap = a*2 - (subtype == ONE_SIDED ? 0 : (n-1));
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int remap = (a == (n - 1)) ? REMAP_LAST : a;
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T transd;
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ZERO(&transd);
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if(type == TRANSLATE) {
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Vector trans = Vector::From(h.param(0), h.param(1), h.param(2));
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trans = trans.ScaledBy(ap);
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transd.MakeFromTransformationOf(steps,
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trans, Quaternion::IDENTITY, 1.0);
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} else {
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Vector trans = Vector::From(h.param(0), h.param(1), h.param(2));
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double theta = ap * SK.GetParam(h.param(3))->val;
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double c = cos(theta), s = sin(theta);
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Vector axis = Vector::From(h.param(4), h.param(5), h.param(6));
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Quaternion q = Quaternion::From(c, s*axis.x, s*axis.y, s*axis.z);
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// Rotation is centered at t; so A(x - t) + t = Ax + (t - At)
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transd.MakeFromTransformationOf(steps,
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trans.Minus(q.Rotate(trans)), q, 1.0);
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}
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// We need to rewrite any plane face entities to the transformed ones.
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transd.RemapFaces(this, remap);
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// And tack this transformed copy on to the return.
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if(soFar->IsEmpty()) {
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scratch->MakeFromCopyOf(&transd);
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} else {
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scratch->MakeFromUnionOf(soFar, &transd);
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}
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SWAP(T *, scratch, soFar);
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scratch->Clear();
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transd.Clear();
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}
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outs->Clear();
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*outs = *soFar;
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}
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template<class T>
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void Group::GenerateForBoolean(T *prevs, T *thiss, T *outs, int how) {
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// If this group contributes no new mesh, then our running mesh is the
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// same as last time, no combining required. Likewise if we have a mesh
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// but it's suppressed.
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if(thiss->IsEmpty() || suppress) {
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outs->MakeFromCopyOf(prevs);
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return;
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}
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// So our group's shell appears in thisShell. Combine this with the
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// previous group's shell, using the requested operation.
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if(how == COMBINE_AS_UNION) {
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outs->MakeFromUnionOf(prevs, thiss);
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} else if(how == COMBINE_AS_DIFFERENCE) {
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outs->MakeFromDifferenceOf(prevs, thiss);
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} else {
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outs->MakeFromAssemblyOf(prevs, thiss);
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}
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}
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void Group::GenerateShellAndMesh(void) {
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bool prevBooleanFailed = booleanFailed;
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booleanFailed = false;
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Group *srcg = this;
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thisShell.Clear();
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thisMesh.Clear();
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runningShell.Clear();
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runningMesh.Clear();
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// Don't attempt a lathe or extrusion unless the source section is good:
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// planar and not self-intersecting.
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bool haveSrc = true;
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if(type == EXTRUDE || type == LATHE) {
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Group *src = SK.GetGroup(opA);
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if(src->polyError.how != POLY_GOOD) {
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haveSrc = false;
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}
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}
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if(type == TRANSLATE || type == ROTATE) {
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// A step and repeat gets merged against the group's prevous group,
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// not our own previous group.
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srcg = SK.GetGroup(opA);
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GenerateForStepAndRepeat<SShell>(&(srcg->thisShell), &thisShell);
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GenerateForStepAndRepeat<SMesh> (&(srcg->thisMesh), &thisMesh);
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} else if(type == EXTRUDE && haveSrc) {
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Group *src = SK.GetGroup(opA);
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Vector translate = Vector::From(h.param(0), h.param(1), h.param(2));
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Vector tbot, ttop;
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if(subtype == ONE_SIDED) {
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tbot = Vector::From(0, 0, 0); ttop = translate.ScaledBy(2);
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} else {
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tbot = translate.ScaledBy(-1); ttop = translate.ScaledBy(1);
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}
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SBezierLoopSetSet *sblss = &(src->bezierLoops);
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SBezierLoopSet *sbls;
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for(sbls = sblss->l.First(); sbls; sbls = sblss->l.NextAfter(sbls)) {
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int is = thisShell.surface.n;
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// Extrude this outer contour (plus its inner contours, if present)
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thisShell.MakeFromExtrusionOf(sbls, tbot, ttop, color);
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// And for any plane faces, annotate the model with the entity for
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// that face, so that the user can select them with the mouse.
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Vector onOrig = sbls->point;
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int i;
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for(i = is; i < thisShell.surface.n; i++) {
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SSurface *ss = &(thisShell.surface.elem[i]);
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hEntity face = Entity::NO_ENTITY;
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Vector p = ss->PointAt(0, 0),
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n = ss->NormalAt(0, 0).WithMagnitude(1);
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double d = n.Dot(p);
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if(i == is || i == (is + 1)) {
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// These are the top and bottom of the shell.
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if(fabs((onOrig.Plus(ttop)).Dot(n) - d) < LENGTH_EPS) {
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face = Remap(Entity::NO_ENTITY, REMAP_TOP);
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ss->face = face.v;
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}
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if(fabs((onOrig.Plus(tbot)).Dot(n) - d) < LENGTH_EPS) {
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face = Remap(Entity::NO_ENTITY, REMAP_BOTTOM);
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ss->face = face.v;
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}
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continue;
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}
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// So these are the sides
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if(ss->degm != 1 || ss->degn != 1) continue;
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Entity *e;
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for(e = SK.entity.First(); e; e = SK.entity.NextAfter(e)) {
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if(e->group.v != opA.v) continue;
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if(e->type != Entity::LINE_SEGMENT) continue;
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Vector a = SK.GetEntity(e->point[0])->PointGetNum(),
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b = SK.GetEntity(e->point[1])->PointGetNum();
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a = a.Plus(ttop);
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b = b.Plus(ttop);
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// Could get taken backwards, so check all cases.
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if((a.Equals(ss->ctrl[0][0]) && b.Equals(ss->ctrl[1][0])) ||
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(b.Equals(ss->ctrl[0][0]) && a.Equals(ss->ctrl[1][0])) ||
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(a.Equals(ss->ctrl[0][1]) && b.Equals(ss->ctrl[1][1])) ||
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(b.Equals(ss->ctrl[0][1]) && a.Equals(ss->ctrl[1][1])))
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{
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face = Remap(e->h, REMAP_LINE_TO_FACE);
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ss->face = face.v;
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break;
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}
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}
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}
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}
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} else if(type == LATHE && haveSrc) {
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Group *src = SK.GetGroup(opA);
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Vector pt = SK.GetEntity(predef.origin)->PointGetNum(),
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axis = SK.GetEntity(predef.entityB)->VectorGetNum();
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axis = axis.WithMagnitude(1);
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SBezierLoopSetSet *sblss = &(src->bezierLoops);
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SBezierLoopSet *sbls;
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for(sbls = sblss->l.First(); sbls; sbls = sblss->l.NextAfter(sbls)) {
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thisShell.MakeFromRevolutionOf(sbls, pt, axis, color);
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}
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} else if(type == IMPORTED) {
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// The imported shell or mesh are copied over, with the appropriate
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// transformation applied. We also must remap the face entities.
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Vector offset = {
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SK.GetParam(h.param(0))->val,
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SK.GetParam(h.param(1))->val,
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SK.GetParam(h.param(2))->val };
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Quaternion q = {
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SK.GetParam(h.param(3))->val,
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SK.GetParam(h.param(4))->val,
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SK.GetParam(h.param(5))->val,
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SK.GetParam(h.param(6))->val };
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thisMesh.MakeFromTransformationOf(&impMesh, offset, q, scale);
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thisMesh.RemapFaces(this, 0);
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thisShell.MakeFromTransformationOf(&impShell, offset, q, scale);
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thisShell.RemapFaces(this, 0);
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}
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if(srcg->meshCombine != COMBINE_AS_ASSEMBLE) {
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thisShell.MergeCoincidentSurfaces();
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}
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// So now we've got the mesh or shell for this group. Combine it with
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// the previous group's mesh or shell with the requested Boolean, and
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// we're done.
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Group *prevg = srcg->RunningMeshGroup();
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if(prevg->runningMesh.IsEmpty() && thisMesh.IsEmpty() && !forceToMesh) {
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SShell *prevs = &(prevg->runningShell);
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GenerateForBoolean<SShell>(prevs, &thisShell, &runningShell,
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srcg->meshCombine);
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if(srcg->meshCombine != COMBINE_AS_ASSEMBLE) {
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runningShell.MergeCoincidentSurfaces();
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}
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// If the Boolean failed, then we should note that in the text screen
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// for this group.
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booleanFailed = runningShell.booleanFailed;
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if(booleanFailed != prevBooleanFailed) {
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SS.later.showTW = true;
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}
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} else {
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SMesh prevm, thism;
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ZERO(&prevm);
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ZERO(&thism);
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prevm.MakeFromCopyOf(&(prevg->runningMesh));
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prevg->runningShell.TriangulateInto(&prevm);
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thism.MakeFromCopyOf(&thisMesh);
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thisShell.TriangulateInto(&thism);
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SMesh outm;
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ZERO(&outm);
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GenerateForBoolean<SMesh>(&prevm, &thism, &outm, srcg->meshCombine);
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// And make sure that the output mesh is vertex-to-vertex.
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SKdNode *root = SKdNode::From(&outm);
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root->SnapToMesh(&outm);
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root->MakeMeshInto(&runningMesh);
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outm.Clear();
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thism.Clear();
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prevm.Clear();
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}
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displayDirty = true;
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}
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void Group::GenerateDisplayItems(void) {
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// This is potentially slow (since we've got to triangulate a shell, or
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// to find the emphasized edges for a mesh), so we will run it only
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// if its inputs have changed.
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if(displayDirty) {
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Group *pg = RunningMeshGroup();
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if(pg && thisMesh.IsEmpty() && thisShell.IsEmpty()) {
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// We don't contribute any new solid model in this group, so our
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// display items are identical to the previous group's; which means
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// that we can just display those, and stop ourselves from
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// recalculating for those every time we get a change in this group.
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//
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// Note that this can end up recursing multiple times (if multiple
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// groups that contribute no solid model exist in sequence), but
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// that's okay.
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pg->GenerateDisplayItems();
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displayMesh.Clear();
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displayMesh.MakeFromCopyOf(&(pg->displayMesh));
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displayEdges.Clear();
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if(SS.GW.showEdges) {
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SEdge *se;
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SEdgeList *src = &(pg->displayEdges);
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for(se = src->l.First(); se; se = src->l.NextAfter(se)) {
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displayEdges.l.Add(se);
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}
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}
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} else {
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// We do contribute new solid model, so we have to triangulate the
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// shell, and edge-find the mesh.
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displayMesh.Clear();
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runningShell.TriangulateInto(&displayMesh);
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STriangle *t;
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for(t = runningMesh.l.First(); t; t = runningMesh.l.NextAfter(t)) {
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STriangle trn = *t;
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Vector n = trn.Normal();
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trn.an = n;
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trn.bn = n;
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trn.cn = n;
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displayMesh.AddTriangle(&trn);
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}
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displayEdges.Clear();
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if(SS.GW.showEdges) {
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runningShell.MakeEdgesInto(&displayEdges);
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runningMesh.MakeEmphasizedEdgesInto(&displayEdges);
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}
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}
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displayDirty = false;
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}
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}
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Group *Group::PreviousGroup(void) {
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int i;
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for(i = 0; i < SK.group.n; i++) {
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Group *g = &(SK.group.elem[i]);
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if(g->h.v == h.v) break;
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}
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if(i == 0 || i >= SK.group.n) return NULL;
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return &(SK.group.elem[i-1]);
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}
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Group *Group::RunningMeshGroup(void) {
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if(type == TRANSLATE || type == ROTATE) {
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return SK.GetGroup(opA)->RunningMeshGroup();
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} else {
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return PreviousGroup();
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}
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}
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void Group::DrawDisplayItems(int t) {
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int specColor;
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if(t == DRAWING_3D || t == DRAWING_WORKPLANE) {
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// force the color to something dim
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specColor = Style::Color(Style::DIM_SOLID);
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} else {
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specColor = -1; // use the model color
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}
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// The back faces are drawn in red; should never seem them, since we
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// draw closed shells, so that's a debugging aid.
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GLfloat mpb[] = { 1.0f, 0.1f, 0.1f, 1.0 };
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glMaterialfv(GL_BACK, GL_AMBIENT_AND_DIFFUSE, mpb);
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// When we fill the mesh, we need to know which triangles are selected
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// or hovered, in order to draw them differently.
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DWORD mh = 0, ms1 = 0, ms2 = 0;
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hEntity he = SS.GW.hover.entity;
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if(he.v != 0 && SK.GetEntity(he)->IsFace()) {
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mh = he.v;
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}
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SS.GW.GroupSelection();
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if(gs.faces > 0) ms1 = gs.face[0].v;
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if(gs.faces > 1) ms2 = gs.face[1].v;
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if(SS.GW.showShaded) {
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glEnable(GL_LIGHTING);
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glxFillMesh(specColor, &displayMesh, mh, ms1, ms2);
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glDisable(GL_LIGHTING);
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}
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if(SS.GW.showEdges) {
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glxDepthRangeOffset(2);
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glxColorRGB(Style::Color(Style::SOLID_EDGE));
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glLineWidth(Style::Width(Style::SOLID_EDGE));
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glxDrawEdges(&displayEdges, false);
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}
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if(SS.GW.showMesh) glxDebugMesh(&displayMesh);
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}
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void Group::Draw(void) {
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// Everything here gets drawn whether or not the group is hidden; we
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// can control this stuff independently, with show/hide solids, edges,
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// mesh, etc.
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GenerateDisplayItems();
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DrawDisplayItems(type);
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if(!SS.checkClosedContour) return;
|
|
|
|
// And finally show the polygons too, and any errors if it's not possible
|
|
// to assemble the lines into closed polygons.
|
|
if(polyError.how == POLY_NOT_CLOSED) {
|
|
// Report this error only in sketch-in-workplane groups; otherwise
|
|
// it's just a nuisance.
|
|
if(type == DRAWING_WORKPLANE) {
|
|
glDisable(GL_DEPTH_TEST);
|
|
glxColorRGBa(Style::Color(Style::DRAW_ERROR), 0.2);
|
|
glLineWidth (Style::Width(Style::DRAW_ERROR));
|
|
glBegin(GL_LINES);
|
|
glxVertex3v(polyError.notClosedAt.a);
|
|
glxVertex3v(polyError.notClosedAt.b);
|
|
glEnd();
|
|
glxColorRGB(Style::Color(Style::DRAW_ERROR));
|
|
glxWriteText("not closed contour, or not all same style!",
|
|
DEFAULT_TEXT_HEIGHT,
|
|
polyError.notClosedAt.b, SS.GW.projRight, SS.GW.projUp,
|
|
NULL, NULL);
|
|
glEnable(GL_DEPTH_TEST);
|
|
}
|
|
} else if(polyError.how == POLY_NOT_COPLANAR ||
|
|
polyError.how == POLY_SELF_INTERSECTING ||
|
|
polyError.how == POLY_ZERO_LEN_EDGE)
|
|
{
|
|
// These errors occur at points, not lines
|
|
if(type == DRAWING_WORKPLANE) {
|
|
glDisable(GL_DEPTH_TEST);
|
|
glxColorRGB(Style::Color(Style::DRAW_ERROR));
|
|
const char *msg;
|
|
if(polyError.how == POLY_NOT_COPLANAR) {
|
|
msg = "points not all coplanar!";
|
|
} else if(polyError.how == POLY_SELF_INTERSECTING) {
|
|
msg = "contour is self-intersecting!";
|
|
} else {
|
|
msg = "zero-length edge!";
|
|
}
|
|
glxWriteText(msg, DEFAULT_TEXT_HEIGHT,
|
|
polyError.errorPointAt, SS.GW.projRight, SS.GW.projUp,
|
|
NULL, NULL);
|
|
glEnable(GL_DEPTH_TEST);
|
|
}
|
|
} else {
|
|
// The contours will get filled in DrawFilledPaths.
|
|
}
|
|
}
|
|
|
|
void Group::FillLoopSetAsPolygon(SBezierLoopSet *sbls) {
|
|
SPolygon sp;
|
|
ZERO(&sp);
|
|
sbls->MakePwlInto(&sp);
|
|
glxDepthRangeOffset(1);
|
|
glxFillPolygon(&sp);
|
|
glxDepthRangeOffset(0);
|
|
sp.Clear();
|
|
}
|
|
|
|
void Group::DrawFilledPaths(void) {
|
|
SBezierLoopSet *sbls;
|
|
SBezierLoopSetSet *sblss = &bezierLoops;
|
|
for(sbls = sblss->l.First(); sbls; sbls = sblss->l.NextAfter(sbls)) {
|
|
if(sbls->l.n == 0 || sbls->l.elem[0].l.n == 0) continue;
|
|
// In an assembled loop, all the styles should be the same; so doesn't
|
|
// matter which one we grab.
|
|
SBezier *sb = &(sbls->l.elem[0].l.elem[0]);
|
|
hStyle hs = { (DWORD)sb->auxA };
|
|
Style *s = Style::Get(hs);
|
|
if(s->filled) {
|
|
// This is a filled loop, where the user specified a fill color.
|
|
glxColorRGBa(s->fillColor, 1);
|
|
FillLoopSetAsPolygon(sbls);
|
|
} else {
|
|
if(h.v == SS.GW.activeGroup.v && SS.checkClosedContour &&
|
|
polyError.how == POLY_GOOD)
|
|
{
|
|
// If this is the active group, and we are supposed to check
|
|
// for closed contours, and we do indeed have a closed and
|
|
// non-intersecting contour, then fill it dimly.
|
|
glxColorRGBa(Style::Color(Style::CONTOUR_FILL), 0.5);
|
|
glxDepthRangeOffset(1);
|
|
FillLoopSetAsPolygon(sbls);
|
|
glxDepthRangeOffset(0);
|
|
}
|
|
}
|
|
}
|
|
}
|
|
|