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solvespace/groupmesh.cpp

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#include "solvespace.h"
#define gs (SS.GW.gs)
void Group::GeneratePolygon(void) {
poly.Clear();
if(type == DRAWING_3D || type == DRAWING_WORKPLANE ||
type == ROTATE || type == TRANSLATE)
{
SEdgeList edges; ZERO(&edges);
int i;
for(i = 0; i < SS.entity.n; i++) {
Entity *e = &(SS.entity.elem[i]);
if(e->group.v != h.v) continue;
e->GenerateEdges(&edges);
}
SEdge error;
if(edges.AssemblePolygon(&poly, &error)) {
polyError.how = POLY_GOOD;
poly.normal = poly.ComputeNormal();
poly.FixContourDirections();
if(!poly.AllPointsInPlane(&(polyError.notCoplanarAt))) {
// The edges aren't all coplanar; so not a good polygon
polyError.how = POLY_NOT_COPLANAR;
poly.Clear();
}
} else {
polyError.how = POLY_NOT_CLOSED;
polyError.notClosedAt = error;
poly.Clear();
}
edges.Clear();
}
}
void Group::GetTrajectory(hGroup hg, SContour *traj, SPolygon *section) {
if(section->IsEmpty()) return;
SEdgeList edges; ZERO(&edges);
int i, j;
for(i = 0; i < SS.entity.n; i++) {
Entity *e = &(SS.entity.elem[i]);
if(e->group.v != hg.v) continue;
e->GenerateEdges(&edges);
}
Vector pn = (section->normal).WithMagnitude(1);
double pd = pn.Dot(section->AnyPoint());
// Find the start of the trajectory
Vector first, last;
for(i = 0; i < edges.l.n; i++) {
SEdge *se = &(edges.l.elem[i]);
bool startA = true, startB = true;
for(j = 0; j < edges.l.n; j++) {
if(i == j) continue;
SEdge *set = &(edges.l.elem[j]);
if((set->a).Equals(se->a)) startA = false;
if((set->b).Equals(se->a)) startA = false;
if((set->a).Equals(se->b)) startB = false;
if((set->b).Equals(se->b)) startB = false;
}
if(startA || startB) {
// It's possible for both to be true, if only one segment exists
if(startA) {
first = se->a;
last = se->b;
} else {
first = se->b;
last = se->a;
}
se->tag = 1;
break;
}
}
if(i >= edges.l.n) goto cleanup;
edges.AssembleContour(first, last, traj, NULL);
if(traj->l.n < 1) goto cleanup;
// Starting and ending points of the trajectory
Vector ps, pf;
ps = traj->l.elem[0].p;
pf = traj->l.elem[traj->l.n - 1].p;
// Distances of those points to the section plane
double ds = fabs(pn.Dot(ps) - pd), df = fabs(pn.Dot(pf) - pd);
if(ds < LENGTH_EPS && df < LENGTH_EPS) {
if(section->WindingNumberForPoint(pf) > 0) {
// Both the start and finish lie on the section plane; let the
// start be the one that's somewhere within the section. Use
// winding > 0, not odd/even, since it's natural e.g. to sweep
// a ring to make a pipe, and draw the trajectory through the
// center of the ring.
traj->Reverse();
}
} else if(ds > df) {
// The starting point is the endpoint that's closer to the plane
traj->Reverse();
}
cleanup:
edges.Clear();
}
void Group::AddQuadWithNormal(STriMeta meta, Vector out,
Vector a, Vector b, Vector c, Vector d)
{
// The quad becomes two triangles
STriangle quad1 = STriangle::From(meta, a, b, c),
quad2 = STriangle::From(meta, c, d, a);
// Could be only one of the triangles has area; be sure
// to use that one for normal checking, then.
Vector n1 = quad1.Normal(), n2 = quad2.Normal();
Vector n = (n1.Magnitude() > n2.Magnitude()) ? n1 : n2;
if(n.Dot(out) < 0) {
quad1.FlipNormal();
quad2.FlipNormal();
}
// One or both of the endpoints might lie on the axis of
// rotation, in which case its triangle is zero-area.
if(n1.Magnitude() > LENGTH_EPS) thisMesh.AddTriangle(&quad1);
if(n2.Magnitude() > LENGTH_EPS) thisMesh.AddTriangle(&quad2);
}
void Group::GenerateMeshForStepAndRepeat(void) {
Group *src = SS.GetGroup(opA);
SMesh *srcm = &(src->thisMesh); // the mesh to step and repeat
if(srcm->l.n == 0) {
runningMesh.Clear();
runningMesh.MakeFromCopy(PreviousGroupMesh());
return;
}
SMesh origm;
ZERO(&origm);
origm.MakeFromCopy(src->PreviousGroupMesh());
int n = (int)valA, a0 = 0;
if(subtype == ONE_SIDED && skipFirst) {
a0++; n++;
}
int a;
for(a = a0; a < n; a++) {
int ap = a*2 - (subtype == ONE_SIDED ? 0 : (n-1));
int remap = (a == (n - 1)) ? REMAP_LAST : a;
thisMesh.Clear();
if(type == TRANSLATE) {
Vector trans = Vector::From(h.param(0), h.param(1), h.param(2));
trans = trans.ScaledBy(ap);
for(int i = 0; i < srcm->l.n; i++) {
STriangle tr = srcm->l.elem[i];
tr.a = (tr.a).Plus(trans);
tr.b = (tr.b).Plus(trans);
tr.c = (tr.c).Plus(trans);
if(tr.meta.face != 0) {
hEntity he = { tr.meta.face };
tr.meta.face = Remap(he, remap).v;
}
thisMesh.AddTriangle(&tr);
}
} else {
Vector trans = Vector::From(h.param(0), h.param(1), h.param(2));
double theta = ap * SS.GetParam(h.param(3))->val;
double c = cos(theta), s = sin(theta);
Vector axis = Vector::From(h.param(4), h.param(5), h.param(6));
Quaternion q = Quaternion::From(c, s*axis.x, s*axis.y, s*axis.z);
for(int i = 0; i < srcm->l.n; i++) {
STriangle tr = srcm->l.elem[i];
tr.a = (q.Rotate((tr.a).Minus(trans))).Plus(trans);
tr.b = (q.Rotate((tr.b).Minus(trans))).Plus(trans);
tr.c = (q.Rotate((tr.c).Minus(trans))).Plus(trans);
if(tr.meta.face != 0) {
hEntity he = { tr.meta.face };
tr.meta.face = Remap(he, remap).v;
}
thisMesh.AddTriangle(&tr);
}
}
runningMesh.Clear();
if(src->meshCombine == COMBINE_AS_DIFFERENCE) {
runningMesh.MakeFromDifference(&origm, &thisMesh);
} else {
runningMesh.MakeFromUnion(&origm, &thisMesh);
}
origm.Clear();
origm.MakeFromCopy(&runningMesh);
}
origm.Clear();
thisMesh.Clear();
}
void Group::GenerateMeshForSweep(bool helical,
Vector axisp, Vector axis, Vector onHelix)
{
STriMeta meta = { 0, color };
int a, i;
// The closed section that will be swept along the curve
Group *section = SS.GetGroup(helical ? opA : opB);
SEdgeList edges;
ZERO(&edges);
(section->poly).MakeEdgesInto(&edges);
// The trajectory along which the section will be swept
SContour traj;
ZERO(&traj);
if(helical) {
double r0 = onHelix.DistanceToLine(axisp, axis);
int n = (int)(SS.CircleSides(r0)*valA) + 4;
Vector origin = onHelix.ClosestPointOnLine(axisp, axis);
Vector u = (onHelix.Minus(origin)).WithMagnitude(1);
Vector v = (axis.Cross(u)).WithMagnitude(1);
for(i = 0; i <= n; i++) {
double turns = (i*valA)/n;
double theta = turns*2*PI;
double r = r0 + turns*valC;
if(subtype == LEFT_HANDED) theta = -theta;
Vector p = origin.Plus(
u.ScaledBy(r*cos(theta)).Plus(
v.ScaledBy(r*sin(theta)).Plus(
axis.WithMagnitude(turns*valB))));
traj.AddPoint(p);
}
} else {
GetTrajectory(opA, &traj, &(section->poly));
}
if(traj.l.n <= 0) {
edges.Clear();
return; // no trajectory, nothing to do
}
// Initial offset/orientation determined by first pwl in trajectory
Vector origRef = traj.l.elem[0].p;
Vector origNormal = (traj.l.elem[1].p).Minus(origRef);
origNormal = origNormal.WithMagnitude(1);
Vector oldRef = origRef, oldNormal = origNormal;
Vector oldU, oldV;
if(helical) {
oldU = axis.WithMagnitude(1);
oldV = (oldNormal.Cross(oldU)).WithMagnitude(1);
// numerical fixup, since pwl segment isn't exactly tangent...
oldU = (oldV.Cross(oldNormal)).WithMagnitude(1);
} else {
oldU = oldNormal.Normal(0);
oldV = oldNormal.Normal(1);
}
// The endcap at the start of the curve
SPolygon cap;
ZERO(&cap);
edges.l.ClearTags();
edges.AssemblePolygon(&cap, NULL);
cap.normal = cap.ComputeNormal();
if(oldNormal.Dot(cap.normal) > 0) {
cap.normal = (cap.normal).ScaledBy(-1);
}
cap.TriangulateInto(&thisMesh, meta);
cap.Clear();
// Rewrite the source polygon so that the trajectory is along the
// z axis, and the poly lies in the xy plane
for(i = 0; i < edges.l.n; i++) {
SEdge *e = &(edges.l.elem[i]);
e->a = ((e->a).Minus(oldRef)).DotInToCsys(oldU, oldV, oldNormal);
e->b = ((e->b).Minus(oldRef)).DotInToCsys(oldU, oldV, oldNormal);
}
Vector polyn =
(section->poly.normal).DotInToCsys(oldU, oldV, oldNormal);
for(a = 1; a < traj.l.n; a++) {
Vector thisRef = traj.l.elem[a].p;
Vector thisNormal, useNormal;
if(a == traj.l.n - 1) {
thisNormal = oldNormal;
useNormal = oldNormal;
} else {
thisNormal = (traj.l.elem[a+1].p).Minus(thisRef);
useNormal = (thisNormal.Plus(oldNormal)).ScaledBy(0.5);
}
Vector useV, useU;
useNormal = useNormal.WithMagnitude(1);
if(helical) {
// The axis of rotation is always a basis vector
useU = axis.WithMagnitude(1);
useV = (useNormal.Cross(useU)).WithMagnitude(1);
} else {
// Choose a new coordinate system, normal to the trajectory and
// with the minimum possible twist about the normal.
useV = (useNormal.Cross(oldU)).WithMagnitude(1);
useU = (useV.Cross(useNormal)).WithMagnitude(1);
}
Quaternion qi = Quaternion::From(oldU, oldV);
Quaternion qf = Quaternion::From(useU, useV);
for(i = 0; i < edges.l.n; i++) {
SEdge *edge = &(edges.l.elem[i]);
Vector ai, bi, af, bf;
ai = qi.Rotate(edge->a).Plus(oldRef);
bi = qi.Rotate(edge->b).Plus(oldRef);
af = qf.Rotate(edge->a).Plus(thisRef);
bf = qf.Rotate(edge->b).Plus(thisRef);
Vector ab = (edge->b).Minus(edge->a);
Vector out = polyn.Cross(ab);
out = qf.Rotate(out);
AddQuadWithNormal(meta, out, ai, bi, bf, af);
}
oldRef = thisRef;
oldNormal = thisNormal;
oldU = useU;
oldV = useV;
}
Quaternion q = Quaternion::From(oldU, oldV);
for(i = 0; i < edges.l.n; i++) {
SEdge *edge = &(edges.l.elem[i]);
(edge->a) = q.Rotate(edge->a).Plus(oldRef);
(edge->b) = q.Rotate(edge->b).Plus(oldRef);
}
edges.l.ClearTags();
edges.AssemblePolygon(&cap, NULL);
cap.normal = cap.ComputeNormal();
if(oldNormal.Dot(cap.normal) < 0) {
cap.normal = (cap.normal).ScaledBy(-1);
}
cap.TriangulateInto(&thisMesh, meta);
cap.Clear();
traj.l.Clear();
edges.Clear();
}
void Group::GenerateMesh(void) {
thisMesh.Clear();
STriMeta meta = { 0, color };
if(type == TRANSLATE || type == ROTATE) {
GenerateMeshForStepAndRepeat();
goto done;
}
if(type == EXTRUDE) {
SEdgeList edges;
ZERO(&edges);
int i;
Group *src = SS.GetGroup(opA);
Vector translate = Vector::From(h.param(0), h.param(1), h.param(2));
Vector tbot, ttop;
if(subtype == ONE_SIDED) {
tbot = Vector::From(0, 0, 0); ttop = translate.ScaledBy(2);
} else {
tbot = translate.ScaledBy(-1); ttop = translate.ScaledBy(1);
}
bool flipBottom = translate.Dot(src->poly.normal) > 0;
// Get a triangulation of the source poly; this is not a closed mesh.
SMesh srcm; ZERO(&srcm);
(src->poly).TriangulateInto(&srcm);
// Do the bottom; that has normal pointing opposite from translate
meta.face = Remap(Entity::NO_ENTITY, REMAP_BOTTOM).v;
for(i = 0; i < srcm.l.n; i++) {
STriangle *st = &(srcm.l.elem[i]);
Vector at = (st->a).Plus(tbot),
bt = (st->b).Plus(tbot),
ct = (st->c).Plus(tbot);
if(flipBottom) {
thisMesh.AddTriangle(meta, ct, bt, at);
} else {
thisMesh.AddTriangle(meta, at, bt, ct);
}
}
// And the top; that has the normal pointing the same dir as translate
meta.face = Remap(Entity::NO_ENTITY, REMAP_TOP).v;
for(i = 0; i < srcm.l.n; i++) {
STriangle *st = &(srcm.l.elem[i]);
Vector at = (st->a).Plus(ttop),
bt = (st->b).Plus(ttop),
ct = (st->c).Plus(ttop);
if(flipBottom) {
thisMesh.AddTriangle(meta, at, bt, ct);
} else {
thisMesh.AddTriangle(meta, ct, bt, at);
}
}
srcm.Clear();
// Get the source polygon to extrude, and break it down to edges
edges.Clear();
(src->poly).MakeEdgesInto(&edges);
edges.l.ClearTags();
TagEdgesFromLineSegments(&edges);
// The sides; these are quads, represented as two triangles.
for(i = 0; i < edges.l.n; i++) {
SEdge *edge = &(edges.l.elem[i]);
Vector abot = (edge->a).Plus(tbot), bbot = (edge->b).Plus(tbot);
Vector atop = (edge->a).Plus(ttop), btop = (edge->b).Plus(ttop);
// We tagged the edges that came from line segments; their
// triangles should be associated with that plane face.
if(edge->tag) {
hEntity hl = { edge->tag };
hEntity hf = Remap(hl, REMAP_LINE_TO_FACE);
meta.face = hf.v;
} else {
meta.face = 0;
}
if(flipBottom) {
thisMesh.AddTriangle(meta, bbot, abot, atop);
thisMesh.AddTriangle(meta, bbot, atop, btop);
} else {
thisMesh.AddTriangle(meta, abot, bbot, atop);
thisMesh.AddTriangle(meta, bbot, btop, atop);
}
}
edges.Clear();
} else if(type == LATHE) {
SEdgeList edges;
ZERO(&edges);
int a, i;
Group *src = SS.GetGroup(opA);
(src->poly).MakeEdgesInto(&edges);
Vector orig = SS.GetEntity(predef.origin)->PointGetNum();
Vector axis = SS.GetEntity(predef.entityB)->VectorGetNum();
axis = axis.WithMagnitude(1);
// Calculate the max radius, to determine fineness of mesh
double r, rmax = 0;
for(i = 0; i < edges.l.n; i++) {
SEdge *edge = &(edges.l.elem[i]);
r = (edge->a).DistanceToLine(orig, axis);
rmax = max(r, rmax);
r = (edge->b).DistanceToLine(orig, axis);
rmax = max(r, rmax);
}
int n = SS.CircleSides(rmax);
for(a = 0; a < n; a++) {
double thetai = (2*PI*WRAP(a-1, n))/n, thetaf = (2*PI*a)/n;
for(i = 0; i < edges.l.n; i++) {
SEdge *edge = &(edges.l.elem[i]);
Vector ai = (edge->a).RotatedAbout(orig, axis, thetai);
Vector bi = (edge->b).RotatedAbout(orig, axis, thetai);
Vector af = (edge->a).RotatedAbout(orig, axis, thetaf);
Vector bf = (edge->b).RotatedAbout(orig, axis, thetaf);
Vector ab = (edge->b).Minus(edge->a);
Vector out = ((src->poly).normal).Cross(ab);
// This is a vector, not a point, so no origin for rotation
out = out.RotatedAbout(axis, thetai);
AddQuadWithNormal(meta, out, ai, bi, bf, af);
}
}
} else if(type == SWEEP) {
Vector zp = Vector::From(0, 0, 0);
GenerateMeshForSweep(false, zp, zp, zp);
} else if(type == HELICAL_SWEEP) {
Entity *ln = SS.GetEntity(predef.entityB);
Vector lna = SS.GetEntity(ln->point[0])->PointGetNum(),
lnb = SS.GetEntity(ln->point[1])->PointGetNum();
Vector onh = SS.GetEntity(predef.origin)->PointGetNum();
GenerateMeshForSweep(true, lna, lnb.Minus(lna), onh);
} else if(type == IMPORTED) {
// Triangles are just copied over, with the appropriate transformation
// applied.
Vector offset = {
SS.GetParam(h.param(0))->val,
SS.GetParam(h.param(1))->val,
SS.GetParam(h.param(2))->val };
Quaternion q = {
SS.GetParam(h.param(3))->val,
SS.GetParam(h.param(4))->val,
SS.GetParam(h.param(5))->val,
SS.GetParam(h.param(6))->val };
for(int i = 0; i < impMesh.l.n; i++) {
STriangle st = impMesh.l.elem[i];
if(st.meta.face != 0) {
hEntity he = { st.meta.face };
st.meta.face = Remap(he, 0).v;
}
st.a = q.Rotate(st.a).Plus(offset);
st.b = q.Rotate(st.b).Plus(offset);
st.c = q.Rotate(st.c).Plus(offset);
thisMesh.AddTriangle(&st);
}
}
runningMesh.Clear();
// If this group contributes no new mesh, then our running mesh is the
// same as last time, no combining required.
if(thisMesh.l.n == 0) {
runningMesh.MakeFromCopy(PreviousGroupMesh());
goto done;
}
// So our group's mesh appears in thisMesh. Combine this with the previous
// group's mesh, using the requested operation.
bool prevMeshError = meshError.yes;
meshError.yes = false;
meshError.interferesAt.Clear();
SMesh *a = PreviousGroupMesh();
if(meshCombine == COMBINE_AS_UNION) {
runningMesh.MakeFromUnion(a, &thisMesh);
} else if(meshCombine == COMBINE_AS_DIFFERENCE) {
runningMesh.MakeFromDifference(a, &thisMesh);
} else {
if(!runningMesh.MakeFromInterferenceCheck(a, &thisMesh,
&(meshError.interferesAt)))
{
meshError.yes = true;
// And the list of failed triangles goes in meshError.interferesAt
}
}
if(prevMeshError != meshError.yes) {
// The error is reported in the text window for the group.
SS.later.showTW = true;
}
done:
emphEdges.Clear();
if(h.v == SS.GW.activeGroup.v && SS.edgeColor != 0) {
SKdNode *root = SKdNode::From(&runningMesh);
root->SnapToMesh(&runningMesh);
root->MakeCertainEdgesInto(&emphEdges, true);
}
}
SMesh *Group::PreviousGroupMesh(void) {
int i;
for(i = 0; i < SS.group.n; i++) {
Group *g = &(SS.group.elem[i]);
if(g->h.v == h.v) break;
}
if(i == 0 || i >= SS.group.n) oops();
return &(SS.group.elem[i-1].runningMesh);
}
void Group::Draw(void) {
// Show this even if the group is not visible. It's already possible
// to show or hide just this with the "show solids" flag.
int specColor;
if(type == DRAWING_3D || type == DRAWING_WORKPLANE) {
specColor = RGB(25, 25, 25); // force the color to something dim
} else {
specColor = -1; // use the model color
}
// The back faces are drawn in red; should never seem them, since we
// draw closed shells, so that's a debugging aid.
GLfloat mpb[] = { 1.0f, 0.1f, 0.1f, 1.0 };
glMaterialfv(GL_BACK, GL_AMBIENT_AND_DIFFUSE, mpb);
// When we fill the mesh, we need to know which triangles are selected
// or hovered, in order to draw them differently.
DWORD mh = 0, ms1 = 0, ms2 = 0;
hEntity he = SS.GW.hover.entity;
if(he.v != 0 && SS.GetEntity(he)->IsFace()) {
mh = he.v;
}
SS.GW.GroupSelection();
if(gs.faces > 0) ms1 = gs.face[0].v;
if(gs.faces > 1) ms2 = gs.face[1].v;
if(SS.GW.showShaded) {
glEnable(GL_LIGHTING);
glxFillMesh(specColor, &runningMesh, mh, ms1, ms2);
glDisable(GL_LIGHTING);
glxDrawEdges(&emphEdges);
}
if(meshError.yes) {
// Draw the error triangles in bright red stripes, with no Z buffering
GLubyte mask[32*32/8];
memset(mask, 0xf0, sizeof(mask));
glPolygonStipple(mask);
int specColor = 0;
glDisable(GL_DEPTH_TEST);
glColor3d(0, 0, 0);
glxFillMesh(0, &meshError.interferesAt, 0, 0, 0);
glEnable(GL_POLYGON_STIPPLE);
glColor3d(1, 0, 0);
glxFillMesh(0, &meshError.interferesAt, 0, 0, 0);
glEnable(GL_DEPTH_TEST);
glDisable(GL_POLYGON_STIPPLE);
}
if(SS.GW.showMesh) glxDebugMesh(&runningMesh);
// And finally show the polygons too
if(!SS.GW.showShaded) return;
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);
glxColor4d(1, 0, 0, 0.2);
glLineWidth(10);
glBegin(GL_LINES);
glxVertex3v(polyError.notClosedAt.a);
glxVertex3v(polyError.notClosedAt.b);
glEnd();
glLineWidth(1);
glxColor3d(1, 0, 0);
glPushMatrix();
glxTranslatev(polyError.notClosedAt.b);
glxOntoWorkplane(SS.GW.projRight, SS.GW.projUp);
glxWriteText("not closed contour!");
glPopMatrix();
glEnable(GL_DEPTH_TEST);
}
} else if(polyError.how == POLY_NOT_COPLANAR) {
// And this one too
if(type == DRAWING_WORKPLANE) {
glDisable(GL_DEPTH_TEST);
glxColor3d(1, 0, 0);
glPushMatrix();
glxTranslatev(polyError.notCoplanarAt);
glxOntoWorkplane(SS.GW.projRight, SS.GW.projUp);
glxWriteText("points not all coplanar!");
glPopMatrix();
glEnable(GL_DEPTH_TEST);
}
} else {
glxColor4d(0, 0.1, 0.1, 0.5);
glxDepthRangeOffset(1);
glxFillPolygon(&poly);
glxDepthRangeOffset(0);
}
}
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