solvespace/generate.cpp

#include "solvespace.h"

void SolveSpace::MarkGroupDirtyByEntity(hEntity he) {
    Entity *e = SS.GetEntity(he);
    MarkGroupDirty(e->group);
}

void SolveSpace::MarkGroupDirty(hGroup hg) {
    int i;
    bool go = false;
    for(i = 0; i < group.n; i++) {
        Group *g = &(group.elem[i]);
        if(g->h.v == hg.v) {
            go = true;
        }
        if(go) {
            g->clean = false;
        }
    }
    unsaved = true;
}

bool SolveSpace::PruneOrphans(void) {
    int i;
    for(i = 0; i < request.n; i++) {
        Request *r = &(request.elem[i]);
        if(GroupExists(r->group)) continue;

        (deleted.requests)++;
        request.RemoveById(r->h);
        return true;
    }

    for(i = 0; i < constraint.n; i++) {
        Constraint *c = &(constraint.elem[i]);
        if(GroupExists(c->group)) continue;

        (deleted.constraints)++;
        constraint.RemoveById(c->h);
        return true;
    }
    return false;
}

bool SolveSpace::GroupsInOrder(hGroup before, hGroup after) {
    if(before.v == 0) return true;
    if(after.v  == 0) return true;

    int beforep = -1, afterp = -1;
    int i;
    for(i = 0; i < group.n; i++) {
        Group *g = &(group.elem[i]);
        if(g->h.v == before.v) beforep = i;
        if(g->h.v == after.v)  afterp  = i;
    }
    if(beforep < 0 || afterp < 0) return false;
    if(beforep >= afterp) return false;
    return true;
}

bool SolveSpace::GroupExists(hGroup hg) {
    // A nonexistent group is not acceptable
    return group.FindByIdNoOops(hg) ? true : false;
}
bool SolveSpace::EntityExists(hEntity he) {
    // A nonexstient entity is acceptable, though, usually just means it
    // doesn't apply.
    if(he.v == Entity::NO_ENTITY.v) return true;
    return entity.FindByIdNoOops(he) ? true : false;
}

bool SolveSpace::PruneGroups(hGroup hg) {
    Group *g = GetGroup(hg);
    if(GroupsInOrder(g->opA, hg) &&
       EntityExists(g->predef.origin) &&
       EntityExists(g->predef.entityB) &&
       EntityExists(g->predef.entityC))
    {
        return false;
    }
    (deleted.groups)++;
    group.RemoveById(g->h);
    return true;
}

bool SolveSpace::PruneRequests(hGroup hg) {
    int i;
    for(i = 0; i < entity.n; i++) {
        Entity *e = &(entity.elem[i]);
        if(e->group.v != hg.v) continue;

        if(EntityExists(e->workplane)) continue;

        if(!e->h.isFromRequest()) oops();

        (deleted.requests)++;
        request.RemoveById(e->h.request());
        return true;
    }
    return false;
}

bool SolveSpace::PruneConstraints(hGroup hg) {
    int i;
    for(i = 0; i < constraint.n; i++) {
        Constraint *c = &(constraint.elem[i]);
        if(c->group.v != hg.v) continue;

        if(EntityExists(c->workplane) &&
           EntityExists(c->ptA) &&
           EntityExists(c->ptB) &&
           EntityExists(c->entityA) &&
           EntityExists(c->entityB) &&
           EntityExists(c->entityC) &&
           EntityExists(c->entityD))
        {
            continue;
        }

        (deleted.constraints)++;
        constraint.RemoveById(c->h);
        return true;
    }
    return false;
}

void SolveSpace::GenerateAll(void) {
    int i;
    int firstDirty = INT_MAX, lastVisible = 0;
    // Start from the first dirty group, and solve until the active group,
    // since all groups after the active group are hidden.
    for(i = 0; i < group.n; i++) {
        Group *g = &(group.elem[i]);
        g->order = i;
        if((!g->clean) || (g->solved.how != Group::SOLVED_OKAY)) {
            firstDirty = min(firstDirty, i);
        }
        if(g->h.v == SS.GW.activeGroup.v) {
            lastVisible = i;
        }
    }
    if(firstDirty == INT_MAX || lastVisible == 0) {
        // All clean; so just regenerate the entities, and don't solve anything.
        GenerateAll(-1, -1);
    } else {
        GenerateAll(firstDirty, lastVisible);
    }
}

void SolveSpace::GenerateAll(int first, int last) {
    int i, j;

    // Remove any requests or constraints that refer to a nonexistent
    // group; can check those immediately, since we know what the list
    // of groups should be.
    while(PruneOrphans())
        ;

    // Don't lose our numerical guesses when we regenerate.
    IdList<Param,hParam> prev;
    param.MoveSelfInto(&prev);
    entity.Clear();

    for(i = 0; i < group.n; i++) {
        Group *g = &(group.elem[i]);

        // The group may depend on entities or other groups, to define its
        // workplane geometry or for its operands. Those must already exist
        // in a previous group, so check them before generating.
        if(PruneGroups(g->h))
            goto pruned;

        for(j = 0; j < request.n; j++) {
            Request *r = &(request.elem[j]);
            if(r->group.v != g->h.v) continue;

            r->Generate(&entity, &param);
        }
        g->Generate(&entity, &param);

        // The requests and constraints depend on stuff in this or the
        // previous group, so check them after generating.
        if(PruneRequests(g->h) || PruneConstraints(g->h))
            goto pruned;

        // Use the previous values for params that we've seen before, as
        // initial guesses for the solver.
        for(j = 0; j < param.n; j++) {
            Param *newp = &(param.elem[j]);
            if(newp->known) continue;

            Param *prevp = prev.FindByIdNoOops(newp->h);
            if(prevp) newp->val = prevp->val;
        }

        if(g->h.v == Group::HGROUP_REFERENCES.v) {
            ForceReferences();
            g->solved.how = Group::SOLVED_OKAY;
            g->clean = true;
        } else {
            if(i >= first && i <= last) {
                // See if we have to do the vertex-to-vertex mesh, that
                // we used for emphasized edges.
                if(first == i && 
                    (g->type == Group::DRAWING_3D ||
                     g->type == Group::DRAWING_WORKPLANE))
                {
                    // Special case--if the first dirty group doesn't change
                    // the mesh, then no need to regen edges for it.
                } else {
                    g->vvMeshClean = false; // so we'll regen it
                }
                // The group falls inside the range, so really solve it,
                // and then regenerate the mesh based on the solved stuff.
                SolveGroup(g->h);
                g->GeneratePolygon();
                g->GenerateMesh();
                g->clean = true;
            } else {
                // The group falls outside the range, so just assume that
                // it's good wherever we left it. The mesh is unchanged,
                // and the parameters must be marked as known.
                for(j = 0; j < param.n; j++) {
                    Param *newp = &(param.elem[j]);

                    Param *prevp = prev.FindByIdNoOops(newp->h);
                    if(prevp) newp->known = true;
                }
            }
        }
    }

    // And update any reference dimensions with their new values
    for(i = 0; i < constraint.n; i++) {
        Constraint *c = &(constraint.elem[i]);
        if(c->reference) {
            c->ModifyToSatisfy();
        }
    }

    // Make sure the point that we're tracing exists.
    if(traced.point.v && !entity.FindByIdNoOops(traced.point)) {
        traced.point = Entity::NO_ENTITY;
    }
    // And if we're tracing a point, add its new value to the path
    if(traced.point.v) {
        Entity *pt = GetEntity(traced.point);
        traced.path.AddPoint(pt->PointGetNum());
    }

    prev.Clear();
    InvalidateGraphics();

    // Remove nonexistent selection items, for same reason we waited till
    // the end to put up a dialog box.
    GW.ClearNonexistentSelectionItems();

    if(deleted.requests > 0 || deleted.constraints > 0 || deleted.groups > 0) {
        // All sorts of interesting things could have happened; for example,
        // the active group or active workplane could have been deleted. So
        // clear all that out.
        if(deleted.groups > 0) {
            SS.TW.ClearSuper();
        }
        later.showTW = true;
        GW.ClearSuper();
        // Don't display any errors until we've regenerated fully. The
        // sketch is not necessarily in a consistent state until we've
        // pruned any orphaned etc. objects, and the message loop for the
        // messagebox could allow us to repaint and crash. But now we must
        // be fine.
        Error("Additional sketch elements were deleted, because they depend "
              "on the element that was just deleted explicitly. These "
              "include: \r\n"
              "     %d request%s\r\n"
              "     %d constraint%s\r\n"
              "     %d group%s\r\n\r\n"
              "Choose Edit -> Undo to undelete all elements.",
                deleted.requests, deleted.requests == 1 ? "" : "s",
                deleted.constraints, deleted.constraints == 1 ? "" : "s",
                deleted.groups, deleted.groups == 1 ? "" : "s");
        memset(&deleted, 0, sizeof(deleted));
    }
    
    FreeAllTemporary();
    allConsistent = true;
    return;

pruned:
    // Restore the numerical guesses
    param.Clear();
    prev.MoveSelfInto(&param);
    // Try again
    GenerateAll(first, last);
}

void SolveSpace::ForceReferences(void) {
    // Force the values of the paramters that define the three reference
    // coordinate systems.
    static const struct {
        hRequest    hr;
        Quaternion  q;
    } Quat[] = {
        { Request::HREQUEST_REFERENCE_XY, { 1,    0,    0,    0,   } },
        { Request::HREQUEST_REFERENCE_YZ, { 0.5,  0.5,  0.5,  0.5, } },
        { Request::HREQUEST_REFERENCE_ZX, { 0.5, -0.5, -0.5, -0.5, } },
    };
    for(int i = 0; i < 3; i++) {
        hRequest hr = Quat[i].hr;
        Entity *wrkpl = GetEntity(hr.entity(0));
        // The origin for our coordinate system, always zero
        Entity *origin = GetEntity(wrkpl->point[0]);
        origin->PointForceTo(Vector::From(0, 0, 0));
        GetParam(origin->param[0])->known = true;
        GetParam(origin->param[1])->known = true;
        GetParam(origin->param[2])->known = true;
        // The quaternion that defines the rotation, from the table.
        Entity *normal = GetEntity(wrkpl->normal); 
        normal->NormalForceTo(Quat[i].q);
        GetParam(normal->param[0])->known = true;
        GetParam(normal->param[1])->known = true;
        GetParam(normal->param[2])->known = true;
        GetParam(normal->param[3])->known = true;
    }
}

void SolveSpace::SolveGroup(hGroup hg) {
    int i;
    // Clear out the system to be solved.
    sys.entity.Clear();
    sys.param.Clear();
    sys.eq.Clear();
    // And generate all the params for requests in this group
    for(i = 0; i < request.n; i++) {
        Request *r = &(request.elem[i]);
        if(r->group.v != hg.v) continue;

        r->Generate(&(sys.entity), &(sys.param));
    }
    // And for the group itself
    Group *g = SS.GetGroup(hg);
    g->Generate(&(sys.entity), &(sys.param));
    // Set the initial guesses for all the params
    for(i = 0; i < sys.param.n; i++) {
        Param *p = &(sys.param.elem[i]);
        p->known = false;
        p->val = GetParam(p->h)->val;
    }

    sys.Solve(g);
    FreeAllTemporary();
}

bool SolveSpace::AllGroupsOkay(void) {
    int i;
    bool allOk = true;
    for(i = 0; i < group.n; i++) {
        if(group.elem[i].solved.how != Group::SOLVED_OKAY) {
            allOk = false;
        }
    }
    return allOk;
}