#include "solvespace.h" ExprVector ExprVector::From(Expr *x, Expr *y, Expr *z) { ExprVector r = { x, y, z}; return r; } ExprVector ExprVector::From(Vector vn) { ExprVector ve; ve.x = Expr::From(vn.x); ve.y = Expr::From(vn.y); ve.z = Expr::From(vn.z); return ve; } ExprVector ExprVector::From(hParam x, hParam y, hParam z) { ExprVector ve; ve.x = Expr::From(x); ve.y = Expr::From(y); ve.z = Expr::From(z); return ve; } ExprVector ExprVector::From(double x, double y, double z) { ExprVector ve; ve.x = Expr::From(x); ve.y = Expr::From(y); ve.z = Expr::From(z); return ve; } ExprVector ExprVector::Minus(ExprVector b) { ExprVector r; r.x = x->Minus(b.x); r.y = y->Minus(b.y); r.z = z->Minus(b.z); return r; } ExprVector ExprVector::Plus(ExprVector b) { ExprVector r; r.x = x->Plus(b.x); r.y = y->Plus(b.y); r.z = z->Plus(b.z); return r; } Expr *ExprVector::Dot(ExprVector b) { Expr *r; r = x->Times(b.x); r = r->Plus(y->Times(b.y)); r = r->Plus(z->Times(b.z)); return r; } ExprVector ExprVector::Cross(ExprVector b) { ExprVector r; r.x = (y->Times(b.z))->Minus(z->Times(b.y)); r.y = (z->Times(b.x))->Minus(x->Times(b.z)); r.z = (x->Times(b.y))->Minus(y->Times(b.x)); return r; } ExprVector ExprVector::ScaledBy(Expr *s) { ExprVector r; r.x = x->Times(s); r.y = y->Times(s); r.z = z->Times(s); return r; } ExprVector ExprVector::WithMagnitude(Expr *s) { Expr *m = Magnitude(); return ScaledBy(s->Div(m)); } Expr *ExprVector::Magnitude(void) { Expr *r; r = x->Square(); r = r->Plus(y->Square()); r = r->Plus(z->Square()); return r->Sqrt(); } Vector ExprVector::Eval(void) { Vector r; r.x = x->Eval(); r.y = y->Eval(); r.z = z->Eval(); return r; } ExprQuaternion ExprQuaternion::From(hParam w, hParam vx, hParam vy, hParam vz) { ExprQuaternion q; q.w = Expr::From(w); q.vx = Expr::From(vx); q.vy = Expr::From(vy); q.vz = Expr::From(vz); return q; } ExprQuaternion ExprQuaternion::From(Expr *w, Expr *vx, Expr *vy, Expr *vz) { ExprQuaternion q; q.w = w; q.vx = vx; q.vy = vy; q.vz = vz; return q; } ExprQuaternion ExprQuaternion::From(Quaternion qn) { ExprQuaternion qe; qe.w = Expr::From(qn.w); qe.vx = Expr::From(qn.vx); qe.vy = Expr::From(qn.vy); qe.vz = Expr::From(qn.vz); return qe; } ExprVector ExprQuaternion::RotationU(void) { ExprVector u; Expr *two = Expr::From(2); u.x = w->Square(); u.x = (u.x)->Plus(vx->Square()); u.x = (u.x)->Minus(vy->Square()); u.x = (u.x)->Minus(vz->Square()); u.y = two->Times(w->Times(vz)); u.y = (u.y)->Plus(two->Times(vx->Times(vy))); u.z = two->Times(vx->Times(vz)); u.z = (u.z)->Minus(two->Times(w->Times(vy))); return u; } ExprVector ExprQuaternion::RotationV(void) { ExprVector v; Expr *two = Expr::From(2); v.x = two->Times(vx->Times(vy)); v.x = (v.x)->Minus(two->Times(w->Times(vz))); v.y = w->Square(); v.y = (v.y)->Minus(vx->Square()); v.y = (v.y)->Plus(vy->Square()); v.y = (v.y)->Minus(vz->Square()); v.z = two->Times(w->Times(vx)); v.z = (v.z)->Plus(two->Times(vy->Times(vz))); return v; } ExprVector ExprQuaternion::RotationN(void) { ExprVector n; Expr *two = Expr::From(2); n.x = two->Times( w->Times(vy)); n.x = (n.x)->Plus (two->Times(vx->Times(vz))); n.y = two->Times(vy->Times(vz)); n.y = (n.y)->Minus(two->Times( w->Times(vx))); n.z = w->Square(); n.z = (n.z)->Minus(vx->Square()); n.z = (n.z)->Minus(vy->Square()); n.z = (n.z)->Plus (vz->Square()); return n; } ExprVector ExprQuaternion::Rotate(ExprVector p) { // Express the point in the new basis return (RotationU().ScaledBy(p.x)).Plus( RotationV().ScaledBy(p.y)).Plus( RotationN().ScaledBy(p.z)); } ExprQuaternion ExprQuaternion::Times(ExprQuaternion b) { Expr *sa = w, *sb = b.w; ExprVector va = { vx, vy, vz }; ExprVector vb = { b.vx, b.vy, b.vz }; ExprQuaternion r; r.w = (sa->Times(sb))->Minus(va.Dot(vb)); ExprVector vr = vb.ScaledBy(sa).Plus( va.ScaledBy(sb).Plus( va.Cross(vb))); r.vx = vr.x; r.vy = vr.y; r.vz = vr.z; return r; } Expr *ExprQuaternion::Magnitude(void) { return ((w ->Square())->Plus( (vx->Square())->Plus( (vy->Square())->Plus( (vz->Square())))))->Sqrt(); } Expr *Expr::From(hParam p) { Expr *r = AllocExpr(); r->op = PARAM; r->x.parh = p; return r; } Expr *Expr::From(double v) { Expr *r = AllocExpr(); r->op = CONSTANT; r->x.v = v; return r; } Expr *Expr::AnyOp(int newOp, Expr *b) { Expr *r = AllocExpr(); r->op = newOp; r->a = this; r->b = b; return r; } int Expr::Children(void) { switch(op) { case PARAM: case PARAM_PTR: case CONSTANT: return 0; case PLUS: case MINUS: case TIMES: case DIV: return 2; case NEGATE: case SQRT: case SQUARE: case SIN: case COS: return 1; default: oops(); } } int Expr::Nodes(void) { switch(Children()) { case 0: return 1; case 1: return 1 + a->Nodes(); case 2: return 1 + a->Nodes() + b->Nodes(); default: oops(); } } Expr *Expr::DeepCopy(void) { Expr *n = AllocExpr(); *n = *this; n->marker = 0; int c = n->Children(); if(c > 0) n->a = a->DeepCopy(); if(c > 1) n->b = b->DeepCopy(); return n; } Expr *Expr::DeepCopyWithParamsAsPointers(IdList *firstTry, IdList *thenTry) { Expr *n = AllocExpr(); if(op == PARAM) { // A param that is referenced by its hParam gets rewritten to go // straight in to the parameter table with a pointer, or simply // into a constant if it's already known. Param *p = firstTry->FindByIdNoOops(x.parh); if(!p) p = thenTry->FindById(x.parh); if(p->known) { n->op = CONSTANT; n->x.v = p->val; } else { n->op = PARAM_PTR; n->x.parp = p; } return n; } *n = *this; int c = n->Children(); if(c > 0) n->a = a->DeepCopyWithParamsAsPointers(firstTry, thenTry); if(c > 1) n->b = b->DeepCopyWithParamsAsPointers(firstTry, thenTry); return n; } double Expr::Eval(void) { switch(op) { case PARAM: return SS.GetParam(x.parh)->val; case PARAM_PTR: return (x.parp)->val; case CONSTANT: return x.v; case PLUS: return a->Eval() + b->Eval(); case MINUS: return a->Eval() - b->Eval(); case TIMES: return a->Eval() * b->Eval(); case DIV: return a->Eval() / b->Eval(); case NEGATE: return -(a->Eval()); case SQRT: return sqrt(a->Eval()); case SQUARE: { double r = a->Eval(); return r*r; } case SIN: return sin(a->Eval()); case COS: return cos(a->Eval()); default: oops(); } } Expr *Expr::PartialWrt(hParam p) { Expr *da, *db; switch(op) { case PARAM_PTR: return From(p.v == x.parp->h.v ? 1 : 0); case PARAM: return From(p.v == x.parh.v ? 1 : 0); case CONSTANT: return From(0.0); case PLUS: return (a->PartialWrt(p))->Plus(b->PartialWrt(p)); case MINUS: return (a->PartialWrt(p))->Minus(b->PartialWrt(p)); case TIMES: da = a->PartialWrt(p); db = b->PartialWrt(p); return (a->Times(db))->Plus(b->Times(da)); case DIV: da = a->PartialWrt(p); db = b->PartialWrt(p); return ((da->Times(b))->Minus(a->Times(db)))->Div(b->Square()); case SQRT: return (From(0.5)->Div(a->Sqrt()))->Times(a->PartialWrt(p)); case SQUARE: return (From(2.0)->Times(a))->Times(a->PartialWrt(p)); case NEGATE: return (a->PartialWrt(p))->Negate(); case SIN: return (a->Cos())->Times(a->PartialWrt(p)); case COS: return ((a->Sin())->Times(a->PartialWrt(p)))->Negate(); default: oops(); } } DWORD Expr::ParamsUsed(void) { DWORD r = 0; if(op == PARAM) r |= (1 << (x.parh.v % 31)); if(op == PARAM_PTR) r |= (1 << (x.parp->h.v % 31)); int c = Children(); if(c >= 1) r |= a->ParamsUsed(); if(c >= 2) r |= b->ParamsUsed(); return r; } bool Expr::Tol(double a, double b) { return fabs(a - b) < 0.001; } Expr *Expr::FoldConstants(void) { Expr *n = AllocExpr(); *n = *this; int c = Children(); if(c >= 1) n->a = a->FoldConstants(); if(c >= 2) n->b = b->FoldConstants(); switch(op) { case PARAM_PTR: case PARAM: case CONSTANT: break; case MINUS: case TIMES: case DIV: case PLUS: // If both ops are known, then we can evaluate immediately if(n->a->op == CONSTANT && n->b->op == CONSTANT) { double nv = n->Eval(); n->op = CONSTANT; n->x.v = nv; break; } // x + 0 = 0 + x = x if(op == PLUS && n->b->op == CONSTANT && Tol(n->b->x.v, 0)) { *n = *(n->a); break; } if(op == PLUS && n->a->op == CONSTANT && Tol(n->a->x.v, 0)) { *n = *(n->b); break; } // 1*x = x*1 = x if(op == TIMES && n->b->op == CONSTANT && Tol(n->b->x.v, 1)) { *n = *(n->a); break; } if(op == TIMES && n->a->op == CONSTANT && Tol(n->a->x.v, 1)) { *n = *(n->b); break; } // 0*x = x*0 = 0 if(op == TIMES && n->b->op == CONSTANT && Tol(n->b->x.v, 0)) { n->op = CONSTANT; n->x.v = 0; break; } if(op == TIMES && n->a->op == CONSTANT && Tol(n->a->x.v, 0)) { n->op = CONSTANT; n->x.v = 0; break; } break; case SQRT: case SQUARE: case NEGATE: case SIN: case COS: if(n->a->op == CONSTANT) { double nv = n->Eval(); n->op = CONSTANT; n->x.v = nv; } break; default: oops(); } return n; } void Expr::Substitute(hParam oldh, hParam newh) { if(op == PARAM_PTR) oops(); if(op == PARAM && x.parh.v == oldh.v) { x.parh = newh; } int c = Children(); if(c >= 1) a->Substitute(oldh, newh); if(c >= 2) b->Substitute(oldh, newh); } static char StringBuffer[4096]; void Expr::App(char *s, ...) { va_list f; va_start(f, s); vsprintf(StringBuffer+strlen(StringBuffer), s, f); } char *Expr::Print(void) { if(!this) return "0"; StringBuffer[0] = '\0'; PrintW(); return StringBuffer; } void Expr::PrintW(void) { char c; switch(op) { case PARAM: App("param(%08x)", x.parh.v); break; case PARAM_PTR: App("param(p%08x)", x.parp->h.v); break; case CONSTANT: App("%.3f", x.v); break; case PLUS: c = '+'; goto p; case MINUS: c = '-'; goto p; case TIMES: c = '*'; goto p; case DIV: c = '/'; goto p; p: App("("); a->PrintW(); App(" %c ", c); b->PrintW(); App(")"); break; case NEGATE: App("(- "); a->PrintW(); App(")"); break; case SQRT: App("(sqrt "); a->PrintW(); App(")"); break; case SQUARE: App("(square "); a->PrintW(); App(")"); break; case SIN: App("(sin "); a->PrintW(); App(")"); break; case COS: App("(cos "); a->PrintW(); App(")"); break; default: oops(); } } #define MAX_UNPARSED 1024 static Expr *Unparsed[MAX_UNPARSED]; static int UnparsedCnt, UnparsedP; static Expr *Operands[MAX_UNPARSED]; static int OperandsP; static Expr *Operators[MAX_UNPARSED]; static int OperatorsP; void Expr::PushOperator(Expr *e) { if(OperatorsP >= MAX_UNPARSED) throw "operator stack full!"; Operators[OperatorsP++] = e; } Expr *Expr::TopOperator(void) { if(OperatorsP <= 0) throw "operator stack empty (get top)"; return Operators[OperatorsP-1]; } Expr *Expr::PopOperator(void) { if(OperatorsP <= 0) throw "operator stack empty (pop)"; return Operators[--OperatorsP]; } void Expr::PushOperand(Expr *e) { if(OperandsP >= MAX_UNPARSED) throw "operand stack full"; Operands[OperandsP++] = e; } Expr *Expr::PopOperand(void) { if(OperandsP <= 0) throw "operand stack empty"; return Operands[--OperandsP]; } Expr *Expr::Next(void) { if(UnparsedP >= UnparsedCnt) return NULL; return Unparsed[UnparsedP]; } void Expr::Consume(void) { if(UnparsedP >= UnparsedCnt) throw "no token to consume"; UnparsedP++; } int Expr::Precedence(Expr *e) { if(e->op == ALL_RESOLVED) return -1; // never want to reduce this marker if(e->op != BINARY_OP && e->op != UNARY_OP) oops(); switch(e->x.c) { case 's': case 'n': return 30; case '*': case '/': return 20; case '+': case '-': return 10; default: oops(); } } void Expr::Reduce(void) { Expr *a, *b; Expr *op = PopOperator(); Expr *n; int o; switch(op->x.c) { case '+': o = PLUS; goto c; case '-': o = MINUS; goto c; case '*': o = TIMES; goto c; case '/': o = DIV; goto c; c: b = PopOperand(); a = PopOperand(); n = a->AnyOp(o, b); break; case 'n': n = PopOperand()->Negate(); break; case 's': n = PopOperand()->Sqrt(); break; default: oops(); } PushOperand(n); } void Expr::ReduceAndPush(Expr *n) { while(Precedence(n) <= Precedence(TopOperator())) { Reduce(); } PushOperator(n); } void Expr::Parse(void) { Expr *e = AllocExpr(); e->op = ALL_RESOLVED; PushOperator(e); for(;;) { Expr *n = Next(); if(!n) throw "end of expression unexpected"; if(n->op == CONSTANT) { PushOperand(n); Consume(); } else if(n->op == PAREN && n->x.c == '(') { Consume(); Parse(); n = Next(); if(n->op != PAREN || n->x.c != ')') throw "expected: )"; Consume(); } else if(n->op == UNARY_OP) { PushOperator(n); Consume(); continue; } else if(n->op == BINARY_OP && n->x.c == '-') { // The minus sign is special, because it might be binary or // unary, depending on context. n->op = UNARY_OP; n->x.c = 'n'; PushOperator(n); Consume(); continue; } else { throw "expected expression"; } n = Next(); if(n && n->op == BINARY_OP) { ReduceAndPush(n); Consume(); } else { break; } } while(TopOperator()->op != ALL_RESOLVED) { Reduce(); } PopOperator(); // discard the ALL_RESOLVED marker } void Expr::Lex(char *in) { while(*in) { if(UnparsedCnt >= MAX_UNPARSED) throw "too long"; char c = *in; if(isdigit(c) || c == '.') { // A number literal char number[70]; int len = 0; while((isdigit(*in) || *in == '.') && len < 30) { number[len++] = *in; in++; } number[len++] = '\0'; Expr *e = AllocExpr(); e->op = CONSTANT; e->x.v = atof(number); Unparsed[UnparsedCnt++] = e; } else if(isalpha(c) || c == '_') { char name[70]; int len = 0; while(isforname(*in) && len < 30) { name[len++] = *in; in++; } name[len++] = '\0'; Expr *e = AllocExpr(); if(strcmp(name, "sqrt")==0) { e->op = UNARY_OP; e->x.c = 's'; } else { throw "unknown name"; } Unparsed[UnparsedCnt++] = e; } else if(strchr("+-*/()", c)) { Expr *e = AllocExpr(); e->op = (c == '(' || c == ')') ? PAREN : BINARY_OP; e->x.c = c; Unparsed[UnparsedCnt++] = e; in++; } else if(isspace(c)) { // Ignore whitespace in++; } else { // This is a lex error. throw "unexpected characters"; } } } Expr *Expr::From(char *in) { UnparsedCnt = 0; UnparsedP = 0; OperandsP = 0; OperatorsP = 0; Expr *r; try { Lex(in); Parse(); r = PopOperand(); } catch (char *e) { dbp("exception: parse/lex error: %s", e); return NULL; } return r; }