#include "c.h" #include #define foldcnst(TYPE,VAR,OP) \ if (l->op == CNST+TYPE && r->op == CNST+TYPE) \ return cnsttree(ty, l->u.v.VAR OP r->u.v.VAR) #define commute(L,R) \ if (generic(R->op) == CNST && generic(L->op) != CNST) \ do { Tree t = L; L = R; R = t; } while(0) #define xfoldcnst(TYPE,VAR,OP,FUNC)\ if (l->op == CNST+TYPE && r->op == CNST+TYPE\ && FUNC(l->u.v.VAR,r->u.v.VAR,\ ty->u.sym->u.limits.min.VAR,\ ty->u.sym->u.limits.max.VAR, needconst)) \ return cnsttree(ty, l->u.v.VAR OP r->u.v.VAR) #define xcvtcnst(FTYPE,SRC,DST,VAR,EXPR) \ if (l->op == CNST+FTYPE) do {\ if (!explicitCast\ && ((SRC) < DST->u.sym->u.limits.min.VAR || (SRC) > DST->u.sym->u.limits.max.VAR))\ warning("overflow in converting constant expression from `%t' to `%t'\n", l->type, DST);\ if (needconst\ || !((SRC) < DST->u.sym->u.limits.min.VAR || (SRC) > DST->u.sym->u.limits.max.VAR))\ return cnsttree(ty, (EXPR)); } while(0) #define identity(X,Y,TYPE,VAR,VAL) \ if (X->op == CNST+TYPE && X->u.v.VAR == VAL) return Y #define zerofield(OP,TYPE,VAR) \ if (l->op == FIELD \ && r->op == CNST+TYPE && r->u.v.VAR == 0)\ return eqtree(OP, bittree(BAND, l->kids[0],\ cnsttree(unsignedtype, \ (unsigned long)fieldmask(l->u.field)<u.field))), r) #define cfoldcnst(TYPE,VAR,OP) \ if (l->op == CNST+TYPE && r->op == CNST+TYPE) \ return cnsttree(inttype, (long)(l->u.v.VAR OP r->u.v.VAR)) #define foldaddp(L,R,RTYPE,VAR) \ if (L->op == CNST+P && R->op == CNST+RTYPE) { \ Tree e = tree(CNST+P, ty, NULL, NULL);\ e->u.v.p = (char *)L->u.v.p + R->u.v.VAR;\ return e; } #define ufoldcnst(TYPE,EXP) if (l->op == CNST+TYPE) return EXP #define sfoldcnst(OP) \ if (l->op == CNST+U && r->op == CNST+I \ && r->u.v.i >= 0 && r->u.v.i < 8*l->type->size) \ return cnsttree(ty, (unsigned long)(l->u.v.u OP r->u.v.i)) #define geu(L,R,V) \ if (R->op == CNST+U && R->u.v.u == 0) do { \ warning("result of unsigned comparison is constant\n"); \ return tree(RIGHT, inttype, root(L), cnsttree(inttype, (long)(V))); } while(0) #define idempotent(OP) if (l->op == OP) return l->kids[0] int needconst; int explicitCast; static int addi(long x, long y, long min, long max, int needconst) { int cond = x == 0 || y == 0 || x < 0 && y < 0 && x >= min - y || x < 0 && y > 0 || x > 0 && y < 0 || x > 0 && y > 0 && x <= max - y; if (!cond && needconst) { warning("overflow in constant expression\n"); cond = 1; } return cond; } static int addd(double x, double y, double min, double max, int needconst) { int cond = x == 0 || y == 0 || x < 0 && y < 0 && x >= min - y || x < 0 && y > 0 || x > 0 && y < 0 || x > 0 && y > 0 && x <= max - y; if (!cond && needconst) { warning("overflow in constant expression\n"); cond = 1; } return cond; } static Tree addrtree(Tree e, long n, Type ty) { Symbol p = e->u.sym, q; if (p->scope == GLOBAL || p->sclass == STATIC || p->sclass == EXTERN) NEW0(q, PERM); else NEW0(q, FUNC); q->name = stringd(genlabel(1)); q->sclass = p->sclass; q->scope = p->scope; assert(isptr(ty) || isarray(ty)); q->type = isptr(ty) ? ty->type : ty; q->temporary = p->temporary; q->generated = p->generated; q->addressed = p->addressed; q->computed = 1; q->defined = 1; q->ref = 1; if (p->scope == GLOBAL || p->sclass == STATIC || p->sclass == EXTERN) { if (p->sclass == AUTO) q->sclass = STATIC; (*IR->address)(q, p, n); } else { Code cp; addlocal(p); cp = code(Address); cp->u.addr.sym = q; cp->u.addr.base = p; cp->u.addr.offset = n; } e = tree(e->op, ty, NULL, NULL); e->u.sym = q; return e; } /* div[id] - return 1 if min <= x/y <= max, 0 otherwise */ static int divi(long x, long y, long min, long max, int needconst) { int cond = y != 0 && !(x == min && y == -1); if (!cond && needconst) { warning("overflow in constant expression\n"); cond = 1; } return cond; } static int divd(double x, double y, double min, double max, int needconst) { int cond; if (x < 0) x = -x; if (y < 0) y = -y; cond = y != 0 && !(y < 1 && x > max*y); if (!cond && needconst) { warning("overflow in constant expression\n"); cond = 1; } return cond; } /* mul[id] - return 1 if min <= x*y <= max, 0 otherwise */ static int muli(long x, long y, long min, long max, int needconst) { int cond = x > -1 && x <= 1 || y > -1 && y <= 1 || x < 0 && y < 0 && -x <= max/-y || x < 0 && y > 0 && x >= min/y || x > 0 && y < 0 && y >= min/x || x > 0 && y > 0 && x <= max/y; if (!cond && needconst) { warning("overflow in constant expression\n"); cond = 1; } return cond; } static int muld(double x, double y, double min, double max, int needconst) { int cond = x >= -1 && x <= 1 || y >= -1 && y <= 1 || x < 0 && y < 0 && -x <= max/-y || x < 0 && y > 0 && x >= min/y || x > 0 && y < 0 && y >= min/x || x > 0 && y > 0 && x <= max/y; if (!cond && needconst) { warning("overflow in constant expression\n"); cond = 1; } return cond; } /* sub[id] - return 1 if min <= x-y <= max, 0 otherwise */ static int subi(long x, long y, long min, long max, int needconst) { return addi(x, -y, min, max, needconst); } static int subd(double x, double y, double min, double max, int needconst) { return addd(x, -y, min, max, needconst); } Tree constexpr(int tok) { Tree p; needconst++; p = expr1(tok); needconst--; return p; } int intexpr(int tok, int n) { Tree p = constexpr(tok); needconst++; if (p->op == CNST+I || p->op == CNST+U) n = cast(p, inttype)->u.v.i; else error("integer expression must be constant\n"); needconst--; return n; } Tree simplify(int op, Type ty, Tree l, Tree r) { int n; Tree p; if (optype(op) == 0) op = mkop(op, ty); switch (op) { case ADD+U: foldcnst(U,u,+); commute(r,l); identity(r,l,U,u,0); break; case ADD+I: xfoldcnst(I,i,+,addi); commute(r,l); identity(r,l,I,i,0); break; case CVI+I: xcvtcnst(I,l->u.v.i,ty,i,(long)extend(l->u.v.i,ty)); break; case CVU+I: if (l->op == CNST+U) { if (!explicitCast && l->u.v.u > ty->u.sym->u.limits.max.i) warning("overflow in converting constant expression from `%t' to `%t'\n", l->type, ty); if (needconst || !(l->u.v.u > ty->u.sym->u.limits.max.i)) return cnsttree(ty, (long)extend(l->u.v.u,ty)); } break; case CVP+U: xcvtcnst(P,(unsigned long)l->u.v.p,ty,u,(unsigned long)l->u.v.p); break; case CVU+P: xcvtcnst(U,(void*)l->u.v.u,ty,p,(void*)l->u.v.u); break; case CVP+P: xcvtcnst(P,l->u.v.p,ty,p,l->u.v.p); break; case CVI+U: xcvtcnst(I,l->u.v.i,ty,u,((unsigned long)l->u.v.i)&ones(8*ty->size)); break; case CVU+U: xcvtcnst(U,l->u.v.u,ty,u,l->u.v.u&ones(8*ty->size)); break; case CVI+F: xcvtcnst(I,l->u.v.i,ty,d,(long double)l->u.v.i); case CVU+F: xcvtcnst(U,l->u.v.u,ty,d,(long double)l->u.v.u); break; case CVF+I: xcvtcnst(F,l->u.v.d,ty,i,(long)l->u.v.d); break; case CVF+F: { float d; if (l->op == CNST+F) if (l->u.v.d < ty->u.sym->u.limits.min.d) d = ty->u.sym->u.limits.min.d; else if (l->u.v.d > ty->u.sym->u.limits.max.d) d = ty->u.sym->u.limits.max.d; else d = l->u.v.d; xcvtcnst(F,l->u.v.d,ty,d,(long double)d); break; } case BAND+U: foldcnst(U,u,&); commute(r,l); identity(r,l,U,u,ones(8*ty->size)); if (r->op == CNST+U && r->u.v.u == 0) return tree(RIGHT, ty, root(l), cnsttree(ty, 0UL)); break; case BAND+I: foldcnst(I,i,&); commute(r,l); identity(r,l,I,i,ones(8*ty->size)); if (r->op == CNST+I && r->u.v.u == 0) return tree(RIGHT, ty, root(l), cnsttree(ty, 0L)); break; case MUL+U: commute(l,r); if (l->op == CNST+U && (n = ispow2(l->u.v.u)) != 0) return simplify(LSH, ty, r, cnsttree(inttype, (long)n)); foldcnst(U,u,*); identity(r,l,U,u,1); break; case NE+I: cfoldcnst(I,i,!=); commute(r,l); zerofield(NE,I,i); break; case EQ+I: cfoldcnst(I,i,==); commute(r,l); zerofield(EQ,I,i); break; case ADD+P: foldaddp(l,r,I,i); foldaddp(l,r,U,u); foldaddp(r,l,I,i); foldaddp(r,l,U,u); commute(r,l); identity(r,retype(l,ty),I,i,0); identity(r,retype(l,ty),U,u,0); if (isaddrop(l->op) && (r->op == CNST+I && r->u.v.i <= longtype->u.sym->u.limits.max.i && r->u.v.i >= longtype->u.sym->u.limits.min.i || r->op == CNST+U && r->u.v.u <= longtype->u.sym->u.limits.max.i)) return addrtree(l, cast(r, longtype)->u.v.i, ty); if (l->op == ADD+P && isaddrop(l->kids[1]->op) && (r->op == CNST+I && r->u.v.i <= longtype->u.sym->u.limits.max.i && r->u.v.i >= longtype->u.sym->u.limits.min.i || r->op == CNST+U && r->u.v.u <= longtype->u.sym->u.limits.max.i)) return simplify(ADD+P, ty, l->kids[0], addrtree(l->kids[1], cast(r, longtype)->u.v.i, ty)); if ((l->op == ADD+I || l->op == SUB+I) && l->kids[1]->op == CNST+I && isaddrop(r->op)) return simplify(ADD+P, ty, l->kids[0], simplify(generic(l->op)+P, ty, r, l->kids[1])); if (l->op == ADD+P && generic(l->kids[1]->op) == CNST && generic(r->op) == CNST) return simplify(ADD+P, ty, l->kids[0], simplify(ADD, l->kids[1]->type, l->kids[1], r)); if (l->op == ADD+I && generic(l->kids[1]->op) == CNST && r->op == ADD+P && generic(r->kids[1]->op) == CNST) return simplify(ADD+P, ty, l->kids[0], simplify(ADD+P, ty, r->kids[0], simplify(ADD, r->kids[1]->type, l->kids[1], r->kids[1]))); if (l->op == RIGHT && l->kids[1]) return tree(RIGHT, ty, l->kids[0], simplify(ADD+P, ty, l->kids[1], r)); else if (l->op == RIGHT && l->kids[0]) return tree(RIGHT, ty, simplify(ADD+P, ty, l->kids[0], r), NULL); break; case ADD+F: xfoldcnst(F,d,+,addd); commute(r,l); break; case AND+I: op = AND; ufoldcnst(I,l->u.v.i ? cond(r) : l); /* 0&&r => 0, 1&&r => r */ break; case OR+I: op = OR; /* 0||r => r, 1||r => 1 */ ufoldcnst(I,l->u.v.i ? cnsttree(ty, 1L) : cond(r)); break; case BCOM+I: ufoldcnst(I,cnsttree(ty, (long)extend((~l->u.v.i)&ones(8*ty->size), ty))); idempotent(BCOM+U); break; case BCOM+U: ufoldcnst(U,cnsttree(ty, (unsigned long)((~l->u.v.u)&ones(8*ty->size)))); idempotent(BCOM+U); break; case BOR+U: foldcnst(U,u,|); commute(r,l); identity(r,l,U,u,0); break; case BOR+I: foldcnst(I,i,|); commute(r,l); identity(r,l,I,i,0); break; case BXOR+U: foldcnst(U,u,^); commute(r,l); identity(r,l,U,u,0); break; case BXOR+I: foldcnst(I,i,^); commute(r,l); identity(r,l,I,i,0); break; case DIV+F: xfoldcnst(F,d,/,divd); break; case DIV+I: identity(r,l,I,i,1); if (r->op == CNST+I && r->u.v.i == 0 || l->op == CNST+I && l->u.v.i == ty->u.sym->u.limits.min.i && r->op == CNST+I && r->u.v.i == -1) break; xfoldcnst(I,i,/,divi); break; case DIV+U: identity(r,l,U,u,1); if (r->op == CNST+U && r->u.v.u == 0) break; if (r->op == CNST+U && (n = ispow2(r->u.v.u)) != 0) return simplify(RSH, ty, l, cnsttree(inttype, (long)n)); foldcnst(U,u,/); break; case EQ+F: cfoldcnst(F,d,==); commute(r,l); break; case EQ+U: cfoldcnst(U,u,==); commute(r,l); zerofield(EQ,U,u); break; case GE+F: cfoldcnst(F,d,>=); break; case GE+I: cfoldcnst(I,i,>=); break; case GE+U: geu(l,r,1); /* l >= 0 => (l,1) */ cfoldcnst(U,u,>=); if (l->op == CNST+U && l->u.v.u == 0) /* 0 >= r => r == 0 */ return eqtree(EQ, r, l); break; case GT+F: cfoldcnst(F,d, >); break; case GT+I: cfoldcnst(I,i, >); break; case GT+U: geu(r,l,0); /* 0 > r => (r,0) */ cfoldcnst(U,u, >); if (r->op == CNST+U && r->u.v.u == 0) /* l > 0 => l != 0 */ return eqtree(NE, l, r); break; case LE+F: cfoldcnst(F,d,<=); break; case LE+I: cfoldcnst(I,i,<=); break; case LE+U: geu(r,l,1); /* 0 <= r => (r,1) */ cfoldcnst(U,u,<=); if (r->op == CNST+U && r->u.v.u == 0) /* l <= 0 => l == 0 */ return eqtree(EQ, l, r); break; case LSH+I: identity(r,l,I,i,0); if (l->op == CNST+I && r->op == CNST+I && r->u.v.i >= 0 && r->u.v.i < 8*l->type->size && muli(l->u.v.i, 1<u.v.i, ty->u.sym->u.limits.min.i, ty->u.sym->u.limits.max.i, needconst)) return cnsttree(ty, (long)(l->u.v.i<u.v.i)); if (r->op == CNST+I && (r->u.v.i >= 8*ty->size || r->u.v.i < 0)) { warning("shifting an `%t' by %d bits is undefined\n", ty, r->u.v.i); break; } break; case LSH+U: identity(r,l,I,i,0); sfoldcnst(<<); if (r->op == CNST+I && (r->u.v.i >= 8*ty->size || r->u.v.i < 0)) { warning("shifting an `%t' by %d bits is undefined\n", ty, r->u.v.i); break; } break; case LT+F: cfoldcnst(F,d, <); break; case LT+I: cfoldcnst(I,i, <); break; case LT+U: geu(l,r,0); /* l < 0 => (l,0) */ cfoldcnst(U,u, <); if (l->op == CNST+U && l->u.v.u == 0) /* 0 < r => r != 0 */ return eqtree(NE, r, l); break; case MOD+I: if (r->op == CNST+I && r->u.v.i == 1) /* l%1 => (l,0) */ return tree(RIGHT, ty, root(l), cnsttree(ty, 0L)); if (r->op == CNST+I && r->u.v.i == 0 || l->op == CNST+I && l->u.v.i == ty->u.sym->u.limits.min.i && r->op == CNST+I && r->u.v.i == -1) break; xfoldcnst(I,i,%,divi); break; case MOD+U: if (r->op == CNST+U && ispow2(r->u.v.u)) /* l%2^n => l&(2^n-1) */ return bittree(BAND, l, cnsttree(ty, r->u.v.u - 1)); if (r->op == CNST+U && r->u.v.u == 0) break; foldcnst(U,u,%); break; case MUL+F: xfoldcnst(F,d,*,muld); commute(l,r); break; case MUL+I: commute(l,r); xfoldcnst(I,i,*,muli); if (l->op == CNST+I && r->op == ADD+I && r->kids[1]->op == CNST+I) /* c1*(x + c2) => c1*x + c1*c2 */ return simplify(ADD, ty, simplify(MUL, ty, l, r->kids[0]), simplify(MUL, ty, l, r->kids[1])); if (l->op == CNST+I && r->op == SUB+I && r->kids[1]->op == CNST+I) /* c1*(x - c2) => c1*x - c1*c2 */ return simplify(SUB, ty, simplify(MUL, ty, l, r->kids[0]), simplify(MUL, ty, l, r->kids[1])); if (l->op == CNST+I && l->u.v.i > 0 && (n = ispow2(l->u.v.i)) != 0) /* 2^n * r => r<u.v.d)); idempotent(NEG+F); break; case NEG+I: if (l->op == CNST+I) { if (needconst && l->u.v.i == ty->u.sym->u.limits.min.i) warning("overflow in constant expression\n"); if (needconst || l->u.v.i != ty->u.sym->u.limits.min.i) return cnsttree(ty, -l->u.v.i); } idempotent(NEG+I); break; case NOT+I: op = NOT; ufoldcnst(I,cnsttree(ty, !l->u.v.i)); break; case RSH+I: identity(r,l,I,i,0); if (l->op == CNST+I && r->op == CNST+I && r->u.v.i >= 0 && r->u.v.i < 8*l->type->size) { long n = l->u.v.i>>r->u.v.i; if (l->u.v.i < 0) n |= ~0UL<<(8*l->type->size - r->u.v.i); return cnsttree(ty, n); } if (r->op == CNST+I && (r->u.v.i >= 8*ty->size || r->u.v.i < 0)) { warning("shifting an `%t' by %d bits is undefined\n", ty, r->u.v.i); break; } break; case RSH+U: identity(r,l,I,i,0); sfoldcnst(>>); if (r->op == CNST+I && (r->u.v.i >= 8*ty->size || r->u.v.i < 0)) { warning("shifting an `%t' by %d bits is undefined\n", ty, r->u.v.i); break; } break; case SUB+F: xfoldcnst(F,d,-,subd); break; case SUB+I: xfoldcnst(I,i,-,subi); identity(r,l,I,i,0); break; case SUB+U: foldcnst(U,u,-); identity(r,l,U,u,0); break; case SUB+P: if (l->op == CNST+P && r->op == CNST+P) return cnsttree(ty, (long)((char *)l->u.v.p - (char *)r->u.v.p)); if (r->op == CNST+I || r->op == CNST+U) return simplify(ADD, ty, l, cnsttree(inttype, r->op == CNST+I ? -r->u.v.i : -(long)r->u.v.u)); if (isaddrop(l->op) && r->op == ADD+I && r->kids[1]->op == CNST+I) /* l - (x + c) => l-c - x */ return simplify(SUB, ty, simplify(SUB, ty, l, r->kids[1]), r->kids[0]); break; default:assert(0); } return tree(op, ty, l, r); } /* ispow2 - if u > 1 && u == 2^n, return n, otherwise return 0 */ int ispow2(unsigned long u) { int n; if (u > 1 && (u&(u-1)) == 0) for (n = 0; u; u >>= 1, n++) if (u&1) return n; return 0; }