Mercurial > projects > ldc
view dmd/optimize.c @ 837:331a176c1f4f
Removed error on naked, not fully complete, but I'll be doing more work on it during this Christmas, and some things do work.
Fixed taking delegate of final class method. see mini/delegate3.d.
| author | Tomas Lindquist Olsen <tomas.l.olsen@gmail.com> |
|---|---|
| date | Tue, 09 Dec 2008 14:07:30 +0100 |
| parents | 870652a9af23 |
| children | 330f999ade44 |
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// Compiler implementation of the D programming language // Copyright (c) 1999-2007 by Digital Mars // All Rights Reserved // written by Walter Bright // http://www.digitalmars.com // License for redistribution is by either the Artistic License // in artistic.txt, or the GNU General Public License in gnu.txt. // See the included readme.txt for details. #include <stdio.h> #include <ctype.h> #include <assert.h> #include <math.h> #if __DMC__ #include <complex.h> #endif #include "lexer.h" #include "mtype.h" #include "expression.h" #include "declaration.h" #include "aggregate.h" #include "init.h" #ifdef IN_GCC #include "d-gcc-real.h" /* %% fix? */ extern "C" bool real_isnan (const real_t *); #endif static real_t zero; // work around DMC bug for now /************************************* * If expression is a variable with a const initializer, * return that initializer. */ Expression *fromConstInitializer(Expression *e1) { //printf("fromConstInitializer(%s)\n", e1->toChars()); if (e1->op == TOKvar) { VarExp *ve = (VarExp *)e1; VarDeclaration *v = ve->var->isVarDeclaration(); if (v && v->isConst() && v->init) { Expression *ei = v->init->toExpression(); if (ei && ei->type) e1 = ei; } } return e1; } Expression *Expression::optimize(int result) { //printf("Expression::optimize(result = x%x) %s\n", result, toChars()); return this; } Expression *VarExp::optimize(int result) { if (result & WANTinterpret) { return fromConstInitializer(this); } return this; } Expression *TupleExp::optimize(int result) { for (size_t i = 0; i < exps->dim; i++) { Expression *e = (Expression *)exps->data[i]; e = e->optimize(WANTvalue | (result & WANTinterpret)); exps->data[i] = (void *)e; } return this; } Expression *ArrayLiteralExp::optimize(int result) { if (elements) { for (size_t i = 0; i < elements->dim; i++) { Expression *e = (Expression *)elements->data[i]; e = e->optimize(WANTvalue | (result & WANTinterpret)); elements->data[i] = (void *)e; } } return this; } Expression *AssocArrayLiteralExp::optimize(int result) { assert(keys->dim == values->dim); for (size_t i = 0; i < keys->dim; i++) { Expression *e = (Expression *)keys->data[i]; e = e->optimize(WANTvalue | (result & WANTinterpret)); keys->data[i] = (void *)e; e = (Expression *)values->data[i]; e = e->optimize(WANTvalue | (result & WANTinterpret)); values->data[i] = (void *)e; } return this; } Expression *StructLiteralExp::optimize(int result) { if (elements) { for (size_t i = 0; i < elements->dim; i++) { Expression *e = (Expression *)elements->data[i]; if (!e) continue; e = e->optimize(WANTvalue | (result & WANTinterpret)); elements->data[i] = (void *)e; } } return this; } Expression *TypeExp::optimize(int result) { return this; } Expression *UnaExp::optimize(int result) { e1 = e1->optimize(result); return this; } Expression *NegExp::optimize(int result) { Expression *e; e1 = e1->optimize(result); if (e1->isConst() == 1) { e = Neg(type, e1); } else e = this; return e; } Expression *ComExp::optimize(int result) { Expression *e; e1 = e1->optimize(result); if (e1->isConst() == 1) { e = Com(type, e1); } else e = this; return e; } Expression *NotExp::optimize(int result) { Expression *e; e1 = e1->optimize(result); if (e1->isConst() == 1) { e = Not(type, e1); } else e = this; return e; } Expression *BoolExp::optimize(int result) { Expression *e; e1 = e1->optimize(result); if (e1->isConst() == 1) { e = Bool(type, e1); } else e = this; return e; } Expression *AddrExp::optimize(int result) { Expression *e; //printf("AddrExp::optimize(result = %d) %s\n", result, toChars()); e1 = e1->optimize(result); // Convert &*ex to ex if (e1->op == TOKstar) { Expression *ex; ex = ((PtrExp *)e1)->e1; if (type->equals(ex->type)) e = ex; else { e = ex->copy(); e->type = type; } return e; } #if !IN_LLVM if (e1->op == TOKvar) { VarExp *ve = (VarExp *)e1; if (!ve->var->isOut() && !ve->var->isRef() && !ve->var->isImportedSymbol()) { e = new SymOffExp(loc, ve->var, 0); e->type = type; return e; } } if (e1->op == TOKindex) { // Convert &array[n] to &array+n IndexExp *ae = (IndexExp *)e1; if (ae->e2->op == TOKint64 && ae->e1->op == TOKvar) { integer_t index = ae->e2->toInteger(); VarExp *ve = (VarExp *)ae->e1; if (ve->type->ty == Tsarray && ve->type->next->ty != Tbit && !ve->var->isImportedSymbol()) { TypeSArray *ts = (TypeSArray *)ve->type; integer_t dim = ts->dim->toInteger(); if (index < 0 || index >= dim) error("array index %lld is out of bounds [0..%lld]", index, dim); e = new SymOffExp(loc, ve->var, index * ts->next->size()); e->type = type; return e; } } } #endif return this; } Expression *PtrExp::optimize(int result) { //printf("PtrExp::optimize(result = x%x) %s\n", result, toChars()); e1 = e1->optimize(result); // Convert *&ex to ex if (e1->op == TOKaddress) { Expression *e; Expression *ex; ex = ((AddrExp *)e1)->e1; if (type->equals(ex->type)) e = ex; else { e = ex->copy(); e->type = type; } return e; } // Constant fold *(&structliteral + offset) if (e1->op == TOKadd) { Expression *e; e = Ptr(type, e1); if (e != EXP_CANT_INTERPRET) return e; } return this; } Expression *DotVarExp::optimize(int result) { e1 = e1->optimize(result); // Constant fold structliteral.member if (e1->op == TOKstructliteral) { StructLiteralExp *se = (StructLiteralExp *)e1; VarDeclaration* v; if (v = var->isVarDeclaration()) { Expression *e = se->getField(type, v->offset); if (!e) e = EXP_CANT_INTERPRET; return e; } } return this; } Expression *CallExp::optimize(int result) { Expression *e = this; e1 = e1->optimize(result); if (e1->op == TOKvar && result & WANTinterpret) { FuncDeclaration *fd = ((VarExp *)e1)->var->isFuncDeclaration(); if (fd) { Expression *eresult = fd->interpret(NULL, arguments); if (eresult && eresult != EXP_VOID_INTERPRET) e = eresult; else if (result & WANTinterpret) error("cannot evaluate %s at compile time", toChars()); } } return e; } Expression *CastExp::optimize(int result) { //printf("CastExp::optimize(result = %d) %s\n", result, toChars()); //printf("from %s to %s\n", type->toChars(), to->toChars()); //printf("from %s\n", type->toChars()); //printf("type = %p\n", type); assert(type); enum TOK op1 = e1->op; e1 = e1->optimize(result); if (result & WANTinterpret) e1 = fromConstInitializer(e1); if ((e1->op == TOKstring || e1->op == TOKarrayliteral) && (type->ty == Tpointer || type->ty == Tarray) && type->next->equals(e1->type->next) ) { e1->type = type; return e1; } /* The first test here is to prevent infinite loops */ if (op1 != TOKarrayliteral && e1->op == TOKarrayliteral) return e1->castTo(NULL, to); if (e1->op == TOKnull && (type->ty == Tpointer || type->ty == Tclass)) { e1->type = type; return e1; } if (result & WANTflags && type->ty == Tclass && e1->type->ty == Tclass) { // See if we can remove an unnecessary cast ClassDeclaration *cdfrom; ClassDeclaration *cdto; int offset; cdfrom = e1->type->isClassHandle(); cdto = type->isClassHandle(); if (cdto->isBaseOf(cdfrom, &offset) && offset == 0) { e1->type = type; return e1; } } Expression *e; if (e1->isConst()) { if (e1->op == TOKsymoff) { if (type->size() == e1->type->size() && type->toBasetype()->ty != Tsarray) { e1->type = type; return e1; } return this; } if (to->toBasetype()->ty == Tvoid) e = this; else e = Cast(type, to, e1); } else e = this; return e; } Expression *BinExp::optimize(int result) { //printf("BinExp::optimize(result = %d) %s\n", result, toChars()); e1 = e1->optimize(result); e2 = e2->optimize(result); if (op == TOKshlass || op == TOKshrass || op == TOKushrass) { if (e2->isConst() == 1) { integer_t i2 = e2->toInteger(); d_uns64 sz = e1->type->size() * 8; if (i2 < 0 || i2 > sz) { error("shift assign by %lld is outside the range 0..%"PRIuSIZE, i2, sz); e2 = new IntegerExp(0); } } } return this; } Expression *AddExp::optimize(int result) { Expression *e; //printf("AddExp::optimize(%s)\n", toChars()); e1 = e1->optimize(result); e2 = e2->optimize(result); if (e1->isConst() && e2->isConst()) { if (e1->op == TOKsymoff && e2->op == TOKsymoff) return this; e = Add(type, e1, e2); } else e = this; return e; } Expression *MinExp::optimize(int result) { Expression *e; e1 = e1->optimize(result); e2 = e2->optimize(result); if (e1->isConst() && e2->isConst()) { if (e2->op == TOKsymoff) return this; e = Min(type, e1, e2); } else e = this; return e; } Expression *MulExp::optimize(int result) { Expression *e; //printf("MulExp::optimize(result = %d) %s\n", result, toChars()); e1 = e1->optimize(result); e2 = e2->optimize(result); if (e1->isConst() == 1 && e2->isConst() == 1) { e = Mul(type, e1, e2); } else e = this; return e; } Expression *DivExp::optimize(int result) { Expression *e; //printf("DivExp::optimize(%s)\n", toChars()); e1 = e1->optimize(result); e2 = e2->optimize(result); if (e1->isConst() == 1 && e2->isConst() == 1) { e = Div(type, e1, e2); } else e = this; return e; } Expression *ModExp::optimize(int result) { Expression *e; e1 = e1->optimize(result); e2 = e2->optimize(result); if (e1->isConst() == 1 && e2->isConst() == 1) { e = Mod(type, e1, e2); } else e = this; return e; } Expression *shift_optimize(int result, BinExp *e, Expression *(*shift)(Type *, Expression *, Expression *)) { Expression *ex = e; e->e1 = e->e1->optimize(result); e->e2 = e->e2->optimize(result); if (e->e2->isConst() == 1) { integer_t i2 = e->e2->toInteger(); d_uns64 sz = e->e1->type->size() * 8; if (i2 < 0 || i2 > sz) { error("shift by %lld is outside the range 0..%"PRIuSIZE, i2, sz); e->e2 = new IntegerExp(0); } if (e->e1->isConst() == 1) ex = (*shift)(e->type, e->e1, e->e2); } return ex; } Expression *ShlExp::optimize(int result) { //printf("ShlExp::optimize(result = %d) %s\n", result, toChars()); return shift_optimize(result, this, Shl); } Expression *ShrExp::optimize(int result) { //printf("ShrExp::optimize(result = %d) %s\n", result, toChars()); return shift_optimize(result, this, Shr); } Expression *UshrExp::optimize(int result) { //printf("UshrExp::optimize(result = %d) %s\n", result, toChars()); return shift_optimize(result, this, Ushr); } Expression *AndExp::optimize(int result) { Expression *e; e1 = e1->optimize(result); e2 = e2->optimize(result); if (e1->isConst() == 1 && e2->isConst() == 1) e = And(type, e1, e2); else e = this; return e; } Expression *OrExp::optimize(int result) { Expression *e; e1 = e1->optimize(result); e2 = e2->optimize(result); if (e1->isConst() == 1 && e2->isConst() == 1) e = Or(type, e1, e2); else e = this; return e; } Expression *XorExp::optimize(int result) { Expression *e; e1 = e1->optimize(result); e2 = e2->optimize(result); if (e1->isConst() == 1 && e2->isConst() == 1) e = Xor(type, e1, e2); else e = this; return e; } Expression *CommaExp::optimize(int result) { Expression *e; //printf("CommaExp::optimize(result = %d) %s\n", result, toChars()); e1 = e1->optimize(result & WANTinterpret); e2 = e2->optimize(result); if (!e1 || e1->op == TOKint64 || e1->op == TOKfloat64 || !e1->checkSideEffect(2)) { e = e2; if (e) e->type = type; } else e = this; //printf("-CommaExp::optimize(result = %d) %s\n", result, e->toChars()); return e; } Expression *ArrayLengthExp::optimize(int result) { Expression *e; //printf("ArrayLengthExp::optimize(result = %d) %s\n", result, toChars()); e1 = e1->optimize(WANTvalue | (result & WANTinterpret)); e = this; if (e1->op == TOKstring || e1->op == TOKarrayliteral || e1->op == TOKassocarrayliteral) { e = ArrayLength(type, e1); } return e; } Expression *EqualExp::optimize(int result) { Expression *e; //printf("EqualExp::optimize(result = %x) %s\n", result, toChars()); e1 = e1->optimize(WANTvalue | (result & WANTinterpret)); e2 = e2->optimize(WANTvalue | (result & WANTinterpret)); e = this; Expression *e1 = fromConstInitializer(this->e1); Expression *e2 = fromConstInitializer(this->e2); e = Equal(op, type, e1, e2); if (e == EXP_CANT_INTERPRET) e = this; return e; } Expression *IdentityExp::optimize(int result) { Expression *e; //printf("IdentityExp::optimize(result = %d) %s\n", result, toChars()); e1 = e1->optimize(WANTvalue | (result & WANTinterpret)); e2 = e2->optimize(WANTvalue | (result & WANTinterpret)); e = this; if (this->e1->isConst() && this->e2->isConst()) { e = Identity(op, type, this->e1, this->e2); } return e; } Expression *IndexExp::optimize(int result) { Expression *e; //printf("IndexExp::optimize(result = %d) %s\n", result, toChars()); Expression *e1 = this->e1->optimize(WANTvalue | (result & WANTinterpret)); if (result & WANTinterpret) e1 = fromConstInitializer(e1); e2 = e2->optimize(WANTvalue | (result & WANTinterpret)); e = Index(type, e1, e2); if (e == EXP_CANT_INTERPRET) e = this; return e; } Expression *SliceExp::optimize(int result) { Expression *e; //printf("SliceExp::optimize(result = %d) %s\n", result, toChars()); e = this; e1 = e1->optimize(WANTvalue | (result & WANTinterpret)); if (!lwr) { if (e1->op == TOKstring) { // Convert slice of string literal into dynamic array Type *t = e1->type->toBasetype(); if (t->next) e = e1->castTo(NULL, t->next->arrayOf()); } return e; } if (result & WANTinterpret) e1 = fromConstInitializer(e1); lwr = lwr->optimize(WANTvalue | (result & WANTinterpret)); upr = upr->optimize(WANTvalue | (result & WANTinterpret)); e = Slice(type, e1, lwr, upr); if (e == EXP_CANT_INTERPRET) e = this; return e; } Expression *AndAndExp::optimize(int result) { Expression *e; //printf("AndAndExp::optimize(%d) %s\n", result, toChars()); e1 = e1->optimize(WANTflags | (result & WANTinterpret)); e = this; if (e1->isBool(FALSE)) { e = new CommaExp(loc, e1, new IntegerExp(loc, 0, type)); e->type = type; e = e->optimize(result); } else { e2 = e2->optimize(WANTflags | (result & WANTinterpret)); if (result && e2->type->toBasetype()->ty == Tvoid && !global.errors) error("void has no value"); if (e1->isConst()) { if (e2->isConst()) { int n1 = e1->isBool(1); int n2 = e2->isBool(1); e = new IntegerExp(loc, n1 && n2, type); } else if (e1->isBool(TRUE)) e = new BoolExp(loc, e2, type); } } return e; } Expression *OrOrExp::optimize(int result) { Expression *e; e1 = e1->optimize(WANTflags | (result & WANTinterpret)); e = this; if (e1->isBool(TRUE)) { // Replace with (e1, 1) e = new CommaExp(loc, e1, new IntegerExp(loc, 1, type)); e->type = type; e = e->optimize(result); } else { e2 = e2->optimize(WANTflags | (result & WANTinterpret)); if (result && e2->type->toBasetype()->ty == Tvoid && !global.errors) error("void has no value"); if (e1->isConst()) { if (e2->isConst()) { int n1 = e1->isBool(1); int n2 = e2->isBool(1); e = new IntegerExp(loc, n1 || n2, type); } else if (e1->isBool(FALSE)) e = new BoolExp(loc, e2, type); } } return e; } Expression *CmpExp::optimize(int result) { Expression *e; //printf("CmpExp::optimize() %s\n", toChars()); e1 = e1->optimize(result); e2 = e2->optimize(result); if (e1->isConst() == 1 && e2->isConst() == 1) { e = Cmp(op, type, this->e1, this->e2); } else e = this; return e; } Expression *CatExp::optimize(int result) { Expression *e; //printf("CatExp::optimize(%d) %s\n", result, toChars()); e1 = e1->optimize(result); e2 = e2->optimize(result); e = Cat(type, e1, e2); if (e == EXP_CANT_INTERPRET) e = this; return e; } Expression *CondExp::optimize(int result) { Expression *e; econd = econd->optimize(WANTflags | (result & WANTinterpret)); if (econd->isBool(TRUE)) e = e1->optimize(result); else if (econd->isBool(FALSE)) e = e2->optimize(result); else { e1 = e1->optimize(result); e2 = e2->optimize(result); e = this; } return e; }