/
apply.d
145 lines (123 loc) · 3.6 KB
/
apply.d
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// Compiler implementation of the D programming language
// Copyright (c) 1999-2015 by Digital Mars
// All Rights Reserved
// written by Walter Bright
// http://www.digitalmars.com
// Distributed under the Boost Software License, Version 1.0.
// http://www.boost.org/LICENSE_1_0.txt
module ddmd.apply;
import ddmd.arraytypes;
import ddmd.expression;
import ddmd.visitor;
/**************************************
* An Expression tree walker that will visit each Expression e in the tree,
* in depth-first evaluation order, and call fp(e,param) on it.
* fp() signals whether the walking continues with its return value:
* Returns:
* 0 continue
* 1 done
* It's a bit slower than using virtual functions, but more encapsulated and less brittle.
* Creating an iterator for this would be much more complex.
*/
extern (C++) final class PostorderExpressionVisitor : StoppableVisitor
{
alias visit = super.visit;
public:
StoppableVisitor v;
extern (D) this(StoppableVisitor v)
{
this.v = v;
}
bool doCond(Expression e)
{
if (!stop && e)
e.accept(this);
return stop;
}
bool doCond(Expressions* e)
{
if (!e)
return false;
for (size_t i = 0; i < e.dim && !stop; i++)
doCond((*e)[i]);
return stop;
}
bool applyTo(Expression e)
{
e.accept(v);
stop = v.stop;
return true;
}
override void visit(Expression e)
{
applyTo(e);
}
override void visit(NewExp e)
{
//printf("NewExp::apply(): %s\n", toChars());
doCond(e.thisexp) || doCond(e.newargs) || doCond(e.arguments) || applyTo(e);
}
override void visit(NewAnonClassExp e)
{
//printf("NewAnonClassExp::apply(): %s\n", toChars());
doCond(e.thisexp) || doCond(e.newargs) || doCond(e.arguments) || applyTo(e);
}
override void visit(UnaExp e)
{
doCond(e.e1) || applyTo(e);
}
override void visit(BinExp e)
{
doCond(e.e1) || doCond(e.e2) || applyTo(e);
}
override void visit(AssertExp e)
{
//printf("CallExp::apply(apply_fp_t fp, void *param): %s\n", toChars());
doCond(e.e1) || doCond(e.msg) || applyTo(e);
}
override void visit(CallExp e)
{
//printf("CallExp::apply(apply_fp_t fp, void *param): %s\n", toChars());
doCond(e.e1) || doCond(e.arguments) || applyTo(e);
}
override void visit(ArrayExp e)
{
//printf("ArrayExp::apply(apply_fp_t fp, void *param): %s\n", toChars());
doCond(e.e1) || doCond(e.arguments) || applyTo(e);
}
override void visit(SliceExp e)
{
doCond(e.e1) || doCond(e.lwr) || doCond(e.upr) || applyTo(e);
}
override void visit(ArrayLiteralExp e)
{
doCond(e.basis) || doCond(e.elements) || applyTo(e);
}
override void visit(AssocArrayLiteralExp e)
{
doCond(e.keys) || doCond(e.values) || applyTo(e);
}
override void visit(StructLiteralExp e)
{
if (e.stageflags & stageApply)
return;
int old = e.stageflags;
e.stageflags |= stageApply;
doCond(e.elements) || applyTo(e);
e.stageflags = old;
}
override void visit(TupleExp e)
{
doCond(e.e0) || doCond(e.exps) || applyTo(e);
}
override void visit(CondExp e)
{
doCond(e.econd) || doCond(e.e1) || doCond(e.e2) || applyTo(e);
}
}
extern (C++) bool walkPostorder(Expression e, StoppableVisitor v)
{
scope PostorderExpressionVisitor pv = new PostorderExpressionVisitor(v);
e.accept(pv);
return v.stop;
}