44

I was calling a method that accepts Expression<Func<bool>>.

As part of the expression I was passing:

this.Bottom == base.lineView.Top

The compiler gave me an error that

an expression tree may not contain a base access

So I simply changed it to

this.Bottom == this.lineView.Top

because the member was protected anyway and now it works.

But this error really got me: why the heck would this base be a problem? Especially if using this instead will work but syntactically be the same result (same variable gets accessed)?

1
  • 3
    Interesting question. However, generally I never use the base keyword without reason. That is I only use it if the inherited member in this type is either overridden or hidden by a new member with the same name. Maybe for that reason I never ran into this issue with base in expression trees. – Jeppe Stig Nielsen Mar 8 '14 at 20:04
43

Looking at the System.Linq.Expressions.Expression documentation, I don't think there's an expression type which represents "base member access". Don't forget that even though in your case it meant the same as just this, in other cases it wouldn't:

class Test
{
    void Foo()
    {
        Expression<Func<string>> baseString = () => base.ToString();
    }

    public override string ToString()
    {
        return "overridden value";
    }
}

Here that would represent a non-virtual call to Object.ToString() (for this). I can't see how that would be represented in an expression tree, hence the error.

Now that leads on to the obvious question of why there isn't a representation of non-virtual base member invocation in expression trees - I'm afraid I can't answer that part... although I can see that if you could build that expression programmatically, that would allow you to bypass normal polymorphism from the outside instead of only from inside the class itself (which is the normal case). That may be the reason. (Admittedly there are other ways of calling methods non-virtually, but that's a different matter, and I dare say there are situations where expression trees are "trusted" but other code isn't.)

5
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    Hey Jon, your conjecture is correct. See my answer for details. – Eric Lippert Mar 8 '14 at 20:15
  • 3
    @EricLippert: Great - it's always good to get confirmation :) – Jon Skeet Mar 8 '14 at 21:23
  • A perfect situation. Interesting question with great answers, thanks. My follow-up question. Are there any non-reflection/non-reflection.emit other ways to bypass polymorphism? – Piotr Zierhoffer Mar 9 '14 at 13:49
  • 2
    @PiotrZierhoffer: This is a question-and-answer site. If you have a new question, post a new question. That way (1) many people will try to answer it, and (2) it will more likely be found by people searching for answers to that question. – Eric Lippert Mar 9 '14 at 15:56
  • Sure thing. But I've just expected a "no". ;-) – Piotr Zierhoffer Mar 9 '14 at 16:46
40

Jon's answer is correct. I want to follow up on Jon's comment:

I can see that if you could build that expression programmatically, that would allow you to bypass normal polymorphism from the outside instead of only from inside the class itself (which is the normal case). That may be the reason

Suppose you have

public abstract class B // Prevent instantiation
{
    internal B() {} // Prevent subclassing outside the assembly. 
    public virtual void Dangerous() { ... } 
}
public sealed class D : B 
{ 
  public override void Dangerous() 
  { 
    if (!Allowed()) throw whatever;
    base.Dangerous();
  }

There should be no way for partially trusted code with a D in hand to call B.Dangerous on the instance of D without doing the safety check in D.Dangerous.

The CLR verifier therefore restricts you from performing a non-virtual invocation (a base invocation is of course non-virtual) on a virtual method from outside the class hierarchy. In fact, it goes even farther; you can't even perform that from a class nested within D ! (Of course if your program is granted the right to skip verification then you can do whatever you want; you can dereference arbitrary pointers to memory in unverifiable code which is a lot worse than making a static call on a virtual method.)

When we were designing expression trees we didn't want to deal with this messy security problem. The easiest thing to do was to simply make the whole thing illegal.

There were a number of other security problems with expression trees that could not so easily be solved, but those are a topic for another day.

2
  • I'll confess that in some situations I've made calls to private members via reflection. Indeed this is why we're told "private" is for your own protection even though it can be circumvented by consenting, sober adults. But now it appears calls to an overridden member may be entirely impossible under any circumstance. Is this the case? – N Jones Mar 12 '14 at 3:12
  • 1
    @NJones: I should have been more clear. The CLR verifier restricts you from making such a call by failing to verify the method with the call. If your program is granted skip-verification permission then it can do so since the verifier doesn't run in the first place. – Eric Lippert Mar 12 '14 at 5:10

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