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There's been some debate going on in this question about whether the following code is legal C++:

std::list<item*>::iterator i = items.begin();
while (i != items.end())
{
    bool isActive = (*i)->update();
    if (!isActive)
    {
        items.erase(i++);  // *** Is this undefined behavior? ***
    }
    else
    {
        other_code_involving(*i);
        ++i;
    }
}

The problem here is that erase() will invalidate the iterator in question. If that happens before i++ is evaluated, then incrementing i like that is technically undefined behavior, even if it appears to work with a particular compiler. One side of the debate says that all function arguments are fully evaluated before the function is called. The other side says, "the only guarantees are that i++ will happen before the next statement and after i++ is used. Whether that is before erase(i++) is invoked or afterwards is compiler dependent."

I opened this question to hopefully settle that debate.

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2  
Love the question. There's something fascinating about a language where even such trivial code as f(i++) can spark long debates about the semantics, with multiple cross-references to the standard... :) –  jalf Feb 28 '09 at 16:20
    
You are really mixing two questions here: (1) whether it is generally legal to use the postincrement operator in a function call argument, and (2) whether a specific use will produce the intended result. It's always legal, but whether it will produce the desired result depends on the specific case. –  Andrew Medico Feb 28 '09 at 16:31
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8 Answers

up vote 37 down vote accepted

Quoth the C++ standard 1.9.16:

When calling a function (whether or not the function is inline), every value computation and side effect associated with any argument expression, or with the postfix expression designating the called function, is sequenced before execution of every expression or statement in the body of the called function. (Note: Value computations and side effects associated with the different argument expressions are unsequenced.)

So it would seem to me that this code:

foo(i++);

is perfectly legal. It will increment i and then call foo with the previous value of i. However, this code:

foo(i++, i++);

yields undefined behavior because paragraph 1.9.16 also says:

If a side effect on a scalar object is unsequenced relative to either another side effect on the same scalar object or a value computation using the value of the same scalar object, the behavior is undefined.

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It ain't undefined here. It will do both, but in a undefined order. –  Migol Feb 28 '09 at 15:35
2  
The second one is undefined, yeah. Modifying a variable twice in the same expression is undefined, not just the order in which they're evaluated. In practical terms, both may increment the original i, rather than the one updated by the other increment. Nothing wrong with the first one. –  jalf Feb 28 '09 at 15:47
    
+1 jalf. (Pad, pad...) –  j_random_hacker Feb 28 '09 at 15:48
    
Wouldn't foo(++i, ++i) be more undefined ? –  Benoît Mar 1 '09 at 9:55
6  
How can it be "more undefined"? –  Ed S. Mar 1 '09 at 10:55
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To build on Kristo's answer,

foo(i++, i++);

yields undefined behavior because the order that function arguments are evaluated is undefined (and in the more general case because if you read a variable twice in an expression where you also write it, the result is undefined). You don't know which argument will be incremented first.

int i = 1;
foo(i++, i++);

might result in a function call of

foo(2, 1);

or

foo(1, 2);

or even

foo(1, 1);

Run the following to see what happens on your platform:

#include <iostream>

using namespace std;

void foo(int a, int b)
{
    cout << "a: " << a << endl;
    cout << "b: " << b << endl;
}

int main()
{
    int i = 1;
    foo(i++, i++);
}

On my machine I get

$ ./a.out
a: 2
b: 1

every time, but this code is not portable, so I would expect to see different results with different compilers.

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It might also result in foo(2,2). You don't know which value of i each increment uses, and it might use the original value in both. In theory, it could result in foo(42, -263) as well, but we're probably not likely to see that particular result from a real world compiler. ;) –  jalf Feb 28 '09 at 15:50
    
oh wait, aren't we off by one in all the examples? Shouldn't it be foo(1,1), foo(1,2) and foo(2,1)? –  jalf Feb 28 '09 at 15:51
    
Are you sure? Won't the function call always be foo(1,1)? The question is what value i will have afterwards. –  Steve Rowe Feb 28 '09 at 15:52
    
@Steve Rowe: Suppose the leftmost incrmeent is evaluated first, yielding 1 as the first argument to the function, and setting i to 2. Then the rightmost increment is evaluated, yielding 2 as the second argument, and setting the final i to 3. Then foo gets called with (1,2), and i=3 afterwards. –  jalf Feb 28 '09 at 16:02
    
@Bill: No, they don't need to have different values, It's undefined (research.att.com/~bs/bs_faq2.html#evaluation-order). There's no guarantee that they'll be evaluated sequentially (or at all, if we want to be pedantic). –  jalf Feb 28 '09 at 16:16
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The standard says the side effect happens before the call, so the code is the same as:

std::list<item*>::iterator i_before = i;

i = i_before + 1;

items.erase(i_before);

rather than being:

std::list<item*>::iterator i_before = i;

items.erase(i);

i = i_before + 1;

So it is safe in this case, because list.erase() specifically doesn't invalidate any iterators other than the one erased.

That said, it's bad style - the erase function for all containers returns the next iterator specifically so you don't have to worry about invalidating iterators due to reallocation, so the idiomatic code:

i = items.erase(i);

will be safe for lists, and will also be safe for vectors, deques and any other sequence container should you want to change your storage.

You also wouldn't get the original code to compile without warnings - you'd have to write

(void)items.erase(i++);

to avoid a warning about an unused return, which would be a big clue that you're doing something odd.

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erase() returns an iterator for sequence containers, but not for associative containers like set and map. –  bk1e Feb 28 '09 at 17:36
    
Added 'sequence' to the post. Some implementations do have the return, but it's not standard. –  Pete Kirkham Feb 28 '09 at 17:46
    
In the first example, it should be items.erase(i_before); –  jmucchiello Mar 1 '09 at 9:47
    
Surely you'd need to set warning levels very high to be warned about unused return values? Have to confess I've never bothered with that -- it requires prepending "(void)" to a helluva lot of perfectly valid code. Or am I missing something? –  j_random_hacker Mar 3 '09 at 10:31
    
Probably not that much valid code; I don't find in onerous and have found otherwise hidden bugs due to it. –  Pete Kirkham Mar 3 '09 at 11:03
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It's perfectly OK. The value passed would be the value of "i" before the increment.

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To build on MarkusQ's answer: ;)

Or rather, Bill's comment to it:

(Edit: Aw, the comment is gone again... Oh well)

They're allowed to be evaluated in parallel. Whether or not it happens in practice is technically speaking irrelevant.

You don't need thread parallelism for this to occur though, just evaluate the first step of both (take the value of i) before the second (increment i). Perfectly legal, and some compilers may consider it more efficient than fully evaluating one i++ before starting on the second.

In fact, I'd expect it to be a common optimization. Look at it from an instruction scheduling point of view. You have the following you need to evaluate:

  1. Take the value of i for the right argument
  2. Increment i in the right argument
  3. Take the value of i for the left argument
  4. Increment i in the left argument

But there's really no dependency between the left and the right argument. Argument evaluation happens in an unspecified order, and need not be done sequentially either (which is why new() in function arguments is usually a memory leak, even when wrapped in a smart pointer) It's also undefined what happens when you modify the same variable twice in the same expression. We do have a dependency between 1 and 2, however, and between 3 and 4. So why would the compiler wait for 2 to complete before computing 3? That introduces added latency, and it'll take even longer than necessary before 4 becomes available. Assuming there's a 1 cycle latency between each, it'll take 3 cycles from 1 is complete until the result of 4 is ready and we can call the function.

But if we reorder them and evaluate in the order 1, 3, 2, 4, we can do it in 2 cycles. 1 and 3 can be started in the same cycle (or even merged into one instruction, since it's the same expression), and in the following, 2 and 4 can be evaluated. All modern CPU's can execute 3-4 instructions per cycle, and a good compiler should try to exploit that.

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What's the point of analyzing what a compiler is likely to do with something undefined? If you want speed, wouldn't it work better just to emit no code for undefined expressions? –  David Thornley Mar 5 '09 at 18:16
    
What the compiler does with undefined expressions doesn't matter speedwise or otherwise, because nothing undefined should be in your code in the first place. If your code invokes undefined behavior, you've already lost. ;) –  jalf Mar 5 '09 at 23:32
    
The point in my post was simply to illustrate a way in which the expression could yield a "surprising" value, and a reason why the compiler might actually choose to do this instead of the more predictable results. Of course relying on any of this would be stupid. :) –  jalf Mar 5 '09 at 23:33
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++Kristo!

The C++ standard 1.9.16 makes a lot of sense with respect to how one implements operator++(postfix) for a class. When that operator++(int) method is called, it increments itself and returns a copy of the original value. Exactly as the C++ spec says.

It's nice to see standards improving!


However, I distinctly remember using older (pre-ANSI) C compilers wherein:

foo -> bar(i++) -> charlie(i++);

Did not do what you think! Instead it compiled equivalent to:

foo -> bar(i) -> charlie(i); ++i; ++i;

And this behavior was compiler-implementation dependent. (Making porting fun.)


It's easy enough to test and verify that modern compilers now behave correctly:

#define SHOW(S,X)  cout << S << ":  " # X " = " << (X) << endl

struct Foo
{
  Foo & bar(const char * theString, int theI)
    { SHOW(theString, theI);   return *this; }
};

int
main()
{
  Foo f;
  int i = 0;
  f . bar("A",i) . bar("B",i++) . bar("C",i) . bar("D",i);
  SHOW("END ",i);
}



Responding to comment in thread...

...And building on pretty much EVERYONE's answers... (Thanks guys!)


I think we need spell this out a bit better:

Given:

baz(g(),h());

Then we don't know whether g() will be invoked before or after h(). It is "unspecified".

But we do know that both g() and h() will be invoked before baz().

Given:

bar(i++,i++);

Again, we don't know which i++ will be evaluated first, and perhaps not even whether i will be incremented once or twice before bar() is called. The results are undefined! (Given i=0, this could be bar(0,0) or bar(1,0) or bar(0,1) or something really weird!)


Given:

foo(i++);

We now know that i will be incremented before foo() is invoked. As Kristo pointed out from the C++ standard section 1.9.16:

When calling a function (whether or not the function is inline), every value computation and side effect associated with any argument expression, or with the postfix expression designating the called function, is sequenced before execution of every expression or statement in the body of the called function. [ Note: Value computations and side effects associated with different argument expressions are unsequenced. -- end note ]

Though I think section 5.2.6 says it better:

The value of a postfix ++ expression is the value of its operand. [ Note: the value obtained is a copy of the original value -- end note ] The operand shall be a modifiable lvalue. The type of the operand shall be an arithmetic type or a pointer to a complete effective object type. The value of the operand object is modified by adding 1 to it, unless the object is of type bool, in which case it is set to true. [ Note: this use is deprecated, see Annex D. -- end note ] The value computation of the ++ expression is sequenced before the modification of the operand object. With respect to an indeterminately-sequenced function call, the operation of postfix ++ is a single evaluation. [ Note: Therefore, a function call shall not intervene between the lvalue-to-rvalue conversion and the side effect associated

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+1, but I had to read the standard carefully to convince myself that this was OK. Am I right in thinking that, if bar() was instead a global function returning say int, f was an int, and those invocations were connected by say "^" instead of ".", then any of A, C and D could report "0"? –  j_random_hacker Mar 3 '09 at 10:25
    
Responded by amending original post. (It took more than 300 chars.) –  Mr.Ree Mar 5 '09 at 18:14
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To build on Bill the Lizard's answer:

int i = 1;
foo(i++, i++);

might also result in a function call of

foo(1, 1);

(meaning that the actuals are evaluated in parallel, and then the postops are applied).

-- MarkusQ

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I find that impossible. –  Milan Babuškov Mar 1 '09 at 11:32
    
I think it was supposed to be foo(1,1). Bill had an off by one error earlier, and I think MarkusQ just copied that in his post –  jalf Mar 1 '09 at 12:32
    
Yes, my bad. Copy & paste without read & think. –  MarkusQ Mar 1 '09 at 16:09
1  
It might also result in the computer turning into a stuffed panda, according to the standard. Undefined is undefined, and arguing about what one particular implementation is likely to do is pointless. –  David Thornley Mar 5 '09 at 18:18
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Sutter's Guru of the Week #55 (and the corresponding piece in "More Exceptional C++") discusses this exact case as an example.

According to him, it is perfectly valid code, and in fact a case where trying to transform the statement into two lines:

items.erase(i);
i++;

does not produce code that is semantically equivalent to the original statement.

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