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I want to parse UTF-8 in C++. When parsing a new character, I don't know in advance if it is an ASCII byte or the leader of a multibyte character, and also I don't know if my input string is sufficiently long to contain the remaining characters.

For simplicity, I'd like to name the four next bytes a, b, c and d, and because I am in C++, I want to do it using references.

Is it valid to define those references at the beginning of a function as long as I don't access them before I know that access is safe? Example:

void parse_utf8_character(const string s) {
    for (size_t i = 0; i < s.size();) {
        const char &a = s[i];
        const char &b = s[i + 1];
        const char &c = s[i + 2];
        const char &d = s[i + 3];

        if (is_ascii(a)) {
            i += 1;
            do_something_only_with(a);
        } else if (is_twobyte_leader(a)) {
            i += 2;
            if (is_safe_to_access_b()) {
                do_something_only_with(a, b);
            }
        }
        ...
     }
}

The above example shows what I want to do semantically. It doesn't illustrate why I want to do this, but obviously real code will be more involved, so defining b,c,d only when I know that access is safe and I need them would be too verbose.

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2  
In all honesty I would think that accessing them when you know you need to (multibyte char detected) is better. Certainly if the array bounds are breached you will have an issue above. However using pointer arithmetic you can avoid that. –  Caribou Dec 9 '12 at 22:49
    
@Caribou: Sorry, I don't get your point. –  Jo So Dec 9 '12 at 22:50
    
Even if it is safe, you might get an assertion failure when trying to go out of bounds; certainly Visual C++ throws one. You could use pointer arithmetic, but obtaining a pointer to the underlying representation of the string might not be portable. –  Andrei Tita Dec 9 '12 at 22:52
    
@JoSo Kevin makes my point :) - lets imagine you have a char near the end of the string . You access beyond the end of the string to set up your refs and bang your program has issues. Pointers will just be calculated addresses and so no access occurs –  Caribou Dec 9 '12 at 22:54
    
@AndreiTita,Caribou: You didn't get my question. I know that accessing might be problematic when the string isn't long enough. I want to know if it is ok to define the references. –  Jo So Dec 9 '12 at 23:09

3 Answers 3

up vote 5 down vote accepted

There are three takes on this:

  • Formally
    well, who knows. I could find out for you by using quite some time on it, but then, so could you. Or any reader. And it's not like that's very practically useful.
    EDIT: OK, looking it up, since you don't seem happy about me mentioning the formal without looking it up for you. Formally you're out of luck:
    N3280 (C++11) §5.7/5 “If both the pointer operand and the result point to elements of the same array object, or one past the last element of the array object, the evaluation shall not produce an overflow; otherwise, the behavior is undefined.”
    Two situations where this can produce undesired behavior: (1) computing an address beyond the end of a segment, and (2) computing an address beyond an array that the compiler knows the size of, with debug checks enabled.

  • Technically
    you're probably OK as long as you avoid any lvalue-to-rvalue conversion, because if the references are implemented as pointers, then it's as safe as pointers, and if the compiler chooses to implement them as aliases, well, that's also ok.

  • Economically
    relying needlessly on a subtlety wastes your time, and then also the time of others dealing with the code. So, not a good idea. Instead, declare the names when it's guaranteed that what they refer to, exists.

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Please don't blame me for not looking up. I didn't ask you to do it. If you don't know it, don't answer. –  Jo So Dec 9 '12 at 22:56
    
But thanks for point "Economically". It is a very valid point. –  Jo So Dec 9 '12 at 22:56
    
Thanks for updating, makes a good answer now. –  Jo So Dec 9 '12 at 23:20

Before going into the legality of references to unaccessible memory, you have another problem in your code. Your call to s[i+x] might call string::operator[] with a parameter bigger then s.size(). The C++11 standard says about string::operator[] ([string.access], §21.4.5):

Requires: pos <= size().

Returns: *(begin()+pos) if pos < size(), otherwise a reference to an object of type T with value charT(); the referenced value shall not be modified.

This means that calling s[x] for x > s.size() is undefined behaviour, so the implementation could very well terminate your program, e.g. by means of an assertion, for that.

Since string is now guaranteed to be continous, you could go around that problem using &s[i]+x to get an address. In praxis this will probably work.

However, strictly speaking doing this is still illegal unfortunately. The reason for this is that the standard allows pointer arithmetic only as long as the pointer stays inside the same array, or one past the end of the array. The relevant part of the (C++11) standard is in [expr.add], §5.7.5:

If both the pointer operand and the result point to elements of the same array object, or one past the last element of the array object, the evaluation shall not produce an overflow; otherwise, the behavior is undefined.

Therefore generating references or pointers to invalid memory locations might work on most implementations, but it is technically undefined behaviour, even if you never dereference the pointer/use the reference. Relying on UB is almost never a good idea , because even if it works for all targeted systems, there are no guarantees about it continuing to work in the future.

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+1 but sorry I have already accepted another good answer. –  Jo So Dec 9 '12 at 23:22
    
@JoSo: The C++11 standard guarantees that &s[i]==s.c_str() + i, which means that &s[i]+x must be identical to &s[i+x] as long as i+x is in range. So where is the glitch? –  Grizzly Dec 9 '12 at 23:29
    
Sorry, I was only completely confused and had already deleted the comment saying "glitch" again. –  Jo So Dec 9 '12 at 23:31

In principle, the idea of taking a reference for a possibly illegal memory address is itself perfectly legal. The reference is only a pointer under the hood, and pointer arithmetic is legal until dereferencing occurs.

EDIT: This claim is a practical one, not one covered by the published standard. There are many corners of the published standard which are formally undefined behaviour, but don't produce any kind of unexpected behaviour in practice.

Take for example to possibility of computing a pointer to the second item after the end of an array (as @DanielTrebbien suggests). The standard says overflow may result in undefined behaviour. In practice, the overflow would only occur if the upper end of the array is just short of the space addressable by a pointer. Not a likely scenario. Even when if it does happen, nothing bad would happen on most architectures. What is violated are certain guarantees about pointer differences, which don't apply here.

@JoSo If you were working with a character array, you can avoid some of the uncertainty about reference semantics by replacing the const-references with const-pointers in your code. That way you can be certain no compiler will alias the values.

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1  
Can you cover that claim? I know that intuitively, references have "pointer semantics but value syntax". But how do you prove that I am allowed to do what I want? –  Jo So Dec 9 '12 at 22:54
1  
"pointer arithmetic is legal until dereferencing occurs" -- How certain are you of that? –  Benjamin Lindley Dec 9 '12 at 22:54
3  
"pointer arithmetic is legal until dereferencing occurs" Actually, that is not true. At least in C, "If both the pointer operand and the result point to elements of the same array object, or one past the last element of the array object, the evaluation shall not produce an overflow; otherwise, the behavior is undefined." So, you technically invoke Undefined Behavior by attempting to create a pointer to beyond one past the last element of an array. –  Daniel Trebbien Dec 9 '12 at 22:59
    
@DanielTrebbien I didn't know that, but surely if that result address is just calculated and not used it is fine in practice? –  Caribou Dec 9 '12 at 23:04
3  
@Caribou: One rule to adhere to always is: never invoke UB. Some code invoking UB may seem fine, but it might be broken in a subtle way. See Contest: Craziest Compiler Output due to Undefined Behavior. –  Daniel Trebbien Dec 9 '12 at 23:10

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