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int main ()
{
   int a = 5,b = 2;
   printf("%d",a+++++b);
   return 0;
}

This code gives the following error:

error: lvalue required as increment operand

But if I put spaces throughout a++ + and ++b, then it works fine.

int main ()
{
   int a = 5,b = 2;
   printf("%d",a++ + ++b);
   return 0;
}

What does the error mean in the first example?

share|improve this question
    
It is surprising after all this time that no one had discovered that the exact expression you are asking about is used as an example in the C99 and C11 standard. It gives a good explanation as well. I have includes that in my answer. –  Shafik Yaghmour Jul 25 at 15:01

9 Answers 9

up vote 68 down vote accepted

printf("%d",a+++++b); is interpreted as (a++)++ + b according to the Maximal Munch Rule!.

++ (postfix) doesn't evaluate to an lvalue but it requires its operand to be an lvalue.

! 6.4/4 says the next preprocessing token is the longest sequence of characters that could constitute a preprocessing token"

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11  
+1 for naming the Maximal Munch Rule method :) –  pmg Mar 17 '11 at 16:05

Compilers are written in stages. The first stage is called the lexer and turns characters into a symbolic structure. So "++" becomes something like an enum SYMBOL_PLUSPLUS. Later, the parser stage turns this into an abstract syntax tree, but it can't change the symbols. You can affect the lexer by inserting spaces (which end symbols unless they are in quotes).

Normal lexers are greedy (with some exceptions), so your code is being interpreted as

a++ ++ +b

The input to the parser is a stream of symbols, so your code would be something like:

[ SYMBOL_NAME(name = "a"), 
  SYMBOL_PLUS_PLUS, 
  SYMBOL_PLUS_PLUS, 
  SYMBOL_PLUS, 
  SYMBOL_NAME(name = "b") 
]

Which the parser thinks is syntactically incorrect. (EDIT based on comments: Semantically incorrect because you cannot apply ++ to an r-value, which a++ results in)

a+++b 

is

a++ +b

Which is ok. So are your other examples.

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26  
+1 Good explanation. I have to nitpick though: It is syntactically correct, it just has a semantic error (attempt to increment the lvalue resulting from a++). –  delnan Apr 15 '11 at 13:22
4  
a++ results in an rvalue. –  Femaref Apr 15 '11 at 13:40
6  
In the context of lexers, the 'greedy' algorithm is usually called Maximal Munch (en.wikipedia.org/wiki/Maximal_munch). –  Joe Gauterin Apr 15 '11 at 14:18
1  
does that mean a++ +++b wouldn't work either? –  Andy Apr 15 '11 at 15:44
14  
Nice. Many languages have similar bizarre corner cases thanks to greedy lexing. Here's a really weird one where making the expression longer makes it better: In VBScript x = 10&987&&654&&321 is illegal, but bizarrely enough x = 10&987&&654&&&321 is legal. –  Eric Lippert Apr 15 '11 at 18:25

The lexer uses what's generally called a "maximum munch" algorithm to create tokens. That means as it's reading characters in, it keeps reading characters until it encounters something that can't be part of the same token as what it already has (e.g., if it's been reading digits so what it has is a number, if it encounters an A, it knows that can't be part of the number. so it stops and leaves the A in the input buffer to use as the beginning of the next token). It then returns that token to the parser.

In this case, that means +++++ gets lexed as a ++ ++ + b. Since the first post-increment yields an rvalue, the second can't be applied to it, and the compiler gives an error.

Just FWIW, in C++ you can overload operator++ to yield an lvalue, which allows this to work. For example:

struct bad_code { 
    bad_code &operator++(int) { 
        return *this;
    }
    int operator+(bad_code const &other) { 
        return 1;
    }
};

int main() { 
    bad_code a, b;

    int c = a+++++b;
    return 0;
}

The compiles and runs (though it does nothing) with the C++ compilers I have handy (VC++, g++, Comeau).

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2  
the question is about C, not C++. –  Femaref Apr 15 '11 at 19:06
10  
@Femaref: Yes, I answered the question about C. Then, because many people who are interested in C also find C++ interesting, I added some about it as well. –  Jerry Coffin Apr 15 '11 at 19:12
    
this wasn't directed at you, @acidzombie24 posted a comment with "this is the only correct answer" to which my comment was directed. –  Femaref Apr 15 '11 at 19:14
1  
"e.g., if it's been reading digits so what it has is a number, if it encounters an A, it knows that can't be part of the number" 16FA is a perfectly fine hexadecimal number that contains an A. –  orlp Apr 15 '11 at 19:55
1  
@nightcracker: yes, but without a 0x at the beginning it'll still treat that as 16 followed by FA, not a single hexadecimal number. –  Jerry Coffin Apr 15 '11 at 19:58

Your compiler desperately tries to parse a+++++b, and interprets it as (a++)++ +b. Now, the result of the post-increment (a++) is not an lvalue, i.e. it can't be post-incremented again.

Please don't ever write such code in production quality programs. Think about the poor fellow coming after you who needs to interpret your code.

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(a++)++ +b

a++ returns the previous value, a rvalue. You can't increment this.

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Because it causes undefined behaviour.

Which one is it?

c = (a++)++ + b
c = (a) + ++(++b)
c = (a++) + (++b)

Yeah, neither you nor the compiler know it.

EDIT:

The real reason is the one as said by the others:

It gets interpreted as (a++)++ + b.

but post increment requires a lvalue (which is a variable with a name) but (a++) returns a rvalue which cannot be incremented thus leading to the error message you get.

Thx to the others to pointing this out.

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5  
you could say the same for a+++b - (a++) + b and a + (++b) have different results. –  Michael Chinen Apr 15 '11 at 13:13
4  
actually, postfix ++ has higher precedence than prefix ++, so a+++b is always a++ + b –  MByD Apr 15 '11 at 13:16
4  
I don't think this is the right answer, but I could be wrong. I think the lexer defines it to be a++ ++ +b which cannot be parsed. –  Lou Franco Apr 15 '11 at 13:17
2  
I disagree with this answer. 'undefined behaviour' is quite different from tokenization ambiguity; and I don't think the problem is either. –  Jim Blackler Apr 15 '11 at 13:17
1  
"Otherwise a+++++b would evaluate to ((a++)++)+b" ... my view right now is a+++++b does evaluate to (a++)++)+b. Certainly with GCC if you insert those brackets and rebuild, the error message doesn't change. –  Jim Blackler Apr 15 '11 at 13:21

I think the compiler sees it as

c = ((a++)++)+b

++ has to have as an operand a value that can be modified. a is a value that can be modified. a++ however is an 'rvalue', it cannot be modified.

By the way the error I see on GCC C is the same, but differently-worded: lvalue required as increment operand.

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This exact example is covered in the draft C99 standard(same details in C11) section 6.4 Lexical elements which in paragraph 4 says:

If the input stream has been parsed into preprocessing tokens up to a given character, the next preprocessing token is the longest sequence of characters that could constitute a preprocessing token. [...]

which is also known as the maximal munch rule which is used in in lexical analysis to avoid ambiguities and works by taking as many elements as it can to form a valid token.

the paragraph also has two examples the second one is an exact match for you question and is as follows:

EXAMPLE 2 The program fragment x+++++y is parsed as x ++ ++ + y, which violates a constraint on increment operators, even though the parse x ++ + ++ y might yield a correct expression.

which tells us that:

a+++++b

will be parsed as:

a ++ ++ + b

which violates the constraints on post increment since the result of the first post increment is an rvalue and post increment requires an lvalue. This is covered in section 6.5.2.4 Postfix increment and decrement operators which says (emphasis mine):

The operand of the postfix increment or decrement operator shall have qualified or unqualified real or pointer type and shall be a modifiable lvalue.

and

The result of the postfix ++ operator is the value of the operand.

The book C++ Gotchas also covers this case in Gotcha #17 Maximal Munch Problems it is the same problem in C++ as well and it also gives some examples. It explains that when dealing with the following set of characters:

->*

the lexical analyzer can do one of three things:

  • Treat it as three tokens: -, > and *
  • Treat it as two tokens: -> and *
  • Treat it as one token: ->*

The maximal munch rule allows it to avoid these ambiguities. The author points out that it (In the C++ context):

solves many more problems than it causes, but in two common situations, it’s an annoyance.

The first example would be templates whose template arguments are also templates (which was solved in C++11), for example:

list<vector<string>> lovos; // error!
                  ^^

Which interprets the closing angle brackets as the shift operator, and so a space is required to disambiguate:

list< vector<string> > lovos;
                    ^

The second case involves default arguments for pointers, for example:

void process( const char *= 0 ); // error!
                         ^^

would be interpreted as *= assignment operator, the solution in this case is to name the parameters in the declaration.

share|improve this answer
    
Typo @ "The book C++ Gothcas" –  AirThomas Nov 19 at 16:23
    
@AirThomas thank you, fixed. –  Shafik Yaghmour Nov 19 at 18:38

I dont know WTF everyone is talking about. They are all wrong. It has nothing to do with how the compiler parses the file. With C++ which keeps backwards compatibility and thus all rules, you can see that ++ does have a well define rule when using it. This code compiles without error in MSVC2010 and in codepad which i assume uses g++.

#include <cstdio>
class A{
public:
    A& operator++()   { return *this; }
    A& operator++(int){ return *this; }
    A  operator+(A& t){ return *this; }
};

int main(){
    A a, b;
    a+++++b;
}

http://codepad.org/s16WTzxU

Now, if someone can tell me why its an error when i change A into int then i'll be interested. More so if they can tell me how to make my own class cause that error as well. Explanation below.


C has that error because C has no 'reference' operator. It has no references so it does not keep track of the original variable as one might think it does when looking at A& operator++(int) in C++. ++ is implemented without references. Behind the scene after a++ is evaluated, it is stored as an int value (or whatever the type is). Since a value is not a variable when C sees ++ again it has no variable to increment causing the problem. Sure the compiler can look into it the expression and try to find out if one variable was use (to increment) or not. But that is extra work and perhaps the C committee agreed it is not desirable since += exist. Thus why the error message says lvalue rather then ambiguity (which it isn't) or confusion of intent (which precedence rules solve).

Its kind of interesting that C++ carried that feature. Even tho C++ allows this, One can write const A operator++(int){ ... }. so var++++ will no longer be legal due to const reasons. auto v = var++ will NOT make v const which creates the desirable effect. Its to bad compilers dont force operator++(int) to return const T and error otherwise (i should check gcc options but last time i check i couldnt. effc++ is close tho)

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4  
That's C++, not C. –  Femaref Apr 15 '11 at 19:02
    
The C++ example is to show C CAN parse that (C++ extends what is parsed). Your error doesn't say anything about ambiguity. I was just pointing that out with a legal example (although in ++). –  acidzombie24 Apr 15 '11 at 19:10
14  
Nobody said that it wasn't parseable. The parsed source just resulted in a semantically wrong syntax tree. This has nothing to do with C++. Your "answer" is just an example that it works in another language, which, additionally to the attitude, misses the point of the question completely. –  Femaref Apr 15 '11 at 19:16
    
Actually the accepted answer says Normal lexers are greedy which is completely incorrect. 'Normal' c lexers process it correctly and 'greed' has nothing to do with it. I know i didn't answer the question but i am just saying the lexer/parser does know how to build the tree. Which is why the error msg mentions lvalue. 'Guesses' make me angry. –  acidzombie24 Apr 15 '11 at 19:23
3  
then prove him wrong, provide a source for it and comment an his post. –  Femaref Apr 15 '11 at 19:26

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