Why is ++i is l-value? and i++ not
Initially there were 2 questions one was removed since that was exact duplicate. So don't down vote the answers that were answering difference between pre- and post-increment.
Well as another answerer pointed out already the reason why
The reason for the second rule is to allow to initialize a reference using a literal, when the reference is a reference to const:
Why do we introduce an rvalue at all you may ask. Well, these terms come up when building the language rules for these two situations:
The above two points are taken from the C99 Standard which includes this nice footnote quite helpful:
The locator value is called lvalue, while the value resulting from evaluating that location is called rvalue. That's right according also to the C++ Standard (talking about the lvalue-to-rvalue conversion):
Using the above semantics, it is clear now why
However, in constrast, the expression returned by
Note also the other occasions where rvalues are generated. For example, all temporaries are rvalues, the result of binary/unary + and minus and all return value expressions that are not references. All those expressions are not located in an named object, but carry rather values only. Those values can of course be backed up by objects that are not constant.
The next C++ Version will include so-called
Other people have tackled the functional difference between post and pre increment.
As far as being an lvalue is concerned,
In terms of assignment, both of the following make no sense in the same sort of way:
Because pre-increment returns a reference to the incremented variable rather than a temporary copy,
Preferring pre-increment for performance reasons becomes an especially good idea when you are incrementing something like an iterator object (eg in the STL) that may well be a good bit more heavyweight than an int.
It seem that a lot of people are explaining how
int i; extern void f (int* p); extern void g (int& p); f (&++i); /* Would be illegal C, but C programmers havent missed this feature */ g (++i); /* C++ programmers would like this to be legal */ g (i++); /* Not legal C++, and it would be difficult to give this meaningful semantics */
By the way, if
In general, in C++, you should use pre-increment, unless you need the original value. It's more efficient, because it doesn't involve making a copy of the original value.
I'm getting the lvalue error when I try to compile
but not when I change it to
This is because the prefix operator (++i) changes the value in i, then returns i, so it can still be assigned to. The postfix operator (i++) changes the value in i, but returns a temporary copy of the old value, which cannot be modified by the assignment operator.
Answer to original question:
If you're talking about using the increment operators in a statement by themselves, like in a for loop, it really makes no difference. Preincrement appears to be more efficient, because postincrement has to increment itself and return a temporary value, but a compiler will optimize this difference away.
is the same as
Things get a little more complicated when you're using the return value of the operation as part of a larger statement.
Even the two simple statements
are different. Which increment operator you choose to use as a part of multi-operator statements depends on what the intended behavior is. In short, no you can't just choose one. You have to understand both.
POD Pre increment:
The pre-increment should act as if the object was incremented before the expression and be usable in this expression as if that happened. Thus the C++ standards comitee decided it can also be used as an l-value.
POD Post increment:
The post-increment should increment the POD object and return a copy for use in the expression (See n2521 Section 5.2.6). As a copy is not actually a variable making it an l-value does not make any sense.
Pre and Post increment on objects is just syntactic sugar of the language provides a means to call methods on the object. Thus technically Objects are not restricted by the standard behavior of the language but only by the restrictions imposed by method calls.
It is up to the implementor of these methods to make the behavior of these objects mirror the behavior of the POD objects (It is not required but expected).
The requirement (expected behavior) here is that the objects is incremented (meaning dependant on object) and the method return a value that is modifiable and looks like the original object after the increment happened (as if the increment had happened before this statement).
To do this is siple and only require that the method return a reference to it-self. A reference is an l-value and thus will behave as expected.
The requirement (expected behavior) here is that the object is incremented (in the same way as pre-increment) and the value returned looks like the old value and is non-mutable (so that it does not behave like an l-value).
Looks like the old value:
In the same way as pre-increment:
The main difference is that i++ returns the pre-increment value whereas ++i returns the post-increment value. I normally use ++i unless I have a very compelling reason to use i++ - namely, if I really do need the pre-increment value.
IMHO it is good practise to use the '++i' form. While the difference between pre- and post-increment is not really measurable when you compare integers or other PODs, the additional object copy you have to make and return when using 'i++' can represent a significant performance impact if the object is either quite expensive to copy, or incremented frequently.
By the way - avoid using multiple increment operators on the same variable in the same statement. You get into a mess of "where are the sequence points" and undefined order of operations, at least in C. I think some of that was cleaned up in Java nd C#.
Maybe this has something to do with the way the post-increment is implemented. Perhaps it's something like this:
Since the copy is neither a variable nor a reference to dynamically allocated memory, it can't be a l-value.
(edit: updated after a blotched first-attempt).