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After posting one of my most controversial answers here, I dare to ask a few questions and eventually fill some gaps in my knowledge.

Why isn't an expression of the kind ((type_t *) x) considered a valid lvalue, assuming that x itself is a pointer and an lvalue, not just some expression?

I know many will say "the standard disallows it", but from a logical standpoint it seems reasonable. What is the reason that the standard disallows it? After all, any two pointers are of the same size and the pointer type is just a compile-time abstraction that indicates the appropriate offset that should be applied when doing pointer arithmetic.

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I think, that already "any two pointers are of the same size" is wrong. Not sure, but I think this is actually architecture dependent. See stackoverflow.com/questions/1241205/… – Dirk Sep 16 '11 at 14:53
Standard C guarantees that pointers to objects are all the same size, but allows pointers to functions to be of different sizes (from each other and from pointers to objects). POSIX requires pointers to objects to be the same size as pointers to functions. – Jonathan Leffler Sep 16 '11 at 14:56
@Jonathan: read 6.2.5/27 in n1256.pdf: "... Pointers to other types need not have the same representation or alignment requirements." – pmg Sep 16 '11 at 15:05
I misspoke. ISO 9899:1999 §6.2.5¶26 says: A pointer to void shall have the same representation and alignment requirements as a pointer to a character type. Similarly, pointers to qualified or unqualified versions of compatible types shall have the same representation and alignment requirements. All pointers to structure types shall have the same representation and alignment requirements as each other. All pointers to union types shall have the same representation and alignment requirements as each other. Pointers to other types need not have the same representation or alignment requirements. – Jonathan Leffler Sep 16 '11 at 15:12
FWIW, the POSIX 2008 standard says (System Interfaces, §2.12.3 Pointer Types): All function pointer types shall have the same representation as the type pointer to void. Conversion of a function pointer to void * shall not alter the representation. A void * value resulting from such a conversion can be converted back to the original function pointer type, using an explicit cast, without loss of information. Note: The ISO C standard does not require this, but it is required for POSIX conformance. – Jonathan Leffler Sep 16 '11 at 15:16
up vote 3 down vote accepted

An even better example, unary + yields an rvalue, as does x+0.

The underlying reason is that all these things, including your cast, create a new value. Casting a value to the type it already is, likewise creates a new value, never mind whether pointers to different types have the same representation or not. In some cases, the new value happens to be equal to the old value, but in principle it's a new value, it's not intended to be used as a reference to the old object, and that's why it's an rvalue.

For these to be lvalues, the standard would have to add some special cases that certain operations when used on an lvalue result in a reference to the old object, instead of a new value. AFAIK there's no great demand for those special cases.

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sir I don't understand how unary plus (+a) yields rvalue,If it yields rvalue then there should be lvalue required error for this (+a)++; but it is working.....plz explain it thnks – A.s. Bhullar Oct 1 '13 at 15:01

The result of a cast is never an lvalue by itself. But *((type_t *) x) is an lvalue.

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Because cast expressions in general do not yield lvalues.

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This is the best answer of all. People who expect (type *)foo to be an lvalue usually have a misunderstanding of C and think that casts are reinterpretations of bits. This is wrong. A cast is an operation on values, and as such, the lvalue is "gone" even "before the cast takes place", as the input operand to the cast is the value of an expression (sometimes called an rvalue), not an lvalue. – R.. Sep 16 '11 at 16:32
@R.., "value or an expressions" and rvalue does not mean the same thing since expressions can evaluate to lvalues too. – ikegami Sep 16 '11 at 16:46
Of, not or. In the phrase "Value of an expression", the key word is value. See the footnote in Lvalues, arrays, and function designators. – R.. Sep 16 '11 at 19:33

Well, casting performs a type conversion. In general case type conversion is a non-trivial operation, which completely changes the representation of the value. Under these circumstances it should be painfully obvious that the result of any conversion is cannot possibly be an lvalue.

For example, if you have an int i = 0; variable, you can convert it to type double as (double) i. How can you possibly expect the result of this conversion to be an lvalue? I mean, it just doesn't make any sense. You apparently expect to be able to do (double) i = 3.0;... Or double *p = &(double) i; So, what should happen to the value of i in the former example, considering that type double might not even have the same size as type int? And even if they had the same size, what would you expect to happen?

Your assumption about all pointers having the same size is incorrect. In C language in general case (with few exceptions) different pointer types have different sizes, different internal representations and different alignment requirements. Even if they were guaranteed to have the same representation, I still don't see why pointers should be separated from all other types and given special treatment in explicit cast situations.

Finally, what you seem to be advocating here is that your original conversion should perform a raw-memory reinterpretation of one pointer type as another pointer type. Raw-memory reinterpretation in almost all cases is a hack. Why this hack should be elevated to the level of the language feature is entirely not clear to me.

Since it is a hack, performing such reinterpretations should require a conscious effort from the user. If you want to perform it in your example, you should do *(type_t **) &x, which will indeed reinterpret x as an lvalue of type type_t *. But allowing the same thing through a mere (type_t *) x would be a disaster completely disconnected with the design principles of C language.

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From the code the questioner refers to in the question, what he actually wants is to abbreviate p = (int*)p + 1, where p has type void*, to ((int*)p)++. It's not clear to me whether this is an attempt to argue that the standard should allow that, or just to correct the misunderstanding that led the questioner to think the latter would work... – Steve Jessop Sep 18 '11 at 1:23

The C standard was written to support exotic machine architectures that require weird hacks to implement the C pointer model for all pointed-to types. In order to allow the compiler to use the most efficient pointer representation for each pointed-to type, the C standard does not require different pointer representations to be compatible. On such an exotic architecture the void pointer type must use the most general and thus slowest of the different representations. There are some specific examples of such now obsolete architectures in the C FAQ: http://c-faq.com/null/machexamp.html

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Note that if x is a pointer type, *(type_t **)&x is an lvalue. However, accessing it as such except perhaps in very restricted circumstances invokes undefined behavior due to aliasing violations. The only time it might be legal is if the pointer types are corresponding signed/unsigned or void/char pointer types, but even then I'm doubtful.

(type_t *)x is not an lvalue, because (T)x is never an lvalue, regardless of the type T or the expression x. (type_t *) is just a special case of (T).

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From a top level, it would generally serve no purpose. Instead of '((type_t *) x) = ' one might as well go ahead and do 'x = ', assuming x is a pointer in your example. If one wishes to directly modify values pointed by the address 'x' but at the same time after interpreting it to be a pointer to a new data type then *((type_t **) &x) = is the way forward. Again ((type_t **) &x) = would serve no purpose, let alone the fact it is not a valid lvalue.

Also in cases of ((int *)x)++, where at least 'gcc' does not complain along the lines of 'lvalue' it could be reinterpreting it as 'x = (int *)x + 1'

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