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I understand that a char variable can accept a null character(1 byte) i.e; \0 as its value but, I don't understand how a char variable in my application below accepts a pointer(4 bytes) as its value and still works properly?

#include<stdio.h>
int main()
{
    char p[10]="Its C";
    printf("%s\n",p);
    p[3]='\0';                // assigning null character 
    printf("%s\n",p);
    p[2]=NULL;               //  assigning null pointer to a char variable
    printf("%s\n",p); 
    p[1]=(void *)0;          //  assigning null pointer to a char variable
    printf("%s\n",p);
    return 0;
}

Note: GCC Compiler (32 Bit Linux Platform).

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Did your compiler produce any warnings for this program? If so, please edit your question to show them to us. –  Keith Thompson Apr 11 '13 at 17:28
1  
@Grijesh Chauhan Thanks for editing –  E F Apr 11 '13 at 18:55
    
@KeithThompson , That was an online editor ,which was not giving any warnings. –  E F Apr 11 '13 at 18:57
    
What online editor lets you compile code but hides warnings from you? –  Keith Thompson Apr 11 '13 at 19:05
1  
Ick. Hiding warnings like that is pretty bad. But there is a workaround. If your program fails to compile, it will show both error messages and warnings. Temporarily add a #error directive, and it will show you the warnings. (But there doesn't seem to be a way to specify compiler options.) You're much better off using a compiler directly if that's at all practical. –  Keith Thompson Apr 11 '13 at 19:31

5 Answers 5

up vote 8 down vote accepted

The NULL macro is required to expand to "an implementation-defined null pointer constant".

A null pointer constant is defined as "An integer constant expression with the value 0, or such an expression cast to type void *". Counterintuitively, this definition does not require the expansion of NULL to be an expression of pointer type. A common implementation is:

#define NULL 0

A null pointer constant, when used in a context that requires a pointer, may be implicitly converted to a pointer value; the result is a null pointer. It may also be explicitly converted using a cast, such as (int*)NULL.

But there's no requirement that an expression that qualifies as a null pointer constant may only be used in such a context. Which means that if the implementation chooses to define NULL as above, then this:

char c = NULL; // legal but ugly

is legal and initializes c to the null character.

Such an initialization is non-portable (since NULL may also expand to ((void*)0) and misleading, so it should be avoided, but a compiler is likely to let it through without warning; NULL is expanded to 0 by the preprocessing phase of the compiler, and later phases see it as char c = 0;, which is legal and innocuous -- though personally I'd prefer char c = '\0';.

I just tried your example on my own 32-bit Ubuntu system, with gcc 4.7. With no options specified, the compiler warned about both p[2]=NULL; and p[1]=(void *)0;:

c.c:8:9: warning: assignment makes integer from pointer without a cast [enabled by default]
c.c:10:9: warning: assignment makes integer from pointer without a cast [enabled by default]

The second warning is to be expected from any C compiler; the first indicates that NULL is actually defined as ((void*)0) (running the code through gcc -E confirms this).

The compiler didn't simply "accept" these assignments; it warned you about them. The C language standard merely requires a "diagnostic" for any violation of the language rules, even a syntax error; that diagnostic may legally be a non-fatal warning message. You can make gcc behave more strictly with -std=c89 -pedantic-errors; replace c89 by c99 or c11 to enforce rules from later versions of the standard. (EDIT: I see from comments that you're using a web interface to the compiler that hides warnings; see my comment on your question for a workaround. Warnings are important.)

If you post C code that produces compiler warnings please show us the warnings and pay close attention to them yourself. They often indicate serious problems, even illegalities, in your program.

A language-lawyer quibble: it's not even clear that this:

char c = (void*)0;

specifies a conversion from void* to char. My own view is that, since it violates a constraint, it has no defined semantics. Most compilers that don't reject it will treat it as if it were a void*-to-char conversion, and it's also been argued that this is the required behavior. But you can avoid such questions if you simply pay attention to compiler warnings and/or don't write code like that in the first place.

(The rules are a bit different for C++, but you're asking about C so I won't get into that.)

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This is simply an excellent answer! –  xci13 Apr 11 '13 at 17:13
1  
Thanks! This saves me the trouble of writing a new answer, warning of the potential for undesirable behaviour that is pointer-to-integer conversion, when NULL is defined as ((void *)0) or some other null pointer. It might still be worth-while to quote from the standard: Any pointer type may be converted to an integer type. Except as previously specified, the result is implementation-defined. If the result cannot be represented in the integer type, the behavior is undefined. The result need not be in the range of values of any integer type. –  undefined behaviour Apr 11 '13 at 17:13
1  
Thanks :) ...I would also like to read your other post in my spare time –  Grijesh Chauhan Apr 11 '13 at 17:34
    
@Keith Thompson : Thank you very much , This was the standard of explanation i was waiting for , Otherwise all of the answers given were good to go with, but this is the best. –  E F Apr 11 '13 at 19:05
    
@modifiablelvalue Thanks for the extension Answer –  E F Apr 11 '13 at 19:25

NULL is a macro and for almost platform is defined in this way

#ifndef __cplusplus
#define NULL ((void *)0)
#else   /* C++ */
#define NULL 0
#endif  /* C++ */

(from stddef.h from my Ubuntu)

and when you write

p[2]=NULL;

It's the same

p[2]=(void *)0; //for c
p[2]=0; //for c++

It's the same

p[2] = 0; // the 0 is casted to char 0 for C --> '\0'
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@GrijeshChauhan fixed –  MOHAMED Apr 11 '13 at 17:01
    
I noticed question is taged only c so you answer should get a + :) :) and + to show difference in c and c++ good –  Grijesh Chauhan Apr 11 '13 at 17:09

Because, in compilers, NULL is substituted for 0 in some compilers and ((void*)0) in others.

The value 0 in itself is a valid value for char but with the conversion to (void*), you're technically casting the 0 into a pointer type, hence why the compiler would give a warning.

Note that if the compiler substitutes NULL with 0, an integer constant, it'll be simply and silently converted into a char.

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1  
added a little explanation –  xci13 Apr 11 '13 at 17:12
    
I am outing me as a downvoter hereby. –  Johannes Schaub - litb Apr 11 '13 at 17:14
1  
@JohannesSchaub-litb: May I know why? I anyhow edited the answer a little to make what I mean clearer. –  xci13 Apr 11 '13 at 17:17
    
@JohannesSchaub-litb While adding answer as help Adel is also a learner like, fairly you should explain him your downvote reason. that will helpful for me as well –  Grijesh Chauhan Apr 11 '13 at 17:23
1  
@AdelQodmani: I suggest cleaning up that first sentence. It still suggests that ((void*)0) is a perfectly valid value for type char. –  Keith Thompson Apr 11 '13 at 17:26

On your platform, a pointer is generally a numerical value treated as a memory address. Since the char type is numeric, a null pointer (memory address 0x00) is being stored in p[1]

The 32-bit value of the pointer (in this case, 0x00000000) is truncated to 8-bit char length: 0x00.

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1  
No, pointers are not simply numerical values; as far as the language is concerned, they're quite distinct entities. If NULL expands to ((void*)0), the assignment is a constraint violation, requiring at least a warning (there's no implicit conversion from void* to char). If NULL expands to 0, there is no pointer conversion; NULL expands to a constant expression of type int, which is implicitly converted to char. –  Keith Thompson Apr 11 '13 at 17:07
3  
@KeithThompson - OP explicitly stated he was using GCC on a 32-bit Linux platform. On this platform, pointers are numeric memory addresses. Don't believe me? Do a memory dump :) –  Unsigned Apr 11 '13 at 19:02
    
Given the added "On your platform" qualification, it's a bit better. But there is no conversion from void* to intptr_t, since there's no mention of inptr_t, either explicit or implicit, in the code. Assigning a void* value to a char is a constraint violation; assuming the compiler merely warns about it, it will probably result in a conversion (not a cast, which is an explicit operator) from void* to char. In any case, IMHO it's better to think of pointers as being distinct from integers; the way they're represented internally is an implementation detail. –  Keith Thompson Apr 11 '13 at 19:24
    
The semantics of a conversion from void* to char (or generally from any pointer type to any integer type) are implementation-defined, but "are intended to be consistent with the addressing structure of the execution environment". But the most important thing to know about the code is that it's invalid. –  Keith Thompson Apr 11 '13 at 19:26
1  
@KeithThompson - On my system, g++ 4.7.2 expands NULL to either __null or 0, depending on the preprocessor selected. As for NULL-assigning being non-portable, which compilers do not permit it? GCC likes it fine: ideone.com/lLEaNe –  Unsigned Apr 11 '13 at 19:50

Try to compile this with -Wall option and you will see that there are impilicit convertions taking place.

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Compiling without -Wall produces warnings. –  Keith Thompson Apr 11 '13 at 17:27

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