What is the difference between these two in terms of memory allocation.

char *p1 = "hello"; 
char p2[] = "hello";
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    The first should be const char*! – rubenvb Jan 13 '11 at 13:21
  • p1 takes 4 or 8 bytes (required to store a memory address) which is platform dependent. p2 takes 6 bytes (= 5 bytes for string hello + 1 byte for null terminating character). – RBT Sep 22 '16 at 6:12

The first one creates a pointer variable (four or eight bytes of storage depending on the platform) and stores a location of a string literal there, The second one creates an array of six characters (including zero string terminator byte) and copies the literal there.

You should get a compiler warning on the first line since the literal is const.

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  • Where exactly is the string literal stored? Is it in heap? – blitzkriegz Jan 13 '11 at 13:19
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    The string literal is commonly stored in a region of memory separate from both the stack and the (new/delete-managed) heap. Depending on your platform, this region may be copy-protected, so writing to it will crash the program. – Fred Foo Jan 13 '11 at 13:22
  • If I'm not wrong p2 is also nothing but a pointer variable. Isn't it? So allocation of four or eight bytes of storage depending on the platform should happen in case of p2 as well. This piece of code p1 = p2; printf("%c" , *(p1 + 4)); prints o. So the only difference left is that fact that there is a null terminating character in case of declaration of p2. – RBT Sep 21 '16 at 1:34

The first one is a non-const pointer to const (read-only) data, the second is a non-const array.

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  • 3
    @Mahatma: yes, and this is also the same as the more readable and intuitive version: const char *p1 = "hello". – Paul R Jan 13 '11 at 13:19
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    @Mahatma: yes, but the first is dangerous: without a const qualification, there is no compiler protection against attempting to modify the string literal, giving undefined behaviour. – Mike Seymour Jan 13 '11 at 13:22
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    @RBT: yes, the string literal initialiser guarantees that. – Paul R Sep 21 '16 at 6:33
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    Ok. Cool. So that means the two code blocks that asker has posted have absolutely no difference in the number of number of bytes allocated (memory taken by string + null terminating character) and both have a pointer variable each which points to starting of the allocated string. The difference you have suggested is bang on target. I couldn't digest the accepted answer on this thread thoroughly. I come from a C# background and couldn't differentiate between string literal (the read-only const thingy) and array of characters :(. – RBT Sep 21 '16 at 6:46
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    You got it! ;-) – Paul R Sep 21 '16 at 6:47

Since the first one is a non-const pointer to const (read-only) data, the second is a non-const array, as Paul said, you can write:

p2[2]='A'; //changing third character - okay

But you cannot write:

p1[2]='A';//changing third character - runtime error!
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  • 1
    The second case is actually worse than a compilation error; the compiler will most likely accept it, giving undefined runtime behaviour. – Mike Seymour Jan 13 '11 at 13:25
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    That's not true- he won't get a compile error as the string literal isn't const. He will however get UB. – Puppy Jan 13 '11 at 13:33
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    That's not fixed. That code produces UB, which is not a run-time error. It is undefined behaviour. Now, in reality on most platforms, you will get a run-time error (SIGSEGV on Unix variants, Access Violation on Windows). However, the Standard says nothing about this and since he didn't mention his platform, you can't assume it. – Puppy Jan 13 '11 at 14:06
  • @Nawaz Will there be a null terminating character in case of both p1 and p2 declarations? Also will the additional allocation of four or eight bytes of storage depending on the platform would happen in case of p2 as well (same as p1) because p2 is also a pointer in the end? – RBT Sep 21 '16 at 1:43
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    @RBT: It is technically wrong to say that the memory of "read-only string literal pointed to be p1" is part of p1. Take this example, char const *x = "Rasik"; char const *y = "Rasik";. Now print the address of both x and y; they will be same (see demo). What does that mean? You cannot say "Rasik" is part of memory allocated to both x and y. That is wrong. "Rasik" is a different object.... and x and y points to that object. There can be more pointers pointing the same object. Makes sense now? – Nawaz Sep 22 '16 at 5:45

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