In C, I can do like this:
char *s ="hello";
So I wonder what is the difference? I want to know what actually happens in memory allocation during compile time and run time.
The difference here is that
will place Hello world in the read-only parts of the memory and making s a pointer to that, making any writing operation on this memory illegal. While doing:
puts the literal string in read-only memory and copies the string to newly allocated memory on the stack. Thus making
First off, in function arguments, they are exactly equivalent:
In other contexts,
Note that you must not ever attempt to modify the contents of this anonymous array via this pointer; the effects are undefined (often meaning a crash):
Using the array syntax directly allocates it into new memory. Thus modification is safe:
However the array only lives as long as its contaning scope, so if you do this in a function, don't return or leak a pointer to this array - make a copy instead with
Creates one object - a
On the other hand, this declaration:
Creates two objects:
The unnamed read-only array is typically located in the "text" segment of the program, which means it is loaded from disk into read-only memory, along with the code itself. The location of the
Given the declarations
assume the following hypothetical memory map:
0x01 0x02 0x03 0x04 0x00008000: 'h' 'e' 'l' 'l' 0x00008004: 'o' ' ' 'w' 'o' 0x00008008: 'r' 'l' 'd' 0x00 ... s0: 0x00010000: 0x00 0x00 0x80 0x00 s1: 0x00010004: 'h' 'e' 'l' 'l' 0x00010008: 'o' ' ' 'w' 'o' 0x0001000C: 'r' 'l' 'd' 0x00
The string literal
You can reassign the variable
In the light of comments here it should be obvious that : char * s = "hello" ; Is a bad idea, and should be used in very narrow scope.
This might be a good opportunity to point out that "const correctness" is a "good thing". Whenever and wherever You can, use the "const" keyword to protect your code, from "relaxed" callers or programmers, which are usually most "relaxed" when pointers come into play.
Enough melodrama, here is what one can achieve when adorning pointers with "const". (Note: One has to read pointer declarations right-to-left.) Here are the 3 different ways to protect yourself when playing with pointers :
— that is, the DBJ object can't be changed via p.
— that is, you can change the DBJ object via p, but you can't change the pointer p itself.
— that is, you can't change the pointer p itself, nor can you change the DBJ object via p.
The errors related to attempted const-ant mutations are caught at compile time. There is no runtime space or speed penalty for const.
(Assumption is you are using C++ compiler, of course ?)
A string literal is used to create these character blocks somewhere in the memory which this pointer
Just to add: you also get different values for their sizes.
As mentioned above, for an array
In the case of:
x is an lvalue -- it can be assigned to. But in the case of:
x is not an lvalue, it is an rvalue -- you cannot assign to it.
C99 N1256 draft
EXAMPLE 8: The declaration
defines "plain" char array objects
This declaration is identical to
The contents of the arrays are modifiable. On the other hand, the declaration
GCC 4.8 x86-64 ELF implementation
Compile and decompile:
Conclusion: GCC stores
If we do the same for
so it gets stored in the stack (relative to
Note however that the default linker script puts
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