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I wrote a small program which reverses a string and prints it to screen:

void ReverseString(char *String)
    char *Begin = String;
    char *End = String + strlen(String) - 1;
    char TempChar = '\0';

    while (Begin < End) 
        TempChar = *Begin;
        *Begin = *End;
        *End = TempChar;

It works perfectly in Dev C++ on Windows (little endian). But I have a sudden doubt of its efficiency. If you look at this line:

while (Begin < End) 

I am comparing the address of the beginning and end. Is this the correct way? Does this code work on a big endian OS like Mac OS X ? Or am I thinking the wrong way ?

I have got several doubts which I mentioned above. Can anyone please clarify ?

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As a minor nit-pick, there's no point in having TempChar outside the loop, and also no point in initializing it. Move it inside the loop, and make it const: const TempChar = *Begin;. –  unwind May 4 '11 at 7:10
Another minor nitpick - Mac OS X is not big endian, it can be either big or little endian as it runs on x86 (little endian), PowerPC (big endian) and other architectures. –  Paul R May 4 '11 at 7:16
If you're looking for issues, this code has undefined behavior when passed an empty string located at the start of an array - it's not valid to take a "one before the beginning" pointer. In practice it will work anywhere with a flat memory model, and probably most places without. –  Steve Jessop May 4 '11 at 8:31

4 Answers 4

Your code has no endianness-related issues. There's also nothing wrong with the way you're comparing the two pointers. In short, your code's fine.

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can you explain me it in detail about why do u think that its correct? –  Vijay May 4 '11 at 6:47
@Zombie: There are only pointers and characters (bytes) in your code. The bytes are by definition endian-neutral. And all you do with the pointers is read, assign, increment and decrement, all of which are endian-neutral operations. You're dereferencing bytes which is also endian-neutral. So everything's fine. –  DarkDust May 4 '11 at 7:06

Endianness is defined as the order of significance of the bytes in a multi-byte primitive type. So if your int is big-endian, that means the first byte (i.e. the one with the lowest address) of an int in memory contains the most significant bits of the int, and so on to the last/least significant. That's all it means. When we say a system is big-endian, that generally means that all of its pointer and arithmetic types are big-endian, although there are some odd special cases out there. Endian-ness doesn't affect pointer arithmetic or comparison, or the order in which strings are stored in memory.

Your code does not use any multi-byte primitive types[*], so endian-ness is irrelevant. In general, endian-ness only becomes relevant if you somehow access the individual bytes of such an object (for example by casting a pointer to unsigned char*, writing the memory to a file or over the network, and the like).

Supposing a caller did something like this:

int x = 0x00010203; // assuming sizeof(int) == 4 and CHAR_BIT == 8
ReverseString((char *)&x);

Then their code would be endian-dependent. On a big-endian system, they would pass you an empty string, since the first byte would be 0, so your code would leave x unchanged. On a little-endian system they would pass you a three-byte string, since the first three bytes would be 0x03, 0x02, 0x01 and the fourth byte 0, so your code would change x to 0x00030201

[*] well, the pointers are multi-byte, on OSX and on pretty much every C implementation. But you don't inspect their storage representations, you just use them as values, so there's no opportunity for behavior to differ according to endianness.

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As far as I know, endianness does not affect a char * as each character is a single byte and forms an array of characters. Have a look at http://www.ibm.com/developerworks/aix/library/au-endianc/index.html?ca=drs- The effect will be seen in multi byte data types like int.

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As long as you manipulate whole type T objects (which is what you do with type T being char) you just can't run into endianness problems.

You could run into them if you for example tried to manipulate separate bytes within a larger type (an int for example) but you don't do anything like that. This is why endianness problems are impossible in your code, period.

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