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I can't say that I know C/C++ bad, but I've encountered with interesting syntax. I have this code:

int i=7;
char* m=(char*)&i;
m[2]=9;
cout<<i;

Its output 589831. So can someone explain me in details what is going here.

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closed as too localized by simonc, Bo Persson, C. A. McCann, Dante is not a Geek, 0x499602D2 Dec 3 '12 at 2:18

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1  
589831 is 090007 in hexa – Eugen Constantin Dinca Dec 2 '12 at 23:07
    
You can verify this if you have Win7. Start the calculator, switch it to programmers view. In Dec (decimal) mode type in 589831. Then switch to bin or hex. – Steve Wellens Dec 2 '12 at 23:07
    
In technical terms, this is known as "crappy code". – brian beuning Dec 3 '12 at 0:40
up vote 3 down vote accepted

The integer i very likely takes 4 bytes, arranged with the lowest value first (little endian). In memory the values look like this:

0x07 0x00 0x00 0x00

You changed the value at index 2 so now it looks like:

0x07 0x00 0x09 0x00

If you reverse the bytes and put them back together, they make the hex value 0x00090007 which is the same as 589831 in decimal.

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  1. a 4-byte integer is filled with the number 7.
  2. the 4-byte integer is mapped to an array of four single bytes (chars). On a little-endian architecture like x86 the least significant bytes come first in a number, so the array looks like this in memory: { 07, 00, 00, 00 }
  3. the 3rd byte of the integer slash byte array is changed to 9. It now looks like this: { 07, 00, 09, 00 }
  4. the resulting integer (hexadecimal 90007) is written to stdout (in decimal format: 589831).

Long story short, it's an example how you can manipulate individual bytes in a multi-byte integer.

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You are casting the integer address to a char* then modifying it using array notation. This step

m[2] = 9;

is the same as the pointer arithmetic

*(m+2) = 9;

that is to say, it is modifying the byte at address of m + 2 bytes. Thus you have changed one of the bytes (3rd) in your initial integer value

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Here is my breakdown of what is going on, then an explanation.

// An integer on the stack, probably 4 bytes big, but we can't say that for sure.
int i=7; // Looks like 0x0000007 in memory. Endianness needs to be considered.

// Treat that integer as a \0 terminated string.
char* m=(char*)&i; // Acts as an empty string since the first byte is a 0, but we can't count on that.

// Set the second byte to 9.
m[2]=9; // Results in i being 0x00090007 (589831 decimal) on whatever architecture you are running. Once again, can't count on it.

// Print the modified integer.
cout<<i;

This is an incredibly dangerous and stupid thing to do for three reasons...

  1. You should not count on the endianness of your architecture. Your code may end up running on a CPU that has a different underlying representation of what an int is.

  2. You cannot count on int to always be 4 bytes.

  3. You now have a char* that if you ever go to perform a string operation on it could cause a crash. In your specific case, it will print an empty string, but it would not take much for that integer to not have a 0 byte in it and go on reading other parts of your stack.

If you really, really, really need to do this, the preferred method is to use unions but this kind of bit twiddling is very error prone and unions do very little to help.

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2  
“// Treat that integer as a \0 terminated string.” char* means, literally, pointer to char. A pointer to char may be used to point to a \0-terminated string but it is not a fault of the code being discussed, whatever its qualities, to use a char * to point to something other than a \0-terminated string. No-one ever said that was the only thing a char * could point to. – Pascal Cuoq Dec 2 '12 at 23:35
    
I suppose you are correct. I guess when I see a char* my brain heads straight to: this is a string. In this case, it is being treated as a char array with no terminator. – Sean Cline Dec 3 '12 at 0:13

int i=7 reserves 4 bytes of memory for integer and depending on CPU architecture (lets say yours is i86) would produce something like this in memory 7 0 0 0

then a pointer m created to point at the beginning of 7 0 0 0 . after m[2] = 9 memory should look like 7 0 9 0 (arrays are zero based);

then you printout i

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