I've looked at one too many pieces of source code that uses bit shifting along with bitwise ANDs to extract a value from a larger data size
(for example, an IP address from a 32-bit integer).
This is error-prone. I'm going to show you an easier way, using a C "union".
A C union is just a simple way to refer to the same memory address using more than one symbolic label.
Okay, its not "that" simple, so here's a slightly simpler explanation. You know when you assign an name to a variable, what you're really doing is giving a piece of memory a symbol, a
(symbolic) name you can use to refer to it. So when we write, for example, int x, what we're really doing is giving a 4-byte
(on 32-bit machines) location of ram a label, "x", that we can refer to in our code.
A union takes this a step further, by allowing us to refer to the same memory location by 2 or more names, and access them as if they're 2 or more data types.
What I'm going to do is create a structure that will allow me to stuff a 32-bit integer into a location, and then extract the individual byte values from the same location, or alternately, write 4 individual bytes, and get the 32-bit integer value, all without any shifts or logical ands.
I do this in 2 steps:
[ol]
[li]declare a structure of 4 bytes (4 unsigned chars, to be exact), that I can address as b0, b1, b2 and b3.[/li]
[li]declare a union that allows this 4 byte structure to overlap the same memory address as an unsigned 4-byte integer;[/li]
[/ol]
Here's the code:
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#include <stdio.h>
#include <stdlib.h>
typedef struct packed_int {
unsigned char b0;
unsigned char b1;
unsigned char b2;
unsigned char b3;
} packed_int;
typedef union {
unsigned int i;
packed_int b;
} packed;
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Okay, now I just need some code to "exercise" these structures, to show you that they actually do what I say, without any fancy bit-shifting in the source ...
(note that I'm not including code to account for "endian-ness" - this would be conditionally included by using a compile-time constant, but its left out here for the sake of clarity).
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int main(int argc, char* argv[], char* env[]) {
packed v; /* this is my "dual-purpose" 32-bit memory location */
v.i = 3232235881UL; /* I assign it an internet address in 32-bit format */
/* next, I'll print out the individual bytes */
printf("the bytes are %d, %d, %d, %d\n", v.b.b0, v.b.b1, v.b.b2, v.b.b3);
/* and just to prove that the 32-bit integer is still there ... print it out too */
printf("the value is %u\n", v.i);
/* just for the heck of it, increment the 32-bit integer */
v.i++;
printf("after v.i++, the bytes are %d, %d, %d, %d\n", v.b.b0, v.b.b1, v.b.b2, v.b.b3);
/* now do the reverse, assign 70.80.90.100 as an ip address */
v.b.b0 = 70;
v.b.b1 = 80;
v.b.b2 = 90;
v.b.b3 = 100;
/* .. and extract the 32-bit integer value */
printf("the value is %u\n", v.i);
/* show that 70.80.90.100 is really what we put in there */
printf("the bytes are %d, %d, %d, %d\n", v.b.b0, v.b.b1, v.b.b2, v.b.b3);
/* ok, we're done here */
return EXIT_SUCCESS;
}
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Now, isn't that a lot easier than creating some freak-show macros to do bit manipulation? BTW, the same trick works for point_t, rect_t, time_t, 64, 128, and 256 bit values, as well as individual bits.
In a future post, I'll show you how to write code to select individual bits without bothering with bitmasks.
my original article source: [[http://trolltalk.com/index.php?name=News&file=article&sid=2]]