12.7. Splitting Variables
Problem
Large scalar variables that cannot be merged, or that have large values that cannot easily be manipulated with a constant transform, need to be obfuscated.
Solution
Splitting variables can be effective when the variables holding the
split values are in different scopes. The split can also be performed
during variable initialization by rewriting the
SPLIT_VAR
macro presented in Section 12.7.3 to declare and
initialize the variables, rather than simply assigning to them.
Discussion
The value of a scalar variable can be split over a number of equal- or smaller-sized variables. The following code demonstrates how the four bytes of an integer can be stored in four different character variables:
#define SPLIT_VAR(in, a, b, c, d) do { \ (a) = (char)((in) >> 24); \ (b) = (char)((in) >> 16); \ (c) = (char)((in) >> 8); \ (d) = (char)((in) & 0xFF); \ } while (0) #define REBUILD_VAR(a, b, c, d) \ ((((a) << 24) & 0xFF000000) | (((b) << 16) & 0x00FF0000) | \ (((c) << 8) & 0x0000FF00) | ((d) & 0xFF))
Each char
variable (a
,
b
, c
, and d
)
is filled with a byte of the original four-byte integer variable.
This is done by shifting each byte in turn into one of the
char
variables. Obviously, the four
char
variables should not be stored contiguously
in memory, or splitting the variable will have no effect.
#include <stdlib.h> char g1, g2; /* store half of the integer here */ void init_rand(char a, char b) { srand(REBUILD_VAR(a, g1, b, g2)); } int main(int argc, char *argv[ ...
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