This is compiled with GCC in CC mode.
I'm looking at some basic interpreter code, and this code is run when parsing the "AND" operator. int_one and int_two are the integer values of the arguments to AND like this in basic:
int_one AND int_two
This portion of the interpreter has already determined that the arguments are integer types (instead of real types), so why do we care how they compare when cast as reals?
i'm not 100% sure what this check does, and furthermore, why it almost always evaluates to false! What is the significance of this check, and why on earth is it false?
Here is some tester code that illustrates some probably false assumptions about buffering the and results, which gives a different result:
#include <stdio.h>
#include <stdlib.h>
int one, two;
int main()
{
// Initialize
one = 3;
two = 3;
// do a test with buffering the and result
float int_and_cast_to_real = (float)(one && two);
float int_cast_to_real_and = (float)one && (float)two;
if (int_and_cast_to_real == int_cast_to_real_and) {
// This message gets fired, so the buffered results are true.
printf("oh they are equal buddy\n");
} else {
printf("you think they'd be equal, but they aint.\n");
}
// do it all at once
if((float)(one && two) == (float)one && (float)two) {
printf("int & real ands give equal result\n");
} else {
// This message gets fired, so the unbuffered results are false.
printf("int & real ands give inequal result\n");
}
return 0;
}
&&
has lower precedence than==
.