1

I have two integer variables:

int i1 = 0xdeadbeef and int i2 = 0xffffbeef.

(11011110101011011011111011101111 or 37359285591 and 111111111111111110111110111011111 or 4294950639 respectively).


(int) (float) i1 == i1 evaluates as false, yet (int) (float) i2 == i2 evaluates as true.

Why is this? In this system, both ints and floats are stored in 4 bytes.

7
  • 1
    None of those hex constants will fit inside a 32 bit int, because it's a signed type with 31 value bits only.
    – Lundin
    Feb 24 at 7:34
  • @tadman It's an exam question, not my own code. I did get some warnings when I put those statements through the compiler, and now I'm just wondering why the two answers are different.
    – Aidan M
    Feb 24 at 7:46
  • This exam is just plain broken then. int is typically constrained to +/-2.1e9 and anything outside of those bounds is undefined behaviour. If these were unsigned int or uint32_t, then the values are valid, but you still have the problem with float.
    – tadman
    Feb 24 at 7:47
  • @tadman Interesting. So why are the results different if they are both UB? Why does deadbeef just happens to work and the exam question is flawed?
    – Aidan M
    Feb 24 at 7:53
  • 2
    @tadman "int is typically constrained to +/-2.1e9 and anything outside of those bounds is undefined behaviour" --> int i1 = 0xdeadbeef is not UB. Conversion "... result is implementation-defined or an implementation-defined signal is raised." Feb 24 at 11:00
3

This is because float has far less precision than int, it can't store all possible int values without them suffering some damage. Sometimes this damage just rounds your value, sometimes your rounded value matches precisely.

A 32-bit float can only store 24 "significand bits", or numerical data. Other bits are reserved for things like exponent, NaN flagging, Infinity and so on, where that eats into the remaining storage space.

A double does have the required precision as it's usually a 64-bit representation that can store 53 bits of numerical data data.

2

Lots of conversions going on.

int i1 = 0xdeadbeef; int i2 = 0xffffbeef incur implementation defined conversions as the constants are out of int range. Here, they are "wrapped".

i2 is a small value (15 significant bits) exactly representable as a float.

i1 is not. i1 has 30 significant bits, 6 more than the 24 of float. Those lower 6 are not 0, so (float) i1 results is a rounded value.

int main() {
  int i1 = 0xdeadbeef;
  int i2 = 0xffffbeef;
  printf("%d\n", (int) (float) i1 == i1);
  printf("%d\n", (int) (float) i2 == i2);
  printf("%u %10d %17f %10d\n", 0xdeadbeef, i1, (float) i1, (int) (float) i1);
  printf("%u %10d %17f %10d\n", 0xffffbeef, i2, (float) i2, (int) (float) i2);
}

Output

0
1
3735928559 -559038737 -559038720.000000 -559038720
4294950639     -16657     -16657.000000     -16657
0

C implementations commonly use a 32-bit int, and 0xdeadbeef does not fit in 32 bits (one sign bit and 32 value bits). Initializing i1 with 0xdeadbeef results in a conversion to int. This conversion is implementation-defined. GCC, for example, defines it to wrap modulo 232, and this is not uncommon.

So int i1 = 0xdeadbeef; initializes i1 to deadbeef16 − 232 = 3735928559 − 232 = −559038737 = −2152411116. As you can see from the 8 hexadecimal digits in “−21524111,” this number spans 30 bits from its leading 1 bit to its trailing 1 bit, inclusive (32 bits in 8 digits, but the first two are zeros). The format commonly used for float, IEEE-754 binary32, has only 24 bits in its significand. Any number spanning more than 24 bits in its significant bits does not fit in the format and will be rounded when converted to this float format. So i1 != (int) (float) i1.

In contrast, int i12 = 0xffffbeef; initializes i2 to ffffbeef16 − 232 = 4294950639 − 232 = −16657 = −411116. This spans 15 bits (16 bits in 4 digits, but the first one is a zero). So it fits in the 24 bits of a float significand, and its value does not change when converted to float. So i2 == (int) (float) i2.

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