Neither 3.2 nor .8 is exactly representable as a 32-bit float. The representable number closest to 3.2 is 3.2000000476837158203125 (in hexadecimal floating-point, 0x1.99999ap+1). The representable number closest to .8 is 0.800000011920928955078125 (0x1.99999ap-1).
When 0.800000011920928955078125 is subtracted from 3.2000000476837158203125, the exact mathematical result is 2.400000035762786865234375 (0x1.3333338p+1). This result is also not exactly representable as a 32-bit float. (You can see this easily in the hexadecimal floating-point. A 32-bit float has a 24-bit significand. “1.3333338” has one bit in the “1”, 24 bits in the middle six digits, and another bit in the ”8”.) So the result is rounded to the nearest 32-bit float, which is 2.400000095367431640625 (0x1.333334p+1).
Subtracting 0.800000011920928955078125 from that yields 1.6000001430511474609375 (0x1.99999cp+0), which is exactly representable. (The “1” is one bit, the five nines are 20 bits, and the “c” has two significant bits. The low bits two bits in the “c” are trailing zeroes and may be neglected. So there are 23 significant bits.)
Subtracting 0.800000011920928955078125 from that yields 0.800000131130218505859375 (0x1.99999ep-1), which is also exactly representable.
Finally, subtracting 0.800000011920928955078125 from that yields 1.1920928955078125e-07 (0x1p-23).
The lesson to be learned here is the floating-point does not represent all numbers, and it rounds results to give you the closest numbers it can represent. When writing software to use floating-point arithmetic, you must understand and allow for these rounding operations. One way to allow for this is to use numbers that you know can be represented. Others have suggested using integer arithmetic. Another option is to use mostly values that you know can be represented exactly in floating-point, which includes integers up to 224. So you could start with 32 and subtract 8, yielding 24, then 16, then 8, then 0. Those would be the intermediate values you use for loop control and continuing calculations with no error. When you are ready to deliver results, then you could divide by 10, producing numbers near 3.2, 2.4, 1.6, .8, and 0 (exactly). This way, your arithmetic would introduce only one rounding error into each result, instead of accumulating rounding errors from iteration to iteration.