# Precision of multiplication by 1.0 and int to float conversion

Is it safe to assume that the condition `(int)(i * 1.0f) == i` is true for any integer `i`?

• I suppose it is, because any mantissa bits will be lost. I don't know if `int` gets promoted to `float` however. – Tony The Lion Nov 15 '12 at 15:32
• My vote is on YES – Steven Nov 15 '12 at 15:32
• For some reason, I want to say no, but I really have no justification for it... :-] – user131441 Nov 15 '12 at 15:32
• @John: I have the same feeling. I was also thinking about large integers, and whether there's any guarantee about multiplying by `1.0`... probably in IEEE754 the answer is "yes", though. – Kerrek SB Nov 15 '12 at 15:33
• @John: that was my initial feeling as well, now I just plain don't know :) – Violet Giraffe Nov 15 '12 at 15:34

No.

If `i` is sufficiently large that `int(float(i)) != i` (assuming float is IEEE-754 single precision, `i = 0x1000001` suffices to exhibit this) then this is false, because multiplication by `1.0f` forces a conversion to `float`, which changes the value even though the subsequent multiplication does not.

However, if `i` is a 32-bit integer and `double` is IEEE-754 double, then it is true that `int(i*1.0) == i`.

Just to be totally clear, multiplication by `1.0f` is exact. It's the conversion from `int` to `float` that may not be.

• To add to this answer: in simple terms the loss of precision is due the fact that float has only 24 bits to accommodate the int, where as an int has 32 bits therefore the least significant bits will be rounded during the cast. – Ifthikhan Nov 15 '12 at 15:52
• rounded, not discarded, but yes, exactly. – Stephen Canon Nov 15 '12 at 15:53
• @anatolyg: No. In C++ this is governed by paragraph 10 of section 5 (the usual arithmetic conversions): "if either operand is float, the other shall be converted to float." So `i` is converted to `float` before the multiplication, which causes rounding. – Stephen Canon Nov 15 '12 at 15:59
• @MichaelShopsin: Exactly one of `a <= b` or `a > b` is true unless `a` or `b` is a NaN. – Eric Postpischil Nov 16 '12 at 2:22
• @MichaelShopsin: You're both right. Eric's statement is absolutely true of floating-point numbers as defined by the standard. However, there have been well documented compiler bugs that produced the behavior that Michael describes. To be clear though, this is not a problem of floating-point comparisons; it's a problem of buggy compilers. – Stephen Canon Nov 16 '12 at 18:28

No, IEEE-754 floating point numbers have a greater dynamic range than integers at the cost of integer precision for the same bit width.

See for example the output of this little snippet:

``````int main() {
int x = 43046721;

float y = x;

printf("%d\n", x);
printf("%f\n", y);
}
``````

`43046721` cannot be represented correctly in the 24 bits of precision available in a 32-bit `float` number, so the output is something along these lines:

``````43046721
43046720.000000
``````

In fact, I would expect any odd number above 16,777,216 to have the same issue when converting to a 32-bit `float` number.

A few points of interest:

• This has more to do with the implicit int-to-float conversion than with the multiplication itself.

• This is not by any mean unique to C - for example Java is also subject to the exact same issue.

• Most compilers have optimization options that may affect how such conversions are handled, by ignoring certain restrictions of the standard. In such a case, `(int)((float)x * 1.0f) == x` might always be `true` if the compiler optimizes out the conversion to `float` and back.

No, the behavior is implementation defined because C and C++ don't require IEEE-754, even though that is the most common representation by far.

To be sure that IEEE-754 is used:

• in C, use `#ifdef __STDC_IEC_559__`
• in C++, use the `std::numeric_limits<float>::is_iec559` constants
• Good to know, thanks! Do you know of any modern (or currently being used) implementations that do NOT conform to IEEE-754? – Violet Giraffe Jun 15 '15 at 15:32

No it is absolutely wrong for all the integers because of the type cast. check code.

``````#include <stdio.h>

int main()
{
int i = 0;
for (; i < 2147483647; ++i) {
if ((int)(i * 1.0f) != i) {
printf("not equal\n");
break;
}
}
printf("out of the loop\n");
getchar();
return 0;
}
``````

This code assumes that you take 32 bit integer

• 32767 != INT_MAX for 32-bit integers. – Stephen Canon Nov 15 '12 at 15:42
• Uh, you did run this program, right? Because it actually prints "not equal" on my system, as it should... – thkala Nov 15 '12 at 15:56
• @thkala It doesn't print "not equal" over here, my system is 32-bit if that matters. – user1551592 Nov 15 '12 at 16:26
• @user9000: what platform and compiler are you using? – thkala Nov 15 '12 at 16:32
• @thkala It is allowed that floating point computations are carried out at greater precision and range than the type specifies. So it's allowed that the compiler uses `double`s or even `long double` or the extended 80-bit x87 floating point numbers, in which case it's legitimate that "not equal" is not printed. Another (unlikely) possibility is that `float` has at least 31 bits of precision already. But with the standard IEEE754 32-bit `float`s, it must print "not equal" if the test is changed to `if ((int)((float)i * 1.0f) != i)`. – Daniel Fischer Nov 15 '12 at 16:41