A common assumption is that `1 / x * x == 1`

. What is the least positive integer that breaks this on common IEEE 754-compliant hardware?

When the assumption of a multiplicative inverse fails, poorly-written rational arithmetic ceases to work. Because many languages including C and C++ by default convert floating-point numbers to integers using round-to-zero, even a small error can cause an integral result to be off by one.

A quick test program produces various results.

```
#include <iostream>
int main () {
{
double n;
for ( n = 2; 1 / n * n == 1; ++ n ) ;
std::cout << n << " (" << 1 - 1/n*n << ")\n";
for ( ; (int) ( 1 / n * n ) == 1; ++ n ) ;
std::cout << n << " (" << 1 - 1/n*n << ")\n";
}
{
float n;
for ( n = 2; 1 / n * n == 1; ++ n ) ;
std::cout << n << " (" << 1 - 1/n*n << ")\n";
for ( ; (int) ( 1 / n * n ) == 1; ++ n ) ;
std::cout << n << " (" << 1 - 1/n*n << ")\n";
}
}
```

On ideone.com using GCC 4.3.4 the results are

```
41 (5.42101e-20)
45 (5.42101e-20)
41 (5.42101e-20)
45 (5.42101e-20)
```

Using GCC 4.5.1 produces the same results but the error margins are reported to be exactly zero.

On my machine (GCC 4.7.2 or Clang 4.1), the results are

```
49 (1.11022e-16)
49 (1.11022e-16)
41 (5.96046e-08)
41 (5.96046e-08)
```

This is regardless of the `--fast-math`

option. Using `-mfpmath=387`

surprisingly produces

```
41 (5.42101e-20)
41 (5.42101e-20)
41 (5.42101e-20)
41 (5.42101e-20)
```

The value 5×10^{-20} seems to imply epsilon corresponding to a 64-bit mantissa, i.e. internal calculations using Intel 80-bit extended precision.

This seems to be highly dependent on FPU hardware. Is there a reliable value that's good for testing?

Note: I don't care what language standards or compilers guarantee about floating point number systems, although I don't think there are many meaningful guarantees in any common programming system. I'm wondering about the interaction between the numbers and real-world computers.

`1/3 * 3`

since`1/3`

can't be represented exactly in binary floating-point. The only way it turns out exact is if`1/3 * 3`

happens to rounds towards`1`

instead of`0.99999...`

or`1.00000001`

or something. – Mysticial Nov 26 '12 at 7:23`1/x*x==1`

fails or for which x there exists an r such that`x*r==1`

evaluates to true provides little insight about how floating-point works and provides little basis for predicting or controlling errors in any other situation. Additionally, the question dismisses language standards or compilers but attempts to use languages and compilers to investigate the issue experimentally. – Eric Postpischil Nov 26 '12 at 14:12xis the least integer that has this error. It is just a random question with little relevance to anything else. This is not how people who engineer floating-point computations work with floating point. – Eric Postpischil Nov 26 '12 at 17:38