Doubles in IEE754 have a precision of 52 bits which means they can store numbers accurately up to (at least) 2^{51}.

If your longs are 32-bit, they will only have the (positive) range 0 to 2^{31} so there is no 32-bit long that cannot be represented exactly as a double. For a 64-bit long, it will be (roughly) 2^{52} so I'd be starting around there, not at zero.

You can use the following program to detect where the failures start to occur. An earlier version I had relied on the fact that the last digit in a number that continuously doubles follows the sequence {2,4,8,6}. However, I opted eventually to use a known trusted tool `(bc)`

for checking the whole number, not just the last digit.

Keep in mind that this *may* be affected by the actions of `sprintf()`

rather than the real accuracy of doubles (I don't think so personally since it had no troubles with certain numbers up to 2^{143}).

This is the program:

```
#include <stdio.h>
#include <string.h>
int main() {
FILE *fin;
double d = 1.0; // 2^n-1 to avoid exact powers of 2.
int i = 1;
char ds[1000];
char tst[1000];
// Loop forever, rely on break to finish.
while (1) {
// Get C version of the double.
sprintf (ds, "%.0f", d);
// Get bc version of the double.
sprintf (tst, "echo '2^%d - 1' | bc >tmpfile", i);
system(tst);
fin = fopen ("tmpfile", "r");
fgets (tst, sizeof (tst), fin);
fclose (fin);
tst[strlen (tst) - 1] = '\0';
// Check them.
if (strcmp (ds, tst) != 0) {
printf( "2^%d - 1 <-- bc failure\n", i);
printf( " got [%s]\n", ds);
printf( " expected [%s]\n", tst);
break;
}
// Output for status then move to next.
printf( "2^%d - 1 = %s\n", i, ds);
d = (d + 1) * 2 - 1; // Again, 2^n - 1.
i++;
}
}
```

This keeps going until:

```
2^51 - 1 = 2251799813685247
2^52 - 1 = 4503599627370495
2^53 - 1 = 9007199254740991
2^54 - 1 <-- bc failure
got [18014398509481984]
expected [18014398509481983]
```

which is about where I expected it to fail.

As an aside, I originally used numbers of the form 2^{n} but that got me up to:

```
2^136 = 87112285931760246646623899502532662132736
2^137 = 174224571863520493293247799005065324265472
2^138 = 348449143727040986586495598010130648530944
2^139 = 696898287454081973172991196020261297061888
2^140 = 1393796574908163946345982392040522594123776
2^141 = 2787593149816327892691964784081045188247552
2^142 = 5575186299632655785383929568162090376495104
2^143 <-- bc failure
got [11150372599265311570767859136324180752990210]
expected [11150372599265311570767859136324180752990208]
```

with the size of a double being 8 bytes (checked with `sizeof`

). It turned out these numbers were of the binary form `"1000..."`

which can be represented for far longer with doubles. That's when I switched to using 2^{n}-1 to get a better bit pattern: all one bits.

Allpowers of two are representable exactly as double, so if your binary search happened to walk powers of two, it might completely miss finding the desired point... :-) – R.. Jan 29 '12 at 2:18