The maximum ones-representable integer is **2**^{53} (9007199254740992) for a 64-bit double and 2^{24} (16777216) for a 32-bit float. See the base digits on the Wikipedia page for IEEE floating point numbers.

Verifying this in Lua is pretty simple:

```
local maxdouble = 2^53
-- one less than the maximum can be represented precisely
print (string.format("%.0f",maxdouble-1)) --> 9007199254740991
-- the maximum itself can be represented precisely
print (string.format("%.0f",maxdouble)) --> 9007199254740992
-- one more than the maximum gets rounded down
print (string.format("%.0f",maxdouble+1)) --> 9007199254740992 again
```

If we don't have the IEEE-defined field sizes handy, knowing what we know about the *design* of floating point numbers, we can determine these values using a simple loop over the *possible* values:

```
#include <stddef.h>
#include <stdint.h>
#include <stdio.h>
#define min(a, b) (a < b ? a : b)
#define bits(type) (sizeof(type) * 8)
#define testimax(test_t) { \
uintmax_t in = 1, out = 2; \
size_t pow = 0, limit = min(bits(test_t), bits(uintmax_t)); \
test_t t; \
while (pow < limit && out == in + 1) { \
in = in << 1; \
out = (test_t) in + 1; \
++pow; \
} \
if (pow == limit) \
puts(#test_t " is as precise as longest integer type"); \
else printf(#test_t " conversion imprecise for 2^%d+1:\n" \
" in: %llu\n out: %llu\n\n", pow, in + 1, out); \
}
int main(void)
{
testimax(float);
testimax(double);
return 0;
}
```

The output of the above code:

```
float conversion imprecise for 2^24+1:
in: 16777217
out: 16777216
double conversion imprecise for 2^53+1:
in: 9007199254740993
out: 9007199254740992
```

Of course, due to the way floating-point precision works, a 64-bit double can represent numbers much larger than 2^{64} as the floating exponent grows positive. The Wikipedia page on double-precision floating-point describes:

Between 2^{52}=4,503,599,627,370,496 and 2^{53}=9,007,199,254,740,992 the representable numbers are exactly the integers. For the next range, from 2^{53} to 2^{54}, everything is multiplied by 2, so the representable numbers are the even ones, etc. Conversely, for the previous range from 2^{51} to 2^{52}, the spacing is 0.5, etc.

The *absolute largest* value a double can hold is listed further down that page: 0x7fefffffffffffff, which computes to (1 + (1 − 2^{−52})) * 2^{1023}, or roughly 1.7976931348623157e308.