Log and power are expensive operations. If you want fast, you probably want to look up the IEEE binary exponent in table to get the approximate power of ten, and then check if the mantissa forces a change by +1 or not. This should be 3 or 4 *integer* machine instructions (alternatively O(1) with a pretty small constant).

Given tables:

```
int IEEE_exponent_to_power_of_ten[2048]; // needs to be 2*max(IEEE_exponent)
double next_power_of_ten[600]; // needs to be 2*log10(pow(2,1024)]
// you can compute these tables offline if needed
for (p=-1023;p>1023;p++) // bounds are rough, see actual IEEE exponent ranges
{ IEEE_exponent_to_power_of_ten[p+1024]=log10(pow(2,p)); // you might have to worry about roundoff errors here
next_power_of_ten[log10(pow(2,p))+1024]=pow(10,IEEE_exponent_to_power_of_ten[p+1024]);
}
```

then your computation should be:

```
power_of_ten=IEEE_exponent_to_power_of_10[IEEE_Exponent(x)+1023];
if (x>=next_power_of_ten[power_of_ten]) power_of_ten++;
answer=next_power_of_ten[power_of_ten];
```

[You might really need to write this as assembler to squeeze out every last clock.]
[This code not tested.]

However, if you insist on doing this in python, the interpreter overhead may swamp the log/exp time and it might not matter.

So, do you want fast, or do you want short-to-write?

EDIT 12/23: OP now tells us that his "x" is integral. Under the assumption that it is a 64 (or 32) bit integer, my proposal still works but obviously there isn't an "IEEE_Exponent". Most processors have a "find first one" instruction that will tell you the number of 0 bits on the left hand (most significant) part of the value, e.g., leading zeros; you likely This is in essence 64 (or 32) minus the power of two for the value. Given exponent = 64 - leadingzeros, you have the power of two exponent and most of the rest of the algorithm is essentially unchanged (Modifications left for the reader).

If the processor doesn't have a find-first-one instruction, then probably the best bet is a balanced discrimination tree to determine the power of ten. For 64 bits, such a tree would take at most 18 compares to determine the exponent (10^18 ~~ 2^64).

`10**(int(math.log10(987654321987654321)))`

, which is actually rather impressive. – Rafe Kettler Dec 22 '10 at 21:07`x`

. You'll probably want to profile a hybrid approach. – Nick Larsen♦ Dec 22 '10 at 22:01`x`

is an integer, but I guess it shouldn't change that much (could cast a float`x`

in an integral value and vice versa). – peoro Dec 23 '10 at 11:32