I see that a lot of people answered the question about overflow, but I wanted to address his original problem. He said the problem was to find a^{b}=c such that all digits are used without repeating. Ok, that's not what he asked in this post, but I'm still think that it was necessary to study the upper bound of the problem and conclude that he would never need to calculate or detect an overflow (note: I'm not proficient in math so I did this step by step, but the end result was so simple that this might have a simple formula).

The main point is that the upper bound that the problem requires for either a, b or c is 98.765.432. Anyway, starting by splitting the problem in the trivial and non trivial parts:

- x
^{0} == 1 (all permutations of 9, 8, 7, 6, 5, 4, 3, 2 are solutions)
- x
^{1} == x (no solution possible)
- 0
^{b} == 0 (no solution possible)
- 1
^{b} == 1 (no solution possible)
- a
^{b}, a > 1, b > 1 (non trivial)

Now we just need to show that no other solution is possible and only the permutations are valid (and then the code to print them is trivial). We go back to the upper bound. Actually the upper bound is c ≤ 98.765.432. It's the upper bound because it's the largest number with 8 digits (10 digits total minus 1 for each a and b). This upper bound is only for c because the bounds for a and b must be much lower because of the exponential growth, as we can calculate, varying b from 2 to the upper bound:

```
9938.08^2 == 98765432
462.241^3 == 98765432
99.6899^4 == 98765432
39.7119^5 == 98765432
21.4998^6 == 98765432
13.8703^7 == 98765432
9.98448^8 == 98765432
7.73196^9 == 98765432
6.30174^10 == 98765432
5.33068^11 == 98765432
4.63679^12 == 98765432
4.12069^13 == 98765432
3.72429^14 == 98765432
3.41172^15 == 98765432
3.15982^16 == 98765432
2.95305^17 == 98765432
2.78064^18 == 98765432
2.63493^19 == 98765432
2.51033^20 == 98765432
2.40268^21 == 98765432
2.30883^22 == 98765432
2.22634^23 == 98765432
2.15332^24 == 98765432
2.08826^25 == 98765432
2.02995^26 == 98765432
1.97741^27 == 98765432
```

Notice, for example the last line: it says that 1.97^27 ~98M. So, for example, 1^27 == 1 and 2^27 == 134.217.728 and that's not a solution because it has 9 digits (2 > 1.97 so it's actually bigger than what should be tested). As it can be seen, the combinations available for testing a and b are really small. For b == 14, we need to try 2 and 3. For b == 3, we start at 2 and stop at 462. All the results are granted to be less than ~98M.

Now just test all the combinations above and look for the ones that do not repeat any digits:

```
['0', '2', '4', '5', '6', '7', '8'] 2^84 = 7056
['1', '2', '3', '4', '5', '8', '9'] 2^59 = 3481
['0', '1', '2', '3', '4', '5', '8', '9'] 2^59 = 3481 (+leading zero)
['1', '2', '3', '5', '8'] 3^8 = 512
['0', '1', '2', '3', '5', '8'] 3^8 = 512 (+leading zero)
['1', '2', '4', '6'] 2^4 = 16
['0', '1', '2', '4', '6'] 2^4 = 16 (+leading zero)
['1', '2', '4', '6'] 4^2 = 16
['0', '1', '2', '4', '6'] 4^2 = 16 (+leading zero)
['1', '2', '8', '9'] 2^9 = 81
['0', '1', '2', '8', '9'] 2^9 = 81 (+leading zero)
['1', '3', '4', '8'] 4^3 = 81
['0', '1', '3', '4', '8'] 4^3 = 81 (+leading zero)
['2', '3', '6', '7', '9'] 6^3 = 729
['0', '2', '3', '6', '7', '9'] 6^3 = 729 (+leading zero)
['2', '3', '8'] 3^2 = 8
['0', '2', '3', '8'] 3^2 = 8 (+leading zero)
['2', '3', '9'] 2^3 = 9
['0', '2', '3', '9'] 2^3 = 9 (+leading zero)
['2', '4', '6', '8'] 2^8 = 64
['0', '2', '4', '6', '8'] 2^8 = 64 (+leading zero)
['2', '4', '7', '9'] 2^7 = 49
['0', '2', '4', '7', '9'] 2^7 = 49 (+leading zero)
```

None of them matches the problem (which can also be seen by the absence of '0', '1', ..., '9').

The example code that solves it follows. Also note that's written in python, not because it needs arbitrary precision integers (the code doesn't calculate anything bigger than 98 million), but because we found out that the amount of tests is so small that we should use a high level language to make use of its built-in containers and libraries (also note: the code has 28 lines).

```
import math
m = 98765432
l = []
for i in xrange(2, 98765432):
inv = 1.0/i
r = m**inv
if (r < 2.0): break
top = int(math.floor(r))
assert(top <= m)
for j in xrange(2, top+1):
s = str(i) + str(j) + str(j**i)
l.append((sorted(s), i, j, j**i))
assert(j**i <= m)
l.sort()
for s, i, j, ji in l:
assert(ji <= m)
ss = sorted(set(s))
if s == ss:
print '%s %d^%d = %d' % (s, i, j, ji)
# Try with non significant zero somewhere
s = ['0'] + s
ss = sorted(set(s))
if s == ss:
print '%s %d^%d = %d (+leading zero)' % (s, i, j, ji)
```

`-ftrapv`

will cause it to generate a SIGABRT on (signed) integer overflow. See here. – nibot Oct 17 '12 at 20:12`clz`

instruction or the`__clz(unsigned)`

function to determine the rank of the number (where its highest bit is). Since I'm unsure if this is available on x86 or x64 I will assume it is not and say that finding the most significant bit will take at worst`log(sizeof(int)*8)`

instructions. – nonsensickle Oct 4 '13 at 0:10