I saw this question,and pop up this idea.

There exists a pretty fast method for integers of limited size (e.g. 32bit integers). Note that for an integer N that is a power of 3 the following is true:
The biggest power of 3 that fits into 32 bits is






Here is a nice and fast implementation of Ray Burns's method in C:
It uses the multiplicative inverse trick for to first divide by 3^10 and then by 3^5. Finally, it needs to check whether the result is 1, 3, 9, 27, 81, or 243, which is done by some simple hashing that I found by trialanderror. On my CPU (Intel Sandy Bridge), it is quite fast, but not as fast as the method of starblue that uses the binary logarithm (which is implemented in hardware on that CPU). But on a CPU without such an instruction, or when lookup tables are undesirable, it might be an alternative. 


Between powers of two there is at most one power of three. So the following is a fast test:
The runtime depends mostly on the time needed for accessing the table entry. If we are using machine integers the table is small, and probably in cache (we are using it many millions of times, otherwise this level of optimization wouldn't make sense). 


Simple and constanttime solution:



Very interesting question, I like the answer from starblue, and this is a variation of his algorithm which will converge little bit faster to the solution:



I'm surprised at this. Everyone seems to have missed the fastest algorithm of all. The following algorithm is faster on average  and dramatically faster in some cases  than a simple
The numeric constants in the code are 3^10, 3^5, and 3^3. Performance calculations In modern CPUs, If input values are evenly distributed over the range of
This algorithm outperforms the simple
What is perhaps even more important, this algorithm handles midsize and large powers of three (and multiples thereof) much more efficiently: In the worst case the simple algorithm will consume over 100 CPU cycles because it will loop 20 times (41 times for 64 bits). The algorithm I present here will never take more than about 25 cycles. Extending to 64 bits Extending the above algorithm to 64 bits is trivial  just add one more step. Here is a 64 bit version of the above algorithm optimized for processors without efficient 64 bit division:
The new constant is 3^20. The optimization lines are omitted from the top of the method because under our assumption that 64 bit division is slow, they would actually be slow things down. Why this technique works Say I want to know if "100000000000000000" is a power of 10. I might follow these steps:
Because I started with a power of 10, every time I divided by a power of 10 I ended up with either a zero quotient or a zero remainder. Had I started out with anything except a power of 10 I would have sooner or later ended up with a nonzero quotient or remainder. In this example I selected exponents of 10, 5, and 3 to match the code provided previously, and added 2 just for the heck of it. Other exponents would also work: There is a simple algorithm for selecting the ideal exponents given your maximum input value and the maximum power of 10 allowed in the output, but this margin does not have enough room to contain it. NOTE: You may have been thinking in base ten throughout this explanation, but the entire explanation above can be read and understood identically if you're thinking in in base three, except the exponents would have been expressed differently (instead of "10", "5", "3" and "2" I would have to say "101", "12", "10" and "2"). 


For really large numbers
which is really slow and most likely the choke point of any algorithm that relies on repeated checking of remainders. You have to understand modular arithmetic to follow what I am doing, which is part of elementary number theory. Let x = Σ _{k} a _{k} 2 ^{ k } be the number of interest. We can let the upper bound of the sum be ∞ with the understanding that a _{k} = 0 for some k > M. Then 0 ≡ x ≡ Σ _{k} a _{k} 2 ^{ k } ≡ Σ _{k} a _{2k} 2 ^{2k} + a _{2k+1} 2 ^{2k+1} ≡ Σ _{k} 2 ^{2k} ( a _{2k} + a _{2k+1} 2) ≡ Σ _{k} a _{2k} + a _{2k+1} 2 (mod 3) since 2^{2k} ≡ 4 ^{k} ≡ 1^{k} ≡ 1 (mod 3). Given a binary representation of a number x with 2n+1 bits as x_{0} x_{1} x_{2} ... x_{2n+1} where x_{k} ∈{0,1} you can group odd even pairs (x_{0} x_{1}) (x_{2} x_{3}) ... (x_{2n} x_{2n+1}). Let q denote the number of pairings of the form (1 0) and let r denote the number of pairings of the form (0 1). Then it follows from the equation above that 3  x if and only if 3  (q + 2r). Furthermore, you can show that 3(q + 2r) if and only if q and r have the same remainder when divided by 3. So an algorithm for determining whether a number is divisible by 3 could be done as follows
This algorithm is more efficient than the use of %. 


Note that 1 is the zeroth power of three. Edit: You also need to check for zero before the loop, as the loop will not terminate for n = 0 (thanks to Bruno Rothgiesser). 


If you are running Python, you can try using this (broken because of rounding error) code.
The test shown below that it is only reliable on the lower values of 3 ** X. Rounding can help, but starblue's answer is certainly superior to any other way of solving your question.



You can do better than repeated division, which takes O(lg(X) * division) time. Essentially you do a binary search on powers of 3. Really we will be doing a binary search on N, where 3^N = input value). Setting the Pth binary digit of N corresponds to multiplying by 3^(2^P), and values of the form 3^(2^P) can be computed by repeated squaring. Algorithm
Complexity: O(lg(lg(X)) * multiplication)  Generating and iterating over L takes lg(lg(X)) iterations, and multiplication is the most expensive operation in an iteration. 


I find myself slightly thinking that if by 'integer' you mean 'signed 32bit integer', then (pseudocode)
has a certain beautiful simplicity to it (the last number is 3^19, so there aren't an absurd number of cases). Even for an unsigned 64bit integer there still be only 41 cases (thanks @Alexandru for pointing out my brainslip). And of course would be impossible for arbitraryprecision arithmetic... 


Set based solution...
With 


if (log n) / (log 3) is integral then n is a power of 3. 


How large is your input? With O(log(N)) memory you can do faster, O(log(log(N)). Precompute the powers of 3 and then do a binary search on the precomputed values. 


Recursively divide by 3, check that the remainder is zero and reapply to the quotient. Note that 1 is a valid answer as 3 to the zero power is 1 is an edge case to beware. 

