Given a large N, I need to iterate through all phi(k) such that 1 < k < N quickly. Since the values of N will be around 10^{12}, it is important that the memory complexity is sub O(n).
Is it possible? If so, how?
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This can be done with Memory complexity O(Sqrt(N)) and CPU complexity O(N * Log(Log(N))) with an optimized windowed Sieve of Eratosthenes, as implemented in the code example below. As no language was specified and as I do not know Python, I have implemented it in VB.net, however I can convert it to C# if you need that.
Note that at O(N * Log(Log(N))), this routine is factoring each number at O(Log(Log(N))) on average which is much, much faster than the fastest single N factorization algorithms sited by some of the replies here. In fact, at N = 10^12 it is 2400 times faster! I have tested this routine on my 2Ghz Intel Core 2 laptop and it computes over 3,000,000 Phi() values per second. At this speed, it would take you about 4 days to compute 10^12 values. I have also tested it for correctness up to 100,000,000 without any errors. It is based in 64bit integers, so anything up to 2^63 (10^19) should be accurate (though too slow for anyone). I also have a Visual Studio WinForm (also VB.net) for running/testing it, that I can provide if you want it. Let me know if you have any questions. As requested in the comments, I have added below a C# version of the code. However, because I am currently in the middle of some other projects, I do not have time to convert it myself, so I have used one of the online VB to C# conversion sites (http://www.carlosag.net/tools/codetranslator/). So be aware that this was autoconverted and I have not had time to test or check it myself yet.



No one has found a faster way to calculate phi(k) (aka, Euler's totient function) than by first finding the prime factors of k. The world's best mathematicians have thrown many CPU cycles at the problem since 1977, since finding a faster way to solve this problem would create a weakness in the RSA publickey algorithm. (Both the public and the private key in RSA are calculated based on phi(n), where n is the product of two large primes.) 


The computation of phi(k) has to be done using the prime factorization of k, which is the only sensible way of doing it. If you need a refresher on that, wikipedia carries the formula. If you now have to compute all prime divisors of every number between 1 and a large N, you'll die of old age before seeing any result, so I'd go the other way around, i.e. build all numbers below N, using their possible prime factors, i.e. all primes less than or equal to N. Your problem is therefore going to be similar to computing all divisors of a number, only you do not know what is the maximum number of times you may find a certain prime in the factorization beforehand. Tweaking an iterator originally written by Tim Peters on the python list (something I've blogged about...) to include the totient function, a possible implementation in python that yields k, phi(k) pairs could be as follows:
If you need help on computing all prime factors below N, I've also blogged about it... Keep in mind, though that computing all primes below 10^{12} is in itself quite a remarkable feat... 


Is this from Project Euler 245? I remember that question, and I have given up on it. The fastest way I found for calculating totient was to multiply the prime factors (p1) together, given that k has no repeated factors (which was never the case if I remember the problem correctly). So for calculating factors, it would probably be best to use gmpy.next_prime or pyecm (elliptic curve factorization). You could also sieve the prime factors as Jaime suggests. For numbers up to 10^{12}, the maximum prime factor is below 1 million which should be reasonable. If you memoize factorizations, it could speed up your phi function even more. 


For these kind of problems I'm using an iterator that returns for each integer m < N the list of primes < sqrt(N) that divide m. To implement such an iterator I'm using an array A of length R where R > sqrt(N). At each point the array A contains list of primes that divide integers m .. m+R1. I.e. A[m % R] contains primes dividing m. Each prime p is in exactly one list, i.e. in A[m % R] for the smallest integer in the range m .. m+R1 that is divisible by p. When generating the next element of the iterator simply the list in A[m % R] is returned. Then the list of primes are removed from A[m % R] and each prime p is appended to A[(m+p) % R]. With a list of primes < sqrt(N) dividing m it is easy to find the factorization of m, since there is at most one prime larger than sqrt(N). This method has complexity O(N log(log(N))) under the assumption that all operations including list operations take O(1). The memory requirement is O(sqrt(N)). There is unfortunately, some constant overhead here, hence I was looking for a more elegant way to generate the values phi(n), but so for I've not been successful. 


Here's an efficient python generator. The caveat is that it doesn't yield the results in order. It is based on http://stackoverflow.com/a/10110008/412529 . Memory complexity is O(log(N)) as it only has to store a list of prime factors for a single number at a time. CPU complexity is just barely superlinear, something like O(N log log N).



I think you can go the other way around. Instead of factorizing an integer k to get phi(k), you can attempt to generate all integers from 1 to N from primes and get phi(k) quickly. For example, if P_{n} is the maximum prime that is less than N, you can generate all integers less than N by P_{1} ^{i 1} * P_{2} ^{i 2} * ... * P_{n} ^{i n} where each i_{j} run from 0 to [log (N) / log (P_{j})] ([] is the floor function). That way, you can get phi(k) quickly wihout expensive prime factorization and still iterate through all k between 1 and N (not in order but I think you don't care about order). 


Sieve the totients to n:



This factorizes N = PQ, where P & Q are prime. Works quite well, in Elixir or Erlang. You can try different generators for your pseudorandom sequence. This line: Other possible points of improvement: better or alternative gcd, rem and abs functions


