72

A coworker just told me that the C# Dictionary collection resizes by prime numbers for arcane reasons relating to hashing. And my immediate question was, "how does it know what the next prime is? do they story a giant table or compute on the fly? that's a scary non-deterministic runtime on an insert causing a resize"

So my question is, given N, which is a prime number, what is the most efficient way to compute the next prime number?

9
  • 3
    This really belongs on mathoverflow. Dec 18, 2010 at 1:05
  • 2
    Maybe your colleague is incorrect, or maybe it uses a few pre-computed primes rather than finding the next prime. Dec 18, 2010 at 1:11
  • 20
    @Kirk: I disagree -- this is an algorithm question, not a math question.
    – Jim Lewis
    Dec 18, 2010 at 1:15
  • 4
    @Kirk It all falls under theoretical computer science, which is very much in the middle of programming and math. So I honestly don't see a problem posting this question on either site.
    – moinudin
    Dec 18, 2010 at 1:27
  • 11
    @Kirk: This definitely does not belong on MathOverflow, which is for research-level questions only. I also disagree that it needs to be on math.stackexchange.com, but it would at least be suitable there as well. Dec 18, 2010 at 2:19

9 Answers 9

80

About a year ago I was working this area for libc++ while implementing the unordered (hash) containers for C++11. I thought I would share my experiences here. This experience supports marcog's accepted answer for a reasonable definition of "brute force".

That means that even a simple brute force will be fast enough in most circumstances, taking O(ln(p)*sqrt(p)) on average.

I developed several implementations of size_t next_prime(size_t n) where the spec for this function is:

Returns: The smallest prime that is greater than or equal to n.

Each implementation of next_prime is accompanied by a helper function is_prime. is_prime should be considered a private implementation detail; not meant to be called directly by the client. Each of these implementations was of course tested for correctness, but also tested with the following performance test:

int main()
{
    typedef std::chrono::high_resolution_clock Clock;
    typedef std::chrono::duration<double, std::milli> ms;
    Clock::time_point t0 = Clock::now();

    std::size_t n = 100000000;
    std::size_t e = 100000;
    for (std::size_t i = 0; i < e; ++i)
        n = next_prime(n+1);

    Clock::time_point t1 = Clock::now();
    std::cout << e/ms(t1-t0).count() << " primes/millisecond\n";
    return n;
}

I should stress that this is a performance test, and does not reflect typical usage, which would look more like:

// Overflow checking not shown for clarity purposes
n = next_prime(2*n + 1);

All performance tests were compiled with:

clang++ -stdlib=libc++ -O3 main.cpp

Implementation 1

There are seven implementations. The purpose for displaying the first implementation is to demonstrate that if you fail to stop testing the candidate prime x for factors at sqrt(x) then you have failed to even achieve an implementation that could be classified as brute force. This implementation is brutally slow.

bool
is_prime(std::size_t x)
{
    if (x < 2)
        return false;
    for (std::size_t i = 2; i < x; ++i)
    {
        if (x % i == 0)
            return false;
    }
    return true;
}

std::size_t
next_prime(std::size_t x)
{
    for (; !is_prime(x); ++x)
        ;
    return x;
}

For this implementation only I had to set e to 100 instead of 100000, just to get a reasonable running time:

0.0015282 primes/millisecond

Implementation 2

This implementation is the slowest of the brute force implementations and the only difference from implementation 1 is that it stops testing for primeness when the factor surpasses sqrt(x).

bool
is_prime(std::size_t x)
{
    if (x < 2)
        return false;
    for (std::size_t i = 2; true; ++i)
    {
        std::size_t q = x / i;
        if (q < i)
            return true;
        if (x % i == 0)
            return false;
    }
    return true;
}

std::size_t
next_prime(std::size_t x)
{
    for (; !is_prime(x); ++x)
        ;
    return x;
}

Note that sqrt(x) isn't directly computed, but inferred by q < i. This speeds things up by a factor of thousands:

5.98576 primes/millisecond

and validates marcog's prediction:

... this is well within the constraints of most problems taking on the order of a millisecond on most modern hardware.

Implementation 3

One can nearly double the speed (at least on the hardware I'm using) by avoiding use of the % operator:

bool
is_prime(std::size_t x)
{
    if (x < 2)
        return false;
    for (std::size_t i = 2; true; ++i)
    {
        std::size_t q = x / i;
        if (q < i)
            return true;
        if (x == q * i)
            return false;
    }
    return true;
}

std::size_t
next_prime(std::size_t x)
{
    for (; !is_prime(x); ++x)
        ;
    return x;
}

11.0512 primes/millisecond

Implementation 4

So far I haven't even used the common knowledge that 2 is the only even prime. This implementation incorporates that knowledge, nearly doubling the speed again:

bool
is_prime(std::size_t x)
{
    for (std::size_t i = 3; true; i += 2)
    {
        std::size_t q = x / i;
        if (q < i)
            return true;
        if (x == q * i)
            return false;
    }
    return true;
}

std::size_t
next_prime(std::size_t x)
{
    if (x <= 2)
        return 2;
    if (!(x & 1))
        ++x;
    for (; !is_prime(x); x += 2)
        ;
    return x;
}

21.9846 primes/millisecond

Implementation 4 is probably what most people have in mind when they think "brute force".

Implementation 5

Using the following formula you can easily choose all numbers which are divisible by neither 2 nor 3:

6 * k + {1, 5}

where k >= 1. The following implementation uses this formula, but implemented with a cute xor trick:

bool
is_prime(std::size_t x)
{
    std::size_t o = 4;
    for (std::size_t i = 5; true; i += o)
    {
        std::size_t q = x / i;
        if (q < i)
            return true;
        if (x == q * i)
            return false;
        o ^= 6;
    }
    return true;
}

std::size_t
next_prime(std::size_t x)
{
    switch (x)
    {
    case 0:
    case 1:
    case 2:
        return 2;
    case 3:
        return 3;
    case 4:
    case 5:
        return 5;
    }
    std::size_t k = x / 6;
    std::size_t i = x - 6 * k;
    std::size_t o = i < 2 ? 1 : 5;
    x = 6 * k + o;
    for (i = (3 + o) / 2; !is_prime(x); x += i)
        i ^= 6;
    return x;
}

This effectively means that the algorithm has to check only 1/3 of the integers for primeness instead of 1/2 of the numbers and the performance test shows the expected speed up of nearly 50%:

32.6167 primes/millisecond

Implementation 6

This implementation is a logical extension of implementation 5: It uses the following formula to compute all numbers which are not divisible by 2, 3 and 5:

30 * k + {1, 7, 11, 13, 17, 19, 23, 29}

It also unrolls the inner loop within is_prime, and creates a list of "small primes" that is useful for dealing with numbers less than 30.

static const std::size_t small_primes[] =
{
    2,
    3,
    5,
    7,
    11,
    13,
    17,
    19,
    23,
    29
};

static const std::size_t indices[] =
{
    1,
    7,
    11,
    13,
    17,
    19,
    23,
    29
};

bool
is_prime(std::size_t x)
{
    const size_t N = sizeof(small_primes) / sizeof(small_primes[0]);
    for (std::size_t i = 3; i < N; ++i)
    {
        const std::size_t p = small_primes[i];
        const std::size_t q = x / p;
        if (q < p)
            return true;
        if (x == q * p)
            return false;
    }
    for (std::size_t i = 31; true;)
    {
        std::size_t q = x / i;
        if (q < i)
            return true;
        if (x == q * i)
            return false;
        i += 6;

        q = x / i;
        if (q < i)
            return true;
        if (x == q * i)
            return false;
        i += 4;

        q = x / i;
        if (q < i)
            return true;
        if (x == q * i)
            return false;
        i += 2;

        q = x / i;
        if (q < i)
            return true;
        if (x == q * i)
            return false;
        i += 4;

        q = x / i;
        if (q < i)
            return true;
        if (x == q * i)
            return false;
        i += 2;

        q = x / i;
        if (q < i)
            return true;
        if (x == q * i)
            return false;
        i += 4;

        q = x / i;
        if (q < i)
            return true;
        if (x == q * i)
            return false;
        i += 6;

        q = x / i;
        if (q < i)
            return true;
        if (x == q * i)
            return false;
        i += 2;
    }
    return true;
}

std::size_t
next_prime(std::size_t n)
{
    const size_t L = 30;
    const size_t N = sizeof(small_primes) / sizeof(small_primes[0]);
    // If n is small enough, search in small_primes
    if (n <= small_primes[N-1])
        return *std::lower_bound(small_primes, small_primes + N, n);
    // Else n > largest small_primes
    // Start searching list of potential primes: L * k0 + indices[in]
    const size_t M = sizeof(indices) / sizeof(indices[0]);
    // Select first potential prime >= n
    //   Known a-priori n >= L
    size_t k0 = n / L;
    size_t in = std::lower_bound(indices, indices + M, n - k0 * L) - indices;
    n = L * k0 + indices[in];
    while (!is_prime(n))
    {
        if (++in == M)
        {
            ++k0;
            in = 0;
        }
        n = L * k0 + indices[in];
    }
    return n;
}

This is arguably getting beyond "brute force" and is good for boosting the speed another 27.5% to:

41.6026 primes/millisecond

Implementation 7

It is practical to play the above game for one more iteration, developing a formula for numbers not divisible by 2, 3, 5 and 7:

210 * k + {1, 11, ...},

The source code isn't shown here, but is very similar to implementation 6. This is the implementation I chose to actually use for the unordered containers of libc++, and that source code is open source (found at the link).

This final iteration is good for another 14.6% speed boost to:

47.685 primes/millisecond

Use of this algorithm assures that clients of libc++'s hash tables can choose any prime they decide is most beneficial to their situation, and the performance for this application is quite acceptable.

3
  • 5
    Since the divide instruction on just about any CPU architecture produces the remainder as well as the quotient, the fact that implementation 3 doubled the speed over implementation 2 indicates that your compiler did not optimize very well and used two divide instructions in implementation 2. On GCC 4.7.1 implementation 2 is indeed 4 % faster than implementation 3, since there is no need for the additional multiply. Your compiler might do better if you switch the two if clauses around. In fact the return false case is more likely so it's worth switching for that reason alone (1 % speed-up).
    – han
    Nov 18, 2012 at 12:27
  • 1
    O(ln(p)*sqrt(p)) is way way off. O(sqrt(p)) is a complexity of trial division testing of a prime, and they are spaced at O(ln(p)) steps, but all those numbers in between are composite, not prime. If I'm reading this correctly, the average complexity is O( ln(ln(p)) * sqrt(p) / ln(p) ).
    – Will Ness
    Aug 6, 2016 at 22:05
  • 2
    @WillNess: <shrug> I'm just quoting the accepted answer. The exact complexity is a side issue for my answer which exists to demonstrate the performance impact of various implementation strategies. Aug 6, 2016 at 22:08
44

Just in case somebody is curious:

Using reflector I determined that .Net uses a static class that contains a hard coded list of ~72 primes ranging up to 7199369 which is scans for the smallest prime that is at least twice the current size, and for sizes larger than that it computes the next prime by trial division of all odd numbers up to the sqrt of the potential number. This class is immutable and thread safe (i.e. larger primes are not stored for future use).

5
  • Good answer. Checking every odd number isn't the most efficient means of determining a prime but presumably the vast majority of dictionaries contain under 3.5 million keys. Dec 18, 2010 at 1:22
  • 2
    STLPort uses a stored list too: really-ugly-long-gitweb-url Dec 18, 2010 at 1:25
  • 3
    I neglected to mention that it first tests for divisibility by 2, although it appears to only try odd numbers to begin with since it increments by 2 when looking for the next prime. However, there is also an oddity, which is that if you were to call HashHelpers.GetPrime(7199370) it will loop through all even numbers from 7199370 to 2147483646 without finding a prime, and then just return 7199370. Amusing, but of course it's internal, so it is probably never called in this way. Dec 18, 2010 at 1:35
  • 3
    bah, I was wrong, there is a sneaky bitwise OR with 1 that turns an even input value into the next greater odd number. Dec 18, 2010 at 1:57
  • 1
    Not actually the answer to my question, though. Dec 20, 2010 at 4:52
35

The gaps between consecutive prime numbers is known to be quite small, with the first gap of over 100 occurring for prime number 370261. That means that even a simple brute force will be fast enough in most circumstances, taking O(ln(p)*sqrt(p)) on average.

For p=10,000 that's O(921) operations. Bearing in mind we'll be performing this once every O(ln(p)) insertion (roughly speaking), this is well within the constraints of most problems taking on the order of a millisecond on most modern hardware.

11
  • I wouldn't call that "fast" in the context of growing a dictionary. Dec 18, 2010 at 1:13
  • Agree that the complexity isn't excessive but each of those operations is a relatively heavy remainder check; & the complexity of the check itself increases as p increases. Dec 18, 2010 at 1:19
  • @GregS See my edit. @Kirk For sure, and coming to realise these expenses is one of the things that make an experienced programmer.
    – moinudin
    Dec 18, 2010 at 1:24
  • @marcog Unless I am still asleep, for p = 10000, ln(p) = 9.2 and sqrt(p) = 100, => O(920). Dec 18, 2010 at 1:30
  • @Kirk No it's me that is the asleep one. Fixing!
    – moinudin
    Dec 18, 2010 at 1:32
13

A nice trick is to use a partial sieve. For example, what is the next prime that follows the number N = 2534536543556?

Check the modulus of N with respect to a list of small primes. Thus...

mod(2534536543556,[3 5 7 11 13 17 19 23 29 31 37])
ans =
     2     1     3     6     4     1     3     4    22    16    25

We know that the next prime following N must be an odd number, and we can immediately discard all odd multiples of this list of small primes. These moduli allow us to sieve out multiples of those small primes. Were we to use the small primes up to 200, we can use this scheme to immediately discard most potential prime numbers greater than N, except for a small list.

More explicitly, if we are looking for a prime number beyond 2534536543556, it cannot be divisible by 2, so we need consider only the odd numbers beyond that value. The moduli above show that 2534536543556 is congruent to 2 mod 3, therefore 2534536543556+1 is congruent to 0 mod 3, as must be 2534536543556+7, 2534536543556+13, etc. Effectively, we can sieve out many of the numbers without any need to test them for primality and without any trial divisions.

Similarly, the fact that

mod(2534536543556,7) = 3

tells us that 2534536543556+4 is congruent to 0 mod 7. Of course, that number is even, so we can ignore it. But 2534536543556+11 is an odd number that is divisible by 7, as is 2534536543556+25, etc. Again, we can exclude these numbers as clearly composite (because they are divisible by 7) and so not prime.

Using only the small list of primes up to 37, we can exclude most of the numbers that immediately follow our starting point of 2534536543556, only excepting a few:

{2534536543573 , 2534536543579 , 2534536543597}

Of those numbers, are they prime?

2534536543573 = 1430239 * 1772107
2534536543579 = 99833 * 25387763

I've made the effort of providing the prime factorizations of the first two numbers in the list. See that they are composite, but the prime factors are large. Of course, this makes sense, since we've already ensured that no number that remains can have small prime factors. The third one in our short list (2534536543597) is in fact the very first prime number beyond N. The sieving scheme I've described will tend to result in numbers that are either prime, or are composed of generally large prime factors. So we needed to actually apply an explicit test for primality to only a few numbers before finding the next prime.

A similar scheme quickly yields the next prime exceeding N = 1000000000000000000000000000, as 1000000000000000000000000103.

3
  • What do you exactly mean by "We know that the next prime following N must be an odd number, and we can immediately discard all odd multiples of this list of small primes. These moduli allow us to sieve out multiples of those small primes." ?
    – venkatKA
    Nov 18, 2012 at 3:25
  • @zander - I've added more explanation.
    – user85109
    Nov 18, 2012 at 4:24
  • That makes some sense! Thank ya
    – venkatKA
    Nov 27, 2012 at 3:55
12

Just a few experiments with inter-primes distance.


This is a complement to visualize other answers.

I got the primes from the 100.000th (=1,299,709) to the 200.000th (=2,750,159)

Some data:

Maximum interprime distance = 148

Mean interprime distance = 15  

Interprime distance frequency plot:

alt text

Interprime Distance vs Prime Number

alt text

Just to see it's "random". However ...

5

There's no function f(n) to calculate the next prime number. Instead a number must be tested for primality.

It is also very useful, when finding the nth prime number, to already know all prime numbers from the 1st up to (n-1)th, because those are the only numbers that need to be tested as factors.

As a result of these reasons, I would not be surprised if there is a precalculated set of large prime numbers. It doesn't really make sense to me if certain primes needed to be recalculated repeatedly.

4
  • You do not need to know the primes from sqrt(p(n)) to p(n-1).
    – Sparr
    Dec 18, 2010 at 3:02
  • @Sparr Agree but the you will need those to calculate p(m) where p(m) >= p(n). When writing a prime algorithm you keep all encountered primes for use 'later on'. Dec 18, 2010 at 9:05
  • Is there provably no such function? Or is this proof by lack of imagination? Dec 20, 2010 at 4:53
  • There is no known function, therefore there is no usable function, therefore for all intents and purposes there is no function. If there were such a function then there would be no need for research or study of prime numbers, right? Dec 20, 2010 at 11:35
4

For sheer novelty, there’s always this approach:

#!/usr/bin/perl
for $p ( 2 .. 200  ) {
    next if (1x$p) =~ /^(11+)\1+$/;
    for ($n=1x(1+$p); $n =~ /^(11+)\1+$/; $n.=1) { }
    printf "next prime after %d is %d\n", $p, length($n);
}

which produces

next prime after 2 is 3
next prime after 3 is 5
next prime after 5 is 7
next prime after 7 is 11
next prime after 11 is 13
next prime after 13 is 17
next prime after 17 is 19
next prime after 19 is 23
next prime after 23 is 29
next prime after 29 is 31
next prime after 31 is 37
next prime after 37 is 41
next prime after 41 is 43
next prime after 43 is 47
next prime after 47 is 53
next prime after 53 is 59
next prime after 59 is 61
next prime after 61 is 67
next prime after 67 is 71
next prime after 71 is 73
next prime after 73 is 79
next prime after 79 is 83
next prime after 83 is 89
next prime after 89 is 97
next prime after 97 is 101
next prime after 101 is 103
next prime after 103 is 107
next prime after 107 is 109
next prime after 109 is 113
next prime after 113 is 127
next prime after 127 is 131
next prime after 131 is 137
next prime after 137 is 139
next prime after 139 is 149
next prime after 149 is 151
next prime after 151 is 157
next prime after 157 is 163
next prime after 163 is 167
next prime after 167 is 173
next prime after 173 is 179
next prime after 179 is 181
next prime after 181 is 191
next prime after 191 is 193
next prime after 193 is 197
next prime after 197 is 199
next prime after 199 is 211

All fun and games aside, it is well known that the optimal hash table size is rigorously provably a prime number of the form 4N−1. So just finding the next prime is insufficient. You have to do the other check, too.

2
  • 2
    Who'd know you can use regular expressions to search for prime numbers :/ Dec 18, 2010 at 1:34
  • 1
    Interesting that Paul Wheeler's answer indicates MS use at least one 4N+1 prime. Dec 18, 2010 at 2:56
3

As others have already noted, a means of finding the next prime number given the current prime has not been found yet. Therefore most algorithms focus more on using a fast means of checking primality since you have to check n/2 of the numbers between your known prime and the next one.

Depending upon the application, you can also get away with just hard-coding a look-up table, as noted by Paul Wheeler.

0

As far as I remember, it uses prime number next to the double of current size. It doesn't calculate that prime number - there table with preloaded numbers up to some big value (do not exactly, something about around 10,000,000). When that number is reached, it uses some naive algorithm to get next number (like curNum=curNum+1) and validates it using some if these methods: http://en.wikipedia.org/wiki/Prime_number#Verifying_primality

2
  • There exist only one pair of primes such that curNum and curNum+1 are both primes. Try harder.
    – tchrist
    Dec 18, 2010 at 1:31
  • Try next_prime = prime + 2. You might be right, and no one can prove that once you get high enough, you'll always be wrong. So go for it. :)
    – tchrist
    Dec 18, 2010 at 1:48

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