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I'm working on a program that runs Monte Carlo simulation; specifically, I'm using a Metropolis algorithm. The program needs to generate possibly billions of "random" numbers. I know that the Mersenne twister is very popular for Monte Carlo simulation, but I would like to make sure that I am seeding the generator in the best way possible.

Currently I'm computing a 32-bit seed using the following method:

mt19937_64 prng; //pseudo random number generator
unsigned long seed; //store seed so that every run can follow the same sequence
unsigned char seed_count; //to help keep seeds from repeating because of temporal proximity

unsigned long genSeed() {
    return (  static_cast<unsigned long>(time(NULL))      << 16 )
         | ( (static_cast<unsigned long>(clock()) & 0xFF) << 8  )
         | ( (static_cast<unsigned long>(seed_count++) & 0xFF) );
}

//...

seed = genSeed();
prng.seed(seed);

I have a feeling there are much better ways to assure non-repeating new seeds, and I'm quite sure mt19937_64 can be seeded with more then 32-bits. Does anyone have any suggestions?

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2  
Why does it matter? Why do you need to ensure that different runs of your simulation get different seeds? Why do you need to go out of your way to do this? It won't give you "better" random numbers. –  jalf Jul 4 at 18:05
    
Because we may run the simulation with the same set of parameters, in which case we don't necessarily expect the exact same results (which is what would happen if we used the same seed.) –  Mathhead200 Jul 6 at 21:53
2  
Sure, but seeding with something as simple as a timestamp would ensure that. Why do you need the NASA-levels of complexity to absolutely guarantee that... I don't even know what it is you are trying to guarantee. It sounds absurdly overengineered. –  jalf Jul 8 at 8:03
    
@jalf The timestamp from time() in <ctime> only has one second precision. But even if I was using millisecond precision (or whatever) it's likely that many of the simulations would start with the same seed. I'm running several of these simulations concurrently, (usually started programically in separate threads.) –  Mathhead200 Jul 8 at 10:05
    
And yet you say nothing about this in your question. You ask for "the best seed", which is a nonsensical question to ask. What you apparently wanted answered is "how do I select seeds so that different threads (or processes?), even if they are started simultaneously, have a minimal chance of choosing the same seeds". That is a reasonable question. But it has nothing to do with choosing "the best seed". You should update your question to ask the actual question you want answered. –  jalf Jul 8 at 14:26

6 Answers 6

Use std::random_device to generate the seed. It'll provide non-deterministic random numbers, provided your implementation supports it. Otherwise it's allowed to use some other random number engine.

std::mt19937_64 prng;
seed = std::random_device{}();
prng.seed(seed);

operator() of std::random_device returns an unsigned int, so if your platform has 32-bit ints, and you want a 64-bit seed, you'll need to call it twice.

std::mt19937_64 prng;
std::random_device device;
seed = (static_cast<uint64_t>(device()) << 32) | device();
prng.seed(seed);

Another available option is using std::seed_seq to seed the PRNG. This allows the PRNG to call seed_seq::generate, which produces a non-biased sequence over the range [0 ≤ i < 232), with an output range large enough to fill its entire state.

std::mt19937_64 prng;
std::random_device device;
std::seed_seq seq{device(), device(), device(), device()};
prng.seed(seq);

I'm calling the random_device 4 times to create a 4 element initial sequence for seed_seq. However, I'm not sure what the best practice for this is, as far as length or source of elements in the initial sequence is concerned.

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AFAIK, this uses "only" a 64 bit seed. I'm not sure this is enough for every purpose. I still wonder how to elegantly use random_device to provide as much seed as the PRNG can make use of. –  dyp Jun 20 at 19:38
    
@dyp There's std::seed_seq that you could feed with multiple calls to random_device, and then pass that to mt19937_64::seed. According to cppreference seed_seq will generate results that are distributed over [0 ≤ i < 2^32), but I have no idea whether doing that is better than bit shifting, or how many times you'd need to call random_device for constructing the input range to seed_seq (meaning how many elements should the input have for it to be considered good). –  Praetorian Jun 20 at 19:47
    
The interesting part about seed sequences is that the MT can request as much seed as it wants to, that can be more than just 64 bit. I'm not sure if using seed_seq in combination with random_device is useful, that depends on the behaviour/requirements which MT has (seed_seq::generate eliminates bias). –  dyp Jun 20 at 19:50
    
Something like this (maybe with more member functions implemented); but as I said, I don't know if the output of uniform_int_distribution + random_device is good for MT. –  dyp Jun 20 at 20:01
    
@dyp Found something interesting ... according to Table 117, seeding using a seed sequence Creates an engine with an initial state that depends on a sequence produced by one call to q.generate. So in this case using that option will result in the mt19937_64 being seeded by a 32-bit seed. I'm not saying that that is a bad thing, don't know enough about this stuff to make such claims. –  Praetorian Jun 20 at 20:07

As far as I can tell from your comments, it seems that what you are interested in is ensuring that if a process starts several of your simulations at exactly the same time, they will get different seeds.

The only significant problem I can see with your current approach is a race condition: if you are going to start multiple simulations simultaneously, it must be done from separate threads. If it is done from separate threads, you need to update seed_count in a thread-safe manner, or multiple simulations could end up with the same seed_count. You could simply make it an std::atomic<int> to solve that.

Beyond that, it just seems more complicated than it has to be. What do you gain by using two separate timers? You could do something as simple as this:

  1. at program startup, grab the current system time (using a high resolution timer) once, and store that.
  2. assign each simulation a unique ID (this could just be an integer initialized to 0, (which should be generated without any race conditions, as mentioned above) which is incremented each time a simulation starts, effectively like your seed_count.
  3. when seeding a simulation, just use the initially generated timestamp + the unique ID. If you do this, every simulation in the process is assured a unique seed.
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That is what I was trying to do with the above code. However, the code is a snip-it from a class, MSD, and these are actually member variables. (Perhaps making seed_count static is warranted.) In the multi-threaded case, each thread has its own instance of MSD and therefor, for that case, seed_count isn't helping. (Again making seed_count static should fix this.) Another problem is these tasks could be split between multiple computers, in which case the about talked about solutions don't apply. –  Mathhead200 Jul 9 at 4:32

How about...

There is some main code that starts the threads and there are copies of a function run in those threads, each copy with it's own Marsenne Twister. Am I correct? If it is so, why not use another random generator in the main code? It would be seeded with time stamp, and send it's consecutive pseudorandom numbers to function instances as their seeds.

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I could do this, (although I'd rather the sequences just be independent); however, this doesn't address the problem of running the simulations on multiple machines. Also, it seems like a lot more work then just messing with seed generation. (The program is fairly large.) –  Mathhead200 Jul 9 at 19:53
    
I think I misunderstood your answer when I responded before. It still doesn't address the issue of multiple machines (or instances of the program running concurrently), but the sequences would be independent and it wouldn't be hard to implement. However, there is a slight change that the PRNG seeded could send repeat seeds. –  Mathhead200 Jul 11 at 20:21

Let's recap (comments too), we want to generate different seeds to get independent sequences of random numbers in each of the following occurrences:

  1. The program is relaunched on the same machine later,
  2. Two threads are launched on the same machine at the same time,
  3. The program is launched on two different machines at the same time.

1 is solved using time since epoch, 2 is solved with a global atomic counter, 3 is solved with a platform dependent id (see How to obtain (almost) unique system identifier in a cross platform way?)

Now the point is what is the best way to combine them to get a uint_fast64_t (the seed type of std::mt19937_64)? I assume here that we do not know a priori the range of each parameter or that they are too big, so that we cannot just play with bit shifts getting a unique seed in a trivial way.

A std::seed_seq would be the easy way to go, however its return type uint_least32_t is not our best choice.

A good 64 bits hasher is a much better choice. The STL offers std::hash under the functional header, a possibility is to concatenate the three numbers above into a string and then passing it to the hasher. The return type is a size_t which on 64 machines is very likely to match our requirements.

Collisions are unlikely but of course possible, if you want to be sure to not build up statistics that include a sequence more than once, you can only store the seeds and discard the duplicated runs.

A std::random_device could also be used to generate the seeds (collisions may still happen, hard to say if more or less often), however since the implementation is library dependent and may go down to a pseudo random generator, it is mandatory to check the entropy of the device and avoid to a use zero-entropy device for this purpose as you will probably break the points above (especially point 3). Unfortunately you can discover the entropy only when you take the program to the specific machine and test with the installed library.

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Thanks, perfect summarization. I'm going to look at that SO link on obtaining unique system identifiers. MY main consern being I don't know what machines this program will be run on in the future. (Same issue with random_device.) -- I thought, in general, Mersenne Twister was seeded with more then 64 bits...? –  Mathhead200 Jul 9 at 19:57
    
@Mathhead200 The STL implementation takes a 64 bits seed, however the original C implementation should take arbitrary long seeds, see math.sci.hiroshima-u.ac.jp/~m-mat/MT/efaq.html (look for init_by_array) This would save you the usage of the hash function and maybe lower the probability of a collision. However having an already cooked STL implementation I'm not sure it is worth it. –  DarioP Jul 10 at 6:49
    
I think seed_seq has been made for supplying arbitrary long seeds. Take a look at seed_seq::generate. generate generates multiple 32-bit values, but mt19937_64 does not need to use a state based on 64-bit data types; even if, you can still use 32-bit values to fill it (via distributions / adapters). –  dyp Jul 12 at 11:58
    
@dyp I do not know what percentage of the sequences of parameters that generate a collision at the first call of seed_seq::generate a will still collide also at the second call. Not being able to exclude that it's 100%, I prefer to go for a real 64 bits hasher. mt19937_64 accepts a uint_fast64_t seed, you can pass a 32 bits value, but if you have a real 64 bits number, in principle you can get a much greater number of different sequences. –  DarioP Jul 12 at 19:47
    
I don't quite understand why you want to call generate multiple times. –  dyp Jul 12 at 21:38

The POSIX function gettimeofday(2) gives the time with microsecond precision.

The POSIX thread function gettid(2) returns the ID number of the current thread.

You should be able to combine the time in seconds since the epoch (which you are already using), the time in microseconds, and the thread ID to get a seed which is always unique on one machine.

If you also need it to be unique across multiple machines, you could consider also getting the hostname, the IP address, or the MAC address.

I would guess that 32 bits is probably enough, since there are over 4 billion unique seeds available. Unless you are running billions of processes, which doesn't seem likely, you should be alright without going to 64 bit seeds.

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Are POSIX functions available on Windows, because I don't want the program to become OS dependent? Also, we are not running four+ billion processes, no; however, you don't need to run four billion processes to get a repeating 32-bit seed (see the Birthday Problem.) –  Mathhead200 Jul 11 at 20:28
    
So, using an approximation to the birthday problem probability, it looks like you have about a 99% chance of having zero collisions when using 10k processes with a 32 bit seed. But, having a collision only matters if the colliding processes are using the same parameters. If you have different run parameters, then a collision will have no impact. I'm just trying to save you unnecessary trouble (unless it actually is necessary). –  jsw Jul 11 at 20:53
    
POSIX is supported on Windows via Cygwin, but do you have users on Windows yet? It's better to have a program that works but is OS dependent than to fuss over OS dependence and have no program at all. If you find that you are hindering adoption, then you can come back to this problem, and even recruit additional developers to help. This is similar to the idea of avoiding premature optimization. Ultimately, you will probably need OS-dependent code with switches to select the appropriate method. Also, if OS-independence is important, add it to the original question (and bounty)! –  jsw Jul 11 at 20:56
    
The program is currently only running on Windows, and I don't have the capability to "recruit" anyone else to help (I wish I did; I've tried.) The program might end up running on a cloud or grid system, or even a super computer at some point, and I don't want to add any dependencies that I can avoid. Thanks for telling me about Cygwin though! –  Mathhead200 Jul 12 at 23:56
    
You are correct that a different seed is on;y really important if there are identical parameters (which isn't often). I was just clarifying your post. Also, I might as well use 64 bits if I have them. –  Mathhead200 Jul 12 at 23:58

From the comments I understand you want to run several instances of the algorithm, one instance per thread. And given that the seed for each instance will be generated pretty much at the same time, you want to ensure that these seeds are different. If that is indeed what you are trying to solve, then your genSeed function will not necessarily guarantee that.

In my opinion, what you need is a parallelisable random number generator (RNG). What this means, is that you only need one RNG which you instantiate with only one seed (which you can generate with your genSeed) and then the sequence of random numbers that would normally be gerenated in a sequential environment is split in X non-overlapping sequences; where X is the number of threads. There is a very good library which provides these type of RNGs in C++, follows the C++ standard for RNGs, and is called TRNG(http://numbercrunch.de/trng).

Here is a little more information. There are two ways you can achieve non-overlapping sequences per thread. Let's assume that the sequence of random numbers from a single RNG is r = {r(1), r(2), r(3),...} and you have only two threads. If you know in advance how many random numbers you will need per thread, say M, you can give the first M of the r sequence to the first thread, ie {r(1), r(2),..., r(M)}, and the second M to the second thread, ie {r(M+1), r(M+2),...r(2M)}. This technique is called blocksplitting since you split the sequence in two consecutive blocks.

The second way is to create the sequence for the first thread as {r(1), r(3), r(5), ...} and for the second thread as {r(2), r(4), r(6),...}, which has the advantage that you do not need to know in advance how many random numbers you will need per thread. This is called leapfroging.

Note that both methods guarantee that the sequences per thread are indeed non-overlapping. The link I posted above has many examples and the library itself is extremely easy to use. I hope my post helps.

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Thanks, but we also run this program on multiple machines as well, and that would mean the random numbers must be generated in a separate program and sent across a network (and that's assuming the computer stay networked as they are now.) –  Mathhead200 Jul 11 at 19:59

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