Given a function which produces a random integer in the range 1 to 5, write a function which produces a random integer in the range 1 to 7.
 What is a simple solution?
 What is an effective solution to reduce memory usage or run on a slower CPU?

This is equivalent to Adam Rosenfield's solution, but may be a bit more clear for some readers. It assumes rand5() is a function that returns a statistically random integer in the range 1 through 5 inclusive.
How does it work? Think of it like this: imagine printing out this doubledimension array on paper, tacking it up to a dart board and randomly throwing darts at it. If you hit a nonzero value, it's a statistically random value between 1 and 7, since there are an equal number of nonzero values to choose from. If you hit a zero, just keep throwing the dart until you hit a nonzero. That's what this code is doing: the i and j indexes randomly select a location on the dart board, and if we don't get a good result, we keep throwing darts. Like Adam said, this can run forever in the worst case, but statistically the worst case never happens. :) 


There is no (exactly correct) solution which will run in a constant amount of time, since 1/7 is an infinite decimal in base 5. One simple solution would be to use rejection sampling, e.g.:
This has an expected runtime of 25/21 = 1.19 iterations of the loop, but there is an infinitesimally small probability of looping forever. 


I'd like to add another answer, in addition to my first answer. This answer attempts to minimize the number of calls to The entropy of a random variable is a welldefined quantity. For a random variable which takes on N states with equal probabilities (a uniform distribution), the entropy is log_{2} N. Thus, Side notes: all logarithms in this answer will be base 2 unless specified otherwise. So how do we do it? We generate an infinitely precise random real number between 0 and 1 (pretend for the moment that we could actually compute and store such an infinitely precise number  we'll fix this later). We can generate such a number by generating its digits in base 5: we pick the random number 0. Ok, so we've picked a random real number between 0 and 1. I now claim that such a random number is uniformly distributed. Intuitively, this is easy to understand, since each digit was picked uniformly, and the number is infinitely precise. However, a formal proof of this is somewhat more involved, since now we're dealing with a continuous distribution instead of a discrete distribution, so we need to prove that the probability that our number lies in an interval [ Now that we have a random real number selected uniformly from the range [0, 1], we need to convert it to a series of uniformly random numbers in the range [0, 6] to generate the output of Taking the example from earlier, if our Ok, so we have the main idea, but we have two problems left: we can't actually compute or store an infinitely precise real number, so how do we deal with only a finite portion of it? Secondly, how do we actually convert it to base 7? One way we can convert a number between 0 and 1 to base 7 is as follows:
To deal with the problem of infinite precision, we compute a partial result, and we also store an upper bound on what the result could be. That is, suppose we've called So, keeping track of the current number so far, and the maximum value it could ever take, we convert both numbers to base 7. If they agree on the first And that's the algorithm  to generate the next output of
Note that Also note that the numbers here get very big, very fast. Powers of 5 and 7 grow quickly. Hence, performance will start to degrade noticeably after generating lots of random numbers, due to bignum arithmetic. But remember here, my goal was to maximize the usage of random bits, not to maximize performance (although that is a secondary goal). In one run of this, I made 12091 calls to In order to port this code to a language that doesn't have arbitrarily large integers builtin, you'll have to cap the values of 


(I have stolen Adam Rosenfeld's answer and made it run about 7% faster.) Assume that rand5() returns one of {0,1,2,3,4} with equal distribution and the goal is return {0,1,2,3,4,5,6} with equal distribution.
We're keeping track of the largest value that the loop can make in the variable Edit: Expect number of times to call rand5() is x in this equation:






Algorithm: 7 can be represented in a sequence of 3 bits Use rand(5) to randomly fill each bit with 0 or 1. if the result is 1 or 2, fill the bit with 0 This way we can fill 3 bits randomly with 0/1 and thus get a number from 17. EDIT: This seems like the simplest and most efficient answer, so here's some code for it:






Edit: That doesn't quite work. It's off by about 2 parts in 1000 (assuming a perfect rand5). The buckets get:
By switching to a sum of
seems to gain an order of magnitude for every 2 added BTW: the table of errors above was not generated via sampling but by the following recurrence relation:



The following produces a uniform distribution on {1, 2, 3, 4, 5, 6, 7} using a random number generator producing a uniform distribution on {1, 2, 3, 4, 5}. The code is messy, but the logic is clear.



If we consider the additional constraint of trying to give the most efficient answer i.e one that given an input stream, The simplest way to analyse this is to treat the streams I and Then if we take a section of the input stream of length So this gives a value for The difficulty with the above analysis is the equation The question is how close to the best possible value of m (log5/log7) can be attain. For example when this number approaches close to an integer can we find a way to achieve this exact integral number of output values? If If we let Then If we just keep substituting we obtain:
Hence
Another way of putting this is:
The best possible case is my original one above where Then The worst case is when we can only find k and s.t 5^m = kx7+s.
Other cases are somewhere inbetween. It would be interesting to see how well we can do for very large m, i.e. how good can we get the error term:
It seems impossible to achieve The whole thing then rests on the distribution of the 7ary digits of I'm sure there is a lot of theory out there that covers this I may have a look and report back at some point. 


Are homework problems allowed here? This function does crude "base 5" math to generate a number between 0 and 6.



Why not do it simple?
The chances of getting 1 and 7 in this solution is lower due to the modulo, however, if you just want a quick and readable solution, this is the way to go. 


Here is a working Python implementation of Adam's answer.
I like to throw algorithms I'm looking at into Python so I can play around with them, thought I'd post it here in the hopes that it is useful to someone out there, not that it took long to throw together. 


The premise behind Adam Rosenfield's correct answer is:
When n equals 2, you have 4 throwaway possibilities: y = {22, 23, 24, 25}. If you use n equals 6, you only have 1 throwaway: y = {15625}. 5^6 = 15625
You call rand5 more times. However, you have a much lower chance of getting a throwaway value (or an infinite loop). If there is a way to get no possible throwaway value for y, I haven't found it yet. 


Assuming that rand(n) here means "random integer in a uniform distribution from 0 to n1", here's a code sample using Python's randint, which has that effect. It uses only randint(5), and constants, to produce the effect of randint(7). A little silly, actually



Here's my answer:
It's a little more complicated than others, but I believe it minimises the calls to rand5. As with other solutions, there's a small probability that it could loop for a long time. 


As long as there aren't seven possibilities left to choose from, draw another random number, which multiplies the number of possibilities by five. In Perl:



I know it has been answered, but is this seems to work ok, but I can not tell you if it has a bias. My 'testing' suggests it is, at least, reasonable. Perhaps Adam Rosenfield would be kind enough to comment? My (naive?) idea is this: Accumulate rand5's until there is enough random bits to make a rand7. This takes at most 2 rand5's. To get the rand7 number I use the accumulated value mod 7. To avoid the accumulator overflowing, and since the accumulator is mod 7 then I take the mod 7 of the accumulator:
The rand7() function follows: (I let the range of rand5 be 04 and rand7 is likewise 06.)
Edit: Added results for 100 million trials. 'Real' rand functions mod 5 or 7 rand5 : avg=1.999802 0:20003944 1:19999889 2:20003690 3:19996938 4:19995539 rand7 : avg=3.000111 0:14282851 1:14282879 2:14284554 3:14288546 4:14292388 5:14288736 6:14280046 My rand7 Average looks ok and number distributions look ok too. randt : avg=3.000080 0:14288793 1:14280135 2:14287848 3:14285277 4:14286341 5:14278663 6:14292943 


Simple and efficient:
(Inspired by http://stackoverflow.com/questions/84556/whatsyourfavoriteprogrammercartoon/84747#84747). 


I don't like ranges starting from 1, so I'll start from 0 :)



in php
loops to produce a random number between 16 and 127, divides by sixteen to create a float between 1 and 7.9375, then rounds down to get an int between 1 and 7. if I am not mistaken, there is a 16/112 chance of getting any one of the 7 outcomes. 


By using a rolling total, you can both
Both these problems are an issue with the simplistic
And this output shows the results:
A simplistic
And, on the advice of Nixuz, I've cleaned the script up so you can just extract and use the



This answer is more an experiment in obtaining the most entropy possible from the Rand5 function. t is therefore somewhat unclear and almost certainly a lot slower than other implementations. Assuming the uniform distribution from 04 and resulting uniform distribution from 06:
The number of bits added to the buffer per call to Rand5 is currently 4/5 * 2 so 1.6. If the 1/5 probability value is included that increases by 0.05 so 1.65 but see the comment in the code where I have had to disable this. Bits consumed by call to Rand7 = 3 + 1/8 * (3 + 1/8 * (3 + 1/8 * (... By extracting information from the sevens I reclaim 1/8*1/7 bits per call so about 0.018 This gives a net consumption 3.4 bits per call which means the ratio is 2.125 calls to Rand5 for every Rand7. The optimum should be 2.1. I would imagine this approach is significantly slower than many of the other ones here unless the cost of the call to Rand5 is extremely expensive (say calling out to some external source of entropy). 


There are elegant algorithms cited above, but here's one way to approach it, although it might be roundabout. I am assuming values generated from 0. R2 = random number generator giving values less than 2 (sample space = {0, 1}) In order to generate R8 from R2, you will run R2 thrice, and use the combined result of all 3 runs as a binary number with 3 digits. Here are the range of values when R2 is ran thrice: 0 0 0 > 0 Now to generate R7 from R8, we simply run R7 again if it returns 7:
The roundabout solution is to generate R2 from R5 (just like we generated R7 from R8), then R8 from R2 and then R7 from R8. 


The function you need is *rand1_7()*, I wrote rand1_5() so that you can test it and plot it.



There you go, uniform distribution and zero rand5 calls.
Need to set seed beforehand. 


Here's a solution that fits entirely within integers and is within about 4% of optimal (i.e. uses 1.26 random numbers in {0..4} for every one in {0..6}). The code's in Scala, but the math should be reasonably clear in any language: you take advantage of the fact that 7^9 + 7^8 is very close to 5^11. So you pick an 11 digit number in base 5, and then interpret it as a 9 digit number in base 7 if it's in range (giving 9 base 7 numbers), or as an 8 digit number if it's over the 9 digit number, etc.:
If you paste a test into the interpreter (REPL actually), you get:
The distribution is nice and flat (within about 10k of 1/7 of 10^8 in each bin, as expected from an approximatelyGaussian distribution). 


just scale your output from your first function






Here's what I've found:
Then we get a range of 1~7, which is the Random7 we're looking for. 


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