Given an array of
n word-frequency pairs:
[ (w0, f0), (w1, f1), ..., (wn-1, fn-1) ]
wi is a word,
fi is an integer frequencey, and the sum of the frequencies
∑fi = m,
I want to use a pseudo-random number generator (pRNG) to select
wj0, wj1, ..., wjp-1 such that
the probability of selecting any word is proportional to its frequency:
P(wi = wjk) = P(i = jk) = fi / m
(Note, this is selection with replacement, so the same word could be chosen every time).
I've come up with three algorithms so far:
Create an array of size
m, and populate it so the first
w0, the next
w1, and so on, so the last
[ w0, ..., w0, w1,..., w1, ..., wp-1, ..., wp-1 ]Then use the pRNG to select
pindices in the range
0...m-1, and report the words stored at those indices.
O(n + m + p)work, which isn't great, since
mcan be much much larger than n.
Step through the input array once, computing
mi = ∑h≤ifh = mi-1 + fiand after computing
mi, use the pRNG to generate a number
xkin the range
wjk(possibly replacing the current value of
xk < fi.
O(n + np)work.
mias in algorithm 2, and generate the following array on n word-frequency-partial-sum triples:
[ (w0, f0, m0), (w1, f1, m1), ..., (wn-1, fn-1, mn-1) ]and then, for each k in
0...p-1, use the pRNG to generate a number
xkin the range
0...m-1then do binary search on the array of triples to find the
mi-fi ≤ xk < mi, and select
O(n + p log n)work.
My question is: Is there a more efficient algorithm I can use for this, or are these as good as it gets?