Given an array of `n`

word-frequency pairs:

[ (w_{0}, f_{0}), (w_{1}, f_{1}), ..., (w_{n-1}, f_{n-1}) ]

where `w`

is a word, _{i}`f`

is an integer frequencey, and the sum of the frequencies _{i}`∑f`

,_{i} = m

I want to use a pseudo-random number generator (pRNG) to select `p`

words `w`

such that
the probability of selecting any word is proportional to its frequency:_{j0}, w_{j1}, ..., w_{jp-1}

P(w_{i}= w_{jk}) = P(i = j_{k}) = f_{i}/ 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`f`

entries are_{0}`w`

, the next_{0}`f`

entries are_{1}`w`

, and so on, so the last_{1}`f`

entries are_{p-1}`w`

._{p-1}[ w

Then use the pRNG to select_{0}, ..., w_{0}, w_{1},..., w_{1}, ..., w_{p-1}, ..., w_{p-1}]`p`

indices in the range`0...m-1`

, and report the words stored at those indices.

This takes`O(n + m + p)`

work, which isn't great, since`m`

can be much much larger than n.Step through the input array once, computing

m

and after computing_{i}= ∑_{h≤i}f_{h}= m_{i-1}+ f_{i}`m`

, use the pRNG to generate a number_{i}`x`

in the range_{k}`0...m`

for each_{i}-1`k`

in`0...p-1`

and select`w`

for_{i}`w`

(possibly replacing the current value of_{jk}`w`

) if_{jk}`x`

._{k}< f_{i}

This requires`O(n + np)`

work.- Compute
`m`

as in algorithm 2, and generate the following array on n word-frequency-partial-sum triples:_{i}[ (w

and then, for each k in_{0}, f_{0}, m_{0}), (w_{1}, f_{1}, m_{1}), ..., (w_{n-1}, f_{n-1}, m_{n-1}) ]`0...p-1`

, use the pRNG to generate a number`x`

in the range_{k}`0...m-1`

then do binary search on the array of triples to find the`i`

s.t.`m`

, and select_{i}-f_{i}≤ x_{k}< m_{i}`w`

for_{i}`w`

._{jk}

This requires`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?