Here is an algorithm. It is probably not the most efficient, but is the best one I could think of.
Input:
A string of length n
A list of words
Create a lookup table:
Create a grid M of n x n slots. (1..n, 1..n)
Create a grid W of n x n slots. (1..n, 1..n)
For each starting position i in 1..n:
For each ending position j in i..n:
For each word w:
Find the edit distance d between w and substring (i..j)
If d is less than M[i,j]:
Set M[i,j] to d
Set W[i,j] to w
Find the best words for each position:
Create a list L of (n+1) slots. (0..n)
Create a list C of (n+1) slots. (0..n)
Set L[0] to 0
For each ending position i in 1..n:
Set L[i] to infinity
For each starting position j in 0..i-1:
If L[j] + M[i,j] is less than L[i]:
Set L[i] to L[j] + M[i,j]
Set C[i] to j
Create the final result string:
Create a list R
Let i be the length of the input (n)
Repeat while i > 0:
Let j be C[i]
Prepend W[j,i] to R
Set i to j-1
Return R
This algorithm is split in three stages:
The first stage calculates a lookup-table. M is the best cost of fitting any word into substring i..j. W is the word associated with that cost. O(n3 m w) (n = input length, w = maximum word length, and m = word count)
The second stage finds the best words for each position. L is the best total cost up to position i. C is the starting position of the last word associated with that cost. O(n2)
The last stage assembles the final string. R is a list of words that receives the least cost when matched against the input string. O(n).
The first stage is the most costly. It should probably be possible to shave off an order of magnitude from it, but I don't see how. You could also combine it with stage 2, but you wouldn't gain much from it.