Take the 2-minute tour ×
Stack Overflow is a question and answer site for professional and enthusiast programmers. It's 100% free, no registration required.

I am doing a large amount of string comparisons using the Levenshtein distance measure, but because I need to be able to account for the spatial adjacency in the latent structure of the strings, I had to make my own script including a weight function.

My problem now is that my script is very inefficient. I have to do approximately 600,000 comparisons and it will take hours for the script to be done. I am therefor seeking a way to make my script more efficient, but being a self taught nub, I don't know how to solve this my self.

Here is the functions:

zeros <- function(lengthA,lengthB){
  m <- matrix(c(rep(0,lengthA*lengthB)),nrow=lengthA,ncol=lengthB)
  return(m)
}


weight <- function(A,B,weights){
  if (weights == TRUE){

    # cost_weight defines the matrix structure of the AOI-placement
    cost_weight <- matrix(c("a","b","c","d","e","f","g","h","i","j","k","l",
                           "m","n","o","p","q","r","s","t","u","v","w","x"),
                          nrow=6)

    max_walk <- 8.00  # defined as the maximum posible distance between letters in 
                      # the cost_weight matrix
    indexA <- which(cost_weight==A, arr.ind=TRUE)
    indexB <- which(cost_weight==B, arr.ind=TRUE)
    walk <- abs(indexA[1]-indexB[1])+abs(indexA[2]-indexB[2])
    w <- walk/max_walk
  }

  else {w <- 1}

  return(w)
}


dist <- function(A, B, insertion, deletion, substitution, weights=TRUE){
  D <- zeros(nchar(A)+1,nchar(B)+1)
  As <- strsplit(A,"")[[1]]
  Bs <- strsplit(B,"")[[1]]
  # filling out the matrix
  for (i in seq(to=nchar(A))){ 
    D[i + 1,1] <- D[i,1] + deletion * weight(As[i],Bs[1], weights)
  }
  for (j in seq(to=nchar(B))){ 
    D[1,j + 1] <- D[1,j] + insertion * weight(As[1],Bs[j], weights)
  }
  for (i in seq(to=nchar(A))){ 
    for (j in seq(to=nchar(B))){
      if (As[i] == Bs[j]){
        D[i + 1,j + 1] <- D[i,j]
        } 
      else{
        D[i + 1,j + 1] <- min(D[i + 1,j] + insertion * weight(As[i],Bs[j], weights),
                              D[i,j + 1] + deletion * weight(As[i],Bs[j], weights),
                              D[i,j]     + substitution * weight(As[i],Bs[j], weights))
      }
    }
  }
  return(D)
}


levenshtein <- function(A, B, insertion=1, deletion=1, substitution=1){
  # Compute levenshtein distance between iterables A and B

  if (nchar(A) == nchar(B) & A == B){
    return(0)
  }

  if (nchar(B) > nchar(A)){
    C <- A
    A <- B
    B <- A
    #(A, B) <- (B, A)
  }

  if (nchar(A) == 0){
    return (nchar(B))
  }

  else{
    return (dist(A, B, insertion, deletion, substitution)[nchar(A),nchar(B)])
  }
}

Comparing the performance of my Levenshtein measure to the one from the stringdist package the performance is 83 times worse.

library (stringdist)
library(rbenchmark)

A <-"abcdefghijklmnopqrstuvwx"
B <-"xwvutsrqponmlkjihgfedcba"

benchmark(levenshtein(A,B), stringdist(A,B,method="lv"),
          columns=c("test", "replications", "elapsed", "relative"),
          order="relative", replications=10) 


                             test replications elapsed relative
2 stringdist(A, B, method = "lv")           10    0.01        1
1               levenshtein(A, B)           10    0.83       83

Does anyone have an idea to improving my script?

share|improve this question
    
The two distances also don't agree with one another: levenshtein(A,B) is 11.25 and stringdist(A,B,method="lv") is 24. –  shadow May 9 at 10:06
    
That is the point, because the levenshtein() place weights on the letters based on the cost_weight matrix defined under the weight() function. –  Martin Petri Bagger May 9 at 10:18

1 Answer 1

The following code is already some improvement (of your code; calculates the same as you did before, not the same as stringdist), but I'm sure it can be even more simplified and sped up.

zeros <- function(lengthA,lengthB){
  m <- matrix(0, nrow=lengthA, ncol=lengthB)
  return(m)
}


weight <- function(A,B,weights){
  if (weights){
    # cost_weight defines the matrix structure of the AOI-placement
    cost_weight <- matrix(c("a","b","c","d","e","f","g","h","i","j","k","l",
                            "m","n","o","p","q","r","s","t","u","v","w","x"),
                          nrow=6)

    max_walk <- 8.00  # defined as the maximum posible distance between letters in 
    # the cost_weight matrix
    amats <- lapply(A, `==`, y=cost_weight)
    bmats <- lapply(B, `==`, y=cost_weight)
    walk <- mapply(function(a, b){
      sum(abs(which(a, arr.ind=TRUE) - which(b, arr.ind=TRUE)))
    }, amats, bmats)
    return(walk/max_walk)
  }
  else return(1)
}


dist <- function(A, B, insertion, deletion, substitution, weights=TRUE){
  #browser()
  D <- zeros(nchar(A)+1,nchar(B)+1)
  As <- strsplit(A,"")[[1]]
  Bs <- strsplit(B,"")[[1]]
  # filling out the matrix
  weight.mat <- outer(As, Bs, weight, weights=weights)
  D[,1] <- c(0, deletion * cumsum(weight.mat[, 1]))
  D[1,] <- c(0, insertion * cumsum(weight.mat[1,]))

  for (i in seq(to=nchar(A))){ 
    for (j in seq(to=nchar(B))){
      if (As[i] == Bs[j]){
        D[i + 1,j + 1] <- D[i,j]
      } 
      else{
        D[i + 1,j + 1] <- min(D[i + 1,j] + insertion * weight.mat[i, j],
                              D[i,j + 1] + deletion * weight.mat[i, j],
                              D[i,j]     + substitution * weight.mat[i, j])
      }
    }
  }
  return(D)
}


levenshtein <- function(A, B, insertion=1, deletion=1, substitution=1){
  # Compute levenshtein distance between iterables A and B

  if (nchar(A) == nchar(B) & A == B){
    return(0)
  }

  if (nchar(B) > nchar(A)){
    C <- A
    A <- B
    B <- A
    #(A, B) <- (B, A)
  }

  if (nchar(A) == 0){
    return (nchar(B))
  }

  else{
    return (dist(A, B, insertion, deletion, substitution)[nchar(A),nchar(B)])
  }
}
share|improve this answer

Your Answer

 
discard

By posting your answer, you agree to the privacy policy and terms of service.

Not the answer you're looking for? Browse other questions tagged or ask your own question.