As promised here is the finished script I wrote. For reference, I'm trying to use the Burrows-Wheeler transform to do repeat matching in strings of DNA. Basically the idea is to take a strand of DNA of some length M and find all repeat within that string. So, as an example, if I had strange acaacg and searched for all duplicated substrings of size 2, I would get a count of 1 and the starting locations of 0,3. You could then type in string[0:2] and string[3:5] to verify that they do actually match and their result is "ac".
If anyone is interested in learning about the Burrows-Wheeler, a Wikipedia search on it produces very helpful results. Here's is another source from Stanford that also explains it well. http://www.stanford.edu/class/cs262/notes/lecture5.pdf
Now, there are a few issues that I did not address in this. First, I'm using n^2 space to create the BW transform. Also, I'm creating a suffix array, sorting it, and then replacing it with numbers so creating that may take up a bit of space. However, at the end I'm only really storing the occ matrix, the end column, and the word itself.
Despite the RAM problems for strings larger that 4^7 (got this to work with a string size of 40,000 but no larger...), I would call this a success seeing as before Monday, the only thing I new how to do in python was to have it print my name and hello world.
# generate random string of DNA
for i in range(length):
string += random.choice("ATGC")
# Make the BW transform from the generated string
word = word + '$'
return ''.join([x[-1] for x in
sorted([word[i:] + word[:i] for i in range(len(word))])])
# Make the occurrence matrix from the transform
for letter in letters:
for i in range(len(bwt)):
# Get the initial starting locations for the Pos(x) values
for letter in set(word):
list[letter]=len([i for i in word if i < letter])
# Single range finder for the BWT. This produces a first and last position for one read.
for letter in newread:
# Iterate the single read finder over the entire string to search for duplicates
for i in range(0,len(bwt)-readlength):
# Create suffix array to use later
suffix_names=[word[i:] for i in range(len(word))]
for i in range(len(output)):
# Remove single hits that were a result of using the substrings to scan the large string
for i in range(0,len(bwtrange)):
# Count the duplicate entries
for i in range(0,len(hits)):
if sum > 0:
# Get the coordinates from BWT and use the suffix array to map them back to their original indices
for element in hits:
# Use the coordinates to get the actual strings that are duplicated
for element in coord:
for i in range(0,len(element)):
# Merge the strings and the coordinates together for one big list.
for i in range(0,len(coord)):
Now run the commands as follows
import random # This is needed to generate a random string
readlength=12 # pick read length
word=get_string(4**7) # make random word
bwt=make_bwt(word) # make bwt transform from word
occ=make_occ(bwt) # make occurrence matrix
pos=get_starts(word) # gets start positions of sorted first row
bwtrange=get_range_large(readlength,occ,pos,bwt) # Runs the get_range function over all substrings in a string.
sa=get_suf_array(word) # This function builds a suffix array and numbers it.
hits=keep_dupes(bwtrange) # Pulls out the number of entries in the bwt results that have more than one hit.
dupes=count_dupes(hits) # counts hits
coord=get_coord(hits) # This part attempts to pull out the coordinates of the hits.
dupstrings=get_dupstrings(coord,readlength) # pulls out all the duplicated strings
strings_coord=together(dupstrings,coord) # puts coordinates and strings in one file for ease of viewing.