1 files changed, 0 insertions, 157 deletions

diff --git a/source/clusters.py b/source/clusters.py
deleted file mode 100755
index e53fac9b..00000000
--- a/source/clusters.py
+++ /dev/null
@@ -1,157 +0,0 @@
-#! /usr/bin/env python

-#-*- coding: utf-8 -*-

-

-import math

-import random

-

-from math import sqrt

-from PIL import Image, ImageDraw

-

-def readfile(filename):

-  lines=[line for line in file(filename)]

-

-  # First line is the column titles

-  colnames=lines[0].strip().split('\t')[1:]

-  rownames=[]

-  data=[]

-  for line in lines[1:]:

-    p=line.strip().split('\t')

-    # First column in each row is the rowname

-    rownames.append(p[0])

-    # The data for this row is the remainder of the row

-    data.append([float(x) for x in p[1:]])

-  return rownames,colnames,data

-

-def pearson(v1,v2):

-  # Simple sums

-  sum1=sum(v1)

-  sum2=sum(v2)

-

-  # Sums of the squares

-  sum1Sq=sum([pow(v,2) for v in v1])

-  sum2Sq=sum([pow(v,2) for v in v2])	

-

-  # Sum of the products

-  pSum=sum([v1[i]*v2[i] for i in range(len(v1))])

-

-  # Calculate r (Pearson score)

-  num=pSum-(sum1*sum2/len(v1))

-  den=sqrt((sum1Sq-pow(sum1,2)/len(v1))*(sum2Sq-pow(sum2,2)/len(v1)))

-  if den==0: return 0

-

-  return 1.0-num/den

-

-def tanimoto(v1, v2):

-    c1, c2, shr = 0, 0, 0

-    for i in range(len(v1)):

-        if v1[i] != 0:

-            c1 += 1 # in v1

-        if v2[i] != 0:

-            c2 += 1 # in v2

-        if v1[i] != 0 and v2[i] != 0:

-            shr += 1 # in both

-    return 1.0 - (float(shr) / (c1 + c2 - shr))

-

-def euclidian(v1, v2):

-    d = 0.0

-    for i in range(len(v1)):

-        d += (v1[i] - v2[i])**2

-    return math.sqrt(d)

-

-def kcluster(rows,distance=pearson,k=4):

-  # Determine the minimum and maximum values for each point

-  ranges=[(min([row[i] for row in rows]),max([row[i] for row in rows])) 

-  for i in range(len(rows[0]))]

-

-  # Create k randomly placed centroids

-  clusters=[[random.random()*(ranges[i][1]-ranges[i][0])+ranges[i][0] 

-  for i in range(len(rows[0]))] for j in range(k)]

-

-  lastmatches=None

-  for t in range(100):

-    print 'Iteration %d' % t

-    bestmatches=[[] for i in range(k)]

-

-    # Find which centroid is the closest for each row

-    for j in range(len(rows)):

-      row=rows[j]

-      bestmatch=0

-      for i in range(k):

-        d=distance(clusters[i],row)

-        if d<distance(clusters[bestmatch],row): bestmatch=i

-      bestmatches[bestmatch].append(j)

-

-    # If the results are the same as last time, this is complete

-    if bestmatches==lastmatches: break

-    lastmatches=bestmatches

-

-    # Move the centroids to the average of their members

-    for i in range(k):

-      avgs=[0.0]*len(rows[0])

-      if len(bestmatches[i])>0:

-        for rowid in bestmatches[i]:

-          for m in range(len(rows[rowid])):

-            avgs[m]+=rows[rowid][m]

-        for j in range(len(avgs)):

-          avgs[j]/=len(bestmatches[i])

-        clusters[i]=avgs

-

-  return bestmatches

-

-def scaledown(data,distance=pearson,rate=0.01):

-  n=len(data)

-

-  # The real distances between every pair of items

-  realdist=[[distance(data[i],data[j]) for j in range(n)] 

-             for i in range(0,n)]

-

-  # Randomly initialize the starting points of the locations in 2D

-  loc=[[random.random(),random.random()] for i in range(n)]

-  fakedist=[[0.0 for j in range(n)] for i in range(n)]

-

-  lasterror=None

-  for m in range(0,1000):

-    # Find projected distances

-    for i in range(n):

-      for j in range(n):

-        fakedist[i][j]=sqrt(sum([pow(loc[i][x]-loc[j][x],2) 

-                                 for x in range(len(loc[i]))]))

-

-    # Move points

-    grad=[[0.0,0.0] for i in range(n)]

-

-    totalerror=0

-    for k in range(n):

-      for j in range(n):

-        if j==k: continue

-        # The error is percent difference between the distances

-        errorterm=(fakedist[j][k]-realdist[j][k])/realdist[j][k]

-

-        # Each point needs to be moved away from or towards the other

-        # point in proportion to how much error it has

-        grad[k][0]+=((loc[k][0]-loc[j][0])/fakedist[j][k])*errorterm

-        grad[k][1]+=((loc[k][1]-loc[j][1])/fakedist[j][k])*errorterm

-

-        # Keep track of the total error

-        totalerror+=abs(errorterm)

-

-

-    # If the answer got worse by moving the points, we are done

-    if lasterror and lasterror<totalerror: break

-    lasterror=totalerror

-

-    # Move each of the points by the learning rate times the gradient

-    for k in range(n):

-      loc[k][0]-=rate*grad[k][0]

-      loc[k][1]-=rate*grad[k][1]

-

-  return loc

-

-def draw2d(data,labels,jpeg='mds2d.jpg'):

-  img=Image.new('RGB',(2000,2000),(255,255,255))

-  draw=ImageDraw.Draw(img)

-  for i in range(len(data)):

-    x=(data[i][0]+0.5)*1000

-    y=(data[i][1]+0.5)*1000

-    draw.text((x,y),labels[i],(0,0,0))

-  img.save(jpeg,'JPEG')