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# -*- coding: utf-8 -*-
from Levenshtein import distance as levenshtein
import re
import itertools
def simplify(text):
mapp = [(u"’", u"'"), (u"↑", u"."), (u"…", u"..."), (u"É", u"E"),
(u"À", u"A"), (u"Ô", u"O"), (u"—", u"-")]
for a, b in mapp:
text = text.replace(a, b)
return text
def cut(word, left, right):
"""Return pair of strings (p + "-", s) such that p+s == word and
L(p + "-", left) + L(s, right) is minimal, where L is the levenshtein
distance.
Implementation is suboptimal since the computation of the Levenshtein
distances will involve comparing the same segments repeatedly.
TODO: handle the case when word contains an hyphen (e.g. c'est-a-dire)
"""
def aux(i):
leftw, rightw = word[:i] + "-", word[i:]
return (leftw, rightw,
levenshtein(leftw, left) + levenshtein(rightw, right))
l = [aux(i) for i in xrange(len(word) + 1)]
return min(l, key=lambda x: x[2])[:2]
def LCS(X, Y):
m = len(X)
n = len(Y)
# An (m+1) times (n+1) matrix
C = [[0] * (n+1) for i in range(m+1)]
for i in range(1, m+1):
for j in range(1, n+1):
if X[i-1] == Y[j-1]:
C[i][j] = C[i-1][j-1] + 1
else:
C[i][j] = max(C[i][j-1], C[i-1][j])
return C
def printDiff(C, X, Y, i, j):
if i > 0 and j > 0 and X[i-1] == Y[j-1]:
printDiff(C, X, Y, i-1, j-1)
print " " + X[i-1]
else:
if j > 0 and (i == 0 or C[i][j-1] >= C[i-1][j]):
printDiff(C, X, Y, i, j-1)
print "+ " + Y[j-1]
elif i > 0 and (j == 0 or C[i][j-1] < C[i-1][j]):
printDiff(C, X, Y, i-1, j)
print "- " + X[i-1]
def join_ocr_words(l, c):
m = list(l)
if len(l) >= 2 and c[-2][2] > c[-1][0] and (not l[-2][-1].isalnum()):
l[-2] = l[-2][:-1]
return "".join(l)
def join_words(l):
return "".join(l)
def align(l1, l2, c2):
"""Compute the optimal alignment between two list of words
à la Needleman-Wunsch.
The function returns a (score, alignment) pair. An alignment is simply
a list of size len(l1) giving for each word in l1, the index of the word in
l2 it maps to (or -1 if the word maps to nothing).
Note that we also allow the index to be a tuple when a word in l1 maps to
a sequence of words in l2. Conversly, consecutive words in l1 can map to
the same word in l2.
"""
# Throughout the function, l1 is to be thought of as the proofread text,
# and l2 as the OCR text. The deletion costs are not symmetric: removing
# junk from the OCR is frequent while removing a word from the proofread
# text should be rare.
del_cost1 = 50
def del_cost2(w):
return 1+3*len([c for c in w if c.isalnum()])
w = 3 # multiplicative cost factor for the Levenshtein distance
n, m = len(l1), len(l2)
# a is the (score, alignment) matrix. a[i][j] is the (score, alignment)
# pair of the first i words of l1 to the first j words of l2
a = [[(0, [])] * (m + 1) for i in xrange(n + 1)]
for j in xrange(1, m + 1):
a[0][j] = j, []
for i in xrange(1, n + 1):
a[i][0] = i * del_cost1, [-1] * i
for j in xrange(1, m + 1):
s, b = a[i-1][j-1]
d = levenshtein(l1[i-1], l2[j-1])
min_s, min_b = s + w * d, b + [j-1]
s, b = a[i-1][j]
if s + del_cost1 < min_s:
min_s, min_b = s + del_cost1, b + [-1]
s, b = a[i][j-1]
if s + del_cost2(l2[j-1]) < min_s:
min_s, min_b = s + del_cost2(l2[j-1]), b
for k in xrange(1, 8):
for l in xrange(1, 5):
if k + l <= 2:
continue
if k+l > 7:
break
if j < l or i < k:
break
s, b = a[i-k][j-l]
d = levenshtein(join_words(l1[i-k:i]),
join_ocr_words(l2[j-l:j], c2[j-l:j]))
if s + w * d < min_s:
temp = [j-1] if l == 1 else [tuple(range(j-l, j))]
min_s, min_b = s + w * d, b + temp * k
a[i][j] = min_s, min_b
return a[n][m]
def print_alignment(l1, l2, c2, alignment):
"""Given two list of words and an alignment (as defined in :func:`align`)
print the two list of words side-by-side and aligned.
"""
prev = 0
for index, g in itertools.groupby(zip(l1, alignment), lambda x:x[1]):
word = " ".join([a[0] for a in g])
if index == -1:
print u"{0:>25} | ".format(word)
else:
if type(index) == tuple:
begin, end = index[0], index[-1]
else:
begin, end = index, index
while prev < begin - 1:
prev += 1
print u"{0:>25} | {1}".format("", l2[prev])
prev = end
if end > begin:
print u"{0:>25} | {1:<25} (M)".format(word,
join_ocr_words(l2[begin:end+1], c2[begin:end+1]))
else:
print u"{0:>25} | {1:<25}".format(word, l2[begin])
if not l1:
for word in l2:
print u"{0:>25} | {1}".format("", word)
def alignment_to_sexp(alignment, sexp, l2):
alignment = iter(alignment)
for line in sexp:
if "word" not in line:
print line
else:
index = alignment.next()
if index == -1:
break
else:
if type(index) == tuple:
word = " ".join([l2[i] for i in list(index)])
else:
try:
word = l2[index]
except IndexError:
print index
word = word.encode("utf-8").encode("string-escape")
re.sub("(?P<begin>\d+ \d+ \d+ \d+\s) \w+(?P<end>\)+$)",
"\g<begin>{0}\g<end>".format(word), line)
print line
|
