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palindrome-pairs.py
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palindrome-pairs.py
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# Time: O(n * k^2), n is the number of the words, k is the max length of the words.
# Space: O(n * k)
# Given a list of unique words. Find all pairs of indices (i, j)
# in the given list, so that the concatenation of the two words,
# i.e. words[i] + words[j] is a palindrome.
#
# Example 1:
# Given words = ["bat", "tab", "cat"]
# Return [[0, 1], [1, 0]]
# The palindromes are ["battab", "tabbat"]
# Example 2:
# Given words = ["abcd", "dcba", "lls", "s", "sssll"]
# Return [[0, 1], [1, 0], [3, 2], [2, 4]]
# The palindromes are ["dcbaabcd", "abcddcba", "slls", "llssssll"]
import collections
class Solution(object):
def palindromePairs(self, words):
"""
:type words: List[str]
:rtype: List[List[int]]
"""
res = []
lookup = {}
for i, word in enumerate(words):
lookup[word] = i
for i in xrange(len(words)):
for j in xrange(len(words[i]) + 1):
prefix = words[i][j:]
suffix = words[i][:j]
if prefix == prefix[::-1] and \
suffix[::-1] in lookup and lookup[suffix[::-1]] != i:
res.append([i, lookup[suffix[::-1]]])
if j > 0 and suffix == suffix[::-1] and \
prefix[::-1] in lookup and lookup[prefix[::-1]] != i:
res.append([lookup[prefix[::-1]], i])
return res
# Time: O(n * k^2), n is the number of the words, k is the max length of the words.
# Space: O(n * k^2)
# Manacher solution.
class Solution_TLE(object):
def palindromePairs(self, words):
"""
:type words: List[str]
:rtype: List[List[int]]
"""
def manacher(s, P):
def preProcess(s):
if not s:
return ['^', '$']
T = ['^']
for c in s:
T += ["#", c]
T += ['#', '$']
return T
T = preProcess(s)
center, right = 0, 0
for i in xrange(1, len(T) - 1):
i_mirror = 2 * center - i
if right > i:
P[i] = min(right - i, P[i_mirror])
else:
P[i] = 0
while T[i + 1 + P[i]] == T[i - 1 - P[i]]:
P[i] += 1
if i + P[i] > right:
center, right = i, i + P[i]
prefix, suffix = collections.defaultdict(list), collections.defaultdict(list)
for i, word in enumerate(words):
P = [0] * (2 * len(word) + 3)
manacher(word, P)
for j in xrange(len(P)):
if j - P[j] == 1:
prefix[word[(j + P[j]) / 2:]].append(i)
if j + P[j] == len(P) - 2:
suffix[word[:(j - P[j]) / 2]].append(i)
res = []
for i, word in enumerate(words):
for j in prefix[word[::-1]]:
if j != i:
res.append([i, j])
for j in suffix[word[::-1]]:
if len(word) != len(words[j]):
res.append([j, i])
return res
# Time: O(n * k^2), n is the number of the words, k is the max length of the words.
# Space: O(n * k)
# Trie solution.
class TrieNode:
def __init__(self):
self.word_idx = -1
self.leaves = {}
def insert(self, word, i):
cur = self
for c in word:
if not c in cur.leaves:
cur.leaves[c] = TrieNode()
cur = cur.leaves[c]
cur.word_idx = i
def find(self, s, idx, res):
cur = self
for i in reversed(xrange(len(s))):
if s[i] in cur.leaves:
cur = cur.leaves[s[i]]
if cur.word_idx not in (-1, idx) and \
self.is_palindrome(s, i - 1):
res.append([cur.word_idx, idx])
else:
break
def is_palindrome(self, s, j):
i = 0
while i <= j:
if s[i] != s[j]:
return False
i += 1
j -= 1
return True
class Solution_MLE(object):
def palindromePairs(self, words):
"""
:type words: List[str]
:rtype: List[List[int]]
"""
res = []
trie = TrieNode()
for i in xrange(len(words)):
trie.insert(words[i], i)
for i in xrange(len(words)):
trie.find(words[i], i, res)
return res