In mathematics, a factorisation of a free monoid is a sequence of subsets of words with the property that every word in the free monoid can be written as a concatenation of elements drawn from the subsets. The Chen–Fox–Lyndon theorem states that the Lyndon words furnish a factorisation. The Schützenberger theorem relates the definition in terms of a multiplicative property to an additive property.[clarification needed]
Let A∗ be the free monoid on an alphabet A. Let Xi be a sequence of subsets of A∗ indexed by a totally ordered index set I. A factorisation of a word w in A∗ is an expression
with and . Some authors reverse the order of the inequalities.
Chen–Fox–Lyndon theorem
editA Lyndon word over a totally ordered alphabet A is a word that is lexicographically less than all its rotations.[1] The Chen–Fox–Lyndon theorem states that every string may be formed in a unique way by concatenating a lexicographically non-increasing sequence of Lyndon words. Hence taking Xl to be the singleton set {l} for each Lyndon word l, with the index set L of Lyndon words ordered lexicographically, we obtain a factorisation of A∗.[2] Such a factorisation can be found in linear time and constant space by Duval's algorithm.[3] The algorithm[4] in Python code is:
def chen_fox_lyndon_factorization(s: list[int]) -> list[int]:
"""Monoid factorisation using the Chen–Fox–Lyndon theorem.
Args:
s: a list of integers
Returns:
a list of integers
"""
n = len(s)
factorization = []
i = 0
while i < n:
j, k = i + 1, i
while j < n and s[k] <= s[j]:
if s[k] < s[j]:
k = i
else:
k += 1
j += 1
while i <= k:
factorization.append(s[i:i + j - k])
i += j - k
return factorization
Hall words
editThe Hall set provides a factorization.[5] Indeed, Lyndon words are a special case of Hall words. The article on Hall words provides a sketch of all of the mechanisms needed to establish a proof of this factorization.
Bisection
editA bisection of a free monoid is a factorisation with just two classes X0, X1.[6]
Examples:
- A = {a,b}, X0 = {A∗b}, X1 = {a}.
If X, Y are disjoint sets of non-empty words, then (X,Y) is a bisection of A∗ if and only if[7]
As a consequence, for any partition P, Q of A+ there is a unique bisection (X,Y) with X a subset of P and Y a subset of Q.[8]
Schützenberger theorem
editThis theorem states that a sequence Xi of subsets of A∗ forms a factorisation if and only if two of the following three statements hold:
- Every element of A∗ has at least one expression in the required form;[clarification needed]
- Every element of A∗ has at most one expression in the required form;
- Each conjugate class C meets just one of the monoids Mi = Xi∗ and the elements of C in Mi are conjugate in Mi.[9][clarification needed]
See also
editReferences
edit- ^ Lothaire (1997) p.64
- ^ Lothaire (1997) p.67
- ^ Duval, Jean-Pierre (1983). "Factorizing words over an ordered alphabet". Journal of Algorithms. 4 (4): 363–381. doi:10.1016/0196-6774(83)90017-2..
- ^ "Lyndon factorization - Algorithms for Competitive Programming". cp-algorithms.com. Retrieved 2024-01-30.
- ^ Guy Melançon, (1992) "Combinatorics of Hall trees and Hall words", Journal of Combinatoric Theory, 59A(2) pp. 285–308.
- ^ Lothaire (1997) p.68
- ^ Lothaire (1997) p.69
- ^ Lothaire (1997) p.71
- ^ Lothaire (1997) p.92
- Lothaire, M. (1997), Combinatorics on words, Encyclopedia of Mathematics and Its Applications, vol. 17, Perrin, D.; Reutenauer, C.; Berstel, J.; Pin, J.-É.; Pirillo, G.; Foata, D.; Sakarovitch, J.; Simon, I.; Schützenberger, M. P.; Choffrut, C.; Cori, R.; Lyndon, R.; Rota, G.-C. Foreword by Roger Lyndon (2nd ed.), Cambridge University Press, ISBN 0-521-59924-5, Zbl 0874.20040