Lib/lib-old/zmod.py - platform/external/python/cpython3 - Gitiles

 # module 'zmod'

 # Compute properties of mathematical "fields" formed by taking
 # Z/n (the whole numbers modulo some whole number n) and an
 # irreducible polynomial (i.e., a polynomial with only complex zeros),
 # e.g., Z/5 and X**2 + 2.
 #
 # The field is formed by taking all possible linear combinations of
 # a set of d base vectors (where d is the degree of the polynomial).
 #
 # Note that this procedure doesn't yield a field for all combinations
 # of n and p: it may well be that some numbers have more than one
 # inverse and others have none.  This is what we check.
 #
 # Remember that a field is a ring where each element has an inverse.
 # A ring has commutative addition and multiplication, a zero and a one:
 # 0*x = x*0 = 0, 0+x = x+0 = x, 1*x = x*1 = x.  Also, the distributive
 # property holds: a*(b+c) = a*b + b*c.
 # (XXX I forget if this is an axiom or follows from the rules.)

 import poly


 # Example N and polynomial

 N = 5
 P = poly.plus(poly.one(0, 2), poly.one(2, 1)) # 2 + x**2


 # Return x modulo y.  Returns >= 0 even if x < 0.

 def mod(x, y):
 	return divmod(x, y)[1]


 # Normalize a polynomial modulo n and modulo p.

 def norm(a, n, p):
 	a = poly.modulo(a, p)
 	a = a[:]
 	for i in range(len(a)): a[i] = mod(a[i], n)
 	a = poly.normalize(a)
 	return a


 # Make a list of all n^d elements of the proposed field.

 def make_all(mat):
 	all = []
 	for row in mat:
 		for a in row:
 			all.append(a)
 	return all

 def make_elements(n, d):
 	if d == 0: return [poly.one(0, 0)]
 	sub = make_elements(n, d-1)
 	all = []
 	for a in sub:
 		for i in range(n):
 			all.append(poly.plus(a, poly.one(d-1, i)))
 	return all

 def make_inv(all, n, p):
 	x = poly.one(1, 1)
 	inv = []
 	for a in all:
 		inv.append(norm(poly.times(a, x), n, p))
 	return inv

 def checkfield(n, p):
 	all = make_elements(n, len(p)-1)
 	inv = make_inv(all, n, p)
 	all1 = all[:]
 	inv1 = inv[:]
 	all1.sort()
 	inv1.sort()
 	if all1 == inv1: print 'BINGO!'
 	else:
 		print 'Sorry:', n, p
 		print all
 		print inv

 def rj(s, width):
 	if type(s) is not type(''): s = `s`
 	n = len(s)
 	if n >= width: return s
 	return ' '*(width - n) + s

 def lj(s, width):
 	if type(s) is not type(''): s = `s`
 	n = len(s)
 	if n >= width: return s
 	return s + ' '*(width - n)
	# module 'zmod'

	# Compute properties of mathematical "fields" formed by taking
	# Z/n (the whole numbers modulo some whole number n) and an
	# irreducible polynomial (i.e., a polynomial with only complex zeros),
	# e.g., Z/5 and X**2 + 2.
	#
	# The field is formed by taking all possible linear combinations of
	# a set of d base vectors (where d is the degree of the polynomial).
	#
	# Note that this procedure doesn't yield a field for all combinations
	# of n and p: it may well be that some numbers have more than one
	# inverse and others have none. This is what we check.
	#
	# Remember that a field is a ring where each element has an inverse.
	# A ring has commutative addition and multiplication, a zero and a one:
	# 0x = x0 = 0, 0+x = x+0 = x, 1x = x1 = x. Also, the distributive
	# property holds: a(b+c) = ab + b*c.
	# (XXX I forget if this is an axiom or follows from the rules.)

	import poly


	# Example N and polynomial

	N = 5
	P = poly.plus(poly.one(0, 2), poly.one(2, 1)) # 2 + x**2


	# Return x modulo y. Returns >= 0 even if x < 0.

	def mod(x, y):
	return divmod(x, y)[1]


	# Normalize a polynomial modulo n and modulo p.

	def norm(a, n, p):
	a = poly.modulo(a, p)
	a = a[:]
	for i in range(len(a)): a[i] = mod(a[i], n)
	a = poly.normalize(a)
	return a


	# Make a list of all n^d elements of the proposed field.

	def make_all(mat):
	all = []
	for row in mat:
	for a in row:
	all.append(a)
	return all

	def make_elements(n, d):
	if d == 0: return [poly.one(0, 0)]
	sub = make_elements(n, d-1)
	all = []
	for a in sub:
	for i in range(n):
	all.append(poly.plus(a, poly.one(d-1, i)))
	return all

	def make_inv(all, n, p):
	x = poly.one(1, 1)
	inv = []
	for a in all:
	inv.append(norm(poly.times(a, x), n, p))
	return inv

	def checkfield(n, p):
	all = make_elements(n, len(p)-1)
	inv = make_inv(all, n, p)
	all1 = all[:]
	inv1 = inv[:]
	all1.sort()
	inv1.sort()
	if all1 == inv1: print 'BINGO!'
	else:
	print 'Sorry:', n, p
	print all
	print inv

	def rj(s, width):
	if type(s) is not type(''): s = `s`
	n = len(s)
	if n >= width: return s
	return ' '*(width - n) + s

	def lj(s, width):
	if type(s) is not type(''): s = `s`
	n = len(s)
	if n >= width: return s
	return s + ' '*(width - n)