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#!/usr/bin/env python
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#!/usr/bin/env python
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import collections
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# TBD: remove part of the description to readme/example
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import sys
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"""
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This script calculates signature functions for knots (cable sums).
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The script can be run as a sage script from the terminal or used in inetactive
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mode.
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To calculate the number of characters for which signature function vanish use
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the function eval_cable_for_thetas as shown below:
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sage: eval_cable_for_thetas([[1, 3], [2], [-1, -2], [-3]])
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T(2, 3; 2, 7) # T(2, 5) # -T(2, 3; 2, 5) # -T(2, 7)
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Zero cases: 69
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All cases: 1225
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Zero theta combinations:
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(0, 0, 0, 0)
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(1, 1, 1, 1)
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(1, 2, 2, 1)
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(2, 1, 1, 2)
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(2, 2, 2, 2)
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(3, 0, 0, 3)
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('T(2, 3; 2, 7) # T(2, 5) # -T(2, 3; 2, 5) # -T(2, 7)', 69, 1225)
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sage:
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The numbers given to the function eval_cable_for_thetas are k-values for each
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component/cable in a direct sum.
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To calculate signature function for a knot and a theta value, use function
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get_function_of_theta_for_sum as follow:
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sage: signature_function_generator = get_function_of_theta_for_sum([1, 3], [2], [-1, -2], [-3])
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sage: sf = signature_function_generator(2, 1, 2, 2)
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sage: print sf
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0: 0
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1/7: 0
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1/6: 0
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1/5: -1
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2/5: 1
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3/7: 0
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1/2: 0
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4/7: 0
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3/5: -1
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4/5: 1
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5/6: 0
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6/7: 0
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sage:
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or like below:
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sage: print get_function_of_theta_for_sum([1, 3], [2], [-1, -2], [-3])(2, 1, 2, 2)
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0: 0
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1/7: 0
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1/6: 0
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1/5: -1
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2/5: 1
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3/7: 0
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1/2: 0
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4/7: 0
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3/5: -1
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4/5: 1
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5/6: 0
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6/7: 0
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sage:
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"""
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import os
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import os
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import sys
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import collections
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import inspect
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import inspect
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import pandas as pd
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import itertools as it
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import itertools as it
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import pandas as pd
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import re
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import re
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class MySettings(object):
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class MySettings(object):
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def __init__(self):
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def __init__(self):
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self.f_results = os.path.join(os.getcwd(), "results.out")
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self.f_results = os.path.join(os.getcwd(), "results.out")
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# is the ratio restriction for values in k_vector taken into account
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# False flag is usefull to make quick script tests
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self.only_slice_candidates = True
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self.only_slice_candidates = True
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self.only_slice_candidates = False
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# self.only_slice_candidates = False
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self.default_limit = 3
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# knot_sum_formula is a schema for knots which signature function
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def main(arg):
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# will be calculated
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try:
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self.knot_sum_formula = "[[k[0], k[1], k[2]], [k[3], k[4]], \
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limit = int(arg[1])
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except:
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limit = None
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second_knot_sum_formula = "[[k[0], k[1], k[2]], [k[3], k[4]], \
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[-k[0], -k[3], -k[4]], [-k[1], -k[2]]]"
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[-k[0], -k[3], -k[4]], [-k[1], -k[2]]]"
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first_knot_sum_formula = "[[k[0], k[1], k[2]], [k[3]],\
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# self.knot_sum_formula = "[[k[0], k[1], k[2]], [k[3]],\
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[-k[0], -k[1], -k[3]], [-k[2]]]"
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# [-k[0], -k[1], -k[3]], [-k[2]]]"
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tests(second_knot_sum_formula, limit)
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self.default_limit = 3
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tests(first_knot_sum_formula, limit)
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def is_trivial_combination(knot_sum):
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if len(knot_sum) == 4:
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oposit_to_first = [-k for k in knot_sum[0]]
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if oposit_to_first in knot_sum:
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return True
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return False
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def tests(knot_sum_formula, limit=None):
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settings = MySettings()
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if limit is None:
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limit = settings.default_limit
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k_vector_size = extract_max(knot_sum_formula) + 1
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with open(settings.f_results, 'w') as f_results:
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combinations = it.combinations_with_replacement(range(1, limit + 1),
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k_vector_size)
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for comb in combinations:
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if settings.only_slice_candidates and k_vector_size == 5:
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comb = [comb[0], 4 * comb[0] + comb[1],
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4 * (4 * comb[0] + comb[1]) + comb[2],
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4 * comb[0] + comb[3],
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4 * (4 * comb[0] + comb[3]) + comb[4]]
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k = comb
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knot_sum = eval(knot_sum_formula)
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if is_trivial_combination(knot_sum):
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continue
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result = eval_cable_for_thetas(knot_sum)
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if result is not None:
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knot_description, null_comb, all_comb = result
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line = (str(k) + ", " + str(null_comb) + ", " +
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str(all_comb) + "\n")
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f_results.write(line)
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class SignatureFunction(object):
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class SignatureFunction(object):
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@ -87,23 +117,12 @@ class SignatureFunction(object):
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"Signature function is defined on the interval [0, 1)."
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"Signature function is defined on the interval [0, 1)."
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self.data[jump_arg] = jump
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self.data[jump_arg] = jump
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def value(self, arg):
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# Compute the value of the signature function at the point arg.
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# This requires summing all signature jumps that occur before arg.
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assert 0 <= arg < 1, \
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"Signature function is defined on the interval [0, 1)."
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val = 0
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for jump_arg, jump in self.data.items():
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if jump_arg < arg:
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val += 2 * jump
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elif jump_arg == arg:
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val += jump
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return val
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def sum_of_absolute_values(self):
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def sum_of_absolute_values(self):
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return sum([abs(i) for i in self.data.values()])
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return sum([abs(i) for i in self.data.values()])
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def double_cover(self):
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def double_cover(self):
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# to read values for t^2
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new_data = []
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new_data = []
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for jump_arg, jump in self.data.items():
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for jump_arg, jump in self.data.items():
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new_data.append((mod_one(jump_arg/2), jump))
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new_data.append((mod_one(jump_arg/2), jump))
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@ -111,7 +130,7 @@ class SignatureFunction(object):
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return SignatureFunction(new_data)
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return SignatureFunction(new_data)
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def __lshift__(self, shift):
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def __lshift__(self, shift):
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# Shift of the signature functions correspond to the rotations.
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# A shift of the signature functions corresponds to the rotation.
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return self.__rshift__(-shift)
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return self.__rshift__(-shift)
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def __rshift__(self, shift):
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def __rshift__(self, shift):
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@ -120,11 +139,8 @@ class SignatureFunction(object):
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new_data.append((mod_one(jump_arg + shift), jump))
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new_data.append((mod_one(jump_arg + shift), jump))
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return SignatureFunction(new_data)
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return SignatureFunction(new_data)
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def __sub__(self, other):
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# we can perform arithmetic operations on signature functions.
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return self + other.__neg__()
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def __neg__(self):
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def __neg__(self):
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# we can perform arithmetic operations on signature functions.
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new_data = []
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new_data = []
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for jump_arg, jump in self.data.items():
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for jump_arg, jump in self.data.items():
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new_data.append(jump_arg, -jump)
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new_data.append(jump_arg, -jump)
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new_signature_function.data = new_data
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new_signature_function.data = new_data
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return new_signature_function
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return new_signature_function
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def __sub__(self, other):
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return self + other.__neg__()
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def __str__(self):
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def __str__(self):
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return '\n'.join([str(jump_arg) + ": " + str(jump)
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return '\n'.join([str(jump_arg) + ": " + str(jump)
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for jump_arg, jump in sorted(self.data.items())])
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for jump_arg, jump in sorted(self.data.items())])
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# def __repr__(self):
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# return self.__str__()
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def main(arg):
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"""
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This function is run if the script was called from the terminal.
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It calls another function to calculate signature functions for a schema
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of a cable sum defined in the class MySettings.
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Optionaly a parameter (a limit for k_0 value) can be given.
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Thought to be run for time consuming calculations.
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"""
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try:
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new_limit = int(arg[1])
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except:
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new_limit = None
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perform_calculations(limit=new_limit)
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def perform_calculations(knot_sum_formula=None, limit=None):
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"""
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This function calculates signature functions for knots constracted
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accordinga a schema for a cable sum. The schema is given as an argument
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or defined in the class MySettings.
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Results of calculations will be writen to a file and to the stdout.
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limit is the upper bound for the first value in k_vector, i.e first k value
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in a cable sum (the number of knots that will be constracted depends
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on limit value).
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For each knot/cable sum the function eval_cable_for_thetas is called.
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eval_cable_for_thetas calculetes the number of all possible thetas
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(characters) and the number of combinations for which signature function
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equeles zero. In case the first number is larger than squere of the second,
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eval_cable_for_thetas returns None (i.e. the knot can not be slice).
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Data for knots that are candidates for slice knots are saved to a file.
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"""
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settings = MySettings()
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if limit is None:
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limit = settings.default_limit
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if knot_sum_formula is None:
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knot_sum_formula = settings.knot_sum_formula
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k_vector_size = extract_max(knot_sum_formula) + 1
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combinations = it.combinations_with_replacement(range(1, limit + 1),
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k_vector_size)
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with open(settings.f_results, 'w') as f_results:
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for k in combinations:
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# print
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print k
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# TBD: maybe the following condition or the function
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# get_shifted_combination should be redefined to a dynamic version
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if settings.only_slice_candidates and k_vector_size == 5:
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k = get_shifted_combination(k)
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print k
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knot_sum = eval(knot_sum_formula)
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if is_trivial_combination(knot_sum):
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continue
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result = eval_cable_for_thetas(knot_sum, print_results=False)
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if result is not None:
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knot_description, null_comb, all_comb = result
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line = (str(k) + ", " + str(null_comb) + ", " +
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str(all_comb) + "\n")
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f_results.write(line)
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def is_trivial_combination(knot_sum):
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# for now is applicable only for schema that are sums of 4 cables
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if len(knot_sum) == 4:
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oposit_to_first = [-k for k in knot_sum[0]]
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if oposit_to_first in knot_sum:
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return True
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return False
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def get_shifted_combination(combination):
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# for now applicable only for schama
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# "[[k[0], k[1], k[2]], [k[3], k[4]],
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# [-k[0], -k[3], -k[4]], [-k[1], -k[2]]]"
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# shift the combination so that the knot can be a candidate for slice
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combination = [combination[0], 4 * combination[0] + combination[1],
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4 * (4 * combination[0] + combination[1]) + combination[2],
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4 * combination[0] + combination[3],
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4 * (4 * combination[0] + combination[3]) + combination[4]]
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return combination
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# Proposition 9.8.
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def get_blanchfield_for_pattern(k_n, theta):
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def get_blanchfield_for_pattern(k_n, theta):
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"""
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This function calculates a twisted signature function for a given cable
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and theta/character. It returns object of class SignatureFunction.
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It is based on Proposition 9.8. in Twisted Blanchfield Pairing.
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"""
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if theta == 0:
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if theta == 0:
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return get_untwisted_signature_function(k_n)
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return get_untwisted_signature_function(k_n)
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results = []
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results = []
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@ -176,16 +281,27 @@ def get_blanchfield_for_pattern(k_n, theta):
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return SignatureFunction(results)
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return SignatureFunction(results)
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# Bl_theta(K'_(2, d) =
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# Bl_theta(T_2, d) + Bl(K')(ksi_l^(-theta) * t)
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# + Bl(K')(ksi_l^theta * t)
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def get_cable_signature_as_theta_function(*arg):
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def get_cable_signature_as_theta_function(*arg):
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def signture_function(theta):
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"""
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This function takes as an argument a single cable and returns another
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function that alow to calculate signature function for previously defined
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cable and a theta given as an argument.
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"""
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def get_signture_function(theta):
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"""
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This function returns SignatureFunction for previously defined cable
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and a theta given as an argument.
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It is an implementaion of the formula:
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Bl_theta(K'_(2, d)) =
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Bl_theta(T_2, d) + Bl(K')(ksi_l^(-theta) * t)
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+ Bl(K')(ksi_l^theta * t)
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"""
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if theta > abs(arg[-1]):
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if theta > abs(arg[-1]):
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print "k for pattern is " + str(arg[-1])
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print "k for the pattern in the cable is " + str(arg[-1])
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print "theta shouldn't be larger than this"
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print "theta shouldn't be larger than this"
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return None
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return None
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cable_signature = get_blanchfield_for_pattern(arg[-1], theta)
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cable_signature = get_blanchfield_for_pattern(arg[-1], theta)
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for i, k in enumerate(arg[:-1][::-1]):
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for i, k in enumerate(arg[:-1][::-1]):
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ksi = 1/(2 * abs(k) + 1)
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ksi = 1/(2 * abs(k) + 1)
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power = 2^i
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power = 2^i
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@ -198,11 +314,12 @@ def get_cable_signature_as_theta_function(*arg):
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c = c.double_cover()
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c = c.double_cover()
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cable_signature += b + c
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cable_signature += b + c
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return cable_signature
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return cable_signature
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return signture_function
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return get_signture_function
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def get_untwisted_signature_function(j):
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def get_untwisted_signature_function(j):
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# Return the signature function of the T_{2,2k+1} torus knot.
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"""This function returns the signature function of the T_{2,2k+1}
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torus knot."""
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k = abs(j)
|
k = abs(j)
|
||||||
w = ([((2 * a + 1)/(4 * k + 2), -1 * sgn(j)) for a in range(k)] +
|
w = ([((2 * a + 1)/(4 * k + 2), -1 * sgn(j)) for a in range(k)] +
|
||||||
[((2 * a + 1)/(4 * k + 2), 1 * sgn(j))
|
[((2 * a + 1)/(4 * k + 2), 1 * sgn(j))
|
||||||
@ -214,17 +331,23 @@ def get_function_of_theta_for_sum(*arg):
|
|||||||
"""
|
"""
|
||||||
Function intended to calculate signature function for a connected
|
Function intended to calculate signature function for a connected
|
||||||
sum of multiple cables with varying theta parameter values.
|
sum of multiple cables with varying theta parameter values.
|
||||||
Accept arbitrary number of arguments (number of cables in connected sum).
|
Accept arbitrary number of arguments (depending on number of cables in
|
||||||
|
connected sum).
|
||||||
Each argument should be given as list of integer representing
|
Each argument should be given as list of integer representing
|
||||||
k - parameters for a cable: parameters k_i (i=1,.., n-1) for satelit knots
|
k - parameters for a cable: parameters k_i (i=1,.., n-1) for satelit knots
|
||||||
T(2, 2k_i + 1) and - the last one - k_n for a pattern knot T(2, 2k_n + 1).
|
T(2, 2k_i + 1) and - the last one - k_n for a pattern knot T(2, 2k_n + 1).
|
||||||
Returns a function described below.
|
Returns a function that will take theta vector as an argument and return
|
||||||
|
an object SignatureFunction.
|
||||||
"""
|
"""
|
||||||
|
|
||||||
def signature_function_for_sum(*thetas):
|
def signature_function_for_sum(*thetas):
|
||||||
# Returns object of SignatureFunction class for a previously defined
|
"""
|
||||||
# connercted sum of len(arg) cables.
|
Returns object of SignatureFunction class for a previously defined
|
||||||
# Accept len(arg) arguments: for each cable one theta parameter.
|
connercted sum of len(arg) cables.
|
||||||
# If call with no arguments, all theta parameters are set to be 0.
|
Accept len(arg) arguments: for each cable one theta parameter.
|
||||||
|
If call with no arguments, all theta parameters are set to be 0.
|
||||||
|
"""
|
||||||
|
|
||||||
la = len(arg)
|
la = len(arg)
|
||||||
lt = len(thetas)
|
lt = len(thetas)
|
||||||
if lt == 0:
|
if lt == 0:
|
||||||
@ -240,13 +363,17 @@ def get_function_of_theta_for_sum(*arg):
|
|||||||
return signature_function_for_sum
|
return signature_function_for_sum
|
||||||
|
|
||||||
|
|
||||||
def mod_one(n):
|
def eval_cable_for_thetas(knot_sum, print_results=True):
|
||||||
"""This function returns the fractional part of some number."""
|
"""
|
||||||
return n - floor(n)
|
This function calculates all possible twisted signature functions for
|
||||||
|
a knot that is given as an argument. The knot should be encoded as a list
|
||||||
|
of its direct component. Each component schould be presented as a list
|
||||||
def eval_cable_for_thetas(knot_sum):
|
of integers. This integers correspond to the k - values in each component/
|
||||||
|
cable. If a component is a mirror image of a cable the minus sign should
|
||||||
|
be written before each number for this component. For example:
|
||||||
|
eval_cable_for_thetas([[1, 8], [2], [-2, -8], [-2]])
|
||||||
|
eval_cable_for_thetas([[1, 2], [-1, -2]])
|
||||||
|
"""
|
||||||
f = get_function_of_theta_for_sum(*knot_sum)
|
f = get_function_of_theta_for_sum(*knot_sum)
|
||||||
knot_description = get_knot_descrption(*knot_sum)
|
knot_description = get_knot_descrption(*knot_sum)
|
||||||
all_combinations = get_number_of_combinations(*knot_sum)
|
all_combinations = get_number_of_combinations(*knot_sum)
|
||||||
@ -261,17 +388,19 @@ def eval_cable_for_thetas(knot_sum):
|
|||||||
zero_theta_combinations.append(v_theta)
|
zero_theta_combinations.append(v_theta)
|
||||||
m = len([theta for theta in v_theta if theta != 0])
|
m = len([theta for theta in v_theta if theta != 0])
|
||||||
null_combinations += 2^m
|
null_combinations += 2^m
|
||||||
else:
|
# else:
|
||||||
assert sum(v_theta) != 0
|
# assert sum(v_theta) != 0
|
||||||
|
|
||||||
if null_combinations^2 >= all_combinations:
|
if print_results:
|
||||||
print
|
print
|
||||||
print knot_description
|
print knot_description
|
||||||
print "Zero cases: " + str(null_combinations)
|
print "Zero cases: " + str(null_combinations)
|
||||||
print "All cases: " + str(all_combinations)
|
print "All cases: " + str(all_combinations)
|
||||||
|
if zero_theta_combinations:
|
||||||
print "Zero theta combinations: "
|
print "Zero theta combinations: "
|
||||||
for el in zero_theta_combinations:
|
for el in zero_theta_combinations:
|
||||||
print el
|
print el
|
||||||
|
if null_combinations^2 >= all_combinations:
|
||||||
return knot_description, null_combinations, all_combinations
|
return knot_description, null_combinations, all_combinations
|
||||||
return None
|
return None
|
||||||
|
|
||||||
@ -294,27 +423,18 @@ def get_number_of_combinations(*arg):
|
|||||||
number_of_combinations *= (2 * abs(knot[-1]) + 1)
|
number_of_combinations *= (2 * abs(knot[-1]) + 1)
|
||||||
return number_of_combinations
|
return number_of_combinations
|
||||||
|
|
||||||
|
|
||||||
def extract_max(string):
|
def extract_max(string):
|
||||||
numbers = re.findall('\d+',string)
|
"""This function returns maximal number from given string."""
|
||||||
numbers = map(int,numbers)
|
numbers = re.findall('\d+', string)
|
||||||
|
numbers = map(int, numbers)
|
||||||
return max(numbers)
|
return max(numbers)
|
||||||
|
|
||||||
|
|
||||||
|
def mod_one(n):
|
||||||
|
"""This function returns the fractional part of some number."""
|
||||||
|
return n - floor(n)
|
||||||
|
|
||||||
|
|
||||||
if __name__ == '__main__' and '__file__' in globals():
|
if __name__ == '__main__' and '__file__' in globals():
|
||||||
main(sys.argv)
|
main(sys.argv)
|
||||||
|
|
||||||
#
|
|
||||||
# def get_sigma(t, k):
|
|
||||||
# p = 2
|
|
||||||
# q = 2 * k + 1
|
|
||||||
# sigma_set = get_sigma_set(p, q)
|
|
||||||
# sigma = len(sigma_set) - 2 * len([z for z in sigma_set if t < z < 1 + t])
|
|
||||||
# return sigma
|
|
||||||
#
|
|
||||||
#
|
|
||||||
# def get_sigma_set(p, q):
|
|
||||||
# sigma_set = set()
|
|
||||||
# for i in range(1, p):
|
|
||||||
# for j in range(1, q):
|
|
||||||
# sigma_set.add(j/q + i/p)
|
|
||||||
# return sigma_set
|
|
||||||
|
Loading…
Reference in New Issue
Block a user