first lines for cab.update function

2020-09-24 02:42:25 +02:00 · 2020-09-24 02:42:25 +02:00 · acbf651697
commit acbf651697
parent b729a4eeee
2 changed files with 90 additions and 33 deletions
--- a/cable_signature.sage
+++ b/cable_signature.sage
@ -7,6 +7,8 @@ from typing import Iterable
 SIGNATURE = 0
 SIGMA = 1

+# 9.11 (9.8)
+# 9.15 (9.9)


 class SignatureFunction(object):
@ -21,40 +23,57 @@ class SignatureFunction(object):

            msg = "Signature function is defined on the interval [0, 1)."
            assert all(k < 1 for k, v in values), msg
-
+            counter2 = collections.Counter({ k : v for k, v in values})
            for k, v in values:
                counter[k] += v
+            assert counter2 == counter
        self.cnt_signature_jumps = counter
+        self.tikz_plot("bum.tex")

-    def sum_of_absolute_values(self):
-        return sum([abs(i) for i in self.cnt_signature_jumps.values()])

    def is_zero_everywhere(self):
        return not any(self.cnt_signature_jumps.values())

    def double_cover(self):
        # to read values for t^2
+        items = self.cnt_signature_jumps.items()
+        counter = collections.Counter({ (1 + k) / 2 : v for k, v in items})
+        counter.update(collections.Counter({ k / 2 : v for k, v in items}))
        new_data = []
        for jump_arg, jump in self.cnt_signature_jumps.items():
            if jump != 0:
                new_data.append((jump_arg/2, jump))
                new_data.append((1/2 + jump_arg/2, jump))
+        assert SignatureFunction(values=new_data) == SignatureFunction(counter=counter)
        return SignatureFunction(values=new_data)

    def square_root(self):
        # to read values for t^(1/2)
        new_data = []
        for jump_arg, jump in self.cnt_signature_jumps.items():
-            if jump_arg < 1/2 and jump != 0:
+            if jump_arg < 1/2:
                new_data.append((2 * jump_arg, jump))
+
+        counter = collections.Counter()
+        for jump_arg, jump in self.cnt_signature_jumps.items():
+            if jump_arg < 1/2:
+                counter[2 * jump_arg] = jump
+        assert SignatureFunction(values=new_data) == SignatureFunction(counter=counter)
+
+
        return SignatureFunction(values=new_data)

    def minus_square_root(self):
        # to read values for t^(1/2)
+        items = self.cnt_signature_jumps.items()
+
        counter = collections.Counter()
        for jump_arg, jump in self.cnt_signature_jumps.items():
-            if jump_arg >= 1/2 and jump != 0:
+            if jump_arg >= 1/2:
                counter[mod_one(2 * jump_arg)] = jump
+        counter2 = collections.Counter({ mod_one(2 * k) : v for k, v in items if k >= 1/2 })
+        assert counter2 ==  counter
+
        return SignatureFunction(counter=counter)

    def is_big(self):
@ -63,12 +82,7 @@ class SignatureFunction(object):
        items = sorted(self.cnt_signature_jumps.items())
        for arg, jump in items:
            current += 2 * jump
-            msg = "current = " + str(current) + ", jump = " + str(jump)
-            msg += "\n" + str(self(arg))
-            result = [jump for jump_arg, jump in self.cnt_signature_jumps.items() if jump_arg < mod_one(arg)]
-            msg += "\nresult = " + str(sum(result))
-            msg += "\narg = " + str(arg)
-            assert current == self(arg) + jump, msg
+            assert current == self(arg) + jump
            if abs(current) > abs(max):
                max = current
                # if abs(max) > 9:
@ -81,6 +95,7 @@ class SignatureFunction(object):
        for jump_arg, jump in self.cnt_signature_jumps.items():
            new_data.append((mod_one(jump_arg + shift), jump))
        sf = SignatureFunction(values=new_data)
+
        counter = collections.Counter({mod_one(k + shift) : v \
                                for k,v in self.cnt_signature_jumps.items()})
        assert SignatureFunction(counter=counter) == \
@ -128,18 +143,29 @@ class SignatureFunction(object):

    def total_sign_jump(self):
        # Total signature jump is the sum of all jumps.
+        result =  sum([j[1] for j in self.to_list()])
+        assert result == sum(v for _, v in self.cnt_signature_jumps.items())
        return sum([j[1] for j in self.to_list()])

    def to_list(self):
        # Return signature jumps formated as a list
+        assert sorted(self.cnt_signature_jumps.items(), key = lambda x: x[0]) == \
+                sorted(self.cnt_signature_jumps.items())
        return sorted(self.cnt_signature_jumps.items(), key = lambda x: x[0])

    def step_function_data(self):
        # Transform the signature jump data to a format understandable
        # by the plot function.
        l = self.to_list()
+        assert l == sorted(self.cnt_signature_jumps.items())
        vals = ([(d[0], sum(2 * j[1] for j in l[:l.index(d)+1])) for d in l] +
              [(0,self.cnt_signature_jumps[0]), (1,self.total_sign_jump())])
+        print("step_function_data")
+        print(vals)
+        counter = copy(self.cnt_signature_jumps)
+        counter[0] = self.cnt_signature_jumps[0]
+        counter[1] = self.total_sign_jump()
+        print(sorted(counter.items()))
        return vals

    def plot(self):
@ -147,7 +173,7 @@ class SignatureFunction(object):
        plot_step_function(self.step_function_data())

    def tikz_plot(self, file_name):
-        # Draw the graph of the signature and transform it into            TiKz.
+        # Draw the graph of the signature and transform it into TiKz.
        # header of the LaTeX file

        with open(file_name, "w") as output_file:
@ -156,10 +182,12 @@ class SignatureFunction(object):
            output_file.write("\\begin{document}\n")
            output_file.write("\\begin{tikzpicture}\n")
            data = sorted(self.step_function_data())
+            print("data")
+            print(data)
            output_file.write("  \\datavisualization[scientific axes,visualize as smooth line,\n")
            output_file.write("  x axis={ticks={none,major={at={")
            output_file.write(", " + str(N(data[0][0],digits=4)) + " as \\(" + str(data[0][0]) + "\\)")
-            for jump_arg,jump in data:
+            for jump_arg, jump in data:
                output_file.write(", " + str(N(jump_arg,digits=4)) + " as \\(" + str(jump_arg) + "\\)")
                output_file.write("}}}}\n")
                output_file.write("  ]\n")
@ -191,9 +219,28 @@ class TorusCable(object):
        self.q_vector = q_vector
        k = k_vector
        self.knot_sum = eval(knot_formula)
-        self.knot_description = self.get_knot_descrption()
+        self.knot_description = self.set_knot_descrption()
        self.__sigma_function = None
+        # TBD property function
        self.signature_as_function_of_theta = None
+        self.signature_as_function_of_theta = self.get_signature_as_function_of_theta()
+        # self.signature_as_function_of_theta = None
+
+    def update(self, other):
+        # TBD knot_formula etc.
+        number_of_summands = len(self.knot_sum)
+        self.knot_description += " # " + other.knot_description
+        self.knot_formula = self.knot_formula[:-1] + ",\n" + \
+                            other.knot_formula[1:]
+        print(self.knot_sum)
+        self.knot_sum += other.knot_sum
+        # self.signature_as_function_of_theta = \
+        #             self.get_signature_as_function_of_theta() + \
+        #             other.get_signature_as_function_of_theta()
+        print(self.knot_description)
+        print(self.knot_formula)
+        print(self.knot_sum)
+

    def __get_sigma_function(self):
        k_1, k_2, k_3, k_4 = [abs(k) for k in self.k_vector]
@ -273,12 +320,18 @@ class TorusCable(object):
                print("one vector " + str(thetas))
                print("max sf " + str(sf.is_big()))
                print()
-                assert untwisted_part.is_zero_everywhere()
+                # assert untwisted_part.is_zero_everywhere()

            if verbose:
                print()
                print(str(thetas))
                print(sf)
+            msg = "tota signature jump = " + str(sf.total_sign_jump())
+            msg += "\nfunction\n" + str(sf)
+            assert sf.total_sign_jump() == 0, msg
+
+
+
            return sf
        signature_as_function_of_theta.__doc__ =\
                                        signature_as_function_of_theta_docstring
@ -354,7 +407,7 @@ class TorusCable(object):
        return SignatureFunction(values=w)


-    def get_knot_descrption(self):
+    def set_knot_descrption(self):
        description = ""
        for knot in self.knot_sum:
            if knot[0] < 0:
@ -728,12 +781,12 @@ TorusCable.get_number_of_combinations_of_theta.__doc__ = \
        and q_j is the last q parameter for the component (a single cable)
    """

-TorusCable.get_knot_descrption.__doc__ = \
+TorusCable.set_knot_descrption.__doc__ = \
    """
    Arguments:
        arbitrary number of lists of numbers, each list encodes a single cable.
    Examples:
-        sage: get_knot_descrption([1, 3], [2], [-1, -2], [-3])
+        sage: set_knot_descrption([1, 3], [2], [-1, -2], [-3])
        'T(2, 3; 2, 7) # T(2, 5) # -T(2, 3; 2, 5) # -T(2, 7)'
    """

--- a/my_signature.sage
+++ b/my_signature.sage
@ -20,8 +20,16 @@ class Config(object):

        # knot_formula is a schema for knots which signature function
        # will be calculated
-        self.knot_formula = "[[k[0], k[1], k[3]], [-k[1], -k[3]], \
-                             [k[2], k[3]], [-k[0], -k[2], -k[3]]]"
+        self.knot_formula = "[[k[0], k[1], k[3]], " + \
+                             "[-k[1], -k[3]], " + \
+                             "[k[2], k[3]], " + \
+                             "[-k[0], -k[2], -k[3]]]"
+
+
+        # self.knot_formula = "[[k[0], k[1], k[4]], [-k[1], -k[3]], \
+        #                      [k[2], k[3]], [-k[0], -k[2], -k[4]]]"
+        #
+        #

        # self.knot_formula = "[[k[3]], [-k[3]], \
        #                      [k[3]], [-k[3]] ]"
@ -42,10 +50,10 @@ class Config(object):
        self.start_shift =  0

        self.verbose = True
-        self.verbose = False
+        # self.verbose = False

        self.print_results = True
-        self.print_results = False
+        # self.print_results = False

        self.print_calculations_for_large_sigma = True
        self.print_calculations_for_large_sigma = False
@ -102,7 +110,7 @@ def set_parameters(knot_formula, limit, verbose, print_results):
    if knot_formula is None:
        knot_formula = config.knot_formula
    if verbose is None:
-        vebose = config.verbose
+        verbose = config.verbose
    if print_results is None:
        print_results = config.print_results
    return knot_formula, limit, verbose, print_results
@ -127,9 +135,8 @@ def search_for_large_sigma_value(knot_formula=None, limit=None,
    for c in combinations:
        q = [P.unrank(i + config.start_shift) for i in c]
        if config.only_slice_candidates:
-            if not (q[3] > 4 * q[2] and
-                    q[2] > 4 * q[1] and
-                    q[1] > 4 * q[0]):
+            ratio = q[3] > 4 * q[2] and q[2] > 4 * q[1] and q[1] > 4 * q[0]
+            if not ratio:
                if verbose:
                    print("Ratio-condition does not hold")
                continue
@ -143,9 +150,6 @@ def search_for_large_sigma_value(knot_formula=None, limit=None,



-
-
-
 # searching for signature == 0
 def search_for_null_signature_value(knot_formula=None, limit=None,
                                     verbose=None, print_results=None):
@ -154,6 +158,8 @@ def search_for_null_signature_value(knot_formula=None, limit=None,
        set_parameters(knot_formula, limit, verbose, print_results)

    k_vector_size = extract_max(knot_formula) + 1
+    limit = max(limit, k_vector_size)
+
    combinations = it.combinations_with_replacement(range(1, limit + 1),
                                                    k_vector_size)
    with open(config.f_results, 'w') as f_results:
@ -202,11 +208,9 @@ def search_for_large_signature_value(knot_formula=None, limit=None,
    # iterate over q-vector
    for c in combinations:
        q = [P.unrank(i + config.start_shift) for i in c]
-        q[3] = 79
        if config.only_slice_candidates:
-            if not (q[3] > 4 * q[2] and
-                    q[2] > 4 * q[1] and
-                    q[1] > 4 * q[0]):
+            ratio = q[3] > 4 * q[2] and q[2] > 4 * q[1] and q[1] > 4 * q[0]
+            if not ratio:
                if verbose:
                    print("Ratio-condition does not hold")
                continue