version for first calculations

my_signature.sage

@@ -12,8 +12,8 @@ class MySettings(object):
     def __init__(self):
         self.f_results = os.path.join(os.getcwd(), "results.out")
 
+
 def main(arg):
-    my_settings = MySettings()
     try:
         tests(int(arg[1]))
     except:
@@ -21,21 +21,23 @@ def main(arg):
 
 
 def tests(limit=10):
+    settings = MySettings()
+    knot_sum_formula = "[[k[0], k[1], k[2]], [k[3], k[4]], \
+                        [-k[0], -k[3], -k[4]], [-k[1], -k[2]]]"
 
-    for comb in it.combinations_with_replacement(range(1, limit + 1), 5):
-        k_0, k_1, k_2, k_3, k_4 = comb
+    with open(settings.f_results, 'w') as f_results:
+        for k in it.combinations_with_replacement(range(1, limit + 1), 5):
+            knot_sum = eval(knot_sum_formula)
+            result = eval_cable_for_thetas(knot_sum)
+            if result is not None:
+                knot_description, null_comb, all_comb = result
+                line = (str(k) + ", " + str(null_comb) + ", " +
+                        str(all_comb) + "\n")
+                f_results.write(line)
 
-        knot_sum = [[k_0, k_1, k_2], [k_3, k_4], [-k_0, -k_3, -k_4], [-k_1, -k_2]]
-
-        result = eval_cable_for_thetas(knot_sum)
-        if result is not None:
-            knot_description, null_comb, all_comb = result
-            print 3 * "\nHURA"
-            print knot_description
-            print null_comb, all_comb
-    # for comb in it.combinations_with_replacement(range(1, limit + 1), 4):
-    #     print comb
-    #     print first_sum(*comb)
+        # for comb in it.combinations_with_replacement(range(1, limit + 1), 4):
+        #     print comb
+        #     print first_sum(*comb)
 
 
 class SignatureFunction(object):
@@ -146,22 +148,6 @@ def get_blanchfield_for_pattern(k_n, theta):
         results.append((1 - e * ksi, 1 * sgn(k_n)))
     return SignatureFunction(results)
 
-#
-# 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
-
 
 # Bl_theta(K'_(2, d) =
 # Bl_theta(T_2, d) + Bl(K')(ksi_l^(-theta) * t)
@@ -265,7 +251,6 @@ def eval_cable_for_thetas(knot_sum):
             #     print v_theta
             #     print
     if null_combinations^2 >= all_combinations:
-        print "\n\nHURA!!"
         print
         print knot_description
         print "Zero cases: " + str(null_combinations)
@@ -275,6 +260,7 @@ def eval_cable_for_thetas(knot_sum):
         return knot_description, null_combinations, all_combinations
     return None
 
+
 def get_knot_descrption(*arg):
     description = ""
     for knot in arg:
@@ -282,16 +268,34 @@ def get_knot_descrption(*arg):
             description += "-"
         description += "T("
         for k in knot:
-            description += "2, " + str(abs(k)) + "; "
+            description += "2, " + str(2 * abs(k) + 1) + "; "
         description = description[:-2]
         description += ") # "
     return description[:-3]
 
+
 def get_number_of_combinations(*arg):
     number_of_combinations = 1
     for knot in arg:
         number_of_combinations *= (2 * abs(knot[-1]) + 1)
     return number_of_combinations
 
+
 if __name__ == '__main__' and '__file__' in globals():
     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