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-rw-r--r--src/python/spiral/__init__.py7
-rw-r--r--src/python/spiral/__pycache__/constants.cpython-36.pycbin0 -> 200 bytes
-rw-r--r--src/python/spiral/__pycache__/galaxytools.cpython-36.pycbin0 -> 5448 bytes
-rw-r--r--src/python/spiral/__pycache__/gen.cpython-36.pycbin0 -> 447 bytes
-rw-r--r--src/python/spiral/__pycache__/test.cpython-36.pycbin0 -> 974 bytes
-rwxr-xr-xsrc/python/spiral/exec.py37
-rw-r--r--src/python/spiral/figs/out.pngbin0 -> 16630 bytes
-rw-r--r--src/python/spiral/galaxytools.py286
-rw-r--r--src/python/spiral/gen.py23
9 files changed, 353 insertions, 0 deletions
diff --git a/src/python/spiral/__init__.py b/src/python/spiral/__init__.py
new file mode 100644
index 0000000..8481bb0
--- /dev/null
+++ b/src/python/spiral/__init__.py
@@ -0,0 +1,7 @@
+import gen
+
+n = 10
+list_a = []
+
+gen.gen_stars(n, list_a)
+print(list_a)
diff --git a/src/python/spiral/__pycache__/constants.cpython-36.pyc b/src/python/spiral/__pycache__/constants.cpython-36.pyc
new file mode 100644
index 0000000..2072913
--- /dev/null
+++ b/src/python/spiral/__pycache__/constants.cpython-36.pyc
Binary files differdiff --git a/src/python/spiral/__pycache__/galaxytools.cpython-36.pyc b/src/python/spiral/__pycache__/galaxytools.cpython-36.pyc
new file mode 100644
index 0000000..3977679
--- /dev/null
+++ b/src/python/spiral/__pycache__/galaxytools.cpython-36.pyc
Binary files differdiff --git a/src/python/spiral/__pycache__/gen.cpython-36.pyc b/src/python/spiral/__pycache__/gen.cpython-36.pyc
new file mode 100644
index 0000000..ff3c6bc
--- /dev/null
+++ b/src/python/spiral/__pycache__/gen.cpython-36.pyc
Binary files differdiff --git a/src/python/spiral/__pycache__/test.cpython-36.pyc b/src/python/spiral/__pycache__/test.cpython-36.pyc
new file mode 100644
index 0000000..953fa3e
--- /dev/null
+++ b/src/python/spiral/__pycache__/test.cpython-36.pyc
Binary files differdiff --git a/src/python/spiral/exec.py b/src/python/spiral/exec.py
new file mode 100755
index 0000000..37bc821
--- /dev/null
+++ b/src/python/spiral/exec.py
@@ -0,0 +1,37 @@
+#!/usr/bin/env python3
+
+import galaxytools as galaxytools
+import time as time
+# import matplotlib.pyplot as plt
+
+# start the timer
+start = time.time()
+
+# generate a new galaxy
+galaxy = galaxytools.new_galaxy(64)
+
+# generate 100 stars
+galaxy.gen_new_stars(1000)
+
+# galaxy.print_stars()
+
+# calculate the forces acting inbetween the stars
+galaxy.calc_all_forces()
+
+# print out the individual forces acting on each star
+# galaxy.print_individual_forces()
+
+galaxy.gen_sphere_positions(0.0001)
+# galaxy.gen_forces_after_t(1)
+
+galaxy.is_star_in_sphere_all()
+
+# save the stop time
+end = time.time()
+
+# calculate the elapsed time
+whole_time = end - start
+
+# print the time and append it to a list
+print("Time:")
+print(whole_time)
diff --git a/src/python/spiral/figs/out.png b/src/python/spiral/figs/out.png
new file mode 100644
index 0000000..3530aa6
--- /dev/null
+++ b/src/python/spiral/figs/out.png
Binary files differdiff --git a/src/python/spiral/galaxytools.py b/src/python/spiral/galaxytools.py
new file mode 100644
index 0000000..1a9336c
--- /dev/null
+++ b/src/python/spiral/galaxytools.py
@@ -0,0 +1,286 @@
+# Import libraries
+import math as math  # general math
+import numpy as np  # advanced math
+
+# import matplotlib.pyplot as plt  # plotting things
+
+
+# class used to create galaxies
+class new_galaxy(object):
+
+    # Initialisation
+    def __init__(self, galaxy_range):
+        print(
+            """>>> Initialising the list storing coordinates, forces and other
+            values"""
+        )
+
+        # list used for storing the coordinates os the stars
+        self.list_coords = []
+
+        # list storing the overall force acting on one star
+        self.list_force_star = []
+
+        # list storing the coordinates of the midpoints of the spheres dividing
+        # the galaxy into equaly big sized cells
+        self.list_sphere_coords = []
+
+        # self.list_sphere_stars = np.array(3, )
+
+        print("\tDone\n")
+        print(">>> Initialising variables and constants")
+
+        # variable storing the number of stars generated
+        self.num_of_stars = 0
+
+        self.galaxy_range = int(galaxy_range)
+
+        # define the universal gravitational constant
+        self.G = 6.67408 * 10e11
+
+        print("\tDone\n")
+
+    # generate n new stars and store the coordinates in list_coords
+    # n = number of stars to be generated
+    # galaxy_range = size of the galaxy
+    def gen_new_stars(self, n):
+        print(">>> Generating Stars...")
+
+        # for a given number of stars
+        for i in range(0, n):
+
+            # generate a temporary random coordinate inside a given range using
+            # numpy
+            self.temp_coord = np.random.uniform(
+                low=0, high=self.galaxy_range, size=(4, ))
+
+            # append the random coordinate to the list storing the coordinates
+            self.list_coords.append(self.temp_coord)
+
+        # increment the generated star counter
+        self.num_of_stars += n
+        print("\tDone")
+        print("\tGenerated " + str(n) + " Stars\n")
+
+    # print out all the coordinates in list_coords
+    def print_stars(self):
+        print(">>> Listing the coordinates of all stars:")
+        # print the coordinates of every star
+        for value in self.list_coords:
+            print(value)
+
+        print("\tDone\n")
+
+    # calculate the forces acting between two stars on a specified axis
+    # star1 = coordinates of the first star
+    # star2 = coordinates of the second star
+    # axes = "x", "y" or "z" (CASE SENSITIVE!)
+    def calc_forces(self, star1, star2, axes):
+        if axes == "x":
+            mass = star1[3] * star2[3]
+            distance = math.sqrt(math.pow(star1[0] - star2[0], 2))
+        elif axes == "y":
+            mass = star1[3] * star2[3]
+            distance = math.sqrt(math.pow(star1[1] - star2[1], 2))
+        elif axes == "z":
+            mass = star1[3] * star2[3]
+            distance = math.sqrt(math.pow(star1[2] - star2[2], 2))
+
+        # stop division by zero
+        if distance == 0:
+            pass
+        else:
+            # return the acting force
+            return self.G * mass / math.pow(distance, 2)
+
+    # calculate all the forces acting in the current galaxy
+    def calc_all_forces(self):
+        print(">>> Calculating all the forces acting inbetween the stars:")
+
+        if (self.num_of_stars <= 5):
+            # print some information above the columns
+            print(">>> Printing the forces acting inbetween every star")
+            print("{:-<60}".format(""))
+            print("\t| {:<3}| {:<3}| ".format("a", "b"))
+            print("\t+{:-<4}+{:-<4}+{:-<60} ".format("", "", ""))
+
+        else:
+            print("\t[W] Too many stars to print out!")
+            print("{:-<60}".format(""))
+
+        # for every star
+        for i in range(0, self.num_of_stars):
+
+            # initialize
+            self.force = 0
+
+            # every other star:
+            for j in range(0, self.num_of_stars):
+
+                # don't calculate the force between a star and and itself
+                if i != j and i < j:
+                    self.arr_force = np.array((0, 0, 0))
+
+                    # calculate the force between the two stars
+                    force_x = self.calc_forces(self.list_coords[i],
+                                               self.list_coords[j], "x")
+                    force_y = self.calc_forces(self.list_coords[i],
+                                               self.list_coords[j], "y")
+                    force_z = self.calc_forces(self.list_coords[i],
+                                               self.list_coords[j], "z")
+
+                    # print("overall force: ", end="")
+                    self.arr_force = np.array((force_x, force_y, force_z))
+
+                    if (self.num_of_stars <= 5):
+                        print("\t| {:<3}| {:<3}| {:<60}".format(
+                            str(i), str(j), str(self.arr_force)))
+                    """
+                    force_x = 42
+                    force_y = 36
+                    force_z = 24
+
+                    (0, 0, 0) --> (42, 36, 24)
+                    """
+
+            # append the variable to the list storing all the forces
+            self.list_force_star.append(self.arr_force)
+
+        print("{:-<60}".format(""))
+        print("\tDone\n")
+
+    # print the individual forces acting on a star
+    def print_individual_forces(self, n=None, print_confirm=False):
+        print(">>> Printing the individual forces acting on every star")
+
+        if self.num_of_stars > 10:
+            print("\t[W] Too many stars to print out!")
+            print("{:-<60}".format(""))
+
+            for i in range(0, 3):
+                print("\t" + str(i) + " " + str(self.list_force_star[i]))
+
+            print("\n\t...\n")
+
+            for i in range(
+                    int(len(self.list_force_star) - 3),
+                    len(self.list_force_star)):
+                print("\t" + str(i) + " " + str(self.list_force_star[i]))
+            print("{:-<60}".format(""))
+
+        else:
+            print("{:-<60}".format(""))
+            if n is None:
+                # for value in self.list_force_star:
+                for i in range(0, len(self.list_force_star)):
+                    print("\t" + str(i) + " " + str(self.list_force_star[i]))
+            else:
+                print(self.list_force_star[n])
+
+            print("{:-<60}".format(""))
+            print("\tDone\n")
+
+    # star      [x, y, z, m]
+    # sphere    [x, y, z, r]
+    def is_star_in_sphere(self, star, sphere):
+
+        # define the sphere values
+        self.sphere_x = sphere[0]
+        self.sphere_y = sphere[1]
+        self.sphere_z = sphere[2]
+        self.sphere_r = sphere[3]
+
+        # define the star coordinates
+        self.star_x = star[0]
+        self.star_y = star[1]
+        self.star_z = star[2]
+
+        self.sphere_x_neg = self.sphere_x - self.sphere_r
+        self.sphere_x_pos = self.sphere_x + self.sphere_r
+
+        self.sphere_y_neg = self.sphere_y - self.sphere_r
+        self.sphere_y_pos = self.sphere_y + self.sphere_r
+
+        self.sphere_z_neg = self.sphere_z - self.sphere_r
+        self.sphere_z_pos = self.sphere_z + self.sphere_r
+
+        # find out if the star is inside the sphere
+        if self.sphere_x_neg < self.star_x < self.sphere_x_pos:
+            if self.sphere_y_neg < self.star_y < self.sphere_y_pos:
+                if self.sphere_z_neg < self.star_z < self.sphere_z_pos:
+                    return True
+                else:
+                    return False
+            else:
+                return False
+        else:
+            return False
+
+    # find out which stars in in which spheres
+    def is_star_in_sphere_all(self):
+
+        # define a counter for indexing the spheres
+        tmp_counter = 0
+
+        # cycle through all the stars
+        for star in self.list_coords:
+
+            # cycle through all the spheres
+            for value in self.list_sphere_coords:
+
+                # parse the needed values from the sphere list
+                sphere = np.array((value[0:4]))
+
+                # if the star is inside the sphere
+                if (self.is_star_in_sphere(star, sphere) is True):
+
+                    # print stuff
+                    print(tmp_counter, end=" ")
+                    print(star, end=" ")
+                    print(sphere)
+
+                    # increment the counter
+                    tmp_counter += 1
+
+                    # break the loop to stop possible multiple assignments
+                    break
+
+    # function generating the positions of the sphere cells
+    def gen_sphere_positions(self, sampling_rate):
+
+        # calculate the distance between the midpoints of the spheres
+        sphere_distance = int(round(self.galaxy_range / sampling_rate, 0))
+
+        # define the sphere_radius
+        tmp_var = math.pow(sphere_distance, 2)
+        sphere_radius = math.sqrt(tmp_var + tmp_var + tmp_var)
+
+        # define a sphere counter for "labeling" the spheres
+        tmp_counter = 0
+
+        # cycle through all potential points
+        for i in range(-self.galaxy_range, self.galaxy_range, sphere_distance):
+            for j in range(-self.galaxy_range, self.galaxy_range,
+                           sphere_distance):
+                for k in range(-self.galaxy_range, self.galaxy_range,
+                               sphere_distance):
+
+                    # generate a temporary array combining all values
+                    temp_arr = np.array((i, j, k, sphere_radius, tmp_counter))
+
+                    # append the array to the list storing the sphere infos
+                    self.list_sphere_coords.append(temp_arr)
+
+                    # increment the sphere counter
+                    tmp_counter += 1
+
+    def calc_forces_sphere():
+        pass
+
+    def calc_forces_sphere_all():
+        pass
+
+    def gen_print_forces_after_t(t):
+        pass
+
+    # def all_stars_in_sphere(self, star, se)
diff --git a/src/python/spiral/gen.py b/src/python/spiral/gen.py
new file mode 100644
index 0000000..f9f6a0a
--- /dev/null
+++ b/src/python/spiral/gen.py
@@ -0,0 +1,23 @@
+# general libraries
+import numpy as np
+
+list_a = []
+
+class spiral:
+    def __init__(self):
+        self.list_a = []
+
+    def print_list_a(self):
+        for value in self.list_a:
+            print(value)
+
+    # def gen_stars(self, n, list_a)
+
+
+# define a function generating n stars
+def gen_stars(n, list_a):
+    for i in range(0, n):
+        list_a.append(np.random.random((3)))
+
+if __name__ == "__main__":
+    gen_stars(n)