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627 lines
23 KiB
Python
627 lines
23 KiB
Python
#
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# Copyright 2023
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# - Skia <skia@hya.sk>
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#
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# Ce fichier fait partie du site de l'Association des Étudiants de l'UTBM,
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# http://ae.utbm.fr.
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#
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# This program is free software; you can redistribute it and/or modify it under
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# the terms of the GNU General Public License a published by the Free Software
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# Foundation; either version 3 of the License, or (at your option) any later
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# version.
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#
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# This program is distributed in the hope that it will be useful, but WITHOUT
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# ANY WARRANTY; without even the implied warranty of MERCHANTABILITY or FITNESS
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# FOR A PARTICULAR PURPOSE. See the GNU General Public License for more
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# details.
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#
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# You should have received a copy of the GNU General Public License along with
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# this program; if not, write to the Free Sofware Foundation, Inc., 59 Temple
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# Place - Suite 330, Boston, MA 02111-1307, USA.
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#
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#
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from __future__ import annotations
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import logging
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import math
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import time
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from typing import NamedTuple, TypedDict
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from django.db import models
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from django.db.models import Case, Count, F, Q, Value, When
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from django.db.models.functions import Concat
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from django.utils import timezone
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from django.utils.translation import gettext_lazy as _
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from club.models import Club
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from core.models import User
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from sas.models import Picture
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class GalaxyStar(models.Model):
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"""Define a star (vertex -> user) in the galaxy graph.
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Store a reference to its owner citizen.
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Stars are linked to each others through the :class:`GalaxyLane` model.
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Each GalaxyStar has a mass which push it towards the center of the galaxy.
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This mass is proportional to the number of pictures the owner of the star
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is tagged on.
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"""
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owner = models.ForeignKey(
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User,
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verbose_name=_("star owner"),
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related_name="stars",
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on_delete=models.CASCADE,
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)
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mass = models.PositiveIntegerField(
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_("star mass"),
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default=0,
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)
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galaxy = models.ForeignKey(
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"Galaxy",
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verbose_name=_("the galaxy this star belongs to"),
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related_name="stars",
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on_delete=models.CASCADE,
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null=True,
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)
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def __str__(self):
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return str(self.owner)
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@property
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def current_star(self) -> GalaxyStar | None:
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"""The star of this user in the :class:`Galaxy`.
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Only take into account the most recent active galaxy.
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Returns:
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The star of this user if there is an active Galaxy
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and this user is a citizen of it, else `None`
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"""
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return self.stars.filter(galaxy=Galaxy.get_current_galaxy()).last()
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# Adding a shortcut to User class for getting its star belonging to the latest ruled Galaxy
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User.current_star = current_star
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class GalaxyLane(models.Model):
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"""Define a lane (edge -> link between galaxy citizen) in the galaxy map.
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Store a reference to both its ends and the distance it covers.
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Score details between citizen owning the stars is also stored here.
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"""
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star1 = models.ForeignKey(
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GalaxyStar,
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verbose_name=_("galaxy star 1"),
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related_name="lanes1",
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on_delete=models.CASCADE,
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)
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star2 = models.ForeignKey(
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GalaxyStar,
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verbose_name=_("galaxy star 2"),
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related_name="lanes2",
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on_delete=models.CASCADE,
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)
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distance = models.PositiveIntegerField(
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_("distance"),
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default=0,
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help_text=_("Distance separating star1 and star2"),
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)
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family = models.PositiveIntegerField(
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_("family score"),
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default=0,
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)
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pictures = models.PositiveIntegerField(
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_("pictures score"),
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default=0,
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)
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clubs = models.PositiveIntegerField(
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_("clubs score"),
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default=0,
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)
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def __str__(self):
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return f"{self.star1} -> {self.star2} ({self.distance})"
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class StarDict(TypedDict):
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id: int
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name: str
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mass: int
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class GalaxyDict(TypedDict):
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nodes: list[StarDict]
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links: list
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class RelationScore(NamedTuple):
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family: int
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pictures: int
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clubs: int
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class Galaxy(models.Model):
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"""The Galaxy, a graph linking the active users between each others.
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The distance between two users is given by a relation score which takes
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into account a few parameter like the number of pictures they are both tagged on,
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the time during which they were in the same clubs and whether they are
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in the same family.
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The citizens of the Galaxy are represented by :class:`GalaxyStar`
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and their relations by :class:`GalaxyLane`.
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Several galaxies can coexist. In this case, only the most recent active one
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shall usually be taken into account.
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This is useful to keep the current galaxy while generating a new one
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and swapping them only at the very end.
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Please take into account that generating the galaxy is a very expensive
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operation. For this reason, try not to call the :meth:`rule` method more
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than once a day in production.
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To quickly access to the state of a galaxy, use the :attr:`state` attribute.
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"""
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logger = logging.getLogger("main")
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GALAXY_SCALE_FACTOR = 2_000
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FAMILY_LINK_POINTS = 366 # Equivalent to a leap year together in a club, because.
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PICTURE_POINTS = 2 # Equivalent to two days as random members of a club.
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CLUBS_POINTS = 1 # One day together as random members in a club is one point.
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state = models.JSONField(_("The galaxy current state"), null=True)
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class Meta:
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ordering = ["pk"]
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def __str__(self):
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stars_count = self.stars.count()
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s = f"GLX-ID{self.pk}-SC{stars_count}-"
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if self.state is None:
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s += "CHS" # CHAOS
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else:
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s += "RLD" # RULED
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return s
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@classmethod
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def get_current_galaxy(
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cls,
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) -> Galaxy: # __future__.annotations is required for this
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return Galaxy.objects.filter(state__isnull=False).last()
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###################
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# User self score #
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###################
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@classmethod
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def compute_user_score(cls, user: User) -> int:
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"""Compute an individual score for each citizen.
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It will later be used by the graph algorithm to push
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higher scores towards the center of the galaxy.
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Idea: This could be added to the computation:
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- Forum posts
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- Picture count
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- Counter consumption
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- Barman time
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- ...
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"""
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user_score = 1
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user_score += cls.query_user_score(user)
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# TODO:
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# Scale that value with some magic number to accommodate to typical data
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# Really active galaxy citizen after 5 years typically have a score of about XXX
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# Citizen that were seen regularly without taking much part in organizations typically have a score of about XXX
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# Citizen that only went to a few events typically score about XXX
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user_score = int(math.log2(user_score))
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return user_score
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@classmethod
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def query_user_score(cls, user: User) -> int:
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"""Get the individual score of the given user in the galaxy."""
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score_query = (
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User.objects.filter(id=user.id)
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.annotate(
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godchildren_count=Count("godchildren", distinct=True)
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* cls.FAMILY_LINK_POINTS,
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godfathers_count=Count("godfathers", distinct=True)
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* cls.FAMILY_LINK_POINTS,
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pictures_score=Count("pictures", distinct=True) * cls.PICTURE_POINTS,
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clubs_score=Count("memberships", distinct=True) * cls.CLUBS_POINTS,
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)
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.aggregate(
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score=models.Sum(
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F("godchildren_count")
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+ F("godfathers_count")
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+ F("pictures_score")
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+ F("clubs_score")
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)
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)
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)
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return score_query.get("score")
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####################
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# Inter-user score #
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####################
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@classmethod
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def compute_users_score(cls, user1: User, user2: User) -> RelationScore:
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"""Compute the relationship scores of the two given users.
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The computation is done with the following fields :
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- family: if they have some godfather/godchild relation
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- pictures: in how many pictures are both tagged
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- clubs: during how many days they were members of the same clubs
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"""
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family = cls.compute_users_family_score(user1, user2)
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pictures = cls.compute_users_pictures_score(user1, user2)
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clubs = cls.compute_users_clubs_score(user1, user2)
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return RelationScore(family=family, pictures=pictures, clubs=clubs)
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@classmethod
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def compute_users_family_score(cls, user1: User, user2: User) -> int:
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"""Compute the family score of the relation between the given users.
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This takes into account mutual godfathers.
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Returns:
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366 if user1 is the godfather of user2 (or vice versa) else 0
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"""
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link_count = User.objects.filter(
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Q(id=user1.id, godfathers=user2) | Q(id=user2.id, godfathers=user1)
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).count()
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if link_count > 0:
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cls.logger.debug(
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f"\t\t- '{user1}' and '{user2}' have {link_count} direct family link"
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)
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return link_count * cls.FAMILY_LINK_POINTS
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@classmethod
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def compute_users_pictures_score(cls, user1: User, user2: User) -> int:
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"""Compute the pictures score of the relation between the given users.
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The pictures score is obtained by counting the number
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of :class:`Picture` in which they have been both identified.
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This score is then multiplied by 2.
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Returns:
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The number of pictures both users have in common, times 2
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"""
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picture_count = (
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Picture.objects.filter(people__user__in=(user1,))
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.filter(people__user__in=(user2,))
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.count()
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)
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if picture_count:
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cls.logger.debug(
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f"\t\t- '{user1}' was pictured with '{user2}' {picture_count} times"
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)
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return picture_count * cls.PICTURE_POINTS
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@classmethod
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def compute_users_clubs_score(cls, user1: User, user2: User) -> int:
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"""Compute the clubs score of the relation between the given users.
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The club score is obtained by counting the number of days
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during which the memberships (see :class:`club.models.Membership`)
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of both users overlapped.
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For example, if user1 was a member of Unitec from 01/01/2020 to 31/12/2021
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(two years) and user2 was a member of the same club from 01/01/2021 to
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31/12/2022 (also two years, but with an offset of one year), then their
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club score is 365.
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Returns:
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the number of days during which both users were in the same club
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"""
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common_clubs = Club.objects.filter(members__in=user1.memberships.all()).filter(
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members__in=user2.memberships.all()
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)
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user1_memberships = user1.memberships.filter(club__in=common_clubs)
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user2_memberships = user2.memberships.filter(club__in=common_clubs)
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score = 0
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for user1_membership in user1_memberships:
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if user1_membership.end_date is None:
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# user1_membership.save() is not called in this function, hence this is safe
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user1_membership.end_date = timezone.now().date()
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query = Q( # start2 <= start1 <= end2
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start_date__lte=user1_membership.start_date,
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end_date__gte=user1_membership.start_date,
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)
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query |= Q( # start2 <= start1 <= now
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start_date__lte=user1_membership.start_date, end_date=None
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)
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query |= Q( # start1 <= start2 <= end2
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start_date__gte=user1_membership.start_date,
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start_date__lte=user1_membership.end_date,
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)
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for user2_membership in user2_memberships.filter(
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query, club=user1_membership.club
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):
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if user2_membership.end_date is None:
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user2_membership.end_date = timezone.now().date()
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latest_start = max(
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user1_membership.start_date, user2_membership.start_date
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)
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earliest_end = min(user1_membership.end_date, user2_membership.end_date)
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cls.logger.debug(
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"\t\t- '%s' was with '%s' in %s starting on %s until %s (%s days)"
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% (
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user1,
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user2,
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user2_membership.club,
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latest_start,
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earliest_end,
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(earliest_end - latest_start).days,
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)
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)
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score += cls.CLUBS_POINTS * (earliest_end - latest_start).days
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return score
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###################
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# Rule the galaxy #
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###################
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@classmethod
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def scale_distance(cls, value: int | float) -> int:
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"""Given a numeric value, return a scaled value which can
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be used in the Galaxy's graphical interface to set the distance
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between two stars.
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Returns:
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the scaled value usable in the Galaxy's 3d graph
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"""
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# TODO: this will need adjustements with the real, typical data on Taiste
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if value == 0:
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return 4000 # Following calculus would give us +∞, we cap it to 4000
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cls.logger.debug(f"\t\t> Score: {value}")
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# Invert score to draw close users together
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value = 1 / value # Cannot be 0
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value += 2 # We use log2 just below and need to stay above 1
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value = ( # Let's get something in the range ]0; log2(3)-1≈0.58[ that we can multiply later
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math.log2(value) - 1
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)
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value *= ( # Scale that value with a magic number to accommodate to typical data
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# Really close galaxy citizen after 5 years typically have a score of about XXX
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# Citizen that were in the same year without being really friends typically have a score of about XXX
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# Citizen that have met once or twice only have a couple of pictures together typically score about XXX
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cls.GALAXY_SCALE_FACTOR
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)
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cls.logger.debug(f"\t\t> Scaled distance: {value}")
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return int(value)
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def rule(self, picture_count_threshold=10) -> None:
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"""Main function of the Galaxy.
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Iterate over all the rulable users to promote them to citizens.
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A citizen is a user who has a corresponding star in the Galaxy.
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Also build up the lanes, which are the links between the different citizen.
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Users who can be ruled are defined with the `picture_count_threshold`:
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all users who are identified in a strictly lower number of pictures
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won't be promoted to citizens.
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This does very effectively limit the quantity of computing to do
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and only includes users who have had a minimum of activity.
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This method still remains very expensive, so think thoroughly before
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you call it, especially in production.
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:param picture_count_threshold: the minimum number of picture to have to be
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included in the galaxy
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"""
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total_time = time.time()
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self.logger.info("Listing rulable citizen.")
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rulable_users = (
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User.objects.filter(subscriptions__isnull=False)
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.annotate(pictures_count=Count("pictures"))
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.filter(pictures_count__gt=picture_count_threshold)
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.distinct()
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)
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# force fetch of the whole query to make sure there won't
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# be any more db hits
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# this is memory expensive but prevents a lot of db hits, therefore
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# is far more time efficient
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rulable_users = list(rulable_users)
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rulable_users_count = len(rulable_users)
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user1_count = 0
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self.logger.info(
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f"{rulable_users_count} citizen have been listed. Starting to rule."
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)
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stars = []
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self.logger.info("Creating stars for all citizen")
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for user in rulable_users:
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star = GalaxyStar(
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owner=user, galaxy=self, mass=self.compute_user_score(user)
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)
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stars.append(star)
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GalaxyStar.objects.bulk_create(stars)
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stars = {}
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for star in GalaxyStar.objects.filter(galaxy=self):
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stars[star.owner.id] = star
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self.logger.info("Creating lanes between stars")
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# Display current speed every $speed_count_frequency users
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speed_count_frequency = max(rulable_users_count // 10, 1) # ten time at most
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global_avg_speed_accumulator = 0
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global_avg_speed_count = 0
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t_global_start = time.time()
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while len(rulable_users) > 0:
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user1 = rulable_users.pop()
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user1_count += 1
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rulable_users_count2 = len(rulable_users)
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star1 = stars[user1.id]
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user_avg_speed = 0
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user_avg_speed_count = 0
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tstart = time.time()
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lanes = []
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for user2_count, user2 in enumerate(rulable_users, start=1):
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self.logger.debug("")
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self.logger.debug(
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f"\t> Examining '{user1}' ({user1_count}/{rulable_users_count}) with '{user2}' ({user2_count}/{rulable_users_count2})"
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)
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star2 = stars[user2.id]
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score = Galaxy.compute_users_score(user1, user2)
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distance = self.scale_distance(sum(score))
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if distance < 30: # TODO: this needs tuning with real-world data
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lanes.append(
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GalaxyLane(
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star1=star1,
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star2=star2,
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distance=distance,
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family=score.family,
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pictures=score.pictures,
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clubs=score.clubs,
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)
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)
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if user2_count % speed_count_frequency == 0:
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tend = time.time()
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delta = tend - tstart
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speed = float(speed_count_frequency) / delta
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user_avg_speed += speed
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user_avg_speed_count += 1
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self.logger.debug(
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f"\tSpeed: {speed:.2f} users per second (time for last {speed_count_frequency} citizens: {delta:.2f} second)"
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)
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tstart = time.time()
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GalaxyLane.objects.bulk_create(lanes)
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self.logger.info("")
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t_global_end = time.time()
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global_delta = t_global_end - t_global_start
|
|
speed = 1.0 / global_delta
|
|
global_avg_speed_accumulator += speed
|
|
global_avg_speed_count += 1
|
|
global_avg_speed = global_avg_speed_accumulator / global_avg_speed_count
|
|
|
|
self.logger.info(f" Ruling of {self} ".center(60, "#"))
|
|
self.logger.info(
|
|
f"Progression: {user1_count}/{rulable_users_count} citizen -- {rulable_users_count - user1_count} remaining"
|
|
)
|
|
self.logger.info(f"Speed: {60.0*global_avg_speed:.2f} citizen per minute")
|
|
|
|
# We can divide the computed ETA by 2 because each loop, there is one citizen less to check, and maths tell
|
|
# us that this averages to a division by two
|
|
eta = rulable_users_count2 / global_avg_speed / 2
|
|
eta_hours = int(eta // 3600)
|
|
eta_minutes = int(eta // 60 % 60)
|
|
self.logger.info(
|
|
f"ETA: {eta_hours} hours {eta_minutes} minutes ({eta / 3600 / 24:.2f} days)"
|
|
)
|
|
self.logger.info("#" * 60)
|
|
t_global_start = time.time()
|
|
|
|
# Here, we get the IDs of the old galaxies that we'll need to delete. In normal operation, only one galaxy
|
|
# should be returned, and we can't delete it yet, as it's the one still displayed by the Sith.
|
|
old_galaxies_pks = list(
|
|
Galaxy.objects.filter(state__isnull=False).values_list("pk", flat=True)
|
|
)
|
|
self.logger.info(
|
|
f"These old galaxies will be deleted once the new one is ready: {old_galaxies_pks}"
|
|
)
|
|
|
|
# Making the state sets this new galaxy as being ready. From now on, the Sith will show us to the world.
|
|
self.make_state()
|
|
|
|
# Avoid accident if there is nothing to delete
|
|
if len(old_galaxies_pks) > 0:
|
|
# Former galaxies can now be deleted.
|
|
Galaxy.objects.filter(pk__in=old_galaxies_pks).delete()
|
|
|
|
total_time = time.time() - total_time
|
|
total_time_hours = int(total_time // 3600)
|
|
total_time_minutes = int(total_time // 60 % 60)
|
|
total_time_seconds = int(total_time % 60)
|
|
self.logger.info(
|
|
f"{self} ruled in {total_time:.2f} seconds ({total_time_hours} hours, {total_time_minutes} minutes, {total_time_seconds} seconds)"
|
|
)
|
|
|
|
def make_state(self) -> None:
|
|
"""Compute JSON structure to send to 3d-force-graph: https://github.com/vasturiano/3d-force-graph/."""
|
|
self.logger.info(
|
|
"Caching current Galaxy state for a quicker display of the Empire's power."
|
|
)
|
|
|
|
without_nickname = Concat(
|
|
F("owner__first_name"), Value(" "), F("owner__last_name")
|
|
)
|
|
with_nickname = Concat(
|
|
F("owner__first_name"),
|
|
Value(" "),
|
|
F("owner__last_name"),
|
|
Value(" ("),
|
|
F("owner__nick_name"),
|
|
Value(")"),
|
|
)
|
|
stars = (
|
|
GalaxyStar.objects.filter(galaxy=self)
|
|
.order_by(
|
|
"owner"
|
|
) # This helps determinism for the tests and doesn't cost much
|
|
.annotate(
|
|
owner_name=Case(
|
|
When(owner__nick_name=None, then=without_nickname),
|
|
default=with_nickname,
|
|
)
|
|
)
|
|
)
|
|
lanes = (
|
|
GalaxyLane.objects.filter(star1__galaxy=self)
|
|
.order_by(
|
|
"star1"
|
|
) # This helps determinism for the tests and doesn't cost much
|
|
.annotate(
|
|
star1_owner=F("star1__owner__id"),
|
|
star2_owner=F("star2__owner__id"),
|
|
)
|
|
)
|
|
json = GalaxyDict(
|
|
nodes=[
|
|
StarDict(
|
|
id=star.owner_id,
|
|
name=star.owner_name,
|
|
mass=star.mass,
|
|
)
|
|
for star in stars
|
|
],
|
|
links=[],
|
|
)
|
|
for path in lanes:
|
|
json["links"].append(
|
|
{
|
|
"source": path.star1_owner,
|
|
"target": path.star2_owner,
|
|
"value": path.distance,
|
|
}
|
|
)
|
|
self.state = json
|
|
self.save()
|
|
self.logger.info(f"{self} is now ready!")
|