# -*- mode: python; coding: utf-8 -*- # Re2o est un logiciel d'administration développé initiallement au rezometz. Il # se veut agnostique au réseau considéré, de manière à être installable en # quelques clics. # # Copyright © 2017 Gabriel Détraz # Copyright © 2017 Goulven Kermarec # Copyright © 2017 Augustin Lemesle # # This program is free software; you can redistribute it and/or modify # it under the terms of the GNU General Public License as published by # the Free Software Foundation; either version 2 of the License, or # (at your option) any later version. # # This program is distributed in the hope that it will be useful, # but WITHOUT ANY WARRANTY; without even the implied warranty of # MERCHANTABILITY or FITNESS FOR A PARTICULAR PURPOSE. See the # GNU General Public License for more details. # # You should have received a copy of the GNU General Public License along # with this program; if not, write to the Free Software Foundation, Inc., # 51 Franklin Street, Fifth Floor, Boston, MA 02110-1301 USA. """ Definition des modèles de l'application topologie. On défini les models suivants : - stack (id, id_min, id_max et nom) regrouppant les switches - switch : nom, nombre de port, et interface machine correspondante (mac, ip, etc) (voir machines.models.interface) - Port: relié à un switch parent par foreign_key, numero du port, relié de façon exclusive à un autre port, une machine (serveur ou borne) ou une prise murale - room : liste des prises murales, nom et commentaire de l'état de la prise """ from __future__ import unicode_literals import itertools from django.db import models from django.db.models.signals import post_save, post_delete from django.utils.functional import cached_property from django.dispatch import receiver from django.core.exceptions import ValidationError from django.db import IntegrityError from django.db import transaction from django.utils.translation import ugettext_lazy as _ from reversion import revisions as reversion from preferences.models import ( OptionalTopologie, RadiusKey, SwitchManagementCred ) from machines.models import Machine, regen from re2o.mixins import AclMixin, RevMixin class Stack(AclMixin, RevMixin, models.Model): """Un objet stack. Regrouppe des switchs en foreign key ,contient une id de stack, un switch id min et max dans le stack""" name = models.CharField(max_length=32, blank=True, null=True) stack_id = models.CharField(max_length=32, unique=True) details = models.CharField(max_length=255, blank=True, null=True) member_id_min = models.PositiveIntegerField() member_id_max = models.PositiveIntegerField() class Meta: permissions = ( ("view_stack", _("Can view a stack object")), ) verbose_name = _("switches stack") verbose_name_plural = _("switches stacks") def __str__(self): return " ".join([self.name, self.stack_id]) def save(self, *args, **kwargs): self.clean() if not self.name: self.name = self.stack_id super(Stack, self).save(*args, **kwargs) def clean(self): """ Verification que l'id_max < id_min""" if self.member_id_max < self.member_id_min: raise ValidationError( {'member_id_max': _("The maximum ID is less than the" " minimum ID.")} ) class AccessPoint(AclMixin, Machine): """Define a wireless AP. Inherit from machines.interfaces Definition pour une borne wifi , hérite de machines.interfaces """ location = models.CharField( max_length=255, help_text=_("Details about the AP's location"), blank=True, null=True ) class Meta: permissions = ( ("view_accesspoint", _("Can view an access point object")), ) verbose_name = _("access point") verbose_name_plural = _("access points") def port(self): """Return the queryset of ports for this device""" return Port.objects.filter( machine_interface__machine=self ) def switch(self): """Return the switch where this is plugged""" return Switch.objects.filter( ports__machine_interface__machine=self ) def building(self): """ Return the building of the AP/Server (building of the switchs connected to...) """ return Building.objects.filter( switchbay__switch=self.switch() ) @cached_property def short_name(self): return str(self.interface_set.first().domain.name) @classmethod def all_ap_in(cls, building_instance): """Get a building as argument, returns all ap of a building""" return cls.objects.filter( interface__port__switch__switchbay__building=building_instance ) def __str__(self): return str(self.interface_set.first()) class Server(Machine): """ Dummy class, to retrieve servers of a building, or get switch of a server """ class Meta: proxy = True def port(self): """Return the queryset of ports for this device""" return Port.objects.filter( machine_interface__machine=self ) def switch(self): """Return the switch where this is plugged""" return Switch.objects.filter( ports__machine_interface__machine=self ) def building(self): """ Return the building of the AP/Server (building of the switchs connected to...) """ return Building.objects.filter( switchbay__switch=self.switch() ) @cached_property def short_name(self): return str(self.interface_set.first().domain.name) @classmethod def all_server_in(cls, building_instance): """Get a building as argument, returns all server of a building""" return cls.objects.filter( interface__port__switch__switchbay__building=building_instance ).exclude(accesspoint__isnull=False) def __str__(self): return str(self.interface_set.first()) class Switch(AclMixin, Machine): """ Definition d'un switch. Contient un nombre de ports (number), un emplacement (location), un stack parent (optionnel, stack) et un id de membre dans le stack (stack_member_id) relié en onetoone à une interface Pourquoi ne pas avoir fait hériter switch de interface ? Principalement par méconnaissance de la puissance de cette façon de faire. Ceci étant entendu, django crée en interne un onetoone, ce qui a un effet identique avec ce que l'on fait ici Validation au save que l'id du stack est bien dans le range id_min id_max de la stack parente""" number = models.PositiveIntegerField( help_text=_("Number of ports") ) stack = models.ForeignKey( 'topologie.Stack', blank=True, null=True, on_delete=models.SET_NULL ) stack_member_id = models.PositiveIntegerField( blank=True, null=True ) model = models.ForeignKey( 'topologie.ModelSwitch', blank=True, null=True, on_delete=models.SET_NULL, help_text=_("Switch model") ) switchbay = models.ForeignKey( 'topologie.SwitchBay', blank=True, null=True, on_delete=models.SET_NULL, ) radius_key = models.ForeignKey( 'preferences.RadiusKey', blank=True, null=True, on_delete=models.PROTECT, help_text="Clef radius du switch" ) management_creds = models.ForeignKey( 'preferences.SwitchManagementCred', blank=True, null=True, on_delete=models.PROTECT, help_text="Identifiant de management de ce switch" ) automatic_provision = models.BooleanField( default=False, help_text='Provision automatique de ce switch', ) class Meta: unique_together = ('stack', 'stack_member_id') permissions = ( ("view_switch", _("Can view a switch object")), ) verbose_name = _("switch") verbose_name_plural = _("switches") def clean(self): """ Verifie que l'id stack est dans le bon range Appelle également le clean de la classe parente""" super(Switch, self).clean() if self.stack is not None: if self.stack_member_id is not None: if (self.stack_member_id > self.stack.member_id_max) or\ (self.stack_member_id < self.stack.member_id_min): raise ValidationError( {'stack_member_id': _("The switch ID exceeds the" " limits allowed by the stack.")} ) else: raise ValidationError( {'stack_member_id': _("The stack member ID can't be" " void.")} ) def create_ports(self, begin, end): """ Crée les ports de begin à end si les valeurs données sont cohérentes. """ s_begin = s_end = 0 nb_ports = self.ports.count() if nb_ports > 0: ports = self.ports.order_by('port').values('port') s_begin = ports.first().get('port') s_end = ports.last().get('port') if end < begin: raise ValidationError(_("The end port is less than the start" " port.")) if end - begin > self.number: raise ValidationError(_("This switch can't have that many ports.")) begin_range = range(begin, s_begin) end_range = range(s_end+1, end+1) for i in itertools.chain(begin_range, end_range): with transaction.atomic(), reversion.create_revision(): _created, _port = Port.objects.get_or_create(switch=self, port=port) reversion.set_comment(_("Creation")) def main_interface(self): """ Returns the 'main' interface of the switch It must the the management interface for that device""" switch_iptype = OptionalTopologie.get_cached_value('switchs_ip_type') if switch_iptype: return self.interface_set.filter(type__ip_type=switch_iptype).first() return self.interface_set.first() @cached_property def get_name(self): return self.name or self.main_interface().domain.name @cached_property def get_radius_key(self): """Retourne l'objet de la clef radius de ce switch""" return self.radius_key or RadiusKey.objects.filter(default_switch=True).first() @cached_property def get_radius_key_value(self): """Retourne la valeur en str de la clef radius, none si il n'y en a pas""" if self.get_radius_key: return self.get_radius_key.radius_key else: return None @cached_property def get_management_cred(self): """Retourne l'objet des creds de managament de ce switch""" return self.management_creds or SwitchManagementCred.objects.filter(default_switch=True).first() @cached_property def get_management_cred_value(self): """Retourne un dict des creds de management du switch""" if self.get_management_cred: return {'id': self.get_management_cred.management_id, 'pass': self.get_management_cred.management_pass} else: return None @cached_property def rest_enabled(self): return OptionalTopologie.get_cached_value('switchs_rest_management') or self.automatic_provision @cached_property def web_management_enabled(self): sw_management = OptionalTopologie.get_cached_value('switchs_web_management') sw_management_ssl = OptionalTopologie.get_cached_value('switchs_web_management_ssl') if sw_management_ssl: return "ssl" elif sw_management: return "plain" else: return self.automatic_provision @cached_property def ipv4(self): """Return the switch's management ipv4""" return str(self.main_interface().ipv4) @cached_property def ipv6(self): """Returne the switch's management ipv6""" return str(self.main_interface().ipv6().first()) @cached_property def interfaces_subnet(self): """Return dict ip:subnet for all ip of the switch""" return dict((str(interface.ipv4), interface.type.ip_type.ip_set_full_info) for interface in self.interface_set.all()) @cached_property def interfaces6_subnet(self): """Return dict ip6:subnet for all ipv6 of the switch""" return dict((str(interface.ipv6().first()), interface.type.ip_type.ip6_set_full_info) for interface in self.interface_set.all()) def __str__(self): return str(self.get_name) class ModelSwitch(AclMixin, RevMixin, models.Model): """Un modèle (au sens constructeur) de switch""" reference = models.CharField(max_length=255) commercial_name = models.CharField( max_length=255, null=True, blank=True ) constructor = models.ForeignKey( 'topologie.ConstructorSwitch', on_delete=models.PROTECT ) firmware = models.CharField( max_length=255, null=True, blank=True ) class Meta: permissions = ( ("view_modelswitch", _("Can view a switch model object")), ) verbose_name = _("switch model") verbose_name_plural = _("switch models") def __str__(self): if self.commercial_name: return str(self.constructor) + ' ' + str(self.commercial_name) else: return str(self.constructor) + ' ' + self.reference class ConstructorSwitch(AclMixin, RevMixin, models.Model): """Un constructeur de switch""" name = models.CharField(max_length=255) class Meta: permissions = ( ("view_constructorswitch", _("Can view a switch constructor" " object")), ) verbose_name = _("switch constructor") verbose_name_plural = ("switch constructors") def __str__(self): return self.name class SwitchBay(AclMixin, RevMixin, models.Model): """Une baie de brassage""" name = models.CharField(max_length=255) building = models.ForeignKey( 'Building', on_delete=models.PROTECT ) info = models.CharField( max_length=255, blank=True, null=True ) class Meta: permissions = ( ("view_switchbay", _("Can view a switch bay object")), ) verbose_name = _("switch bay") verbose_name_plural = _("switch bays") def __str__(self): return self.name class Building(AclMixin, RevMixin, models.Model): """Un batiment""" name = models.CharField(max_length=255) class Meta: permissions = ( ("view_building", _("Can view a building object")), ) verbose_name = _("building") verbose_name_plural = _("buildings") def all_ap_in(self): """Returns all ap of the building""" return AccessPoint.all_ap_in(self) def __str__(self): return self.name class Port(AclMixin, RevMixin, models.Model): """ Definition d'un port. Relié à un switch(foreign_key), un port peut etre relié de manière exclusive à : - une chambre (room) - une machine (serveur etc) (machine_interface) - un autre port (uplink) (related) Champs supplémentaires : - RADIUS (mode STRICT : connexion sur port uniquement si machine d'un adhérent à jour de cotisation et que la chambre est également à jour de cotisation mode COMMON : vérification uniquement du statut de la machine mode NO : accepte toute demande venant du port et place sur le vlan normal mode BLOQ : rejet de toute authentification - vlan_force : override la politique générale de placement vlan, permet de forcer un port sur un vlan particulier. S'additionne à la politique RADIUS""" switch = models.ForeignKey( 'Switch', related_name="ports", on_delete=models.CASCADE ) port = models.PositiveIntegerField() room = models.ForeignKey( 'Room', on_delete=models.PROTECT, blank=True, null=True ) machine_interface = models.ForeignKey( 'machines.Interface', on_delete=models.SET_NULL, blank=True, null=True ) related = models.OneToOneField( 'self', null=True, blank=True, related_name='related_port' ) custom_profile = models.ForeignKey( 'PortProfile', on_delete=models.PROTECT, blank=True, null=True ) state = models.BooleanField( default=True, help_text='Port state Active', verbose_name=_("Port state Active") ) details = models.CharField(max_length=255, blank=True) class Meta: unique_together = ('switch', 'port') permissions = ( ("view_port", _("Can view a port object")), ) verbose_name = _("port") verbose_name_plural = _("ports") @cached_property def pretty_name(self): """More elaborated name for label on switch conf""" if self.related: return "Uplink : " + self.related.switch.short_name elif self.machine_interface: return "Machine : " + str(self.machine_interface.domain) elif self.room: return "Chambre : " + str(self.room) else: return "Inconnue" @cached_property def get_port_profile(self): """Return the config profil for this port :returns: the profile of self (port)""" def profile_or_nothing(profile): port_profile = PortProfile.objects.filter( profil_default=profile).first() if port_profile: return port_profile else: nothing_profile, _created = PortProfile.objects.get_or_create( profil_default='nothing', name='nothing', radius_type='NO' ) return nothing_profile if self.custom_profile: return self.custom_profile elif self.related: return profile_or_nothing('uplink') elif self.machine_interface: if hasattr(self.machine_interface.machine, 'accesspoint'): return profile_or_nothing('access_point') else: return profile_or_nothing('asso_machine') elif self.room: return profile_or_nothing('room') else: return profile_or_nothing('nothing') @classmethod def get_instance(cls, portid, *_args, **kwargs): return (cls.objects .select_related('machine_interface__domain__extension') .select_related('machine_interface__machine__switch') .select_related('room') .select_related('related') .prefetch_related('switch__interface_set__domain__extension') .get(pk=portid)) def make_port_related(self): """ Synchronise le port distant sur self""" related_port = self.related related_port.related = self related_port.save() def clean_port_related(self): """ Supprime la relation related sur self""" related_port = self.related_port related_port.related = None related_port.save() def clean(self): """ Verifie que un seul de chambre, interface_parent et related_port est rempli. Verifie que le related n'est pas le port lui-même.... Verifie que le related n'est pas déjà occupé par une machine ou une chambre. Si ce n'est pas le cas, applique la relation related Si un port related point vers self, on nettoie la relation A priori pas d'autre solution que de faire ça à la main. A priori tout cela est dans un bloc transaction, donc pas de problème de cohérence""" if hasattr(self, 'switch'): if self.port > self.switch.number: raise ValidationError( _("The port can't exist, its number is too great.") ) if (self.room and self.machine_interface or self.room and self.related or self.machine_interface and self.related): raise ValidationError( _("Room, interface and related port are mutually exclusive.") ) if self.related == self: raise ValidationError(_("A port can't be related to itself.")) if self.related and not self.related.related: if self.related.machine_interface or self.related.room: raise ValidationError( _("The related port is already used, please clear it" " before creating the relation.") ) else: self.make_port_related() elif hasattr(self, 'related_port'): self.clean_port_related() def __str__(self): return str(self.switch) + " - " + str(self.port) class Room(AclMixin, RevMixin, models.Model): """Une chambre/local contenant une prise murale""" name = models.CharField(max_length=255, unique=True) details = models.CharField(max_length=255, blank=True) class Meta: ordering = ['name'] permissions = ( ("view_room", _("Can view a room object")), ) verbose_name = _("room") verbose_name_plural = _("rooms") def __str__(self): return self.name class PortProfile(AclMixin, RevMixin, models.Model): """Contains the information of the ports' configuration for a switch""" TYPES = ( ('NO', 'NO'), ('802.1X', '802.1X'), ('MAC-radius', 'MAC-radius'), ) MODES = ( ('STRICT', 'STRICT'), ('COMMON', 'COMMON'), ) SPEED = ( ('10-half', '10-half'), ('100-half', '100-half'), ('10-full', '10-full'), ('100-full', '100-full'), ('1000-full', '1000-full'), ('auto', 'auto'), ('auto-10', 'auto-10'), ('auto-100', 'auto-100'), ) PROFIL_DEFAULT = ( ('room', 'room'), ('access_point', 'access_point'), ('uplink', 'uplink'), ('asso_machine', 'asso_machine'), ('nothing', 'nothing'), ) name = models.CharField(max_length=255, verbose_name=_("Name")) profil_default = models.CharField( max_length=32, choices=PROFIL_DEFAULT, blank=True, null=True, unique=True, verbose_name=_("Default profile") ) vlan_untagged = models.ForeignKey( 'machines.Vlan', related_name='vlan_untagged', on_delete=models.SET_NULL, blank=True, null=True, verbose_name=_("VLAN untagged") ) vlan_tagged = models.ManyToManyField( 'machines.Vlan', related_name='vlan_tagged', blank=True, verbose_name=_("VLAN(s) tagged") ) radius_type = models.CharField( max_length=32, choices=TYPES, help_text=_("Type of RADIUS authentication : inactive, MAC-address or" " 802.1X"), verbose_name=_("RADIUS type") ) radius_mode = models.CharField( max_length=32, choices=MODES, default='COMMON', help_text=_("In case of MAC-authentication : mode COMMON or STRICT on" " this port"), verbose_name=_("RADIUS mode") ) speed = models.CharField( max_length=32, choices=SPEED, default='auto', help_text=_("Port speed limit"), ) mac_limit = models.IntegerField( null=True, blank=True, help_text=_("Limit of MAC-address on this port"), verbose_name=_("MAC limit") ) flow_control = models.BooleanField( default=False, help_text=_("Flow control"), ) dhcp_snooping = models.BooleanField( default=False, help_text=_("Protect against rogue DHCP"), verbose_name=_("DHCP snooping") ) dhcpv6_snooping = models.BooleanField( default=False, help_text=_("Protect against rogue DHCPv6"), verbose_name=_("DHCPv6 snooping") ) arp_protect = models.BooleanField( default=False, help_text=_("Check if IP adress is DHCP assigned"), verbose_name=_("ARP protection") ) ra_guard = models.BooleanField( default=False, help_text=_("Protect against rogue RA"), verbose_name=_("RA guard") ) loop_protect = models.BooleanField( default=False, help_text=_("Protect against loop"), verbose_name=_("Loop protection") ) class Meta: permissions = ( ("view_port_profile", _("Can view a port profile object")), ) verbose_name = _("port profile") verbose_name_plural = _("port profiles") security_parameters_fields = [ 'loop_protect', 'ra_guard', 'arp_protect', 'dhcpv6_snooping', 'dhcp_snooping', 'flow_control' ] @cached_property def security_parameters_enabled(self): return [ parameter for parameter in self.security_parameters_fields if getattr(self, parameter) ] @cached_property def security_parameters_as_str(self): return ','.join(self.security_parameters_enabled) def __str__(self): return self.name @receiver(post_save, sender=AccessPoint) def ap_post_save(**_kwargs): """Regeneration des noms des bornes vers le controleur""" regen('unifi-ap-names') regen("graph_topo") @receiver(post_delete, sender=AccessPoint) def ap_post_delete(**_kwargs): """Regeneration des noms des bornes vers le controleur""" regen('unifi-ap-names') regen("graph_topo") @receiver(post_delete, sender=Stack) def stack_post_delete(**_kwargs): """Vide les id des switches membres d'une stack supprimée""" Switch.objects.filter(stack=None).update(stack_member_id=None) @receiver(post_save, sender=Port) def port_post_save(**_kwargs): regen("graph_topo") @receiver(post_delete, sender=Port) def port_post_delete(**_kwargs): regen("graph_topo") @receiver(post_save, sender=ModelSwitch) def modelswitch_post_save(**_kwargs): regen("graph_topo") @receiver(post_delete, sender=ModelSwitch) def modelswitch_post_delete(**_kwargs): regen("graph_topo") @receiver(post_save, sender=Building) def building_post_save(**_kwargs): regen("graph_topo") @receiver(post_delete, sender=Building) def building_post_delete(**_kwargs): regen("graph_topo") @receiver(post_save, sender=Switch) def switch_post_save(**_kwargs): regen("graph_topo") @receiver(post_delete, sender=Switch) def switch_post_delete(**_kwargs): regen("graph_topo")