# -.- coding: utf-8 -.- # Zeitgeist # # Copyright © 2009 Mikkel Kamstrup Erlandsen # Copyright © 2009 Markus Korn # Copyright © 2009-2010 Seif Lotfy # Copyright © 2009-2010 Siegfried-Angel Gevatter Pujals # Copyright © 2011 Collabora Ltd. # By Siegfried-Angel Gevatter Pujals # # This program is free software: you can redistribute it and/or modify # it under the terms of the GNU Lesser General Public License as published by # the Free Software Foundation, either version 2.1 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 Lesser General Public License for more details. # # You should have received a copy of the GNU Lesser General Public License # along with this program. If not, see . import os.path import gettext import time import sys gettext.install("zeitgeist") __all__ = [ 'Interpretation', 'Manifestation', 'ResultType', 'RelevantResultType', 'StorageState', 'TimeRange', 'DataSource', 'Event', 'Subject', 'NULL_EVENT', 'NEGATION_OPERATOR', ] NEGATION_OPERATOR = "!" WILDCARD = "*" def EQUAL(x, y): """checks if both given arguments are equal""" return x == y def STARTSWITH(x, y): """checks if 'x' startswith 'y'""" return x.startswith(y) NEEDS_CHILD_RESOLUTION = set() def get_timestamp_for_now(): """ Return the current time in milliseconds since the Unix Epoch. """ return int(time.time() * 1000) class EnumValue(int): """Class which behaves like an int, but has an additional docstring""" def __new__(cls, value, doc=""): obj = super(EnumValue, cls).__new__(EnumValue, value) obj.__doc__ = "%s. ``(Integer value: %i)``" %(doc, obj) return obj def isCamelCase(text): return text and text[0].isupper() and " " not in text def get_name_or_str(obj): try: return str(obj.name) except AttributeError: return str(obj) _SYMBOLS_BY_URI = {} class Symbol(str): def __new__(cls, name, parent=None, uri=None, display_name=None, doc=None, auto_resolve=True): if not isCamelCase(name): raise ValueError("Naming convention requires symbol name to be CamelCase, got '%s'" %name) return super(Symbol, cls).__new__(Symbol, uri or name) def __init__(self, name, parent=None, uri=None, display_name=None, doc=None, auto_resolve=True): self._children = dict() self._all_children = None self._parents = parent or set() # will be bootstrapped to a dict at module load time assert isinstance(self._parents, set), name self._name = name self._uri = uri self._display_name = display_name self._doc = doc _SYMBOLS_BY_URI[uri] = self def __repr__(self): return "<%s '%s'>" %(get_name_or_str(self), self.uri) def __getattr__(self, name): self._ensure_all_children() try: return self._all_children[name] except KeyError: for child in self.iter_all_children(): if child == self: continue try: return getattr(child, name) except AttributeError: pass raise AttributeError("'%s' object has no attribute '%s'" %(self.__class__.__name__, name)) def __getitem__ (self, uri): return _SYMBOLS_BY_URI[uri] def _ensure_all_children (self): if self._all_children is not None : return self._all_children = dict() for child in list(self._children.values()): child._visit(self._all_children) def _visit (self, dikt): dikt[self.name] = self for child in list(self._children.values()): child._visit(dikt) @staticmethod def find_child_uris_extended (uri): """ Creates a list of all known child Symbols of `uri`, including `uri` itself in the list. Hence the "extended". If `uri` is unknown a list containing only `uri` is returned. """ try: symbol = _SYMBOLS_BY_URI[uri] children = list(symbol.get_all_children()) children.append(uri) return children except KeyError as e: return [uri] @property def uri(self): return self._uri or self.name @property def display_name(self): return self._display_name or "" @property def name(self): return self._name __name__ = name def __dir__(self): self._ensure_all_children() return list(self._all_children.keys()) @property def doc(self): return self._doc or "" @property def __doc__(self): return "%s\n\n %s. ``(Display name: '%s')``" %(self.uri, self.doc.rstrip("."), self.display_name) def get_children(self): """ Returns a list of immediate child symbols """ return frozenset(iter(list(self._children.values()))) def iter_all_children(self): """ Returns a generator that recursively iterates over all children of this symbol """ self._ensure_all_children() return iter(list(self._all_children.values())) def get_all_children(self): """ Return a read-only set containing all children of this symbol """ return frozenset(self.iter_all_children()) def get_parents(self): """ Returns a list of immediate parent symbols """ return frozenset(iter(list(self._parents.values()))) def is_child_of (self, parent): """ Returns True if this symbol is a child of `parent`. """ if not isinstance (parent, Symbol): try: parent = _SYMBOLS_BY_URI[parent] except KeyError as e: # Parent is not a known URI return self.uri == parent # Invariant: parent is a Symbol if self.uri == parent.uri : return True parent._ensure_all_children() # FIXME: We should really check that child.uri is in there, # but that is not fast with the current code layout return self.name in parent._all_children @staticmethod def uri_is_child_of (child, parent): """ Returns True if `child` is a child of `parent`. Both `child` and `parent` arguments must be any combination of :class:`Symbol` and/or string. """ if isinstance (child, str): try: child = _SYMBOLS_BY_URI[child] except KeyError as e: # Child is not a know URI if isinstance (parent, str): return child == parent elif isinstance (parent, Symbol): return child == parent.uri else: return False if not isinstance (child, Symbol): raise ValueError("Child argument must be a Symbol or string. Got %s" % type(child)) return child.is_child_of(parent) class TimeRange(list): """ A class that represents a time range with a beginning and an end. The timestamps used are integers representing milliseconds since the Epoch. By design this class will be automatically transformed to the DBus type (xx). """ # Maximal value of our timestamps _max_stamp = 2**63 - 1 def __init__ (self, begin, end): super(TimeRange, self).__init__((int(begin), int(end))) def __eq__ (self, other): return self.begin == other.begin and self.end == other.end def __str__ (self): return "(%s, %s)" % (self.begin, self.end) def get_begin(self): return self[0] def set_begin(self, begin): self[0] = begin begin = property(get_begin, set_begin, doc="The begining timestamp of this time range") def get_end(self): return self[1] def set_end(self, end): self[1] = end end = property(get_end, set_end, doc="The end timestamp of this time range") @classmethod def until_now(cls): """ Return a :class:`TimeRange` from 0 to the instant of invocation """ return cls(0, int(time.time() * 1000)) @classmethod def from_now(cls): """ Return a :class:`TimeRange` from the instant of invocation to the end of time """ return cls(int(time.time() * 1000), cls._max_stamp) @classmethod def from_seconds_ago(cls, sec): """ Return a :class:`TimeRange` ranging from "sec" seconds before the instant of invocation to the same. """ now = int(time.time() * 1000) return cls(now - (sec * 1000), now) @classmethod def from_timestamp(cls, timestamp): """ Return a :class:`TimeRange` ranging from the given timestamp until the end of time. The given timestamp is expected to be expressed in miliseconds. """ return cls(int(timestamp), cls._max_stamp) @classmethod def always(cls): """ Return a :class:`TimeRange` from 0 (January 1, 1970) to the most distant future """ return cls(0, cls._max_stamp) def is_always(self): """ Returns True if this time range goes from timestamp 0 (January 1, 1970) -or lower- to the most distant future. """ return self.begin <= 0 and self.end >= TimeRange._max_stamp def intersect(self, time_range): """ Return a new :class:`TimeRange` that is the intersection of the two time range intervals. If the intersection is empty this method returns :const:`None`. """ # Behold the boolean madness! result = TimeRange(0,0) if self.begin < time_range.begin: if self.end < time_range.begin: return None else: result.begin = time_range.begin else: if self.begin > time_range.end: return None else: result.begin = self.begin if self.end < time_range.end: if self.end < time_range.begin: return None else: result.end = self.end else: if self.begin > time_range.end: return None else: result.end = time_range.end return result class Subject(list): """ Represents a subject of an :class:`Event`. This class is both used to represent actual subjects, but also create subject templates to match other subjects against. Applications should normally use the method :meth:`new_for_values` to create new subjects. """ Fields = (Uri, Interpretation, Manifestation, Origin, Mimetype, Text, Storage, CurrentUri, CurrentOrigin) = list(range(9)) SUPPORTS_NEGATION = (Uri, CurrentUri, Interpretation, Manifestation, Origin, CurrentOrigin, Mimetype) SUPPORTS_WILDCARDS = (Uri, CurrentUri, Origin, CurrentOrigin, Mimetype) def __init__(self, data=None): if data: if len(data) == len(Subject.Fields) - 2: # current_uri has been added in Zeitgeist 0.8.0 data.append("") if len(data) == len(Subject.Fields) - 1: # current_origin has been added in Zeitgeist 1.0 Beta 1 data.append("") if len(data) < len(Subject.Fields): raise ValueError( "Invalid subject data length %s, expected %s" \ %(len(data), len(Subject.Fields))) super(Subject, self).__init__(data) else: super(Subject, self).__init__([""]*len(Subject.Fields)) def __repr__(self): return "%s(%s)" %( self.__class__.__name__, super(Subject, self).__repr__() ) def __eq__(self, other): for field in Subject.Fields: if field in (Subject.CurrentUri, Subject.CurrentOrigin) and \ not self[field] or not other[field]: continue if self[field] != other[field]: return False return True @staticmethod def new_for_values (**values): """ Create a new Subject instance and set its properties according to the keyword arguments passed to this method. :param uri: The URI of the subject. Eg. *file:///tmp/ratpie.txt* :param current_uri: The current known URI of the subject (if it was moved or deleted). :param interpretation: The interpretation type of the subject, given either as a string URI or as a :class:`Interpretation` instance :param manifestation: The manifestation type of the subject, given either as a string URI or as a :class:`Manifestation` instance :param origin: The URI of the location where subject resides or can be found :param current_origin: The URI of the location where subject resides or can be found (if it was moved or deleted). :param mimetype: The mimetype of the subject encoded as a string, if applicable. Eg. *text/plain*. :param text: Free form textual annotation of the subject. :param storage: String identifier for the storage medium of the subject. This should be the UUID of the volume or the string "net" for resources requiring a network interface, and the string "deleted" for subjects that are deleted. """ self = Subject() for key, value in list(values.items()): if not key in ("uri", "current_uri", "interpretation", "manifestation", "origin", "current_origin", "mimetype", "text", "storage"): raise ValueError("Subject parameter '%s' is not supported" %key) setattr(self, key, value) return self def get_uri(self): return self[Subject.Uri] def set_uri(self, value): self[Subject.Uri] = value uri = property(get_uri, set_uri, doc="Read/write property with the URI of the subject encoded as a string") def get_current_uri(self): return self[Subject.CurrentUri] def set_current_uri(self, value): self[Subject.CurrentUri] = value current_uri = property(get_current_uri, set_current_uri, doc="Read/write property with the current URI of the subject encoded as a string") def get_interpretation(self): return self[Subject.Interpretation] def set_interpretation(self, value): self[Subject.Interpretation] = value interpretation = property(get_interpretation, set_interpretation, doc="Read/write property defining the :class:`interpretation type ` of the subject") def get_manifestation(self): return self[Subject.Manifestation] def set_manifestation(self, value): self[Subject.Manifestation] = value manifestation = property(get_manifestation, set_manifestation, doc="Read/write property defining the :class:`manifestation type ` of the subject") def get_origin(self): return self[Subject.Origin] def set_origin(self, value): self[Subject.Origin] = value origin = property(get_origin, set_origin, doc="Read/write property with the URI of the location where the subject can be found. For files this is the parent directory, or for downloaded files it would be the URL of the page where you clicked the download link") def get_current_origin(self): return self[Subject.CurrentOrigin] def set_current_origin(self, value): self[Subject.CurrentOrigin] = value current_origin = property(get_current_origin, set_current_origin, doc="Read/write property with the URI of the location where the subject can be found. For files this is the parent directory, or for downloaded files it would be the URL of the page where you clicked the download link") def get_mimetype(self): return self[Subject.Mimetype] def set_mimetype(self, value): self[Subject.Mimetype] = value mimetype = property(get_mimetype, set_mimetype, doc="Read/write property containing the mimetype of the subject (encoded as a string) if applicable") def get_text(self): return self[Subject.Text] def set_text(self, value): self[Subject.Text] = value text = property(get_text, set_text, doc="Read/write property with a free form textual annotation of the subject") def get_storage(self): return self[Subject.Storage] def set_storage(self, value): self[Subject.Storage] = value storage = property(get_storage, set_storage, doc="Read/write property with a string id of the storage medium where the subject is stored. Fx. the UUID of the disk partition or just the string 'net' for items requiring network interface to be available") def matches_template (self, subject_template): """ Return True if this Subject matches *subject_template*. Empty fields in the template are treated as wildcards. Interpretations and manifestations are also matched if they are children of the types specified in `subject_template`. See also :meth:`Event.matches_template` """ for m in Subject.Fields: if not subject_template[m]: # empty fields are handled as wildcards continue if m == Subject.Storage: # we do not support searching by storage field for now # see LP: #580364 raise ValueError("zeitgeist does not support searching by 'storage' field") elif m in (Subject.Interpretation, Subject.Manifestation): # symbols are treated differently comp = Symbol.uri_is_child_of else: comp = EQUAL if not self._check_field_match(m, subject_template[m], comp): return False return True def _check_field_match(self, field_id, expression, comp): """ Checks if an expression matches a field given by its `field_id` using a `comp` comparison function """ if field_id in self.SUPPORTS_NEGATION \ and expression.startswith(NEGATION_OPERATOR): return not self._check_field_match(field_id, expression[len(NEGATION_OPERATOR):], comp) elif field_id in self.SUPPORTS_WILDCARDS \ and expression.endswith(WILDCARD): assert comp == EQUAL, "wildcards only work for pure text fields" return self._check_field_match(field_id, expression[:-len(WILDCARD)], STARTSWITH) else: return comp(self[field_id], expression) class Event(list): """ Core data structure in the Zeitgeist framework. It is an optimized and convenient representation of an event. This class is designed so that you can pass it directly over DBus using the Python DBus bindings. It will automagically be marshalled with the signature a(asaasay). See also the section on the :ref:`event serialization format `. This class does integer based lookups everywhere and can wrap any conformant data structure without the need for marshalling back and forth between DBus wire format. These two properties makes it highly efficient and is recommended for use everywhere. """ Fields = (Id, Timestamp, Interpretation, Manifestation, Actor, Origin) = list(range(6)) SUPPORTS_NEGATION = (Interpretation, Manifestation, Actor, Origin) SUPPORTS_WILDCARDS = (Actor, Origin) _subject_type = Subject def __init__(self, struct = None): """ If 'struct' is set it must be a list containing the event metadata in the first position, and optionally the list of subjects in the second position, and again optionally the event payload in the third position. Unless the event metadata contains a timestamp the event will have its timestamp set to "now". Ie. the instant of invocation. The event metadata (struct[0]) will be used as is, and must contain the event data on the positions defined by the Event.Fields enumeration. Likewise each member of the subjects (struct[1]) must be an array with subject metadata defined in the positions as laid out by the Subject.Fields enumeration. On the third position (struct[2]) the struct may contain the event payload, which can be an arbitrary binary blob. The payload will be transfered over DBus with the 'ay' signature (as an array of bytes). """ super(Event, self).__init__() if struct: if len(struct) == 1: self.append(self._check_event_struct(struct[0])) self.append([]) self.append("") elif len(struct) == 2: self.append(self._check_event_struct(struct[0])) self.append(list(map(self._subject_type, struct[1]))) self.append("") elif len(struct) == 3: self.append(self._check_event_struct(struct[0])) self.append(list(map(self._subject_type, struct[1]))) self.append(struct[2]) else: raise ValueError("Invalid struct length %s" % len(struct)) # If this event is being created from an existing Event instance, # make a copy of the list holding the event information. This # enables the idiom "event2 = Event(event1)" to copy an event. if isinstance(struct, Event): self[0] = list(self[0]) else: self.extend(([""]* len(Event.Fields), [], "")) # If we have no timestamp just set it to now if not self[0][Event.Timestamp]: self[0][Event.Timestamp] = str(get_timestamp_for_now()) # If we have no origin for Event then we set None if len(self[0]) == 5: self[0].append(None) @classmethod def _check_event_struct(cls, event_data): if len(event_data) == len(cls.Fields) - 1: # Old versions of Zeitgeist didn't have the event origin field. event_data.append("") if len(event_data) < len(cls.Fields): raise ValueError("event_data must have %s members, found %s" % \ (len(cls.Fields), len(event_data))) return event_data @classmethod def new_for_data(cls, event_data): """ Create a new Event setting event_data as the backing array behind the event metadata. The contents of the array must contain the event metadata at the positions defined by the Event.Fields enumeration. """ self = cls() self[0] = self._check_event_struct(event_data) return self @classmethod def new_for_struct(cls, struct): """Returns a new Event instance or None if `struct` is a `NULL_EVENT`""" if struct == NULL_EVENT: return None return cls(struct) @classmethod def new_for_values(cls, **values): """ Create a new Event instance from a collection of keyword arguments. :param timestamp: Event timestamp in milliseconds since the Unix Epoch :param interpretaion: The Interpretation type of the event :param manifestation: Manifestation type of the event :param actor: The actor (application) that triggered the event :param origin: The origin (domain) where the event was triggered :param subjects: A list of :class:`Subject` instances Instead of setting the *subjects* argument one may use a more convenient approach for events that have exactly one Subject. Namely by using the *subject_** keys - mapping directly to their counterparts in :meth:`Subject.new_for_values`: :param subject_uri: :param subject_current_uri: :param subject_interpretation: :param subject_manifestation: :param subject_origin: :param subject_current_origin: :param subject_mimetype: :param subject_text: :param subject_storage: """ self = cls() for key in values: if not key in ("timestamp", "interpretation", "manifestation", "actor", "origin", "subjects", "subject_uri", "subject_current_uri", "subject_interpretation", "subject_manifestation", "subject_origin", "subject_current_origin", "subject_mimetype", "subject_text", "subject_storage"): raise ValueError("Event parameter '%s' is not supported" % key) self.timestamp = values.get("timestamp", self.timestamp) self.interpretation = values.get("interpretation", "") self.manifestation = values.get("manifestation", "") self.actor = values.get("actor", "") self.origin = values.get("origin", "") self.subjects = values.get("subjects", self.subjects) if self._dict_contains_subject_keys(values): if "subjects" in values: raise ValueError("Subject keys, subject_*, specified together with full subject list") subj = self._subject_type() subj.uri = values.get("subject_uri", "") subj.current_uri = values.get("subject_current_uri", "") subj.interpretation = values.get("subject_interpretation", "") subj.manifestation = values.get("subject_manifestation", "") subj.origin = values.get("subject_origin", "") subj.current_origin = values.get("subject_current_origin", "") subj.mimetype = values.get("subject_mimetype", "") subj.text = values.get("subject_text", "") subj.storage = values.get("subject_storage", "") self.subjects = [subj] return self @staticmethod def _dict_contains_subject_keys (dikt): if "subject_uri" in dikt: return True elif "subject_current_uri" in dikt: return True elif "subject_current_origin" in dikt: return True elif "subject_interpretation" in dikt: return True elif "subject_manifestation" in dikt: return True elif "subject_origin" in dikt: return True elif "subject_mimetype" in dikt: return True elif "subject_text" in dikt: return True elif "subject_storage" in dikt: return True return False def __repr__(self): return "%s(%s)" %( self.__class__.__name__, super(Event, self).__repr__() ) def append_subject(self, subject=None): """ Append a new empty Subject and return a reference to it """ if not subject: subject = self._subject_type() self.subjects.append(subject) return subject def get_subjects(self): return self[1] def set_subjects(self, subjects): self[1] = subjects subjects = property(get_subjects, set_subjects, doc="Read/write property with a list of :class:`Subjects `") def get_id(self): val = self[0][Event.Id] return int(val) if val else 0 id = property(get_id, doc="Read only property containing the the event id if the event has one") def get_timestamp(self): return self[0][Event.Timestamp] def set_timestamp(self, value): self[0][Event.Timestamp] = str(value) timestamp = property(get_timestamp, set_timestamp, doc="Read/write property with the event timestamp defined as milliseconds since the Epoch. By default it is set to the moment of instance creation") def get_interpretation(self): return self[0][Event.Interpretation] def set_interpretation(self, value): self[0][Event.Interpretation] = value interpretation = property(get_interpretation, set_interpretation, doc="Read/write property defining the interpretation type of the event") def get_manifestation(self): return self[0][Event.Manifestation] def set_manifestation(self, value): self[0][Event.Manifestation] = value manifestation = property(get_manifestation, set_manifestation, doc="Read/write property defining the manifestation type of the event") def get_actor(self): return self[0][Event.Actor] def set_actor(self, value): self[0][Event.Actor] = value actor = property(get_actor, set_actor, doc="Read/write property defining the application or entity responsible " "for emitting the event. For applications, the format of this field is " "the base filename of the corresponding .desktop file with an " "`application://` URI scheme. For example, " "`/usr/share/applications/firefox.desktop` is encoded as " "`application://firefox.desktop`") def get_origin(self): return self[0][Event.Origin] def set_origin(self, value): self[0][Event.Origin] = value origin = property(get_origin, set_origin, doc="Read/write property defining the origin where the event was emitted.") def get_payload(self): return self[2] def set_payload(self, value): self[2] = value payload = property(get_payload, set_payload, doc="Free form attachment for the event. Transfered over DBus as an array of bytes") def matches_template(self, event_template): """ Return True if this event matches *event_template*. The matching is done where unset fields in the template is interpreted as wild cards. Interpretations and manifestations are also matched if they are children of the types specified in `event_template`. If the template has more than one subject, this event matches if at least one of the subjects on this event matches any single one of the subjects on the template. Basically this method mimics the matching behaviour found in the :meth:`FindEventIds` method on the Zeitgeist engine. """ # We use direct member access to speed things up a bit # First match the raw event data data = self[0] tdata = event_template[0] for m in Event.Fields: if m == Event.Timestamp or not tdata[m]: # matching be timestamp is not supported and # empty template-fields are treated as wildcards continue if m in (Event.Manifestation, Event.Interpretation): # special check for symbols comp = Symbol.uri_is_child_of else: comp = EQUAL if not self._check_field_match(m, tdata[m], comp): return False # If template has no subjects we have a match if len(event_template[1]) == 0 : return True # Now we check the subjects for tsubj in event_template[1]: for subj in self[1]: if not subj.matches_template(tsubj) : continue # We have a matching subject, all good! return True # Template has subjects, but we never found a match return False def _check_field_match(self, field_id, expression, comp): """ Checks if an expression matches a field given by its `field_id` using a `comp` comparison function """ if field_id in self.SUPPORTS_NEGATION \ and expression.startswith(NEGATION_OPERATOR): return not self._check_field_match(field_id, expression[len(NEGATION_OPERATOR):], comp) elif field_id in self.SUPPORTS_WILDCARDS \ and expression.endswith(WILDCARD): assert comp == EQUAL, "wildcards only work for pure text fields" return self._check_field_match(field_id, expression[:-len(WILDCARD)], STARTSWITH) else: return comp(self[0][field_id], expression) def matches_event (self, event): """ Interpret *self* as the template an match *event* against it. This method is the dual method of :meth:`matches_template`. """ return event.matches_template(self) def in_time_range (self, time_range): """ Check if the event timestamp lies within a :class:`TimeRange` """ t = int(self.timestamp) # The timestamp may be stored as a string return (t >= time_range.begin) and (t <= time_range.end) class DataSource(list): """ Optimized and convenient data structure representing a datasource. This class is designed so that you can pass it directly over DBus using the Python DBus bindings. It will automagically be marshalled with the signature a(asaasay). See also the section on the :ref:`event serialization format `. This class does integer based lookups everywhere and can wrap any conformant data structure without the need for marshalling back and forth between DBus wire format. These two properties makes it highly efficient and is recommended for use everywhere. This is part of the :const:`org.gnome.zeitgeist.DataSourceRegistry` extension. """ Fields = (UniqueId, Name, Description, EventTemplates, Running, LastSeen, # last time the data-source did something (connected, # inserted events, disconnected). Enabled) = list(range(7)) def get_unique_id(self): return self[self.UniqueId] def set_unique_id(self, value): self[self.UniqueId] = value def get_name(self): return self[self.Name] def set_name(self, value): self[self.Name] = value def get_description(self): return self[self.Description] def set_description(self, value): self[self.Description] = value def get_running(self): return self[self.Running] def set_running(self,value): self[self.Running] = value def get_running(self): return self[self.Running] def running(self, value): self[self.Running] = value def get_last_seen(self): return self[self.LastSeen] def set_last_seen(self, value): self[self.LastSeen] = value def get_enabled(self): return self[self.Enabled] def set_enabled(self, value): self[self.Enabled] = value unique_id = property(get_unique_id, set_unique_id) name = property(get_name, set_name) description = property(get_description, set_description) running = property(get_running, set_running) last_seen = property(get_last_seen, set_last_seen) enabled = property(get_enabled, set_enabled) def __init__(self, unique_id, name, description, templates, running=True, last_seen=None, enabled=True): """ Create a new DataSource object using the given parameters. If you want to instantiate this class from a dbus.Struct, you can use: DataSource(*data_source), where data_source is the dbus.Struct. """ super(DataSource, self).__init__() self.append(unique_id) self.append(name) self.append(description) self.append(templates) self.append(bool(running)) self.append(last_seen if last_seen else get_timestamp_for_now()) self.append(enabled) def __eq__(self, source): return self[self.UniqueId] == source[self.UniqueId] def __repr__(self): return "%s: %s (%s)" % (self.__class__.__name__, self[self.UniqueId], self[self.Name]) NULL_EVENT = ([], [], []) """Minimal Event representation, a tuple containing three empty lists. This `NULL_EVENT` is used by the API to indicate a queried but not available (not found or blocked) Event. """ class _Enumeration(object): @classmethod def iteritems(self): """ Return an iterator yielding (name, value) tuples for all items in this enumeration. """ return iter([(x, getattr(self, x)) for x in [x for x in sorted(self.__dict__) if not x.startswith('__')]]) class RelevantResultType(_Enumeration): """ An enumeration class used to define how query results should be returned from the Zeitgeist engine. """ Recent = EnumValue(0, "All uris with the most recent uri first") Related = EnumValue(1, "All uris with the most related one first") class StorageState(_Enumeration): """ Enumeration class defining the possible values for the storage state of an event subject. The StorageState enumeration can be used to control whether or not matched events must have their subjects available to the user. Fx. not including deleted files, files on unplugged USB drives, files available only when a network is available etc. """ NotAvailable = EnumValue(0, "The storage medium of the events " "subjects must not be available to the user") Available = EnumValue(1, "The storage medium of all event subjects " "must be immediately available to the user") Any = EnumValue(2, "The event subjects may or may not be available") class ResultType(_Enumeration): """ An enumeration class used to define how query results should be returned from the Zeitgeist engine. """ MostRecentEvents = EnumValue(0, "All events with the most recent events first") LeastRecentEvents = EnumValue(1, "All events with the oldest ones first") MostRecentSubjects = EnumValue(2, "One event for each subject only, " "ordered with the most recent events first") LeastRecentSubjects = EnumValue(3, "One event for each subject only, " "ordered with oldest events first") MostPopularSubjects = EnumValue(4, "One event for each subject only, " "ordered by the popularity of the subject") LeastPopularSubjects = EnumValue(5, "One event for each subject only, " "ordered ascendingly by popularity of the subject") MostPopularActor = EnumValue(6, "The last event of each different actor," "ordered by the popularity of the actor") LeastPopularActor = EnumValue(7, "The last event of each different actor," "ordered ascendingly by the popularity of the actor") MostRecentActor = EnumValue(8, "The Actor that has been used to most recently") LeastRecentActor = EnumValue(9, "The Actor that has been used to least recently") MostRecentOrigin = EnumValue(10, "The last event of each different subject origin") LeastRecentOrigin = EnumValue(11, "The last event of each different " "subject origin, ordered by least recently used first") MostPopularOrigin = EnumValue(12, "The last event of each different " "subject origin, ordered by the popularity of the origins") LeastPopularOrigin = EnumValue(13, "The last event of each different " "subject origin, ordered ascendingly by the popularity of the origin") OldestActor = EnumValue(14, "The first event of each different actor") MostRecentSubjectInterpretation = EnumValue(15, "One event for each " "subject interpretation only, ordered with the most recent " "events first") LeastRecentSubjectInterpretation = EnumValue(16, "One event for each " "subject interpretation only, ordered with the least recent " "events first") MostPopularSubjectInterpretation = EnumValue(17, "One event for each " "subject interpretation only, ordered by the popularity of the " "subject interpretation") LeastPopularSubjectInterpretation = EnumValue(18, "One event for each " "subject interpretation only, ordered ascendingly by popularity of " "the subject interpretation") MostRecentMimeType = EnumValue(19, "One event for each mimetype only, " "ordered with the most recent events first") LeastRecentMimeType = EnumValue(20, "One event for each mimetype only, " "ordered with the least recent events first") MostPopularMimeType = EnumValue(21, "One event for each mimetype only, " "ordered by the popularity of the mimetype") LeastPopularMimeType = EnumValue(22, "One event for each mimetype only, " "ordered ascendingly by popularity of the mimetype") MostRecentCurrentUri = EnumValue(23, "One event for each subject only " "(by current_uri instead of uri), " "ordered with the most recent events first") LeastRecentCurrentUri = EnumValue(24, "One event for each subject only " "(by current_uri instead of uri), " "ordered with oldest events first") MostPopularCurrentUri = EnumValue(25, "One event for each subject only " "(by current_uri instead of uri), " "ordered by the popularity of the subject") LeastPopularCurrentUri = EnumValue(26, "One event for each subject only " "(by current_uri instead of uri), " "ordered ascendingly by popularity of the subject") MostRecentEventOrigin = EnumValue(27, "The last event of each different origin") LeastRecentEventOrigin = EnumValue(28, "The last event of each " " different origin, ordered by least recently used first") MostPopularEventOrigin = EnumValue(29, "The last event of each " "different origin, ordered by the popularity of the origins") LeastPopularEventOrigin = EnumValue(30, "The last event of each " "different origin, ordered ascendingly by the popularity of the origin") MostRecentCurrentOrigin = EnumValue(31, "The last event of each different subject origin") LeastRecentCurrentOrigin = EnumValue(32, "The last event of each different " "subject origin, ordered by least recently used first") MostPopularCurrentOrigin = EnumValue(33, "The last event of each different " "subject origin, ordered by the popularity of the origins") LeastPopularCurrentOrigin = EnumValue(34, "The last event of each different " "subject origin, ordered ascendingly by the popularity of the origin") # We should eventually migrate over to those names to disambiguate # subject origin and event origin: MostRecentSubjectOrigin = MostRecentOrigin LeastRecentSubjectOrigin = LeastRecentOrigin MostPopularSubjectOrigin = MostPopularOrigin LeastPopularSubjectOrigin = LeastPopularOrigin INTERPRETATION_DOC = \ """In general terms the *interpretation* of an event or subject is an abstract description of *"what happened"* or *"what is this"*. Each interpretation type is uniquely identified by a URI. This class provides a list of hard coded URI constants for programming convenience. In addition; each interpretation instance in this class has a *display_name* property, which is an internationalized string meant for end user display. The interpretation types listed here are all subclasses of *str* and may be used anywhere a string would be used. Interpretations form a hierarchical type tree. So that fx. Audio, Video, and Image all are sub types of Media. These types again have their own sub types, like fx. Image has children Icon, Photo, and VectorImage (among others). Templates match on all sub types, so that a query on subjects with interpretation Media also match subjects with interpretations Audio, Photo, and all other sub types of Media. """ MANIFESTATION_DOC = \ """The manifestation type of an event or subject is an abstract classification of *"how did this happen"* or *"how does this item exist"*. Each manifestation type is uniquely identified by a URI. This class provides a list of hard coded URI constants for programming convenience. In addition; each interpretation instance in this class has a *display_name* property, which is an internationalized string meant for end user display. The manifestation types listed here are all subclasses of *str* and may be used anywhere a string would be used. Manifestations form a hierarchical type tree. So that fx. ArchiveItem, Attachment, and RemoteDataObject all are sub types of FileDataObject. These types can again have their own sub types. Templates match on all sub types, so that a query on subjects with manifestation FileDataObject also match subjects of types Attachment or ArchiveItem and all other sub types of FileDataObject """ start_symbols = time.time() Interpretation = Symbol("Interpretation", doc=INTERPRETATION_DOC) Manifestation = Symbol("Manifestation", doc=MANIFESTATION_DOC) _SYMBOLS_BY_URI["Interpretation"] = Interpretation _SYMBOLS_BY_URI["Manifestation"] = Manifestation # Load the ontology definitions ontology_file = os.path.join(os.path.dirname(__file__), "_ontology.py") try: with open(ontology_file, "rb") as f: exec(compile(f.read(), ontology_file, 'exec')) except IOError: raise ImportError("Unable to load Zeitgeist ontology. Did you run `make`?") # # Bootstrap the symbol relations. We use a 2-pass strategy: # # 1) Make sure that all parents and children are registered on each symbol for symbol in list(_SYMBOLS_BY_URI.values()): for parent in symbol._parents: try: _SYMBOLS_BY_URI[parent]._children[symbol.uri] = None except KeyError as e: print("ERROR", e, parent, symbol.uri) pass for child in symbol._children: try: _SYMBOLS_BY_URI[child]._parents.add(symbol.uri) except KeyError: print("ERROR", e, child, symbol.uri) pass # 2) Resolve all child and parent URIs to their actual Symbol instances for symbol in list(_SYMBOLS_BY_URI.values()): for child_uri in list(symbol._children.keys()): symbol._children[child_uri] = _SYMBOLS_BY_URI[child_uri] parents = {} for parent_uri in symbol._parents: parents[parent_uri] = _SYMBOLS_BY_URI[parent_uri] symbol._parents = parents if __name__ == "__main__": print("Success") end_symbols = time.time() print("Import time: %s" % (end_symbols - start_symbols), file=sys.stderr) # vim:noexpandtab:ts=4:sw=4