// Copyright 2020 The Matrix.org Foundation C.I.C. // // Licensed under the Apache License, Version 2.0 (the "License"); // you may not use this file except in compliance with the License. // You may obtain a copy of the License at // // http://www.apache.org/licenses/LICENSE-2.0 // // Unless required by applicable law or agreed to in writing, software // distributed under the License is distributed on an "AS IS" BASIS, // WITHOUT WARRANTIES OR CONDITIONS OF ANY KIND, either express or implied. // See the License for the specific language governing permissions and // limitations under the License. // TODO // // handle the case where we can't create a session with a device. clearing our // stale key share requests that we'll never be able to handle. // // If we don't trust the device store an object that remembers the request and // let the users introspect that object. use std::{collections::BTreeMap, sync::Arc}; use dashmap::{mapref::entry::Entry, DashMap, DashSet}; use matrix_sdk_common::{ api::r0::to_device::DeviceIdOrAllDevices, events::{ forwarded_room_key::ForwardedRoomKeyToDeviceEventContent, room_key_request::{Action, RequestedKeyInfo, RoomKeyRequestToDeviceEventContent}, AnyToDeviceEvent, EventType, ToDeviceEvent, }, identifiers::{DeviceId, DeviceIdBox, EventEncryptionAlgorithm, RoomId, UserId}, uuid::Uuid, }; use serde::{Deserialize, Serialize}; use serde_json::value::to_raw_value; use thiserror::Error; use tracing::{error, info, trace, warn}; use crate::{ error::{OlmError, OlmResult}, olm::{InboundGroupSession, Session, ShareState}, requests::{OutgoingRequest, ToDeviceRequest}, session_manager::GroupSessionCache, store::{Changes, CryptoStoreError, Store}, Device, }; /// An error describing why a key share request won't be honored. #[derive(Debug, Clone, Error, PartialEq)] pub enum KeyshareDecision { /// The key request is from a device that we don't own, we're only sharing /// sessions that we know the requesting device already was supposed to get. #[error("can't find an active outbound group session")] MissingOutboundSession, /// The key request is from a device that we don't own and the device wasn't /// meant to receive the session in the original key share. #[error("outbound session wasn't shared with the requesting device")] OutboundSessionNotShared, /// The key request is from a device we own, yet we don't trust it. #[error("requesting device isn't trusted")] UntrustedDevice, } /// A queue where we store room key requests that we want to serve but the /// device that requested the key doesn't share an Olm session with us. #[derive(Debug, Clone)] struct WaitQueue { requests_waiting_for_session: Arc< DashMap<(UserId, DeviceIdBox, String), ToDeviceEvent>, >, requests_ids_waiting: Arc>>, } impl WaitQueue { fn new() -> Self { Self { requests_waiting_for_session: Arc::new(DashMap::new()), requests_ids_waiting: Arc::new(DashMap::new()), } } #[cfg(test)] fn is_empty(&self) -> bool { self.requests_ids_waiting.is_empty() && self.requests_waiting_for_session.is_empty() } fn insert(&self, device: &Device, event: &ToDeviceEvent) { let key = ( device.user_id().to_owned(), device.device_id().into(), event.content.request_id.to_owned(), ); self.requests_waiting_for_session.insert(key, event.clone()); let key = (device.user_id().to_owned(), device.device_id().into()); self.requests_ids_waiting .entry(key) .or_insert_with(DashSet::new) .insert(event.content.request_id.clone()); } fn remove( &self, user_id: &UserId, device_id: &DeviceId, ) -> Vec<((UserId, DeviceIdBox, String), ToDeviceEvent)> { self.requests_ids_waiting .remove(&(user_id.to_owned(), device_id.into())) .map(|(_, request_ids)| { request_ids .iter() .filter_map(|id| { let key = (user_id.to_owned(), device_id.into(), id.to_owned()); self.requests_waiting_for_session.remove(&key) }) .collect() }) .unwrap_or_default() } } #[derive(Debug, Clone)] pub(crate) struct KeyRequestMachine { user_id: Arc, device_id: Arc, store: Store, outbound_group_sessions: GroupSessionCache, outgoing_to_device_requests: Arc>, incoming_key_requests: Arc< DashMap<(UserId, DeviceIdBox, String), ToDeviceEvent>, >, wait_queue: WaitQueue, users_for_key_claim: Arc>>, } /// A struct describing an outgoing key request. #[derive(Debug, Clone, Serialize, Deserialize)] pub struct OutgoingKeyRequest { /// The user we requested the key from pub request_recipient: UserId, /// The unique id of the key request. pub request_id: Uuid, /// The info of the requested key. pub info: RequestedKeyInfo, /// Has the request been sent out. pub sent_out: bool, } impl OutgoingKeyRequest { fn to_request(&self, own_device_id: &DeviceId) -> Result { let content = RoomKeyRequestToDeviceEventContent { action: Action::Request, request_id: self.request_id.to_string(), requesting_device_id: own_device_id.to_owned(), body: Some(self.info.clone()), }; wrap_key_request_content(self.request_recipient.clone(), self.request_id, &content) } fn to_cancelation( &self, own_device_id: &DeviceId, ) -> Result { let content = RoomKeyRequestToDeviceEventContent { action: Action::CancelRequest, request_id: self.request_id.to_string(), requesting_device_id: own_device_id.to_owned(), body: None, }; let id = Uuid::new_v4(); wrap_key_request_content(self.request_recipient.clone(), id, &content) } } impl PartialEq for OutgoingKeyRequest { fn eq(&self, other: &Self) -> bool { self.request_id == other.request_id && self.info.algorithm == other.info.algorithm && self.info.room_id == other.info.room_id && self.info.session_id == other.info.session_id && self.info.sender_key == other.info.sender_key } } fn wrap_key_request_content( recipient: UserId, id: Uuid, content: &RoomKeyRequestToDeviceEventContent, ) -> Result { let mut messages = BTreeMap::new(); messages .entry(recipient) .or_insert_with(BTreeMap::new) .insert(DeviceIdOrAllDevices::AllDevices, to_raw_value(content)?); Ok(OutgoingRequest { request_id: id, request: Arc::new( ToDeviceRequest { event_type: EventType::RoomKeyRequest, txn_id: id, messages }.into(), ), }) } impl KeyRequestMachine { pub fn new( user_id: Arc, device_id: Arc, store: Store, outbound_group_sessions: GroupSessionCache, users_for_key_claim: Arc>>, ) -> Self { Self { user_id, device_id, store, outbound_group_sessions, outgoing_to_device_requests: DashMap::new().into(), incoming_key_requests: DashMap::new().into(), wait_queue: WaitQueue::new(), users_for_key_claim, } } /// Load stored outgoing requests that were not yet sent out. async fn load_outgoing_requests(&self) -> Result, CryptoStoreError> { self.store .get_unsent_key_requests() .await? .into_iter() .filter(|i| !i.sent_out) .map(|info| info.to_request(self.device_id()).map_err(CryptoStoreError::from)) .collect() } /// Our own user id. pub fn user_id(&self) -> &UserId { &self.user_id } /// Our own device id. pub fn device_id(&self) -> &DeviceId { &self.device_id } pub async fn outgoing_to_device_requests( &self, ) -> Result, CryptoStoreError> { let mut key_requests = self.load_outgoing_requests().await?; let key_forwards: Vec = self.outgoing_to_device_requests.iter().map(|i| i.value().clone()).collect(); key_requests.extend(key_forwards); Ok(key_requests) } /// Receive a room key request event. pub fn receive_incoming_key_request( &self, event: &ToDeviceEvent, ) { let sender = event.sender.clone(); let device_id = event.content.requesting_device_id.clone(); let request_id = event.content.request_id.clone(); self.incoming_key_requests.insert((sender, device_id, request_id), event.clone()); } /// Handle all the incoming key requests that are queued up and empty our /// key request queue. pub async fn collect_incoming_key_requests(&self) -> OlmResult> { let mut changed_sessions = Vec::new(); for item in self.incoming_key_requests.iter() { let event = item.value(); if let Some(s) = self.handle_key_request(event).await? { changed_sessions.push(s); } } self.incoming_key_requests.clear(); Ok(changed_sessions) } /// Store the key share request for later, once we get an Olm session with /// the given device [`retry_keyshare`](#method.retry_keyshare) should be /// called. fn handle_key_share_without_session( &self, device: Device, event: &ToDeviceEvent, ) { self.users_for_key_claim .entry(device.user_id().to_owned()) .or_insert_with(DashSet::new) .insert(device.device_id().into()); self.wait_queue.insert(&device, event); } /// Retry keyshares for a device that previously didn't have an Olm session /// with us. /// /// This should be only called if the given user/device got a new Olm /// session. /// /// # Arguments /// /// * `user_id` - The user id of the device that we created the Olm session /// with. /// /// * `device_id` - The device id of the device that got the Olm session. pub fn retry_keyshare(&self, user_id: &UserId, device_id: &DeviceId) { if let Entry::Occupied(e) = self.users_for_key_claim.entry(user_id.to_owned()) { e.get().remove(device_id); if e.get().is_empty() { e.remove(); } } for (key, event) in self.wait_queue.remove(user_id, device_id) { if !self.incoming_key_requests.contains_key(&key) { self.incoming_key_requests.insert(key, event); } } } /// Handle a single incoming key request. async fn handle_key_request( &self, event: &ToDeviceEvent, ) -> OlmResult> { // Some servers might send to-device events to ourselves if we send one // out using a wildcard instead of a specific device as a recipient. // // Check if we're the sender of this key request event and ignore it if // so. if &event.sender == self.user_id() && &*event.content.requesting_device_id == self.device_id() { return Ok(None); } let key_info = match &event.content.action { Action::Request => { if let Some(info) = &event.content.body { info } else { warn!( "Received a key request from {} {} with a request \ action, but no key info was found", event.sender, event.content.requesting_device_id ); return Ok(None); } } // We ignore cancellations here since there's nothing to serve. Action::CancelRequest => return Ok(None), action => { warn!("Unknown room key request action: {:?}", action); return Ok(None); } }; let session = self .store .get_inbound_group_session( &key_info.room_id, &key_info.sender_key, &key_info.session_id, ) .await?; let session = if let Some(s) = session { s } else { info!( "Received a key request from {} {} for an unknown inbound group session {}.", &event.sender, &event.content.requesting_device_id, &key_info.session_id ); return Ok(None); }; let device = self.store.get_device(&event.sender, &event.content.requesting_device_id).await?; if let Some(device) = device { match self.should_share_key(&device, &session).await { Err(e) => { info!( "Received a key request from {} {} that we won't serve: {}", device.user_id(), device.device_id(), e ); Ok(None) } Ok(message_index) => { info!( "Serving a key request for {} from {} {} with message_index {:?}.", key_info.session_id, device.user_id(), device.device_id(), message_index, ); match self.share_session(&session, &device, message_index).await { Ok(s) => Ok(Some(s)), Err(OlmError::MissingSession) => { info!( "Key request from {} {} is missing an Olm session, \ putting the request in the wait queue", device.user_id(), device.device_id() ); self.handle_key_share_without_session(device, event); Ok(None) } Err(e) => Err(e), } } } } else { warn!( "Received a key request from an unknown device {} {}.", &event.sender, &event.content.requesting_device_id ); self.store.update_tracked_user(&event.sender, true).await?; Ok(None) } } async fn share_session( &self, session: &InboundGroupSession, device: &Device, message_index: Option, ) -> OlmResult { let (used_session, content) = device.encrypt_session(session.clone(), message_index).await?; let id = Uuid::new_v4(); let mut messages = BTreeMap::new(); messages.entry(device.user_id().to_owned()).or_insert_with(BTreeMap::new).insert( DeviceIdOrAllDevices::DeviceId(device.device_id().into()), to_raw_value(&content)?, ); let request = OutgoingRequest { request_id: id, request: Arc::new( ToDeviceRequest { event_type: EventType::RoomEncrypted, txn_id: id, messages } .into(), ), }; self.outgoing_to_device_requests.insert(id, request); Ok(used_session) } /// Check if it's ok to share a session with the given device. /// /// The logic for this currently is as follows: /// /// * Share any session with our own devices as long as they are trusted. /// /// * Share with devices of other users only sessions that were meant to be /// shared with them in the first place, in other words if an outbound /// session still exists and the session was shared with that user/device /// pair. /// /// # Arguments /// /// * `device` - The device that is requesting a session from us. /// /// * `session` - The session that was requested to be shared. async fn should_share_key( &self, device: &Device, session: &InboundGroupSession, ) -> Result, KeyshareDecision> { let outbound_session = self .outbound_group_sessions .get_with_id(session.room_id(), session.session_id()) .await .ok() .flatten(); let own_device_check = || { if device.trust_state() { Ok(None) } else { Err(KeyshareDecision::UntrustedDevice) } }; // If we have a matching outbound session we can check the list of // users/devices that received the session, if it wasn't shared check if // it's our own device and if it's trusted. if let Some(outbound) = outbound_session { if let ShareState::Shared(message_index) = outbound.is_shared_with(device.user_id(), device.device_id()) { Ok(Some(message_index)) } else if device.user_id() == self.user_id() { own_device_check() } else { Err(KeyshareDecision::OutboundSessionNotShared) } // Else just check if it's one of our own devices that requested the key // and check if the device is trusted. } else if device.user_id() == self.user_id() { own_device_check() // Otherwise, there's not enough info to decide if we can safely share // the session. } else { Err(KeyshareDecision::MissingOutboundSession) } } /// Check if it's ok, or rather if it makes sense to automatically request /// a key from our other devices. /// /// # Arguments /// /// * `key_info` - The info of our key request containing information about /// the key we wish to request. async fn should_request_key( &self, key_info: &RequestedKeyInfo, ) -> Result { let request = self.store.get_key_request_by_info(&key_info).await?; // Don't send out duplicate requests, users can re-request them if they // think a second request might succeed. if request.is_none() { let devices = self.store.get_user_devices(self.user_id()).await?; // Devices will only respond to key requests if the devices are // verified, if the device isn't verified by us it's unlikely that // we're verified by them either. Don't request keys if there isn't // at least one verified device. if devices.is_any_verified() { Ok(true) } else { Ok(false) } } else { Ok(false) } } /// Create a new outgoing key request for the key with the given session id. /// /// This will queue up a new to-device request and store the key info so /// once we receive a forwarded room key we can check that it matches the /// key we requested. /// /// This method will return a cancel request and a new key request if the /// key was already requested, otherwise it will return just the key /// request. /// /// # Arguments /// /// * `room_id` - The id of the room where the key is used in. /// /// * `sender_key` - The curve25519 key of the sender that owns the key. /// /// * `session_id` - The id that uniquely identifies the session. pub async fn request_key( &self, room_id: &RoomId, sender_key: &str, session_id: &str, ) -> Result<(Option, OutgoingRequest), CryptoStoreError> { let key_info = RequestedKeyInfo { algorithm: EventEncryptionAlgorithm::MegolmV1AesSha2, room_id: room_id.to_owned(), sender_key: sender_key.to_owned(), session_id: session_id.to_owned(), }; let request = self.store.get_key_request_by_info(&key_info).await?; if let Some(request) = request { let cancel = request.to_cancelation(self.device_id())?; let request = request.to_request(self.device_id())?; Ok((Some(cancel), request)) } else { let request = self.request_key_helper(key_info).await?; Ok((None, request)) } } async fn request_key_helper( &self, key_info: RequestedKeyInfo, ) -> Result { info!("Creating new outgoing room key request {:#?}", key_info); let request = OutgoingKeyRequest { request_recipient: self.user_id().to_owned(), request_id: Uuid::new_v4(), info: key_info, sent_out: false, }; let outgoing_request = request.to_request(self.device_id())?; self.save_outgoing_key_info(request).await?; Ok(outgoing_request) } /// Create a new outgoing key request for the key with the given session id. /// /// This will queue up a new to-device request and store the key info so /// once we receive a forwarded room key we can check that it matches the /// key we requested. /// /// This does nothing if a request for this key has already been sent out. /// /// # Arguments /// * `room_id` - The id of the room where the key is used in. /// /// * `sender_key` - The curve25519 key of the sender that owns the key. /// /// * `session_id` - The id that uniquely identifies the session. pub async fn create_outgoing_key_request( &self, room_id: &RoomId, sender_key: &str, session_id: &str, ) -> Result<(), CryptoStoreError> { let key_info = RequestedKeyInfo { algorithm: EventEncryptionAlgorithm::MegolmV1AesSha2, room_id: room_id.to_owned(), sender_key: sender_key.to_owned(), session_id: session_id.to_owned(), }; if self.should_request_key(&key_info).await? { self.request_key_helper(key_info).await?; } Ok(()) } /// Save an outgoing key info. async fn save_outgoing_key_info( &self, info: OutgoingKeyRequest, ) -> Result<(), CryptoStoreError> { let mut changes = Changes::default(); changes.key_requests.push(info); self.store.save_changes(changes).await?; Ok(()) } /// Get an outgoing key info that matches the forwarded room key content. async fn get_key_info( &self, content: &ForwardedRoomKeyToDeviceEventContent, ) -> Result, CryptoStoreError> { let info = RequestedKeyInfo { algorithm: content.algorithm.clone(), room_id: content.room_id.clone(), sender_key: content.sender_key.clone(), session_id: content.session_id.clone(), }; self.store.get_key_request_by_info(&info).await } /// Delete the given outgoing key info. async fn delete_key_info(&self, info: &OutgoingKeyRequest) -> Result<(), CryptoStoreError> { self.store.delete_outgoing_key_request(info.request_id).await } /// Mark the outgoing request as sent. pub async fn mark_outgoing_request_as_sent(&self, id: Uuid) -> Result<(), CryptoStoreError> { let info = self.store.get_outgoing_key_request(id).await?; if let Some(mut info) = info { trace!("Marking outgoing key request as sent {:#?}", info); info.sent_out = true; self.save_outgoing_key_info(info).await?; } self.outgoing_to_device_requests.remove(&id); Ok(()) } /// Mark the given outgoing key info as done. /// /// This will queue up a request cancelation. async fn mark_as_done(&self, key_info: OutgoingKeyRequest) -> Result<(), CryptoStoreError> { // TODO perhaps only remove the key info if the first known index is 0. trace!("Successfully received a forwarded room key for {:#?}", key_info); self.outgoing_to_device_requests.remove(&key_info.request_id); // TODO return the key info instead of deleting it so the sync handler // can delete it in one transaction. self.delete_key_info(&key_info).await?; let request = key_info.to_cancelation(self.device_id())?; self.outgoing_to_device_requests.insert(request.request_id, request); Ok(()) } /// Receive a forwarded room key event. pub async fn receive_forwarded_room_key( &self, sender_key: &str, event: &mut ToDeviceEvent, ) -> Result<(Option, Option), CryptoStoreError> { let key_info = self.get_key_info(&event.content).await?; if let Some(info) = key_info { let session = InboundGroupSession::from_forwarded_key(sender_key, &mut event.content)?; let old_session = self .store .get_inbound_group_session( session.room_id(), &session.sender_key, session.session_id(), ) .await?; // If we have a previous session, check if we have a better version // and store the new one if so. let session = if let Some(old_session) = old_session { let first_old_index = old_session.first_known_index(); let first_index = session.first_known_index(); if first_old_index > first_index { self.mark_as_done(info).await?; Some(session) } else { None } // If we didn't have a previous session, store it. } else { self.mark_as_done(info).await?; Some(session) }; if let Some(s) = &session { info!( "Received a forwarded room key from {} for room {} with session id {}", event.sender, s.room_id(), s.session_id() ); } Ok((Some(AnyToDeviceEvent::ForwardedRoomKey(event.clone())), session)) } else { info!( "Received a forwarded room key from {}, but no key info was found.", event.sender, ); Ok((None, None)) } } } #[cfg(test)] mod test { use std::{convert::TryInto, sync::Arc}; use dashmap::DashMap; use matrix_sdk_common::{ api::r0::to_device::DeviceIdOrAllDevices, events::{ forwarded_room_key::ForwardedRoomKeyToDeviceEventContent, room::encrypted::EncryptedEventContent, room_key_request::RoomKeyRequestToDeviceEventContent, AnyToDeviceEvent, ToDeviceEvent, }, identifiers::{room_id, user_id, DeviceIdBox, RoomId, UserId}, locks::Mutex, }; use matrix_sdk_test::async_test; use super::{KeyRequestMachine, KeyshareDecision}; use crate::{ identities::{LocalTrust, ReadOnlyDevice}, olm::{Account, PrivateCrossSigningIdentity, ReadOnlyAccount}, session_manager::GroupSessionCache, store::{Changes, CryptoStore, MemoryStore, Store}, verification::VerificationMachine, }; fn alice_id() -> UserId { user_id!("@alice:example.org") } fn alice_device_id() -> DeviceIdBox { "JLAFKJWSCS".into() } fn bob_id() -> UserId { user_id!("@bob:example.org") } fn bob_device_id() -> DeviceIdBox { "ILMLKASTES".into() } fn alice2_device_id() -> DeviceIdBox { "ILMLKASTES".into() } fn room_id() -> RoomId { room_id!("!test:example.org") } fn account() -> ReadOnlyAccount { ReadOnlyAccount::new(&alice_id(), &alice_device_id()) } fn bob_account() -> ReadOnlyAccount { ReadOnlyAccount::new(&bob_id(), &bob_device_id()) } fn alice_2_account() -> ReadOnlyAccount { ReadOnlyAccount::new(&alice_id(), &alice2_device_id()) } fn bob_machine() -> KeyRequestMachine { let user_id = Arc::new(bob_id()); let account = ReadOnlyAccount::new(&user_id, &alice_device_id()); let store: Arc> = Arc::new(Box::new(MemoryStore::new())); let identity = Arc::new(Mutex::new(PrivateCrossSigningIdentity::empty(bob_id()))); let verification = VerificationMachine::new(account, identity.clone(), store.clone()); let store = Store::new(user_id.clone(), identity, store, verification); let session_cache = GroupSessionCache::new(store.clone()); KeyRequestMachine::new( user_id, Arc::new(bob_device_id()), store, session_cache, Arc::new(DashMap::new()), ) } async fn get_machine() -> KeyRequestMachine { let user_id = Arc::new(alice_id()); let account = ReadOnlyAccount::new(&user_id, &alice_device_id()); let device = ReadOnlyDevice::from_account(&account).await; let store: Arc> = Arc::new(Box::new(MemoryStore::new())); let identity = Arc::new(Mutex::new(PrivateCrossSigningIdentity::empty(alice_id()))); let verification = VerificationMachine::new(account, identity.clone(), store.clone()); let store = Store::new(user_id.clone(), identity, store, verification); store.save_devices(&[device]).await.unwrap(); let session_cache = GroupSessionCache::new(store.clone()); KeyRequestMachine::new( user_id, Arc::new(alice_device_id()), store, session_cache, Arc::new(DashMap::new()), ) } #[async_test] async fn create_machine() { let machine = get_machine().await; assert!(machine.outgoing_to_device_requests().await.unwrap().is_empty()); } #[async_test] async fn re_request_keys() { let machine = get_machine().await; let account = account(); let (_, session) = account.create_group_session_pair_with_defaults(&room_id()).await.unwrap(); assert!(machine.outgoing_to_device_requests().await.unwrap().is_empty()); let (cancel, request) = machine .request_key(session.room_id(), &session.sender_key, session.session_id()) .await .unwrap(); assert!(cancel.is_none()); machine.mark_outgoing_request_as_sent(request.request_id).await.unwrap(); let (cancel, _) = machine .request_key(session.room_id(), &session.sender_key, session.session_id()) .await .unwrap(); assert!(cancel.is_some()); } #[async_test] async fn create_key_request() { let machine = get_machine().await; let account = account(); let second_account = alice_2_account(); let alice_device = ReadOnlyDevice::from_account(&second_account).await; // We need a trusted device, otherwise we won't request keys alice_device.set_trust_state(LocalTrust::Verified); machine.store.save_devices(&[alice_device]).await.unwrap(); let (_, session) = account.create_group_session_pair_with_defaults(&room_id()).await.unwrap(); assert!(machine.outgoing_to_device_requests().await.unwrap().is_empty()); machine .create_outgoing_key_request( session.room_id(), &session.sender_key, session.session_id(), ) .await .unwrap(); assert!(!machine.outgoing_to_device_requests().await.unwrap().is_empty()); assert_eq!(machine.outgoing_to_device_requests().await.unwrap().len(), 1); machine .create_outgoing_key_request( session.room_id(), &session.sender_key, session.session_id(), ) .await .unwrap(); let requests = machine.outgoing_to_device_requests().await.unwrap(); assert_eq!(requests.len(), 1); let request = requests.get(0).unwrap(); machine.mark_outgoing_request_as_sent(request.request_id).await.unwrap(); assert!(machine.outgoing_to_device_requests().await.unwrap().is_empty()); } #[async_test] async fn receive_forwarded_key() { let machine = get_machine().await; let account = account(); let second_account = alice_2_account(); let alice_device = ReadOnlyDevice::from_account(&second_account).await; // We need a trusted device, otherwise we won't request keys alice_device.set_trust_state(LocalTrust::Verified); machine.store.save_devices(&[alice_device]).await.unwrap(); let (_, session) = account.create_group_session_pair_with_defaults(&room_id()).await.unwrap(); machine .create_outgoing_key_request( session.room_id(), &session.sender_key, session.session_id(), ) .await .unwrap(); let requests = machine.outgoing_to_device_requests().await.unwrap(); let request = requests.get(0).unwrap(); let id = request.request_id; machine.mark_outgoing_request_as_sent(id).await.unwrap(); let export = session.export_at_index(10).await; let content: ForwardedRoomKeyToDeviceEventContent = export.try_into().unwrap(); let mut event = ToDeviceEvent { sender: alice_id(), content }; assert!( machine .store .get_inbound_group_session( session.room_id(), &session.sender_key, session.session_id(), ) .await .unwrap() .is_none() ); let (_, first_session) = machine.receive_forwarded_room_key(&session.sender_key, &mut event).await.unwrap(); let first_session = first_session.unwrap(); assert_eq!(first_session.first_known_index(), 10); machine.store.save_inbound_group_sessions(&[first_session.clone()]).await.unwrap(); // Get the cancel request. let request = machine.outgoing_to_device_requests.iter().next().unwrap(); let id = request.request_id; drop(request); machine.mark_outgoing_request_as_sent(id).await.unwrap(); machine .create_outgoing_key_request( session.room_id(), &session.sender_key, session.session_id(), ) .await .unwrap(); let requests = machine.outgoing_to_device_requests().await.unwrap(); let request = &requests[0]; machine.mark_outgoing_request_as_sent(request.request_id).await.unwrap(); let export = session.export_at_index(15).await; let content: ForwardedRoomKeyToDeviceEventContent = export.try_into().unwrap(); let mut event = ToDeviceEvent { sender: alice_id(), content }; let (_, second_session) = machine.receive_forwarded_room_key(&session.sender_key, &mut event).await.unwrap(); assert!(second_session.is_none()); let export = session.export_at_index(0).await; let content: ForwardedRoomKeyToDeviceEventContent = export.try_into().unwrap(); let mut event = ToDeviceEvent { sender: alice_id(), content }; let (_, second_session) = machine.receive_forwarded_room_key(&session.sender_key, &mut event).await.unwrap(); assert_eq!(second_session.unwrap().first_known_index(), 0); } #[async_test] async fn should_share_key_test() { let machine = get_machine().await; let account = account(); let own_device = machine.store.get_device(&alice_id(), &alice_device_id()).await.unwrap().unwrap(); let (outbound, inbound) = account.create_group_session_pair_with_defaults(&room_id()).await.unwrap(); // We don't share keys with untrusted devices. assert_eq!( machine .should_share_key(&own_device, &inbound) .await .expect_err("Should not share with untrusted"), KeyshareDecision::UntrustedDevice ); own_device.set_trust_state(LocalTrust::Verified); // Now we do want to share the keys. assert!(machine.should_share_key(&own_device, &inbound).await.is_ok()); let bob_device = ReadOnlyDevice::from_account(&bob_account()).await; machine.store.save_devices(&[bob_device]).await.unwrap(); let bob_device = machine.store.get_device(&bob_id(), &bob_device_id()).await.unwrap().unwrap(); // We don't share sessions with other user's devices if no outbound // session was provided. assert_eq!( machine .should_share_key(&bob_device, &inbound) .await .expect_err("Should not share with other."), KeyshareDecision::MissingOutboundSession ); let mut changes = Changes::default(); changes.outbound_group_sessions.push(outbound.clone()); changes.inbound_group_sessions.push(inbound.clone()); machine.store.save_changes(changes).await.unwrap(); machine.outbound_group_sessions.insert(outbound.clone()); // We don't share sessions with other user's devices if the session // wasn't shared in the first place. assert_eq!( machine .should_share_key(&bob_device, &inbound) .await .expect_err("Should not share with other unless shared."), KeyshareDecision::OutboundSessionNotShared ); bob_device.set_trust_state(LocalTrust::Verified); // We don't share sessions with other user's devices if the session // wasn't shared in the first place even if the device is trusted. assert_eq!( machine .should_share_key(&bob_device, &inbound) .await .expect_err("Should not share with other unless shared."), KeyshareDecision::OutboundSessionNotShared ); // We now share the session, since it was shared before. outbound.mark_shared_with(bob_device.user_id(), bob_device.device_id()); assert!(machine.should_share_key(&bob_device, &inbound).await.is_ok()); // But we don't share some other session that doesn't match our outbound // session let (_, other_inbound) = account.create_group_session_pair_with_defaults(&room_id()).await.unwrap(); assert_eq!( machine .should_share_key(&bob_device, &other_inbound) .await .expect_err("Should not share with other unless shared."), KeyshareDecision::MissingOutboundSession ); } #[async_test] async fn key_share_cycle() { let alice_machine = get_machine().await; let alice_account = Account { inner: account(), store: alice_machine.store.clone() }; let bob_machine = bob_machine(); let bob_account = bob_account(); let second_account = alice_2_account(); let alice_device = ReadOnlyDevice::from_account(&second_account).await; // We need a trusted device, otherwise we won't request keys alice_device.set_trust_state(LocalTrust::Verified); alice_machine.store.save_devices(&[alice_device]).await.unwrap(); // Create Olm sessions for our two accounts. let (alice_session, bob_session) = alice_account.create_session_for(&bob_account).await; let alice_device = ReadOnlyDevice::from_account(&alice_account).await; let bob_device = ReadOnlyDevice::from_account(&bob_account).await; // Populate our stores with Olm sessions and a Megolm session. alice_machine.store.save_sessions(&[alice_session]).await.unwrap(); alice_machine.store.save_devices(&[bob_device]).await.unwrap(); bob_machine.store.save_sessions(&[bob_session]).await.unwrap(); bob_machine.store.save_devices(&[alice_device]).await.unwrap(); let (group_session, inbound_group_session) = bob_account.create_group_session_pair_with_defaults(&room_id()).await.unwrap(); bob_machine.store.save_inbound_group_sessions(&[inbound_group_session]).await.unwrap(); // Alice wants to request the outbound group session from bob. alice_machine .create_outgoing_key_request( &room_id(), bob_account.identity_keys.curve25519(), group_session.session_id(), ) .await .unwrap(); group_session.mark_shared_with(&alice_id(), &alice_device_id()); // Put the outbound session into bobs store. bob_machine.outbound_group_sessions.insert(group_session.clone()); // Get the request and convert it into a event. let requests = alice_machine.outgoing_to_device_requests().await.unwrap(); let request = &requests[0]; let id = request.request_id; let content = request .request .to_device() .unwrap() .messages .get(&alice_id()) .unwrap() .get(&DeviceIdOrAllDevices::AllDevices) .unwrap(); let content: RoomKeyRequestToDeviceEventContent = serde_json::from_str(content.get()).unwrap(); alice_machine.mark_outgoing_request_as_sent(id).await.unwrap(); let event = ToDeviceEvent { sender: alice_id(), content }; // Bob doesn't have any outgoing requests. assert!(bob_machine.outgoing_to_device_requests.is_empty()); // Receive the room key request from alice. bob_machine.receive_incoming_key_request(&event); bob_machine.collect_incoming_key_requests().await.unwrap(); // Now bob does have an outgoing request. assert!(!bob_machine.outgoing_to_device_requests.is_empty()); // Get the request and convert it to a encrypted to-device event. let requests = bob_machine.outgoing_to_device_requests().await.unwrap(); let request = &requests[0]; let id = request.request_id; let content = request .request .to_device() .unwrap() .messages .get(&alice_id()) .unwrap() .get(&DeviceIdOrAllDevices::DeviceId(alice_device_id())) .unwrap(); let content: EncryptedEventContent = serde_json::from_str(content.get()).unwrap(); bob_machine.mark_outgoing_request_as_sent(id).await.unwrap(); let event = ToDeviceEvent { sender: bob_id(), content }; // Check that alice doesn't have the session. assert!(alice_machine .store .get_inbound_group_session( &room_id(), &bob_account.identity_keys().curve25519(), group_session.session_id() ) .await .unwrap() .is_none()); let decrypted = alice_account.decrypt_to_device_event(&event).await.unwrap(); if let AnyToDeviceEvent::ForwardedRoomKey(mut e) = decrypted.event.deserialize().unwrap() { let (_, session) = alice_machine .receive_forwarded_room_key(&decrypted.sender_key, &mut e) .await .unwrap(); alice_machine.store.save_inbound_group_sessions(&[session.unwrap()]).await.unwrap(); } else { panic!("Invalid decrypted event type"); } // Check that alice now does have the session. let session = alice_machine .store .get_inbound_group_session( &room_id(), &decrypted.sender_key, group_session.session_id(), ) .await .unwrap() .unwrap(); assert_eq!(session.session_id(), group_session.session_id()) } #[async_test] async fn key_share_cycle_without_session() { let alice_machine = get_machine().await; let alice_account = Account { inner: account(), store: alice_machine.store.clone() }; let bob_machine = bob_machine(); let bob_account = bob_account(); let second_account = alice_2_account(); let alice_device = ReadOnlyDevice::from_account(&second_account).await; // We need a trusted device, otherwise we won't request keys alice_device.set_trust_state(LocalTrust::Verified); alice_machine.store.save_devices(&[alice_device]).await.unwrap(); // Create Olm sessions for our two accounts. let (alice_session, bob_session) = alice_account.create_session_for(&bob_account).await; let alice_device = ReadOnlyDevice::from_account(&alice_account).await; let bob_device = ReadOnlyDevice::from_account(&bob_account).await; // Populate our stores with Olm sessions and a Megolm session. alice_machine.store.save_devices(&[bob_device]).await.unwrap(); bob_machine.store.save_devices(&[alice_device]).await.unwrap(); let (group_session, inbound_group_session) = bob_account.create_group_session_pair_with_defaults(&room_id()).await.unwrap(); bob_machine.store.save_inbound_group_sessions(&[inbound_group_session]).await.unwrap(); // Alice wants to request the outbound group session from bob. alice_machine .create_outgoing_key_request( &room_id(), bob_account.identity_keys.curve25519(), group_session.session_id(), ) .await .unwrap(); group_session.mark_shared_with(&alice_id(), &alice_device_id()); // Put the outbound session into bobs store. bob_machine.outbound_group_sessions.insert(group_session.clone()); // Get the request and convert it into a event. let requests = alice_machine.outgoing_to_device_requests().await.unwrap(); let request = &requests[0]; let id = request.request_id; let content = request .request .to_device() .unwrap() .messages .get(&alice_id()) .unwrap() .get(&DeviceIdOrAllDevices::AllDevices) .unwrap(); let content: RoomKeyRequestToDeviceEventContent = serde_json::from_str(content.get()).unwrap(); alice_machine.mark_outgoing_request_as_sent(id).await.unwrap(); let event = ToDeviceEvent { sender: alice_id(), content }; // Bob doesn't have any outgoing requests. assert!(bob_machine.outgoing_to_device_requests().await.unwrap().is_empty()); assert!(bob_machine.users_for_key_claim.is_empty()); assert!(bob_machine.wait_queue.is_empty()); // Receive the room key request from alice. bob_machine.receive_incoming_key_request(&event); bob_machine.collect_incoming_key_requests().await.unwrap(); // Bob doens't have an outgoing requests since we're lacking a session. assert!(bob_machine.outgoing_to_device_requests().await.unwrap().is_empty()); assert!(!bob_machine.users_for_key_claim.is_empty()); assert!(!bob_machine.wait_queue.is_empty()); // We create a session now. alice_machine.store.save_sessions(&[alice_session]).await.unwrap(); bob_machine.store.save_sessions(&[bob_session]).await.unwrap(); bob_machine.retry_keyshare(&alice_id(), &alice_device_id()); assert!(bob_machine.users_for_key_claim.is_empty()); bob_machine.collect_incoming_key_requests().await.unwrap(); // Bob now has an outgoing requests. assert!(!bob_machine.outgoing_to_device_requests().await.unwrap().is_empty()); assert!(bob_machine.wait_queue.is_empty()); // Get the request and convert it to a encrypted to-device event. let requests = bob_machine.outgoing_to_device_requests().await.unwrap(); let request = &requests[0]; let id = request.request_id; let content = request .request .to_device() .unwrap() .messages .get(&alice_id()) .unwrap() .get(&DeviceIdOrAllDevices::DeviceId(alice_device_id())) .unwrap(); let content: EncryptedEventContent = serde_json::from_str(content.get()).unwrap(); bob_machine.mark_outgoing_request_as_sent(id).await.unwrap(); let event = ToDeviceEvent { sender: bob_id(), content }; // Check that alice doesn't have the session. assert!(alice_machine .store .get_inbound_group_session( &room_id(), &bob_account.identity_keys().curve25519(), group_session.session_id() ) .await .unwrap() .is_none()); let decrypted = alice_account.decrypt_to_device_event(&event).await.unwrap(); if let AnyToDeviceEvent::ForwardedRoomKey(mut e) = decrypted.event.deserialize().unwrap() { let (_, session) = alice_machine .receive_forwarded_room_key(&decrypted.sender_key, &mut e) .await .unwrap(); alice_machine.store.save_inbound_group_sessions(&[session.unwrap()]).await.unwrap(); } else { panic!("Invalid decrypted event type"); } // Check that alice now does have the session. let session = alice_machine .store .get_inbound_group_session( &room_id(), &decrypted.sender_key, group_session.session_id(), ) .await .unwrap() .unwrap(); assert_eq!(session.session_id(), group_session.session_id()) } }