use crate::{ rpc::RECONNECT_TIMEOUT, tests::{room_participants, RoomParticipants, TestServer}, }; use call::ActiveCall; use channel::{ChannelId, ChannelMembership, ChannelStore}; use client::User; use gpui::{executor::Deterministic, ModelHandle, TestAppContext}; use rpc::{proto, RECEIVE_TIMEOUT}; use std::sync::Arc; #[gpui::test] async fn test_core_channels( deterministic: Arc, cx_a: &mut TestAppContext, cx_b: &mut TestAppContext, ) { deterministic.forbid_parking(); let mut server = TestServer::start(&deterministic).await; let client_a = server.create_client(cx_a, "user_a").await; let client_b = server.create_client(cx_b, "user_b").await; let channel_a_id = client_a .channel_store() .update(cx_a, |channel_store, cx| { channel_store.create_channel("channel-a", None, cx) }) .await .unwrap(); let channel_b_id = client_a .channel_store() .update(cx_a, |channel_store, cx| { channel_store.create_channel("channel-b", Some(channel_a_id), cx) }) .await .unwrap(); deterministic.run_until_parked(); assert_channels( client_a.channel_store(), cx_a, &[ ExpectedChannel { id: channel_a_id, name: "channel-a".to_string(), depth: 0, user_is_admin: true, }, ExpectedChannel { id: channel_b_id, name: "channel-b".to_string(), depth: 1, user_is_admin: true, }, ], ); client_b.channel_store().read_with(cx_b, |channels, _| { assert!(channels.channels().collect::>().is_empty()) }); // Invite client B to channel A as client A. client_a .channel_store() .update(cx_a, |store, cx| { assert!(!store.has_pending_channel_invite(channel_a_id, client_b.user_id().unwrap())); let invite = store.invite_member(channel_a_id, client_b.user_id().unwrap(), false, cx); // Make sure we're synchronously storing the pending invite assert!(store.has_pending_channel_invite(channel_a_id, client_b.user_id().unwrap())); invite }) .await .unwrap(); // Client A sees that B has been invited. deterministic.run_until_parked(); assert_channel_invitations( client_b.channel_store(), cx_b, &[ExpectedChannel { id: channel_a_id, name: "channel-a".to_string(), depth: 0, user_is_admin: false, }], ); let members = client_a .channel_store() .update(cx_a, |store, cx| { assert!(!store.has_pending_channel_invite(channel_a_id, client_b.user_id().unwrap())); store.get_channel_member_details(channel_a_id, cx) }) .await .unwrap(); assert_members_eq( &members, &[ ( client_a.user_id().unwrap(), true, proto::channel_member::Kind::Member, ), ( client_b.user_id().unwrap(), false, proto::channel_member::Kind::Invitee, ), ], ); // Client B accepts the invitation. client_b .channel_store() .update(cx_b, |channels, _| { channels.respond_to_channel_invite(channel_a_id, true) }) .await .unwrap(); deterministic.run_until_parked(); // Client B now sees that they are a member of channel A and its existing subchannels. assert_channel_invitations(client_b.channel_store(), cx_b, &[]); assert_channels( client_b.channel_store(), cx_b, &[ ExpectedChannel { id: channel_a_id, name: "channel-a".to_string(), user_is_admin: false, depth: 0, }, ExpectedChannel { id: channel_b_id, name: "channel-b".to_string(), user_is_admin: false, depth: 1, }, ], ); let channel_c_id = client_a .channel_store() .update(cx_a, |channel_store, cx| { channel_store.create_channel("channel-c", Some(channel_b_id), cx) }) .await .unwrap(); deterministic.run_until_parked(); assert_channels( client_b.channel_store(), cx_b, &[ ExpectedChannel { id: channel_a_id, name: "channel-a".to_string(), user_is_admin: false, depth: 0, }, ExpectedChannel { id: channel_b_id, name: "channel-b".to_string(), user_is_admin: false, depth: 1, }, ExpectedChannel { id: channel_c_id, name: "channel-c".to_string(), user_is_admin: false, depth: 2, }, ], ); // Update client B's membership to channel A to be an admin. client_a .channel_store() .update(cx_a, |store, cx| { store.set_member_admin(channel_a_id, client_b.user_id().unwrap(), true, cx) }) .await .unwrap(); deterministic.run_until_parked(); // Observe that client B is now an admin of channel A, and that // their admin priveleges extend to subchannels of channel A. assert_channel_invitations(client_b.channel_store(), cx_b, &[]); assert_channels( client_b.channel_store(), cx_b, &[ ExpectedChannel { id: channel_a_id, name: "channel-a".to_string(), depth: 0, user_is_admin: true, }, ExpectedChannel { id: channel_b_id, name: "channel-b".to_string(), depth: 1, user_is_admin: true, }, ExpectedChannel { id: channel_c_id, name: "channel-c".to_string(), depth: 2, user_is_admin: true, }, ], ); // Client A deletes the channel, deletion also deletes subchannels. client_a .channel_store() .update(cx_a, |channel_store, _| { channel_store.remove_channel(channel_b_id) }) .await .unwrap(); deterministic.run_until_parked(); assert_channels( client_a.channel_store(), cx_a, &[ExpectedChannel { id: channel_a_id, name: "channel-a".to_string(), depth: 0, user_is_admin: true, }], ); assert_channels( client_b.channel_store(), cx_b, &[ExpectedChannel { id: channel_a_id, name: "channel-a".to_string(), depth: 0, user_is_admin: true, }], ); // Remove client B client_a .channel_store() .update(cx_a, |channel_store, cx| { channel_store.remove_member(channel_a_id, client_b.user_id().unwrap(), cx) }) .await .unwrap(); deterministic.run_until_parked(); // Client A still has their channel assert_channels( client_a.channel_store(), cx_a, &[ExpectedChannel { id: channel_a_id, name: "channel-a".to_string(), depth: 0, user_is_admin: true, }], ); // Client B no longer has access to the channel assert_channels(client_b.channel_store(), cx_b, &[]); // When disconnected, client A sees no channels. server.forbid_connections(); server.disconnect_client(client_a.peer_id().unwrap()); deterministic.advance_clock(RECEIVE_TIMEOUT + RECONNECT_TIMEOUT); assert_channels(client_a.channel_store(), cx_a, &[]); server.allow_connections(); deterministic.advance_clock(RECEIVE_TIMEOUT + RECONNECT_TIMEOUT); assert_channels( client_a.channel_store(), cx_a, &[ExpectedChannel { id: channel_a_id, name: "channel-a".to_string(), depth: 0, user_is_admin: true, }], ); } #[track_caller] fn assert_participants_eq(participants: &[Arc], expected_partitipants: &[u64]) { assert_eq!( participants.iter().map(|p| p.id).collect::>(), expected_partitipants ); } #[track_caller] fn assert_members_eq( members: &[ChannelMembership], expected_members: &[(u64, bool, proto::channel_member::Kind)], ) { assert_eq!( members .iter() .map(|member| (member.user.id, member.admin, member.kind)) .collect::>(), expected_members ); } #[gpui::test] async fn test_joining_channel_ancestor_member( deterministic: Arc, cx_a: &mut TestAppContext, cx_b: &mut TestAppContext, ) { deterministic.forbid_parking(); let mut server = TestServer::start(&deterministic).await; let client_a = server.create_client(cx_a, "user_a").await; let client_b = server.create_client(cx_b, "user_b").await; let parent_id = server .make_channel("parent", (&client_a, cx_a), &mut [(&client_b, cx_b)]) .await; let sub_id = client_a .channel_store() .update(cx_a, |channel_store, cx| { channel_store.create_channel("sub_channel", Some(parent_id), cx) }) .await .unwrap(); let active_call_b = cx_b.read(ActiveCall::global); assert!(active_call_b .update(cx_b, |active_call, cx| active_call.join_channel(sub_id, cx)) .await .is_ok()); } #[gpui::test] async fn test_channel_room( deterministic: Arc, cx_a: &mut TestAppContext, cx_b: &mut TestAppContext, cx_c: &mut TestAppContext, ) { deterministic.forbid_parking(); let mut server = TestServer::start(&deterministic).await; let client_a = server.create_client(cx_a, "user_a").await; let client_b = server.create_client(cx_b, "user_b").await; let client_c = server.create_client(cx_c, "user_c").await; let zed_id = server .make_channel( "zed", (&client_a, cx_a), &mut [(&client_b, cx_b), (&client_c, cx_c)], ) .await; let active_call_a = cx_a.read(ActiveCall::global); let active_call_b = cx_b.read(ActiveCall::global); active_call_a .update(cx_a, |active_call, cx| active_call.join_channel(zed_id, cx)) .await .unwrap(); // Give everyone a chance to observe user A joining deterministic.run_until_parked(); client_a.channel_store().read_with(cx_a, |channels, _| { assert_participants_eq( channels.channel_participants(zed_id), &[client_a.user_id().unwrap()], ); }); assert_channels( client_b.channel_store(), cx_b, &[ExpectedChannel { id: zed_id, name: "zed".to_string(), depth: 0, user_is_admin: false, }], ); client_b.channel_store().read_with(cx_b, |channels, _| { assert_participants_eq( channels.channel_participants(zed_id), &[client_a.user_id().unwrap()], ); }); client_c.channel_store().read_with(cx_c, |channels, _| { assert_participants_eq( channels.channel_participants(zed_id), &[client_a.user_id().unwrap()], ); }); active_call_b .update(cx_b, |active_call, cx| active_call.join_channel(zed_id, cx)) .await .unwrap(); deterministic.run_until_parked(); client_a.channel_store().read_with(cx_a, |channels, _| { assert_participants_eq( channels.channel_participants(zed_id), &[client_a.user_id().unwrap(), client_b.user_id().unwrap()], ); }); client_b.channel_store().read_with(cx_b, |channels, _| { assert_participants_eq( channels.channel_participants(zed_id), &[client_a.user_id().unwrap(), client_b.user_id().unwrap()], ); }); client_c.channel_store().read_with(cx_c, |channels, _| { assert_participants_eq( channels.channel_participants(zed_id), &[client_a.user_id().unwrap(), client_b.user_id().unwrap()], ); }); let room_a = active_call_a.read_with(cx_a, |call, _| call.room().unwrap().clone()); room_a.read_with(cx_a, |room, _| assert!(room.is_connected())); assert_eq!( room_participants(&room_a, cx_a), RoomParticipants { remote: vec!["user_b".to_string()], pending: vec![] } ); let room_b = active_call_b.read_with(cx_b, |call, _| call.room().unwrap().clone()); room_b.read_with(cx_b, |room, _| assert!(room.is_connected())); assert_eq!( room_participants(&room_b, cx_b), RoomParticipants { remote: vec!["user_a".to_string()], pending: vec![] } ); // Make sure that leaving and rejoining works active_call_a .update(cx_a, |active_call, cx| active_call.hang_up(cx)) .await .unwrap(); deterministic.run_until_parked(); client_a.channel_store().read_with(cx_a, |channels, _| { assert_participants_eq( channels.channel_participants(zed_id), &[client_b.user_id().unwrap()], ); }); client_b.channel_store().read_with(cx_b, |channels, _| { assert_participants_eq( channels.channel_participants(zed_id), &[client_b.user_id().unwrap()], ); }); client_c.channel_store().read_with(cx_c, |channels, _| { assert_participants_eq( channels.channel_participants(zed_id), &[client_b.user_id().unwrap()], ); }); active_call_b .update(cx_b, |active_call, cx| active_call.hang_up(cx)) .await .unwrap(); deterministic.run_until_parked(); client_a.channel_store().read_with(cx_a, |channels, _| { assert_participants_eq(channels.channel_participants(zed_id), &[]); }); client_b.channel_store().read_with(cx_b, |channels, _| { assert_participants_eq(channels.channel_participants(zed_id), &[]); }); client_c.channel_store().read_with(cx_c, |channels, _| { assert_participants_eq(channels.channel_participants(zed_id), &[]); }); active_call_a .update(cx_a, |active_call, cx| active_call.join_channel(zed_id, cx)) .await .unwrap(); active_call_b .update(cx_b, |active_call, cx| active_call.join_channel(zed_id, cx)) .await .unwrap(); deterministic.run_until_parked(); let room_a = active_call_a.read_with(cx_a, |call, _| call.room().unwrap().clone()); room_a.read_with(cx_a, |room, _| assert!(room.is_connected())); assert_eq!( room_participants(&room_a, cx_a), RoomParticipants { remote: vec!["user_b".to_string()], pending: vec![] } ); let room_b = active_call_b.read_with(cx_b, |call, _| call.room().unwrap().clone()); room_b.read_with(cx_b, |room, _| assert!(room.is_connected())); assert_eq!( room_participants(&room_b, cx_b), RoomParticipants { remote: vec!["user_a".to_string()], pending: vec![] } ); } #[gpui::test] async fn test_channel_jumping(deterministic: Arc, cx_a: &mut TestAppContext) { deterministic.forbid_parking(); let mut server = TestServer::start(&deterministic).await; let client_a = server.create_client(cx_a, "user_a").await; let zed_id = server.make_channel("zed", (&client_a, cx_a), &mut []).await; let rust_id = server .make_channel("rust", (&client_a, cx_a), &mut []) .await; let active_call_a = cx_a.read(ActiveCall::global); active_call_a .update(cx_a, |active_call, cx| active_call.join_channel(zed_id, cx)) .await .unwrap(); // Give everything a chance to observe user A joining deterministic.run_until_parked(); client_a.channel_store().read_with(cx_a, |channels, _| { assert_participants_eq( channels.channel_participants(zed_id), &[client_a.user_id().unwrap()], ); assert_participants_eq(channels.channel_participants(rust_id), &[]); }); active_call_a .update(cx_a, |active_call, cx| { active_call.join_channel(rust_id, cx) }) .await .unwrap(); deterministic.run_until_parked(); client_a.channel_store().read_with(cx_a, |channels, _| { assert_participants_eq(channels.channel_participants(zed_id), &[]); assert_participants_eq( channels.channel_participants(rust_id), &[client_a.user_id().unwrap()], ); }); } #[gpui::test] async fn test_permissions_update_while_invited( deterministic: Arc, cx_a: &mut TestAppContext, cx_b: &mut TestAppContext, ) { deterministic.forbid_parking(); let mut server = TestServer::start(&deterministic).await; let client_a = server.create_client(cx_a, "user_a").await; let client_b = server.create_client(cx_b, "user_b").await; let rust_id = server .make_channel("rust", (&client_a, cx_a), &mut []) .await; client_a .channel_store() .update(cx_a, |channel_store, cx| { channel_store.invite_member(rust_id, client_b.user_id().unwrap(), false, cx) }) .await .unwrap(); deterministic.run_until_parked(); assert_channel_invitations( client_b.channel_store(), cx_b, &[ExpectedChannel { depth: 0, id: rust_id, name: "rust".to_string(), user_is_admin: false, }], ); assert_channels(client_b.channel_store(), cx_b, &[]); // Update B's invite before they've accepted it client_a .channel_store() .update(cx_a, |channel_store, cx| { channel_store.set_member_admin(rust_id, client_b.user_id().unwrap(), true, cx) }) .await .unwrap(); deterministic.run_until_parked(); assert_channel_invitations( client_b.channel_store(), cx_b, &[ExpectedChannel { depth: 0, id: rust_id, name: "rust".to_string(), user_is_admin: false, }], ); assert_channels(client_b.channel_store(), cx_b, &[]); } #[gpui::test] async fn test_channel_rename( deterministic: Arc, cx_a: &mut TestAppContext, cx_b: &mut TestAppContext, ) { deterministic.forbid_parking(); let mut server = TestServer::start(&deterministic).await; let client_a = server.create_client(cx_a, "user_a").await; let client_b = server.create_client(cx_b, "user_b").await; let rust_id = server .make_channel("rust", (&client_a, cx_a), &mut [(&client_b, cx_b)]) .await; // Rename the channel client_a .channel_store() .update(cx_a, |channel_store, cx| { channel_store.rename(rust_id, "#rust-archive", cx) }) .await .unwrap(); deterministic.run_until_parked(); // Client A sees the channel with its new name. assert_channels( client_a.channel_store(), cx_a, &[ExpectedChannel { depth: 0, id: rust_id, name: "rust-archive".to_string(), user_is_admin: true, }], ); // Client B sees the channel with its new name. assert_channels( client_b.channel_store(), cx_b, &[ExpectedChannel { depth: 0, id: rust_id, name: "rust-archive".to_string(), user_is_admin: false, }], ); } #[gpui::test] async fn test_call_from_channel( deterministic: Arc, cx_a: &mut TestAppContext, cx_b: &mut TestAppContext, cx_c: &mut TestAppContext, ) { deterministic.forbid_parking(); let mut server = TestServer::start(&deterministic).await; let client_a = server.create_client(cx_a, "user_a").await; let client_b = server.create_client(cx_b, "user_b").await; let client_c = server.create_client(cx_c, "user_c").await; server .make_contacts(&mut [(&client_a, cx_a), (&client_b, cx_b)]) .await; let channel_id = server .make_channel( "x", (&client_a, cx_a), &mut [(&client_b, cx_b), (&client_c, cx_c)], ) .await; let active_call_a = cx_a.read(ActiveCall::global); let active_call_b = cx_b.read(ActiveCall::global); active_call_a .update(cx_a, |call, cx| call.join_channel(channel_id, cx)) .await .unwrap(); // Client A calls client B while in the channel. active_call_a .update(cx_a, |call, cx| { call.invite(client_b.user_id().unwrap(), None, cx) }) .await .unwrap(); // Client B accepts the call. deterministic.run_until_parked(); active_call_b .update(cx_b, |call, cx| call.accept_incoming(cx)) .await .unwrap(); // Client B sees that they are now in the channel deterministic.run_until_parked(); active_call_b.read_with(cx_b, |call, cx| { assert_eq!(call.channel_id(cx), Some(channel_id)); }); client_b.channel_store().read_with(cx_b, |channels, _| { assert_participants_eq( channels.channel_participants(channel_id), &[client_a.user_id().unwrap(), client_b.user_id().unwrap()], ); }); // Clients A and C also see that client B is in the channel. client_a.channel_store().read_with(cx_a, |channels, _| { assert_participants_eq( channels.channel_participants(channel_id), &[client_a.user_id().unwrap(), client_b.user_id().unwrap()], ); }); client_c.channel_store().read_with(cx_c, |channels, _| { assert_participants_eq( channels.channel_participants(channel_id), &[client_a.user_id().unwrap(), client_b.user_id().unwrap()], ); }); } #[gpui::test] async fn test_lost_channel_creation( deterministic: Arc, cx_a: &mut TestAppContext, cx_b: &mut TestAppContext, ) { deterministic.forbid_parking(); let mut server = TestServer::start(&deterministic).await; let client_a = server.create_client(cx_a, "user_a").await; let client_b = server.create_client(cx_b, "user_b").await; server .make_contacts(&mut [(&client_a, cx_a), (&client_b, cx_b)]) .await; let channel_id = server.make_channel("x", (&client_a, cx_a), &mut []).await; // Invite a member client_a .channel_store() .update(cx_a, |channel_store, cx| { channel_store.invite_member(channel_id, client_b.user_id().unwrap(), false, cx) }) .await .unwrap(); deterministic.run_until_parked(); // Sanity check, B has the invitation assert_channel_invitations( client_b.channel_store(), cx_b, &[ExpectedChannel { depth: 0, id: channel_id, name: "x".to_string(), user_is_admin: false, }], ); // A creates a subchannel while the invite is still pending. let subchannel_id = client_a .channel_store() .update(cx_a, |channel_store, cx| { channel_store.create_channel("subchannel", Some(channel_id), cx) }) .await .unwrap(); deterministic.run_until_parked(); // Make sure A sees their new channel assert_channels( client_a.channel_store(), cx_a, &[ ExpectedChannel { depth: 0, id: channel_id, name: "x".to_string(), user_is_admin: true, }, ExpectedChannel { depth: 1, id: subchannel_id, name: "subchannel".to_string(), user_is_admin: true, }, ], ); // Client B accepts the invite client_b .channel_store() .update(cx_b, |channel_store, _| { channel_store.respond_to_channel_invite(channel_id, true) }) .await .unwrap(); deterministic.run_until_parked(); // Client B should now see the channel assert_channels( client_b.channel_store(), cx_b, &[ ExpectedChannel { depth: 0, id: channel_id, name: "x".to_string(), user_is_admin: false, }, ExpectedChannel { depth: 1, id: subchannel_id, name: "subchannel".to_string(), user_is_admin: false, }, ], ); } #[derive(Debug, PartialEq)] struct ExpectedChannel { depth: usize, id: ChannelId, name: String, user_is_admin: bool, } #[track_caller] fn assert_channel_invitations( channel_store: &ModelHandle, cx: &TestAppContext, expected_channels: &[ExpectedChannel], ) { let actual = channel_store.read_with(cx, |store, _| { store .channel_invitations() .iter() .map(|channel| ExpectedChannel { depth: 0, name: channel.name.clone(), id: channel.id, user_is_admin: store.is_user_admin(channel.id), }) .collect::>() }); assert_eq!(actual, expected_channels); } #[track_caller] fn assert_channels( channel_store: &ModelHandle, cx: &TestAppContext, expected_channels: &[ExpectedChannel], ) { let actual = channel_store.read_with(cx, |store, _| { store .channels() .map(|(depth, channel)| ExpectedChannel { depth, name: channel.name.clone(), id: channel.id, user_is_admin: store.is_user_admin(channel.id), }) .collect::>() }); assert_eq!(actual, expected_channels); }