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osu-lazer/osu.Game/Online/Spectator/SpectatorClient.cs
2024-04-03 17:32:02 +09:00

372 lines
13 KiB
C#

// Copyright (c) ppy Pty Ltd <contact@ppy.sh>. Licensed under the MIT Licence.
// See the LICENCE file in the repository root for full licence text.
using System;
using System.Collections.Generic;
using System.Diagnostics;
using System.Linq;
using System.Threading.Tasks;
using osu.Framework.Allocation;
using osu.Framework.Bindables;
using osu.Framework.Development;
using osu.Framework.Graphics;
using osu.Framework.Logging;
using osu.Game.Beatmaps;
using osu.Game.Online.API;
using osu.Game.Replays.Legacy;
using osu.Game.Rulesets.Replays;
using osu.Game.Rulesets.Replays.Types;
using osu.Game.Rulesets.Scoring;
using osu.Game.Scoring;
using osu.Game.Screens.Play;
namespace osu.Game.Online.Spectator
{
public abstract partial class SpectatorClient : Component, ISpectatorClient
{
/// <summary>
/// The maximum milliseconds between frame bundle sends.
/// </summary>
public const double TIME_BETWEEN_SENDS = 200;
/// <summary>
/// Whether the <see cref="SpectatorClient"/> is currently connected.
/// This is NOT thread safe and usage should be scheduled.
/// </summary>
public abstract IBindable<bool> IsConnected { get; }
/// <summary>
/// The states of all users currently being watched.
/// </summary>
public virtual IBindableDictionary<int, SpectatorState> WatchedUserStates => watchedUserStates;
/// <summary>
/// A global list of all players currently playing.
/// </summary>
public IBindableList<int> PlayingUsers => playingUsers;
/// <summary>
/// Whether the local user is playing.
/// </summary>
private bool isPlaying { get; set; }
/// <summary>
/// Called whenever new frames arrive from the server.
/// </summary>
public virtual event Action<int, FrameDataBundle>? OnNewFrames;
/// <summary>
/// Called whenever a user starts a play session, or immediately if the user is being watched and currently in a play session.
/// </summary>
public event Action<int, SpectatorState>? OnUserBeganPlaying;
/// <summary>
/// Called whenever a user finishes a play session.
/// </summary>
public event Action<int, SpectatorState>? OnUserFinishedPlaying;
/// <summary>
/// Called whenever a user-submitted score has been fully processed.
/// </summary>
public event Action<int, long>? OnUserScoreProcessed;
/// <summary>
/// Invoked just prior to disconnection requested by the server via <see cref="IStatefulUserHubClient.DisconnectRequested"/>.
/// </summary>
public event Action? Disconnecting;
/// <summary>
/// A dictionary containing all users currently being watched, with the number of watching components for each user.
/// </summary>
private readonly Dictionary<int, int> watchedUsersRefCounts = new Dictionary<int, int>();
private readonly BindableDictionary<int, SpectatorState> watchedUserStates = new BindableDictionary<int, SpectatorState>();
private readonly BindableList<int> playingUsers = new BindableList<int>();
private readonly SpectatorState currentState = new SpectatorState();
private IBeatmap? currentBeatmap;
private Score? currentScore;
private long? currentScoreToken;
private ScoreProcessor? currentScoreProcessor;
private readonly Queue<FrameDataBundle> pendingFrameBundles = new Queue<FrameDataBundle>();
private readonly Queue<LegacyReplayFrame> pendingFrames = new Queue<LegacyReplayFrame>();
private double lastPurgeTime;
private Task? lastSend;
private const int max_pending_frames = 30;
[BackgroundDependencyLoader]
private void load()
{
IsConnected.BindValueChanged(connected => Schedule(() =>
{
if (connected.NewValue)
{
// get all the users that were previously being watched
var users = new Dictionary<int, int>(watchedUsersRefCounts);
watchedUsersRefCounts.Clear();
// resubscribe to watched users.
foreach ((int user, int watchers) in users)
{
for (int i = 0; i < watchers; i++)
WatchUser(user);
}
// re-send state in case it wasn't received
if (isPlaying)
// TODO: this is likely sent out of order after a reconnect scenario. needs further consideration.
BeginPlayingInternal(currentScoreToken, currentState);
}
else
{
playingUsers.Clear();
watchedUserStates.Clear();
}
}), true);
}
Task ISpectatorClient.UserBeganPlaying(int userId, SpectatorState state)
{
Schedule(() =>
{
if (!playingUsers.Contains(userId))
playingUsers.Add(userId);
if (watchedUsersRefCounts.ContainsKey(userId))
watchedUserStates[userId] = state;
OnUserBeganPlaying?.Invoke(userId, state);
});
return Task.CompletedTask;
}
Task ISpectatorClient.UserFinishedPlaying(int userId, SpectatorState state)
{
Schedule(() =>
{
playingUsers.Remove(userId);
if (watchedUsersRefCounts.ContainsKey(userId))
watchedUserStates[userId] = state;
OnUserFinishedPlaying?.Invoke(userId, state);
});
return Task.CompletedTask;
}
Task ISpectatorClient.UserSentFrames(int userId, FrameDataBundle data)
{
if (data.Frames.Count > 0)
data.Frames[^1].Header = data.Header;
Schedule(() => OnNewFrames?.Invoke(userId, data));
return Task.CompletedTask;
}
Task ISpectatorClient.UserScoreProcessed(int userId, long scoreId)
{
Schedule(() => OnUserScoreProcessed?.Invoke(userId, scoreId));
return Task.CompletedTask;
}
Task IStatefulUserHubClient.DisconnectRequested()
{
Schedule(() => DisconnectInternal());
return Task.CompletedTask;
}
public void BeginPlaying(long? scoreToken, GameplayState state, Score score)
{
// This schedule is only here to match the one below in `EndPlaying`.
Schedule(() =>
{
if (isPlaying)
throw new InvalidOperationException($"Cannot invoke {nameof(BeginPlaying)} when already playing");
isPlaying = true;
// transfer state at point of beginning play
currentState.BeatmapID = score.ScoreInfo.BeatmapInfo!.OnlineID;
currentState.RulesetID = score.ScoreInfo.RulesetID;
currentState.Mods = score.ScoreInfo.Mods.Select(m => new APIMod(m)).ToArray();
currentState.State = SpectatedUserState.Playing;
currentState.MaximumStatistics = state.ScoreProcessor.MaximumStatistics;
currentBeatmap = state.Beatmap;
currentScore = score;
currentScoreToken = scoreToken;
currentScoreProcessor = state.ScoreProcessor;
BeginPlayingInternal(currentScoreToken, currentState);
});
}
public void HandleFrame(ReplayFrame frame) => Schedule(() =>
{
if (!isPlaying)
{
Logger.Log($"Frames arrived at {nameof(SpectatorClient)} outside of gameplay scope and will be ignored.");
return;
}
if (frame is IConvertibleReplayFrame convertible)
{
Debug.Assert(currentBeatmap != null);
pendingFrames.Enqueue(convertible.ToLegacy(currentBeatmap));
}
if (pendingFrames.Count > max_pending_frames)
purgePendingFrames();
});
public void EndPlaying(GameplayState state)
{
// This method is most commonly called via Dispose(), which is can be asynchronous (via the AsyncDisposalQueue).
// We probably need to find a better way to handle this...
Schedule(() =>
{
if (!isPlaying)
return;
// Disposal can take some time, leading to EndPlaying potentially being called after a future play session.
// Account for this by ensuring the score of the current play matches the one in the provided state.
if (currentScore != state.Score)
return;
if (pendingFrames.Count > 0)
purgePendingFrames();
isPlaying = false;
currentBeatmap = null;
currentScore = null;
currentScoreProcessor = null;
currentScoreToken = null;
if (state.HasPassed)
currentState.State = SpectatedUserState.Passed;
else if (state.HasFailed)
currentState.State = SpectatedUserState.Failed;
else
currentState.State = SpectatedUserState.Quit;
EndPlayingInternal(currentState);
});
}
public virtual void WatchUser(int userId)
{
Debug.Assert(ThreadSafety.IsUpdateThread);
if (!watchedUsersRefCounts.TryAdd(userId, 1))
{
watchedUsersRefCounts[userId]++;
return;
}
WatchUserInternal(userId);
}
public void StopWatchingUser(int userId)
{
// This method is most commonly called via Dispose(), which is asynchronous.
// Todo: This should not be a thing, but requires framework changes.
Schedule(() =>
{
if (watchedUsersRefCounts.TryGetValue(userId, out int watchers) && watchers > 1)
{
watchedUsersRefCounts[userId]--;
return;
}
watchedUsersRefCounts.Remove(userId);
watchedUserStates.Remove(userId);
StopWatchingUserInternal(userId);
});
}
protected abstract Task BeginPlayingInternal(long? scoreToken, SpectatorState state);
protected abstract Task SendFramesInternal(FrameDataBundle bundle);
protected abstract Task EndPlayingInternal(SpectatorState state);
protected abstract Task WatchUserInternal(int userId);
protected abstract Task StopWatchingUserInternal(int userId);
protected virtual Task DisconnectInternal()
{
Disconnecting?.Invoke();
return Task.CompletedTask;
}
protected override void Update()
{
base.Update();
if (pendingFrames.Count > 0 && Time.Current - lastPurgeTime > TIME_BETWEEN_SENDS)
purgePendingFrames();
}
private void purgePendingFrames()
{
if (pendingFrames.Count == 0)
return;
Debug.Assert(currentScore != null);
Debug.Assert(currentScoreProcessor != null);
var frames = pendingFrames.ToArray();
var bundle = new FrameDataBundle(currentScore.ScoreInfo, currentScoreProcessor, frames);
pendingFrames.Clear();
lastPurgeTime = Time.Current;
pendingFrameBundles.Enqueue(bundle);
sendNextBundleIfRequired();
}
private void sendNextBundleIfRequired()
{
Debug.Assert(ThreadSafety.IsUpdateThread);
if (lastSend?.IsCompleted == false)
return;
if (!pendingFrameBundles.TryPeek(out var bundle))
return;
TaskCompletionSource<bool> tcs = new TaskCompletionSource<bool>();
lastSend = tcs.Task;
SendFramesInternal(bundle).ContinueWith(t =>
{
// Handle exception outside of `Schedule` to ensure it doesn't go unobserved.
bool wasSuccessful = t.Exception == null;
return Schedule(() =>
{
// If the last bundle send wasn't successful, try again without dequeuing.
if (wasSuccessful)
pendingFrameBundles.Dequeue();
tcs.SetResult(wasSuccessful);
sendNextBundleIfRequired();
});
});
}
}
}