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osu-lazer/osu.Game/Screens/OnlinePlay/Multiplayer/Spectate/SpectatorSyncManager.cs

205 lines
7.3 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.Linq;
using osu.Framework.Graphics;
using osu.Framework.Logging;
using osu.Game.Screens.Play;
namespace osu.Game.Screens.OnlinePlay.Multiplayer.Spectate
{
/// <summary>
/// Manages the synchronisation between one or more <see cref="SpectatorPlayerClock"/>s in relation to a master clock.
/// </summary>
public partial class SpectatorSyncManager : Component
{
/// <summary>
/// The offset from the master clock to which player clocks should remain within to be considered in-sync.
/// </summary>
public const double SYNC_TARGET = 16;
/// <summary>
/// The offset from the master clock at which player clocks begin resynchronising.
/// </summary>
public const double MAX_SYNC_OFFSET = 50;
/// <summary>
/// The maximum delay to start gameplay, if any (but not all) player clocks are ready.
/// </summary>
public const double MAXIMUM_START_DELAY = 15000;
/// <summary>
/// An event which is invoked when gameplay is ready to start.
/// </summary>
public Action? ReadyToStart;
public double CurrentMasterTime => masterClock.CurrentTime;
/// <summary>
/// The master clock which is used to control the timing of all player clocks clocks.
/// </summary>
private readonly GameplayClockContainer masterClock;
/// <summary>
/// The player clocks.
/// </summary>
private readonly List<SpectatorPlayerClock> playerClocks = new List<SpectatorPlayerClock>();
private MasterClockState masterState = MasterClockState.Synchronised;
private bool hasStarted;
private double? firstStartAttemptTime;
public SpectatorSyncManager(GameplayClockContainer master)
{
masterClock = master;
}
/// <summary>
/// Create a new managed <see cref="SpectatorPlayerClock"/>.
/// </summary>
/// <returns>The newly created <see cref="SpectatorPlayerClock"/>.</returns>
public SpectatorPlayerClock CreateManagedClock()
{
var clock = new SpectatorPlayerClock(masterClock);
playerClocks.Add(clock);
return clock;
}
/// <summary>
/// Removes an <see cref="SpectatorPlayerClock"/>, stopping it from being managed by this <see cref="SpectatorSyncManager"/>.
/// </summary>
/// <param name="clock">The <see cref="SpectatorPlayerClock"/> to remove.</param>
public void RemoveManagedClock(SpectatorPlayerClock clock)
{
playerClocks.Remove(clock);
Logger.Log($"Removing managed clock from {nameof(SpectatorSyncManager)} ({playerClocks.Count} remain)");
clock.IsRunning = false;
}
protected override void Update()
{
base.Update();
if (!attemptStart())
{
// Ensure all player clocks are stopped until the start succeeds.
foreach (var clock in playerClocks)
clock.IsRunning = false;
return;
}
updatePlayerCatchup();
updateMasterState();
}
/// <summary>
/// Attempts to start playback. Waits for all player clocks to have available frames for up to <see cref="MAXIMUM_START_DELAY"/> milliseconds.
/// </summary>
/// <returns>Whether playback was started and syncing should occur.</returns>
private bool attemptStart()
{
if (hasStarted)
return true;
if (playerClocks.Count == 0)
return false;
int readyCount = playerClocks.Count(s => !s.WaitingOnFrames);
if (readyCount == playerClocks.Count)
return performStart();
if (readyCount > 0)
{
firstStartAttemptTime ??= Time.Current;
if (Time.Current - firstStartAttemptTime > MAXIMUM_START_DELAY)
return performStart();
}
bool performStart()
{
ReadyToStart?.Invoke();
return hasStarted = true;
}
return false;
}
/// <summary>
/// Updates the catchup states of all player clocks.
/// </summary>
private void updatePlayerCatchup()
{
for (int i = 0; i < playerClocks.Count; i++)
{
var clock = playerClocks[i];
// How far this player's clock is out of sync, compared to the master clock.
// A negative value means the player is running fast (ahead); a positive value means the player is running behind (catching up).
double timeDelta = masterClock.CurrentTime - clock.CurrentTime;
// Check that the player clock isn't too far ahead.
// This is a quiet case in which the catchup is done by the master clock, so IsCatchingUp is not set on the player clock.
if (timeDelta < -SYNC_TARGET)
{
// Importantly, set the clock to a non-catchup state. if this isn't done, updateMasterState may incorrectly pause the master clock
// when it is required to be running (ie. if all players are ahead of the master).
clock.IsCatchingUp = false;
clock.IsRunning = false;
continue;
}
// Make sure the player clock is running if it can.
clock.IsRunning = !clock.WaitingOnFrames;
if (clock.IsCatchingUp)
{
// Stop the player clock from catching up if it's within the sync target.
if (timeDelta <= SYNC_TARGET)
clock.IsCatchingUp = false;
}
else
{
// Make the player clock start catching up if it's exceeded the maximum allowable sync offset.
if (timeDelta > MAX_SYNC_OFFSET)
clock.IsCatchingUp = true;
}
}
}
/// <summary>
/// Updates the state of the master clock.
/// </summary>
private void updateMasterState()
{
// Clocks are removed as players complete the beatmap.
// Once there are no clocks we want to make sure the track plays out to the end.
MasterClockState newState = playerClocks.Count == 0 || playerClocks.Any(s => !s.IsCatchingUp) ? MasterClockState.Synchronised : MasterClockState.TooFarAhead;
if (masterState == newState)
return;
masterState = newState;
Logger.Log($"{nameof(SpectatorSyncManager)}'s master clock became {masterState}");
switch (masterState)
{
case MasterClockState.Synchronised:
if (hasStarted)
masterClock.Start();
break;
case MasterClockState.TooFarAhead:
masterClock.Stop();
break;
}
}
}
}