1
0
mirror of https://github.com/ppy/osu.git synced 2024-11-16 10:17:36 +08:00
osu-lazer/osu.Game/Beatmaps/FramedBeatmapClock.cs

219 lines
7.7 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.Diagnostics;
using osu.Framework;
using osu.Framework.Allocation;
using osu.Framework.Bindables;
using osu.Framework.Graphics;
using osu.Framework.Timing;
using osu.Game.Configuration;
using osu.Game.Database;
using osu.Game.Screens.Play;
namespace osu.Game.Beatmaps
{
/// <summary>
/// A clock intended to be the single source-of-truth for beatmap timing.
///
/// It provides some functionality:
/// - Optionally applies (and tracks changes of) beatmap, user, and platform offsets (see ctor argument applyOffsets).
/// - Adjusts <see cref="Seek"/> operations to account for any applied offsets, seeking in raw "beatmap" time values.
/// - Exposes track length.
/// - Allows changing the source to a new track (for cases like editor track updating).
/// </summary>
public partial class FramedBeatmapClock : Component, IFrameBasedClock, IAdjustableClock, ISourceChangeableClock
{
private readonly bool applyOffsets;
private readonly OffsetCorrectionClock? userGlobalOffsetClock;
private readonly OffsetCorrectionClock? platformOffsetClock;
private readonly FramedOffsetClock? userBeatmapOffsetClock;
private readonly IFrameBasedClock finalClockSource;
private Bindable<double>? userAudioOffset;
private IDisposable? beatmapOffsetSubscription;
private readonly DecouplingFramedClock decoupledTrack;
private readonly InterpolatingFramedClock interpolatedTrack;
[Resolved]
private OsuConfigManager config { get; set; } = null!;
[Resolved]
private RealmAccess realm { get; set; } = null!;
[Resolved]
private IBindable<WorkingBeatmap> beatmap { get; set; } = null!;
public bool IsRewinding { get; private set; }
public FramedBeatmapClock(bool applyOffsets, bool requireDecoupling, IClock? source = null)
{
this.applyOffsets = applyOffsets;
decoupledTrack = new DecouplingFramedClock(source) { AllowDecoupling = requireDecoupling };
// An interpolating clock is used to ensure precise time values even when the host audio subsystem is not reporting
// high precision times (on windows there's generally only 5-10ms reporting intervals, as an example).
interpolatedTrack = new InterpolatingFramedClock(decoupledTrack);
if (applyOffsets)
{
// Audio timings in general with newer BASS versions don't match stable.
// This only seems to be required on windows. We need to eventually figure out why, with a bit of luck.
platformOffsetClock = new OffsetCorrectionClock(interpolatedTrack) { Offset = RuntimeInfo.OS == RuntimeInfo.Platform.Windows ? 15 : 0 };
// User global offset (set in settings) should also be applied.
userGlobalOffsetClock = new OffsetCorrectionClock(platformOffsetClock);
// User per-beatmap offset will be applied to this final clock.
finalClockSource = userBeatmapOffsetClock = new FramedOffsetClock(userGlobalOffsetClock);
}
else
{
finalClockSource = interpolatedTrack;
}
}
protected override void LoadComplete()
{
base.LoadComplete();
if (applyOffsets)
{
Debug.Assert(userBeatmapOffsetClock != null);
Debug.Assert(userGlobalOffsetClock != null);
userAudioOffset = config.GetBindable<double>(OsuSetting.AudioOffset);
userAudioOffset.BindValueChanged(offset => userGlobalOffsetClock.Offset = offset.NewValue, true);
// TODO: this doesn't update when using ChangeSource() to change beatmap.
beatmapOffsetSubscription = realm.SubscribeToPropertyChanged(
r => r.Find<BeatmapInfo>(beatmap.Value.BeatmapInfo.ID)?.UserSettings,
settings => settings.Offset,
val =>
{
userBeatmapOffsetClock.Offset = val;
});
}
}
protected override void Update()
{
base.Update();
finalClockSource.ProcessFrame();
if (Clock.ElapsedFrameTime != 0)
IsRewinding = Clock.ElapsedFrameTime < 0;
}
public double TotalAppliedOffset
{
get
{
if (!applyOffsets)
return 0;
Debug.Assert(userGlobalOffsetClock != null);
Debug.Assert(userBeatmapOffsetClock != null);
Debug.Assert(platformOffsetClock != null);
return userGlobalOffsetClock.RateAdjustedOffset + userBeatmapOffsetClock.Offset + platformOffsetClock.RateAdjustedOffset;
}
}
#region Delegation of IAdjustableClock / ISourceChangeableClock to decoupled clock.
public void ChangeSource(IClock? source) => decoupledTrack.ChangeSource(source);
public IClock Source => decoupledTrack.Source;
public void Reset()
{
decoupledTrack.Reset();
finalClockSource.ProcessFrame();
}
public void Start()
{
decoupledTrack.Start();
finalClockSource.ProcessFrame();
}
public void Stop()
{
decoupledTrack.Stop();
finalClockSource.ProcessFrame();
}
public bool Seek(double position)
{
bool success = decoupledTrack.Seek(position - TotalAppliedOffset);
finalClockSource.ProcessFrame();
return success;
}
public void ResetSpeedAdjustments() => decoupledTrack.ResetSpeedAdjustments();
public double Rate
{
get => decoupledTrack.Rate;
set => decoupledTrack.Rate = value;
}
#endregion
#region Delegation of IFrameBasedClock to clock with all offsets applied
public double CurrentTime => finalClockSource.CurrentTime;
public bool IsRunning => finalClockSource.IsRunning;
public void ProcessFrame()
{
// Noop to ensure an external consumer doesn't process the internal clock an extra time.
}
public double ElapsedFrameTime => finalClockSource.ElapsedFrameTime;
public double FramesPerSecond => finalClockSource.FramesPerSecond;
#endregion
protected override void Dispose(bool isDisposing)
{
base.Dispose(isDisposing);
beatmapOffsetSubscription?.Dispose();
}
public string GetSnapshot()
{
return
$"originalSource: {output(Source)}\n" +
$"userGlobalOffsetClock: {output(userGlobalOffsetClock)}\n" +
$"platformOffsetClock: {output(platformOffsetClock)}\n" +
$"userBeatmapOffsetClock: {output(userBeatmapOffsetClock)}\n" +
$"interpolatedTrack: {output(interpolatedTrack)}\n" +
$"decoupledTrack: {output(decoupledTrack)}\n" +
$"finalClockSource: {output(finalClockSource)}\n";
string output(IClock? clock)
{
if (clock == null)
return "null";
if (clock is IFrameBasedClock framed)
return $"current: {clock.CurrentTime:N2} running: {clock.IsRunning} rate: {clock.Rate} elapsed: {framed.ElapsedFrameTime:N2}";
return $"current: {clock.CurrentTime:N2} running: {clock.IsRunning} rate: {clock.Rate}";
}
}
}
}