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osu-lazer/osu.Game/Screens/Edit/EditorClock.cs
Bartłomiej Dach 4df7ff21c7 Fix editor arrow seek snapping not updating after control point changes
The editor clock, which is responsible for performing the seek, was not
aware of changes in control points due to reading from the wrong
beatmap. `loadableBeatmap` is not actually changed by any of the editor
components; `playableBeatmap` and `editorBeatmap` are.

For now this is changed to use `playableBeatmap`. A better follow-up
would be to use `editorBeatmap`, but it would probably be best to move
the beat snap bindable into `EditorBeatmap` first.
2021-04-03 14:02:46 +02:00

317 lines
11 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.Linq;
using osu.Framework.Audio.Track;
using osu.Framework.Bindables;
using osu.Framework.Graphics;
using osu.Framework.Graphics.Transforms;
using osu.Framework.Timing;
using osu.Framework.Utils;
using osu.Game.Beatmaps;
using osu.Game.Beatmaps.ControlPoints;
namespace osu.Game.Screens.Edit
{
/// <summary>
/// A decoupled clock which adds editor-specific functionality, such as snapping to a user-defined beat divisor.
/// </summary>
public class EditorClock : Component, IFrameBasedClock, IAdjustableClock, ISourceChangeableClock
{
public IBindable<Track> Track => track;
private readonly Bindable<Track> track = new Bindable<Track>();
public double TrackLength => track.Value?.Length ?? 60000;
public ControlPointInfo ControlPointInfo;
private readonly BindableBeatDivisor beatDivisor;
private readonly DecoupleableInterpolatingFramedClock underlyingClock;
private bool playbackFinished;
public IBindable<bool> SeekingOrStopped => seekingOrStopped;
private readonly Bindable<bool> seekingOrStopped = new Bindable<bool>(true);
/// <summary>
/// Whether a seek is currently in progress. True for the duration of a seek performed via <see cref="SeekSmoothlyTo"/>.
/// </summary>
public bool IsSeeking { get; private set; }
public EditorClock(IBeatmap beatmap, BindableBeatDivisor beatDivisor)
: this(beatmap.ControlPointInfo, beatDivisor)
{
}
public EditorClock(ControlPointInfo controlPointInfo, BindableBeatDivisor beatDivisor)
{
this.beatDivisor = beatDivisor;
ControlPointInfo = controlPointInfo;
underlyingClock = new DecoupleableInterpolatingFramedClock();
}
public EditorClock()
: this(new ControlPointInfo(), new BindableBeatDivisor())
{
}
/// <summary>
/// Seek to the closest snappable beat from a time.
/// </summary>
/// <param name="position">The raw position which should be seeked around.</param>
/// <returns>Whether the seek could be performed.</returns>
public bool SeekSnapped(double position)
{
var timingPoint = ControlPointInfo.TimingPointAt(position);
double beatSnapLength = timingPoint.BeatLength / beatDivisor.Value;
// We will be snapping to beats within the timing point
position -= timingPoint.Time;
// Determine the index from the current timing point of the closest beat to position
int closestBeat = (int)Math.Round(position / beatSnapLength);
position = timingPoint.Time + closestBeat * beatSnapLength;
// Depending on beatSnapLength, we may snap to a beat that is beyond timingPoint's end time, but we want to instead snap to
// the next timing point's start time
var nextTimingPoint = ControlPointInfo.TimingPoints.FirstOrDefault(t => t.Time > timingPoint.Time);
if (position > nextTimingPoint?.Time)
position = nextTimingPoint.Time;
return Seek(position);
}
/// <summary>
/// Seeks backwards by one beat length.
/// </summary>
/// <param name="snapped">Whether to snap to the closest beat after seeking.</param>
/// <param name="amount">The relative amount (magnitude) which should be seeked.</param>
public void SeekBackward(bool snapped = false, double amount = 1) => seek(-1, snapped, amount + (IsRunning ? 1.5 : 0));
/// <summary>
/// Seeks forwards by one beat length.
/// </summary>
/// <param name="snapped">Whether to snap to the closest beat after seeking.</param>
/// <param name="amount">The relative amount (magnitude) which should be seeked.</param>
public void SeekForward(bool snapped = false, double amount = 1) => seek(1, snapped, amount);
private void seek(int direction, bool snapped, double amount = 1)
{
double current = CurrentTimeAccurate;
if (amount <= 0) throw new ArgumentException("Value should be greater than zero", nameof(amount));
var timingPoint = ControlPointInfo.TimingPointAt(current);
if (direction < 0 && timingPoint.Time == current)
// When going backwards and we're at the boundary of two timing points, we compute the seek distance with the timing point which we are seeking into
timingPoint = ControlPointInfo.TimingPointAt(current - 1);
double seekAmount = timingPoint.BeatLength / beatDivisor.Value * amount;
double seekTime = current + seekAmount * direction;
if (!snapped || ControlPointInfo.TimingPoints.Count == 0)
{
SeekSmoothlyTo(seekTime);
return;
}
// We will be snapping to beats within timingPoint
seekTime -= timingPoint.Time;
// Determine the index from timingPoint of the closest beat to seekTime, accounting for scrolling direction
int closestBeat;
if (direction > 0)
closestBeat = (int)Math.Floor(seekTime / seekAmount);
else
closestBeat = (int)Math.Ceiling(seekTime / seekAmount);
seekTime = timingPoint.Time + closestBeat * seekAmount;
// limit forward seeking to only up to the next timing point's start time.
var nextTimingPoint = ControlPointInfo.TimingPoints.FirstOrDefault(t => t.Time > timingPoint.Time);
if (seekTime > nextTimingPoint?.Time)
seekTime = nextTimingPoint.Time;
// Due to the rounding above, we may end up on the current beat. This will effectively cause 0 seeking to happen, but we don't want this.
// Instead, we'll go to the next beat in the direction when this is the case
if (Precision.AlmostEquals(current, seekTime, 0.5f))
{
closestBeat += direction > 0 ? 1 : -1;
seekTime = timingPoint.Time + closestBeat * seekAmount;
}
if (seekTime < timingPoint.Time && timingPoint != ControlPointInfo.TimingPoints.First())
seekTime = timingPoint.Time;
// Ensure the sought point is within the boundaries
seekTime = Math.Clamp(seekTime, 0, TrackLength);
SeekSmoothlyTo(seekTime);
}
/// <summary>
/// The current time of this clock, include any active transform seeks performed via <see cref="SeekSmoothlyTo"/>.
/// </summary>
public double CurrentTimeAccurate =>
Transforms.OfType<TransformSeek>().FirstOrDefault()?.EndValue ?? CurrentTime;
public double CurrentTime => underlyingClock.CurrentTime;
public void Reset()
{
ClearTransforms();
underlyingClock.Reset();
}
public void Start()
{
ClearTransforms();
if (playbackFinished)
underlyingClock.Seek(0);
underlyingClock.Start();
}
public void Stop()
{
seekingOrStopped.Value = true;
underlyingClock.Stop();
}
public bool Seek(double position)
{
seekingOrStopped.Value = IsSeeking = true;
ClearTransforms();
return underlyingClock.Seek(position);
}
/// <summary>
/// Seek smoothly to the provided destination.
/// Use <see cref="Seek"/> to perform an immediate seek.
/// </summary>
/// <param name="seekDestination"></param>
public void SeekSmoothlyTo(double seekDestination)
{
seekingOrStopped.Value = true;
if (IsRunning)
Seek(seekDestination);
else
{
transformSeekTo(seekDestination, transform_time, Easing.OutQuint);
}
}
public void ResetSpeedAdjustments() => underlyingClock.ResetSpeedAdjustments();
double IAdjustableClock.Rate
{
get => underlyingClock.Rate;
set => underlyingClock.Rate = value;
}
double IClock.Rate => underlyingClock.Rate;
public bool IsRunning => underlyingClock.IsRunning;
public void ProcessFrame()
{
underlyingClock.ProcessFrame();
playbackFinished = CurrentTime >= TrackLength;
if (playbackFinished)
{
if (IsRunning)
underlyingClock.Stop();
if (CurrentTime > TrackLength)
underlyingClock.Seek(TrackLength);
}
}
public double ElapsedFrameTime => underlyingClock.ElapsedFrameTime;
public double FramesPerSecond => underlyingClock.FramesPerSecond;
public FrameTimeInfo TimeInfo => underlyingClock.TimeInfo;
public void ChangeSource(IClock source)
{
track.Value = source as Track;
underlyingClock.ChangeSource(source);
}
public IClock Source => underlyingClock.Source;
public bool IsCoupled
{
get => underlyingClock.IsCoupled;
set => underlyingClock.IsCoupled = value;
}
private const double transform_time = 300;
protected override void Update()
{
base.Update();
updateSeekingState();
}
private void updateSeekingState()
{
if (seekingOrStopped.Value)
{
IsSeeking &= Transforms.Any();
if (track.Value?.IsRunning != true)
{
// seeking in the editor can happen while the track isn't running.
// in this case we always want to expose ourselves as seeking (to avoid sample playback).
return;
}
// we are either running a seek tween or doing an immediate seek.
// in the case of an immediate seek the seeking bool will be set to false after one update.
// this allows for silencing hit sounds and the likes.
seekingOrStopped.Value = IsSeeking;
}
}
private void transformSeekTo(double seek, double duration = 0, Easing easing = Easing.None)
=> this.TransformTo(this.PopulateTransform(new TransformSeek(), seek, duration, easing));
private double currentTime
{
get => underlyingClock.CurrentTime;
set => underlyingClock.Seek(value);
}
private class TransformSeek : Transform<double, EditorClock>
{
public override string TargetMember => nameof(currentTime);
protected override void Apply(EditorClock clock, double time) => clock.currentTime = valueAt(time);
private double valueAt(double time)
{
if (time < StartTime) return StartValue;
if (time >= EndTime) return EndValue;
return Interpolation.ValueAt(time, StartValue, EndValue, StartTime, EndTime, Easing);
}
protected override void ReadIntoStartValue(EditorClock clock) => StartValue = clock.currentTime;
}
}
}