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// 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.Utils ;
using osu.Game.Rulesets.Objects ;
using osu.Game.Rulesets.Objects.Types ;
using osuTK ;
#nullable enable
namespace osu.Game.Rulesets.Catch.Objects
{
/// <summary>
/// Represents the path of a juice stream.
/// <para>
/// A <see cref="JuiceStream"/> holds a legacy <see cref="SliderPath"/> as the representation of the path.
/// However, the <see cref="SliderPath"/> representation is difficult to work with.
/// This <see cref="JuiceStreamPath"/> represents the path in a more convenient way, a polyline connecting list of <see cref="JuiceStreamPathVertex"/>s.
/// </para>
/// </summary>
public class JuiceStreamPath
{
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/// <summary>
/// The height of legacy osu!standard playfield.
/// The sliders converted by <see cref="ConvertToSliderPath"/> are vertically contained in this height.
/// </summary>
internal const float OSU_PLAYFIELD_HEIGHT = 384 ;
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/// <summary>
/// The list of vertices of the path, which is represented as a polyline connecting the vertices.
/// </summary>
public IReadOnlyList < JuiceStreamPathVertex > Vertices = > vertices ;
/// <summary>
/// The current version number.
/// This starts from <c>1</c> and incremented whenever this <see cref="JuiceStreamPath"/> is modified.
/// </summary>
public int InvalidationID { get ; private set ; } = 1 ;
/// <summary>
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/// The difference between first vertex's <see cref="JuiceStreamPathVertex.Time"/> and last vertex's <see cref="JuiceStreamPathVertex.Time"/>.
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/// </summary>
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public double Duration = > vertices [ ^ 1 ] . Time - vertices [ 0 ] . Time ;
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/// <remarks>
/// This list should always be non-empty.
/// </remarks>
private readonly List < JuiceStreamPathVertex > vertices = new List < JuiceStreamPathVertex >
{
new JuiceStreamPathVertex ( )
} ;
/// <summary>
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/// Compute the x-position of the path at the given <paramref name="time"/>.
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/// </summary>
/// <remarks>
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/// When the given time is outside of the path, the x position at the corresponding endpoint is returned,
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/// </remarks>
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public float PositionAtTime ( double time )
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{
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int index = vertexIndexAtTime ( time ) ;
return positionAtTime ( time , index ) ;
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}
/// <summary>
/// Remove all vertices of this path, then add a new vertex <c>(0, 0)</c>.
/// </summary>
public void Clear ( )
{
vertices . Clear ( ) ;
vertices . Add ( new JuiceStreamPathVertex ( ) ) ;
invalidate ( ) ;
}
/// <summary>
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/// Insert a vertex at given <paramref name="time"/>.
/// The <see cref="PositionAtTime"/> is used as the position of the new vertex.
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/// Thus, the set of points of the path is not changed (up to floating-point precision).
/// </summary>
/// <returns>The index of the new vertex.</returns>
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public int InsertVertex ( double time )
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{
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if ( ! double . IsFinite ( time ) )
throw new ArgumentOutOfRangeException ( nameof ( time ) ) ;
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int index = vertexIndexAtTime ( time ) ;
float x = positionAtTime ( time , index ) ;
vertices . Insert ( index , new JuiceStreamPathVertex ( time , x ) ) ;
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invalidate ( ) ;
return index ;
}
/// <summary>
/// Move the vertex of given <paramref name="index"/> to the given position <paramref name="newX"/>.
/// </summary>
public void SetVertexPosition ( int index , float newX )
{
if ( index < 0 | | index > = vertices . Count )
throw new ArgumentOutOfRangeException ( nameof ( index ) ) ;
if ( ! float . IsFinite ( newX ) )
throw new ArgumentOutOfRangeException ( nameof ( newX ) ) ;
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vertices [ index ] = new JuiceStreamPathVertex ( vertices [ index ] . Time , newX ) ;
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invalidate ( ) ;
}
/// <summary>
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/// Add a new vertex at given <paramref name="time"/> and position.
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/// </summary>
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public void Add ( double time , float x )
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{
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int index = InsertVertex ( time ) ;
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SetVertexPosition ( index , x ) ;
}
/// <summary>
/// Remove all vertices that satisfy the given <paramref name="predicate"/>.
/// </summary>
/// <remarks>
/// If all vertices are removed, a new vertex <c>(0, 0)</c> is added.
/// </remarks>
/// <param name="predicate">The predicate to determine whether a vertex should be removed given the vertex and its index in the path.</param>
/// <returns>The number of removed vertices.</returns>
public int RemoveVertices ( Func < JuiceStreamPathVertex , int , bool > predicate )
{
int index = 0 ;
int removeCount = vertices . RemoveAll ( vertex = > predicate ( vertex , index + + ) ) ;
if ( vertices . Count = = 0 )
vertices . Add ( new JuiceStreamPathVertex ( ) ) ;
if ( removeCount ! = 0 )
invalidate ( ) ;
return removeCount ;
}
/// <summary>
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/// Recreate this path by using difference set of vertices at given time points.
/// In addition to the given <paramref name="sampleTimes"/>, the first vertex and the last vertex are always added to the new path.
/// New vertices use the positions on the original path. Thus, <see cref="PositionAtTime"/>s at <paramref name="sampleTimes"/> are preserved.
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/// </summary>
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public void ResampleVertices ( IEnumerable < double > sampleTimes )
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{
var sampledVertices = new List < JuiceStreamPathVertex > ( ) ;
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foreach ( double time in sampleTimes )
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{
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if ( ! double . IsFinite ( time ) )
throw new ArgumentOutOfRangeException ( nameof ( sampleTimes ) ) ;
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double clampedTime = Math . Clamp ( time , vertices [ 0 ] . Time , vertices [ ^ 1 ] . Time ) ;
float x = PositionAtTime ( clampedTime ) ;
sampledVertices . Add ( new JuiceStreamPathVertex ( clampedTime , x ) ) ;
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}
sampledVertices . Sort ( ) ;
// The first vertex and the last vertex are always used in the result.
vertices . RemoveRange ( 1 , vertices . Count - ( vertices . Count = = 1 ? 1 : 2 ) ) ;
vertices . InsertRange ( 1 , sampledVertices ) ;
invalidate ( ) ;
}
/// <summary>
/// Convert a <see cref="SliderPath"/> to list of vertices and write the result to this <see cref="JuiceStreamPath"/>.
/// </summary>
/// <remarks>
/// Duplicated vertices are automatically removed.
/// </remarks>
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public void ConvertFromSliderPath ( SliderPath sliderPath , double velocity )
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{
var sliderPathVertices = new List < Vector2 > ( ) ;
sliderPath . GetPathToProgress ( sliderPathVertices , 0 , 1 ) ;
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double time = 0 ;
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vertices . Clear ( ) ;
vertices . Add ( new JuiceStreamPathVertex ( 0 , sliderPathVertices . FirstOrDefault ( ) . X ) ) ;
for ( int i = 1 ; i < sliderPathVertices . Count ; i + + )
{
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time + = Vector2 . Distance ( sliderPathVertices [ i - 1 ] , sliderPathVertices [ i ] ) / velocity ;
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if ( ! Precision . AlmostEquals ( vertices [ ^ 1 ] . Time , time ) )
Add ( time , sliderPathVertices [ i ] . X ) ;
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}
invalidate ( ) ;
}
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/// <summary>
/// Computes the minimum slider velocity required to convert this path to a <see cref="SliderPath"/>.
/// </summary>
public double ComputeRequiredVelocity ( )
{
double maximumSlope = 0 ;
for ( int i = 1 ; i < vertices . Count ; i + + )
{
double xDifference = Math . Abs ( ( double ) vertices [ i ] . X - vertices [ i - 1 ] . X ) ;
double timeDifference = vertices [ i ] . Time - vertices [ i - 1 ] . Time ;
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// A short segment won't affect the resulting path much anyways so ignore it to avoid divide-by-zero.
if ( Precision . AlmostEquals ( timeDifference , 0 ) )
continue ;
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maximumSlope = Math . Max ( maximumSlope , xDifference / timeDifference ) ;
}
return maximumSlope ;
}
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/// <summary>
/// Convert the path of this <see cref="JuiceStreamPath"/> to a <see cref="SliderPath"/> and write the result to <paramref name="sliderPath"/>.
/// The resulting slider is "folded" to make it vertically contained in the playfield `(0..<see cref="OSU_PLAYFIELD_HEIGHT"/>)` assuming the slider start position is <paramref name="sliderStartY"/>.
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///
/// The velocity of the converted slider is assumed to be <paramref name="velocity"/>.
/// To preserve the path, <paramref name="velocity"/> should be at least the value returned by <see cref="ComputeRequiredVelocity"/>.
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/// </summary>
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public void ConvertToSliderPath ( SliderPath sliderPath , float sliderStartY , double velocity )
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{
const float margin = 1 ;
// Note: these two variables and `sliderPath` are modified by the local functions.
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double currentTime = 0 ;
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Vector2 lastPosition = new Vector2 ( vertices [ 0 ] . X , 0 ) ;
sliderPath . ControlPoints . Clear ( ) ;
sliderPath . ControlPoints . Add ( new PathControlPoint ( lastPosition ) ) ;
for ( int i = 1 ; i < vertices . Count ; i + + )
{
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sliderPath . ControlPoints [ ^ 1 ] . Type = PathType . Linear ;
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float deltaX = vertices [ i ] . X - lastPosition . X ;
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double length = ( vertices [ i ] . Time - currentTime ) * velocity ;
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// Should satisfy `deltaX^2 + deltaY^2 = length^2`.
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// The expression inside the `sqrt` is (almost) non-negative if the slider velocity is large enough.
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double deltaY = Math . Sqrt ( Math . Max ( 0 , length * length - ( double ) deltaX * deltaX ) ) ;
// When `deltaY` is small, one segment is always enough.
// This case is handled separately to prevent divide-by-zero.
if ( deltaY < = OSU_PLAYFIELD_HEIGHT / 2 - margin )
{
float nextX = vertices [ i ] . X ;
float nextY = ( float ) ( lastPosition . Y + getYDirection ( ) * deltaY ) ;
addControlPoint ( nextX , nextY ) ;
continue ;
}
// When `deltaY` is large or when the slider velocity is fast, the segment must be partitioned to subsegments to stay in bounds.
for ( double currentProgress = 0 ; currentProgress < deltaY ; )
{
double nextProgress = Math . Min ( currentProgress + getMaxDeltaY ( ) , deltaY ) ;
float nextX = ( float ) ( vertices [ i - 1 ] . X + nextProgress / deltaY * deltaX ) ;
float nextY = ( float ) ( lastPosition . Y + getYDirection ( ) * ( nextProgress - currentProgress ) ) ;
addControlPoint ( nextX , nextY ) ;
currentProgress = nextProgress ;
}
}
int getYDirection ( )
{
float lastSliderY = sliderStartY + lastPosition . Y ;
return lastSliderY < OSU_PLAYFIELD_HEIGHT / 2 ? 1 : - 1 ;
}
float getMaxDeltaY ( )
{
float lastSliderY = sliderStartY + lastPosition . Y ;
return Math . Max ( lastSliderY , OSU_PLAYFIELD_HEIGHT - lastSliderY ) - margin ;
}
void addControlPoint ( float nextX , float nextY )
{
Vector2 nextPosition = new Vector2 ( nextX , nextY ) ;
sliderPath . ControlPoints . Add ( new PathControlPoint ( nextPosition ) ) ;
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currentTime + = Vector2 . Distance ( lastPosition , nextPosition ) / velocity ;
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lastPosition = nextPosition ;
}
}
/// <summary>
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/// Find the index at which a new vertex with <paramref name="time"/> can be inserted.
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/// </summary>
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private int vertexIndexAtTime ( double time )
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{
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// The position of `(time, Infinity)` is uniquely determined because infinite positions are not allowed.
int i = vertices . BinarySearch ( new JuiceStreamPathVertex ( time , float . PositiveInfinity ) ) ;
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return i < 0 ? ~ i : i ;
}
/// <summary>
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/// Compute the position at the given <paramref name="time"/>, assuming <paramref name="index"/> is the vertex index returned by <see cref="vertexIndexAtTime"/>.
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/// </summary>
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private float positionAtTime ( double time , int index )
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{
if ( index < = 0 )
return vertices [ 0 ] . X ;
if ( index > = vertices . Count )
return vertices [ ^ 1 ] . X ;
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double duration = vertices [ index ] . Time - vertices [ index - 1 ] . Time ;
if ( Precision . AlmostEquals ( duration , 0 ) )
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return vertices [ index ] . X ;
float deltaX = vertices [ index ] . X - vertices [ index - 1 ] . X ;
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return ( float ) ( vertices [ index - 1 ] . X + deltaX * ( ( time - vertices [ index - 1 ] . Time ) / duration ) ) ;
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}
private void invalidate ( ) = > InvalidationID + + ;
}
}