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global using Microsoft.VisualStudio.TestTools.UnitTesting;
[TestClass]
public class TestInit
{
[AssemblyInitialize]
public static void ClassInitialize( TestContext context )
{
Sandbox.Application.InitUnitTest();
}
}
using System;
using System.Collections.Generic;
using System.IO;
using System.Linq;
using Sandbox;
namespace SFXR;
[Title( "SFXR Component" )]
[Category( "SFXR" )]
[Icon( "volume_up" )]
public sealed class SFXRComponent : Component
{
/// <summary>
/// The base Waveform
/// (Default: Square)
/// </summary>
[Property, Group( "Sound" )]
public Waveform Waveform { get; set; } = Waveform.Square;
/// <summary>
/// The sample rate of the sound
/// </summary>
[Property, Group( "Sound" )]
public SampleRate SampleRate { get; set; } = SampleRate.Hz44100;
/// <summary>
/// The bit depth of the sound
/// </summary>
// [Property, Group( "Sound" )]
public BitDepth BitDepth { get; set; } = BitDepth.Bit16;
/// <summary>
/// The length of the sound in seconds
/// </summary>
[Property, Group( "Sound" ), Range( 0f, 20f, 0.01f )]
public float Length { get; set; } = 0.5f;
/// <summary>
/// The volume of the sound
/// (Default: 0.5)
/// </summary>
[Property, Group( "Sound" ), Range( 0f, 1f, 0.01f )]
public float MasterVolume { get; set; } = 0.5f;
[Property, Group( "Frequency" ), Range( 0, 3000f, 1f )]
float StartFrequency
{
get => Frequency.Start;
set => Frequency.Start = value;
}
[Property, Group( "Frequency" ), Range( -3000f, 3000f, 1f )]
float Slide
{
get => Frequency.Slide;
set => Frequency.Slide = value;
}
[Property, Group( "Frequency" ), Range( -3000f, 3000f, 1f )]
float SlideDelta
{
get => Frequency.DeltaSlide;
set => Frequency.DeltaSlide = value;
}
/// <summary>
/// The random seed
/// </summary>
[Property, Group( "Controls" )]
public long Seed { get; set; } = 0;
[Property, Group( "Controls" )]
public SFXRControls Controls { get; set; } = new SFXRControls();
public SFXRFrequency Frequency { get; set; } = new SFXRFrequency();
Random _random = new Random();
List<SFXRNote> NotesPlaying = new();
/// <summary>
/// Plays the sound defined by the component
/// </summary>
/// <returns>The sound handle of the sound. This can be used to change position, pitch, ect</returns>
public SoundHandle PlaySound()
{
var sfx = Generate( (int)(Length * (int)SampleRate) );
var handle = sfx.Play();
// DestroyStream(sfx, Length);
return handle;
}
/// <summary>
/// Plays the sound defined by the component (Via a frequency trigger. This will play indefinitely until released)
/// </summary>
/// <param name="frequency">The frequency of the sound</param>
/// <param name="volume">The volume of the trigger </param>
public void TriggerNotePress( float frequency, float volume = 1f )
{
foreach ( var note in NotesPlaying.Where( x => x.Frequency == frequency ) )
{
note.Release();
}
var newNote = new SFXRNote( this, frequency, volume );
newNote.Trigger();
NotesPlaying.Add( newNote );
}
/// <summary>
/// Releases a note playing at the given frequency
/// </summary>
/// <param name="frequency">The frequency of the sound</param>
public void TriggerNoteRelease( float frequency )
{
foreach ( var note in NotesPlaying.Where( x => x.Frequency == frequency ) )
{
note.Release();
}
}
/// <summary>
/// Releases all notes playing
/// </summary>
public void TriggerReleaseAll()
{
foreach ( var note in NotesPlaying )
{
note.Release();
}
}
/// <summary>
/// Generates a sound stream from the component
/// </summary>
/// <param name="sampleCount">How many samples the stream should be filled with</param>
/// <returns></returns>
public SoundStream Generate( int sampleCount )
{
List<SFXREffect> effects = new();
foreach ( var component in GameObject.Components.GetAll() )
{
if ( component is not SFXREffect effect || !effect.Enabled ) continue;
effects.Add( effect );
}
return Generate( sampleCount, effects );
}
/// <summary>
/// Generates a sound stream from the component with the given effects
/// </summary>
/// <param name="sampleCount">The number of samples</param>
/// <param name="effects">A list of the effects to apply</param>
/// <returns></returns>
public SoundStream Generate( int sampleCount, List<SFXREffect> effects )
{
short[] samples = new short[sampleCount];
float t = 0;
for ( int i = 0; i < sampleCount; i++ )
{
t += 1f / (int)SampleRate;
short sampleValue = SFXR.GetWaveformSample( Waveform, t, Frequency.GetFrequency( t ) );
sampleValue = (short)((float)sampleValue * MasterVolume);
samples[i] = sampleValue;
}
foreach ( var effect in effects )
{
if ( !effect.Enabled ) continue;
samples = effect.Apply( samples, this );
}
var stream = new SoundStream( (int)SampleRate );
stream.WriteData( samples );
return stream;
}
/// <summary>
/// Randomizes the component's parameters
/// </summary>
public void Randomize()
{
if ( Seed != 0 ) _random = new Random( (int)Seed );
var waveform = Waveform;
ResetParameters();
Waveform = waveform;
Frequency.Start = _random.Next( 10, 3000 );
if ( _random.Next( 2 ) == 0 ) Frequency.Slide = _random.Next( -3000, 3000 );
if ( Frequency.Start > 2000 && Frequency.Slide > 200 ) Frequency.Slide = -Frequency.Slide;
else if ( Frequency.Start < 400 && Frequency.Slide < -50 ) Frequency.Slide = -Frequency.Slide;
if ( _random.Next( 2 ) == 0 ) Frequency.DeltaSlide = _random.Next( -3000, 3000 );
SanitizeParameters();
}
/// <summary>
/// Mutates the component's parameters slightly
/// </summary>
public void Mutate( float mutation = 0.05f )
{
if ( Seed != 0 ) _random = new Random( (int)Seed );
Frequency.Start += _random.Float( -mutation, mutation ) * 1000;
if ( Frequency.Start > 2000 && Frequency.Slide > 200 ) Frequency.Slide = -Frequency.Slide;
else if ( Frequency.Start < 400 && Frequency.Slide < -50 ) Frequency.Slide = -Frequency.Slide;
Frequency.Slide += _random.Float( -mutation, mutation ) * 1000;
Frequency.DeltaSlide += _random.Float( -mutation, mutation ) * 1000;
if ( Frequency.Slide < -3000 ) Frequency.Slide = -3000;
if ( Frequency.Slide > 3000 ) Frequency.Slide = 3000;
SanitizeParameters();
}
public void RandomizePickup()
{
if ( Seed != 0 ) _random = new Random( (int)Seed );
ResetParameters();
foreach ( var component in GameObject.Components.GetAll() )
{
if ( component is not SFXREffect effect ) continue;
effect.Enabled = false;
}
var envelope = Components.GetOrCreate<SFXREnvelope>();
Waveform = (Waveform)_random.Int( 0, 2 );
Frequency.Start = _random.Float( 0.4f, 0.9f ) * 3000;
envelope.Enabled = true;
envelope.Attack = 0;
envelope.Decay = _random.Float( 0.1f, 0.3f );
envelope.Sustain = _random.Float( 0f, 0.1f );
envelope.Release = _random.Float( 0.1f, 0.3f );
Length = envelope.Attack + envelope.Sustain + envelope.Decay + envelope.Release;
}
public void RandomizeLaser()
{
if ( Seed != 0 ) _random = new Random( (int)Seed );
ResetParameters();
foreach ( var component in GameObject.Components.GetAll() )
{
if ( component is not SFXREffect effect ) continue;
effect.Enabled = false;
}
var envelope = Components.GetOrCreate<SFXREnvelope>();
var highpass = Components.GetOrCreate<SFXRHighPass>();
Waveform = (Waveform)_random.Int( 0, 2 );
if ( Waveform == Waveform.Sine && _random.Next( 2 ) == 0 ) Waveform = (Waveform)_random.Int( 0, 1 );
Frequency.Start = _random.Float( 0.6f, 0.75f ) * 3000;
Frequency.Slide = _random.Float( -0.25f, -0.15f ) * 3000;
envelope.Enabled = true;
envelope.Attack = 0;
envelope.Decay = _random.Float( 0f, 0.4f );
envelope.Sustain = _random.Float( 0.1f, 0.3f );
envelope.Release = _random.Float( 0.25f, 0.3f );
Length = envelope.Attack + envelope.Sustain + envelope.Decay + envelope.Release;
if ( _random.Next( 2 ) == 0 )
{
highpass.Enabled = true;
highpass.Cutoff = _random.Float( 0f, 0.3f );
}
}
public void RandomizeExplosion()
{
if ( Seed != 0 ) _random = new Random( (int)Seed );
ResetParameters();
foreach ( var component in GameObject.Components.GetAll() )
{
if ( component is not SFXREffect effect ) continue;
effect.Enabled = false;
}
var envelope = Components.GetOrCreate<SFXREnvelope>();
var vibrato = Components.GetOrCreate<SFXRVibrato>();
Waveform = Waveform.Noise;
if ( _random.Next( 2 ) == 0 )
{
Frequency.Start = _random.Float( 0.025f, 0.15f ) * 3000;
Frequency.Slide = _random.Float( -0.1f, -0.01f ) * 3000;
}
else
{
Frequency.Start = _random.Float( 0.1f, 0.2f ) * 3000;
Frequency.Slide = _random.Float( -0.6f, 0.6f ) * 3000;
}
if ( _random.Next( 4 ) == 0 ) Frequency.Slide = 0;
envelope.Enabled = true;
envelope.Attack = 0;
envelope.Sustain = _random.Float( 0.1f, 0.4f );
envelope.Release = _random.Float( 0.1f, 0.3f );
Length = envelope.Attack + envelope.Sustain + envelope.Decay + envelope.Release;
if ( _random.Next( 2 ) == 0 )
{
vibrato.Enabled = true;
vibrato.Depth = _random.Float( 0f, 0.7f );
vibrato.Speed = _random.Float( 0f, 60f );
}
else
{
vibrato.Enabled = false;
}
if ( -Frequency.Slide > Frequency.Start )
{
Frequency.Slide = -Frequency.Start;
}
}
public void RandomizePowerup()
{
if ( Seed != 0 ) _random = new Random( (int)Seed );
ResetParameters();
foreach ( var component in GameObject.Components.GetAll() )
{
if ( component is not SFXREffect effect ) continue;
effect.Enabled = false;
}
var envelope = Components.GetOrCreate<SFXREnvelope>();
var vibrato = Components.GetOrCreate<SFXRVibrato>();
if ( _random.Next( 2 ) == 0 )
{
Waveform = Waveform.Sawtooth;
}
if ( _random.Next( 2 ) == 0 )
{
Frequency.Start = _random.Float( 0.2f, 0.5f ) * 3000;
Frequency.Slide = _random.Float( 0.1f, 0.5f ) * 3000;
}
else
{
Frequency.Start = _random.Float( 0.25f, 0.5f ) * 3000;
Frequency.Slide = _random.Float( 0.05f, 0.25f ) * 3000;
if ( _random.Next( 2 ) == 0 )
{
vibrato.Enabled = true;
vibrato.Depth = _random.Float( 0, 0.7f );
vibrato.Speed = _random.Float( 0, 60f );
}
else
{
vibrato.Enabled = false;
}
}
if ( -Frequency.Slide > Frequency.Start )
{
Frequency.Slide = -Frequency.Start;
}
envelope.Enabled = true;
envelope.Attack = 0;
envelope.Sustain = _random.Float( 0f, 0.4f );
envelope.Release = _random.Float( 0.1f, 0.5f );
Length = envelope.Attack + envelope.Sustain + envelope.Decay + envelope.Release;
}
public void RandomizeHit()
{
if ( Seed != 0 ) _random = new Random( (int)Seed );
ResetParameters();
foreach ( var component in GameObject.Components.GetAll() )
{
if ( component is not SFXREffect effect ) continue;
effect.Enabled = false;
}
var envelope = Components.GetOrCreate<SFXREnvelope>();
var highpass = Components.GetOrCreate<SFXRHighPass>();
Waveform = (Waveform)_random.Int( 0, 3 );
if ( Waveform == Waveform.Sine )
{
Waveform = Waveform.Noise;
}
Frequency.Start = _random.Float( 0.1f, 0.5f ) * 3000;
Frequency.Slide = _random.Float( -0.7f, -0.3f ) * 3000;
if ( -Frequency.Slide > Frequency.Start )
{
Frequency.Slide = -Frequency.Start;
}
envelope.Enabled = true;
envelope.Attack = 0;
envelope.Decay = 0;
envelope.Sustain = _random.Float( 0.025f, 0.1f );
envelope.Release = _random.Float( 0.1f, 0.3f );
Length = envelope.Attack + envelope.Sustain + envelope.Decay + envelope.Release;
if ( _random.Next( 2 ) == 0 )
{
highpass.Enabled = true;
highpass.Cutoff = _random.Float( 0f, 0.3f );
}
else
{
highpass.Enabled = false;
}
}
public void RandomizeJump()
{
if ( Seed != 0 ) _random = new Random( (int)Seed );
ResetParameters();
foreach ( var component in GameObject.Components.GetAll() )
{
if ( component is not SFXREffect effect ) continue;
effect.Enabled = false;
}
var envelope = Components.GetOrCreate<SFXREnvelope>();
Waveform = Waveform.Square;
Frequency.Start = _random.Float( 0.3f, 0.6f ) * 3000;
Frequency.Slide = _random.Float( 0.1f, 0.3f ) * 3000;
if ( -Frequency.Slide > Frequency.Start )
{
Frequency.Slide = -Frequency.Start;
}
envelope.Enabled = true;
envelope.Attack = 0;
envelope.Sustain = _random.Float( 0.1f, 0.4f );
envelope.Release = _random.Float( 0.1f, 0.3f );
Length = envelope.Attack + envelope.Sustain + envelope.Decay + envelope.Release;
}
public void RandomizeBlip()
{
if ( Seed != 0 ) _random = new Random( (int)Seed );
ResetParameters();
foreach ( var component in GameObject.Components.GetAll() )
{
if ( component is not SFXREffect effect ) continue;
effect.Enabled = false;
}
var envelope = Components.GetOrCreate<SFXREnvelope>();
Waveform = Waveform.Square;
Frequency.Start = _random.Float( 0.2f, 0.6f ) * 3000;
envelope.Enabled = true;
envelope.Attack = 0;
envelope.Decay = _random.Float( 0.1f, 0.2f );
envelope.Sustain = _random.Float( 0.025f, 0.1f );
envelope.Release = _random.Float( 0.1f, 0.3f );
Length = envelope.Attack + envelope.Sustain + envelope.Decay + envelope.Release;
}
public void ResetParameters()
{
Waveform = Waveform.Square;
SampleRate = SampleRate.Hz44100;
BitDepth = BitDepth.Bit16;
Length = 0.5f;
MasterVolume = 0.5f;
Frequency = new SFXRFrequency();
Controls = new SFXRControls();
}
void SanitizeParameters()
{
}
protected override void OnUpdate()
{
foreach ( var note in NotesPlaying )
{
note.Update();
// if (!note.IsPlaying)
// {
// note.DestroyStreams();
// }
}
NotesPlaying.RemoveAll( x => !x.IsPlaying );
}
}
using Editor;
using Sandbox;
using Sandbox.Helpers;
using System.Collections.Generic;
using System.Linq;
namespace SFXR.Editor;
[CustomEditor( typeof( List<SFXRSequencer.Note> ) )]
public class SFXRNotesListControlWidget : ControlWidget
{
private SerializedCollection Collection;
private Layout Content;
private Button addButton;
public override bool SupportsMultiEdit => false;
SFXRSequencer Sequencer;
public SFXRNotesListControlWidget( SerializedProperty property )
: base( property )
{
SetSizeMode( SizeMode.Ignore, SizeMode.Ignore );
base.Layout = Layout.Column();
base.Layout.Spacing = 2f;
if ( property.TryGetAsObject( out var obj ) && obj is SerializedCollection collection )
{
if ( property.Parent.Targets.First() is SFXRSequencer sequencer )
{
Sequencer = sequencer;
}
Collection = collection;
Collection.OnEntryAdded = Rebuild;
Collection.OnEntryRemoved = Rebuild;
Content = Layout.Column();
base.Layout.Add( Content );
Layout layout = base.Layout.AddRow();
layout.Margin = 8;
layout.AddStretchCell();
addButton = layout.Add( new Button( "Add Note" )
{
ToolTip = "Add new note",
} );
addButton.MinimumWidth = 200;
addButton.Clicked = () => AddEntry();
layout.AddStretchCell();
Rebuild();
}
}
public void Rebuild()
{
Content.Clear( deleteWidgets: true );
Content.Margin = 0f;
Layout layout = Layout.Column();
layout.Spacing = 2f;
int num = 0;
int count = Collection.Count();
for ( int i = 0; i < count; i++ )
{
var item = Collection.ElementAt( i );
int index = num;
var itemLayout = Layout.Row();
itemLayout.Spacing = 4f;
// try to get object
if ( item.TryGetAsObject( out var obj ) )
{
var thing = new SFXRNoteSheet( obj );
itemLayout.Add( thing );
}
else
{
var thing = ControlWidget.Create( item );
thing.MinimumHeight = 100;
itemLayout.Add( thing );
}
var buttonLayout = Layout.Column();
if ( i > 0 )
{
buttonLayout.Add( new IconButton( "arrow_upward", delegate
{
MoveUp( index );
} )
{
Background = Color.Transparent,
FixedWidth = ControlWidget.ControlRowHeight,
FixedHeight = ControlWidget.ControlRowHeight,
ToolTip = "Move note up"
} );
}
else
{
buttonLayout.AddSpacingCell( 25 );
}
buttonLayout.Add( new IconButton( "delete", delegate
{
RemoveEntry( index );
} )
{
Background = Color.Red,
FixedWidth = ControlWidget.ControlRowHeight,
FixedHeight = ControlWidget.ControlRowHeight,
ToolTip = "Delete note"
} );
if ( i < count - 1 )
{
buttonLayout.Add( new IconButton( "arrow_downward", delegate
{
MoveDown( index );
} )
{
Background = Color.Transparent,
FixedWidth = ControlWidget.ControlRowHeight,
FixedHeight = ControlWidget.ControlRowHeight,
ToolTip = "Move note down"
} );
}
else
{
buttonLayout.AddSpacingCell( 25 );
}
itemLayout.Add( buttonLayout );
layout.Add( itemLayout );
num++;
}
MinimumHeight = 50 + (num * 105);
Content.Add( layout );
Content.Margin = ((num > 0) ? 3 : 0);
}
private void AddEntry()
{
Collection.Add( new SFXRSequencer.Note() );
}
private void RemoveEntry( int index )
{
Collection.RemoveAt( index );
}
private void MoveUp( int index )
{
// Move the index up in Sequencer.Notes list
if ( index > 0 )
{
var note = Sequencer.Notes[index];
Sequencer.Notes.RemoveAt( index );
Sequencer.Notes.Insert( index - 1, note );
}
Rebuild();
}
private void MoveDown( int index )
{
// Move the index down in Sequencer.Notes list
if ( index < Sequencer.Notes.Count - 1 )
{
var note = Sequencer.Notes[index];
Sequencer.Notes.RemoveAt( index );
Sequencer.Notes.Insert( index + 1, note );
}
Rebuild();
}
protected override void OnPaint()
{
}
public void AddEffectDialog( Button source )
{
var s = new SFXREffectTypeSelector( this );
s.OnSelect += ( t ) => AddEffect( t );
s.OpenAt( source.ScreenRect.BottomLeft, animateOffset: new Vector2( 0, -4 ) );
s.FixedWidth = source.Width;
}
void AddEffect( TypeDescription type )
{
if ( !type.TargetType.IsAssignableTo( typeof( SFXREffect ) ) )
{
Log.Error( $"Type {type.TargetType} is not assignable to {typeof( SFXREffect )}" );
return;
}
SFXREffect effect = type.Create<SFXREffect>();
Collection.Add( effect );
Log.Info( effect );
}
}
using System;
using System.Collections.Generic;
using Sandbox;
namespace SFXR;
[Title( "ADSR Envelope" )]
[Category( "SFXR Effects" )]
[Icon( "mail_outline" )]
public class SFXREnvelope : SFXREffect
{
/// <summary>
/// Time the sound takes to reach its peak amplitude
/// (Default: 0)
/// </summary>
[Property, Range( 0, 10 )]
public float Attack { get; set; } = 0;
/// <summary>
/// The time taken for the sound to fade to the sustain level
/// </summary>
[Property, Range( 0, 10 )]
public float Decay { get; set; } = 0;
/// <summary>
/// The level maintained until release is triggered
/// (Default: 1)
/// </summary>
[Property, Range( 0, 1 )]
public float Sustain { get; set; } = 1f;
/// <summary>
/// The time taken for the sound to fade to zero after the sustain
/// (Default: 0.3)
/// </summary>
[Property, Range( 0, 10 )]
public float SustainTime { get; set; } = 0.3f;
/// <summary>
/// The time taken for the sound to fade to zero after the release
/// (Default: 0.4)
/// </summary>
[Property, Range( 0, 10 )]
public float Release { get; set; } = 0.4f;
/// <summary>
/// Returns the amplitude of the envelope at a given time
/// </summary>
/// <param name="time">Time in seconds</param>
/// <returns>Amplitude of the envelope at the given time</returns>
public float GetAmplitude( float time )
{
return GetCurve().Evaluate( time / GetLength() );
}
public override short[] Apply( short[] samples, SFXRComponent sound )
{
// Calculate the envelope amplitude for each sample
for ( int i = 0; i < samples.Length; i++ )
{
float t = i / (float)sound.SampleRate;
float amplitude = GetAmplitude( t );
samples[i] = (short)(samples[i] * amplitude);
}
return samples;
}
public float GetLength()
{
return Attack + Decay + SustainTime + Release;
}
public Curve GetCurve()
{
Curve curve = new();
List<Vector2> points = new();
// Add the attack curve
points.Add( new Vector2( 0, 0 ) );
points.Add( new Vector2( Attack, 1 ) );
// Add the decay curve
points.Add( new Vector2( Attack + Decay, Sustain ) );
// Add the sustain curve
points.Add( new Vector2( Attack + Decay + SustainTime, Sustain ) );
// Add the release curve
points.Add( new Vector2( Attack + Decay + SustainTime + Release, 0 ) );
// Normalize the curve to 0-1 in the x
for ( int i = 0; i < points.Count; i++ )
{
points[i] = new Vector2( points[i].x / (Attack + Decay + SustainTime + Release), points[i].y );
}
// Add the points to the curve
foreach ( var point in points )
{
curve.AddPoint( point.x, point.y );
}
return curve;
}
}using Sandbox;
public sealed class SceneTrigger : Component, Component.ITriggerListener
{
[Property] public SceneFile SceneFile { get; set; }
protected override void OnUpdate()
{
}
void ITriggerListener.OnTriggerEnter(Sandbox.Collider other)
{
if (other.GameObject.Parent.Tags.Has("player") || other.GameObject.Tags.Has("boat"))
{
Game.ActiveScene.Load(SceneFile);
}
}
void ITriggerListener.OnTriggerExit(Sandbox.Collider other)
{
}
}
using System.Collections.Generic;
namespace Sandbox;
/// <summary>
/// How to use the system:
/// <code>
/// public sealed class ExampleComponent : Component
/// {
/// // Reference to the system.
/// private FixedUpdateInputSystem _fixedInput;
///
/// protected override void Start()
/// {
/// // Get the reference like this:
/// _fixedInput = Scene.GetSystem<FixedUpdateInputSystem>();
///
/// base.OnStart();
/// }
///
/// protected override void OnFixedUpdate()
/// {
/// // Query for input like usual.
/// if( _fixedInput.Pressed("jump") )
/// {
/// Log.Info("Jumped");
/// }
///
/// base.OnFixedUpdate();
/// }
/// }
/// </code>
/// </summary>
public sealed class FixedUpdateInputSystem : GameObjectSystem
{
private struct FixedUpdateInputBuffer
{
private class State
{
public bool Held;
public bool Pressed;
public bool Released;
}
private Dictionary<string, State> _actionStates;
public FixedUpdateInputBuffer()
{
_actionStates = new Dictionary<string, State>();
foreach ( var b in Input.GetActions() )
{
_actionStates[b.Name.ToLowerInvariant()] = new State();
}
}
/// <summary>
/// Call from a <see cref="Component.OnUpdate"/> method
/// to update the states of the actions.
/// </summary>
public void OnUpdate()
{
foreach ( var (name, state) in _actionStates )
{
if ( Input.Down( name ) )
_actionStates[name].Held = true;
if ( Input.Pressed( name ) )
_actionStates[name].Pressed = true;
if ( Input.Released( name ) )
_actionStates[name].Released = true;
}
}
/// <summary>
/// Call from a <see cref="Component.OnFixedUpdate"/>
/// method to get the <see cref="State.Held"/> state of this action.
/// </summary>
/// <param name="action">The action name (case insensitive).</param>
/// <returns></returns>
///
public bool Held( string action )
{
return _actionStates[action.ToLowerInvariant()].Held;
}
/// <summary>
/// Call from a <see cref="Component.OnFixedUpdate"/>
/// method to get the <see cref="State.Pressed"/> state of this action.
/// </summary>
/// <param name="action">The action name (case insensitive).</param>
/// <returns></returns>
public bool Pressed( string action )
{
return _actionStates[action.ToLowerInvariant()].Pressed;
}
/// <summary>
/// Call from a <see cref="Component.OnFixedUpdate"/>
/// method to get the <see cref="State.Pressed"/> state of this action.
/// </summary>
/// <param name="action">The action name (case insensitive).</param>
/// <returns></returns>
public bool Released( string action )
{
return _actionStates[action.ToLowerInvariant()].Released;
}
/// <summary>
/// Call at the end of your <see cref="Component.OnFixedUpdate"/> method
/// to clear the state of the struct and reset.
/// </summary>
public void Clear()
{
foreach ( var actionName in _actionStates.Keys )
{
_actionStates[actionName].Held = false;
_actionStates[actionName].Pressed = false;
}
}
}
private FixedUpdateInputBuffer _buffer;
public FixedUpdateInputSystem( Scene scene ) : base( scene )
{
_buffer = new();
Listen( Stage.StartUpdate, int.MinValue, OnStartUpdate, "FUIB.OnStartUpdate" );
Listen( Stage.FinishFixedUpdate, int.MaxValue, OnFinishFixedUpdate, "FUIB.OnFinishFixedUpdate" );
}
private void OnStartUpdate()
{
_buffer.OnUpdate();
}
private void OnFinishFixedUpdate()
{
_buffer.Clear();
}
/// <summary>
/// Is the action currently held down?
/// </summary>
/// <param name="action">The action name (case insensitive).</param>
/// <returns></returns>
///
public bool Held( string action ) => _buffer.Held( action );
/// <summary>
/// Was the action pressed?
/// </summary>
/// <param name="action">The action name (case insensitive).</param>
/// <returns></returns>
public bool Pressed( string action ) => _buffer.Pressed( action );
/// <summary>
/// Was the action released?
/// </summary>
/// <param name="action">The action name (case insensitive).</param>
/// <returns></returns>
public bool Released( string action ) => _buffer.Released( action );
}
using System;
namespace Sandbox.Events;
/// <summary>
/// Only valid on <see cref="IGameEventHandler{T}.OnGameEvent"/> implementations. Forces this
/// event handler to be invoked before any handlers not marked as early, except if more specific
/// constraints are given (i.e., <see cref="BeforeAttribute{T}"/>, <see cref="AfterAttribute{T}"/>).
/// </summary>
[AttributeUsage( AttributeTargets.Method )]
public sealed class EarlyAttribute : Attribute
{
}
/// <summary>
/// Only valid on <see cref="IGameEventHandler{T}.OnGameEvent"/> implementations. Forces this
/// event handler to be invoked after any handlers not marked as late, except if more specific
/// constraints are given (i.e., <see cref="BeforeAttribute{T}"/>, <see cref="AfterAttribute{T}"/>).
/// </summary>
[AttributeUsage( AttributeTargets.Method )]
public sealed class LateAttribute : Attribute
{
}
internal interface IBeforeAttribute
{
Type Type { get; }
}
internal interface IAfterAttribute
{
Type Type { get; }
}
/// <summary>
/// Only valid on <see cref="IGameEventHandler{T}.OnGameEvent"/> implementations. Forces this
/// event handler to be invoked before any handlers in the specified type.
/// </summary>
[AttributeUsage( AttributeTargets.Method, AllowMultiple = true )]
public sealed class BeforeAttribute<T> : Attribute, IBeforeAttribute
{
Type IBeforeAttribute.Type => typeof(T);
}
/// <summary>
/// Only valid on <see cref="IGameEventHandler{T}.OnGameEvent"/> implementations. Forces this
/// event handler to be invoked after any handlers in the specified type.
/// </summary>
[AttributeUsage( AttributeTargets.Method, AllowMultiple = true )]
public sealed class AfterAttribute<T> : Attribute, IAfterAttribute
{
Type IAfterAttribute.Type => typeof( T );
}
using System.Collections.Generic;
using System.Linq;
namespace Sandbox.Events;
/// <summary>
/// Generate an ordering based on a set of first-most and last-most items, and
/// individual constraints between pairs of items. All first-most items will be
/// ordered before all last-most items, and any other items will be put in the
/// middle unless forced to be elsewhere by a constraint.
/// </summary>
internal class SortingHelper
{
public record struct SortConstraint( int EarlierIndex, int LaterIndex )
{
public SortConstraint Complement => new ( LaterIndex, EarlierIndex );
}
private readonly int _itemCount;
private readonly HashSet<SortConstraint> _initialConstraints = new HashSet<SortConstraint>();
private readonly HashSet<int> _first = new HashSet<int>();
private readonly HashSet<int> _last = new HashSet<int>();
public SortingHelper( int itemCount )
{
_itemCount = itemCount;
}
public void AddConstraint( int earlierIndex, int laterIndex )
{
_initialConstraints.Add( new SortConstraint( earlierIndex, laterIndex ) );
}
public void AddFirst( int earlierIndex )
{
_first.Add( earlierIndex );
}
public void AddLast( int laterIndex )
{
_last.Add( laterIndex );
}
public bool Sort( List<int> result, out SortConstraint invalidConstraint )
{
var middle = new HashSet<int>();
for ( var index = 0; index < _itemCount; ++index )
{
if ( !_first.Contains( index ) && !_last.Contains( index ) )
middle.Add( index );
}
var allConstraints = new HashSet<SortConstraint>();
var newConstraints = new Queue<SortConstraint>();
var beforeDict = new Dictionary<int, HashSet<int>>();
var afterDict = new Dictionary<int, HashSet<int>>();
bool AddWorkingConstraint( int earlierIndex, int laterIndex, out SortConstraint constraint )
{
constraint = new SortConstraint( earlierIndex, laterIndex );
if ( allConstraints.Contains( constraint.Complement ) )
return false;
if ( !allConstraints.Add( constraint ) )
return true;
newConstraints.Enqueue( constraint );
if ( !beforeDict.TryGetValue( earlierIndex, out var before ) )
beforeDict.Add( earlierIndex, before = new HashSet<int>() );
if ( !afterDict.TryGetValue( laterIndex, out var after ) )
afterDict.Add( laterIndex, after = new HashSet<int>() );
before.Add( laterIndex );
after.Add( earlierIndex );
return true;
}
// Add initial constraints
foreach ( var initialConstraint in _initialConstraints )
{
if ( !AddWorkingConstraint( initialConstraint.EarlierIndex, initialConstraint.LaterIndex, out invalidConstraint ) )
return false;
}
// Everything in _first should be before everything in _last
foreach ( var earlierIndex in _first )
{
foreach ( var laterIndex in _last )
{
if ( !AddWorkingConstraint( earlierIndex, laterIndex, out invalidConstraint ) )
return false;
}
}
// Keep propagating constraints until nothing changes
while ( newConstraints.TryDequeue( out var nextConstraint ) )
{
// if a < b, and b < c, then a < c etc
if ( beforeDict.TryGetValue( nextConstraint.LaterIndex, out var before ) )
{
foreach ( var laterIndex in before )
{
if ( !AddWorkingConstraint( nextConstraint.EarlierIndex, laterIndex, out invalidConstraint ) )
return false;
}
}
if ( afterDict.TryGetValue( nextConstraint.EarlierIndex, out var after ) )
{
foreach ( var earlierIndex in after )
{
if ( !AddWorkingConstraint( earlierIndex, nextConstraint.LaterIndex, out invalidConstraint ) )
{
return false;
}
}
}
}
// Now if we have any items that aren't using GroupOrder.First, and haven't
// determined that they are ordered before another item with GroupOrder.First,
// we can safely order them after all GroupOrder.First items. And vice versa.
foreach ( var middleIndex in middle )
{
var isBeforeAnyFirst = beforeDict.TryGetValue( middleIndex, out var before )
&& before.Any( x => _first.Contains( x ) );
var isAfterAnyLast = afterDict.TryGetValue( middleIndex, out var after )
&& after.Any( x => _last.Contains( x ) );
if ( !isBeforeAnyFirst )
{
foreach ( var earlierIndex in _first )
AddWorkingConstraint( earlierIndex, middleIndex, out invalidConstraint );
}
if ( !isAfterAnyLast )
{
foreach ( var laterIndex in _last )
AddWorkingConstraint( middleIndex, laterIndex, out invalidConstraint );
}
}
// Now lets add items to the final ordering if all items that should be sorted
// before them are already added to that ordering. We'll implement this by choosing
// items that have an empty list / don't appear in afterDict, and update that
// dictionary as we go.
var earliestRemaining = new Queue<int>();
// First, seed the queue with everything that's already not ordered after anything
for ( var index = 0; index < _itemCount; ++index )
{
if ( !afterDict.ContainsKey( index ) )
{
earliestRemaining.Enqueue( index );
}
}
result.Clear();
while ( earliestRemaining.TryDequeue( out var nextIndex ) )
{
result.Add( nextIndex );
foreach ( var laterIndex in beforeDict.TryGetValue( nextIndex, out var laterIndices )
? laterIndices : Enumerable.Empty<int>() )
{
var beforeLater = afterDict[laterIndex];
beforeLater.Remove( nextIndex );
if ( beforeLater.Count == 0 )
earliestRemaining.Enqueue( laterIndex );
}
}
invalidConstraint = default;
return result.Count == _itemCount;
}
}
using Sandbox;
[TestClass]
public partial class LibraryTests
{
[TestMethod]
public void SceneTest()
{
var scene = new Scene();
using ( scene.Push() )
{
var go = new GameObject();
Assert.AreEqual( 1, scene.Directory.GameObjectCount );
}
}
}
public sealed class PlayerPusher : Component
{
[Property] public float Radius { get; set; } = 100;
protected override void DrawGizmos()
{
base.DrawGizmos();
Gizmo.Draw.LineSphere( Vector3.Zero, Radius );
}
public static Vector3 GetPushVector( in Vector3 position, Scene scene, GameObject ignore )
{
Vector3 vec = default;
foreach ( var pusher in scene.GetAllComponents<PlayerPusher>() )
{
if ( pusher.GameObject.IsAncestor( ignore ) )
continue;
pusher.Collect( position, ref vec );
}
return vec;
}
private void Collect( Vector3 position, ref Vector3 output )
{
var delta = (position - Transform.Position);
if ( delta.Length > Radius ) return;
delta.z = 0; // ignore z
var distanceDelta = (delta.Length / Radius);
output += delta.Normal * (1.0f - distanceDelta);
}
}
using Sandbox;
[TestClass]
public partial class LibraryTests
{
[TestMethod]
public void SceneTest()
{
var scene = new Scene();
using ( scene.Push() )
{
var go = new GameObject();
Assert.AreEqual( 1, scene.Directory.GameObjectCount );
}
}
}
using System.Collections.Generic;
using System.Linq;
using System.Text;
using System.Text.Json;
using Sandbox;
using System.Threading.Tasks;
public sealed class WebSocketUtility : Component
{
[Property] public List<WebsocketTools> websocketToolsList { get; set; }
protected override void OnAwake()
{
foreach ( var websocketTools in websocketToolsList )
{
if ( websocketTools.url is null )
{
Log.Error( "WebsocketTools URL is null" );
return;
}
websocketTools.webSocket = new WebSocket();
ConnectToSocket( websocketTools.webSocket, websocketTools.url );
websocketTools.isConnected = true;
websocketTools.webSocket.OnMessageReceived += websocketTools.OnMessageReceivedMethod;
websocketTools.isSubscribed = true;
}
}
protected override void OnUpdate()
{
SendMessageFromList( WebsocketTools.Fetch.OnUpdate );
}
protected override void OnFixedUpdate()
{
SendMessageFromList( WebsocketTools.Fetch.OnFixedUpdate );
}
protected override void OnStart()
{
SendMessageFromList( WebsocketTools.Fetch.OnStart );
}
private async void SendMessageFromList( WebsocketTools.Fetch fetch )
{
foreach ( var websocketTools in websocketToolsList )
{
if ( websocketTools.fetch == fetch )
{
if ( websocketTools.message.UseJsonTags )
{
var jsonStrings = websocketTools.message.jsonTags.Select( tag => Json.Serialize( tag.ToString() ) );
var bigString = string.Join( "", jsonStrings );
var finalJsonString = Json.Serialize( bigString );
await websocketTools.webSocket.Send( finalJsonString );
}
else
{
var messageBytes = Encoding.UTF8.GetBytes( websocketTools.message.message );
await websocketTools.webSocket.Send( messageBytes );
}
}
}
}
[Description( "Sends a message over a websocket connection" )]
public static async Task SendAsync( WebsocketTools websocketTools )
{
if ( websocketTools.webSocket is null )
{
websocketTools.webSocket = new WebSocket();
}
if ( !websocketTools.isConnected )
{
await websocketTools.webSocket.Connect( websocketTools.url );
websocketTools.isConnected = true;
}
if ( websocketTools.message.UseJsonTags )
await websocketTools.webSocket.Send( Json.Serialize( websocketTools.message.jsonTags ) );
else
await websocketTools.webSocket.Send( websocketTools.message.message );
if ( !websocketTools.isSubscribed )
{
websocketTools.webSocket.OnMessageReceived += websocketTools.OnMessageReceivedMethod;
websocketTools.isSubscribed = true;
}
}
public static async Task SendStringAsync( string url, string message )
{
var webSocket = new WebSocket();
await webSocket.Connect( url );
await webSocket.Send( message );
}
public static void ChangeJsonTagValue( WebsocketMessage message, string tag, string value )
{
if ( message is null )
message = new WebsocketMessage();
if ( message.jsonTags is null )
message.jsonTags = new List<JsonTags>();
var jsonTag = message.jsonTags.Find( x => x.tag == tag );
if ( jsonTag is null )
{
Log.Warning( $"Tag {tag} not found in message" );
}
else
{
jsonTag.value = value;
}
}
public static void AddJsonTag( WebsocketMessage message, string tag, string value )
{
if ( message is null )
message = new WebsocketMessage();
if ( message.jsonTags is null )
message.jsonTags = new List<JsonTags>();
var jsonTag = new JsonTags
{
tag = tag,
value = value
};
message.jsonTags.Add( jsonTag );
}
private async void ConnectToSocket( WebSocket webSocket, string url )
{
await webSocket.Connect( url );
}
[ActionGraphNode( "new websocket tools" ), Pure]
public static WebsocketTools NewWebsocketTools()
{
return new WebsocketTools();
}
}
public class WebsocketTools
{
public delegate void OnMessageReceived( string message );
public OnMessageReceived onMessageReceived { get; set; }
public WebSocket webSocket { get; set; }
public string url { get; set; }
public WebsocketMessage message { get; set; } = new();
public bool isConnected { get; set; }
public bool isSubscribed { get; set; }
public string returnMessage { get; set; }
public enum Fetch
{
OnUpdate,
OnFixedUpdate,
OnStart,
}
public Fetch fetch { get; set; }
public void OnMessageReceivedMethod( string message )
{
onMessageReceived?.Invoke( message );
returnMessage = message;
}
public WebsocketTools()
{
url = "ws://localhost:8080";
fetch = Fetch.OnUpdate;
onMessageReceived = null;
message = null;
}
public WebsocketTools( string url, OnMessageReceived onMessageReceived, WebsocketMessage message, Fetch fetch = Fetch.OnUpdate )
{
this.url = url;
this.fetch = fetch;
this.onMessageReceived = onMessageReceived;
this.message = message;
}
}
[GameResource( "Message", "message", "A message to be sent over a websocket connection", Icon = "chat_bubble" )]
public class WebsocketMessage : GameResource
{
public bool UseJsonTags { get; set; }
[ShowIf( "UseJsonTags", false )] public string message { get; set; } = "";
[ShowIf( "UseJsonTags", true )] public List<JsonTags> jsonTags { get; set; } = new();
}
public class JsonTags
{
public string tag { get; set; }
public string value { get; set; }
}
using Sandbox;
using System.Collections.Generic;
namespace EZCameraShake
{
public class CameraShaker : Component
{
/// <summary>
/// The single instance of the CameraShaker in the current scene. Do not use if you have multiple instances.
/// </summary>
public static CameraShaker Instance;
static Dictionary<string, CameraShaker> instanceList = new Dictionary<string, CameraShaker>();
/// <summary>
/// The default position influcence of all shakes created by this shaker.
/// </summary>
[Property] public Vector3 DefaultPosInfluence = new Vector3(0.15f, 0.15f, 0.15f);
/// <summary>
/// The default rotation influcence of all shakes created by this shaker.
/// </summary>
[Property] public Vector3 DefaultRotInfluence = new Vector3(1, 1, 1);
/// <summary>
/// Offset that will be applied to the camera's default (0,0,0) rest position
/// </summary>
[Property] public Vector3 RestPositionOffset = new Vector3(0, 0, 0);
/// <summary>
/// Offset that will be applied to the camera's default (0,0,0) rest rotation
/// </summary>
[Property] public Vector3 RestRotationOffset = new Vector3(0, 0, 0);
Vector3 posAddShake, rotAddShake;
List<CameraShakeInstance> cameraShakeInstances = new List<CameraShakeInstance>();
protected override void OnAwake()
{
Instance = this;
instanceList.Add(GameObject.Name, this);
}
protected override void OnUpdate()
{
posAddShake = Vector3.Zero;
rotAddShake = Vector3.Zero;
for (int i = 0; i < cameraShakeInstances.Count; i++)
{
if (i >= cameraShakeInstances.Count)
break;
CameraShakeInstance c = cameraShakeInstances[i];
if (c.CurrentState == CameraShakeState.Inactive && c.DeleteOnInactive)
{
cameraShakeInstances.RemoveAt(i);
i--;
}
else if (c.CurrentState != CameraShakeState.Inactive)
{
posAddShake += CameraUtilities.MultiplyVectors(c.UpdateShake(), c.PositionInfluence);
rotAddShake += CameraUtilities.MultiplyVectors(c.UpdateShake(), c.RotationInfluence);
}
}
Transform.LocalPosition = (posAddShake) + RestPositionOffset;
Vector3 thing = (rotAddShake / 100) + RestRotationOffset;
Transform.LocalRotation = new Angles(thing.x, thing.y, thing.z);
}
/// <summary>
/// Gets the CameraShaker with the given name, if it exists.
/// </summary>
/// <param name="name">The name of the camera shaker instance.</param>
/// <returns></returns>
public static CameraShaker GetInstance(string name)
{
CameraShaker c;
if (instanceList.TryGetValue(name, out c))
return c;
Log.Error("CameraShake " + name + " not found!");
return null;
}
/// <summary>
/// Starts a shake using the given preset.
/// </summary>
/// <param name="shake">The preset to use.</param>
/// <returns>A CameraShakeInstance that can be used to alter the shake's properties.</returns>
public CameraShakeInstance Shake(CameraShakeInstance shake)
{
cameraShakeInstances.Add(shake);
return shake;
}
/// <summary>
/// Shake the camera once, fading in and out over a specified durations.
/// </summary>
/// <param name="magnitude">The intensity of the shake.</param>
/// <param name="roughness">Roughness of the shake. Lower values are smoother, higher values are more jarring.</param>
/// <param name="fadeInTime">How long to fade in the shake, in seconds.</param>
/// <param name="fadeOutTime">How long to fade out the shake, in seconds.</param>
/// <returns>A CameraShakeInstance that can be used to alter the shake's properties.</returns>
public CameraShakeInstance ShakeOnce(float magnitude, float roughness, float fadeInTime, float fadeOutTime)
{
CameraShakeInstance shake = new CameraShakeInstance(magnitude, roughness, fadeInTime, fadeOutTime);
shake.PositionInfluence = DefaultPosInfluence;
shake.RotationInfluence = DefaultRotInfluence;
cameraShakeInstances.Add(shake);
return shake;
}
/// <summary>
/// Shake the camera once, fading in and out over a specified durations.
/// </summary>
/// <param name="magnitude">The intensity of the shake.</param>
/// <param name="roughness">Roughness of the shake. Lower values are smoother, higher values are more jarring.</param>
/// <param name="fadeInTime">How long to fade in the shake, in seconds.</param>
/// <param name="fadeOutTime">How long to fade out the shake, in seconds.</param>
/// <param name="posInfluence">How much this shake influences position.</param>
/// <param name="rotInfluence">How much this shake influences rotation.</param>
/// <returns>A CameraShakeInstance that can be used to alter the shake's properties.</returns>
public CameraShakeInstance ShakeOnce(float magnitude, float roughness, float fadeInTime, float fadeOutTime, Vector3 posInfluence, Vector3 rotInfluence)
{
CameraShakeInstance shake = new CameraShakeInstance(magnitude, roughness, fadeInTime, fadeOutTime);
shake.PositionInfluence = posInfluence;
shake.RotationInfluence = rotInfluence;
cameraShakeInstances.Add(shake);
return shake;
}
/// <summary>
/// Start shaking the camera.
/// </summary>
/// <param name="magnitude">The intensity of the shake.</param>
/// <param name="roughness">Roughness of the shake. Lower values are smoother, higher values are more jarring.</param>
/// <param name="fadeInTime">How long to fade in the shake, in seconds.</param>
/// <returns>A CameraShakeInstance that can be used to alter the shake's properties.</returns>
public CameraShakeInstance StartShake(float magnitude, float roughness, float fadeInTime)
{
CameraShakeInstance shake = new CameraShakeInstance(magnitude, roughness);
shake.PositionInfluence = DefaultPosInfluence;
shake.RotationInfluence = DefaultRotInfluence;
shake.StartFadeIn(fadeInTime);
cameraShakeInstances.Add(shake);
return shake;
}
/// <summary>
/// Start shaking the camera.
/// </summary>
/// <param name="magnitude">The intensity of the shake.</param>
/// <param name="roughness">Roughness of the shake. Lower values are smoother, higher values are more jarring.</param>
/// <param name="fadeInTime">How long to fade in the shake, in seconds.</param>
/// <param name="posInfluence">How much this shake influences position.</param>
/// <param name="rotInfluence">How much this shake influences rotation.</param>
/// <returns>A CameraShakeInstance that can be used to alter the shake's properties.</returns>
public CameraShakeInstance StartShake(float magnitude, float roughness, float fadeInTime, Vector3 posInfluence, Vector3 rotInfluence)
{
CameraShakeInstance shake = new CameraShakeInstance(magnitude, roughness);
shake.PositionInfluence = posInfluence;
shake.RotationInfluence = rotInfluence;
shake.StartFadeIn(fadeInTime);
cameraShakeInstances.Add(shake);
return shake;
}
/// <summary>
/// Gets a copy of the list of current camera shake instances.
/// </summary>
public List<CameraShakeInstance> ShakeInstances
{ get { return new List<CameraShakeInstance>(cameraShakeInstances); } }
protected override void OnDestroy()
{
instanceList.Remove(GameObject.Name);
}
}
}
using System;
using System.Collections.Generic;
using System.Collections.Immutable;
using System.Linq;
namespace Sandbox.Events;
/// <summary>
/// Interface for event payloads that can be listened for by <see cref="IGameEventHandler{T}"/>s.
/// </summary>
public interface IGameEvent { }
/// <summary>
/// Interface for components that handle game events with a payload of type <see cref="T"/>.
/// </summary>
/// <typeparam name="T">Event payload type.</typeparam>
public interface IGameEventHandler<in T>
where T : IGameEvent
{
/// <summary>
/// Called when an event with payload of type <see cref="T"/> is dispatched on a <see cref="GameObject"/>
/// that contains this component, including on a descendant.
/// </summary>
/// <param name="eventArgs">Event payload.</param>
void OnGameEvent( T eventArgs );
}
/// <summary>
/// Helper for dispatching game events in a scene.
/// </summary>
public static class GameEvent
{
private static Dictionary<Type, IReadOnlyDictionary<Type, int>> HandlerOrderingCache { get; } = new();
/// <summary>
/// Notifies all <see cref="IGameEventHandler{T}"/> components that are within <paramref name="root"/>,
/// with a payload of type <typeparamref name="T"/>.
/// </summary>
public static void Dispatch<T>( this GameObject root, T eventArgs )
where T : IGameEvent
{
var handlers = (root is Scene scene
? scene.GetAllComponents<IGameEventHandler<T>>() // I think this is more efficient?
: root.Components.GetAll<IGameEventHandler<T>>())
.ToArray();
if ( !HandlerOrderingCache.TryGetValue( typeof(T), out var ordering ) || handlers.Any( x => !ordering.ContainsKey( x.GetType() ) ) )
{
ordering = HandlerOrderingCache[typeof(T)] = GetHandlerOrdering<T>();
}
List<Exception>? exceptions = null;
foreach ( var handler in handlers.OrderBy( x => ordering[x.GetType()] ) )
{
try
{
handler.OnGameEvent( eventArgs );
}
catch ( Exception e )
{
exceptions ??= new();
exceptions.Add( e );
}
}
switch ( exceptions?.Count )
{
case 1:
Log.Error( exceptions[0] );
break;
case > 1:
Log.Error( new AggregateException( exceptions ) );
break;
}
}
private static bool IsImplementingMethodName( string methodName )
{
if ( methodName == nameof(IGameEventHandler<IGameEvent>.OnGameEvent) )
{
return true;
}
return methodName.StartsWith( "Sandbox.Events.IGameEventHandler<" ) && methodName.EndsWith( ">.OnGameEvent" );
}
private static MethodDescription? GetImplementation<T>( TypeDescription type )
{
foreach ( var method in type.Methods )
{
if ( method.IsStatic ) continue;
if ( method.Parameters.Length != 1 ) continue;
if ( method.Parameters[0].ParameterType != typeof( T ) ) continue;
if ( !IsImplementingMethodName( method.Name ) ) continue;
return method;
}
return null;
}
private static IReadOnlyDictionary<Type, int> GetHandlerOrdering<T>()
where T : IGameEvent
{
var types = TypeLibrary.GetTypes<IGameEventHandler<T>>().ToArray();
var helper = new SortingHelper( types.Length );
for ( var i = 0; i < types.Length; ++i )
{
var type = types[i];
var method = GetImplementation<T>( type );
if ( method is null )
{
Log.Warning( $"Can't find {nameof( IGameEventHandler<T> )}<{typeof( T ).Name}> implementation in {type.Name}!" );
continue;
}
foreach ( var attrib in method.Attributes )
{
switch ( attrib )
{
case EarlyAttribute:
helper.AddFirst( i );
break;
case LateAttribute:
helper.AddLast( i );
break;
case IBeforeAttribute before:
for ( var j = 0; j < types.Length; ++j )
{
if ( i == j ) continue;
var other = types[j];
if ( before.Type.IsAssignableFrom( other.TargetType ) )
{
helper.AddConstraint( i, j );
}
}
break;
case IAfterAttribute after:
for ( var j = 0; j < types.Length; ++j )
{
if ( i == j ) continue;
var other = types[j];
if ( after.Type.IsAssignableFrom( other.TargetType ) )
{
helper.AddConstraint( j, i );
}
}
break;
}
}
}
var ordering = new List<int>();
if ( !helper.Sort( ordering, out var invalid ) )
{
Log.Error( $"Invalid event ordering constraint between {types[invalid.EarlierIndex].Name} and {types[invalid.LaterIndex].Name}!" );
return ImmutableDictionary<Type, int>.Empty;
}
return Enumerable.Range( 0, ordering.Count )
.ToImmutableDictionary( i => types[ordering[i]].TargetType, i => i );
}
}
public delegate void GameEventAction<in T>( T eventArgs )
where T : IGameEvent;
/// <summary>
/// Base class for components that expose game events to Action Graph.
/// </summary>
public abstract class GameEventComponent<T> : Component, IGameEventHandler<T>
where T : IGameEvent
{
/// <summary>
/// Action invoked when the <typeparamref name="T"/> event is dispatched.
/// </summary>
[Property]
public GameEventAction<T>? OnEvent { get; set; }
/// <summary>
/// If this component is within a state machine, optional state to transition
/// to when this event is dispatched.
/// </summary>
[Property]
public StateComponent? NextState { get; set; }
void IGameEventHandler<T>.OnGameEvent( T eventArgs )
{
OnEvent?.Invoke( eventArgs );
if ( NextState is not null )
{
Components.GetInAncestorsOrSelf<StateMachineComponent>()?.Transition( NextState );
}
}
}
using System.Collections.Generic;
using System.Linq;
namespace Sandbox.Events;
/// <summary>
/// Generate an ordering based on a set of first-most and last-most items, and
/// individual constraints between pairs of items. All first-most items will be
/// ordered before all last-most items, and any other items will be put in the
/// middle unless forced to be elsewhere by a constraint.
/// </summary>
internal class SortingHelper
{
public record struct SortConstraint( int EarlierIndex, int LaterIndex )
{
public SortConstraint Complement => new ( LaterIndex, EarlierIndex );
}
private readonly int _itemCount;
private readonly HashSet<SortConstraint> _initialConstraints = new HashSet<SortConstraint>();
private readonly HashSet<int> _first = new HashSet<int>();
private readonly HashSet<int> _last = new HashSet<int>();
public SortingHelper( int itemCount )
{
_itemCount = itemCount;
}
public void AddConstraint( int earlierIndex, int laterIndex )
{
_initialConstraints.Add( new SortConstraint( earlierIndex, laterIndex ) );
}
public void AddFirst( int earlierIndex )
{
_first.Add( earlierIndex );
}
public void AddLast( int laterIndex )
{
_last.Add( laterIndex );
}
public bool Sort( List<int> result, out SortConstraint invalidConstraint )
{
var middle = new HashSet<int>();
for ( var index = 0; index < _itemCount; ++index )
{
if ( !_first.Contains( index ) && !_last.Contains( index ) )
middle.Add( index );
}
var allConstraints = new HashSet<SortConstraint>();
var newConstraints = new Queue<SortConstraint>();
var beforeDict = new Dictionary<int, HashSet<int>>();
var afterDict = new Dictionary<int, HashSet<int>>();
bool AddWorkingConstraint( int earlierIndex, int laterIndex, out SortConstraint constraint )
{
constraint = new SortConstraint( earlierIndex, laterIndex );
if ( allConstraints.Contains( constraint.Complement ) )
return false;
if ( !allConstraints.Add( constraint ) )
return true;
newConstraints.Enqueue( constraint );
if ( !beforeDict.TryGetValue( earlierIndex, out var before ) )
beforeDict.Add( earlierIndex, before = new HashSet<int>() );
if ( !afterDict.TryGetValue( laterIndex, out var after ) )
afterDict.Add( laterIndex, after = new HashSet<int>() );
before.Add( laterIndex );
after.Add( earlierIndex );
return true;
}
// Add initial constraints
foreach ( var initialConstraint in _initialConstraints )
{
if ( !AddWorkingConstraint( initialConstraint.EarlierIndex, initialConstraint.LaterIndex, out invalidConstraint ) )
return false;
}
// Everything in _first should be before everything in _last
foreach ( var earlierIndex in _first )
{
foreach ( var laterIndex in _last )
{
if ( !AddWorkingConstraint( earlierIndex, laterIndex, out invalidConstraint ) )
return false;
}
}
// Keep propagating constraints until nothing changes
while ( newConstraints.TryDequeue( out var nextConstraint ) )
{
// if a < b, and b < c, then a < c etc
if ( beforeDict.TryGetValue( nextConstraint.LaterIndex, out var before ) )
{
foreach ( var laterIndex in before )
{
if ( !AddWorkingConstraint( nextConstraint.EarlierIndex, laterIndex, out invalidConstraint ) )
return false;
}
}
if ( afterDict.TryGetValue( nextConstraint.EarlierIndex, out var after ) )
{
foreach ( var earlierIndex in after )
{
if ( !AddWorkingConstraint( earlierIndex, nextConstraint.LaterIndex, out invalidConstraint ) )
{
return false;
}
}
}
}
// Now if we have any items that aren't using GroupOrder.First, and haven't
// determined that they are ordered before another item with GroupOrder.First,
// we can safely order them after all GroupOrder.First items. And vice versa.
foreach ( var middleIndex in middle )
{
var isBeforeAnyFirst = beforeDict.TryGetValue( middleIndex, out var before )
&& before.Any( x => _first.Contains( x ) );
var isAfterAnyLast = afterDict.TryGetValue( middleIndex, out var after )
&& after.Any( x => _last.Contains( x ) );
if ( !isBeforeAnyFirst )
{
foreach ( var earlierIndex in _first )
AddWorkingConstraint( earlierIndex, middleIndex, out invalidConstraint );
}
if ( !isAfterAnyLast )
{
foreach ( var laterIndex in _last )
AddWorkingConstraint( middleIndex, laterIndex, out invalidConstraint );
}
}
// Now lets add items to the final ordering if all items that should be sorted
// before them are already added to that ordering. We'll implement this by choosing
// items that have an empty list / don't appear in afterDict, and update that
// dictionary as we go.
var earliestRemaining = new Queue<int>();
// First, seed the queue with everything that's already not ordered after anything
for ( var index = 0; index < _itemCount; ++index )
{
if ( !afterDict.ContainsKey( index ) )
{
earliestRemaining.Enqueue( index );
}
}
result.Clear();
while ( earliestRemaining.TryDequeue( out var nextIndex ) )
{
result.Add( nextIndex );
foreach ( var laterIndex in beforeDict.TryGetValue( nextIndex, out var laterIndices )
? laterIndices : Enumerable.Empty<int>() )
{
var beforeLater = afterDict[laterIndex];
beforeLater.Remove( nextIndex );
if ( beforeLater.Count == 0 )
earliestRemaining.Enqueue( laterIndex );
}
}
invalidConstraint = default;
return result.Count == _itemCount;
}
}
using Editor;
public static class MyEditorMenu
{
[Menu( "Editor", "CrosshairBuilder/My Menu Option" )]
public static void OpenMyMenu()
{
EditorUtility.DisplayDialog( "It worked!", "This is being called from your library's editor code!" );
}
}
using Braxnet;
using Sandbox;
[TestClass]
public partial class LibraryTests
{
[TestMethod]
public void SceneTest()
{
var scene = new Scene();
using ( scene.Push() )
{
// var go = new GameObject();
Assert.AreEqual( 1, scene.Directory.GameObjectCount );
Assert.IsTrue( scene.Directory.FindByName( "LibraryTestComponent" ) != null );
}
}
}
[Autoload]
public class LibraryTestComponent : Component
{
}
public sealed class JiggleBone : TransformProxyComponent
{
JiggleBoneState state = new JiggleBoneState();
[Property]
public Vector3 StartPoint = new Vector3( 0, 0, 0 );
[Property]
public Vector3 EndPoint = new Vector3( 32, 0, 0 );
[Property, Range( 0, 2 )]
public float Speed { get; set; } = 1.0f;
[Property, Range( 0, 2 )]
public float Stiffness { get; set; } = 1.0f;
[Property, Range( 0, 2 )]
public float Damping { get; set; } = 1.0f;
[Property, Range( 0, 100 )]
public float Radius { get; set; } = 40.0f;
[Property, Range( 0, 100 )]
public float Mass { get; set; } = 1.0f;
Transform LocalJigglePosition;
protected override void OnEnabled()
{
LocalJigglePosition = Transform.Local;
base.OnEnabled();
state = new JiggleBoneState();
}
protected override void OnUpdate()
{
var oldPos = LocalJigglePosition;
using ( Transform.DisableProxy() )
{
var worldTx = Transform.World;
var startPoint = worldTx.PointToWorld( StartPoint );
var endPoint = worldTx.PointToWorld( EndPoint );
//Gizmo.Draw.LineSphere( startPoint, 1 );
//Gizmo.Draw.LineSphere( endPoint, 1 );
state.Extent = (endPoint - startPoint);
state.Stiffness = Stiffness;
state.Damping = Damping;
state.Radius = Radius;
state.Mass = Mass;
state.Update( startPoint, Time.Delta * Speed * 16.0f );
var tx = worldTx.RotateAround( startPoint, state.Rotation );
LocalJigglePosition = GameObject.Parent.Transform.World.ToLocal( tx );
}
if ( oldPos != LocalJigglePosition )
{
MarkTransformChanged();
}
}
protected override void DrawGizmos()
{
base.DrawGizmos();
if ( !Gizmo.IsSelected )
return;
using ( Transform.DisableProxy() )
{
Gizmo.Transform = Transform.World;
Gizmo.Draw.IgnoreDepth = false;
Gizmo.Draw.Color = Gizmo.Colors.Yaw.WithAlpha( 0.5f );
Gizmo.Draw.Line( StartPoint, EndPoint );
Gizmo.Draw.LineBBox( BBox.FromPositionAndSize( StartPoint, 5 ) );
Gizmo.Draw.LineBBox( BBox.FromPositionAndSize( EndPoint, 5 ) );
Gizmo.Draw.LineSphere( EndPoint, Radius * 2.0f, 4 );
}
}
public override Transform GetLocalTransform()
{
return LocalJigglePosition;
}
}
class JiggleBoneState
{
public Vector3 Extent = new Vector3( 32, 0, 0 );
public Vector3 Position { get; set; }
public Rotation Rotation { get; set; }
public float Stiffness { get; set; } = 1.0f;
public float Damping { get; set; } = 1.0f;
public float Radius { get; set; } = 10.0f;
public float Gravity { get; set; } = 1.0f;
public float Mass { get; set; } = 1.0f;
Vector3 basePosition;
Vector3 velocity;
public JiggleBoneState()
{
}
internal void Update( Vector3 position, float timeDelta )
{
basePosition = position + Extent;
// initialization
if ( Position == default )
{
Position = basePosition;
}
// Calculate spring force based on displacement from the cube
Vector3 displacement = Position - basePosition;
Vector3 springForce = -Stiffness * displacement;
// Calculate acceleration (Newton's second law)
Vector3 acceleration = springForce / Mass;
// Update velocity (integrate acceleration)
velocity += acceleration * timeDelta;
// Apply exponential damping
velocity *= (float)Math.Exp( -Damping * timeDelta );
// Update position (integrate velocity)
Position += velocity * timeDelta;
{
var diff = Position - basePosition;
var diffLen = diff.Length;
if ( diffLen > Radius )
{
Position = basePosition + diff.Normal * Radius;
//velocity = velocity.AddClamped( -diff * 2.0f, diff.Length );
}
}
// Store the rotation offset result
Rotation = Rotation.FromToRotation( basePosition - position, Position - position );
//Gizmo.Draw.IgnoreDepth = true;
//Gizmo.Draw.Line( position, Position );
//Gizmo.Draw.Line( basePosition, Position );
}
}
using Sandbox;
/// <summary>
/// This is a component - in your library!
/// </summary>
[Title( "LibraryImporter - My Component" )]
public class MyLibraryComponent : Component
{
}
using Sandbox;
public sealed class CameraMovement : Component
{
[Property] public CharacterController1 Player { get; set; }
[Property] public GameObject Body { get; set; }
[Property] public GameObject Head { get; set; }
[Property] public float Distance { get; set; } = 0f;
[Property] public float Sensitivity { get; set; } = 0.1f;
public bool IsFirstPerson => Distance == 0f;
private CameraComponent Camera;
private ModelRenderer BodyRenderer;
private Vector3 CurrentOffset = Vector3.Zero;
protected override void OnAwake()
{
base.OnAwake();
Camera = Components.Get<CameraComponent>();
BodyRenderer = Body.Components.Get<ModelRenderer>();
}
protected override void OnUpdate()
{
var eyeAngles = Head.Transform.Rotation.Angles();
eyeAngles.pitch += Input.MouseDelta.y * Sensitivity;
eyeAngles.yaw -= Input.MouseDelta.x * Sensitivity;
eyeAngles.roll = 0f;
eyeAngles.pitch = eyeAngles.pitch.Clamp( -89.9f, 89.9f );
Head.Transform.Rotation = eyeAngles.ToRotation();
var targetOffset = Vector3.Zero;
if ( Player.IsCrouching ) targetOffset += Vector3.Down * 35f;
CurrentOffset = Vector3.Lerp( CurrentOffset, targetOffset, Time.Delta * 10f );
if ( Camera is not null )
{
var camPos = Head.Transform.Position + CurrentOffset;
if ( !IsFirstPerson )
{
var camForward = eyeAngles.ToRotation().Forward;
var camTrace = Scene.Trace.Ray( camPos, camPos - (camForward * Distance) )
.WithoutTags( "player", "trigger" )
.Run();
if ( camTrace.Hit )
{
camPos = camTrace.HitPosition + camTrace.Normal;
}
else
{
camPos = camTrace.EndPosition;
}
BodyRenderer.RenderType = ModelRenderer.ShadowRenderType.On;
}
else
{
BodyRenderer.RenderType = ModelRenderer.ShadowRenderType.ShadowsOnly;
}
Log.Info( CurrentOffset );
Camera.Transform.Position = camPos;
Camera.Transform.Rotation = eyeAngles.ToRotation();
}
}
}
global using System;
global using System.Linq;
global using System.Collections.Generic;
global using Editor;
global using Sandbox;
global using PathTool;
global using Application = Editor.Application;
global using Microsoft.AspNetCore.Components;
global using Microsoft.AspNetCore.Components.Rendering;
using Editor;
using System.Collections.Generic;
using Sandbox.Diagnostics;
namespace NPBehave
{
public class Parallel : Composite
{
public enum Policy
{
One,
All,
}
// public enum Wait
// {
// NEVER,
// ON_FAILURE,
// ON_SUCCESS,
// BOTH
// }
// private Wait waitForPendingChildrenRule;
private Policy _failurePolicy;
private Policy _successPolicy;
private int _childrenCount = 0;
private int _runningCount = 0;
private int _succeededCount = 0;
private int _failedCount = 0;
private Dictionary<Node, bool> _childrenResults;
private bool _successState;
private bool _childrenAborted;
public Parallel(Policy successPolicy, Policy failurePolicy, /*Wait waitForPendingChildrenRule,*/ params Node[] children) : base("Parallel", children)
{
_successPolicy = successPolicy;
_failurePolicy = failurePolicy;
// this.waitForPendingChildrenRule = waitForPendingChildrenRule;
_childrenCount = children.Length;
_childrenResults = new Dictionary<Node, bool>();
}
protected override void DoStart()
{
foreach (Node child in Children)
{
Assert.AreEqual(child.CurrentState, State.Inactive);
}
_childrenAborted = false;
_runningCount = 0;
_succeededCount = 0;
_failedCount = 0;
foreach (Node child in Children)
{
_runningCount++;
child.Start();
}
}
protected override void DoStop()
{
Assert.True(_runningCount + _succeededCount + _failedCount == _childrenCount);
foreach (Node child in Children)
{
if (child.IsActive)
{
child.Stop();
}
}
}
protected override void DoChildStopped(Node child, bool result)
{
_runningCount--;
if (result)
{
_succeededCount++;
}
else
{
_failedCount++;
}
_childrenResults[child] = result;
bool allChildrenStarted = _runningCount + _succeededCount + _failedCount == _childrenCount;
if (allChildrenStarted)
{
if (_runningCount == 0)
{
if (!_childrenAborted) // if children got aborted because rule was evaluated previously, we don't want to override the successState
{
if (_failurePolicy == Policy.One && _failedCount > 0)
{
_successState = false;
}
else if (_successPolicy == Policy.One && _succeededCount > 0)
{
_successState = true;
}
else if (_successPolicy == Policy.All && _succeededCount == _childrenCount)
{
_successState = true;
}
else
{
_successState = false;
}
}
Stopped(_successState);
}
else if (!_childrenAborted)
{
Assert.False(_succeededCount == _childrenCount);
Assert.False(_failedCount == _childrenCount);
if (_failurePolicy == Policy.One && _failedCount > 0/* && waitForPendingChildrenRule != Wait.ON_FAILURE && waitForPendingChildrenRule != Wait.BOTH*/)
{
_successState = false;
_childrenAborted = true;
}
else if (_successPolicy == Policy.One && _succeededCount > 0/* && waitForPendingChildrenRule != Wait.ON_SUCCESS && waitForPendingChildrenRule != Wait.BOTH*/)
{
_successState = true;
_childrenAborted = true;
}
if (_childrenAborted)
{
foreach (Node currentChild in Children)
{
if (currentChild.IsActive)
{
currentChild.Stop();
}
}
}
}
}
}
public override void StopLowerPriorityChildrenForChild(Node abortForChild, bool immediateRestart)
{
if (immediateRestart)
{
Assert.False(abortForChild.IsActive);
if (_childrenResults[abortForChild])
{
_succeededCount--;
}
else
{
_failedCount--;
}
_runningCount++;
abortForChild.Start();
}
else
{
throw new Exception("On Parallel Nodes all children have the same priority, thus the method does nothing if you pass false to 'immediateRestart'!");
}
}
}
}
using System.Collections;
using Sandbox.Diagnostics;
namespace NPBehave
{
public class RandomSequence : Composite
{
static System.Random _rng = new System.Random();
#if DEBUG
static public void DebugSetSeed( int seed )
{
_rng = new System.Random( seed );
}
#endif
private int _currentIndex = -1;
private int[] _randomizedOrder;
public RandomSequence(params Node[] children) : base("Random Sequence", children)
{
_randomizedOrder = new int[children.Length];
for (int i = 0; i < Children.Length; i++)
{
_randomizedOrder[i] = i;
}
}
protected override void DoStart()
{
foreach (Node child in Children)
{
Assert.AreEqual(child.CurrentState, State.Inactive);
}
_currentIndex = -1;
// Shuffling
int n = _randomizedOrder.Length;
while (n > 1)
{
int k = _rng.Next(n--);
(_randomizedOrder[n], _randomizedOrder[k]) = (_randomizedOrder[k], _randomizedOrder[n]);
}
ProcessChildren();
}
protected override void DoStop()
{
Children[_randomizedOrder[_currentIndex]].Stop();
}
protected override void DoChildStopped(Node child, bool result)
{
if (result)
{
ProcessChildren();
}
else
{
Stopped(false);
}
}
private void ProcessChildren()
{
if (++_currentIndex < Children.Length)
{
if (IsStopRequested)
{
Stopped(false);
}
else
{
Children[_randomizedOrder[_currentIndex]].Start();
}
}
else
{
Stopped(true);
}
}
public override void StopLowerPriorityChildrenForChild(Node abortForChild, bool immediateRestart)
{
int indexForChild = 0;
bool found = false;
foreach (Node currentChild in Children)
{
if (currentChild == abortForChild)
{
found = true;
}
else if (!found)
{
indexForChild++;
}
else if (found && currentChild.IsActive)
{
if (immediateRestart)
{
_currentIndex = indexForChild - 1;
}
else
{
_currentIndex = Children.Length;
}
currentChild.Stop();
break;
}
}
}
public override string ToString()
{
return $"{base.ToString()}[{_currentIndex}]";
}
}
}
namespace NPBehave
{
public class Succeeder : Decorator
{
public Succeeder(Node decoratee) : base("Succeeder", decoratee)
{
}
protected override void DoStart()
{
Decoratee.Start();
}
protected override void DoStop()
{
Decoratee.Stop();
}
protected override void DoChildStopped(Node child, bool result)
{
Stopped(true);
}
}
}using System;
namespace NPBehave
{
public class Exception : System.Exception
{
public Exception(string message) : base(message)
{
}
}
}namespace NPBehave
{
public class Repeater : Decorator
{
private int _loopCount = -1;
private int _currentLoop;
/// <param name="loopCount">number of times to execute the decoratee. Set to -1 to repeat forever, be careful with endless loops!</param>
/// <param name="decoratee">Decorated Node</param>
public Repeater(int loopCount, Node decoratee) : base("Repeater", decoratee)
{
_loopCount = loopCount;
}
/// <param name="decoratee">Decorated Node, repeated forever</param>
public Repeater(Node decoratee) : base("Repeater", decoratee)
{
}
protected override void DoStart()
{
if (_loopCount != 0)
{
_currentLoop = 0;
Decoratee.Start();
}
else
{
Stopped(true);
}
}
protected override void DoStop()
{
Clock.RemoveTimer(RestartDecoratee);
if (Decoratee.IsActive)
{
Decoratee.Stop();
}
else
{
Stopped(false);
}
}
protected override void DoChildStopped(Node child, bool result)
{
if (result)
{
if (IsStopRequested || (_loopCount > 0 && ++_currentLoop >= _loopCount))
{
Stopped(true);
}
else
{
Clock.AddTimer(0, 0, RestartDecoratee);
}
}
else
{
Stopped(false);
}
}
protected void RestartDecoratee()
{
Decoratee.Start();
}
}
}global using Sandbox;
global using System.Collections.Generic;
global using System.Linq;
global using Microsoft.VisualStudio.TestTools.UnitTesting;
[TestClass]
public class TestInit
{
[AssemblyInitialize]
public static void ClassInitialize( TestContext context )
{
Sandbox.Application.InitUnitTest();
}
}
global using Microsoft.AspNetCore.Components;
global using Microsoft.AspNetCore.Components.Rendering;
global using Sandbox;
global using System.Collections.Generic;
global using System.Linq;
using System.Threading.Tasks;
using System.Threading;
using System;
namespace Duccsoft;
/// <summary>
/// Provides a handy asynchronous wrapper for loading a VideoPlayer and waiting
/// until its video and audio are both loaded.
/// </summary>
public class AsyncVideoLoader
{
public AsyncVideoLoader()
{
_videoPlayer = new VideoPlayer();
}
public AsyncVideoLoader( VideoPlayer player )
{
_videoPlayer = player ?? new VideoPlayer();
}
public bool IsLoading { get; private set; }
private VideoPlayer _videoPlayer;
private Action _onLoaded;
private Action _onAudioReady;
public async Task<VideoPlayer> LoadFromUrl( string url, CancellationToken cancelToken = default )
{
void Play( VideoPlayer player ) => player.Play( url );
await Load( Play, cancelToken );
return _videoPlayer;
}
public async Task<VideoPlayer> LoadFromFile( BaseFileSystem fileSystem, string path, CancellationToken cancelToken )
{
void Play( VideoPlayer player ) => player.Play( fileSystem, path );
await Load( Play, cancelToken );
return _videoPlayer;
}
private async Task Load( Action<VideoPlayer> playAction, CancellationToken cancelToken = default )
{
// Attempting to play a video from a thread would throw an exception.
await GameTask.MainThread( cancelToken );
if ( IsLoading )
{
throw new InvalidOperationException( "Another video was already being loaded. Check IsLoading or create a new instance of AsyncVideoLoader." );
}
IsLoading = true;
bool videoLoaded = false;
bool audioLoaded = false;
// Assign private members instead of named methods to the invocation lists of the
// VideoPlayer delegates to break reference equality between runs.
_onLoaded = () => videoLoaded = true;
_onAudioReady = () => audioLoaded = true;
_videoPlayer.OnLoaded = _onLoaded;
_videoPlayer.OnAudioReady = _onAudioReady;
playAction?.Invoke( _videoPlayer );
// Non-blocking spin until video and audio are loaded.
while ( !videoLoaded || !audioLoaded )
{
// If OnLoaded or OnAudioReady are changed externally before we're finished
// loading, the video will likely never load. Abort to avoid spinning forever.
var callbacksChanged = _onLoaded != _videoPlayer.OnLoaded || _onAudioReady != _videoPlayer.OnAudioReady;
if ( callbacksChanged || cancelToken.IsCancellationRequested )
{
IsLoading = false;
return;
}
await GameTask.Yield();
}
IsLoading = false;
}
}
global using Microsoft.AspNetCore.Components;
global using Microsoft.AspNetCore.Components.Rendering;
using System;
using System.Collections.Generic;
using System.Linq;
using System.Threading.Tasks;
using System.IO;
using Editor;
using Sandbox;
using System.Text;
class SpectogramWidget : Widget
{
private short[] samples;
private int sampleRate;
private List<int> splitPoints = new List<int>();
private int? dragPoint = null;
private Label loadingLabel;
private Label dropLabel;
private bool isLoading = true;
public SoundFile CurrentSound { get; private set; }
public SpectogramWidget(SoundFile soundFile) : base(null)
{
MinimumSize = 100;
MouseTracking = true;
AcceptDrops = true;
loadingLabel = new Label(this);
loadingLabel.Text = "Loading audio data...";
loadingLabel.Visible = false;
dropLabel = new Label(this);
dropLabel.Text = "Drop a sound file here";
dropLabel.SetStyles("font-size: 18px; color: #aaa; text-align: center;");
if (soundFile != null)
{
LoadSound(soundFile);
}
}
public async void LoadSound(SoundFile soundFile)
{
CurrentSound = soundFile;
isLoading = true;
samples = null;
splitPoints.Clear();
loadingLabel.Visible = true;
dropLabel.Visible = false;
await LoadAudioDataAsync(soundFile);
}
private async Task LoadAudioDataAsync(SoundFile soundFile)
{
try
{
await soundFile.LoadAsync();
samples = await soundFile.GetSamplesAsync();
if (samples == null)
{
loadingLabel.Text = "Failed to load audio data";
return;
}
sampleRate = soundFile.Rate;
splitPoints.Add(0);
splitPoints.Add(samples.Length - 1);
loadingLabel.Visible = false;
isLoading = false;
Update();
}
catch (Exception ex)
{
loadingLabel.Text = $"Error loading audio: {ex.Message}";
}
}
protected override void DoLayout()
{
base.DoLayout();
if (loadingLabel != null)
{
loadingLabel.Position = new Vector2(10, Height / 2 - 10);
loadingLabel.Size = new Vector2(Width - 20, 20);
}
if (dropLabel != null)
{
dropLabel.Position = new Vector2(10, Height / 2 - 10);
dropLabel.Size = new Vector2(Width - 20, 20);
}
}
public override void OnDragDrop(DragEvent e)
{
base.OnDragDrop(e);
if (!e.Data.HasFileOrFolder) return;
var asset = AssetSystem.FindByPath(e.Data.FileOrFolder);
if (asset?.AssetType != AssetType.SoundFile) return;
var soundFile = SoundFile.Load(asset.Path);
if (soundFile != null)
{
LoadSound(soundFile);
}
}
public override void OnDragHover(DragEvent e)
{
base.OnDragHover(e);
if (!e.Data.HasFileOrFolder) return;
var asset = AssetSystem.FindByPath(e.Data.FileOrFolder);
if (asset?.AssetType != AssetType.SoundFile) return;
e.Action = DropAction.Link;
}
protected override void OnMouseClick(MouseEvent e)
{
if (isLoading) return;
base.OnMouseClick(e);
if (e.Button == MouseButtons.Left)
{
var samplePos = (int)(e.LocalPosition.x / Width * samples.Length);
var nearPoint = splitPoints.FirstOrDefault(p => Math.Abs(p - samplePos) < (samples.Length / Width * 5));
if (nearPoint != default)
{
dragPoint = splitPoints.IndexOf(nearPoint);
}
else
{
splitPoints.Add(samplePos);
splitPoints.Sort();
Update();
}
}
}
protected override void OnMouseMove(MouseEvent e)
{
if (isLoading) return;
base.OnMouseMove(e);
if (dragPoint.HasValue)
{
var samplePos = (int)(e.LocalPosition.x / Width * samples.Length);
splitPoints[dragPoint.Value] = samplePos;
splitPoints.Sort();
Update();
}
}
protected override void OnMouseReleased(MouseEvent e)
{
if (isLoading) return;
base.OnMouseReleased(e);
dragPoint = null;
}
protected override void OnPaint()
{
base.OnPaint();
if (isLoading || samples == null)
{
return;
}
Paint.ClearPen();
Paint.SetBrush(Theme.Grey.WithAlpha(0.1f));
Paint.DrawRect(LocalRect);
Paint.SetPen(Theme.Blue);
var samplesPerPixel = samples.Length / Width;
for (int x = 0; x < Width; x++)
{
var startSample = (int)(x * samplesPerPixel);
var endSample = Math.Min(startSample + samplesPerPixel, samples.Length);
var max = short.MinValue;
var min = short.MaxValue;
for (int i = startSample; i < endSample; i++)
{
max = Math.Max(max, samples[i]);
min = Math.Min(min, samples[i]);
}
var y1 = Height / 2 + (min / (float)short.MaxValue * Height / 2);
var y2 = Height / 2 + (max / (float)short.MaxValue * Height / 2);
Paint.DrawLine(new Vector2(x, y1), new Vector2(x, y2));
}
Paint.SetPen(Theme.Red);
foreach (var point in splitPoints)
{
var x = point / (float)samples.Length * Width;
Paint.DrawLine(new Vector2(x, 0), new Vector2(x, Height));
}
}
public List<int> GetSplitPoints()
{
return new List<int>(splitPoints);
}
public void SplitCurrentSound(Action<SoundFile> onSoundCreated)
{
if (CurrentSound == null || samples == null) return;
var splitPoints = GetSplitPoints();
if (splitPoints.Count < 2) return;
try
{
var baseFileName = Path.GetFileNameWithoutExtension(CurrentSound.ResourcePath);
var outputDir = Path.Combine(
Project.Current.GetAssetsPath(),
"generated",
$"{baseFileName}_splits"
);
Directory.CreateDirectory(outputDir);
for (int i = 0; i < splitPoints.Count - 1; i++)
{
var start = splitPoints[i];
var end = splitPoints[i + 1];
var length = end - start;
var segmentSamples = new short[length];
Array.Copy(samples, start, segmentSamples, 0, length);
var wavPath = Path.Combine(outputDir, $"{baseFileName}_part_{i + 1}.wav");
using (var writer = new BinaryWriter(File.Create(wavPath)))
{
writer.Write(Encoding.ASCII.GetBytes("RIFF"));
writer.Write(36 + (segmentSamples.Length * 2));
writer.Write(Encoding.ASCII.GetBytes("WAVE"));
writer.Write(Encoding.ASCII.GetBytes("fmt "));
writer.Write(16);
writer.Write((short)1);
writer.Write((short)CurrentSound.Channels);
writer.Write(CurrentSound.Rate);
writer.Write(CurrentSound.Rate * CurrentSound.Channels * 2);
writer.Write((short)(CurrentSound.Channels * 2));
writer.Write((short)16);
writer.Write(Encoding.ASCII.GetBytes("data"));
writer.Write(segmentSamples.Length * 2);
foreach (var sample in segmentSamples)
{
writer.Write(sample);
}
}
var asset = AssetSystem.RegisterFile(wavPath);
if (asset != null)
{
var soundFile = SoundFile.Load(asset.RelativePath);
if (soundFile != null)
{
onSoundCreated?.Invoke(soundFile);
}
}
}
}
catch (Exception ex)
{
Log.Error($"Error splitting sound: {ex.Message}");
}
}
}using System;
using System.Collections.Generic;
using System.Linq;
using System.Threading.Tasks;
using Sandbox;
namespace TikTokTTS;
/// <summary>
/// A static class that allows you to use the TikTokTTS API.
/// </summary>
public static class TikTokTTS
{
/// <summary>
/// The API endpoint that the library uses.
/// </summary>
public static string ENDPOINT = "https://tiktok-tts.weilnet.workers.dev";
static int currentId = 0;
/// <summary>
/// Use TikTok's TTS to speak via a MusicPlayer. This MusicPlayer will automatically dispose itself when it finishes playing.
/// </summary>
/// <param name="text">The text to be said by the TTS</param>
/// <param name="voice">The name of the voice</param>
/// <returns></returns>
public static async Task<MusicPlayer> Say( string text, string voice = "en_us_007" )
{
string fileName = $"tts-{currentId}.mp3";
currentId++;
if ( !FileSystem.Data.FileExists( fileName ) )
{
await Download( text, voice, fileName, FileSystem.Data );
}
var musicPlayer = MusicPlayer.Play( FileSystem.Data, fileName );
musicPlayer.ListenLocal = true;
return musicPlayer;
}
/// <summary>
/// Use TikTok's TTS to speak and download/save the mp3 file.
/// </summary>
/// <param name="text">The text to be said by the TTS</param>
/// <param name="voice">The name of the voice</param>
/// <param name="fileName">The file name/path it should download to (defaults to "tts-##########.mp3"</param>
/// <param name="fileSystem">The filesystem to use (defaults to FileSystem.Data)</param>
/// <returns>The file path</returns>
public static async Task<string> Download( string text, string voice = "en_us_007", string fileName = null, BaseFileSystem fileSystem = null )
{
if ( fileSystem == null ) fileSystem = FileSystem.Data;
if ( string.IsNullOrEmpty( fileName ) ) fileName = $"tts-{new Guid()}.mp3";
var content = new Dictionary<string, string> {
{ "text", text },
{ "voice", voice }
};
var headers = new Dictionary<string, string> {
{ "Content-Type", "application/json" }
};
text = text.RemoveBadCharacters();
text = text.Substring( 0, Math.Min( text.Length, 300 ) );
if ( !text.Any( x => char.IsLetterOrDigit( x ) ) ) return null;
if ( string.IsNullOrEmpty( text ) ) return null;
// Make sure folders exist
var folders = fileName.Split( '/' );
if ( folders.Length == 1 ) folders = fileName.Split( '\\' );
if ( folders.Length > 1 )
{
string path = "";
for ( int i = 0; i < folders.Length - 1; i++ )
{
path += folders[i] + "/";
if ( !fileSystem.DirectoryExists( path ) )
fileSystem.CreateDirectory( path );
}
}
try
{
if ( fileSystem.FileExists( fileName ) )
fileSystem.DeleteFile( fileName );
var response = await Http.RequestJsonAsync<TikTokTTSResponse>( "https://tiktok-tts.weilnet.workers.dev/api/generation", "POST", Http.CreateJsonContent( content ), headers );
string base64 = response.data;
byte[] mp3 = Convert.FromBase64String( base64 );
var stream = fileSystem.OpenWrite( fileName );
stream.Write( mp3, 0, mp3.Length );
stream.Close();
return fileName;
}
catch ( Exception e )
{
Log.Error( e.Message );
return null;
}
}
class TikTokTTSResponse
{
public bool success { get; set; }
public string data { get; set; }
public string error { get; set; }
}
}
using System;
using System.Collections.Generic;
namespace Sandbox.Polygons;
public class PolygonModelRenderer : ModelRenderer
{
private Mesh _mesh;
private string _svg;
private bool _meshDirty;
/// <summary>
/// Scalable Vector Graphics source string for this model.
/// </summary>
[Property]
public string Svg
{
get => _svg;
set
{
_svg = value;
_meshDirty = true;
}
}
private int _lastHash = 0;
protected override void OnEnabled()
{
base.OnEnabled();
UpdateModel();
}
protected override void OnValidate()
{
base.OnValidate();
_meshDirty = true;
}
private void UpdateModel()
{
if ( !_meshDirty )
{
return;
}
var hash = Svg?.FastHash() ?? 0;
if ( _lastHash == hash )
{
return;
}
if ( Model?.IsProcedural is not true )
{
Model = null;
}
_lastHash = hash;
if ( !string.IsNullOrEmpty( Svg ) )
{
using var builder = PolygonMeshBuilder.Rent();
builder.MaxSmoothAngle = 33f.DegreeToRadian();
builder.AddSvg( _svg, new AddSvgOptions
{
ThrowIfNotSupported = true
}, new Rect( -128f, -128f, 256f, 256f ) );
builder.Extrude( 8f );
builder.Arc( 2f, 2 );
builder.Fill();
builder.Mirror();
_mesh ??= new Mesh( Material.Load( "materials/default/white.vmat" ) );
_mesh.UpdateMesh( PolygonMeshBuilder.Vertex.Layout, builder.Vertices, builder.Indices );
Model ??= new ModelBuilder()
.AddMesh( _mesh )
.Create();
}
else
{
_mesh?.SetIndexRange( 0, 0 );
}
}
protected override void OnUpdate()
{
UpdateModel();
base.OnUpdate();
}
}
using System;
namespace Duccsoft;
public partial class Freecam
{
/// <summary>
/// Invoked whenever a freecam is enabled. The argument is the freecam that was enabled.
/// </summary>
public static event Action<Freecam> OnFreecamStart;
/// <summary>
/// Invoked whenever a freecam is disabled. The argument is the freecam that was disabled.
/// </summary>
public static event Action<Freecam> OnFreecamEnd;
/// <summary>
/// Removes all listeners from the static events of this class. Used by
/// <see cref="CameraEventCleanupSystem"/> to tidy things up between play sessions.
/// </summary>
public static void ClearInvocationLists()
{
OnFreecamStart = null;
OnFreecamEnd = null;
}
}
global using Sandbox;
global using System.Collections.Generic;
global using System.Linq;
using Editor;
using Sandbox;
using System.Linq;
namespace SFXR.Editor;
//[CustomEditor( typeof( SFXRComponent ) )]
public class SFXRComponentEditor : ComponentEditorWidget
{
//ParticleFloatControlWidget
public SFXRComponentEditor( SerializedObject obj ) : base( obj )
{
var defaultInspector = new PropertyControlSheet();
defaultInspector.AddObject( obj );
Layout = Layout.Column();
Layout.Add( defaultInspector );
Layout.AddSpacingCell( 5 );
}
}using System.Collections.Generic;
using System.Linq;
using Sandbox;
namespace SFXR;
[Title( "SFXR Sequencer" )]
[Category( "SFXR" )]
[Icon( "view_comfy" )]
public class SFXRSequencer : Component
{
[Property, Group( "Settings" )]
public float BPM { get; set; } = 120;
[Property, Group( "Settings" )]
public int BeatsPerBar { get; set; } = 4;
[Property, Group( "Notes" )]
public List<Note> Notes { get; set; } = new();
[Property, Group( "Controls" )]
public SFXRSequencerControls Controls { get; set; } = new();
public bool IsPlaying { get; private set; } = false;
public float CurrentTime { get; private set; } = 0f;
SFXRComponent Sfxr;
List<Note> NotesToPlay = new();
List<Note> NotesToStop = new();
protected override void OnDisabled()
{
Sfxr.TriggerReleaseAll();
StopSequence();
}
protected override void OnUpdate()
{
if ( !IsPlaying ) return;
Sfxr ??= GameObject.Components.Get<SFXRComponent>();
if ( Sfxr is null )
{
Log.Error( "SFXRSequencer requires an SFXRComponent to be attached to the same GameObject" );
return;
}
CurrentTime += Time.Delta;
for ( int i = 0; i < NotesToStop.Count; i++ )
{
var note = NotesToStop[i];
var time = BeatsToSeconds( note.Time + note.Length );
if ( CurrentTime >= time )
{
Sfxr.TriggerNoteRelease( note.Frequency );
NotesToStop.RemoveAt( i );
i--;
}
}
for ( int i = 0; i < NotesToPlay.Count; i++ )
{
var note = NotesToPlay[i];
var time = BeatsToSeconds( note.Time );
if ( CurrentTime >= time )
{
// Sfxr.Frequency.Start = note.Frequency;
// Sfxr.Length = BeatsToSeconds( note.Length );
// Sfxr.MasterVolume = note.Volume;
Sfxr.TriggerNotePress( note.Frequency, note.Volume );
NotesToStop.Add( note );
NotesToPlay.RemoveAt( i );
i--;
}
}
if ( NotesToPlay.Count == 0 && NotesToStop.Count == 0 )
{
IsPlaying = false;
}
}
public void PlaySequence()
{
if ( Sfxr is null )
{
Sfxr = GameObject.Components.Get<SFXRComponent>();
}
if ( !Sfxr.Enabled ) return;
IsPlaying = true;
CurrentTime = 0f;
NotesToPlay.Clear();
NotesToPlay.AddRange( Notes );
}
public void StopSequence()
{
IsPlaying = false;
CurrentTime = 0f;
}
public void PlayRange( float start, float end )
{
IsPlaying = true;
CurrentTime = BeatsToSeconds( start );
Sfxr.TriggerReleaseAll();
NotesToStop.Clear();
NotesToPlay.Clear();
NotesToPlay.AddRange( Notes.Where( x => x.Time >= start && x.Time <= end ) );
}
float BeatsToSeconds( float beats )
{
return beats * (60f / BPM / BeatsPerBar);
}
public class Note
{
[Property] public float Time { get; set; }
[Property] public float Frequency { get; set; }
[Property] public float Length { get; set; }
[Property] public float Volume { get; set; }
public Note()
{
Time = 0;
Frequency = 440;
Length = 1f;
Volume = 1f;
}
}
}using Sandbox;
using Editor;
using System;
using System.Collections.Generic;
using System.Linq;
namespace SFXR.Editor;
//[CustomEditor( typeof( SFXRFloat ) )]
// public class SFXRFloatControlWidget : ControlWidget
// {
// SerializedObject Target;
// public SFXRFloatControlWidget( SerializedProperty property ) : base( property )
// {
// SetSizeMode( SizeMode.Ignore, SizeMode.Default );
// if ( !property.TryGetAsObject( out Target ) )
// return;
// Layout = Layout.Row();
// Layout.Spacing = 2;
// var value = Target.GetProperty( "Value" );
// FloatControlWidget valueWidget = new FloatControlWidget( value );
// if ( property.TryGetAttribute<RangeAttribute>( out var attribute ) )
// {
// valueWidget.Range = new Vector2( attribute.Min, attribute.Max );
// valueWidget.RangeStep = attribute.Step;
// valueWidget.HasRange = attribute.Slider;
// // if ( attribute.Slider )
// // {
// // sliderWidget = new FloatSlider( this );
// // sliderWidget.HighlightColor = Theme.Grey;
// // sliderWidget.Minimum = attribute.Min;
// // sliderWidget.Maximum = attribute.Max;
// // sliderWidget.Step = attribute.S;
// // sliderWidget.OnValueEdited = delegate
// // {
// // base.SerializedProperty.As.Float = sliderWidget.Value;
// // };
// // }
// }
// Layout.Add( valueWidget );
// var locked = Target.GetProperty( "Locked" );
// IconButton lockedButton = new IconButton( "lock_open" );
// lockedButton.OnClick = () =>
// {
// if ( Target.Targets.First() is SFXRFloat sfxrFloat )
// {
// sfxrFloat.Locked = !sfxrFloat.Locked;
// Log.Info( sfxrFloat.Locked );
// lockedButton.Icon = sfxrFloat.Locked ? "lock" : "lock_open";
// lockedButton.Update();
// }
// };
// lockedButton.ToolTip = "Lock/Unlock this value";
// Layout.Add( lockedButton );
// }
// protected override void OnPaint()
// {
// }
// }
// public class SFXRFloatControlWidget : FloatControlWidget
// {
// SerializedObject Target;
// public SFXRFloatControlWidget( SerializedProperty property ) : base( property )
// {
// if ( !property.TryGetAsObject( out Target ) )
// return;
// var locked = Target.GetProperty( "Locked" );
// IconButton lockedButton = new IconButton( "lock_open" );
// lockedButton.OnClick = () =>
// {
// // if ( Target.Targets.First() is SFXRFloat sfxrFloat )
// // {
// // sfxrFloat.Locked = !sfxrFloat.Locked;
// // Log.Info( sfxrFloat.Locked );
// // lockedButton.Icon = sfxrFloat.Locked ? "lock" : "lock_open";
// // lockedButton.Update();
// // }
// };
// lockedButton.ToolTip = "Lock/Unlock this value";
// //Layout.Add( lockedButton );
// }
// protected override void PaintControl()
// {
// if ( Target is null ) return;
// base.PaintControl();
// }
// protected override void OnPaint()
// {
// if ( Target is null ) return;
// base.OnPaint();
// }
// }using Editor;
using Sandbox;
using System.Linq;
namespace SFXR.Editor;
[CustomEditor( typeof( SFXRControls ) )]
public class SFXRSoundControlWidget : ControlWidget
{
SerializedObject Target;
public SFXRSoundControlWidget( SerializedProperty property ) : base( property )
{
if ( !property.TryGetAsObject( out Target ) )
return;
var component = property.Parent.Targets.First() as SFXRComponent;
// Randomize Button
var btnRandomize = new Button( "Randomize All", "casino" );
btnRandomize.Clicked = () =>
{
component.Randomize();
component.PlaySound();
};
btnRandomize.ToolTip = "Randomize all sound properties";
// Play Sound Button
var btnPlaySound = new Button( "Play Sound", "play_arrow" );
btnPlaySound.Clicked = () =>
{
component.PlaySound();
};
btnPlaySound.MinimumWidth = 200;
btnPlaySound.ToolTip = "Play the current sound";
// Mutate Button
var btnMutate = new Button( "Mutate", "shuffle" );
btnMutate.Clicked = () =>
{
component.Mutate();
component.PlaySound();
};
btnMutate.ToolTip = "Mutate all sound properties";
// Randomize Pickup Button
var btnRandomizePickup = new Button( "", "monetization_on" );
btnRandomizePickup.Clicked = () =>
{
component.RandomizePickup();
component.PlaySound();
};
btnRandomizePickup.ToolTip = "Generate random pickup sound";
// Randomize Laser Button
var btnRandomizeLaser = new Button( "", "bolt" );
btnRandomizeLaser.Clicked = () =>
{
component.RandomizeLaser();
component.PlaySound();
};
btnRandomizeLaser.ToolTip = "Generate random laser sound";
// Randomize Explosion Button
var btnRandomizeExplosion = new Button( "", "flare" );
btnRandomizeExplosion.Clicked = () =>
{
component.RandomizeExplosion();
component.PlaySound();
};
btnRandomizeExplosion.ToolTip = "Generate random explosion sound";
// Randomize Powerup Button
var btnRandomizePowerup = new Button( "", "star" );
btnRandomizePowerup.Clicked = () =>
{
component.RandomizePowerup();
component.PlaySound();
};
btnRandomizePowerup.ToolTip = "Generate random powerup sound";
// Randomize Hit Hurt Button
var btnRandomizeHit = new Button( "", "sentiment_very_dissatisfied" );
btnRandomizeHit.Clicked = () =>
{
component.RandomizeHit();
component.PlaySound();
};
btnRandomizeHit.ToolTip = "Generate random hit/hurt sound";
// Randomize Jump Button
var btnRandomizeJump = new Button( "", "settings_accessibility" );
btnRandomizeJump.Clicked = () =>
{
component.RandomizeJump();
component.PlaySound();
};
btnRandomizeJump.ToolTip = "Generate random jump sound";
// Randomize Blip Select Button
var btnRandomizeBlipSelect = new Button( "", "menu" );
btnRandomizeBlipSelect.Clicked = () =>
{
component.RandomizeBlip();
component.PlaySound();
};
btnRandomizeBlipSelect.ToolTip = "Generate random blip/select sound";
Layout = Layout.Column();
Layout.Spacing = 2;
Layout.Margin = new Sandbox.UI.Margin( 0, 4 );
MinimumHeight = 90;
var grid = Layout.Grid();
grid.Spacing = 2;
grid.AddCell( 0, 0, btnRandomizePickup );
grid.AddCell( 1, 0, btnRandomizeLaser );
grid.AddCell( 2, 0, btnRandomizeExplosion );
grid.AddCell( 3, 0, btnRandomizePowerup );
grid.AddCell( 4, 0, btnRandomizeHit );
grid.AddCell( 5, 0, btnRandomizeJump );
grid.AddCell( 6, 0, btnRandomizeBlipSelect );
var randomRow = Layout.Row();
randomRow.Spacing = 2;
randomRow.Add( btnRandomize );
randomRow.Add( btnMutate );
Layout.Add( grid );
Layout.Add( randomRow );
Layout.Add( btnPlaySound );
}
protected override void OnPaint()
{
}
}using Sandbox;
using System;
using System.Text.Json.Serialization;
namespace SFXR;
public struct SFXRFloat
{
[JsonInclude] public float Value { get; set; }
[JsonInclude] public bool Locked { get; set; }
public SFXRFloat( float value )
{
Value = value;
Locked = false;
}
public static implicit operator float( SFXRFloat value ) => value.Value;
public static implicit operator SFXRFloat( float value ) => new SFXRFloat( value );
}using System.Collections.Generic;
using System.Linq;
namespace Sandbox.Volumes;
/// <summary>
/// A base GameObjectSystem for handling of VolumeComponents. The idea is that you're going to have
/// a custom VolumeComponent, and register your volumes in a VolumeGameObjectSystem derived GameObjectSystem.
/// This system's responsibility is primarily to store volumes and make them searchable.
/// </summary>
public abstract class VolumeSystem<T> : GameObjectSystem where T : VolumeComponent
{
public VolumeSystem( Scene scene ) : base( scene )
{
}
HashSet<T> volumes = new HashSet<T>();
public void Add( T volume )
{
volumes.Add( volume );
}
public void Remove( T volume )
{
volumes.Remove( volume );
}
public T FindVolume( Vector3 position )
{
return FindAll( position ).FirstOrDefault();
}
public IEnumerable<T> FindAll( Vector3 position )
{
foreach ( var volume in volumes )
{
if ( !volume.SceneVolume.Test( volume.Transform.World, position ) )
continue;
yield return volume;
}
}
}
namespace Sandbox.Volumes;
public class VolumeComponent : Component
{
[InlineEditor]
[Property] public SceneVolume SceneVolume { get; set; } = new SceneVolume();
protected override void DrawGizmos()
{
base.DrawGizmos();
if ( !Gizmo.IsSelected )
return;
var vol = SceneVolume;
vol.DrawGizmos( true );
SceneVolume = vol;
}
public virtual float GetPriority()
{
// higher number is better, smaller volume is better
return 1.0f - (SceneVolume.GetVolume() / 16000000000f);
}
}
global using Microsoft.VisualStudio.TestTools.UnitTesting;
[TestClass]
public class TestInit
{
[AssemblyInitialize]
public static void ClassInitialize( TestContext context )
{
Sandbox.Application.InitUnitTest();
}
}
using System.Collections.Generic;
using System.Linq;
namespace Sandbox.Events;
/// <summary>
/// Generate an ordering based on a set of first-most and last-most items, and
/// individual constraints between pairs of items. All first-most items will be
/// ordered before all last-most items, and any other items will be put in the
/// middle unless forced to be elsewhere by a constraint.
/// </summary>
internal class SortingHelper
{
public record struct SortConstraint( int EarlierIndex, int LaterIndex )
{
public SortConstraint Complement => new ( LaterIndex, EarlierIndex );
}
private readonly int _itemCount;
private readonly HashSet<SortConstraint> _initialConstraints = new HashSet<SortConstraint>();
private readonly HashSet<int> _first = new HashSet<int>();
private readonly HashSet<int> _last = new HashSet<int>();
public SortingHelper( int itemCount )
{
_itemCount = itemCount;
}
public void AddConstraint( int earlierIndex, int laterIndex )
{
_initialConstraints.Add( new SortConstraint( earlierIndex, laterIndex ) );
}
public void AddFirst( int earlierIndex )
{
_first.Add( earlierIndex );
}
public void AddLast( int laterIndex )
{
_last.Add( laterIndex );
}
public bool Sort( List<int> result, out SortConstraint invalidConstraint )
{
var middle = new HashSet<int>();
for ( var index = 0; index < _itemCount; ++index )
{
if ( !_first.Contains( index ) && !_last.Contains( index ) )
middle.Add( index );
}
var allConstraints = new HashSet<SortConstraint>();
var newConstraints = new Queue<SortConstraint>();
var beforeDict = new Dictionary<int, HashSet<int>>();
var afterDict = new Dictionary<int, HashSet<int>>();
bool AddWorkingConstraint( int earlierIndex, int laterIndex, out SortConstraint constraint )
{
constraint = new SortConstraint( earlierIndex, laterIndex );
if ( allConstraints.Contains( constraint.Complement ) )
return false;
if ( !allConstraints.Add( constraint ) )
return true;
newConstraints.Enqueue( constraint );
if ( !beforeDict.TryGetValue( earlierIndex, out var before ) )
beforeDict.Add( earlierIndex, before = new HashSet<int>() );
if ( !afterDict.TryGetValue( laterIndex, out var after ) )
afterDict.Add( laterIndex, after = new HashSet<int>() );
before.Add( laterIndex );
after.Add( earlierIndex );
return true;
}
// Add initial constraints
foreach ( var initialConstraint in _initialConstraints )
{
if ( !AddWorkingConstraint( initialConstraint.EarlierIndex, initialConstraint.LaterIndex, out invalidConstraint ) )
return false;
}
// Everything in _first should be before everything in _last
foreach ( var earlierIndex in _first )
{
foreach ( var laterIndex in _last )
{
if ( !AddWorkingConstraint( earlierIndex, laterIndex, out invalidConstraint ) )
return false;
}
}
// Keep propagating constraints until nothing changes
while ( newConstraints.TryDequeue( out var nextConstraint ) )
{
// if a < b, and b < c, then a < c etc
if ( beforeDict.TryGetValue( nextConstraint.LaterIndex, out var before ) )
{
foreach ( var laterIndex in before )
{
if ( !AddWorkingConstraint( nextConstraint.EarlierIndex, laterIndex, out invalidConstraint ) )
return false;
}
}
if ( afterDict.TryGetValue( nextConstraint.EarlierIndex, out var after ) )
{
foreach ( var earlierIndex in after )
{
if ( !AddWorkingConstraint( earlierIndex, nextConstraint.LaterIndex, out invalidConstraint ) )
{
return false;
}
}
}
}
// Now if we have any items that aren't using GroupOrder.First, and haven't
// determined that they are ordered before another item with GroupOrder.First,
// we can safely order them after all GroupOrder.First items. And vice versa.
foreach ( var middleIndex in middle )
{
var isBeforeAnyFirst = beforeDict.TryGetValue( middleIndex, out var before )
&& before.Any( x => _first.Contains( x ) );
var isAfterAnyLast = afterDict.TryGetValue( middleIndex, out var after )
&& after.Any( x => _last.Contains( x ) );
if ( !isBeforeAnyFirst )
{
foreach ( var earlierIndex in _first )
AddWorkingConstraint( earlierIndex, middleIndex, out invalidConstraint );
}
if ( !isAfterAnyLast )
{
foreach ( var laterIndex in _last )
AddWorkingConstraint( middleIndex, laterIndex, out invalidConstraint );
}
}
// Now lets add items to the final ordering if all items that should be sorted
// before them are already added to that ordering. We'll implement this by choosing
// items that have an empty list / don't appear in afterDict, and update that
// dictionary as we go.
var earliestRemaining = new Queue<int>();
// First, seed the queue with everything that's already not ordered after anything
for ( var index = 0; index < _itemCount; ++index )
{
if ( !afterDict.ContainsKey( index ) )
{
earliestRemaining.Enqueue( index );
}
}
result.Clear();
while ( earliestRemaining.TryDequeue( out var nextIndex ) )
{
result.Add( nextIndex );
foreach ( var laterIndex in beforeDict.TryGetValue( nextIndex, out var laterIndices )
? laterIndices : Enumerable.Empty<int>() )
{
var beforeLater = afterDict[laterIndex];
beforeLater.Remove( nextIndex );
if ( beforeLater.Count == 0 )
earliestRemaining.Enqueue( laterIndex );
}
}
invalidConstraint = default;
return result.Count == _itemCount;
}
}
public sealed class PlayerFootsteps : Component
{
[Property] SkinnedModelRenderer Source { get; set; }
protected override void OnEnabled()
{
if ( Source is null )
return;
Source.OnFootstepEvent += OnEvent;
}
protected override void OnDisabled()
{
if ( Source is null )
return;
Source.OnFootstepEvent -= OnEvent;
}
TimeSince timeSinceStep;
private void OnEvent( SceneModel.FootstepEvent e )
{
if ( timeSinceStep < 0.2f )
return;
var tr = Scene.Trace
.Ray( e.Transform.Position + Vector3.Up * 20, e.Transform.Position + Vector3.Up * -20 )
.Run();
if ( !tr.Hit )
return;
if ( tr.Surface is null )
return;
timeSinceStep = 0;
var sound = e.FootId == 0 ? tr.Surface.Sounds.FootLeft : tr.Surface.Sounds.FootRight;
if ( sound is null ) return;
var handle = Sound.Play( sound, tr.HitPosition + tr.Normal * 5 );
handle.Volume *= e.Volume;
handle.Update();
}
}
public sealed class BouncyBone : TransformProxyComponent
{
JiggleBoneState state = new JiggleBoneState();
[Property]
public Vector3 Influence { get; set; } = new Vector3( 1, 1, 1 );
[Property, Range( 0, 50.0f )]
public float Stiffness { get; set; } = 1;
[Property, Range( 0, 50.0f )]
public float Damping { get; set; } = 1;
Transform LocalJigglePosition;
TransformSpring springer;
protected override void OnEnabled()
{
springer = new TransformSpring();
springer.Transform = Transform.World;
LocalJigglePosition = springer.Transform;
base.OnEnabled();
}
protected override void OnUpdate()
{
var oldPos = LocalJigglePosition;
using ( Transform.DisableProxy() )
{
var worldTx = Transform.World;
springer.Stiffness = Stiffness;
springer.Damping = Damping;
springer.UpdateSpring( Transform.World, Time.Delta );
var tx = GameObject.Parent.Transform.World.ToLocal( springer.Transform );
LocalJigglePosition = tx;
}
if ( oldPos != LocalJigglePosition )
{
MarkTransformChanged();
}
}
public override Transform GetLocalTransform()
{
return LocalJigglePosition;
}
}
public struct TransformSpring
{
public Transform Transform;
private Vector3 velocityPosition;
private Vector3 velocityScale;
private Rotation velocityRotation = Rotation.Identity;
public float Stiffness = 1.5f; // Spring stiffness, higher is stiffer
public float Damping = 1.0f; // Damping, higher is less oscillation
public TransformSpring()
{
Transform = global::Transform.Zero;
}
public void UpdateSpring( Transform target, float deltaTime )
{
Transform.Position = SpringLerp( Transform.Position, target.Position, ref velocityPosition, deltaTime );
Transform.Scale = SpringLerp( Transform.Scale, target.Scale, ref velocityScale, deltaTime );
Transform.Rotation = target.Rotation;
}
private Vector3 SpringLerp( Vector3 current, Vector3 target, ref Vector3 velocity, float deltaTime )
{
float omega = 2f * MathF.PI * Stiffness;
float damper = MathF.Exp( -Damping * deltaTime * omega );
Vector3 displacement = current - target;
Vector3 springForce = -omega * omega * displacement;
Vector3 dampingForce = -2f * omega * Damping * velocity;
Vector3 acceleration = springForce + dampingForce;
velocity = (velocity + acceleration * deltaTime) * damper;
return target + displacement + velocity * deltaTime;
}
}