using System;
using System.Collections.Generic;
using System.Runtime.CompilerServices;
using Coffee.UIParticleInternal;
using UnityEngine;
using UnityEngine.Rendering;
using UnityEngine.Serialization;
using UnityEngine.UI;
using Random = UnityEngine.Random;
[assembly: InternalsVisibleTo("Coffee.UIParticle.Editor")]
namespace Coffee.UIExtensions
{
///
/// Render maskable and sortable particle effect ,without Camera, RenderTexture or Canvas.
///
[ExecuteAlways]
[RequireComponent(typeof(RectTransform))]
[RequireComponent(typeof(CanvasRenderer))]
public class UIParticle : MaskableGraphic, ISerializationCallbackReceiver
{
public enum AutoScalingMode
{
None,
UIParticle,
Transform
}
public enum MeshSharing
{
None,
Auto,
Primary,
PrimarySimulator,
Replica
}
public enum PositionMode
{
Relative,
Absolute
}
[HideInInspector]
[SerializeField]
[Obsolete]
internal bool m_IsTrail;
[HideInInspector]
[FormerlySerializedAs("m_IgnoreParent")]
[SerializeField]
[Obsolete]
private bool m_IgnoreCanvasScaler;
[HideInInspector]
[SerializeField]
[Obsolete]
internal bool m_AbsoluteMode;
[Tooltip("Scale the rendering particles. When the `3D` toggle is enabled, 3D scale (x, y, z) is supported.")]
[SerializeField]
private Vector3 m_Scale3D = new Vector3(10, 10, 10);
[Tooltip("If you want to update material properties (e.g. _MainTex_ST, _Color) in AnimationClip, " +
"use this to mark as animatable.")]
[SerializeField]
internal AnimatableProperty[] m_AnimatableProperties = new AnimatableProperty[0];
[Tooltip("Particles")]
[SerializeField]
private List m_Particles = new List();
[Tooltip("Particle simulation results are shared within the same group. " +
"A large number of the same effects can be displayed with a small load.\n" +
"None: Disable mesh sharing.\n" +
"Auto: Automatically select Primary/Replica.\n" +
"Primary: Provides particle simulation results to the same group.\n" +
"Primary Simulator: Primary, but do not render the particle (simulation only).\n" +
"Replica: Render simulation results provided by the primary.")]
[SerializeField]
private MeshSharing m_MeshSharing = MeshSharing.None;
[Tooltip("Mesh sharing group ID.\n" +
"If non-zero is specified, particle simulation results are shared within the group.")]
[SerializeField]
private int m_GroupId;
[SerializeField]
private int m_GroupMaxId;
[Tooltip("Emission position mode.\n" +
"Relative: The particles will be emitted from the scaled position.\n" +
"Absolute: The particles will be emitted from the world position.")]
[SerializeField]
private PositionMode m_PositionMode = PositionMode.Relative;
[SerializeField]
[Obsolete]
internal bool m_AutoScaling;
[SerializeField]
[Tooltip(
"How to automatically adjust when the Canvas scale is changed by the screen size or reference resolution.\n" +
"None: Do nothing.\n" +
"Transform: Transform.lossyScale (=world scale) will be set to (1, 1, 1).\n" +
"UIParticle: UIParticle.scale will be adjusted.")]
private AutoScalingMode m_AutoScalingMode = AutoScalingMode.Transform;
[SerializeField]
[Tooltip("Use a custom view.\n" +
"Use this if the particles are not displayed correctly due to min/max particle size.")]
private bool m_UseCustomView;
[SerializeField]
[Tooltip("Custom view size.\n" +
"Change the bake view size.")]
private float m_CustomViewSize = 10;
private readonly List _renderers = new List();
private Camera _bakeCamera;
private int _groupId;
private bool _isScaleStored;
private Vector3 _storedScale;
private DrivenRectTransformTracker _tracker;
///
/// Should this graphic be considered a target for ray-casting?
///
public override bool raycastTarget
{
get => false;
set { }
}
///
/// Particle simulation results are shared within the same group.
/// A large number of the same effects can be displayed with a small load.
/// None: disable mesh sharing.
/// Auto: automatically select Primary/Replica.
/// Primary: provides particle simulation results to the same group.
/// Primary Simulator: Primary, but do not render the particle (simulation only).
/// Replica: render simulation results provided by the primary.
///
public MeshSharing meshSharing
{
get => m_MeshSharing;
set => m_MeshSharing = value;
}
///
/// Mesh sharing group ID.
/// If non-zero is specified, particle simulation results are shared within the group.
///
public int groupId
{
get => _groupId;
set
{
if (m_GroupId == value) return;
m_GroupId = value;
if (m_GroupId != m_GroupMaxId)
{
ResetGroupId();
}
}
}
public int groupMaxId
{
get => m_GroupMaxId;
set
{
if (m_GroupMaxId == value) return;
m_GroupMaxId = value;
ResetGroupId();
}
}
///
/// Emission position mode.
/// Relative: The particles will be emitted from the scaled position.
/// Absolute: The particles will be emitted from the world position.
///
public PositionMode positionMode
{
get => m_PositionMode;
set => m_PositionMode = value;
}
///
/// Particle position mode.
/// Relative: The particles will be emitted from the scaled position of the ParticleSystem.
/// Absolute: The particles will be emitted from the world position of the ParticleSystem.
///
[Obsolete("The absoluteMode is now obsolete. Please use the autoScalingMode instead.", false)]
public bool absoluteMode
{
get => m_PositionMode == PositionMode.Absolute;
set => positionMode = value ? PositionMode.Absolute : PositionMode.Relative;
}
///
/// Prevents the root-Canvas scale from affecting the hierarchy-scaled ParticleSystem.
///
[Obsolete("The autoScaling is now obsolete. Please use the autoScalingMode instead.", false)]
public bool autoScaling
{
get => m_AutoScalingMode != AutoScalingMode.None;
set => autoScalingMode = value ? AutoScalingMode.Transform : AutoScalingMode.None;
}
///
/// How to automatically adjust when the Canvas scale is changed by the screen size or reference resolution.
///
/// None: Do nothing.
///
/// Transform: Transform.lossyScale (=world scale) will be set to (1, 1, 1).
///
/// UIParticle: UIParticle.scale will be adjusted.
///
public AutoScalingMode autoScalingMode
{
get => m_AutoScalingMode;
set
{
if (m_AutoScalingMode == value) return;
m_AutoScalingMode = value;
if (autoScalingMode != AutoScalingMode.Transform && _isScaleStored)
{
transform.localScale = _storedScale;
_isScaleStored = false;
}
}
}
///
/// Use a custom view.
/// Use this if the particles are not displayed correctly due to min/max particle size.
///
public bool useCustomView
{
get => m_UseCustomView;
set => m_UseCustomView = value;
}
///
/// Custom view size.
/// Change the bake view size.
///
public float customViewSize
{
get => m_CustomViewSize;
set => m_CustomViewSize = Mathf.Max(0.1f, value);
}
internal bool useMeshSharing => m_MeshSharing != MeshSharing.None;
internal bool isPrimary =>
m_MeshSharing == MeshSharing.Primary
|| m_MeshSharing == MeshSharing.PrimarySimulator;
internal bool canSimulate =>
m_MeshSharing == MeshSharing.None
|| m_MeshSharing == MeshSharing.Auto
|| m_MeshSharing == MeshSharing.Primary
|| m_MeshSharing == MeshSharing.PrimarySimulator;
internal bool canRender =>
m_MeshSharing == MeshSharing.None
|| m_MeshSharing == MeshSharing.Auto
|| m_MeshSharing == MeshSharing.Primary
|| m_MeshSharing == MeshSharing.Replica;
///
/// Particle effect scale.
///
public float scale
{
get => m_Scale3D.x;
set => m_Scale3D = new Vector3(value, value, value);
}
///
/// Particle effect scale.
///
public Vector3 scale3D
{
get => m_Scale3D;
set => m_Scale3D = value;
}
///
/// Particle effect scale.
///
public Vector3 scale3DForCalc => autoScalingMode == AutoScalingMode.Transform
? m_Scale3D
: m_Scale3D.GetScaled(canvasScale, transform.localScale);
public List particles => m_Particles;
///
/// Paused.
///
public bool isPaused { get; private set; }
public Vector3 parentScale { get; private set; }
public Vector3 canvasScale { get; private set; }
protected override void OnEnable()
{
_isScaleStored = false;
ResetGroupId();
UIParticleUpdater.Register(this);
RegisterDirtyMaterialCallback(UpdateRendererMaterial);
if (0 < particles.Count)
{
RefreshParticles(particles);
}
else
{
RefreshParticles();
}
base.OnEnable();
}
///
/// This function is called when the behaviour becomes disabled.
///
protected override void OnDisable()
{
_tracker.Clear();
if (autoScalingMode == AutoScalingMode.Transform && _isScaleStored)
{
transform.localScale = _storedScale;
}
_isScaleStored = false;
UIParticleUpdater.Unregister(this);
_renderers.ForEach(r => r.Reset());
UnregisterDirtyMaterialCallback(UpdateRendererMaterial);
base.OnDisable();
}
///
/// Callback for when properties have been changed by animation.
///
protected override void OnDidApplyAnimationProperties()
{
}
void ISerializationCallbackReceiver.OnBeforeSerialize()
{
}
void ISerializationCallbackReceiver.OnAfterDeserialize()
{
#pragma warning disable CS0612 // Type or member is obsolete
if (m_IgnoreCanvasScaler || m_AutoScaling)
{
m_IgnoreCanvasScaler = false;
m_AutoScaling = false;
m_AutoScalingMode = AutoScalingMode.Transform;
}
if (m_AbsoluteMode)
{
m_AbsoluteMode = false;
m_PositionMode = PositionMode.Absolute;
}
#pragma warning restore CS0612 // Type or member is obsolete
}
///
/// Play the ParticleSystems.
///
public void Play()
{
particles.Exec(p => p.Simulate(0, false, true));
isPaused = false;
}
///
/// Pause the ParticleSystems.
///
public void Pause()
{
particles.Exec(p => p.Pause());
isPaused = true;
}
///
/// Unpause the ParticleSystems.
///
public void Resume()
{
isPaused = false;
}
///
/// Stop the ParticleSystems.
///
public void Stop()
{
particles.Exec(p => p.Stop());
isPaused = true;
}
///
/// Start emission of the ParticleSystems.
///
public void StartEmission()
{
particles.Exec(p =>
{
var emission = p.emission;
emission.enabled = true;
});
}
///
/// Stop emission of the ParticleSystems.
///
public void StopEmission()
{
particles.Exec(p =>
{
var emission = p.emission;
emission.enabled = false;
});
}
///
/// Clear the particles of the ParticleSystems.
///
public void Clear()
{
particles.Exec(p => p.Clear());
isPaused = true;
}
///
/// Get all base materials to render.
///
public void GetMaterials(List result)
{
if (result == null) return;
for (var i = 0; i < _renderers.Count; i++)
{
var r = _renderers[i];
if (!r || !r.material) continue;
result.Add(r.material);
}
}
///
/// Refresh UIParticle using the ParticleSystem instance.
///
public void SetParticleSystemInstance(GameObject instance)
{
SetParticleSystemInstance(instance, true);
}
///
/// Refresh UIParticle using the ParticleSystem instance.
///
public void SetParticleSystemInstance(GameObject instance, bool destroyOldParticles)
{
if (!instance) return;
var childCount = transform.childCount;
for (var i = 0; i < childCount; i++)
{
var go = transform.GetChild(i).gameObject;
if (go.TryGetComponent(out var cam) && cam == _bakeCamera) continue;
if (go.TryGetComponent(out var _)) continue;
go.SetActive(false);
if (destroyOldParticles)
{
Misc.Destroy(go);
}
}
var tr = instance.transform;
tr.SetParent(transform, false);
tr.localPosition = Vector3.zero;
RefreshParticles(instance);
}
///
/// Refresh UIParticle using the prefab.
/// The prefab is automatically instantiated.
///
public void SetParticleSystemPrefab(GameObject prefab)
{
if (!prefab) return;
SetParticleSystemInstance(Instantiate(prefab.gameObject), true);
}
///
/// Refresh UIParticle.
/// Collect ParticleSystems under the GameObject and refresh the UIParticle.
///
public void RefreshParticles()
{
RefreshParticles(gameObject);
}
///
/// Refresh UIParticle.
/// Collect ParticleSystems under the GameObject and refresh the UIParticle.
///
private void RefreshParticles(GameObject root)
{
if (!root) return;
root.GetComponentsInChildren(true, particles);
for (var i = particles.Count - 1; 0 <= i; i--)
{
var ps = particles[i];
if (!ps || ps.GetComponentInParent(true) != this)
{
particles.RemoveAt(i);
}
}
for (var i = 0; i < particles.Count; i++)
{
var ps = particles[i];
var tsa = ps.textureSheetAnimation;
if (tsa.mode == ParticleSystemAnimationMode.Sprites && tsa.uvChannelMask == 0)
{
tsa.uvChannelMask = UVChannelFlags.UV0;
}
}
RefreshParticles(particles);
}
///
/// Refresh UIParticle using a list of ParticleSystems.
///
public void RefreshParticles(List particleSystems)
{
// Collect children UIParticleRenderer components.
// #246: Nullptr exceptions when using nested UIParticle components in hierarchy
_renderers.Clear();
var childCount = transform.childCount;
for (var i = 0; i < childCount; i++)
{
var child = transform.GetChild(i);
if (child.TryGetComponent(out UIParticleRenderer uiParticleRenderer))
{
_renderers.Add(uiParticleRenderer);
}
}
// Reset the UIParticleRenderer components.
for (var i = 0; i < _renderers.Count; i++)
{
_renderers[i].Reset(i);
}
// Set the ParticleSystem to the UIParticleRenderer. If the trail is enabled, set it additionally.
var j = 0;
for (var i = 0; i < particleSystems.Count; i++)
{
var ps = particleSystems[i];
if (!ps) continue;
GetRenderer(j++).Set(this, ps, false);
// If the trail is enabled, set it additionally.
if (ps.trails.enabled)
{
GetRenderer(j++).Set(this, ps, true);
}
}
}
internal void UpdateTransformScale()
{
_tracker.Clear();
canvasScale = canvas.rootCanvas.transform.localScale.Inverse();
parentScale = transform.parent.lossyScale;
if (autoScalingMode != AutoScalingMode.Transform)
{
if (_isScaleStored)
{
transform.localScale = _storedScale;
}
_isScaleStored = false;
return;
}
var currentScale = transform.localScale;
if (!_isScaleStored)
{
_storedScale = currentScale.IsVisible() ? currentScale : Vector3.one;
_isScaleStored = true;
}
_tracker.Add(this, rectTransform, DrivenTransformProperties.Scale);
var newScale = parentScale.Inverse();
if (currentScale != newScale)
{
transform.localScale = newScale;
}
}
internal void UpdateRenderers()
{
if (!isActiveAndEnabled) return;
for (var i = 0; i < _renderers.Count; i++)
{
var r = _renderers[i];
if (r) continue;
RefreshParticles(particles);
break;
}
var bakeCamera = GetBakeCamera();
for (var i = 0; i < _renderers.Count; i++)
{
var r = _renderers[i];
if (!r) continue;
r.UpdateMesh(bakeCamera);
}
}
internal void ResetGroupId()
{
_groupId = m_GroupId == m_GroupMaxId
? m_GroupId
: Random.Range(m_GroupId, m_GroupMaxId + 1);
}
protected override void UpdateMaterial()
{
}
///
/// Call to update the geometry of the Graphic onto the CanvasRenderer.
///
protected override void UpdateGeometry()
{
}
private void UpdateRendererMaterial()
{
for (var i = 0; i < _renderers.Count; i++)
{
var r = _renderers[i];
if (!r) continue;
r.maskable = maskable;
r.SetMaterialDirty();
}
}
internal UIParticleRenderer GetRenderer(int index)
{
if (_renderers.Count <= index)
{
_renderers.Add(UIParticleRenderer.AddRenderer(this, index));
}
if (!_renderers[index])
{
_renderers[index] = UIParticleRenderer.AddRenderer(this, index);
}
return _renderers[index];
}
private Camera GetBakeCamera()
{
if (!canvas) return Camera.main;
if (!useCustomView && canvas.renderMode != RenderMode.ScreenSpaceOverlay && canvas.rootCanvas.worldCamera)
{
return canvas.rootCanvas.worldCamera;
}
if (_bakeCamera)
{
_bakeCamera.orthographicSize = useCustomView ? customViewSize : 10;
return _bakeCamera;
}
// Find existing baking camera.
var childCount = transform.childCount;
for (var i = 0; i < childCount; i++)
{
if (transform.GetChild(i).TryGetComponent(out var cam)
&& cam.name == "[generated] UIParticle BakingCamera")
{
_bakeCamera = cam;
break;
}
}
// Create baking camera.
if (!_bakeCamera)
{
var go = new GameObject("[generated] UIParticle BakingCamera");
go.SetActive(false);
go.transform.SetParent(transform, false);
_bakeCamera = go.AddComponent();
}
// Setup baking camera.
_bakeCamera.enabled = false;
_bakeCamera.orthographicSize = useCustomView ? customViewSize : 10;
_bakeCamera.transform.SetPositionAndRotation(new Vector3(0, 0, -1000), Quaternion.identity);
_bakeCamera.orthographic = true;
_bakeCamera.farClipPlane = 2000f;
_bakeCamera.clearFlags = CameraClearFlags.Nothing;
_bakeCamera.cullingMask = 0; // Nothing
_bakeCamera.allowHDR = false;
_bakeCamera.allowMSAA = false;
_bakeCamera.renderingPath = RenderingPath.Forward;
_bakeCamera.useOcclusionCulling = false;
_bakeCamera.gameObject.SetActive(false);
_bakeCamera.gameObject.hideFlags = HideFlags.HideAndDontSave;
return _bakeCamera;
}
}
}