ScriptableRenderPipeline/com.unity.render-pipelines.high-definition/HDRP/Lighting/Reflection/Volumes/InfluenceVolume.cs

using System;
using UnityEngine.Serialization;
using UnityEngine.Experimental.Rendering;

namespace UnityEngine.Experimental.Rendering.HDPipeline
{
    [Serializable]
    public class InfluenceVolume
    {
        HDProbe probe;

        [SerializeField, FormerlySerializedAs("m_ShapeType")]
        Shape m_Shape = Shape.Box;
        [SerializeField, FormerlySerializedAs("m_BoxBaseOffset")]
        Vector3 m_Offset;
#pragma warning disable 649 //never assigned
        [SerializeField, Obsolete("Kept only for compatibility. Use m_Offset instead")]
        Vector3 m_SphereBaseOffset;
#pragma warning restore 649 //never assigned

        // Box
        [SerializeField, FormerlySerializedAs("m_BoxBaseSize")]
        Vector3 m_BoxSize = Vector3.one * 10;
        [SerializeField, FormerlySerializedAs("m_BoxInfluencePositiveFade")]
        Vector3 m_BoxBlendDistancePositive;
        [SerializeField, FormerlySerializedAs("m_BoxInfluenceNegativeFade")]
        Vector3 m_BoxBlendDistanceNegative;
        [SerializeField, FormerlySerializedAs("m_BoxInfluenceNormalPositiveFade")]
        Vector3 m_BoxBlendNormalDistancePositive;
        [SerializeField, FormerlySerializedAs("m_BoxInfluenceNormalNegativeFade")]
        Vector3 m_BoxBlendNormalDistanceNegative;
        [SerializeField, FormerlySerializedAs("m_BoxPositiveFaceFade")]
        Vector3 m_BoxSideFadePositive = Vector3.one;
        [SerializeField, FormerlySerializedAs("m_BoxNegativeFaceFade")]
        Vector3 m_BoxSideFadeNegative = Vector3.one;

        //editor value that need to be saved for easy passing from simplified to advanced and vice et versa
        // /!\ must not be used outside editor code
        [SerializeField, FormerlySerializedAs("editorAdvancedModeBlendDistancePositive")]
        Vector3 m_EditorAdvancedModeBlendDistancePositive;
        [SerializeField, FormerlySerializedAs("editorAdvancedModeBlendDistanceNegative")]
        Vector3 m_EditorAdvancedModeBlendDistanceNegative;
        [SerializeField, FormerlySerializedAs("editorSimplifiedModeBlendDistance")]
        float m_EditorSimplifiedModeBlendDistance;
        [SerializeField, FormerlySerializedAs("editorAdvancedModeBlendNormalDistancePositive")]
        Vector3 m_EditorAdvancedModeBlendNormalDistancePositive;
        [SerializeField, FormerlySerializedAs("editorAdvancedModeBlendNormalDistanceNegative")]
        Vector3 m_EditorAdvancedModeBlendNormalDistanceNegative;
        [SerializeField, FormerlySerializedAs("editorSimplifiedModeBlendNormalDistance")]
        float m_EditorSimplifiedModeBlendNormalDistance;
        [SerializeField, FormerlySerializedAs("editorAdvancedModeEnabled")]
        bool m_EditorAdvancedModeEnabled;

        // Sphere
        [SerializeField, FormerlySerializedAs("m_SphereBaseRadius")]
        float m_SphereRadius = 1;
        [SerializeField, FormerlySerializedAs("m_SphereInfluenceFade")]
        float m_SphereBlendDistance;
        [SerializeField, FormerlySerializedAs("m_SphereInfluenceNormalFade")]
        float m_SphereBlendNormalDistance;

        /// <summary>Shape of this InfluenceVolume.</summary>
        public Shape shape
        {
            get { return m_Shape; }
            set
            {
                m_Shape = value;
                switch (m_Shape)
                {
                    case Shape.Box:
                        probe.UpdatedInfluenceVolumeShape(m_BoxSize, offset);
                        break;
                    case Shape.Sphere:
                        probe.UpdatedInfluenceVolumeShape(Vector3.one * (2 * m_SphereRadius), offset);
                        break;
                }
            }
        }

        /// <summary>Offset of this influence volume to the component handling him.</summary>
        public Vector3 offset { get { return m_Offset; } set { m_Offset = value; } }

        /// <summary>Size of the InfluenceVolume in Box Mode.</summary>
        public Vector3 boxSize
        {
            get { return m_BoxSize; }
            set
            {
                m_BoxSize = value;
                probe.UpdatedInfluenceVolumeShape(m_BoxSize, offset);
            }
        }

        /// <summary>Offset of sub volume defining fading.</summary>
        public Vector3 boxBlendOffset { get { return (boxBlendDistanceNegative - boxBlendDistancePositive) * 0.5f; } }
        /// <summary>Size of sub volume defining fading.</summary>
        public Vector3 boxBlendSize { get { return -(boxBlendDistancePositive + boxBlendDistanceNegative); } }
        /// <summary>
        /// Position of fade sub volume maxOffset point relative to InfluenceVolume max corner.
        /// Values between 0 (on InfluenceVolume hull) to half of boxSize corresponding axis.
        /// </summary>
        public Vector3 boxBlendDistancePositive { get { return m_BoxBlendDistancePositive; } set { m_BoxBlendDistancePositive = value; } }
        /// <summary>
        /// Position of fade sub volume minOffset point relative to InfluenceVolume min corner.
        /// Values between 0 (on InfluenceVolume hull) to half of boxSize corresponding axis.
        /// </summary>
        public Vector3 boxBlendDistanceNegative { get { return m_BoxBlendDistanceNegative; } set { m_BoxBlendDistanceNegative = value; } }

        /// <summary>Offset of sub volume defining fading relative to normal orientation.</summary>
        public Vector3 boxBlendNormalOffset { get { return (boxBlendNormalDistanceNegative - boxBlendNormalDistancePositive) * 0.5f; } }
        /// <summary>Size of sub volume defining fading relative to normal orientation.</summary>
        public Vector3 boxBlendNormalSize { get { return -(boxBlendNormalDistancePositive + boxBlendNormalDistanceNegative); } }
        /// <summary>
        /// Position of normal fade sub volume maxOffset point relative to InfluenceVolume max corner.
        /// Values between 0 (on InfluenceVolume hull) to half of boxSize corresponding axis (on origin for this axis).
        /// </summary>
        public Vector3 boxBlendNormalDistancePositive { get { return m_BoxBlendNormalDistancePositive; } set { m_BoxBlendNormalDistancePositive = value; } }
        /// <summary>
        /// Position of normal fade sub volume minOffset point relative to InfluenceVolume min corner.
        /// Values between 0 (on InfluenceVolume hull) to half of boxSize corresponding axis (on origin for this axis).
        /// </summary>
        public Vector3 boxBlendNormalDistanceNegative { get { return m_BoxBlendNormalDistanceNegative; } set { m_BoxBlendNormalDistanceNegative = value; } }

        /// <summary>Define fading percent of +X, +Y and +Z locally oriented face. (values from 0 to 1)</summary>
        public Vector3 boxSideFadePositive { get { return m_BoxSideFadePositive; } set { m_BoxSideFadePositive = value; } }
        /// <summary>Define fading percent of -X, -Y and -Z locally oriented face. (values from 0 to 1)</summary>
        public Vector3 boxSideFadeNegative { get { return m_BoxSideFadeNegative; } set { m_BoxSideFadeNegative = value; } }


        /// <summary>Radius of the InfluenceVolume in Sphere Mode.</summary>
        public float sphereRadius
        {
            get { return m_SphereRadius; }
            set
            {
                m_SphereRadius = value;
                probe.UpdatedInfluenceVolumeShape(Vector3.one * (2 * m_SphereRadius), offset);
            }
        }
        /// <summary>
        /// Offset of the fade sub volume from InfluenceVolume hull.
        /// Value between 0 (on InfluenceVolume hull) and sphereRadius (fade sub volume reduced to a point).
        /// </summary>
        public float sphereBlendDistance { get { return m_SphereBlendDistance; } set { m_SphereBlendDistance = value; } }
        /// <summary>
        /// Offset of the normal fade sub volume from InfluenceVolume hull.
        /// Value between 0 (on InfluenceVolume hull) and sphereRadius (fade sub volume reduced to a point).
        /// </summary>
        public float sphereBlendNormalDistance { get { return m_SphereBlendNormalDistance; } set { m_SphereBlendNormalDistance = value; } }

        internal InfluenceVolume(HDProbe probe)
        {
            Init(probe);
        }

        internal void Init(HDProbe probe)
        {
            this.probe = probe;
        }

        internal BoundingSphere GetBoundingSphereAt(Transform probeTransform)
        {
            switch (shape)
            {
                default:
                case Shape.Sphere:
                    return new BoundingSphere(probeTransform.TransformPoint(offset), sphereRadius);
                case Shape.Box:
                {
                    var position = probeTransform.TransformPoint(offset);
                    var radius = Mathf.Max(boxSize.x, Mathf.Max(boxSize.y, boxSize.z));
                    return new BoundingSphere(position, radius);
                }
            }
        }

        internal Bounds GetBoundsAt(Transform probeTransform)
        {
            switch (shape)
            {
                default:
                case Shape.Sphere:
                    return new Bounds(probeTransform.position, Vector3.one * sphereRadius);
                case Shape.Box:
                {
                    var position = probeTransform.TransformPoint(offset);
                    return new Bounds(position, boxSize);
                }
            }
        }

        internal Vector3 GetWorldPosition(Transform probeTransform)
        {
            return probeTransform.TransformPoint(offset);
        }

        internal void MigrateOffsetSphere()
        {
            if (shape == Shape.Sphere)
            {
#pragma warning disable CS0618 // Type or member is obsolete
                m_Offset = m_SphereBaseOffset;
#pragma warning restore CS0618 // Type or member is obsolete
            }
        }
    }
}