acdream/src/AcDream.Core/Vfx/ParticleSystem.cs

using System;
using System.Collections.Generic;
using System.Numerics;

namespace AcDream.Core.Vfx;

/// <summary>
/// Runtime particle orchestrator. The data and update rules are a direct
/// port of retail's <c>ParticleEmitterInfo</c>, <c>ParticleEmitter</c>, and
/// <c>Particle::Update</c> paths from the named retail decompilation.
/// </summary>
public sealed class ParticleSystem : IParticleSystem
{
    private readonly EmitterDescRegistry _registry;
    private readonly Random _rng;
    private readonly Dictionary<int, ParticleEmitter> _byHandle = new();
    private readonly List<int> _handleOrder = new();

    private int _nextHandle = 1;
    private float _time;
    private int _activeParticleCount;

    public ParticleSystem(EmitterDescRegistry registry, Random? rng = null)
    {
        _registry = registry ?? throw new ArgumentNullException(nameof(registry));
        _rng = rng ?? Random.Shared;
    }

    public int ActiveEmitterCount => _byHandle.Count;
    public int ActiveParticleCount => _activeParticleCount;

    public int SpawnEmitter(
        EmitterDesc desc,
        Vector3 anchor,
        Quaternion? rot = null,
        uint attachedObjectId = 0,
        int attachedPartIndex = -1,
        ParticleRenderPass renderPass = ParticleRenderPass.Scene)
    {
        ArgumentNullException.ThrowIfNull(desc);

        int handle = _nextHandle++;
        var emitter = new ParticleEmitter
        {
            Desc = desc,
            AnchorPos = anchor,
            AnchorRot = rot ?? Quaternion.Identity,
            AttachedObjectId = attachedObjectId,
            AttachedPartIndex = attachedPartIndex,
            RenderPass = renderPass,
            Particles = new Particle[Math.Max(1, desc.MaxParticles)],
            StartedAt = _time,
            LastEmitTime = _time,
            LastEmitOffset = anchor,
        };

        _byHandle[handle] = emitter;
        _handleOrder.Add(handle);

        for (int i = 0; i < desc.InitialParticles; i++)
            SpawnOne(emitter, allowWhenFull: false);

        return handle;
    }

    public int SpawnEmitterById(
        uint emitterId,
        Vector3 anchor,
        Quaternion? rot = null,
        uint attachedObjectId = 0,
        int attachedPartIndex = -1,
        ParticleRenderPass renderPass = ParticleRenderPass.Scene)
    {
        var desc = _registry.Get(emitterId);
        return SpawnEmitter(desc, anchor, rot, attachedObjectId, attachedPartIndex, renderPass);
    }

    public void PlayScript(uint scriptId, uint targetObjectId, float modifier = 1f)
    {
        // Full PhysicsScript scheduling lives in PhysicsScriptRunner.
    }

    public void StopEmitter(int handle, bool fadeOut)
    {
        if (!_byHandle.TryGetValue(handle, out var em))
            return;

        em.Finished = true;
        if (!fadeOut)
        {
            for (int i = 0; i < em.Particles.Length; i++)
                em.Particles[i].Alive = false;
        }
    }

    /// <summary>
    /// Refresh an active emitter's world anchor + orientation. Required for
    /// retail's <c>is_parent_local=1</c> (acdream's
    /// <see cref="EmitterFlags.AttachLocal"/>) semantics: retail
    /// <c>ParticleEmitter::UpdateParticles</c> at <c>0x0051d2d4</c> reads the
    /// LIVE parent frame each tick when <c>is_parent_local != 0</c>. The
    /// caller (typically a tick loop tracking a moving parent — the camera
    /// for sky-PES, an entity for animation hooks) drives this every frame.
    /// </summary>
    public void UpdateEmitterAnchor(int handle, Vector3 anchor, Quaternion? rot = null)
    {
        if (!_byHandle.TryGetValue(handle, out var em))
            return;
        em.AnchorPos = anchor;
        if (rot.HasValue)
            em.AnchorRot = rot.Value;
    }

    /// <summary>True when the given handle still maps to a live emitter.</summary>
    public bool IsEmitterAlive(int handle) => _byHandle.ContainsKey(handle);

    /// <summary>
    /// Fired exactly once per emitter when it is removed from the live set
    /// (either because it finished naturally or was stopped without fade).
    /// Subscribers (e.g. <see cref="ParticleHookSink"/>) use this to prune
    /// per-entity handle tracking so the per-entity bag doesn't grow without
    /// bound during a long session.
    /// </summary>
    public event Action<int>? EmitterDied;

    public void Tick(float dt)
    {
        if (dt <= 0f)
            return;

        _time += dt;
        _activeParticleCount = 0;

        for (int i = 0; i < _handleOrder.Count; i++)
        {
            int handle = _handleOrder[i];
            if (!_byHandle.TryGetValue(handle, out var em))
                continue;

            AdvanceEmitter(em);
            int live = CountAlive(em);
            em.ActiveCount = live;
            _activeParticleCount += live;

            if (em.Desc.TotalDuration > 0f && (_time - em.StartedAt) > em.Desc.TotalDuration)
                em.Finished = true;

            if (em.Desc.TotalParticles > 0 && em.TotalEmitted >= em.Desc.TotalParticles)
                em.Finished = true;

            if (em.Finished && live == 0)
            {
                _byHandle.Remove(handle);
                _handleOrder.RemoveAt(i);
                i--;
                EmitterDied?.Invoke(handle);
            }
        }
    }

    public IEnumerable<(ParticleEmitter Emitter, int Index)> EnumerateLive()
    {
        foreach (var handle in _handleOrder)
        {
            if (!_byHandle.TryGetValue(handle, out var em))
                continue;

            for (int i = 0; i < em.Particles.Length; i++)
            {
                if (em.Particles[i].Alive)
                    yield return (em, i);
            }
        }
    }

    private void AdvanceEmitter(ParticleEmitter em)
    {
        for (int i = 0; i < em.Particles.Length; i++)
        {
            ref var p = ref em.Particles[i];
            if (!p.Alive)
                continue;

            p.Age = _time - p.SpawnedAt;
            if (p.Lifetime <= 0f || p.Age >= p.Lifetime)
            {
                p.Alive = false;
                continue;
            }

            p.Position = ComputePosition(em, p);
            float tLife = Math.Clamp(p.Age / p.Lifetime, 0f, 1f);
            p.Size = Lerp(p.StartSize, p.EndSize, tLife);
            p.Rotation = Lerp(em.Desc.StartRotation, em.Desc.EndRotation, tLife);
            float alpha = Lerp(p.StartAlpha, p.EndAlpha, tLife);
            p.ColorArgb = Color32(alpha, em.Desc.StartColorArgb, em.Desc.EndColorArgb, tLife);
        }

        if (em.Finished || _time < em.StartedAt + em.Desc.StartDelay)
            return;

        while (ShouldEmitParticle(em))
        {
            if (!SpawnOne(em, allowWhenFull: false))
                break;
        }

        if (em.Desc.Birthrate <= 0f && em.Desc.EmitRate > 0f)
        {
            float dt = _time - em.LastEmitTime;
            em.EmittedAccumulator += dt * em.Desc.EmitRate;
            em.LastEmitTime = _time;
            while (em.EmittedAccumulator >= 1f)
            {
                em.EmittedAccumulator -= 1f;
                if (!SpawnOne(em, allowWhenFull: false))
                    break;
            }
        }
    }

    private bool ShouldEmitParticle(ParticleEmitter em)
    {
        var desc = em.Desc;
        if (desc.TotalParticles > 0 && em.TotalEmitted >= desc.TotalParticles)
            return false;

        if (CountAlive(em) >= desc.MaxParticles)
            return false;

        if (desc.Birthrate <= 0f)
            return false;

        return desc.EmitterKind switch
        {
            ParticleEmitterKind.BirthratePerSec => (_time - em.LastEmitTime) > desc.Birthrate,
            ParticleEmitterKind.BirthratePerMeter =>
                Vector3.DistanceSquared(em.AnchorPos, em.LastEmitOffset) > desc.Birthrate * desc.Birthrate,
            _ => false,
        };
    }

    private bool SpawnOne(ParticleEmitter em, bool allowWhenFull)
    {
        int slot = FindFreeSlot(em);
        if (slot < 0 && allowWhenFull)
            slot = FindOldestSlot(em);
        if (slot < 0)
            return false;

        ref var particle = ref em.Particles[slot];
        particle = default;
        particle.Alive = true;
        particle.SpawnedAt = _time;
        particle.Lifetime = RandomLifespan(em.Desc);
        particle.EmissionOrigin = em.AnchorPos;
        particle.SpawnRotation = em.AnchorRot;

        Vector3 localOffset = RandomOffset(em.Desc);
        Vector3 localA = RandomVector(em.Desc.A, em.Desc.MinA, em.Desc.MaxA);
        Vector3 localB = RandomVector(em.Desc.B, em.Desc.MinB, em.Desc.MaxB);
        Vector3 localC = RandomVector(em.Desc.C, em.Desc.MinC, em.Desc.MaxC);

        if (localA == Vector3.Zero && em.Desc.InitialVelocity != Vector3.Zero)
        {
            localA = em.Desc.InitialVelocity;
            if (em.Desc.VelocityJitter > 0f)
            {
                localA += new Vector3(
                    RandomCentered(em.Desc.VelocityJitter),
                    RandomCentered(em.Desc.VelocityJitter),
                    RandomCentered(em.Desc.VelocityJitter));
            }
        }
        if (localB == Vector3.Zero && em.Desc.Gravity != Vector3.Zero)
            localB = em.Desc.Gravity;

        InitParticleVectors(em, ref particle, localOffset, localA, localB, localC);

        particle.Velocity = particle.A;
        particle.StartSize = RandomScale(em.Desc.StartSize, em.Desc.ScaleRand);
        particle.EndSize = RandomScale(em.Desc.EndSize, em.Desc.ScaleRand);
        particle.StartAlpha = RandomTrans(em.Desc.StartAlpha, em.Desc.TransRand);
        particle.EndAlpha = RandomTrans(em.Desc.EndAlpha, em.Desc.TransRand);
        particle.Size = particle.StartSize;
        particle.ColorArgb = Color32(particle.StartAlpha, em.Desc.StartColorArgb, em.Desc.EndColorArgb, 0f);
        particle.Position = ComputePosition(em, particle);

        em.TotalEmitted++;
        em.LastEmitTime = _time;
        em.LastEmitOffset = em.AnchorPos;
        return true;
    }

    private Vector3 ComputePosition(ParticleEmitter em, Particle p)
    {
        float t = p.Age;
        Vector3 origin = (em.Desc.Flags & EmitterFlags.AttachLocal) != 0
            ? em.AnchorPos
            : p.EmissionOrigin;
        Vector3 offset = p.Offset;
        Vector3 a = p.A;
        Vector3 b = p.B;
        Vector3 c = p.C;

        return em.Desc.Type switch
        {
            ParticleType.Still => origin + offset,
            ParticleType.LocalVelocity or ParticleType.GlobalVelocity =>
                origin + offset + t * a,
            ParticleType.ParabolicLVGA or ParticleType.ParabolicLVLA or ParticleType.ParabolicGVGA =>
                origin + offset + t * a + 0.5f * t * t * b,
            ParticleType.ParabolicLVGAGR or ParticleType.ParabolicLVLALR or ParticleType.ParabolicGVGAGR =>
                origin + offset + t * a + 0.5f * t * t * b,
            ParticleType.Swarm =>
                origin + offset + t * a + new Vector3(
                    MathF.Cos(t * b.X) * c.X,
                    MathF.Sin(t * b.Y) * c.Y,
                    MathF.Cos(t * b.Z) * c.Z),
            ParticleType.Explode =>
                origin + offset + new Vector3(
                    (t * b.X + c.X * a.X) * t,
                    (t * b.Y + c.Y * a.X) * t,
                    (t * b.Z + c.Z * a.X + a.Z) * t),
            ParticleType.Implode =>
                origin + offset + MathF.Cos(a.X * t) * c + t * t * b,
            _ => origin + offset + t * a,
        };
    }

    private void InitParticleVectors(
        ParticleEmitter em,
        ref Particle particle,
        Vector3 localOffset,
        Vector3 localA,
        Vector3 localB,
        Vector3 localC)
    {
        // Retail Particle::Init 0x0051c930 resolves local/global vector
        // spaces once at spawn; Particle::Update 0x0051c290 then integrates
        // those stored world-space coefficients each frame.
        particle.Offset = ToSpawnWorld(em, localOffset);
        particle.A = localA;
        particle.B = localB;
        particle.C = localC;

        switch (em.Desc.Type)
        {
            case ParticleType.LocalVelocity:
            case ParticleType.ParabolicLVGA:
                particle.A = ToSpawnWorld(em, localA);
                break;

            case ParticleType.ParabolicLVLA:
                particle.A = ToSpawnWorld(em, localA);
                particle.B = ToSpawnWorld(em, localB);
                break;

            case ParticleType.ParabolicLVGAGR:
                particle.A = ToSpawnWorld(em, localA);
                particle.C = localC;
                break;

            case ParticleType.Swarm:
                particle.A = ToSpawnWorld(em, localA);
                break;

            case ParticleType.Explode:
                particle.A = localA;
                particle.B = localB;
                particle.C = RandomExplodeDirection(localC);
                break;

            case ParticleType.Implode:
                particle.A = localA;
                particle.B = localB;
                particle.Offset = new Vector3(
                    particle.Offset.X * localC.X,
                    particle.Offset.Y * localC.Y,
                    particle.Offset.Z * localC.Z);
                particle.C = particle.Offset;
                break;

            case ParticleType.ParabolicLVLALR:
                particle.A = ToSpawnWorld(em, localA);
                particle.B = ToSpawnWorld(em, localB);
                particle.C = ToSpawnWorld(em, localC);
                break;

            case ParticleType.ParabolicGVGAGR:
                particle.C = localC;
                break;
        }
    }

    private static Vector3 ToSpawnWorld(ParticleEmitter em, Vector3 value)
        => em.AnchorRot == Quaternion.Identity ? value : Vector3.Transform(value, em.AnchorRot);

    private Vector3 RandomExplodeDirection(Vector3 localC)
    {
        float yaw = RandomRange(-MathF.PI, MathF.PI);
        float pitch = RandomRange(-MathF.PI, MathF.PI);
        float cosPitch = MathF.Cos(pitch);
        Vector3 c = new(
            MathF.Cos(yaw) * localC.X * cosPitch,
            MathF.Sin(yaw) * localC.Y * cosPitch,
            MathF.Sin(pitch) * localC.Z);

        return NormalizeCheckSmall(ref c) ? Vector3.Zero : c;
    }

    private int FindFreeSlot(ParticleEmitter em)
    {
        for (int i = 0; i < em.Particles.Length; i++)
        {
            if (!em.Particles[i].Alive)
                return i;
        }

        return -1;
    }

    private static int FindOldestSlot(ParticleEmitter em)
    {
        int slot = -1;
        float best = -1f;
        for (int i = 0; i < em.Particles.Length; i++)
        {
            ref var p = ref em.Particles[i];
            float r = p.Lifetime > 0f ? p.Age / p.Lifetime : 1f;
            if (r > best)
            {
                best = r;
                slot = i;
            }
        }

        return slot;
    }

    private static int CountAlive(ParticleEmitter em)
    {
        int n = 0;
        for (int i = 0; i < em.Particles.Length; i++)
        {
            if (em.Particles[i].Alive)
                n++;
        }

        return n;
    }

    private float RandomLifespan(EmitterDesc desc)
    {
        float lifespan = desc.Lifespan > 0f ? desc.Lifespan : (desc.LifetimeMin + desc.LifetimeMax) * 0.5f;
        float rand = desc.LifespanRand > 0f ? desc.LifespanRand : MathF.Abs(desc.LifetimeMax - desc.LifetimeMin) * 0.5f;
        float value = lifespan + RandomCentered(rand);
        if (value <= 0f && desc.LifetimeMax > 0f)
            value = Lerp(desc.LifetimeMin, desc.LifetimeMax, (float)_rng.NextDouble());
        return MathF.Max(0f, value);
    }

    private Vector3 RandomOffset(EmitterDesc desc)
    {
        float min = MathF.Min(desc.MinOffset, desc.MaxOffset);
        float max = MathF.Max(desc.MinOffset, desc.MaxOffset);
        if (max <= 0f)
            return Vector3.Zero;

        Vector3 axis = NormalizeOrZero(desc.OffsetDir);
        Vector3 v = new(
            RandomCentered(1f),
            RandomCentered(1f),
            RandomCentered(1f));

        if (axis != Vector3.Zero)
            v -= axis * Vector3.Dot(v, axis);

        if (v.LengthSquared() < 1e-8f)
            v = axis != Vector3.Zero ? Perpendicular(axis) : Vector3.UnitX;
        else
            v = Vector3.Normalize(v);

        return v * Lerp(min, max, (float)_rng.NextDouble());
    }

    private Vector3 RandomVector(Vector3 direction, float min, float max)
    {
        if (direction == Vector3.Zero)
            return Vector3.Zero;

        if (max < min)
            (min, max) = (max, min);

        return direction * Lerp(min, max, (float)_rng.NextDouble());
    }

    private float RandomScale(float baseValue, float rand)
        => Math.Clamp(baseValue + RandomCentered(rand), 0.1f, 10f);

    private float RandomTrans(float baseValue, float rand)
        => Math.Clamp(baseValue + RandomCentered(rand), 0f, 1f);

    private float RandomCentered(float halfWidth)
        => ((float)_rng.NextDouble() - 0.5f) * 2f * halfWidth;

    private float RandomRange(float min, float max)
        => Lerp(min, max, (float)_rng.NextDouble());

    private static float Lerp(float a, float b, float t) => a + (b - a) * t;

    private static Vector3 NormalizeOrZero(Vector3 v)
        => v.LengthSquared() > 1e-8f ? Vector3.Normalize(v) : Vector3.Zero;

    private static bool NormalizeCheckSmall(ref Vector3 v)
    {
        float length = v.Length();
        if (length < 1e-8f)
            return true;

        v /= length;
        return false;
    }

    private static Vector3 Perpendicular(Vector3 v)
    {
        Vector3 basis = MathF.Abs(v.X) < 0.9f ? Vector3.UnitX : Vector3.UnitY;
        return Vector3.Normalize(Vector3.Cross(v, basis));
    }

    private static uint Color32(float alpha, uint startArgb, uint endArgb, float t)
    {
        byte sr = (byte)((startArgb >> 16) & 0xFF);
        byte sg = (byte)((startArgb >> 8) & 0xFF);
        byte sb = (byte)(startArgb & 0xFF);
        byte er = (byte)((endArgb >> 16) & 0xFF);
        byte eg = (byte)((endArgb >> 8) & 0xFF);
        byte eb = (byte)(endArgb & 0xFF);

        byte r = (byte)Math.Clamp(sr + (er - sr) * t, 0f, 255f);
        byte g = (byte)Math.Clamp(sg + (eg - sg) * t, 0f, 255f);
        byte b = (byte)Math.Clamp(sb + (eb - sb) * t, 0f, 255f);
        byte a = (byte)Math.Clamp(alpha * 255f, 0f, 255f);
        return ((uint)a << 24) | ((uint)r << 16) | ((uint)g << 8) | b;
    }
}