The faithful fix for the spotty dungeon/house/outdoor lighting is retail's per-vertex static-light bake (D3DPolyRender::SetStaticLightingVertexColors 0x0059cfe0), NOT a per-pixel ramp. This lands the GL-free Core: LightBake.PointContribution / ComputeVertexColor port calc_point_light (0x0059c8b0) VERBATIM — verified against a clean Ghidra decompile (the BN pseudo-C is x87-mangled): half-Lambert wrap with LIGHT_POINT_RANGE=0.75 (0x007e5430), the distsq>1 norm branch, the per-channel min-to-color clamp, and the final [0,1] clamp. static_light_factor=1.3 (0x00820e24) is already folded into LightSource.Range by LightInfoLoader. 7 conformance tests (hand-derived golden values) green. NOT wired yet — the integration (a per-vertex colour attribute on the cell mesh + the bake driver keyed on envCellId + the shader consumption) is the remaining A7 work; see ISSUES.md A7. Co-Authored-By: Claude Opus 4.8 (1M context) <noreply@anthropic.com>
109 lines
4 KiB
C#
109 lines
4 KiB
C#
using System;
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using System.Numerics;
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using AcDream.Core.Lighting;
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using Xunit;
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namespace AcDream.Core.Tests.Lighting;
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/// <summary>
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/// Conformance tests for the per-vertex static-light burn-in
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/// (<see cref="LightBake"/>), ported from retail <c>calc_point_light</c>
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/// (0x0059c8b0). Golden values are hand-derived from the decompiled equation:
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/// wrap = (1/1.5)·(N·D + 0.5·dist); norm = distsq>1 ? distsq·dist : dist;
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/// scale = (1 − dist/Range)·intensity·(wrap/norm); contrib = min(scale·color, color).
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/// </summary>
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public sealed class LightBakeTests
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{
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private static LightSource Torch(Vector3 pos, float intensity = 100f, float range = 10f)
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=> new LightSource
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{
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Kind = LightKind.Point,
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WorldPosition = pos,
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ColorLinear = Vector3.One,
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Intensity = intensity,
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Range = range,
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IsLit = true,
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};
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[Fact]
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public void NearTorch_FacingIt_SaturatesToColor()
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{
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// Vertex at origin facing up (+Z); torch 2 m above.
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// dist=2, distsq=4, wrap=(1/1.5)(2+1)=2, norm=4·2=8,
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// scale=(1-0.2)·100·(2/8)=20 → min(20·1,1)=1 per channel.
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var c = LightBake.PointContribution(
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Vector3.Zero, new Vector3(0, 0, 1), Torch(new Vector3(0, 0, 2)));
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Assert.Equal(1f, c.X, 4);
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Assert.Equal(1f, c.Y, 4);
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Assert.Equal(1f, c.Z, 4);
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}
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[Fact]
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public void FarTorch_FallsOffSmoothly()
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{
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// Torch 8 m above (still within Range 10). scale=(1-0.8)·100·(8/512)=0.3125.
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var c = LightBake.PointContribution(
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Vector3.Zero, new Vector3(0, 0, 1), Torch(new Vector3(0, 0, 8)));
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Assert.Equal(0.3125f, c.X, 4);
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Assert.Equal(0.3125f, c.Y, 4);
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Assert.Equal(0.3125f, c.Z, 4);
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}
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[Fact]
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public void OutOfRange_ContributesNothing()
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{
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// Torch 11 m above, Range 10 → dist >= falloff_eff, skipped.
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var c = LightBake.PointContribution(
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Vector3.Zero, new Vector3(0, 0, 1), Torch(new Vector3(0, 0, 11)));
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Assert.Equal(Vector3.Zero, c);
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}
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[Fact]
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public void FacingAway_BeyondWrap_ContributesNothing()
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{
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// Normal points away (−Z) from a torch above: N·D=−2, wrap=(1/1.5)(−2+1)<0.
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var c = LightBake.PointContribution(
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Vector3.Zero, new Vector3(0, 0, -1), Torch(new Vector3(0, 0, 2)));
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Assert.Equal(Vector3.Zero, c);
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}
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[Fact]
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public void HalfLambertWrap_LightsSurfaceAngledPast90Degrees()
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{
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// Normal at ~100° from the light direction still gets light (Lambert would not).
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// Light straight above (+Z 2 m); normal tilted to (sin100°, 0, cos100°).
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double t = 100.0 * Math.PI / 180.0;
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var n = new Vector3((float)Math.Sin(t), 0, (float)Math.Cos(t)); // cos100° < 0
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var c = LightBake.PointContribution(Vector3.Zero, n, Torch(new Vector3(0, 0, 2)));
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Assert.True(c.X > 0f, "half-Lambert wrap should light a surface angled past 90°");
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}
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[Fact]
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public void ComputeVertexColor_SumsLightsAndClampsToOne()
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{
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// Two saturating torches → sum clamps to 1, never overflows.
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var lights = new[]
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{
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Torch(new Vector3(0, 0, 2)),
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Torch(new Vector3(0, 0, 2)),
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};
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var c = LightBake.ComputeVertexColor(Vector3.Zero, new Vector3(0, 0, 1), lights);
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Assert.Equal(1f, c.X, 4);
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Assert.Equal(1f, c.Y, 4);
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Assert.Equal(1f, c.Z, 4);
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}
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[Fact]
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public void ComputeVertexColor_SkipsDirectionalAndUnlit()
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{
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var lights = new[]
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{
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new LightSource { Kind = LightKind.Directional, WorldPosition = new Vector3(0,0,2),
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ColorLinear = Vector3.One, Intensity = 100f, Range = 10f, IsLit = true },
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new LightSource { Kind = LightKind.Point, WorldPosition = new Vector3(0,0,2),
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ColorLinear = Vector3.One, Intensity = 100f, Range = 10f, IsLit = false },
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};
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var c = LightBake.ComputeVertexColor(Vector3.Zero, new Vector3(0, 0, 1), lights);
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Assert.Equal(Vector3.Zero, c);
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}
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}
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