f48c74aa8b
Subtract 0.01 from every terrain vertex Z in the modern terrain vertex shader, matching retail's per-draw nudge applied inside ACRender::landPolysDraw(arg2=2). Coplanar building floors now always win the depth test against the rendered terrain, so the visual "ground at the building floor" reads as the building's floor, not as Z-fighting. Constant 0.01f bit-equals retail's float literal 0.00999999978 when rounded to single precision. Render-only — physics reads the un-nudged heightmap via TerrainSurface.SampleZ / SampleZFromHeightmap. The same render-vs- physics split is already established for EnvCell render lift (+0.02m at GameWindow.cs around the cell-mesh draw). Retail anchors: docs/research/named-retail/acclient_2013_pseudo_c.txt:1120769 docs/research/named-retail/acclient_2013_pseudo_c.txt:702254 Cross-ref: docs/research/2026-05-25-issue-100-terrain-cutout-handoff.md docs/superpowers/plans/2026-05-25-issue-100-terrain-cutout.md Followed by Task 2 (delete the hiddenTerrainCells / BuildingTerrainCells plumbing). Visible result of this commit alone: building floors stop Z-fighting, but the 24m x 24m transparent rectangles persist until the plumbing is removed. Co-Authored-By: Claude Opus 4.7 (1M context) <noreply@anthropic.com>
147 lines
6 KiB
GLSL
147 lines
6 KiB
GLSL
#version 460 core
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#extension GL_ARB_bindless_texture : require
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// Phase N.5b: terrain shader on the modern bindless dispatcher.
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// Math identical to terrain.vert (Phase 3c per-cell mesh + Phase G AdjustPlanes
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// lighting). The only structural change is the version + bindless extension
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// — sampler access in the fragment stage is unchanged at the GLSL level.
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layout(location = 0) in vec3 aPos;
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layout(location = 1) in vec3 aNormal;
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layout(location = 2) in uvec4 aPacked0;
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layout(location = 3) in uvec4 aPacked1;
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layout(location = 4) in uvec4 aPacked2;
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layout(location = 5) in uvec4 aPacked3;
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uniform mat4 uView;
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uniform mat4 uProjection;
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struct Light {
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vec4 posAndKind;
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vec4 dirAndRange;
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vec4 colorAndIntensity;
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vec4 coneAngleEtc;
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};
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layout(std140, binding = 1) uniform SceneLighting {
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Light uLights[8];
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vec4 uCellAmbient;
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vec4 uFogParams;
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vec4 uFogColor;
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vec4 uCameraAndTime;
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};
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out vec2 vBaseUV;
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out vec3 vWorldNormal;
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out vec3 vWorldPos;
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out vec3 vLightingRGB;
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out vec4 vOverlay0;
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out vec4 vOverlay1;
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out vec4 vOverlay2;
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out vec4 vRoad0;
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out vec4 vRoad1;
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flat out float vBaseTexIdx;
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// Retail's N·L floor from FUN_00532440 lines 2119/2138/2157/2176 at
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// chunk_00530000.c (AdjustPlanes). The decompile reads:
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// if (fVar3 < DAT_00796344) fVar3 = DAT_00796344;
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// applied to the clamped Lambert result BEFORE it's multiplied into
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// dirColor. DAT_00796344's exact literal isn't pinned by the decompile
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// but every other "floor" use in retail clamps negatives to zero (the
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// physically-correct Lambert half-space). Our previous 0.08 was a
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// defensive guess from early acdream days that made back-lit terrain
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// visibly brighter than retail (user-observed 2026-04-24 "acdream
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// warmer / less blue than retail"). Reverting to 0.0 matches retail
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// per the decompile and lets ambient fill in the back side.
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// Cross-ref: docs/research/2026-04-24-lambert-brightness-split.md.
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const float MIN_FACTOR = 0.0;
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vec4 unpackOverlayLayer(uint texIdxU, uint alphaIdxU, uint rotIdx, vec2 baseUV) {
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float texIdx = float(texIdxU);
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float alphaIdx = float(alphaIdxU);
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if (texIdx >= 254.0) texIdx = -1.0;
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if (alphaIdx >= 254.0) alphaIdx = -1.0;
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vec2 rotatedUV = baseUV;
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if (rotIdx == 1u) rotatedUV = vec2(1.0 - baseUV.y, baseUV.x);
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else if (rotIdx == 2u) rotatedUV = vec2(1.0 - baseUV.x, 1.0 - baseUV.y);
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else if (rotIdx == 3u) rotatedUV = vec2( baseUV.y, 1.0 - baseUV.x);
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return vec4(rotatedUV.x, rotatedUV.y, texIdx, alphaIdx);
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}
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void main() {
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// Unpack rotation fields from aPacked3. Bit layout (data3):
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// .x (byte 0): bits 0-1 rotBase (unused), 2-3 rotOvl0, 4-5 rotOvl1, 6-7 rotOvl2
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// .y (byte 1): bits 0-1 rotRd0 (= data3 bit 8-9),
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// bits 2-3 rotRd1 (= data3 bit 10-11),
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// bit 4 splitDir (= data3 bit 12)
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uint rotOvl0 = (aPacked3.x >> 2u) & 3u;
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uint rotOvl1 = (aPacked3.x >> 4u) & 3u;
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uint rotOvl2 = (aPacked3.x >> 6u) & 3u;
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uint rotRd0 = aPacked3.y & 3u;
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uint rotRd1 = (aPacked3.y >> 2u) & 3u;
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uint splitDir= (aPacked3.y >> 4u) & 1u;
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// Derive which of the 4 cell corners this vertex represents from
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// gl_VertexID % 6. The CPU-side LandblockMesh emits vertices in a
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// specific order for each split direction; the tables below must stay
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// in lockstep with LandblockMesh.Build's SWtoNE/SEtoNW branches.
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// 2026-04-21 fix: geometry re-derived to match ACE's ConstructPolygons
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// convention. SWtoNE (cut BL→TR, y=x diagonal) now maps to the {BL,BR,TR}
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// + {BL,TR,TL} triangle pair; SEtoNW (cut BR→TL, x+y=1 diagonal) maps to
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// {BL,BR,TL} + {BR,TR,TL}.
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int vIdx = gl_VertexID % 6;
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int corner = 0;
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if (splitDir == 0u) {
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// SWtoNE order: BL, BR, TR, BL, TR, TL → corners 0, 1, 2, 0, 2, 3
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if (vIdx == 0) corner = 0;
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else if (vIdx == 1) corner = 1;
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else if (vIdx == 2) corner = 2;
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else if (vIdx == 3) corner = 0;
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else if (vIdx == 4) corner = 2;
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else corner = 3;
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} else {
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// SEtoNW order: BL, BR, TL, BR, TR, TL → corners 0, 1, 3, 1, 2, 3
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if (vIdx == 0) corner = 0;
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else if (vIdx == 1) corner = 1;
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else if (vIdx == 2) corner = 3;
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else if (vIdx == 3) corner = 1;
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else if (vIdx == 4) corner = 2;
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else corner = 3;
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}
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vec2 baseUV;
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if (corner == 0) baseUV = vec2(0.0, 1.0);
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else if (corner == 1) baseUV = vec2(1.0, 1.0);
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else if (corner == 2) baseUV = vec2(1.0, 0.0);
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else baseUV = vec2(0.0, 0.0);
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vBaseUV = baseUV;
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vWorldPos = aPos;
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vWorldNormal = normalize(aNormal);
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// Retail AdjustPlanes bake (terrain.vert:124-134 — identical math).
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vec3 sunDir = uLights[0].dirAndRange.xyz;
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vec3 sunCol = uLights[0].colorAndIntensity.xyz * uLights[0].colorAndIntensity.w;
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float L = max(dot(vWorldNormal, -sunDir), MIN_FACTOR);
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vLightingRGB = sunCol * L + uCellAmbient.xyz;
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float baseTex = float(aPacked0.x);
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if (baseTex >= 254.0) baseTex = -1.0;
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vBaseTexIdx = baseTex;
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vOverlay0 = unpackOverlayLayer(aPacked0.z, aPacked0.w, rotOvl0, baseUV);
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vOverlay1 = unpackOverlayLayer(aPacked1.x, aPacked1.y, rotOvl1, baseUV);
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vOverlay2 = unpackOverlayLayer(aPacked1.z, aPacked1.w, rotOvl2, baseUV);
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vRoad0 = unpackOverlayLayer(aPacked2.x, aPacked2.y, rotRd0, baseUV);
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vRoad1 = unpackOverlayLayer(aPacked2.z, aPacked2.w, rotRd1, baseUV);
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// Retail zFightTerrainAdjust (acclient_2013_pseudo_c.txt:1120769 = 0.00999999978,
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// applied per terrain vertex inside ACRender::landPolysDraw at line 702254,
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// address 006b6402). Render terrain 1 cm below its physical Z so coplanar
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// building floors win the depth test. Physics path is unaffected — it reads
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// the un-nudged heightmap via TerrainSurface.SampleZ.
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// Closes issue #100; supersedes the hiddenTerrainCells cell-collapse hack.
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vec3 terrainPos = vec3(aPos.xy, aPos.z - 0.01);
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gl_Position = uProjection * uView * vec4(terrainPos, 1.0);
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}
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