#include "Runtime/World/CFluidPlaneCPU.hpp" #include "Runtime/CSimplePool.hpp" #include "Runtime/CStateManager.hpp" #include "Runtime/GameGlobalObjects.hpp" #include "Runtime/Camera/CGameCamera.hpp" #include "Runtime/World/CFluidPlaneManager.hpp" #include "Runtime/World/CScriptWater.hpp" #include "Runtime/World/CWorld.hpp" #include "TCastTo.hpp" // Generated file, do not modify include path namespace metaforce { constexpr u32 kTableSize = 2048; CFluidPlaneCPU::CTurbulence::CTurbulence(float speed, float distance, float freqMax, float freqMin, float phaseMax, float phaseMin, float amplitudeMax, float amplitudeMin) : x0_speed(speed) , x4_distance(distance) , x8_freqMax(freqMax) , xc_freqMin(freqMin) , x10_phaseMax(phaseMax) , x14_phaseMin(phaseMin) , x18_amplitudeMax(amplitudeMax) , x1c_amplitudeMin(amplitudeMin) , x2c_ooTurbSpeed(1.f / x0_speed) , x30_ooTurbDistance(1.f / x4_distance) { if (x18_amplitudeMax == 0.f && x1c_amplitudeMin == 0.f) { return; } x24_tableCount = kTableSize; x28_heightSelPitch = x24_tableCount; x20_table.reset(new float[x24_tableCount]); const float anglePitch = 2.f * M_PIF / x28_heightSelPitch; const float freqConstant = 0.5f * (x8_freqMax + xc_freqMin); const float freqLinear = 0.5f * (x8_freqMax - xc_freqMin); const float phaseConstant = 0.5f * (x10_phaseMax + x14_phaseMin); const float phaseLinear = 0.5f * (x10_phaseMax - x14_phaseMin); const float amplitudeConstant = 0.5f * (x18_amplitudeMax + x1c_amplitudeMin); const float amplitudeLinear = 0.5f * (x18_amplitudeMax - x1c_amplitudeMin); float curAng = 0.f; for (size_t i = 0; i < x24_tableCount; ++i, curAng += anglePitch) { const float angCos = std::cos(curAng); x20_table[i] = (amplitudeLinear * angCos + amplitudeConstant) * std::sin((freqLinear * angCos + freqConstant) * curAng + (phaseLinear * angCos + phaseConstant)); } x34_hasTurbulence = true; } CFluidPlaneCPU::CFluidPlaneCPU(CAssetId texPattern1, CAssetId texPattern2, CAssetId texColor, CAssetId bumpMap, CAssetId envMap, CAssetId envBumpMap, CAssetId lightMap, float unitsPerLightmapTexel, float tileSize, u32 tileSubdivisions, EFluidType fluidType, float alpha, const zeus::CVector3f& bumpLightDir, float bumpScale, const CFluidUVMotion& mot, float turbSpeed, float turbDistance, float turbFreqMax, float turbFreqMin, float turbPhaseMax, float turbPhaseMin, float turbAmplitudeMax, float turbAmplitudeMin, float specularMin, float specularMax, float reflectionBlend, float reflectionSize, float rippleIntensity, u32 maxVertCount) : CFluidPlane(texPattern1, texPattern2, texColor, alpha, fluidType, rippleIntensity, mot) , xa0_texIdBumpMap(bumpMap) , xa4_texIdEnvMap(envMap) , xa8_texIdEnvBumpMap(envBumpMap) , xac_texId4(lightMap) , xf0_bumpLightDir(bumpLightDir) , xfc_bumpScale(bumpScale) , x100_tileSize(tileSize) , x104_tileSubdivisions(tileSubdivisions & ~0x1) , x108_rippleResolution(x100_tileSize / float(x104_tileSubdivisions)) , x10c_specularMin(specularMin) , x110_specularMax(specularMax) , x114_reflectionBlend(reflectionBlend) , x118_reflectionSize(reflectionSize) , x11c_unitsPerLightmapTexel(unitsPerLightmapTexel) , x120_turbulence(turbSpeed, turbDistance, turbFreqMax, turbFreqMin, turbPhaseMax, turbPhaseMin, turbAmplitudeMax, turbAmplitudeMin) , m_maxVertCount(maxVertCount) { if (g_ResFactory->GetResourceTypeById(xa0_texIdBumpMap) == FOURCC('TXTR')) xb0_bumpMap = g_SimplePool->GetObj(SObjectTag{FOURCC('TXTR'), xa0_texIdBumpMap}); if (g_ResFactory->GetResourceTypeById(xa4_texIdEnvMap) == FOURCC('TXTR')) xc0_envMap = g_SimplePool->GetObj(SObjectTag{FOURCC('TXTR'), xa4_texIdEnvMap}); if (g_ResFactory->GetResourceTypeById(xa8_texIdEnvBumpMap) == FOURCC('TXTR')) xd0_envBumpMap = g_SimplePool->GetObj(SObjectTag{FOURCC('TXTR'), xa8_texIdEnvBumpMap}); if (g_ResFactory->GetResourceTypeById(xac_texId4) == FOURCC('TXTR')) xe0_lightmap = g_SimplePool->GetObj(SObjectTag{FOURCC('TXTR'), xac_texId4}); } void CFluidPlaneCPU::CreateRipple(const CRipple& ripple, CStateManager& mgr) {} void CFluidPlaneCPU::CalculateLightmapMatrix(const zeus::CTransform& areaXf, const zeus::CTransform& xf, const zeus::CAABox& aabb, zeus::CMatrix4f& mtxOut) const { int width = GetLightMap().GetWidth(); int height = GetLightMap().GetHeight(); zeus::CTransform toLocal = areaXf.getRotation().inverse(); zeus::CAABox areaLocalAABB = aabb.getTransformedAABox(toLocal); float f26 = (areaLocalAABB.max.x() - areaLocalAABB.min.x()) / (width * x11c_unitsPerLightmapTexel); float f25 = (areaLocalAABB.max.y() - areaLocalAABB.min.y()) / (height * x11c_unitsPerLightmapTexel); float f24 = (1.f + std::fmod(areaLocalAABB.min.x() + xf.origin.x(), x11c_unitsPerLightmapTexel)) / width; float f23 = (2.f - std::fmod(areaLocalAABB.max.x() + xf.origin.x(), x11c_unitsPerLightmapTexel)) / width; float f29 = (1.f + std::fmod(areaLocalAABB.min.y() + xf.origin.y(), x11c_unitsPerLightmapTexel)) / height; float f6 = (2.f - std::fmod(areaLocalAABB.max.y() + xf.origin.y(), x11c_unitsPerLightmapTexel)) / height; float scaleX = (f26 - f24 - f23) / (areaLocalAABB.max.x() - areaLocalAABB.min.x()); float scaleY = -(f25 - f29 - f6) / (areaLocalAABB.max.y() - areaLocalAABB.min.y()); float offX = f24 + f26 * -areaLocalAABB.min.x() / (areaLocalAABB.max.x() - areaLocalAABB.min.x()); float offY = f25 * areaLocalAABB.min.y() / (areaLocalAABB.max.y() - areaLocalAABB.min.y()) - f6; mtxOut = (zeus::CTransform(zeus::CMatrix3f(zeus::CVector3f(scaleX, scaleY, 0.f)), zeus::CVector3f(offX, offY, 0.f)) * toLocal) .toMatrix4f(); } static bool sSineWaveInitialized = false; static CFluidPlaneCPU::SineTable sGlobalSineWave{}; static void InitializeSineWave() { if (sSineWaveInitialized) { return; } for (size_t i = 0; i < sGlobalSineWave.size(); ++i) { sGlobalSineWave[i] = std::sin(2.f * M_PIF * (float(i) / 256.f)); } sSineWaveInitialized = true; } #define kEnableWaterBumpMaps true CFluidPlaneShader::RenderSetupInfo CFluidPlaneCPU::RenderSetup(const CStateManager& mgr, float alpha, const zeus::CTransform& xf, const zeus::CTransform& areaXf, const zeus::CAABox& aabb, const CScriptWater* water) { OPTICK_EVENT(); CFluidPlaneShader::RenderSetupInfo out; const float uvT = mgr.GetFluidPlaneManager()->GetUVT(); const bool hasBumpMap = HasBumpMap() && kEnableWaterBumpMaps; bool doubleLightmapBlend = false; const bool hasEnvMap = mgr.GetCameraManager()->GetFluidCounter() == 0 && HasEnvMap(); const bool hasEnvBumpMap = HasEnvBumpMap(); InitializeSineWave(); CGraphics::SetModelMatrix(xf); if (hasBumpMap) { // Build 50% grey directional light with xf0_bumpLightDir and load into LIGHT_3 // Light 3 in channel 1 // Vertex colors in channel 0 out.lights.resize(4); out.lights[3] = CLight::BuildDirectional(xf0_bumpLightDir, zeus::skGrey); } else { // Normal light mask in channel 1 // Vertex colors in channel 0 out.lights = water->GetActorLights()->BuildLightVector(); } int curTex = 3; if (hasBumpMap) { // Load into next curTex++; } if (hasEnvMap) { // Load into next curTex++; } if (hasEnvBumpMap) { // Load into next curTex++; } const auto fluidUVs = x4c_uvMotion.CalculateFluidTextureOffset(uvT); out.texMtxs[0][0][0] = x4c_uvMotion.GetFluidLayers()[1].GetUVScale(); out.texMtxs[0][1][1] = x4c_uvMotion.GetFluidLayers()[1].GetUVScale(); out.texMtxs[0][3][0] = fluidUVs[1][0]; out.texMtxs[0][3][1] = fluidUVs[1][1]; out.texMtxs[1][0][0] = x4c_uvMotion.GetFluidLayers()[2].GetUVScale(); out.texMtxs[1][1][1] = x4c_uvMotion.GetFluidLayers()[2].GetUVScale(); out.texMtxs[1][3][0] = fluidUVs[2][0]; out.texMtxs[1][3][1] = fluidUVs[2][1]; out.texMtxs[2][0][0] = x4c_uvMotion.GetFluidLayers()[0].GetUVScale(); out.texMtxs[2][1][1] = x4c_uvMotion.GetFluidLayers()[0].GetUVScale(); out.texMtxs[2][3][0] = fluidUVs[0][0]; out.texMtxs[2][3][1] = fluidUVs[0][1]; // Load normal mtx 0 with out.normMtx = (zeus::CTransform::Scale(xfc_bumpScale) * CGraphics::g_ViewMatrix.getRotation().inverse()).toMatrix4f(); // Setup TCGs int nextTexMtx = 3; if (hasEnvBumpMap) { float pttScale; if (hasEnvMap) pttScale = 0.5f * (1.f - x118_reflectionSize); else pttScale = g_tweakGame->GetFluidEnvBumpScale() * x4c_uvMotion.GetFluidLayers()[0].GetUVScale(); // Load GX_TEXMTX3 with identity zeus::CMatrix4f& texMtx = out.texMtxs[nextTexMtx++]; texMtx[0][0] = pttScale; texMtx[1][1] = pttScale; texMtx[3][0] = 0.5f; texMtx[3][1] = 0.5f; // Load GX_PTTEXMTX0 with scale of pttScale // Next: GX_TG_MTX2x4 GX_TG_NRM, GX_TEXMTX3, true, GX_PTTEXMTX0 out.indScale = 0.5f * (hasEnvMap ? x118_reflectionSize : 1.f); // Load ind mtx with scale of (indScale, -indScale) // Load envBumpMap into ind stage 0 with previous TCG } if (hasEnvMap) { float scale = std::max(aabb.max.x() - aabb.min.x(), aabb.max.y() - aabb.min.y()); zeus::CMatrix4f& texMtx = out.texMtxs[nextTexMtx++]; texMtx[0][0] = 1.f / scale; texMtx[1][1] = 1.f / scale; zeus::CVector3f center = aabb.center(); texMtx[3][0] = 0.5f + -center.x() / scale; texMtx[3][1] = 0.5f + -center.y() / scale; // Next: GX_TG_MTX2x4 GX_TG_POS, mtxNext, false, GX_PTIDENTITY } if (HasLightMap()) { float lowLightBlend = 1.f; const CGameArea* area = mgr.GetWorld()->GetAreaAlways(mgr.GetNextAreaId()); float lightLevel = area->GetPostConstructed()->x1128_worldLightingLevel; const CScriptWater* nextWater = water->GetNextConnectedWater(mgr); if (std::fabs(water->GetMorphFactor()) < 0.00001f || !nextWater || !nextWater->GetFluidPlane().HasLightMap()) { // Load lightmap CalculateLightmapMatrix(areaXf, xf, aabb, out.texMtxs[nextTexMtx++]); // Next: GX_TG_MTX2x4 GX_TG_POS, mtxNext, false, GX_PTIDENTITY } else if (nextWater && nextWater->GetFluidPlane().HasLightMap()) { if (std::fabs(water->GetMorphFactor() - 1.f) < 0.00001f) { // Load lightmap CalculateLightmapMatrix(areaXf, xf, aabb, out.texMtxs[nextTexMtx++]); // Next: GX_TG_MTX2x4 GX_TG_POS, mtxNext, false, GX_PTIDENTITY } else { // Load lightmap CalculateLightmapMatrix(areaXf, xf, aabb, out.texMtxs[nextTexMtx++]); // Next: GX_TG_MTX2x4 GX_TG_POS, mtxNext, false, GX_PTIDENTITY // Load lightmap CalculateLightmapMatrix(areaXf, xf, aabb, out.texMtxs[nextTexMtx++]); // Next: GX_TG_MTX2x4 GX_TG_POS, mtxNext, false, GX_PTIDENTITY float lum = lightLevel * water->GetMorphFactor(); out.kColors[3] = zeus::CColor(lum, 1.f); lowLightBlend = (1.f - water->GetMorphFactor()) / (1.f - lum); doubleLightmapBlend = true; } } out.kColors[2] = zeus::CColor(lowLightBlend * lightLevel, 1.f); } float waterPlaneOrthoDot = xf.transposeRotate(zeus::skUp).dot(CGraphics::g_ViewMatrix.inverse().transposeRotate(zeus::skForward)); if (waterPlaneOrthoDot < 0.f) waterPlaneOrthoDot = -waterPlaneOrthoDot; out.kColors[0] = zeus::CColor((1.f - waterPlaneOrthoDot) * (x110_specularMax - x10c_specularMin) + x10c_specularMin, alpha); out.kColors[1] = zeus::CColor(x114_reflectionBlend, 1.f); if (!m_shader || m_cachedDoubleLightmapBlend != doubleLightmapBlend || m_cachedAdditive != (mgr.GetThermalDrawFlag() == EThermalDrawFlag::Hot)) { m_cachedDoubleLightmapBlend = doubleLightmapBlend; m_cachedAdditive = mgr.GetThermalDrawFlag() == EThermalDrawFlag::Hot; m_shader.emplace(x44_fluidType, x10_texPattern1, x20_texPattern2, x30_texColor, xb0_bumpMap, xc0_envMap, xd0_envBumpMap, xe0_lightmap, m_tessellation ? CFluidPlaneManager::RippleMapTex : std::shared_ptr{}, m_cachedDoubleLightmapBlend, m_cachedAdditive, m_maxVertCount); } return out; } int CFluidPlaneRender::numTilesInHField; int CFluidPlaneRender::numSubdivisionsInTile; int CFluidPlaneRender::numSubdivisionsInHField; bool CFluidPlaneCPU::PrepareRipple(const CRipple& ripple, const CFluidPlaneRender::SPatchInfo& info, CFluidPlaneRender::SRippleInfo& rippleOut) { auto lifeIdx = int((1.f - (ripple.GetTimeFalloff() - ripple.GetTime()) / ripple.GetTimeFalloff()) * 64.f); float dist = CFluidPlaneManager::RippleMaxs[lifeIdx] * (ripple.GetDistanceFalloff() / 256.f); dist *= dist; if (dist != 0) dist = std::sqrt(dist); dist = info.x24_ooRippleResolution * dist + 1.f; float centerX = info.x24_ooRippleResolution * (ripple.GetCenter().x() - info.xc_globalMin.x()); float centerY = info.x24_ooRippleResolution * (ripple.GetCenter().y() - info.xc_globalMin.y()); int fromX = int(centerX - dist) - 1; int toX = int(centerX + dist) + 1; int fromY = int(centerY - dist) - 1; int toY = int(centerY + dist) + 1; rippleOut.x4_fromX = std::max(0, fromX); rippleOut.x8_toX = std::min(int(info.x0_xSubdivs), toX); rippleOut.xc_fromY = std::max(0, fromY); rippleOut.x10_toY = std::min(int(info.x1_ySubdivs), toY); rippleOut.x14_gfromX = std::max(rippleOut.x14_gfromX, fromX); rippleOut.x18_gtoX = std::min(rippleOut.x18_gtoX, toX); rippleOut.x1c_gfromY = std::max(rippleOut.x1c_gfromY, fromY); rippleOut.x20_gtoY = std::min(rippleOut.x20_gtoY, toY); return !(rippleOut.x14_gfromX > rippleOut.x18_gtoX || rippleOut.x1c_gfromY > rippleOut.x20_gtoY); } void CFluidPlaneCPU::ApplyTurbulence(float t, Heights& heights, const Flags& flags, const SineTable& sineWave, const CFluidPlaneRender::SPatchInfo& info, const zeus::CVector3f& areaCenter) const { if (!HasTurbulence()) { memset(&heights, 0, sizeof(heights)); return; } float scaledT = t * GetOOTurbulenceSpeed(); float curY = info.x4_localMin.y() - info.x18_rippleResolution - areaCenter.y(); int xDivs = (info.x0_xSubdivs + CFluidPlaneRender::numSubdivisionsInTile - 4) / CFluidPlaneRender::numSubdivisionsInTile * CFluidPlaneRender::numSubdivisionsInTile + 2; int yDivs = (info.x1_ySubdivs + CFluidPlaneRender::numSubdivisionsInTile - 4) / CFluidPlaneRender::numSubdivisionsInTile * CFluidPlaneRender::numSubdivisionsInTile + 2; for (int i = 0; i <= yDivs; ++i) { float curYSq = curY * curY; float curX = info.x4_localMin.x() - info.x18_rippleResolution - areaCenter.x(); for (int j = 0; j <= xDivs; ++j) { float distFac = curX * curX + curYSq; if (distFac != 0.f) distFac = std::sqrt(distFac); heights[i][j].height = GetTurbulenceHeight(GetOOTurbulenceDistance() * distFac + scaledT); curX += info.x18_rippleResolution; } curY += info.x18_rippleResolution; } } void CFluidPlaneCPU::ApplyRipple(const CFluidPlaneRender::SRippleInfo& rippleInfo, Heights& heights, Flags& flags, const SineTable& sineWave, const CFluidPlaneRender::SPatchInfo& info) const { float lookupT = 256.f * (1.f - rippleInfo.x0_ripple.GetTime() * rippleInfo.x0_ripple.GetOOTimeFalloff() * rippleInfo.x0_ripple.GetOOTimeFalloff()) * rippleInfo.x0_ripple.GetFrequency(); auto lifeIdx = int(64.f * rippleInfo.x0_ripple.GetTime() * rippleInfo.x0_ripple.GetOOTimeFalloff()); float distMul = rippleInfo.x0_ripple.GetDistanceFalloff() / 255.f; float minDist = CFluidPlaneManager::RippleMins[lifeIdx] * distMul; float minDistSq = minDist * minDist; if (minDistSq != 0.f) minDist = std::sqrt(minDistSq); float maxDist = CFluidPlaneManager::RippleMaxs[lifeIdx] * distMul; float maxDistSq = maxDist * maxDist; if (maxDistSq != 0.f) maxDist = std::sqrt(maxDistSq); int fromY = (rippleInfo.x1c_gfromY + CFluidPlaneRender::numSubdivisionsInTile - 1) / CFluidPlaneRender::numSubdivisionsInTile; int fromX = (rippleInfo.x14_gfromX + CFluidPlaneRender::numSubdivisionsInTile - 1) / CFluidPlaneRender::numSubdivisionsInTile; int toY = (rippleInfo.x20_gtoY + CFluidPlaneRender::numSubdivisionsInTile - 1) / CFluidPlaneRender::numSubdivisionsInTile; int toX = (rippleInfo.x18_gtoX + CFluidPlaneRender::numSubdivisionsInTile - 1) / CFluidPlaneRender::numSubdivisionsInTile; float curY = rippleInfo.x0_ripple.GetCenter().y() - info.xc_globalMin.y() - (0.5f * info.x14_tileSize + (fromY - 1) * info.x14_tileSize); int curGridY = info.x2a_gridDimX * (info.x2e_tileY + fromY - 1); int startGridX = (info.x28_tileX + fromX - 1); int gridCells = info.x2a_gridDimX * info.x2c_gridDimY; float distFalloff = 64.f * rippleInfo.x0_ripple.GetOODistanceFalloff(); int curYDiv = rippleInfo.xc_fromY; for (int i = fromY; i <= toY; ++i, curY -= info.x14_tileSize) { int nextYDiv = (i + 1) * CFluidPlaneRender::numSubdivisionsInTile; float curYSq = curY * curY; int curGridX = startGridX; int curXDiv = rippleInfo.x4_fromX; float curX = rippleInfo.x0_ripple.GetCenter().x() - info.xc_globalMin.x() - (0.5f * info.x14_tileSize + (fromX - 1) * info.x14_tileSize); for (int j = fromX; j <= toX; ++j, curX -= info.x14_tileSize, ++curGridX) { float dist = curX * curX + curYSq; if (dist != 0.f) dist = std::sqrt(dist); if (maxDist < dist - info.x1c_tileHypRadius || minDist > dist + info.x1c_tileHypRadius) continue; bool addedRipple = false; int nextXDiv = (j + 1) * CFluidPlaneRender::numSubdivisionsInTile; float curXMod = (rippleInfo.x0_ripple.GetCenter().x() - info.xc_globalMin.x()) - info.x18_rippleResolution * curXDiv; float curYMod = (rippleInfo.x0_ripple.GetCenter().y() - info.xc_globalMin.y()) - info.x18_rippleResolution * curYDiv; if (!info.x30_gridFlags || (info.x30_gridFlags && curGridY >= 0 && curGridY < gridCells && curGridX >= 0 && curGridX < info.x2a_gridDimX && info.x30_gridFlags[curGridX + curGridY])) { for (int k = curYDiv; k <= std::min(rippleInfo.x10_toY, nextYDiv - 1); ++k, curYMod -= info.x18_rippleResolution) { float tmpXMod = curXMod; float curYModSq = curYMod * curYMod; for (int l = curXDiv; l <= std::min(rippleInfo.x8_toX, nextXDiv - 1); ++l, tmpXMod -= info.x18_rippleResolution) { float divDistSq = tmpXMod * tmpXMod + curYModSq; if (divDistSq < minDistSq || divDistSq > maxDistSq) continue; if (m_tessellation) { /* This will be evaluated in tessellation shader instead */ addedRipple = true; break; } float divDist = (divDistSq != 0.f) ? std::sqrt(divDistSq) : 0.f; if (u8 rippleV = CFluidPlaneManager::RippleValues[lifeIdx][int(divDist * distFalloff)]) { heights[k][l].height += rippleV * rippleInfo.x0_ripple.GetLookupAmplitude() * sineWave[size_t(divDist * rippleInfo.x0_ripple.GetLookupPhase() + lookupT) & 0xff]; } else { heights[k][l].height += 0.f; } addedRipple = true; } } if (addedRipple) flags[i][j] = 0x1f; } else { int yMin = nextYDiv - 1; int yMax = nextYDiv - CFluidPlaneRender::numSubdivisionsInTile + 1; int xMin = nextXDiv - 1; int xMax = nextXDiv - CFluidPlaneRender::numSubdivisionsInTile + 1; if (curGridX >= 0.f && curGridX < info.x2a_gridDimX && curGridY - info.x2a_gridDimX >= 0 && !info.x30_gridFlags[curGridX + curGridY - info.x2a_gridDimX]) yMax -= 2; if (curGridX >= 0.f && curGridX < info.x2a_gridDimX && curGridY + info.x2a_gridDimX < gridCells && !info.x30_gridFlags[curGridX + info.x2a_gridDimX]) yMin += 2; if (curGridY >= 0 && curGridY < info.x2c_gridDimY && curGridX > 0 && !info.x30_gridFlags[curGridX - 1]) xMax -= 2; if (curGridY >= 0 && curGridY < info.x2c_gridDimY && curGridX + 1 < info.x2a_gridDimX && !info.x30_gridFlags[curGridX + 1]) xMin += 2; for (int k = curYDiv; k <= std::min(rippleInfo.x10_toY, nextYDiv - 1); ++k, curYMod -= info.x18_rippleResolution) { float tmpXMod = curXMod; float curYModSq = curYMod * curYMod; for (int l = curXDiv; l <= std::min(rippleInfo.x8_toX, nextXDiv - 1); ++l, tmpXMod -= info.x18_rippleResolution) { if (k <= yMax || k >= yMin || l <= xMax || l >= xMin) { float divDistSq = tmpXMod * tmpXMod + curYModSq; if (divDistSq < minDistSq || divDistSq > maxDistSq) continue; if (m_tessellation) { /* This will be evaluated in tessellation shader instead */ addedRipple = true; break; } float divDist = (divDistSq != 0.f) ? std::sqrt(divDistSq) : 0.f; if (u8 rippleV = CFluidPlaneManager::RippleValues[lifeIdx][int(divDist * distFalloff)]) { heights[k][l].height += rippleV * rippleInfo.x0_ripple.GetLookupAmplitude() * sineWave[size_t(divDist * rippleInfo.x0_ripple.GetLookupPhase() + lookupT) & 0xff]; } else { heights[k][l].height += 0.f; } addedRipple = true; } } if (m_tessellation && addedRipple) break; } if (addedRipple) flags[i][j] = 0xf; } curXDiv = nextXDiv; } curYDiv = nextYDiv; curGridY += info.x2a_gridDimX; } } void CFluidPlaneCPU::ApplyRipples(const rstl::reserved_vector& rippleInfos, Heights& heights, Flags& flags, const SineTable& sineWave, const CFluidPlaneRender::SPatchInfo& info) const { for (const CFluidPlaneRender::SRippleInfo& rippleInfo : rippleInfos) ApplyRipple(rippleInfo, heights, flags, sineWave, info); for (int i = 0; i < CFluidPlaneRender::numTilesInHField; ++i) flags[0][i + 1] |= 1; for (int i = 0; i < CFluidPlaneRender::numTilesInHField; ++i) flags[i + 1][0] |= 8; for (int i = 0; i < CFluidPlaneRender::numTilesInHField; ++i) flags[i + 1][CFluidPlaneRender::numTilesInHField + 1] |= 4; for (int i = 0; i < CFluidPlaneRender::numTilesInHField; ++i) flags[CFluidPlaneRender::numTilesInHField + 1][i + 1] |= 2; } void CFluidPlaneCPU::UpdatePatchNoNormals(Heights& heights, const Flags& flags, const CFluidPlaneRender::SPatchInfo& info) { for (int i = 1; i <= (info.x1_ySubdivs + CFluidPlaneRender::numSubdivisionsInTile - 2) / CFluidPlaneRender::numSubdivisionsInTile; ++i) { int r10 = i * CFluidPlaneRender::numSubdivisionsInTile + 1; int r9 = std::max(0, r10 - CFluidPlaneRender::numSubdivisionsInTile); int x24 = std::min(r10, info.x1_ySubdivs + 1); for (int j = 1; j <= (info.x0_xSubdivs + CFluidPlaneRender::numSubdivisionsInTile - 2) / CFluidPlaneRender::numSubdivisionsInTile; ++j) { int r29 = j * CFluidPlaneRender::numSubdivisionsInTile + 1; int r11 = std::max(0, r29 - CFluidPlaneRender::numSubdivisionsInTile); int x28 = std::min(r29, info.x0_xSubdivs + 1); if ((flags[i][j] & 0x1f) == 0x1f) { for (int k = r9; k < x24; ++k) { for (int l = r11; l < x28; ++l) { CFluidPlaneRender::SHFieldSample& sample = heights[k][l]; if (sample.height > 0.f) sample.wavecapIntensity = u8(std::min(255, int(info.x38_wavecapIntensityScale * sample.height))); else sample.wavecapIntensity = 0; } } } else { if (i > 0 && i < CFluidPlaneRender::numTilesInHField + 1 && j > 0 && j < CFluidPlaneRender::numTilesInHField + 1) { int halfSubdivs = CFluidPlaneRender::numSubdivisionsInTile / 2; CFluidPlaneRender::SHFieldSample& sample = heights[halfSubdivs + r9][halfSubdivs + r11]; if (sample.height > 0.f) sample.wavecapIntensity = u8(std::min(255, int(info.x38_wavecapIntensityScale * sample.height))); else sample.wavecapIntensity = 0; } if (i != 0) { for (int l = r11; l < x28; ++l) { CFluidPlaneRender::SHFieldSample& sample = heights[r9][l]; if (sample.height > 0.f) sample.wavecapIntensity = u8(std::min(255, int(info.x38_wavecapIntensityScale * sample.height))); else sample.wavecapIntensity = 0; } } if (j != 0) { for (int k = r9 + 1; k < x24; ++k) { CFluidPlaneRender::SHFieldSample& sample = heights[k][r11]; if (sample.height > 0.f) sample.wavecapIntensity = u8(std::min(255, int(info.x38_wavecapIntensityScale * sample.height))); else sample.wavecapIntensity = 0; } } } } } } void CFluidPlaneCPU::UpdatePatchWithNormals(Heights& heights, const Flags& flags, const CFluidPlaneRender::SPatchInfo& info) { float normalScale = -(2.f * info.x18_rippleResolution); float nz = 0.25f * 2.f * info.x18_rippleResolution; int curGridY = info.x2e_tileY * info.x2a_gridDimX - 1 + info.x28_tileX; for (int i = 1; i <= (info.x1_ySubdivs + CFluidPlaneRender::numSubdivisionsInTile - 2) / CFluidPlaneRender::numSubdivisionsInTile; ++i, curGridY += info.x2a_gridDimX) { int r11 = i * CFluidPlaneRender::numSubdivisionsInTile + 1; int r9 = std::max(0, r11 - CFluidPlaneRender::numSubdivisionsInTile); int x38 = std::min(r11, info.x1_ySubdivs + 1); for (int j = 1; j <= (info.x0_xSubdivs + CFluidPlaneRender::numSubdivisionsInTile - 2) / CFluidPlaneRender::numSubdivisionsInTile; ++j) { int r12 = j * CFluidPlaneRender::numSubdivisionsInTile + 1; int x3c = std::min(r12, info.x0_xSubdivs + 1); r12 -= CFluidPlaneRender::numSubdivisionsInTile; if ((flags[i][j] & 0x1f) == 0x1f) { for (int k = r9; k < x38; ++k) { for (int l = r12; l < x3c; ++l) { CFluidPlaneRender::SHFieldSample& sample = heights[k][l]; CFluidPlaneRender::SHFieldSample& up = heights[k + 1][l]; CFluidPlaneRender::SHFieldSample& down = heights[k - 1][l]; CFluidPlaneRender::SHFieldSample& right = heights[k][l + 1]; CFluidPlaneRender::SHFieldSample& left = heights[k][l - 1]; float nx = (right.height - left.height) * normalScale; float ny = (up.height - down.height) * normalScale; float normalizer = ny * ny + nx * nx + nz * nz; if (normalizer != 0.f) normalizer = std::sqrt(normalizer); normalizer = 63.f / normalizer; sample.nx = s8(nx * normalizer); sample.ny = s8(ny * normalizer); sample.nz = s8(nz * normalizer); if (sample.height > 0.f) sample.wavecapIntensity = u8(std::min(255, int(info.x38_wavecapIntensityScale * sample.height))); else sample.wavecapIntensity = 0; } } } else { if (!info.x30_gridFlags || info.x30_gridFlags[curGridY + j]) { if (i > 0 && i < CFluidPlaneRender::numTilesInHField + 1 && j > 0 && j < CFluidPlaneRender::numTilesInHField + 1) { int halfSubdivs = CFluidPlaneRender::numSubdivisionsInTile / 2; int k = halfSubdivs + r9; int l = halfSubdivs + r12; CFluidPlaneRender::SHFieldSample& sample = heights[k][l]; CFluidPlaneRender::SHFieldSample& up = heights[k + 1][l]; CFluidPlaneRender::SHFieldSample& down = heights[k - 1][l]; CFluidPlaneRender::SHFieldSample& right = heights[k][l + 1]; CFluidPlaneRender::SHFieldSample& left = heights[k][l - 1]; float nx = (right.height - left.height) * normalScale; float ny = (up.height - down.height) * normalScale; float normalizer = ny * ny + nx * nx + nz * nz; if (normalizer != 0.f) normalizer = std::sqrt(normalizer); normalizer = 63.f / normalizer; sample.nx = s8(nx * normalizer); sample.ny = s8(ny * normalizer); sample.nz = s8(nz * normalizer); if (sample.height > 0.f) sample.wavecapIntensity = u8(std::min(255, int(info.x38_wavecapIntensityScale * sample.height))); else sample.wavecapIntensity = 0; } } if (j != 0 && i != 0) { if ((flags[i][j] & 2) != 0 || (flags[i - 1][j] & 1) != 0 || (flags[i][j] & 4) != 0 || (flags[i][j - 1] & 8) != 0) { for (int l = r12; l < x3c; ++l) { CFluidPlaneRender::SHFieldSample& sample = heights[r9][l]; CFluidPlaneRender::SHFieldSample& up = heights[r9 + 1][l]; CFluidPlaneRender::SHFieldSample& down = heights[r9 - 1][l]; CFluidPlaneRender::SHFieldSample& right = heights[r9][l + 1]; CFluidPlaneRender::SHFieldSample& left = heights[r9][l - 1]; float nx = (right.height - left.height) * normalScale; float ny = (up.height - down.height) * normalScale; float normalizer = ny * ny + nx * nx + nz * nz; if (normalizer != 0.f) normalizer = std::sqrt(normalizer); normalizer = 63.f / normalizer; sample.nx = s8(nx * normalizer); sample.ny = s8(ny * normalizer); sample.nz = s8(nz * normalizer); if (sample.height > 0.f) sample.wavecapIntensity = u8(std::min(255, int(info.x38_wavecapIntensityScale * sample.height))); else sample.wavecapIntensity = 0; } for (int k = r9; k < x38; ++k) { CFluidPlaneRender::SHFieldSample& sample = heights[k][r12]; CFluidPlaneRender::SHFieldSample& up = heights[k + 1][r12]; CFluidPlaneRender::SHFieldSample& down = heights[k - 1][r12]; CFluidPlaneRender::SHFieldSample& right = heights[k][r12 + 1]; CFluidPlaneRender::SHFieldSample& left = heights[k][r12 - 1]; float nx = (right.height - left.height) * normalScale; float ny = (up.height - down.height) * normalScale; float normalizer = ny * ny + nx * nx + nz * nz; if (normalizer != 0.f) normalizer = std::sqrt(normalizer); normalizer = 63.f / normalizer; sample.nx = s8(nx * normalizer); sample.ny = s8(ny * normalizer); sample.nz = s8(nz * normalizer); if (sample.height > 0.f) sample.wavecapIntensity = u8(std::min(255, int(info.x38_wavecapIntensityScale * sample.height))); else sample.wavecapIntensity = 0; } } else { CFluidPlaneRender::SHFieldSample& sample = heights[r9][r12]; CFluidPlaneRender::SHFieldSample& up = heights[r9 + 1][r12]; CFluidPlaneRender::SHFieldSample& down = heights[r9 - 1][r12]; CFluidPlaneRender::SHFieldSample& right = heights[r9][r12 + 1]; CFluidPlaneRender::SHFieldSample& left = heights[r9][r12 - 1]; float nx = (right.height - left.height) * normalScale; float ny = (up.height - down.height) * normalScale; float normalizer = ny * ny + nx * nx + nz * nz; if (normalizer != 0.f) normalizer = std::sqrt(normalizer); normalizer = 63.f / normalizer; sample.nx = s8(nx * normalizer); sample.ny = s8(ny * normalizer); sample.nz = s8(nz * normalizer); if (sample.height > 0.f) sample.wavecapIntensity = u8(std::min(255, int(info.x38_wavecapIntensityScale * sample.height))); else sample.wavecapIntensity = 0; } } } } } } bool CFluidPlaneCPU::UpdatePatch(float time, const CFluidPlaneRender::SPatchInfo& info, Heights& heights, Flags& flags, const zeus::CVector3f& areaCenter, const std::optional& rippleManager, int fromX, int toX, int fromY, int toY) const { rstl::reserved_vector rippleInfos; if (rippleManager) { for (const CRipple& ripple : rippleManager->GetRipples()) { if (ripple.GetTime() >= ripple.GetTimeFalloff()) continue; CFluidPlaneRender::SRippleInfo rippleInfo(ripple, fromX, toX, fromY, toY); if (PrepareRipple(ripple, info, rippleInfo)) rippleInfos.push_back(rippleInfo); } } if (rippleInfos.empty()) return true; ApplyTurbulence(time, heights, flags, sGlobalSineWave, info, areaCenter); ApplyRipples(rippleInfos, heights, flags, sGlobalSineWave, info); /* No further action necessary if using tessellation shaders */ if (m_tessellation) return false; if (info.x37_normalMode == CFluidPlaneRender::NormalMode::NoNormals) UpdatePatchNoNormals(heights, flags, info); else UpdatePatchWithNormals(heights, flags, info); return false; } // Used to be part of locked cache // These are too big for stack allocation static CFluidPlane::Heights lc_heights{}; static CFluidPlane::Flags lc_flags{}; void CFluidPlaneCPU::Render(const CStateManager& mgr, float alpha, const zeus::CAABox& aabb, const zeus::CTransform& xf, const zeus::CTransform& areaXf, bool noNormals, const zeus::CFrustum& frustum, const std::optional& rippleManager, TUniqueId waterId, const bool* gridFlags, u32 gridDimX, u32 gridDimY, const zeus::CVector3f& areaCenter) { SCOPED_GRAPHICS_DEBUG_GROUP("CFluidPlaneCPU::Render", zeus::skCyan); TCastToConstPtr water = mgr.GetObjectById(waterId); CFluidPlaneShader::RenderSetupInfo setupInfo = RenderSetup(mgr, alpha, xf, areaXf, aabb, water.GetPtr()); // if (!m_shader->isReady()) // return; CFluidPlaneRender::NormalMode normalMode; if (xb0_bumpMap && kEnableWaterBumpMaps) normalMode = CFluidPlaneRender::NormalMode::NBT; else if (!noNormals) normalMode = CFluidPlaneRender::NormalMode::Normals; else normalMode = CFluidPlaneRender::NormalMode::NoNormals; // Set Position and color format switch (normalMode) { case CFluidPlaneRender::NormalMode::NBT: // Set NBT format break; case CFluidPlaneRender::NormalMode::Normals: // Set Normal format break; default: break; } float rippleResolutionRecip = 1.f / x108_rippleResolution; CFluidPlaneRender::numSubdivisionsInTile = x104_tileSubdivisions; CFluidPlaneRender::numTilesInHField = std::min(7, 42 / CFluidPlaneRender::numSubdivisionsInTile); CFluidPlaneRender::numSubdivisionsInHField = CFluidPlaneRender::numTilesInHField * CFluidPlaneRender::numSubdivisionsInTile; zeus::CVector2f ripplePitch(x108_rippleResolution * CFluidPlaneRender::numSubdivisionsInHField); // Amount to shift intensity values right (for added wavecap color) int redShift = 0; int greenShift = 0; int blueShift = 0; float wavecapIntensityScale = g_tweakGame->GetWavecapIntensityNormal(); switch (x44_fluidType) { case EFluidType::PoisonWater: wavecapIntensityScale = g_tweakGame->GetWavecapIntensityPoison(); redShift = 1; blueShift = 1; break; case EFluidType::Lava: case EFluidType::ThickLava: wavecapIntensityScale = g_tweakGame->GetWavecapIntensityLava(); blueShift = 8; greenShift = 8; break; default: break; } if (water) { float cameraPenetration = mgr.GetCameraManager()->GetCurrentCamera(mgr)->GetTranslation().dot(zeus::skUp) - water->GetTriggerBoundsWR().max.z(); wavecapIntensityScale *= (cameraPenetration >= 0.5f || cameraPenetration < 0.f) ? 1.f : 2.f * cameraPenetration; } u32 patchDimX = (water && water->GetPatchDimensionX()) ? water->GetPatchDimensionX() : 128; u32 patchDimY = (water && water->GetPatchDimensionY()) ? water->GetPatchDimensionY() : 128; m_verts.clear(); m_pVerts.clear(); if (m_tessellation) { /* Additional uniform data for tessellation evaluation shader */ zeus::CColor colorMul; colorMul.r() = wavecapIntensityScale / 255.f / float(1 << redShift); colorMul.g() = wavecapIntensityScale / 255.f / float(1 << greenShift); colorMul.b() = wavecapIntensityScale / 255.f / float(1 << blueShift); m_shader->prepareDraw(setupInfo, xf.origin, *rippleManager, colorMul, x108_rippleResolution / 4.f); } else { m_shader->prepareDraw(setupInfo); } u32 tileY = 0; float curY = aabb.min.y(); for (int i = 0; curY < aabb.max.y() && i < patchDimY; ++i) { u32 tileX = 0; float curX = aabb.min.x(); float _remDivsY = (aabb.max.y() - curY) * rippleResolutionRecip; for (int j = 0; curX < aabb.max.x() && j < patchDimX; ++j) { if (u8 renderFlags = water->GetPatchRenderFlags(j, i)) { s16 remDivsX = std::min(s16((aabb.max.x() - curX) * rippleResolutionRecip), s16(CFluidPlaneRender::numSubdivisionsInHField)); s16 remDivsY = std::min(s16(_remDivsY), s16(CFluidPlaneRender::numSubdivisionsInHField)); zeus::CVector3f localMax(x108_rippleResolution * remDivsX + curX, x108_rippleResolution * remDivsY + curY, aabb.max.z()); zeus::CVector3f localMin(curX, curY, aabb.min.z()); zeus::CAABox testaabb(localMin + xf.origin, localMax + xf.origin); if (frustum.aabbFrustumTest(testaabb)) { CFluidPlaneRender::SPatchInfo info(localMin, localMax, xf.origin, x108_rippleResolution, x100_tileSize, wavecapIntensityScale, CFluidPlaneRender::numSubdivisionsInHField, normalMode, redShift, greenShift, blueShift, tileX, gridDimX, gridDimY, tileY, gridFlags); int fromX = tileX != 0 ? (2 - CFluidPlaneRender::numSubdivisionsInTile) : 0; int toX; if (tileX != gridDimX - 1) toX = info.x0_xSubdivs + (CFluidPlaneRender::numSubdivisionsInTile - 2); else toX = info.x0_xSubdivs; int fromY = tileY != 0 ? (2 - CFluidPlaneRender::numSubdivisionsInTile) : 0; int toY; if (tileY != gridDimY - 1) toY = info.x1_ySubdivs + (CFluidPlaneRender::numSubdivisionsInTile - 2); else toY = info.x1_ySubdivs; bool noRipples = UpdatePatch(mgr.GetFluidPlaneManager()->GetUVT(), info, lc_heights, lc_flags, areaCenter, rippleManager, fromX, toX, fromY, toY); RenderPatch(info, lc_heights, lc_flags, noRipples, renderFlags == 1, m_verts, m_pVerts); } } curX += ripplePitch.x(); tileX += CFluidPlaneRender::numTilesInHField; } curY += ripplePitch.y(); tileY += CFluidPlaneRender::numTilesInHField; } m_shader->loadVerts(m_verts, m_pVerts); m_shader->doneDrawing(); } } // namespace metaforce