#include "Runtime/Graphics/CRainSplashGenerator.hpp" #include "Runtime/CStateManager.hpp" #include "Runtime/GameGlobalObjects.hpp" #include "Runtime/Graphics/CBooRenderer.hpp" #include "Runtime/World/CWorld.hpp" namespace urde { CRainSplashGenerator::CRainSplashGenerator(const zeus::CVector3f& scale, u32 maxSplashes, u32 genRate, float minZ, float alpha) : x14_scale(scale), x2c_minZ(minZ) { x30_alpha = std::min(1.f, alpha); x44_genRate = std::min(maxSplashes, genRate); x48_24 = false; x48_25_raining = true; x0_rainSplashes.reserve(maxSplashes); CGraphics::CommitResources([&](boo::IGraphicsDataFactory::Context& ctx) { for (u32 i = 0; i < maxSplashes; ++i) x0_rainSplashes.emplace_back(ctx); return true; } BooTrace); } void CRainSplashGenerator::SSplashLine::Draw(float alpha, float dt, const zeus::CVector3f& pos) const { if (x0_t > 0.f) { float delta = dt * xc_speed; float vt = std::max(0.f, x0_t - delta * x15_length); auto vertCount = u32((x0_t - vt) / delta + 1.f); m_renderer.Reset(); for (u32 i = 0; i < vertCount; ++i) { float vertAlpha = vt * alpha; zeus::CVector3f vec(vt * x4_xEnd, vt * x8_yEnd, -4.f * vt * (vt - 1.f) * x10_zParabolaHeight); vec += pos; vt += delta; m_renderer.AddVertex(vec, zeus::CColor(1.f, vertAlpha), 1); } m_renderer.Render(g_Renderer->IsThermalVisorHotPass()); } } void CRainSplashGenerator::SRainSplash::Draw(float alpha, float dt, const zeus::CVector3f& pos) const { for (const SSplashLine& line : x0_lines) line.Draw(alpha, dt, pos); } void CRainSplashGenerator::DoDraw(const zeus::CTransform& xf) const { SCOPED_GRAPHICS_DEBUG_GROUP("CRainSplashGenerator::DoDraw", zeus::skYellow); CGraphics::SetModelMatrix(xf); if (x40_queueSize > 0) { if (x38_queueTail <= x3c_queueHead) { for (size_t i = x3c_queueHead; i < x0_rainSplashes.size(); ++i) { const SRainSplash& splash = x0_rainSplashes[i]; splash.Draw(x30_alpha, x28_dt, splash.x64_pos); } for (size_t i = 0; i < x38_queueTail; ++i) { const SRainSplash& splash = x0_rainSplashes[i]; splash.Draw(x30_alpha, x28_dt, splash.x64_pos); } } else { for (size_t i = x3c_queueHead; i < x38_queueTail; ++i) { const SRainSplash& splash = x0_rainSplashes[i]; splash.Draw(x30_alpha, x28_dt, splash.x64_pos); } } } } void CRainSplashGenerator::Draw(const zeus::CTransform& xf) const { if (x48_25_raining) DoDraw(xf); } CRainSplashGenerator::SSplashLine::SSplashLine(boo::IGraphicsDataFactory::Context& ctx) : m_renderer(ctx, CLineRenderer::EPrimitiveMode::LineStrip, 3, nullptr, false) {} CRainSplashGenerator::SRainSplash::SRainSplash(boo::IGraphicsDataFactory::Context& ctx) { for (int i = 0; i < 4; ++i) x0_lines.emplace_back(ctx); } void CRainSplashGenerator::SSplashLine::Update(float dt, CStateManager& mgr) { if (!x16_active) return; if (x0_t <= 0.8f) { x14_ = u8(5.f * (1.f - x0_t) + 3.f * x0_t); x0_t += dt * xc_speed; } else if (x15_length != 0) { x15_length -= 1; } else { x16_active = false; xc_speed = mgr.GetActiveRandom()->Range(0.015625f, 8.f); x10_zParabolaHeight = mgr.GetActiveRandom()->Range(0.015625f, 0.03125f); x4_xEnd = mgr.GetActiveRandom()->Range(-0.125f, 0.125f); x8_yEnd = mgr.GetActiveRandom()->Range(-0.125f, 0.125f); x15_length = u8(mgr.GetActiveRandom()->Range(1, 2)); } } void CRainSplashGenerator::SRainSplash::Update(float dt, CStateManager& mgr) { for (SSplashLine& point : x0_lines) point.Update(dt, mgr); } bool CRainSplashGenerator::SRainSplash::IsActive() const { bool ret = false; for (const SSplashLine& line : x0_lines) ret |= line.x16_active; return ret; } void CRainSplashGenerator::UpdateRainSplashRange(CStateManager& mgr, int start, int end, float dt) { for (int i = start; i < end; ++i) { SRainSplash& set = x0_rainSplashes[i]; set.Update(dt, mgr); if (!set.IsActive()) { x40_queueSize -= 1; x3c_queueHead += 1; if (x3c_queueHead >= x0_rainSplashes.size()) x3c_queueHead = 0; } } } void CRainSplashGenerator::UpdateRainSplashes(CStateManager& mgr, float magnitude, float dt) { x20_generateTimer += dt; x24_generateInterval = 1.f / (70.f * magnitude); if (x40_queueSize > 0) { if (x38_queueTail <= x3c_queueHead) { UpdateRainSplashRange(mgr, x3c_queueHead, int(x0_rainSplashes.size()), dt); UpdateRainSplashRange(mgr, 0, x38_queueTail, dt); } else { UpdateRainSplashRange(mgr, x3c_queueHead, x38_queueTail, dt); } } } void CRainSplashGenerator::Update(float dt, CStateManager& mgr) { EEnvFxType neededFx = mgr.GetWorld()->GetNeededEnvFx(); x28_dt = dt; x48_25_raining = false; if (neededFx != EEnvFxType::None && mgr.GetEnvFxManager()->IsSplashActive() && mgr.GetEnvFxManager()->GetRainMagnitude() != 0.f && neededFx == EEnvFxType::Rain) { UpdateRainSplashes(mgr, mgr.GetEnvFxManager()->GetRainMagnitude(), dt); x48_25_raining = true; } } u32 CRainSplashGenerator::GetNextBestPt(u32 pt, const std::vector>& vn, CRandom16& rand, float minZ) { auto& refVert = vn[pt]; float maxDist = 0.f; u32 nextPt = pt; for (int i = 0; i < 3; ++i) { auto idx = u32(rand.Range(0, int(vn.size() - 1))); auto& vert = vn[idx]; float distSq = (refVert.first - vert.first).magSquared(); if (distSq > maxDist && vert.second.dot(zeus::skUp) >= 0.f && (vert.first.z() <= 0.f || vert.first.z() > minZ)) { nextPt = idx; maxDist = distSq; } } return nextPt; } void CRainSplashGenerator::SRainSplash::SetPoint(const zeus::CVector3f& pos) { for (SSplashLine& line : x0_lines) line.SetActive(); x64_pos = pos; } void CRainSplashGenerator::AddPoint(const zeus::CVector3f& pos) { if (x38_queueTail >= x0_rainSplashes.size()) x38_queueTail = 0; x0_rainSplashes[x38_queueTail].SetPoint(pos); x40_queueSize += 1; x38_queueTail += 1; } void CRainSplashGenerator::GeneratePoints(const std::vector>& vn) { if (!x48_25_raining) return; if (x20_generateTimer > x24_generateInterval) { for (u32 i = 0; i < x44_genRate; ++i) { if (x40_queueSize >= x0_rainSplashes.size()) break; x34_curPoint = GetNextBestPt(x34_curPoint, vn, x10_random, x2c_minZ); AddPoint(x14_scale * vn[x34_curPoint].first); } x20_generateTimer = 0.f; } } } // namespace urde