#include "Runtime/Graphics/CGraphics.hpp" #include "Runtime/CTimeProvider.hpp" #include "Runtime/Graphics/CLight.hpp" #include "Runtime/Graphics/CLineRenderer.hpp" #include "Runtime/Graphics/CTexture.hpp" #include "Runtime/Graphics/Shaders/CTextSupportShader.hpp" #include "Runtime/GuiSys/CGuiSys.hpp" #include "Runtime/Graphics/CGX.hpp" #include namespace metaforce { CGraphics::CProjectionState CGraphics::g_Proj; // CFogState CGraphics::g_Fog; float CGraphics::g_ProjAspect = 1.f; u32 CGraphics::g_NumBreakpointsWaiting = 0; u32 CGraphics::g_FlippingState; bool CGraphics::g_LastFrameUsedAbove = false; bool CGraphics::g_InterruptLastFrameUsedAbove = false; GX::LightMask CGraphics::g_LightActive{}; zeus::CTransform CGraphics::g_GXModelView; zeus::CTransform CGraphics::g_GXModelViewInvXpose; zeus::CTransform CGraphics::g_GXModelMatrix = zeus::CTransform(); zeus::CTransform CGraphics::g_ViewMatrix; zeus::CVector3f CGraphics::g_ViewPoint; zeus::CTransform CGraphics::g_GXViewPointMatrix; zeus::CTransform CGraphics::g_CameraMatrix; SClipScreenRect CGraphics::g_CroppedViewport; bool CGraphics::g_IsGXModelMatrixIdentity = true; zeus::CColor CGraphics::g_ClearColor = zeus::skClear; float CGraphics::g_ClearDepthValue = 1.f; bool CGraphics::g_IsBeginSceneClearFb = true; SViewport CGraphics::g_Viewport = { 0, 0, 640, 480, 640 / 2.f, 480 / 2.f, 0.0f, }; u32 CGraphics::g_FrameCounter = 0; u32 CGraphics::g_Framerate = 0; u32 CGraphics::g_FramesPast = 0; frame_clock::time_point CGraphics::g_FrameStartTime = frame_clock::now(); ERglEnum CGraphics::g_depthFunc = ERglEnum::Never; ERglCullMode CGraphics::g_cullMode = ERglCullMode::None; const std::array CGraphics::skCubeBasisMats{{ /* Right */ {0.f, 1.f, 0.f, 1.f, 0.f, 0.f, 0.f, 0.f, -1.f}, /* Left */ {0.f, -1.f, 0.f, -1.f, 0.f, 0.f, 0.f, 0.f, -1.f}, /* Up */ {1.f, 0.f, 0.f, 0.f, 0.f, -1.f, 0.f, 1.f, 0.f}, /* Down */ {1.f, 0.f, 0.f, 0.f, 0.f, 1.f, 0.f, -1.f, 0.f}, /* Back */ {1.f, 0.f, 0.f, 0.f, -1.f, 0.f, 0.f, 0.f, -1.f}, /* Forward */ {-1.f, 0.f, 0.f, 0.f, 1.f, 0.f, 0.f, 0.f, -1.f}, }}; // Stream API static EStreamFlags sStreamFlags; static GX::Primitive sStreamPrimitive; static u32 sVerticesCount; static zeus::CColor sQueuedColor; // Originally writes directly to GX FIFO struct StreamVertex { zeus::CColor color; zeus::CVector2f texCoord; zeus::CVector3f normal; zeus::CVector3f vertex; constexpr StreamVertex(const zeus::CColor& color) : color(color) {} constexpr StreamVertex(const StreamVertex&) = default; }; static std::vector sQueuedVertices; void CGraphics::DisableAllLights() { g_LightActive.reset(); CGX::SetChanCtrl(CGX::EChannelId::Channel0, {}); } void CGraphics::LoadLight(ERglLight light, const CLight& info) { const auto lightId = static_cast(1 << light); switch (info.GetType()) { case ELightType::LocalAmbient: aurora::gfx::load_light_ambient(lightId, info.GetColor()); break; case ELightType::Point: case ELightType::Spot: case ELightType::Custom: case ELightType::Directional: { aurora::gfx::Light lightOut{ .pos = CGraphics::g_CameraMatrix * info.GetPosition(), .dir = (CGraphics::g_CameraMatrix.basis * info.GetDirection()).normalized(), .color = info.GetColor(), .linAtt = {info.GetAttenuationConstant(), info.GetAttenuationLinear(), info.GetAttenuationQuadratic()}, .angAtt = {info.GetAngleAttenuationConstant(), info.GetAngleAttenuationLinear(), info.GetAngleAttenuationQuadratic()}, }; if (info.GetType() == ELightType::Directional) { lightOut.pos = (-lightOut.dir) * 1048576.f; } aurora::gfx::load_light(lightId, lightOut); break; } } } void CGraphics::EnableLight(ERglLight light) { CGX::SetNumChans(1); if (!g_LightActive.test(light)) { g_LightActive.set(light); CGX::SetChanCtrl(CGX::EChannelId::Channel0, g_LightActive); } } void CGraphics::SetLightState(GX::LightMask lightState) { g_LightActive = lightState; const bool hasLights = lightState.any(); CGX::SetChanCtrl(CGX::EChannelId::Channel0, hasLights, GX::SRC_REG, sStreamFlags & EStreamFlagBits::fHasColor ? GX::SRC_VTX : GX::SRC_REG, lightState, hasLights ? GX::DF_CLAMP : GX::DF_NONE, hasLights ? GX::AF_SPOT : GX::AF_NONE); } void CGraphics::SetAmbientColor(const zeus::CColor& col) { CGX::SetChanAmbColor(CGX::EChannelId::Channel0, col); CGX::SetChanAmbColor(CGX::EChannelId::Channel1, col); } void CGraphics::SetFog(ERglFogMode mode, float startz, float endz, const zeus::CColor& color) { CGX::SetFog(GX::FogType(mode), startz, endz, g_Proj.x14_near, g_Proj.x18_far, color); } void CGraphics::SetDepthWriteMode(bool compare_enable, ERglEnum comp, bool update_enable) { g_depthFunc = comp; CGX::SetZMode(compare_enable, GX::Compare(comp), update_enable); } void CGraphics::SetBlendMode(ERglBlendMode mode, ERglBlendFactor src, ERglBlendFactor dst, ERglLogicOp op) { CGX::SetBlendMode(GX::BlendMode(mode), GX::BlendFactor(src), GX::BlendFactor(dst), GX::LogicOp(op)); } void CGraphics::SetCullMode(ERglCullMode mode) { g_cullMode = mode; GXSetCullMode(GX::CullMode(mode)); } void CGraphics::BeginScene() { // ClearBackAndDepthBuffers(); } void CGraphics::EndScene() { CGX::SetZMode(true, GX::LEQUAL, true); /* Spinwait until g_NumBreakpointsWaiting is 0 */ /* ++g_NumBreakpointsWaiting; */ /* GXCopyDisp to g_CurrenFrameBuf with clear enabled */ /* Register next breakpoint with GP FIFO */ /* Yup, GX effectively had fences long before D3D12 and Vulkan * (same functionality implemented in boo's execute method) */ /* This usually comes from VI register during interrupt; * we don't care in the era of progressive-scan dominance, * so simulate field-flipping with XOR instead */ g_InterruptLastFrameUsedAbove ^= 1; g_LastFrameUsedAbove = g_InterruptLastFrameUsedAbove; /* Flush text instance buffers just before GPU command list submission */ CTextSupportShader::UpdateBuffers(); /* Same with line renderer */ // CLineRenderer::UpdateBuffers(); ++g_FrameCounter; UpdateFPSCounter(); } void CGraphics::Render2D(CTexture& tex, u32 x, u32 y, u32 w, u32 h, const zeus::CColor& col) { const auto oldProj = g_Proj; const auto oldCull = g_cullMode; const auto oldLights = g_LightActive; SetOrtho(-g_Viewport.x10_halfWidth, g_Viewport.x10_halfWidth, g_Viewport.x14_halfHeight, -g_Viewport.x14_halfHeight, -1.f, -10.f); GXLoadPosMtxImm({}, GX::PNMTX0); DisableAllLights(); SetCullMode(ERglCullMode::None); tex.Load(GX::TEXMAP0, EClampMode::Repeat); // float hPad, vPad; // if (CGraphics::GetViewportAspect() >= 1.78f) { // hPad = 1.78f / CGraphics::GetViewportAspect(); // vPad = 1.78f / 1.33f; // } else { // hPad = 1.f; // vPad = CGraphics::GetViewportAspect() / 1.33f; // } // TODO make this right float scaledX = static_cast(x) / 640.f * static_cast(g_Viewport.x8_width); float scaledY = static_cast(y) / 448.f * static_cast(g_Viewport.xc_height); float scaledW = static_cast(w) / 640.f * static_cast(g_Viewport.x8_width); float scaledH = static_cast(h) / 448.f * static_cast(g_Viewport.xc_height); float x1 = scaledX - g_Viewport.x10_halfWidth; float y1 = scaledY - g_Viewport.x14_halfHeight; float x2 = x1 + scaledW; float y2 = y1 + scaledH; StreamBegin(GX::TRIANGLESTRIP); StreamColor(col); StreamTexcoord(0.f, 0.f); StreamVertex(x1, y1, 1.f); StreamTexcoord(1.f, 0.f); StreamVertex(x2, y1, 1.f); StreamTexcoord(0.f, 1.f); StreamVertex(x1, y2, 1.f); StreamTexcoord(1.f, 1.f); StreamVertex(x2, y2, 1.f); StreamEnd(); SetLightState(g_LightActive); g_Proj = oldProj; FlushProjection(); SetModelMatrix({}); SetCullMode(oldCull); } bool CGraphics::BeginRender2D(const CTexture& tex) { return false; } void CGraphics::DoRender2D(const CTexture& tex, s32 x, s32 y, s32 w1, s32 w2, s32 w3, s32 w4, s32 w5, const zeus::CColor& col) {} void CGraphics::EndRender2D(bool v) {} void CGraphics::SetAlphaCompare(ERglAlphaFunc comp0, u8 ref0, ERglAlphaOp op, ERglAlphaFunc comp1, u8 ref1) { CGX::SetAlphaCompare(static_cast(comp0), ref0, static_cast(op), static_cast(comp1), ref1); } void CGraphics::SetViewPointMatrix(const zeus::CTransform& xf) { g_ViewMatrix = xf; g_ViewPoint = xf.origin; zeus::CMatrix3f tmp(xf.basis[0], xf.basis[2], -xf.basis[1]); g_GXViewPointMatrix = zeus::CTransform(tmp.transposed()); SetViewMatrix(); } void CGraphics::SetViewMatrix() { g_CameraMatrix = g_GXViewPointMatrix * zeus::CTransform::Translate(-g_ViewPoint); if (g_IsGXModelMatrixIdentity) g_GXModelView = g_CameraMatrix; else g_GXModelView = g_CameraMatrix * g_GXModelMatrix; /* Load position matrix */ GXLoadPosMtxImm(g_GXModelView, GX::PNMTX0); /* Inverse-transpose */ g_GXModelViewInvXpose = g_GXModelView.inverse(); g_GXModelViewInvXpose.basis.transpose(); /* Load normal matrix */ GXLoadNrmMtxImm(g_GXModelViewInvXpose, GX::PNMTX0); } void CGraphics::SetModelMatrix(const zeus::CTransform& xf) { g_IsGXModelMatrixIdentity = false; g_GXModelMatrix = xf; SetViewMatrix(); } constexpr zeus::CMatrix4f PlusOneZ(1.f, 0.f, 0.f, 0.f, 0.f, 1.f, 0.f, 0.f, 0.f, 0.f, 1.f, 1.f, 0.f, 0.f, 0.f, 1.f); constexpr zeus::CMatrix4f VulkanCorrect(1.f, 0.f, 0.f, 0.f, 0.f, -1.f, 0.f, 0.f, 0.f, 0.f, 0.5f, 0.5f + FLT_EPSILON, 0.f, 0.f, 0.f, 1.f); zeus::CMatrix4f CGraphics::CalculatePerspectiveMatrix(float fovy, float aspect, float znear, float zfar) { CProjectionState st; float tfov = std::tan(zeus::degToRad(fovy * 0.5f)); st.x14_near = znear; st.x18_far = zfar; st.xc_top = znear * tfov; st.x10_bottom = -st.xc_top; st.x8_right = aspect * znear * tfov; st.x4_left = -st.x8_right; float rml = st.x8_right - st.x4_left; float rpl = st.x8_right + st.x4_left; float tmb = st.xc_top - st.x10_bottom; float tpb = st.xc_top + st.x10_bottom; float fpn = st.x18_far + st.x14_near; float fmn = st.x18_far - st.x14_near; // clang-format off return { 2.f * st.x14_near / rml, 0.f, rpl / rml, 0.f, 0.f, 2.f * st.x14_near / tmb, tpb / tmb, 0.f, 0.f, 0.f, -fpn / fmn, -2.f * st.x18_far * st.x14_near / fmn, 0.f, 0.f, -1.f, 0.f, }; // clang-format on } zeus::CMatrix4f CGraphics::GetPerspectiveProjectionMatrix() { if (g_Proj.x0_persp) { float rml = g_Proj.x8_right - g_Proj.x4_left; float rpl = g_Proj.x8_right + g_Proj.x4_left; float tmb = g_Proj.xc_top - g_Proj.x10_bottom; float tpb = g_Proj.xc_top + g_Proj.x10_bottom; float fpn = g_Proj.x18_far + g_Proj.x14_near; float fmn = g_Proj.x18_far - g_Proj.x14_near; // clang-format off return { 2.f * g_Proj.x14_near / rml, 0.f, rpl / rml, 0.f, 0.f, 2.f * g_Proj.x14_near / tmb, tpb / tmb, 0.f, 0.f, 0.f, -fpn / fmn, -2.f * g_Proj.x18_far * g_Proj.x14_near / fmn, 0.f, 0.f, -1.f, 0.f, }; // clang-format on } else { float rml = g_Proj.x8_right - g_Proj.x4_left; float rpl = g_Proj.x8_right + g_Proj.x4_left; float tmb = g_Proj.xc_top - g_Proj.x10_bottom; float tpb = g_Proj.xc_top + g_Proj.x10_bottom; float fmn = g_Proj.x18_far - g_Proj.x14_near; // clang-format off return { 2.f / rml, 0.f, 0.f, -rpl / rml, 0.f, 2.f / tmb, 0.f, -tpb / tmb, 0.f, 0.f, -1.f / fmn, -g_Proj.x14_near / fmn, 0.f, 0.f, 0.f, 1.f }; // clang-format on } } const CGraphics::CProjectionState& CGraphics::GetProjectionState() { return g_Proj; } void CGraphics::SetProjectionState(const CGraphics::CProjectionState& proj) { g_Proj = proj; FlushProjection(); } void CGraphics::SetPerspective(float fovy, float aspect, float znear, float zfar) { g_ProjAspect = aspect; float tfov = std::tan(zeus::degToRad(fovy * 0.5f)); g_Proj.x0_persp = true; g_Proj.x14_near = znear; g_Proj.x18_far = zfar; g_Proj.xc_top = znear * tfov; g_Proj.x10_bottom = -g_Proj.xc_top; g_Proj.x8_right = aspect * znear * tfov; g_Proj.x4_left = -g_Proj.x8_right; FlushProjection(); } void CGraphics::SetOrtho(float left, float right, float top, float bottom, float znear, float zfar) { g_Proj.x0_persp = false; g_Proj.x4_left = left; g_Proj.x8_right = right; g_Proj.xc_top = top; g_Proj.x10_bottom = bottom; g_Proj.x14_near = znear; g_Proj.x18_far = zfar; FlushProjection(); } void CGraphics::FlushProjection() { const auto mtx = GetPerspectiveProjectionMatrix(); if (g_Proj.x0_persp) { // Convert and load persp GXSetProjection(mtx, GX::PERSPECTIVE); } else { // Convert and load ortho GXSetProjection(mtx, GX::ORTHOGRAPHIC); } } zeus::CVector2i CGraphics::ProjectPoint(const zeus::CVector3f& point) { zeus::CVector3f projPt = GetPerspectiveProjectionMatrix().multiplyOneOverW(point); return {int(projPt.x() * g_Viewport.x10_halfWidth) + int(g_Viewport.x10_halfWidth), int(g_Viewport.xc_height) - (int(projPt.y() * g_Viewport.x14_halfHeight) + int(g_Viewport.x14_halfHeight))}; } SClipScreenRect CGraphics::ClipScreenRectFromMS(const zeus::CVector3f& p1, const zeus::CVector3f& p2) { zeus::CVector3f xf1 = g_GXModelView * p1; zeus::CVector3f xf2 = g_GXModelView * p2; return ClipScreenRectFromVS(xf1, xf2); } SClipScreenRect CGraphics::ClipScreenRectFromVS(const zeus::CVector3f& p1, const zeus::CVector3f& p2) { if (p1.x() == 0.f && p1.y() == 0.f && p1.z() == 0.f) return {}; if (p2.x() == 0.f && p2.y() == 0.f && p2.z() == 0.f) return {}; if (-p1.z() < GetProjectionState().x14_near || -p2.z() < GetProjectionState().x14_near) return {}; if (-p1.z() > GetProjectionState().x18_far || -p2.z() > GetProjectionState().x18_far) return {}; zeus::CVector2i sp1 = ProjectPoint(p1); zeus::CVector2i sp2 = ProjectPoint(p2); int minX = std::min(sp2.x, sp1.x); int minX2 = minX & 0xfffffffe; int minY = std::min(sp2.y, sp1.y); int minY2 = minY & 0xfffffffe; if (minX2 >= g_Viewport.x8_width) return {}; int maxX = abs(sp1.x - sp2.x) + minX; int maxX2 = (maxX + 2) & 0xfffffffe; if (maxX2 <= 0 /* ViewportX origin */) return {}; // int finalMinX = std::max(minX, 0 /* ViewportX origin */); // int finalMaxX = std::min(maxX, int(g_Viewport.x8_width)); if (minY2 >= g_Viewport.xc_height) return {}; int maxY = abs(sp1.y - sp2.y) + minY; int maxY2 = (maxY + 2) & 0xfffffffe; if (maxY2 <= 0 /* ViewportY origin */) return {}; // int finalMinY = std::max(minY, 0 /* ViewportY origin */); // int finalMaxY = std::min(maxY, int(g_Viewport.xc_height)); int width = maxX2 - minX2; int height = maxY2 - minY2; return {true, minX2, minY2, width, height, width, minX2 / float(g_Viewport.x8_width), maxX2 / float(g_Viewport.x8_width), 1.f - maxY2 / float(g_Viewport.xc_height), 1.f - minY2 / float(g_Viewport.xc_height)}; } void CGraphics::SetViewportResolution(const zeus::CVector2i& res) { g_Viewport.x8_width = res.x; g_Viewport.xc_height = res.y; g_CroppedViewport = SClipScreenRect(); g_CroppedViewport.xc_width = res.x; g_CroppedViewport.x10_height = res.y; g_Viewport.x10_halfWidth = res.x / 2.f; g_Viewport.x14_halfHeight = res.y / 2.f; g_Viewport.aspect = res.x / float(res.y); if (g_GuiSys) g_GuiSys->OnViewportResize(); } static zeus::CRectangle CachedVP; zeus::CVector2f CGraphics::g_CachedDepthRange = {0.f, 1.f}; void CGraphics::SetViewport(int leftOff, int bottomOff, int width, int height) { CachedVP.position[0] = leftOff; CachedVP.position[1] = bottomOff; CachedVP.size[0] = width; CachedVP.size[1] = height; GXSetViewport(CachedVP.position[0], CachedVP.position[1], CachedVP.size[0], CachedVP.size[1], g_CachedDepthRange[0], g_CachedDepthRange[1]); } void CGraphics::SetScissor(int leftOff, int bottomOff, int width, int height) { GXSetScissor(leftOff, bottomOff, width, height); } void CGraphics::SetDepthRange(float znear, float zfar) { g_CachedDepthRange[0] = znear; g_CachedDepthRange[1] = zfar; GXSetViewport(CachedVP.position[0], CachedVP.position[1], CachedVP.size[0], CachedVP.size[1], g_CachedDepthRange[0], g_CachedDepthRange[1]); } CTimeProvider* CGraphics::g_ExternalTimeProvider = nullptr; float CGraphics::g_DefaultSeconds = 0.f; u32 CGraphics::g_RenderTimings = 0; float CGraphics::GetSecondsMod900() { if (!g_ExternalTimeProvider) return g_DefaultSeconds; return g_ExternalTimeProvider->x0_currentTime; } void CGraphics::TickRenderTimings() { OPTICK_EVENT(); g_RenderTimings = (g_RenderTimings + 1) % u32(900 * 60); g_DefaultSeconds = g_RenderTimings / 60.f; } static constexpr u64 FPS_REFRESH_RATE = 1000; void CGraphics::UpdateFPSCounter() { ++g_FramesPast; std::chrono::duration timeElapsed = frame_clock::now() - g_FrameStartTime; if (timeElapsed.count() > FPS_REFRESH_RATE) { g_Framerate = g_FramesPast; g_FrameStartTime = frame_clock::now(); g_FramesPast = 0; } } static bool g_UseVideoFilter = false; void CGraphics::SetUseVideoFilter(bool filter) { g_UseVideoFilter = filter; // GXSetCopyFilter(CGraphics::mRenderModeObj.aa, CGraphics::mRenderModeObj.sample_pattern, filter, // CGraphics::mRenderModeObj.vfilter); } void CGraphics::SetClearColor(const zeus::CColor& color) { g_ClearColor = color; GXSetCopyClear(color, g_ClearDepthValue); } void CGraphics::SetCopyClear(const zeus::CColor& color, float depth) { g_ClearColor = color; g_ClearDepthValue = depth; // 1.6777215E7 * depth; Metroid Prime needed this to convert float [0,1] depth into 24 bit // range, we no longer have this requirement GXSetCopyClear(g_ClearColor, g_ClearDepthValue); } void CGraphics::SetIsBeginSceneClearFb(bool clear) { g_IsBeginSceneClearFb = clear; } void CGraphics::SetTevOp(ERglTevStage stage, const CTevCombiners::CTevPass& pass) { CTevCombiners::SetupPass(stage, pass); } void CGraphics::StreamBegin(GX::Primitive primitive) { // Originally ResetVertexDataStream(true); sQueuedVertices.clear(); sQueuedVertices.emplace_back(sQueuedColor); sVerticesCount = 0; // End sStreamFlags = EStreamFlagBits::fHasColor; sStreamPrimitive = primitive; } void CGraphics::StreamNormal(const zeus::CVector3f& nrm) { sQueuedVertices.back().normal = nrm; sStreamFlags |= EStreamFlagBits::fHasNormal; } void CGraphics::StreamColor(const zeus::CColor& color) { if (sStreamFlags) { sQueuedVertices.back().color = color; } else { sQueuedColor = color; } sStreamFlags |= EStreamFlagBits::fHasColor; } void CGraphics::StreamTexcoord(const zeus::CVector2f& uv) { sQueuedVertices.back().texCoord = uv; sStreamFlags |= EStreamFlagBits::fHasTexture; } void CGraphics::StreamVertex(const zeus::CVector3f& pos) { sQueuedVertices.back().vertex = pos; UpdateVertexDataStream(); } void CGraphics::StreamEnd() { if (sVerticesCount != 0) { FlushStream(); } sStreamFlags = {}; } void CGraphics::UpdateVertexDataStream() { ++sVerticesCount; if (sVerticesCount == 240) { FlushStream(); ResetVertexDataStream(false); } else { sQueuedVertices.emplace_back(sQueuedVertices.back()); } } void CGraphics::FlushStream() { std::array vtxDescList{}; size_t idx = 0; vtxDescList[idx++] = {GX::VA_POS, GX::DIRECT}; if (sStreamFlags & EStreamFlagBits::fHasNormal) { vtxDescList[idx++] = {GX::VA_NRM, GX::DIRECT}; } if (sStreamFlags & EStreamFlagBits::fHasColor) { vtxDescList[idx++] = {GX::VA_CLR0, GX::DIRECT}; } if (sStreamFlags & EStreamFlagBits::fHasTexture) { vtxDescList[idx++] = {GX::VA_TEX0, GX::DIRECT}; } CGX::SetVtxDescv(vtxDescList.data()); SetTevStates(sStreamFlags); FullRender(); } void CGraphics::FullRender() { CGX::Begin(sStreamPrimitive, GX::VTXFMT0, sVerticesCount); for (size_t i = 0; i < sVerticesCount; ++i) { const auto& item = sQueuedVertices[i]; GXPosition3f32(item.vertex); if (sStreamFlags & EStreamFlagBits::fHasNormal) { GXNormal3f32(item.normal); } if (sStreamFlags & EStreamFlagBits::fHasColor) { GXColor4f32(item.color); } if (sStreamFlags & EStreamFlagBits::fHasTexture) { GXTexCoord2f32(item.texCoord); } } CGX::End(); } void CGraphics::ResetVertexDataStream(bool end) { if (end) { sQueuedVertices.clear(); } else { const auto lastVertex = sQueuedVertices.back(); sQueuedVertices.clear(); sQueuedVertices.emplace_back(lastVertex); } sVerticesCount = 0; if (!end) { // TODO something with triangle fans } } void CGraphics::DrawPrimitive(GX::Primitive primitive, const zeus::CVector3f* pos, const zeus::CVector3f& normal, const zeus::CColor& col, s32 numVerts) { StreamBegin(primitive); StreamColor(col); StreamNormal(normal); for (u32 i = 0; i < numVerts; ++i) { StreamVertex(pos[i]); } StreamEnd(); } void CGraphics::SetTevStates(EStreamFlags flags) noexcept { if (flags & EStreamFlagBits::fHasTexture) { CGX::SetNumTexGens(1); // sTextureUsed & 3? CGX::SetTevOrder(GX::TEVSTAGE0, GX::TEXCOORD0, GX::TEXMAP0, GX::COLOR0A0); CGX::SetTevOrder(GX::TEVSTAGE1, GX::TEXCOORD1, GX::TEXMAP1, GX::COLOR0A0); } else { CGX::SetNumTexGens(0); CGX::SetNumTevStages(1); CGX::SetTevOrder(GX::TEVSTAGE0, GX::TEXCOORD_NULL, GX::TEXMAP_NULL, GX::COLOR0A0); CGX::SetTevOrder(GX::TEVSTAGE1, GX::TEXCOORD_NULL, GX::TEXMAP_NULL, GX::COLOR0A0); } CGX::SetNumChans(1); CGX::SetNumIndStages(0); CGX::SetTexCoordGen(GX::TEXCOORD0, GX::TG_MTX2x4, GX::TG_TEX0, GX::IDENTITY, false, GX::PTIDENTITY); CGX::SetTexCoordGen(GX::TEXCOORD1, GX::TG_MTX2x4, GX::TG_TEX1, GX::IDENTITY, false, GX::PTIDENTITY); const bool hasLights = g_LightActive.any(); CGX::SetChanCtrl(CGX::EChannelId::Channel0, hasLights, GX::SRC_REG, flags & EStreamFlagBits::fHasColor ? GX::SRC_VTX : GX::SRC_REG, g_LightActive, hasLights ? GX::DF_CLAMP : GX::DF_NONE, hasLights ? GX::AF_SPOT : GX::AF_NONE); CGX::FlushState(); // normally would be handled in FullRender TODO } void CGraphics::Startup() { // Setup GXFifo CGX::ResetGXStates(); InitGraphicsVariables(); // ConfigureFrameBuffer(...); InitGraphicsDefaults(); // GXInitTexCacheRegion // GXSetTexRegionCallback } void CGraphics::InitGraphicsVariables() { // g_lightTypes[0..n] = Directional; g_LightActive = {}; SetDepthWriteMode(false, g_depthFunc, false); SetCullMode(ERglCullMode::None); SetAmbientColor(zeus::CColor{0.2f, 1.f}); g_IsGXModelMatrixIdentity = false; // SetIdentityViewPointMatrix(); // SetIdentityModelMatrix(); // SetViewport(...); // SetPerspective(...); SetCopyClear(g_ClearColor, 1.f); CGX::SetChanMatColor(CGX::EChannelId::Channel0, zeus::skWhite); // g_RenderState.ResetFlushAll(); } void CGraphics::InitGraphicsDefaults() { SetDepthRange(0.f, 1.f); g_IsGXModelMatrixIdentity = false; SetModelMatrix(g_GXModelMatrix); SetViewPointMatrix(g_GXModelView); SetDepthWriteMode(false, g_depthFunc, false); SetCullMode(g_cullMode); SetViewport(g_Viewport.x0_left, g_Viewport.x4_top, g_Viewport.x8_width, g_Viewport.xc_height); FlushProjection(); CTevCombiners::Init(); DisableAllLights(); SetDefaultVtxAttrFmt(); } void CGraphics::SetDefaultVtxAttrFmt() { // Unneeded, all attributes are expected to be full floats // Left here for reference // GXSetVtxAttrFmt(GX::VTXFMT0, GX::VA_POS, GX::POS_XYZ, GX::F32, 0); // GXSetVtxAttrFmt(GX::VTXFMT1, GX::VA_POS, GX::POS_XYZ, GX::F32, 0); // GXSetVtxAttrFmt(GX::VTXFMT2, GX::VA_POS, GX::POS_XYZ, GX::F32, 0); // GXSetVtxAttrFmt(GX::VTXFMT0, GX::VA_NRM, GX::NRM_XYZ, GX::F32, 0); // GXSetVtxAttrFmt(GX::VTXFMT1, GX::VA_NRM, GX::NRM_XYZ, GX::S16, 14); // GXSetVtxAttrFmt(GX::VTXFMT2, GX::VA_NRM, GX::NRM_XYZ, GX::S16, 14); // GXSetVtxAttrFmt(GX::VTXFMT0, GX::VA_CLR0, GX::CLR_RGBA, GX::RGBA8, 0); // GXSetVtxAttrFmt(GX::VTXFMT1, GX::VA_CLR0, GX::CLR_RGBA, GX::RGBA8, 0); // GXSetVtxAttrFmt(GX::VTXFMT2, GX::VA_CLR0, GX::CLR_RGBA, GX::RGBA8, 0); // GXSetVtxAttrFmt(GX::VTXFMT0, GX::VA_TEX0, GX::TEX_ST, GX::F32, 0); // GXSetVtxAttrFmt(GX::VTXFMT1, GX::VA_TEX0, GX::TEX_ST, GX::F32, 0); // GXSetVtxAttrFmt(GX::VTXFMT2, GX::VA_TEX0, GX::TEX_ST, GX::U16, 15); // for (GX::Attr attr = GX::VA_TEX1; attr <= GX::VA_TEX7; attr = GX::Attr(attr + 1)) { // GXSetVtxAttrFmt(GX::VTXFMT0, attr, GX::TEX_ST, GX::F32, 0); // GXSetVtxAttrFmt(GX::VTXFMT1, attr, GX::TEX_ST, GX::F32, 0); // GXSetVtxAttrFmt(GX::VTXFMT2, attr, GX::TEX_ST, GX::F32, 0); // } } } // namespace metaforce