#include "trail.hpp" #include #include #include "globals.hpp" void CTrail::onTick() { static auto* const PHISTORYSTEP = (Hyprlang::INT* const*)HyprlandAPI::getConfigValue(PHANDLE, "plugin:hyprtrails:history_step")->getDataStaticPtr(); static auto* const PHISTORYPOINTS = (Hyprlang::INT* const*)HyprlandAPI::getConfigValue(PHANDLE, "plugin:hyprtrails:history_points")->getDataStaticPtr(); m_iTimer++; const auto PWINDOW = m_pWindow.lock(); if (m_iTimer > **PHISTORYSTEP) { m_dLastGeoms.push_front({box{(float)PWINDOW->m_vRealPosition.value().x, (float)PWINDOW->m_vRealPosition.value().y, (float)PWINDOW->m_vRealSize.value().x, (float)PWINDOW->m_vRealSize.value().y}, std::chrono::system_clock::now()}); while (m_dLastGeoms.size() > **PHISTORYPOINTS) m_dLastGeoms.pop_back(); m_iTimer = 0; } if (m_bNeedsDamage) { g_pHyprRenderer->damageBox(&m_bLastBox); m_bNeedsDamage = false; } } CTrail::CTrail(PHLWINDOW pWindow) : IHyprWindowDecoration(pWindow), m_pWindow(pWindow) { m_vLastWindowPos = pWindow->m_vRealPosition.value(); m_vLastWindowSize = pWindow->m_vRealSize.value(); pTickCb = HyprlandAPI::registerCallbackDynamic(PHANDLE, "trailTick", [this](void* self, SCallbackInfo& info, std::any data) { this->onTick(); }); } CTrail::~CTrail() { damageEntire(); HyprlandAPI::unregisterCallback(PHANDLE, pTickCb); } SDecorationPositioningInfo CTrail::getPositioningInfo() { return {DECORATION_POSITION_ABSOLUTE}; } void CTrail::onPositioningReply(const SDecorationPositioningReply& reply) { ; // ignored } void scaleBox2(box& box, float coeff) { float hwl = (box.w - (box.w * coeff)) / 2.0; float hhl = (box.h - (box.h * coeff)) / 2.0; box.w *= coeff; box.h *= coeff; box.x += hwl; box.y += hhl; } Vector2D vecForT(const Vector2D& a, const Vector2D& b, const float& t) { const Vector2D vec_PQ = b - a; return Vector2D{a + vec_PQ * t}; } Vector2D vecForBezierT(const float& t, const std::vector& verts) { std::vector pts; for (size_t vertexIndex = 0; vertexIndex < verts.size() - 1; vertexIndex++) { Vector2D p = verts[vertexIndex]; pts.push_back(vecForT(p, verts[vertexIndex + 1], t)); } if (pts.size() > 1) return vecForBezierT(t, pts); else return pts[0]; } void CTrail::draw(PHLMONITOR pMonitor, const float &a) { if (!validMapped(m_pWindow)) return; const auto PWINDOW = m_pWindow.lock(); if (!PWINDOW->m_sWindowData.decorate.valueOrDefault()) return; static auto* const PBEZIERSTEP = (Hyprlang::FLOAT* const*)HyprlandAPI::getConfigValue(PHANDLE, "plugin:hyprtrails:bezier_step")->getDataStaticPtr(); static auto* const PPOINTSPERSTEP = (Hyprlang::INT* const*)HyprlandAPI::getConfigValue(PHANDLE, "plugin:hyprtrails:points_per_step")->getDataStaticPtr(); static auto* const PCOLOR = (Hyprlang::INT* const*)HyprlandAPI::getConfigValue(PHANDLE, "plugin:hyprtrails:color")->getDataStaticPtr(); const CColor COLOR = **PCOLOR; if (m_dLastGeoms.size() < 2) return; box thisbox = box{(float)PWINDOW->m_vRealPosition.value().x, (float)PWINDOW->m_vRealPosition.value().y, (float)PWINDOW->m_vRealSize.value().x, (float)PWINDOW->m_vRealSize.value().y}; CBox wlrbox = {thisbox.x - pMonitor->vecPosition.x, thisbox.y - pMonitor->vecPosition.y, thisbox.w, thisbox.h}; wlrbox.scale(pMonitor->scale).round(); g_pHyprOpenGL->scissor((CBox*)nullptr); // allow the entire window and stencil to render glClearStencil(0); glClear(GL_STENCIL_BUFFER_BIT); glEnable(GL_STENCIL_TEST); glStencilFunc(GL_ALWAYS, 1, -1); glStencilOp(GL_KEEP, GL_KEEP, GL_REPLACE); glColorMask(GL_FALSE, GL_FALSE, GL_FALSE, GL_FALSE); g_pHyprOpenGL->renderRect(&wlrbox, CColor(0, 0, 0, 0), PWINDOW->rounding() * pMonitor->scale); glColorMask(GL_TRUE, GL_TRUE, GL_TRUE, GL_TRUE); glStencilFunc(GL_NOTEQUAL, 1, -1); glStencilOp(GL_KEEP, GL_KEEP, GL_REPLACE); CBox monbox = {0, 0, g_pHyprOpenGL->m_RenderData.pMonitor->vecTransformedSize.x, g_pHyprOpenGL->m_RenderData.pMonitor->vecTransformedSize.y}; Mat3x3 matrix = g_pHyprOpenGL->m_RenderData.monitorProjection.projectBox(monbox, wlTransformToHyprutils(invertTransform(WL_OUTPUT_TRANSFORM_NORMAL)), monbox.rot); Mat3x3 glMatrix = g_pHyprOpenGL->m_RenderData.projection.copy().multiply(matrix); g_pHyprOpenGL->blend(true); glUseProgram(g_pGlobalState->trailShader.program); #ifndef GLES2 glUniformMatrix3fv(g_pGlobalState->trailShader.proj, 1, GL_TRUE, glMatrix.getMatrix().data()); #else glMatrix.transpose(); glUniformMatrix3fv(g_pGlobalState->trailShader.proj, 1, GL_FALSE, glMatrix.getMatrix().data()); #endif std::vector points; std::vector bezierPts; std::vector pointsForBezier; std::vector agesForBezier; float originalCoeff = 50; auto msFrom = [](std::chrono::system_clock::time_point t) -> float { return std::chrono::duration_cast(std::chrono::system_clock::now() - t).count() / 1000.0; }; auto dist = [&](const point2& a, const point2& b) -> float { Vector2D diff = Vector2D{a.x - b.x, a.y - b.y} * pMonitor->vecSize; return std::sqrt(diff.x * diff.x + diff.y * diff.y); }; float msMaxToLast = msFrom(m_dLastGeoms.back().second); float dists[2] = {0, 0}; Vector2D mainVec = {originalCoeff / pMonitor->vecSize.x, originalCoeff / pMonitor->vecSize.y}; Vector2D windowMiddle = PWINDOW->middle() - pMonitor->vecPosition; points.push_back( Vector2D{cos(0) * mainVec.x - sin(0) * mainVec.y + windowMiddle.x / pMonitor->vecSize.x, sin(0) * mainVec.x + cos(0) * mainVec.y + windowMiddle.y / pMonitor->vecSize.y}); points.push_back(Vector2D{cos(-M_PI_2) * mainVec.x - sin(-M_PI_2) * mainVec.y + windowMiddle.x / pMonitor->vecSize.x, sin(-M_PI_2) * mainVec.x + cos(-M_PI_2) * mainVec.y + windowMiddle.y / pMonitor->vecSize.y}); points.push_back(Vector2D{cos(M_PI_2) * mainVec.x - sin(M_PI_2) * mainVec.y + windowMiddle.x / pMonitor->vecSize.x, sin(M_PI_2) * mainVec.x + cos(M_PI_2) * mainVec.y + windowMiddle.y / pMonitor->vecSize.y}); points.push_back(Vector2D{cos(M_PI) * mainVec.x - sin(M_PI) * mainVec.y + windowMiddle.x / pMonitor->vecSize.x, sin(M_PI) * mainVec.x + cos(M_PI) * mainVec.y + windowMiddle.y / pMonitor->vecSize.y}); pointsForBezier.push_back(windowMiddle); agesForBezier.push_back(0); for (size_t i = 0; i < m_dLastGeoms.size(); i += 1) { box box = m_dLastGeoms[i].first; box.x -= pMonitor->vecPosition.x; box.y -= pMonitor->vecPosition.y; Vector2D middle = {box.x + box.w / 2.0, box.y + box.h / 2.0}; if (middle == pointsForBezier[pointsForBezier.size() - 1]) continue; pointsForBezier.push_back(middle); agesForBezier.push_back(msFrom(m_dLastGeoms[i].second)); } if (pointsForBezier.size() < 3) { glClearStencil(0); glClear(GL_STENCIL_BUFFER_BIT); glDisable(GL_STENCIL_TEST); glStencilMask(-1); glStencilFunc(GL_ALWAYS, 1, 0xFF); g_pHyprOpenGL->scissor((CBox*)nullptr); return; } float maxAge = agesForBezier.back(); float tCoeff = **PBEZIERSTEP; int pointsPerBezier = **PPOINTSPERSTEP; bezierPts.push_back(vecForBezierT(0, pointsForBezier)); for (float t = tCoeff; t <= 1.0; t += tCoeff) { bezierPts.push_back(vecForBezierT(t, pointsForBezier)); const Vector2D& lastbezier = bezierPts.back(); const Vector2D& lastprevbezier = bezierPts[bezierPts.size() - 2]; for (size_t i = 1; i < pointsPerBezier + 1; ++i) { const float bezierPointStep = (1.0 / (pointsPerBezier + 2)); const Vector2D& middle = vecForT(lastprevbezier, lastbezier, bezierPointStep * (i + 1)); const Vector2D& lastmiddle = vecForT(lastprevbezier, lastbezier, bezierPointStep * i); Vector2D vecNormal = {middle.x - lastmiddle.x, middle.y - lastmiddle.y}; // normalize vec float invlen = 1.0 / std::sqrt(vecNormal.x * vecNormal.x + vecNormal.y * vecNormal.y); vecNormal.x *= invlen; vecNormal.y *= invlen; // make sure it points up // vecNormal.y = std::abs(vecNormal.y); // extend by coeff float ageCoeff = t * (agesForBezier.size() - 1); float ageFloor = std::floor(ageCoeff); float ageCeil = std::ceil(ageCoeff); float approxAge = agesForBezier[static_cast(ageFloor)] + (agesForBezier[static_cast(ageCeil)] - agesForBezier[static_cast(ageFloor)]) * (ageCoeff - ageFloor); float coeff = originalCoeff * (1.0 - (approxAge / maxAge)); Vector2D newVec = {vecNormal.x * coeff / pMonitor->vecSize.x, vecNormal.y * coeff / pMonitor->vecSize.y}; if ((newVec.x == 0 && newVec.y == 0) || std::isnan(newVec.x) || std::isnan(newVec.y)) continue; // rotate by 90 and -90 and add middle points.push_back(Vector2D{cos(M_PI_2) * newVec.x - sin(M_PI_2) * newVec.y + middle.x / pMonitor->vecSize.x, sin(M_PI_2) * newVec.x + cos(M_PI_2) * newVec.y + middle.y / pMonitor->vecSize.y}); points.push_back(Vector2D{cos(-M_PI_2) * newVec.x - sin(-M_PI_2) * newVec.y + middle.x / pMonitor->vecSize.x, sin(-M_PI_2) * newVec.x + cos(-M_PI_2) * newVec.y + middle.y / pMonitor->vecSize.y}); } } box thisboxopengl = box{(PWINDOW->m_vRealPosition.value().x - pMonitor->vecPosition.x) / pMonitor->vecSize.x, (PWINDOW->m_vRealPosition.value().y - pMonitor->vecPosition.y) / pMonitor->vecSize.y, (PWINDOW->m_vRealPosition.value().x + PWINDOW->m_vRealSize.value().x) / pMonitor->vecSize.x, (PWINDOW->m_vRealPosition.value().y + PWINDOW->m_vRealSize.value().y) / pMonitor->vecSize.y}; glUniform4f(g_pGlobalState->trailShader.gradient, thisboxopengl.x, thisboxopengl.y, thisboxopengl.w, thisboxopengl.h); glUniform4f(g_pGlobalState->trailShader.color, COLOR.r, COLOR.g, COLOR.b, COLOR.a); CBox transformedBox = monbox; transformedBox.transform(wlTransformToHyprutils(invertTransform(g_pHyprOpenGL->m_RenderData.pMonitor->transform)), g_pHyprOpenGL->m_RenderData.pMonitor->vecTransformedSize.x, g_pHyprOpenGL->m_RenderData.pMonitor->vecTransformedSize.y); glVertexAttribPointer(g_pGlobalState->trailShader.posAttrib, 2, GL_FLOAT, GL_FALSE, 0, (float*)points.data()); glEnableVertexAttribArray(g_pGlobalState->trailShader.posAttrib); if (g_pHyprOpenGL->m_RenderData.clipBox.width != 0 && g_pHyprOpenGL->m_RenderData.clipBox.height != 0) { CRegion damageClip{g_pHyprOpenGL->m_RenderData.clipBox.x, g_pHyprOpenGL->m_RenderData.clipBox.y, g_pHyprOpenGL->m_RenderData.clipBox.width, g_pHyprOpenGL->m_RenderData.clipBox.height}; damageClip.intersect(g_pHyprOpenGL->m_RenderData.damage); if (!damageClip.empty()) { for (auto& RECT : damageClip.getRects()) { g_pHyprOpenGL->scissor(&RECT); glDrawArrays(GL_TRIANGLE_STRIP, 0, points.size()); } } } else { for (auto& RECT : g_pHyprOpenGL->m_RenderData.damage.getRects()) { g_pHyprOpenGL->scissor(&RECT); glDrawArrays(GL_TRIANGLE_STRIP, 0, points.size()); } } glDisableVertexAttribArray(g_pGlobalState->trailShader.posAttrib); glClearStencil(0); glClear(GL_STENCIL_BUFFER_BIT); glDisable(GL_STENCIL_TEST); glStencilMask(-1); glStencilFunc(GL_ALWAYS, 1, 0xFF); g_pHyprOpenGL->scissor((CBox*)nullptr); // calculate damage float minX = 9999999; float minY = 9999999; float maxX = -9999999; float maxY = -9999999; for (auto& p : points) { if (p.x < minX) minX = p.x; if (p.y < minY) minY = p.y; if (p.x > maxX) maxX = p.x; if (p.y > maxY) maxY = p.y; } // bring back to global coords minX *= pMonitor->vecSize.x; minY *= pMonitor->vecSize.y; maxX *= pMonitor->vecSize.x; maxY *= pMonitor->vecSize.y; m_bLastBox.x = minX + pMonitor->vecPosition.x; m_bLastBox.y = minY + pMonitor->vecPosition.y; m_bLastBox.width = maxX - minX; m_bLastBox.height = maxY - minY; m_bNeedsDamage = true; } eDecorationType CTrail::getDecorationType() { return DECORATION_CUSTOM; } void CTrail::updateWindow(PHLWINDOW pWindow) { const auto PWORKSPACE = pWindow->m_pWorkspace; const auto WORKSPACEOFFSET = PWORKSPACE && !pWindow->m_bPinned ? PWORKSPACE->m_vRenderOffset.value() : Vector2D(); m_vLastWindowPos = pWindow->m_vRealPosition.value() + WORKSPACEOFFSET; m_vLastWindowSize = pWindow->m_vRealSize.value(); damageEntire(); } void CTrail::damageEntire() { CBox dm = {(int)(m_vLastWindowPos.x - m_seExtents.topLeft.x), (int)(m_vLastWindowPos.y - m_seExtents.topLeft.y), (int)(m_vLastWindowSize.x + m_seExtents.topLeft.x + m_seExtents.bottomRight.x), (int)m_seExtents.topLeft.y}; g_pHyprRenderer->damageBox(&dm); }