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hyprland/src/helpers/Monitor.cpp
Lee Bousfield 279b06044c
screencopy, render: Use explicit sync for screencopy (#9697) 
* screencopy, render: Use explicit sync for screencopy

* screencopy: Check if explicit sync is enabled

* screencopy: Don't require explicit KMS enabled
2025-03-22 17:01:14 +01:00

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#include "Monitor.hpp"
#include "MiscFunctions.hpp"
#include "../macros.hpp"
#include "math/Math.hpp"
#include "../protocols/ColorManagement.hpp"
#include "sync/SyncReleaser.hpp"
#include "../Compositor.hpp"
#include "../config/ConfigValue.hpp"
#include "../protocols/GammaControl.hpp"
#include "../devices/ITouch.hpp"
#include "../protocols/LayerShell.hpp"
#include "../protocols/PresentationTime.hpp"
#include "../protocols/DRMLease.hpp"
#include "../protocols/DRMSyncobj.hpp"
#include "../protocols/core/Output.hpp"
#include "../protocols/Screencopy.hpp"
#include "../protocols/ToplevelExport.hpp"
#include "../managers/PointerManager.hpp"
#include "../managers/eventLoop/EventLoopManager.hpp"
#include "../protocols/core/Compositor.hpp"
#include "../render/Renderer.hpp"
#include "../managers/EventManager.hpp"
#include "../managers/LayoutManager.hpp"
#include "../managers/input/InputManager.hpp"
#include "sync/SyncTimeline.hpp"
#include "../desktop/LayerSurface.hpp"
#include <aquamarine/output/Output.hpp>
#include "debug/Log.hpp"
#include "debug/HyprNotificationOverlay.hpp"
#include <hyprutils/string/String.hpp>
#include <hyprutils/utils/ScopeGuard.hpp>
#include <cstring>
#include <ranges>
using namespace Hyprutils::String;
using namespace Hyprutils::Utils;
using namespace Hyprutils::OS;
using enum NContentType::eContentType;
static int ratHandler(void* data) {
g_pHyprRenderer->renderMonitor(((CMonitor*)data)->self.lock());
return 1;
}
CMonitor::CMonitor(SP<Aquamarine::IOutput> output_) : state(this), output(output_) {
;
}
CMonitor::~CMonitor() {
events.destroy.emit();
}
void CMonitor::onConnect(bool noRule) {
EMIT_HOOK_EVENT("preMonitorAdded", self.lock());
CScopeGuard x = {[]() { g_pCompositor->arrangeMonitors(); }};
g_pEventLoopManager->doLater([] { g_pConfigManager->ensurePersistentWorkspacesPresent(); });
if (output->supportsExplicit) {
inTimeline = CSyncTimeline::create(output->getBackend()->drmFD());
}
listeners.frame = output->events.frame.registerListener([this](std::any d) { onMonitorFrame(); });
listeners.commit = output->events.commit.registerListener([this](std::any d) {
if (true) { // FIXME: E->state->committed & WLR_OUTPUT_STATE_BUFFER
PROTO::screencopy->onOutputCommit(self.lock());
PROTO::toplevelExport->onOutputCommit(self.lock());
}
});
listeners.needsFrame =
output->events.needsFrame.registerListener([this](std::any d) { g_pCompositor->scheduleFrameForMonitor(self.lock(), Aquamarine::IOutput::AQ_SCHEDULE_NEEDS_FRAME); });
listeners.presented = output->events.present.registerListener([this](std::any d) {
auto E = std::any_cast<Aquamarine::IOutput::SPresentEvent>(d);
PROTO::presentation->onPresented(self.lock(), E.when, E.refresh, E.seq, E.flags);
});
listeners.destroy = output->events.destroy.registerListener([this](std::any d) {
Debug::log(LOG, "Destroy called for monitor {}", szName);
onDisconnect(true);
output = nullptr;
m_bRenderingInitPassed = false;
Debug::log(LOG, "Removing monitor {} from realMonitors", szName);
std::erase_if(g_pCompositor->m_vRealMonitors, [&](PHLMONITOR& el) { return el.get() == this; });
});
listeners.state = output->events.state.registerListener([this](std::any d) {
auto E = std::any_cast<Aquamarine::IOutput::SStateEvent>(d);
if (E.size == Vector2D{}) {
// an indication to re-set state
// we can't do much for createdByUser displays I think
if (createdByUser)
return;
Debug::log(LOG, "Reapplying monitor rule for {} from a state request", szName);
applyMonitorRule(&activeMonitorRule, true);
return;
}
if (!createdByUser)
return;
const auto SIZE = E.size;
forceSize = SIZE;
SMonitorRule rule = activeMonitorRule;
rule.resolution = SIZE;
applyMonitorRule(&rule);
});
tearingState.canTear = output->getBackend()->type() == Aquamarine::AQ_BACKEND_DRM;
if (m_bEnabled) {
output->state->resetExplicitFences();
output->state->setEnabled(true);
state.commit();
return;
}
szName = output->name;
szDescription = output->description;
// remove comma character from description. This allow monitor specific rules to work on monitor with comma on their description
std::erase(szDescription, ',');
// field is backwards-compatible with intended usage of `szDescription` but excludes the parenthesized DRM node name suffix
szShortDescription = trim(std::format("{} {} {}", output->make, output->model, output->serial));
std::erase(szShortDescription, ',');
if (output->getBackend()->type() != Aquamarine::AQ_BACKEND_DRM)
createdByUser = true; // should be true. WL and Headless backends should be addable / removable
// get monitor rule that matches
SMonitorRule monitorRule = g_pConfigManager->getMonitorRuleFor(self.lock());
// if it's disabled, disable and ignore
if (monitorRule.disabled) {
output->state->resetExplicitFences();
output->state->setEnabled(false);
if (!state.commit())
Debug::log(ERR, "Couldn't commit disabled state on output {}", output->name);
m_bEnabled = false;
listeners.frame.reset();
return;
}
if (output->nonDesktop) {
Debug::log(LOG, "Not configuring non-desktop output");
if (PROTO::lease)
PROTO::lease->offer(self.lock());
return;
}
PHLMONITOR* thisWrapper = nullptr;
// find the wrap
for (auto& m : g_pCompositor->m_vRealMonitors) {
if (m->ID == ID) {
thisWrapper = &m;
break;
}
}
RASSERT(thisWrapper->get(), "CMonitor::onConnect: Had no wrapper???");
if (std::find_if(g_pCompositor->m_vMonitors.begin(), g_pCompositor->m_vMonitors.end(), [&](auto& other) { return other.get() == this; }) == g_pCompositor->m_vMonitors.end())
g_pCompositor->m_vMonitors.push_back(*thisWrapper);
m_bEnabled = true;
output->state->resetExplicitFences();
output->state->setEnabled(true);
// set mode, also applies
if (!noRule)
applyMonitorRule(&monitorRule, true);
if (!state.commit())
Debug::log(WARN, "state.commit() failed in CMonitor::onCommit");
damage.setSize(vecTransformedSize);
Debug::log(LOG, "Added new monitor with name {} at {:j0} with size {:j0}, pointer {:x}", output->name, vecPosition, vecPixelSize, (uintptr_t)output.get());
setupDefaultWS(monitorRule);
for (auto const& ws : g_pCompositor->m_vWorkspaces) {
if (!valid(ws))
continue;
if (ws->m_szLastMonitor == szName || g_pCompositor->m_vMonitors.size() == 1 /* avoid lost workspaces on recover */) {
g_pCompositor->moveWorkspaceToMonitor(ws, self.lock());
ws->startAnim(true, true, true);
ws->m_szLastMonitor = "";
}
}
scale = monitorRule.scale;
if (scale < 0.1)
scale = getDefaultScale();
forceFullFrames = 3; // force 3 full frames to make sure there is no blinking due to double-buffering.
//
if (!activeMonitorRule.mirrorOf.empty())
setMirror(activeMonitorRule.mirrorOf);
if (!g_pCompositor->m_pLastMonitor) // set the last monitor if it isnt set yet
g_pCompositor->setActiveMonitor(self.lock());
g_pHyprRenderer->arrangeLayersForMonitor(ID);
g_pLayoutManager->getCurrentLayout()->recalculateMonitor(ID);
// ensure VRR (will enable if necessary)
g_pConfigManager->ensureVRR(self.lock());
// verify last mon valid
bool found = false;
for (auto const& m : g_pCompositor->m_vMonitors) {
if (m == g_pCompositor->m_pLastMonitor) {
found = true;
break;
}
}
if (!found)
g_pCompositor->setActiveMonitor(self.lock());
renderTimer = wl_event_loop_add_timer(g_pCompositor->m_sWLEventLoop, ratHandler, this);
g_pCompositor->scheduleFrameForMonitor(self.lock(), Aquamarine::IOutput::AQ_SCHEDULE_NEW_MONITOR);
PROTO::gamma->applyGammaToState(self.lock());
events.connect.emit();
g_pEventManager->postEvent(SHyprIPCEvent{"monitoradded", szName});
g_pEventManager->postEvent(SHyprIPCEvent{"monitoraddedv2", std::format("{},{},{}", ID, szName, szShortDescription)});
EMIT_HOOK_EVENT("monitorAdded", self.lock());
}
void CMonitor::onDisconnect(bool destroy) {
EMIT_HOOK_EVENT("preMonitorRemoved", self.lock());
CScopeGuard x = {[this]() {
if (g_pCompositor->m_bIsShuttingDown)
return;
g_pEventManager->postEvent(SHyprIPCEvent{"monitorremoved", szName});
EMIT_HOOK_EVENT("monitorRemoved", self.lock());
g_pCompositor->arrangeMonitors();
}};
if (renderTimer) {
wl_event_source_remove(renderTimer);
renderTimer = nullptr;
}
if (!m_bEnabled || g_pCompositor->m_bIsShuttingDown)
return;
Debug::log(LOG, "onDisconnect called for {}", output->name);
events.disconnect.emit();
// Cleanup everything. Move windows back, snap cursor, shit.
PHLMONITOR BACKUPMON = nullptr;
for (auto const& m : g_pCompositor->m_vMonitors) {
if (m.get() != this) {
BACKUPMON = m;
break;
}
}
// remove mirror
if (pMirrorOf) {
pMirrorOf->mirrors.erase(std::find_if(pMirrorOf->mirrors.begin(), pMirrorOf->mirrors.end(), [&](const auto& other) { return other == self; }));
// unlock software for mirrored monitor
g_pPointerManager->unlockSoftwareForMonitor(pMirrorOf.lock());
pMirrorOf.reset();
}
if (!mirrors.empty()) {
for (auto const& m : mirrors) {
m->setMirror("");
}
g_pConfigManager->m_bWantsMonitorReload = true;
}
listeners.frame.reset();
listeners.presented.reset();
listeners.needsFrame.reset();
listeners.commit.reset();
for (size_t i = 0; i < 4; ++i) {
for (auto const& ls : m_aLayerSurfaceLayers[i]) {
if (ls->layerSurface && !ls->fadingOut)
ls->layerSurface->sendClosed();
}
m_aLayerSurfaceLayers[i].clear();
}
Debug::log(LOG, "Removed monitor {}!", szName);
if (!BACKUPMON) {
Debug::log(WARN, "Unplugged last monitor, entering an unsafe state. Good luck my friend.");
g_pCompositor->enterUnsafeState();
}
m_bEnabled = false;
m_bRenderingInitPassed = false;
if (BACKUPMON) {
// snap cursor
g_pCompositor->warpCursorTo(BACKUPMON->vecPosition + BACKUPMON->vecTransformedSize / 2.F, true);
// move workspaces
std::vector<PHLWORKSPACE> wspToMove;
for (auto const& w : g_pCompositor->m_vWorkspaces) {
if (w->m_pMonitor == self || !w->m_pMonitor)
wspToMove.push_back(w);
}
for (auto const& w : wspToMove) {
w->m_szLastMonitor = szName;
g_pCompositor->moveWorkspaceToMonitor(w, BACKUPMON);
w->startAnim(true, true, true);
}
} else {
g_pCompositor->m_pLastFocus.reset();
g_pCompositor->m_pLastWindow.reset();
g_pCompositor->m_pLastMonitor.reset();
}
if (activeWorkspace)
activeWorkspace->m_bVisible = false;
activeWorkspace.reset();
output->state->resetExplicitFences();
output->state->setAdaptiveSync(false);
output->state->setEnabled(false);
if (!state.commit())
Debug::log(WARN, "state.commit() failed in CMonitor::onDisconnect");
if (g_pCompositor->m_pLastMonitor == self)
g_pCompositor->setActiveMonitor(BACKUPMON ? BACKUPMON : g_pCompositor->m_pUnsafeOutput.lock());
if (g_pHyprRenderer->m_pMostHzMonitor == self) {
int mostHz = 0;
PHLMONITOR pMonitorMostHz = nullptr;
for (auto const& m : g_pCompositor->m_vMonitors) {
if (m->refreshRate > mostHz && m != self) {
pMonitorMostHz = m;
mostHz = m->refreshRate;
}
}
g_pHyprRenderer->m_pMostHzMonitor = pMonitorMostHz;
}
std::erase_if(g_pCompositor->m_vMonitors, [&](PHLMONITOR& el) { return el.get() == this; });
}
bool CMonitor::applyMonitorRule(SMonitorRule* pMonitorRule, bool force) {
static auto PDISABLESCALECHECKS = CConfigValue<Hyprlang::INT>("debug:disable_scale_checks");
Debug::log(LOG, "Applying monitor rule for {}", szName);
activeMonitorRule = *pMonitorRule;
if (forceSize.has_value())
activeMonitorRule.resolution = forceSize.value();
const auto RULE = &activeMonitorRule;
// if it's disabled, disable and ignore
if (RULE->disabled) {
if (m_bEnabled)
onDisconnect();
events.modeChanged.emit();
return true;
}
// don't touch VR headsets
if (output->nonDesktop)
return true;
if (!m_bEnabled) {
onConnect(true); // enable it.
Debug::log(LOG, "Monitor {} is disabled but is requested to be enabled", szName);
force = true;
}
// Check if the rule isn't already applied
// TODO: clean this up lol
if (!force && DELTALESSTHAN(vecPixelSize.x, RULE->resolution.x, 1) && DELTALESSTHAN(vecPixelSize.y, RULE->resolution.y, 1) &&
DELTALESSTHAN(refreshRate, RULE->refreshRate, 1) && setScale == RULE->scale &&
((DELTALESSTHAN(vecPosition.x, RULE->offset.x, 1) && DELTALESSTHAN(vecPosition.y, RULE->offset.y, 1)) || RULE->offset == Vector2D(-INT32_MAX, -INT32_MAX)) &&
transform == RULE->transform && RULE->enable10bit == enabled10bit && RULE->cmType == cmType && RULE->sdrSaturation == sdrSaturation &&
RULE->sdrBrightness == sdrBrightness && !std::memcmp(&customDrmMode, &RULE->drmMode, sizeof(customDrmMode))) {
Debug::log(LOG, "Not applying a new rule to {} because it's already applied!", szName);
setMirror(RULE->mirrorOf);
return true;
}
bool autoScale = false;
if (RULE->scale > 0.1) {
scale = RULE->scale;
} else {
autoScale = true;
const auto DEFAULTSCALE = getDefaultScale();
scale = DEFAULTSCALE;
}
setScale = scale;
transform = RULE->transform;
// accumulate requested modes in reverse order (cause inesrting at front is inefficient)
std::vector<SP<Aquamarine::SOutputMode>> requestedModes;
std::string requestedStr = "unknown";
// use sortFunc, add best 3 to requestedModes in reverse, since we test in reverse
auto addBest3Modes = [&](auto const& sortFunc) {
auto sortedModes = output->modes;
std::ranges::sort(sortedModes, sortFunc);
if (sortedModes.size() > 3)
sortedModes.erase(sortedModes.begin() + 3, sortedModes.end());
requestedModes.insert(requestedModes.end(), sortedModes.rbegin(), sortedModes.rend());
};
// last fallback is always preferred mode
if (!output->preferredMode())
Debug::log(ERR, "Monitor {} has NO PREFERRED MODE", output->name);
else
requestedModes.push_back(output->preferredMode());
if (RULE->resolution == Vector2D()) {
requestedStr = "preferred";
// fallback to first 3 modes if preferred fails/doesn't exist
requestedModes = output->modes;
if (requestedModes.size() > 3)
requestedModes.erase(requestedModes.begin() + 3, requestedModes.end());
std::ranges::reverse(requestedModes.begin(), requestedModes.end());
if (output->preferredMode())
requestedModes.push_back(output->preferredMode());
} else if (RULE->resolution == Vector2D(-1, -1)) {
requestedStr = "highrr";
// sort prioritizing refresh rate 1st and resolution 2nd, then add best 3
addBest3Modes([](auto const& a, auto const& b) {
if (std::round(a->refreshRate) > std::round(b->refreshRate))
return true;
else if (DELTALESSTHAN((float)a->refreshRate, (float)b->refreshRate, 1.F) && a->pixelSize.x > b->pixelSize.x && a->pixelSize.y > b->pixelSize.y)
return true;
return false;
});
} else if (RULE->resolution == Vector2D(-1, -2)) {
requestedStr = "highres";
// sort prioritizing resultion 1st and refresh rate 2nd, then add best 3
addBest3Modes([](auto const& a, auto const& b) {
if (a->pixelSize.x > b->pixelSize.x && a->pixelSize.y > b->pixelSize.y)
return true;
else if (DELTALESSTHAN(a->pixelSize.x, b->pixelSize.x, 1) && DELTALESSTHAN(a->pixelSize.y, b->pixelSize.y, 1) &&
std::round(a->refreshRate) > std::round(b->refreshRate))
return true;
return false;
});
} else if (RULE->resolution != Vector2D()) {
// user requested mode
requestedStr = std::format("{:X0}@{:.2f}Hz", RULE->resolution, RULE->refreshRate);
// sort by closeness to requested, then add best 3
addBest3Modes([&](auto const& a, auto const& b) {
if (abs(a->pixelSize.x - RULE->resolution.x) < abs(b->pixelSize.x - RULE->resolution.x))
return true;
if (a->pixelSize.x == b->pixelSize.x && abs(a->pixelSize.y - RULE->resolution.y) < abs(b->pixelSize.y - RULE->resolution.y))
return true;
if (a->pixelSize == b->pixelSize && abs((a->refreshRate / 1000.f) - RULE->refreshRate) < abs((b->refreshRate / 1000.f) - RULE->refreshRate))
return true;
return false;
});
// if the best mode isnt close to requested, then try requested as custom mode first
if (!requestedModes.empty()) {
auto bestMode = requestedModes.back();
if (!DELTALESSTHAN(bestMode->pixelSize.x, RULE->resolution.x, 1) || !DELTALESSTHAN(bestMode->pixelSize.y, RULE->resolution.y, 1) ||
!DELTALESSTHAN(bestMode->refreshRate / 1000.f, RULE->refreshRate, 1))
requestedModes.push_back(makeShared<Aquamarine::SOutputMode>(Aquamarine::SOutputMode{.pixelSize = RULE->resolution, .refreshRate = RULE->refreshRate * 1000.f}));
}
// then if requested is custom, try custom mode first
if (RULE->drmMode.type == DRM_MODE_TYPE_USERDEF) {
if (output->getBackend()->type() != Aquamarine::eBackendType::AQ_BACKEND_DRM)
Debug::log(ERR, "Tried to set custom modeline on non-DRM output");
else
requestedModes.push_back(makeShared<Aquamarine::SOutputMode>(
Aquamarine::SOutputMode{.pixelSize = {RULE->drmMode.hdisplay, RULE->drmMode.vdisplay}, .refreshRate = RULE->drmMode.vrefresh, .modeInfo = RULE->drmMode}));
}
}
const auto WAS10B = enabled10bit;
const auto OLDRES = vecPixelSize;
bool success = false;
// Needed in case we are switching from a custom modeline to a standard mode
customDrmMode = {};
currentMode = nullptr;
output->state->setFormat(DRM_FORMAT_XRGB8888);
prevDrmFormat = drmFormat;
drmFormat = DRM_FORMAT_XRGB8888;
output->state->resetExplicitFences();
if (Debug::trace) {
Debug::log(TRACE, "Monitor {} requested modes:", szName);
if (requestedModes.empty())
Debug::log(TRACE, "| None");
else {
for (auto const& mode : requestedModes | std::views::reverse) {
Debug::log(TRACE, "| {:X0}@{:.2f}Hz", mode->pixelSize, mode->refreshRate / 1000.f);
}
}
}
for (auto const& mode : requestedModes | std::views::reverse) {
std::string modeStr = std::format("{:X0}@{:.2f}Hz", mode->pixelSize, mode->refreshRate / 1000.f);
if (mode->modeInfo.has_value() && mode->modeInfo->type == DRM_MODE_TYPE_USERDEF) {
output->state->setCustomMode(mode);
if (!state.test()) {
Debug::log(ERR, "Monitor {}: REJECTED custom mode {}!", szName, modeStr);
continue;
}
customDrmMode = mode->modeInfo.value();
} else {
output->state->setMode(mode);
if (!state.test()) {
Debug::log(ERR, "Monitor {}: REJECTED available mode {}!", szName, modeStr);
if (mode->preferred)
Debug::log(ERR, "Monitor {}: REJECTED preferred mode!!!", szName);
continue;
}
customDrmMode = {};
}
refreshRate = mode->refreshRate / 1000.f;
vecSize = mode->pixelSize;
currentMode = mode;
success = true;
if (mode->preferred)
Debug::log(LOG, "Monitor {}: requested {}, using preferred mode {}", szName, requestedStr, modeStr);
else if (mode->modeInfo.has_value() && mode->modeInfo->type == DRM_MODE_TYPE_USERDEF)
Debug::log(LOG, "Monitor {}: requested {}, using custom mode {}", szName, requestedStr, modeStr);
else
Debug::log(LOG, "Monitor {}: requested {}, using available mode {}", szName, requestedStr, modeStr);
break;
}
// try requested as custom mode jic it works
if (!success && RULE->resolution != Vector2D() && RULE->resolution != Vector2D(-1, -1) && RULE->resolution != Vector2D(-1, -2)) {
auto refreshRate = output->getBackend()->type() == Aquamarine::eBackendType::AQ_BACKEND_DRM ? RULE->refreshRate * 1000 : 0;
auto mode = makeShared<Aquamarine::SOutputMode>(Aquamarine::SOutputMode{.pixelSize = RULE->resolution, .refreshRate = refreshRate});
std::string modeStr = std::format("{:X0}@{:.2f}Hz", mode->pixelSize, mode->refreshRate / 1000.f);
output->state->setCustomMode(mode);
if (state.test()) {
Debug::log(LOG, "Monitor {}: requested {}, using custom mode {}", szName, requestedStr, modeStr);
refreshRate = mode->refreshRate / 1000.f;
vecSize = mode->pixelSize;
currentMode = mode;
customDrmMode = {};
success = true;
} else
Debug::log(ERR, "Monitor {}: REJECTED custom mode {}!", szName, modeStr);
}
// try any of the modes if none of the above work
if (!success) {
for (auto const& mode : output->modes) {
output->state->setMode(mode);
if (!state.test())
continue;
auto errorMessage =
std::format("Monitor {} failed to set any requested modes, falling back to mode {:X0}@{:.2f}Hz", szName, mode->pixelSize, mode->refreshRate / 1000.f);
Debug::log(WARN, errorMessage);
g_pHyprNotificationOverlay->addNotification(errorMessage, CHyprColor(0xff0000ff), 5000, ICON_WARNING);
refreshRate = mode->refreshRate / 1000.f;
vecSize = mode->pixelSize;
currentMode = mode;
customDrmMode = {};
success = true;
break;
}
}
if (!success) {
Debug::log(ERR, "Monitor {} has NO FALLBACK MODES, and an INVALID one was requested: {:X0}@{:.2f}Hz", szName, RULE->resolution, RULE->refreshRate);
return true;
}
vrrActive = output->state->state().adaptiveSync // disabled here, will be tested in CConfigManager::ensureVRR()
|| createdByUser; // wayland backend doesn't allow for disabling adaptive_sync
vecPixelSize = vecSize;
// clang-format off
static const std::array<std::vector<std::pair<std::string, uint32_t>>, 2> formats{
std::vector<std::pair<std::string, uint32_t>>{ /* 10-bit */
{"DRM_FORMAT_XRGB2101010", DRM_FORMAT_XRGB2101010}, {"DRM_FORMAT_XBGR2101010", DRM_FORMAT_XBGR2101010}, {"DRM_FORMAT_XRGB8888", DRM_FORMAT_XRGB8888}, {"DRM_FORMAT_XBGR8888", DRM_FORMAT_XBGR8888}
},
std::vector<std::pair<std::string, uint32_t>>{ /* 8-bit */
{"DRM_FORMAT_XRGB8888", DRM_FORMAT_XRGB8888}, {"DRM_FORMAT_XBGR8888", DRM_FORMAT_XBGR8888}
}
};
// clang-format on
bool set10bit = false;
for (auto const& fmt : formats[(int)!RULE->enable10bit]) {
output->state->setFormat(fmt.second);
prevDrmFormat = drmFormat;
drmFormat = fmt.second;
if (!state.test()) {
Debug::log(ERR, "output {} failed basic test on format {}", szName, fmt.first);
} else {
Debug::log(LOG, "output {} succeeded basic test on format {}", szName, fmt.first);
if (RULE->enable10bit && fmt.first.contains("101010"))
set10bit = true;
break;
}
}
enabled10bit = set10bit;
auto oldImageDescription = imageDescription;
cmType = RULE->cmType;
switch (cmType) {
case CM_AUTO: cmType = enabled10bit && output->parsedEDID.supportsBT2020 ? CM_WIDE : CM_SRGB; break;
case CM_EDID: cmType = output->parsedEDID.chromaticityCoords.has_value() ? CM_EDID : CM_SRGB; break;
case CM_HDR:
case CM_HDR_EDID:
cmType = output->parsedEDID.supportsBT2020 && output->parsedEDID.hdrMetadata.has_value() && output->parsedEDID.hdrMetadata->supportsPQ ? cmType : CM_SRGB;
break;
default: break;
}
switch (cmType) {
case CM_SRGB: imageDescription = {}; break; // assumes SImageDescirption defaults to sRGB
case CM_WIDE:
imageDescription = {.primariesNameSet = true,
.primariesNamed = NColorManagement::CM_PRIMARIES_BT2020,
.primaries = NColorManagement::getPrimaries(NColorManagement::CM_PRIMARIES_BT2020)};
break;
case CM_EDID:
imageDescription = {.primariesNameSet = false,
.primariesNamed = NColorManagement::CM_PRIMARIES_BT2020,
.primaries = {
.red = {.x = output->parsedEDID.chromaticityCoords->red.x, .y = output->parsedEDID.chromaticityCoords->red.y},
.green = {.x = output->parsedEDID.chromaticityCoords->green.x, .y = output->parsedEDID.chromaticityCoords->green.y},
.blue = {.x = output->parsedEDID.chromaticityCoords->blue.x, .y = output->parsedEDID.chromaticityCoords->blue.y},
.white = {.x = output->parsedEDID.chromaticityCoords->white.x, .y = output->parsedEDID.chromaticityCoords->white.y},
}};
break;
case CM_HDR:
imageDescription = {.transferFunction = NColorManagement::CM_TRANSFER_FUNCTION_ST2084_PQ,
.primariesNameSet = true,
.primariesNamed = NColorManagement::CM_PRIMARIES_BT2020,
.primaries = NColorManagement::getPrimaries(NColorManagement::CM_PRIMARIES_BT2020),
.luminances = {.min = 0, .max = 10000, .reference = 203}};
break;
case CM_HDR_EDID:
imageDescription = {.transferFunction = NColorManagement::CM_TRANSFER_FUNCTION_ST2084_PQ,
.primariesNameSet = false,
.primariesNamed = NColorManagement::CM_PRIMARIES_BT2020,
.primaries = output->parsedEDID.chromaticityCoords.has_value() ?
NColorManagement::SPCPRimaries{
.red = {.x = output->parsedEDID.chromaticityCoords->red.x, .y = output->parsedEDID.chromaticityCoords->red.y},
.green = {.x = output->parsedEDID.chromaticityCoords->green.x, .y = output->parsedEDID.chromaticityCoords->green.y},
.blue = {.x = output->parsedEDID.chromaticityCoords->blue.x, .y = output->parsedEDID.chromaticityCoords->blue.y},
.white = {.x = output->parsedEDID.chromaticityCoords->white.x, .y = output->parsedEDID.chromaticityCoords->white.y},
} :
NColorManagement::getPrimaries(NColorManagement::CM_PRIMARIES_BT2020),
.luminances = {.min = output->parsedEDID.hdrMetadata->desiredContentMinLuminance,
.max = output->parsedEDID.hdrMetadata->desiredContentMaxLuminance,
.reference = output->parsedEDID.hdrMetadata->desiredMaxFrameAverageLuminance}};
break;
default: UNREACHABLE();
}
if (oldImageDescription != imageDescription)
PROTO::colorManagement->onMonitorImageDescriptionChanged(self);
sdrSaturation = RULE->sdrSaturation;
sdrBrightness = RULE->sdrBrightness;
Vector2D logicalSize = vecPixelSize / scale;
if (!*PDISABLESCALECHECKS && (logicalSize.x != std::round(logicalSize.x) || logicalSize.y != std::round(logicalSize.y))) {
// invalid scale, will produce fractional pixels.
// find the nearest valid.
float searchScale = std::round(scale * 120.0);
bool found = false;
double scaleZero = searchScale / 120.0;
Vector2D logicalZero = vecPixelSize / scaleZero;
if (logicalZero == logicalZero.round())
scale = scaleZero;
else {
for (size_t i = 1; i < 90; ++i) {
double scaleUp = (searchScale + i) / 120.0;
double scaleDown = (searchScale - i) / 120.0;
Vector2D logicalUp = vecPixelSize / scaleUp;
Vector2D logicalDown = vecPixelSize / scaleDown;
if (logicalUp == logicalUp.round()) {
found = true;
searchScale = scaleUp;
break;
}
if (logicalDown == logicalDown.round()) {
found = true;
searchScale = scaleDown;
break;
}
}
if (!found) {
if (autoScale)
scale = std::round(scaleZero);
else {
Debug::log(ERR, "Invalid scale passed to monitor, {} failed to find a clean divisor", scale);
g_pConfigManager->addParseError("Invalid scale passed to monitor " + szName + ", failed to find a clean divisor");
scale = getDefaultScale();
}
} else {
if (!autoScale) {
Debug::log(ERR, "Invalid scale passed to monitor, {} found suggestion {}", scale, searchScale);
g_pConfigManager->addParseError(
std::format("Invalid scale passed to monitor {}, failed to find a clean divisor. Suggested nearest scale: {:5f}", szName, searchScale));
scale = getDefaultScale();
} else
scale = searchScale;
}
}
}
output->scheduleFrame();
if (!state.commit())
Debug::log(ERR, "Couldn't commit output named {}", output->name);
Vector2D xfmd = transform % 2 == 1 ? Vector2D{vecPixelSize.y, vecPixelSize.x} : vecPixelSize;
vecSize = (xfmd / scale).round();
vecTransformedSize = xfmd;
if (createdByUser) {
CBox transformedBox = {0, 0, vecTransformedSize.x, vecTransformedSize.y};
transformedBox.transform(wlTransformToHyprutils(invertTransform(transform)), vecTransformedSize.x, vecTransformedSize.y);
vecPixelSize = Vector2D(transformedBox.width, transformedBox.height);
}
updateMatrix();
if (WAS10B != enabled10bit || OLDRES != vecPixelSize)
g_pHyprOpenGL->destroyMonitorResources(self.lock());
g_pCompositor->arrangeMonitors();
damage.setSize(vecTransformedSize);
// Set scale for all surfaces on this monitor, needed for some clients
// but not on unsafe state to avoid crashes
if (!g_pCompositor->m_bUnsafeState) {
for (auto const& w : g_pCompositor->m_vWindows) {
w->updateSurfaceScaleTransformDetails();
}
}
// updato us
g_pHyprRenderer->arrangeLayersForMonitor(ID);
// reload to fix mirrors
g_pConfigManager->m_bWantsMonitorReload = true;
Debug::log(LOG, "Monitor {} data dump: res {:X}@{:.2f}Hz, scale {:.2f}, transform {}, pos {:X}, 10b {}", szName, vecPixelSize, refreshRate, scale, (int)transform, vecPosition,
(int)enabled10bit);
EMIT_HOOK_EVENT("monitorLayoutChanged", nullptr);
events.modeChanged.emit();
return true;
}
void CMonitor::addDamage(const pixman_region32_t* rg) {
static auto PZOOMFACTOR = CConfigValue<Hyprlang::FLOAT>("cursor:zoom_factor");
if (*PZOOMFACTOR != 1.f && g_pCompositor->getMonitorFromCursor() == self) {
damage.damageEntire();
g_pCompositor->scheduleFrameForMonitor(self.lock(), Aquamarine::IOutput::AQ_SCHEDULE_DAMAGE);
} else if (damage.damage(rg))
g_pCompositor->scheduleFrameForMonitor(self.lock(), Aquamarine::IOutput::AQ_SCHEDULE_DAMAGE);
}
void CMonitor::addDamage(const CRegion& rg) {
addDamage(const_cast<CRegion*>(&rg)->pixman());
}
void CMonitor::addDamage(const CBox& box) {
static auto PZOOMFACTOR = CConfigValue<Hyprlang::FLOAT>("cursor:zoom_factor");
if (*PZOOMFACTOR != 1.f && g_pCompositor->getMonitorFromCursor() == self) {
damage.damageEntire();
g_pCompositor->scheduleFrameForMonitor(self.lock(), Aquamarine::IOutput::AQ_SCHEDULE_DAMAGE);
}
if (damage.damage(box))
g_pCompositor->scheduleFrameForMonitor(self.lock(), Aquamarine::IOutput::AQ_SCHEDULE_DAMAGE);
}
bool CMonitor::shouldSkipScheduleFrameOnMouseEvent() {
static auto PNOBREAK = CConfigValue<Hyprlang::INT>("cursor:no_break_fs_vrr");
static auto PMINRR = CConfigValue<Hyprlang::INT>("cursor:min_refresh_rate");
// skip scheduling extra frames for fullsreen apps with vrr
const bool shouldSkip = activeWorkspace && activeWorkspace->m_bHasFullscreenWindow && activeWorkspace->m_efFullscreenMode == FSMODE_FULLSCREEN &&
(*PNOBREAK == 1 || (*PNOBREAK == 2 && activeWorkspace->getFullscreenWindow()->getContentType() == CONTENT_TYPE_GAME)) && output->state->state().adaptiveSync;
// keep requested minimum refresh rate
if (shouldSkip && *PMINRR && lastPresentationTimer.getMillis() > 1000.0f / *PMINRR) {
// damage whole screen because some previous cursor box damages were skipped
damage.damageEntire();
return false;
}
return shouldSkip;
}
bool CMonitor::isMirror() {
return pMirrorOf != nullptr;
}
bool CMonitor::matchesStaticSelector(const std::string& selector) const {
if (selector.starts_with("desc:")) {
// match by description
const auto DESCRIPTIONSELECTOR = selector.substr(5);
return szDescription.starts_with(DESCRIPTIONSELECTOR) || szShortDescription.starts_with(DESCRIPTIONSELECTOR);
} else {
// match by selector
return szName == selector;
}
}
WORKSPACEID CMonitor::findAvailableDefaultWS() {
for (WORKSPACEID i = 1; i < LONG_MAX; ++i) {
if (g_pCompositor->getWorkspaceByID(i))
continue;
if (const auto BOUND = g_pConfigManager->getBoundMonitorStringForWS(std::to_string(i)); !BOUND.empty() && BOUND != szName)
continue;
return i;
}
return LONG_MAX; // shouldn't be reachable
}
void CMonitor::setupDefaultWS(const SMonitorRule& monitorRule) {
// Workspace
std::string newDefaultWorkspaceName = "";
int64_t wsID = WORKSPACE_INVALID;
if (g_pConfigManager->getDefaultWorkspaceFor(szName).empty())
wsID = findAvailableDefaultWS();
else {
const auto ws = getWorkspaceIDNameFromString(g_pConfigManager->getDefaultWorkspaceFor(szName));
wsID = ws.id;
newDefaultWorkspaceName = ws.name;
}
if (wsID == WORKSPACE_INVALID || (wsID >= SPECIAL_WORKSPACE_START && wsID <= -2)) {
wsID = g_pCompositor->m_vWorkspaces.size() + 1;
newDefaultWorkspaceName = std::to_string(wsID);
Debug::log(LOG, "Invalid workspace= directive name in monitor parsing, workspace name \"{}\" is invalid.", g_pConfigManager->getDefaultWorkspaceFor(szName));
}
auto PNEWWORKSPACE = g_pCompositor->getWorkspaceByID(wsID);
Debug::log(LOG, "New monitor: WORKSPACEID {}, exists: {}", wsID, (int)(PNEWWORKSPACE != nullptr));
if (PNEWWORKSPACE) {
// workspace exists, move it to the newly connected monitor
g_pCompositor->moveWorkspaceToMonitor(PNEWWORKSPACE, self.lock());
activeWorkspace = PNEWWORKSPACE;
g_pLayoutManager->getCurrentLayout()->recalculateMonitor(ID);
PNEWWORKSPACE->startAnim(true, true, true);
} else {
if (newDefaultWorkspaceName == "")
newDefaultWorkspaceName = std::to_string(wsID);
PNEWWORKSPACE = g_pCompositor->m_vWorkspaces.emplace_back(CWorkspace::create(wsID, self.lock(), newDefaultWorkspaceName));
}
activeWorkspace = PNEWWORKSPACE;
PNEWWORKSPACE->setActive(true);
PNEWWORKSPACE->m_bVisible = true;
PNEWWORKSPACE->m_szLastMonitor = "";
}
void CMonitor::setMirror(const std::string& mirrorOf) {
const auto PMIRRORMON = g_pCompositor->getMonitorFromString(mirrorOf);
if (PMIRRORMON == pMirrorOf)
return;
if (PMIRRORMON && PMIRRORMON->isMirror()) {
Debug::log(ERR, "Cannot mirror a mirror!");
return;
}
if (PMIRRORMON == self) {
Debug::log(ERR, "Cannot mirror self!");
return;
}
if (!PMIRRORMON) {
// disable mirroring
if (pMirrorOf) {
pMirrorOf->mirrors.erase(std::find_if(pMirrorOf->mirrors.begin(), pMirrorOf->mirrors.end(), [&](const auto& other) { return other == self; }));
// unlock software for mirrored monitor
g_pPointerManager->unlockSoftwareForMonitor(pMirrorOf.lock());
}
pMirrorOf.reset();
// set rule
const auto RULE = g_pConfigManager->getMonitorRuleFor(self.lock());
vecPosition = RULE.offset;
// push to mvmonitors
PHLMONITOR* thisWrapper = nullptr;
// find the wrap
for (auto& m : g_pCompositor->m_vRealMonitors) {
if (m->ID == ID) {
thisWrapper = &m;
break;
}
}
RASSERT(thisWrapper->get(), "CMonitor::setMirror: Had no wrapper???");
if (std::find_if(g_pCompositor->m_vMonitors.begin(), g_pCompositor->m_vMonitors.end(), [&](auto& other) { return other.get() == this; }) ==
g_pCompositor->m_vMonitors.end()) {
g_pCompositor->m_vMonitors.push_back(*thisWrapper);
}
setupDefaultWS(RULE);
applyMonitorRule((SMonitorRule*)&RULE, true); // will apply the offset and stuff
} else {
PHLMONITOR BACKUPMON = nullptr;
for (auto const& m : g_pCompositor->m_vMonitors) {
if (m.get() != this) {
BACKUPMON = m;
break;
}
}
// move all the WS
std::vector<PHLWORKSPACE> wspToMove;
for (auto const& w : g_pCompositor->m_vWorkspaces) {
if (w->m_pMonitor == self || !w->m_pMonitor)
wspToMove.push_back(w);
}
for (auto const& w : wspToMove) {
g_pCompositor->moveWorkspaceToMonitor(w, BACKUPMON);
w->startAnim(true, true, true);
}
activeWorkspace.reset();
vecPosition = PMIRRORMON->vecPosition;
pMirrorOf = PMIRRORMON;
pMirrorOf->mirrors.push_back(self);
// remove from mvmonitors
std::erase_if(g_pCompositor->m_vMonitors, [&](const auto& other) { return other == self; });
g_pCompositor->arrangeMonitors();
g_pCompositor->setActiveMonitor(g_pCompositor->m_vMonitors.front());
g_pCompositor->sanityCheckWorkspaces();
// Software lock mirrored monitor
g_pPointerManager->lockSoftwareForMonitor(PMIRRORMON);
}
events.modeChanged.emit();
}
float CMonitor::getDefaultScale() {
if (!m_bEnabled)
return 1;
static constexpr double MMPERINCH = 25.4;
const auto DIAGONALPX = sqrt(pow(vecPixelSize.x, 2) + pow(vecPixelSize.y, 2));
const auto DIAGONALIN = sqrt(pow(output->physicalSize.x / MMPERINCH, 2) + pow(output->physicalSize.y / MMPERINCH, 2));
const auto PPI = DIAGONALPX / DIAGONALIN;
if (PPI > 200 /* High PPI, 2x*/)
return 2;
else if (PPI > 140 /* Medium PPI, 1.5x*/)
return 1.5;
return 1;
}
void CMonitor::changeWorkspace(const PHLWORKSPACE& pWorkspace, bool internal, bool noMouseMove, bool noFocus) {
if (!pWorkspace)
return;
if (pWorkspace->m_bIsSpecialWorkspace) {
if (activeSpecialWorkspace != pWorkspace) {
Debug::log(LOG, "changeworkspace on special, togglespecialworkspace to id {}", pWorkspace->m_iID);
setSpecialWorkspace(pWorkspace);
}
return;
}
if (pWorkspace == activeWorkspace)
return;
const auto POLDWORKSPACE = activeWorkspace;
if (POLDWORKSPACE)
POLDWORKSPACE->m_bVisible = false;
pWorkspace->m_bVisible = true;
activeWorkspace = pWorkspace;
if (!internal) {
const auto ANIMTOLEFT = POLDWORKSPACE && pWorkspace->m_iID > POLDWORKSPACE->m_iID;
if (POLDWORKSPACE)
POLDWORKSPACE->startAnim(false, ANIMTOLEFT);
pWorkspace->startAnim(true, ANIMTOLEFT);
// move pinned windows
for (auto const& w : g_pCompositor->m_vWindows) {
if (w->m_pWorkspace == POLDWORKSPACE && w->m_bPinned)
w->moveToWorkspace(pWorkspace);
}
if (!noFocus && !g_pCompositor->m_pLastMonitor->activeSpecialWorkspace &&
!(g_pCompositor->m_pLastWindow.lock() && g_pCompositor->m_pLastWindow->m_bPinned && g_pCompositor->m_pLastWindow->m_pMonitor == self)) {
static auto PFOLLOWMOUSE = CConfigValue<Hyprlang::INT>("input:follow_mouse");
auto pWindow = pWorkspace->m_bHasFullscreenWindow ? pWorkspace->getFullscreenWindow() : pWorkspace->getLastFocusedWindow();
if (!pWindow) {
if (*PFOLLOWMOUSE == 1)
pWindow = g_pCompositor->vectorToWindowUnified(g_pInputManager->getMouseCoordsInternal(), RESERVED_EXTENTS | INPUT_EXTENTS | ALLOW_FLOATING);
if (!pWindow)
pWindow = pWorkspace->getTopLeftWindow();
if (!pWindow)
pWindow = pWorkspace->getFirstWindow();
}
g_pCompositor->focusWindow(pWindow);
}
if (!noMouseMove)
g_pInputManager->simulateMouseMovement();
g_pLayoutManager->getCurrentLayout()->recalculateMonitor(ID);
g_pEventManager->postEvent(SHyprIPCEvent{"workspace", pWorkspace->m_szName});
g_pEventManager->postEvent(SHyprIPCEvent{"workspacev2", std::format("{},{}", pWorkspace->m_iID, pWorkspace->m_szName)});
EMIT_HOOK_EVENT("workspace", pWorkspace);
}
g_pHyprRenderer->damageMonitor(self.lock());
g_pCompositor->updateFullscreenFadeOnWorkspace(pWorkspace);
g_pConfigManager->ensureVRR(self.lock());
g_pCompositor->updateSuspendedStates();
if (activeSpecialWorkspace)
g_pCompositor->updateFullscreenFadeOnWorkspace(activeSpecialWorkspace);
}
void CMonitor::changeWorkspace(const WORKSPACEID& id, bool internal, bool noMouseMove, bool noFocus) {
changeWorkspace(g_pCompositor->getWorkspaceByID(id), internal, noMouseMove, noFocus);
}
void CMonitor::setSpecialWorkspace(const PHLWORKSPACE& pWorkspace) {
if (activeSpecialWorkspace == pWorkspace)
return;
g_pHyprRenderer->damageMonitor(self.lock());
if (!pWorkspace) {
// remove special if exists
if (activeSpecialWorkspace) {
activeSpecialWorkspace->m_bVisible = false;
activeSpecialWorkspace->startAnim(false, false);
g_pEventManager->postEvent(SHyprIPCEvent{"activespecial", "," + szName});
g_pEventManager->postEvent(SHyprIPCEvent{"activespecialv2", ",," + szName});
}
activeSpecialWorkspace.reset();
g_pLayoutManager->getCurrentLayout()->recalculateMonitor(ID);
if (!(g_pCompositor->m_pLastWindow.lock() && g_pCompositor->m_pLastWindow->m_bPinned && g_pCompositor->m_pLastWindow->m_pMonitor == self)) {
if (const auto PLAST = activeWorkspace->getLastFocusedWindow(); PLAST)
g_pCompositor->focusWindow(PLAST);
else
g_pInputManager->refocus();
}
g_pCompositor->updateFullscreenFadeOnWorkspace(activeWorkspace);
g_pConfigManager->ensureVRR(self.lock());
g_pCompositor->updateSuspendedStates();
return;
}
if (activeSpecialWorkspace) {
activeSpecialWorkspace->m_bVisible = false;
activeSpecialWorkspace->startAnim(false, false);
}
bool animate = true;
//close if open elsewhere
const auto PMONITORWORKSPACEOWNER = pWorkspace->m_pMonitor.lock();
if (const auto PMWSOWNER = pWorkspace->m_pMonitor.lock(); PMWSOWNER && PMWSOWNER->activeSpecialWorkspace == pWorkspace) {
PMWSOWNER->activeSpecialWorkspace.reset();
g_pLayoutManager->getCurrentLayout()->recalculateMonitor(PMWSOWNER->ID);
g_pEventManager->postEvent(SHyprIPCEvent{"activespecial", "," + PMWSOWNER->szName});
g_pEventManager->postEvent(SHyprIPCEvent{"activespecialv2", ",," + PMWSOWNER->szName});
const auto PACTIVEWORKSPACE = PMWSOWNER->activeWorkspace;
g_pCompositor->updateFullscreenFadeOnWorkspace(PACTIVEWORKSPACE);
animate = false;
}
// open special
pWorkspace->m_pMonitor = self;
activeSpecialWorkspace = pWorkspace;
activeSpecialWorkspace->m_bVisible = true;
if (animate)
pWorkspace->startAnim(true, true);
for (auto const& w : g_pCompositor->m_vWindows) {
if (w->m_pWorkspace == pWorkspace) {
w->m_pMonitor = self;
w->updateSurfaceScaleTransformDetails();
w->setAnimationsToMove();
const auto MIDDLE = w->middle();
if (w->m_bIsFloating && !VECINRECT(MIDDLE, vecPosition.x, vecPosition.y, vecPosition.x + vecSize.x, vecPosition.y + vecSize.y) && !w->isX11OverrideRedirect()) {
// if it's floating and the middle isnt on the current mon, move it to the center
const auto PMONFROMMIDDLE = g_pCompositor->getMonitorFromVector(MIDDLE);
Vector2D pos = w->m_vRealPosition->goal();
if (!VECINRECT(MIDDLE, PMONFROMMIDDLE->vecPosition.x, PMONFROMMIDDLE->vecPosition.y, PMONFROMMIDDLE->vecPosition.x + PMONFROMMIDDLE->vecSize.x,
PMONFROMMIDDLE->vecPosition.y + PMONFROMMIDDLE->vecSize.y)) {
// not on any monitor, center
pos = middle() / 2.f - w->m_vRealSize->goal() / 2.f;
} else
pos = pos - PMONFROMMIDDLE->vecPosition + vecPosition;
*w->m_vRealPosition = pos;
w->m_vPosition = pos;
}
}
}
g_pLayoutManager->getCurrentLayout()->recalculateMonitor(ID);
if (!(g_pCompositor->m_pLastWindow.lock() && g_pCompositor->m_pLastWindow->m_bPinned && g_pCompositor->m_pLastWindow->m_pMonitor == self)) {
if (const auto PLAST = pWorkspace->getLastFocusedWindow(); PLAST)
g_pCompositor->focusWindow(PLAST);
else
g_pInputManager->refocus();
}
g_pEventManager->postEvent(SHyprIPCEvent{"activespecial", pWorkspace->m_szName + "," + szName});
g_pEventManager->postEvent(SHyprIPCEvent{"activespecialv2", std::to_string(pWorkspace->m_iID) + "," + pWorkspace->m_szName + "," + szName});
g_pHyprRenderer->damageMonitor(self.lock());
g_pCompositor->updateFullscreenFadeOnWorkspace(pWorkspace);
g_pConfigManager->ensureVRR(self.lock());
g_pCompositor->updateSuspendedStates();
}
void CMonitor::setSpecialWorkspace(const WORKSPACEID& id) {
setSpecialWorkspace(g_pCompositor->getWorkspaceByID(id));
}
void CMonitor::moveTo(const Vector2D& pos) {
vecPosition = pos;
}
SWorkspaceIDName CMonitor::getPrevWorkspaceIDName(const WORKSPACEID id) {
while (!prevWorkSpaces.empty()) {
const int PREVID = prevWorkSpaces.top();
prevWorkSpaces.pop();
if (PREVID == id) // skip same workspace
continue;
// recheck if previous workspace's was moved to another monitor
const auto ws = g_pCompositor->getWorkspaceByID(PREVID);
if (ws && ws->monitorID() == ID)
return {.id = PREVID, .name = ws->m_szName};
}
return {.id = WORKSPACE_INVALID};
}
void CMonitor::addPrevWorkspaceID(const WORKSPACEID id) {
if (!prevWorkSpaces.empty() && prevWorkSpaces.top() == id)
return;
prevWorkSpaces.emplace(id);
}
Vector2D CMonitor::middle() {
return vecPosition + vecSize / 2.f;
}
void CMonitor::updateMatrix() {
projMatrix = Mat3x3::identity();
if (transform != WL_OUTPUT_TRANSFORM_NORMAL)
projMatrix.translate(vecPixelSize / 2.0).transform(wlTransformToHyprutils(transform)).translate(-vecTransformedSize / 2.0);
}
WORKSPACEID CMonitor::activeWorkspaceID() {
return activeWorkspace ? activeWorkspace->m_iID : 0;
}
WORKSPACEID CMonitor::activeSpecialWorkspaceID() {
return activeSpecialWorkspace ? activeSpecialWorkspace->m_iID : 0;
}
CBox CMonitor::logicalBox() {
return {vecPosition, vecSize};
}
void CMonitor::scheduleDone() {
if (doneScheduled)
return;
doneScheduled = true;
g_pEventLoopManager->doLater([M = self] {
if (!M) // if M is gone, we got destroyed, doesn't matter.
return;
if (!PROTO::outputs.contains(M->szName))
return;
PROTO::outputs.at(M->szName)->sendDone();
M->doneScheduled = false;
});
}
void CMonitor::setCTM(const Mat3x3& ctm_) {
ctm = ctm_;
ctmUpdated = true;
g_pCompositor->scheduleFrameForMonitor(self.lock(), Aquamarine::IOutput::scheduleFrameReason::AQ_SCHEDULE_NEEDS_FRAME);
}
bool CMonitor::attemptDirectScanout() {
if (!mirrors.empty() || isMirror() || g_pHyprRenderer->m_bDirectScanoutBlocked)
return false; // do not DS if this monitor is being mirrored. Will break the functionality.
if (g_pPointerManager->softwareLockedFor(self.lock()))
return false;
const auto PCANDIDATE = solitaryClient.lock();
if (!PCANDIDATE)
return false;
const auto PSURFACE = g_pXWaylandManager->getWindowSurface(PCANDIDATE);
if (!PSURFACE || !PSURFACE->current.texture || !PSURFACE->current.buffer)
return false;
if (PSURFACE->current.bufferSize != vecPixelSize || PSURFACE->current.transform != transform)
return false;
// we can't scanout shm buffers.
const auto params = PSURFACE->current.buffer->buffer->dmabuf();
if (!params.success || !PSURFACE->current.texture->m_pEglImage /* dmabuf */)
return false;
Debug::log(TRACE, "attemptDirectScanout: surface {:x} passed, will attempt, buffer {}", (uintptr_t)PSURFACE.get(), (uintptr_t)PSURFACE->current.buffer->buffer.get());
auto PBUFFER = PSURFACE->current.buffer->buffer;
if (PBUFFER == output->state->state().buffer) {
if (scanoutNeedsCursorUpdate) {
if (!state.test()) {
Debug::log(TRACE, "attemptDirectScanout: failed basic test");
return false;
}
if (!output->commit()) {
Debug::log(TRACE, "attemptDirectScanout: failed to commit cursor update");
lastScanout.reset();
return false;
}
scanoutNeedsCursorUpdate = false;
}
return true;
}
// FIXME: make sure the buffer actually follows the available scanout dmabuf formats
// and comes from the appropriate device. This may implode on multi-gpu!!
// entering into scanout, so save monitor format
if (lastScanout.expired())
prevDrmFormat = drmFormat;
if (drmFormat != params.format) {
output->state->setFormat(params.format);
drmFormat = params.format;
}
output->state->setBuffer(PBUFFER);
output->state->setPresentationMode(tearingState.activelyTearing ? Aquamarine::eOutputPresentationMode::AQ_OUTPUT_PRESENTATION_IMMEDIATE :
Aquamarine::eOutputPresentationMode::AQ_OUTPUT_PRESENTATION_VSYNC);
if (!state.test()) {
Debug::log(TRACE, "attemptDirectScanout: failed basic test");
return false;
}
timespec now;
clock_gettime(CLOCK_MONOTONIC, &now);
PSURFACE->presentFeedback(&now, self.lock());
output->state->addDamage(PSURFACE->accumulateCurrentBufferDamage());
output->state->resetExplicitFences();
auto cleanup = CScopeGuard([this]() { output->state->resetExplicitFences(); });
auto explicitOptions = g_pHyprRenderer->getExplicitSyncSettings(output);
bool DOEXPLICIT = PSURFACE->syncobj && PSURFACE->current.buffer && PSURFACE->current.buffer->acquire && explicitOptions.explicitKMSEnabled;
if (DOEXPLICIT) {
// wait for surface's explicit fence if present
inFence = PSURFACE->current.buffer->acquire->exportAsFD();
if (inFence.isValid()) {
Debug::log(TRACE, "attemptDirectScanout: setting IN_FENCE for aq to {}", inFence.get());
output->state->setExplicitInFence(inFence.get());
} else {
Debug::log(TRACE, "attemptDirectScanout: failed to acquire an sync file fd for aq IN_FENCE");
DOEXPLICIT = false;
}
}
bool ok = output->commit();
if (!ok && DOEXPLICIT) {
Debug::log(TRACE, "attemptDirectScanout: EXPLICIT SYNC FAILED: commit() returned false. Resetting fences and retrying, might result in glitches.");
output->state->resetExplicitFences();
ok = output->commit();
}
if (!ok) {
Debug::log(TRACE, "attemptDirectScanout: failed to scanout surface");
lastScanout.reset();
return false;
}
if (lastScanout.expired()) {
lastScanout = PCANDIDATE;
Debug::log(LOG, "Entered a direct scanout to {:x}: \"{}\"", (uintptr_t)PCANDIDATE.get(), PCANDIDATE->m_szTitle);
}
scanoutNeedsCursorUpdate = false;
if (!PBUFFER->lockedByBackend || PBUFFER->hlEvents.backendRelease)
return true;
// lock buffer while DRM/KMS is using it, then release it when page flip happens since DRM/KMS should be done by then
// btw buffer's syncReleaser will take care of signaling release point, so we don't do that here
PBUFFER->lock();
PBUFFER->onBackendRelease([PBUFFER]() { PBUFFER->unlock(); });
return true;
}
void CMonitor::debugLastPresentation(const std::string& message) {
Debug::log(TRACE, "{} (last presentation {} - {} fps)", message, lastPresentationTimer.getMillis(),
lastPresentationTimer.getMillis() > 0 ? 1000.0f / lastPresentationTimer.getMillis() : 0.0f);
}
void CMonitor::onMonitorFrame() {
if ((g_pCompositor->m_pAqBackend->hasSession() && !g_pCompositor->m_pAqBackend->session->active) || !g_pCompositor->m_bSessionActive || g_pCompositor->m_bUnsafeState) {
Debug::log(WARN, "Attempted to render frame on inactive session!");
if (g_pCompositor->m_bUnsafeState && std::ranges::any_of(g_pCompositor->m_vMonitors.begin(), g_pCompositor->m_vMonitors.end(), [&](auto& m) {
return m->output != g_pCompositor->m_pUnsafeOutput->output;
})) {
// restore from unsafe state
g_pCompositor->leaveUnsafeState();
}
return; // cannot draw on session inactive (different tty)
}
if (!m_bEnabled)
return;
g_pHyprRenderer->recheckSolitaryForMonitor(self.lock());
tearingState.busy = false;
if (tearingState.activelyTearing && solitaryClient.lock() /* can be invalidated by a recheck */) {
if (!tearingState.frameScheduledWhileBusy)
return; // we did not schedule a frame yet to be displayed, but we are tearing. Why render?
tearingState.nextRenderTorn = true;
tearingState.frameScheduledWhileBusy = false;
}
static auto PENABLERAT = CConfigValue<Hyprlang::INT>("misc:render_ahead_of_time");
static auto PRATSAFE = CConfigValue<Hyprlang::INT>("misc:render_ahead_safezone");
lastPresentationTimer.reset();
if (*PENABLERAT && !tearingState.nextRenderTorn) {
if (!RATScheduled) {
// render
g_pHyprRenderer->renderMonitor(self.lock());
}
RATScheduled = false;
const auto& [avg, max, min] = g_pHyprRenderer->getRenderTimes(self.lock());
if (max + *PRATSAFE > 1000.0 / refreshRate)
return;
const auto MSLEFT = 1000.0 / refreshRate - lastPresentationTimer.getMillis();
RATScheduled = true;
const auto ESTRENDERTIME = std::ceil(avg + *PRATSAFE);
const auto TIMETOSLEEP = std::floor(MSLEFT - ESTRENDERTIME);
if (MSLEFT < 1 || MSLEFT < ESTRENDERTIME || TIMETOSLEEP < 1)
g_pHyprRenderer->renderMonitor(self.lock());
else
wl_event_source_timer_update(renderTimer, TIMETOSLEEP);
} else
g_pHyprRenderer->renderMonitor(self.lock());
}
void CMonitor::onCursorMovedOnMonitor() {
if (!tearingState.activelyTearing || !solitaryClient || !g_pHyprRenderer->shouldRenderCursor())
return;
// submit a frame immediately. This will only update the cursor pos.
// output->state->setBuffer(output->state->state().buffer);
// output->state->addDamage(CRegion{});
// output->state->setPresentationMode(Aquamarine::eOutputPresentationMode::AQ_OUTPUT_PRESENTATION_IMMEDIATE);
// if (!output->commit())
// Debug::log(ERR, "onCursorMovedOnMonitor: tearing and wanted to update cursor, failed.");
// FIXME: try to do the above. We currently can't just render because drm is a fucking bitch
// and throws a "nO pRoP cAn Be ChAnGeD dUrInG AsYnC fLiP" on crtc_x
// this will throw too but fix it if we use sw cursors
tearingState.frameScheduledWhileBusy = true;
}
CMonitorState::CMonitorState(CMonitor* owner) : m_pOwner(owner) {
;
}
void CMonitorState::ensureBufferPresent() {
const auto STATE = m_pOwner->output->state->state();
if (!STATE.enabled) {
Debug::log(TRACE, "CMonitorState::ensureBufferPresent: Ignoring, monitor is not enabled");
return;
}
if (STATE.buffer) {
if (const auto params = STATE.buffer->dmabuf(); params.success && params.format == m_pOwner->drmFormat)
return;
}
// this is required for modesetting being possible and might be missing in case of first tests in the renderer
// where we test modes and buffers
Debug::log(LOG, "CMonitorState::ensureBufferPresent: no buffer or mismatched format, attaching one from the swapchain for modeset being possible");
m_pOwner->output->state->setBuffer(m_pOwner->output->swapchain->next(nullptr));
m_pOwner->output->swapchain->rollback(); // restore the counter, don't advance the swapchain
}
bool CMonitorState::commit() {
if (!updateSwapchain())
return false;
EMIT_HOOK_EVENT("preMonitorCommit", m_pOwner->self.lock());
ensureBufferPresent();
bool ret = m_pOwner->output->commit();
return ret;
}
bool CMonitorState::test() {
if (!updateSwapchain())
return false;
ensureBufferPresent();
return m_pOwner->output->test();
}
bool CMonitorState::updateSwapchain() {
auto options = m_pOwner->output->swapchain->currentOptions();
const auto& STATE = m_pOwner->output->state->state();
const auto& MODE = STATE.mode ? STATE.mode : STATE.customMode;
if (!MODE) {
Debug::log(WARN, "updateSwapchain: No mode?");
return true;
}
options.format = m_pOwner->drmFormat;
options.scanout = true;
options.length = 2;
options.size = MODE->pixelSize;
return m_pOwner->output->swapchain->reconfigure(options);
}
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