Hyprland/src/managers/PointerManager.cpp

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#include "PointerManager.hpp"
#include "../Compositor.hpp"
#include "../config/ConfigValue.hpp"
#include "../protocols/PointerGestures.hpp"
#include "../protocols/RelativePointer.hpp"
#include "../protocols/FractionalScale.hpp"
#include "../protocols/IdleNotify.hpp"
#include "../protocols/core/Compositor.hpp"
#include "../protocols/core/Seat.hpp"
#include "eventLoop/EventLoopManager.hpp"
2024-05-10 19:27:57 +02:00
#include "SeatManager.hpp"
#include <cstring>
#include <gbm.h>
CPointerManager::CPointerManager() {
hooks.monitorAdded = g_pHookSystem->hookDynamic("monitorAdded", [this](void* self, SCallbackInfo& info, std::any data) {
auto PMONITOR = std::any_cast<PHLMONITOR>(data);
onMonitorLayoutChange();
PMONITOR->events.modeChanged.registerStaticListener([this](void* owner, std::any data) { g_pEventLoopManager->doLater([this]() { onMonitorLayoutChange(); }); }, nullptr);
PMONITOR->events.disconnect.registerStaticListener([this](void* owner, std::any data) { g_pEventLoopManager->doLater([this]() { onMonitorLayoutChange(); }); }, nullptr);
PMONITOR->events.destroy.registerStaticListener(
[this](void* owner, std::any data) {
if (g_pCompositor && !g_pCompositor->m_bIsShuttingDown)
std::erase_if(monitorStates, [](const auto& other) { return other->monitor.expired(); });
},
nullptr);
});
hooks.monitorPreRender = g_pHookSystem->hookDynamic("preMonitorCommit", [this](void* self, SCallbackInfo& info, std::any data) {
auto state = stateFor(std::any_cast<PHLMONITOR>(data));
if (!state)
return;
state->cursorRendered = false;
});
}
void CPointerManager::lockSoftwareAll() {
for (auto const& state : monitorStates)
state->softwareLocks++;
updateCursorBackend();
}
void CPointerManager::unlockSoftwareAll() {
for (auto const& state : monitorStates)
state->softwareLocks--;
updateCursorBackend();
}
void CPointerManager::lockSoftwareForMonitor(PHLMONITOR mon) {
auto const state = stateFor(mon);
state->softwareLocks++;
if (state->softwareLocks == 1)
updateCursorBackend();
}
void CPointerManager::unlockSoftwareForMonitor(PHLMONITOR mon) {
auto const state = stateFor(mon);
state->softwareLocks--;
if (state->softwareLocks < 0)
state->softwareLocks = 0;
if (state->softwareLocks == 0)
updateCursorBackend();
}
bool CPointerManager::softwareLockedFor(PHLMONITOR mon) {
auto const state = stateFor(mon);
return state->softwareLocks > 0 || state->hardwareFailed;
}
Vector2D CPointerManager::position() {
return pointerPos;
}
bool CPointerManager::hasCursor() {
return currentCursorImage.pBuffer || currentCursorImage.surface;
}
SP<CPointerManager::SMonitorPointerState> CPointerManager::stateFor(PHLMONITOR mon) {
auto it = std::find_if(monitorStates.begin(), monitorStates.end(), [mon](const auto& other) { return other->monitor == mon; });
if (it == monitorStates.end())
return monitorStates.emplace_back(makeShared<CPointerManager::SMonitorPointerState>(mon));
return *it;
}
void CPointerManager::setCursorBuffer(SP<Aquamarine::IBuffer> buf, const Vector2D& hotspot, const float& scale) {
damageIfSoftware();
if (buf == currentCursorImage.pBuffer) {
if (hotspot != currentCursorImage.hotspot || scale != currentCursorImage.scale) {
currentCursorImage.hotspot = hotspot;
currentCursorImage.scale = scale;
updateCursorBackend();
damageIfSoftware();
}
return;
}
resetCursorImage(false);
if (buf) {
currentCursorImage.size = buf->size;
currentCursorImage.pBuffer = buf;
}
currentCursorImage.hotspot = hotspot;
currentCursorImage.scale = scale;
updateCursorBackend();
damageIfSoftware();
}
void CPointerManager::setCursorSurface(SP<CWLSurface> surf, const Vector2D& hotspot) {
damageIfSoftware();
if (surf == currentCursorImage.surface) {
if (hotspot != currentCursorImage.hotspot || (surf && surf->resource() ? surf->resource()->current.scale : 1.F) != currentCursorImage.scale) {
currentCursorImage.hotspot = hotspot;
currentCursorImage.scale = surf && surf->resource() ? surf->resource()->current.scale : 1.F;
updateCursorBackend();
damageIfSoftware();
}
return;
}
resetCursorImage(false);
if (surf) {
currentCursorImage.surface = surf;
currentCursorImage.scale = surf->resource()->current.scale;
surf->resource()->map();
currentCursorImage.destroySurface = surf->events.destroy.registerListener([this](std::any data) { resetCursorImage(); });
currentCursorImage.commitSurface = surf->resource()->events.commit.registerListener([this](std::any data) {
damageIfSoftware();
currentCursorImage.size = currentCursorImage.surface->resource()->current.texture ? currentCursorImage.surface->resource()->current.bufferSize : Vector2D{};
currentCursorImage.scale = currentCursorImage.surface ? currentCursorImage.surface->resource()->current.scale : 1.F;
recheckEnteredOutputs();
updateCursorBackend();
damageIfSoftware();
});
if (surf->resource()->current.texture) {
currentCursorImage.size = surf->resource()->current.bufferSize;
timespec now;
clock_gettime(CLOCK_MONOTONIC, &now);
surf->resource()->frame(&now);
}
}
currentCursorImage.hotspot = hotspot;
recheckEnteredOutputs();
updateCursorBackend();
damageIfSoftware();
}
void CPointerManager::recheckEnteredOutputs() {
if (!hasCursor())
return;
auto box = getCursorBoxGlobal();
for (auto const& s : monitorStates) {
if (s->monitor.expired() || s->monitor->isMirror() || !s->monitor->m_bEnabled)
continue;
const bool overlaps = box.overlaps(s->monitor->logicalBox());
if (!s->entered && overlaps) {
s->entered = true;
if (!currentCursorImage.surface)
continue;
currentCursorImage.surface->resource()->enter(s->monitor.lock());
PROTO::fractional->sendScale(currentCursorImage.surface->resource(), s->monitor->scale);
g_pCompositor->setPreferredScaleForSurface(currentCursorImage.surface->resource(), s->monitor->scale);
} else if (s->entered && !overlaps) {
s->entered = false;
// if we are using hw cursors, prevent
// the cursor from being stuck at the last point.
if (!s->hardwareFailed && (s->monitor->output->getBackend()->capabilities() & Aquamarine::IBackendImplementation::eBackendCapabilities::AQ_BACKEND_CAPABILITY_POINTER))
setHWCursorBuffer(s, nullptr);
if (!currentCursorImage.surface)
continue;
currentCursorImage.surface->resource()->leave(s->monitor.lock());
}
}
}
void CPointerManager::resetCursorImage(bool apply) {
damageIfSoftware();
if (currentCursorImage.surface) {
for (auto const& m : g_pCompositor->m_vMonitors) {
currentCursorImage.surface->resource()->leave(m);
}
currentCursorImage.surface->resource()->unmap();
currentCursorImage.destroySurface.reset();
currentCursorImage.commitSurface.reset();
currentCursorImage.surface.reset();
} else if (currentCursorImage.pBuffer)
currentCursorImage.pBuffer = nullptr;
if (currentCursorImage.bufferTex)
currentCursorImage.bufferTex = nullptr;
currentCursorImage.scale = 1.F;
currentCursorImage.hotspot = {0, 0};
for (auto const& s : monitorStates) {
if (s->monitor.expired() || s->monitor->isMirror() || !s->monitor->m_bEnabled)
continue;
s->entered = false;
}
if (!apply)
return;
for (auto const& ms : monitorStates) {
if (!ms->monitor || !ms->monitor->m_bEnabled || !ms->monitor->dpmsStatus) {
Debug::log(TRACE, "Not updating hw cursors: disabled / dpms off display");
continue;
}
if (ms->cursorFrontBuffer) {
if (ms->monitor->output->getBackend()->capabilities() & Aquamarine::IBackendImplementation::eBackendCapabilities::AQ_BACKEND_CAPABILITY_POINTER)
ms->monitor->output->setCursor(nullptr, {});
ms->cursorFrontBuffer = nullptr;
}
}
}
void CPointerManager::updateCursorBackend() {
const auto CURSORBOX = getCursorBoxGlobal();
for (auto const& m : g_pCompositor->m_vMonitors) {
if (!m->m_bEnabled || !m->dpmsStatus) {
Debug::log(TRACE, "Not updating hw cursors: disabled / dpms off display");
continue;
}
auto CROSSES = !m->logicalBox().intersection(CURSORBOX).empty();
auto state = stateFor(m);
if (!CROSSES) {
if (state->cursorFrontBuffer)
setHWCursorBuffer(state, nullptr);
continue;
}
if (state->softwareLocks > 0 || g_pConfigManager->shouldUseSoftwareCursors() || !attemptHardwareCursor(state)) {
Debug::log(TRACE, "Output {} rejected hardware cursors, falling back to sw", m->szName);
state->box = getCursorBoxLogicalForMonitor(state->monitor.lock());
state->hardwareFailed = true;
if (state->hwApplied)
setHWCursorBuffer(state, nullptr);
state->hwApplied = false;
continue;
}
state->hardwareFailed = false;
}
}
void CPointerManager::onCursorMoved() {
if (!hasCursor())
return;
const auto CURSORBOX = getCursorBoxGlobal();
bool recalc = false;
for (auto const& m : g_pCompositor->m_vMonitors) {
auto state = stateFor(m);
state->box = getCursorBoxLogicalForMonitor(state->monitor.lock());
auto CROSSES = !m->logicalBox().intersection(CURSORBOX).empty();
if (!CROSSES && state->cursorFrontBuffer) {
Debug::log(TRACE, "onCursorMoved for output {}: cursor left the viewport, removing it from the backend", m->szName);
setHWCursorBuffer(state, nullptr);
continue;
} else if (CROSSES && !state->cursorFrontBuffer) {
Debug::log(TRACE, "onCursorMoved for output {}: cursor entered the output, but no front buffer, forcing recalc", m->szName);
recalc = true;
}
if (state->hardwareFailed || !state->entered)
continue;
const auto CURSORPOS = getCursorPosForMonitor(m);
m->output->moveCursor(CURSORPOS, m->shouldSkipScheduleFrameOnMouseEvent());
}
if (recalc)
updateCursorBackend();
}
bool CPointerManager::attemptHardwareCursor(SP<CPointerManager::SMonitorPointerState> state) {
auto output = state->monitor->output;
if (!(output->getBackend()->capabilities() & Aquamarine::IBackendImplementation::eBackendCapabilities::AQ_BACKEND_CAPABILITY_POINTER))
return false;
const auto CURSORPOS = getCursorPosForMonitor(state->monitor.lock());
state->monitor->output->moveCursor(CURSORPOS, state->monitor->shouldSkipScheduleFrameOnMouseEvent());
auto texture = getCurrentCursorTexture();
if (!texture) {
Debug::log(TRACE, "[pointer] no texture for hw cursor -> hiding");
setHWCursorBuffer(state, nullptr);
return true;
}
auto buffer = renderHWCursorBuffer(state, texture);
if (!buffer) {
Debug::log(TRACE, "[pointer] hw cursor failed rendering");
setHWCursorBuffer(state, nullptr);
return false;
}
bool success = setHWCursorBuffer(state, buffer);
if (!success) {
Debug::log(TRACE, "[pointer] hw cursor failed applying, hiding");
setHWCursorBuffer(state, nullptr);
return false;
} else
state->hwApplied = true;
return success;
}
bool CPointerManager::setHWCursorBuffer(SP<SMonitorPointerState> state, SP<Aquamarine::IBuffer> buf) {
if (!(state->monitor->output->getBackend()->capabilities() & Aquamarine::IBackendImplementation::eBackendCapabilities::AQ_BACKEND_CAPABILITY_POINTER))
return false;
const auto HOTSPOT = transformedHotspot(state->monitor.lock());
Debug::log(TRACE, "[pointer] hw transformed hotspot for {}: {}", state->monitor->szName, HOTSPOT);
if (!state->monitor->output->setCursor(buf, HOTSPOT))
return false;
state->cursorFrontBuffer = buf;
if (!state->monitor->shouldSkipScheduleFrameOnMouseEvent())
g_pCompositor->scheduleFrameForMonitor(state->monitor.lock(), Aquamarine::IOutput::AQ_SCHEDULE_CURSOR_SHAPE);
return true;
}
SP<Aquamarine::IBuffer> CPointerManager::renderHWCursorBuffer(SP<CPointerManager::SMonitorPointerState> state, SP<CTexture> texture) {
auto maxSize = state->monitor->output->cursorPlaneSize();
auto const& cursorSize = currentCursorImage.size;
static auto PDUMB = CConfigValue<Hyprlang::INT>("cursor:use_cpu_buffer");
if (maxSize == Vector2D{})
return nullptr;
if (maxSize != Vector2D{-1, -1}) {
if (cursorSize.x > maxSize.x || cursorSize.y > maxSize.y) {
Debug::log(TRACE, "hardware cursor too big! {} > {}", currentCursorImage.size, maxSize);
return nullptr;
}
} else
maxSize = cursorSize;
if (!state->monitor->cursorSwapchain || maxSize != state->monitor->cursorSwapchain->currentOptions().size ||
*PDUMB != (state->monitor->cursorSwapchain->getAllocator()->type() != Aquamarine::AQ_ALLOCATOR_TYPE_GBM)) {
if (!state->monitor->cursorSwapchain || *PDUMB != (state->monitor->cursorSwapchain->getAllocator()->type() != Aquamarine::AQ_ALLOCATOR_TYPE_GBM)) {
auto allocator = state->monitor->output->getBackend()->preferredAllocator();
if (*PDUMB) {
for (const auto& a : state->monitor->output->getBackend()->getAllocators()) {
if (a->type() == Aquamarine::AQ_ALLOCATOR_TYPE_DRM_DUMB) {
allocator = a;
break;
}
}
}
state->monitor->cursorSwapchain = Aquamarine::CSwapchain::create(allocator, state->monitor->output->getBackend());
}
auto options = state->monitor->cursorSwapchain->currentOptions();
options.size = maxSize;
options.length = 2;
options.scanout = true;
options.cursor = true;
options.multigpu = state->monitor->output->getBackend()->preferredAllocator()->drmFD() != g_pCompositor->m_iDRMFD;
// We do not set the format (unless shm). If it's unset (DRM_FORMAT_INVALID) then the swapchain will pick for us,
// but if it's set, we don't wanna change it.
if (*PDUMB)
options.format = DRM_FORMAT_ARGB8888;
if (!state->monitor->cursorSwapchain->reconfigure(options)) {
Debug::log(TRACE, "Failed to reconfigure cursor swapchain");
return nullptr;
}
}
// if we already rendered the cursor, revert the swapchain to avoid rendering the cursor over
// the current front buffer
// this flag will be reset in the preRender hook, so when we commit this buffer to KMS
if (state->cursorRendered)
state->monitor->cursorSwapchain->rollback();
state->cursorRendered = true;
auto buf = state->monitor->cursorSwapchain->next(nullptr);
if (!buf) {
Debug::log(TRACE, "Failed to acquire a buffer from the cursor swapchain");
return nullptr;
}
if (*PDUMB) {
// get the texture data if available.
auto texData = texture->dataCopy();
if (texData.empty()) {
if (currentCursorImage.surface && currentCursorImage.surface->resource()->role->role() == SURFACE_ROLE_CURSOR) {
const auto SURFACE = currentCursorImage.surface->resource();
auto& shmBuffer = CCursorSurfaceRole::cursorPixelData(SURFACE);
bool flipRB = false;
if (SURFACE->current.texture) {
Debug::log(TRACE, "Cursor CPU surface: format {}, expecting AR24", FormatUtils::drmFormatName(SURFACE->current.texture->m_iDrmFormat));
if (SURFACE->current.texture->m_iDrmFormat == DRM_FORMAT_ABGR8888) {
Debug::log(TRACE, "Cursor CPU surface format AB24, will flip. WARNING: this will break on big endian!");
flipRB = true;
} else if (SURFACE->current.texture->m_iDrmFormat != DRM_FORMAT_ARGB8888) {
Debug::log(TRACE, "Cursor CPU surface format rejected, falling back to sw");
return nullptr;
}
}
if (shmBuffer.data())
texData = shmBuffer;
else {
texData.resize(texture->m_vSize.x * 4 * texture->m_vSize.y);
memset(texData.data(), 0x00, texData.size());
}
if (flipRB) {
for (size_t i = 0; i < shmBuffer.size(); i += 4) {
std::swap(shmBuffer.at(i), shmBuffer.at(i + 2)); // little-endian!!!!!!
}
}
} else {
Debug::log(TRACE, "Cannot use dumb copy on dmabuf cursor buffers");
return nullptr;
}
}
// then, we just yeet it into the dumb buffer
auto [data, fmt, size] = buf->beginDataPtr(0);
memset(data, 0, size);
if (buf->dmabuf().size.x > texture->m_vSize.x) {
size_t STRIDE = 4 * texture->m_vSize.x;
for (int i = 0; i < texture->m_vSize.y; i++)
memcpy(data + i * buf->dmabuf().strides[0], texData.data() + i * STRIDE, STRIDE);
} else
memcpy(data, texData.data(), std::min(size, texData.size()));
buf->endDataPtr();
return buf;
}
g_pHyprRenderer->makeEGLCurrent();
g_pHyprOpenGL->m_RenderData.pMonitor = state->monitor;
auto RBO = g_pHyprRenderer->getOrCreateRenderbuffer(buf, state->monitor->cursorSwapchain->currentOptions().format);
if (!RBO) {
Debug::log(TRACE, "Failed to create cursor RB with format {}, mod {}", buf->dmabuf().format, buf->dmabuf().modifier);
return nullptr;
}
RBO->bind();
g_pHyprOpenGL->beginSimple(state->monitor.lock(), {0, 0, INT16_MAX, INT16_MAX}, RBO);
g_pHyprOpenGL->clear(CColor{0.F, 0.F, 0.F, 0.F});
CBox xbox = {{}, Vector2D{currentCursorImage.size / currentCursorImage.scale * state->monitor->scale}.round()};
Debug::log(TRACE, "[pointer] monitor: {}, size: {}, hw buf: {}, scale: {:.2f}, monscale: {:.2f}, xbox: {}", state->monitor->szName, currentCursorImage.size, cursorSize,
currentCursorImage.scale, state->monitor->scale, xbox.size());
g_pHyprOpenGL->renderTexture(texture, &xbox, 1.F);
g_pHyprOpenGL->end();
glFlush();
g_pHyprOpenGL->m_RenderData.pMonitor.reset();
g_pHyprRenderer->onRenderbufferDestroy(RBO.get());
return buf;
}
void CPointerManager::renderSoftwareCursorsFor(PHLMONITOR pMonitor, timespec* now, CRegion& damage, std::optional<Vector2D> overridePos) {
if (!hasCursor())
return;
auto state = stateFor(pMonitor);
if ((!state->hardwareFailed && state->softwareLocks == 0)) {
if (currentCursorImage.surface)
currentCursorImage.surface->resource()->frame(now);
return;
}
auto box = state->box.copy();
if (overridePos.has_value()) {
box.x = overridePos->x;
box.y = overridePos->y;
}
if (box.intersection(CBox{{}, {pMonitor->vecSize}}).empty())
return;
auto texture = getCurrentCursorTexture();
if (!texture)
return;
box.scale(pMonitor->scale);
box.x = std::round(box.x);
box.y = std::round(box.y);
g_pHyprOpenGL->renderTextureWithDamage(texture, &box, &damage, 1.F, 0, false, false, currentCursorImage.waitTimeline, currentCursorImage.waitPoint);
if (currentCursorImage.surface)
currentCursorImage.surface->resource()->frame(now);
}
Vector2D CPointerManager::getCursorPosForMonitor(PHLMONITOR pMonitor) {
return CBox{pointerPos - pMonitor->vecPosition, {0, 0}}
.transform(wlTransformToHyprutils(invertTransform(pMonitor->transform)), pMonitor->vecTransformedSize.x / pMonitor->scale,
pMonitor->vecTransformedSize.y / pMonitor->scale)
.pos() *
pMonitor->scale;
}
Vector2D CPointerManager::transformedHotspot(PHLMONITOR pMonitor) {
if (!pMonitor->cursorSwapchain)
return {}; // doesn't matter, we have no hw cursor, and this is only for hw cursors
return CBox{currentCursorImage.hotspot * pMonitor->scale, {0, 0}}
.transform(wlTransformToHyprutils(invertTransform(pMonitor->transform)), pMonitor->cursorSwapchain->currentOptions().size.x,
pMonitor->cursorSwapchain->currentOptions().size.y)
.pos();
}
CBox CPointerManager::getCursorBoxLogicalForMonitor(PHLMONITOR pMonitor) {
return getCursorBoxGlobal().translate(-pMonitor->vecPosition);
}
CBox CPointerManager::getCursorBoxGlobal() {
return CBox{pointerPos, currentCursorImage.size / currentCursorImage.scale}.translate(-currentCursorImage.hotspot);
}
Vector2D CPointerManager::closestValid(const Vector2D& pos) {
static auto PADDING = CConfigValue<Hyprlang::INT>("cursor:hotspot_padding");
auto CURSOR_PADDING = std::clamp((int)*PADDING, 0, 100);
CBox hotBox = {{pos.x - CURSOR_PADDING, pos.y - CURSOR_PADDING}, {2 * CURSOR_PADDING, 2 * CURSOR_PADDING}};
//
static auto INSIDE_LAYOUT = [this](const CBox& box) -> bool {
for (auto const& b : currentMonitorLayout.monitorBoxes) {
if (box.inside(b))
return true;
}
return false;
};
static auto INSIDE_LAYOUT_COORD = [this](const Vector2D& vec) -> bool {
for (auto const& b : currentMonitorLayout.monitorBoxes) {
if (b.containsPoint(vec))
return true;
}
return false;
};
static auto NEAREST_LAYOUT = [this](const Vector2D& vec) -> Vector2D {
Vector2D leader;
float distanceSq = __FLT_MAX__;
for (auto const& b : currentMonitorLayout.monitorBoxes) {
auto p = b.closestPoint(vec);
auto distSq = p.distanceSq(vec);
if (distSq < distanceSq) {
leader = p;
distanceSq = distSq;
}
}
if (distanceSq > 1337.69420e+20F)
return {0, 0}; // ???
return leader;
};
if (INSIDE_LAYOUT(hotBox))
return pos;
Vector2D leader = NEAREST_LAYOUT(pos);
hotBox.x = leader.x - CURSOR_PADDING;
hotBox.y = leader.y - CURSOR_PADDING;
// push the hotbox around so that it fits in the layout
if (!INSIDE_LAYOUT_COORD(hotBox.middle() + Vector2D{CURSOR_PADDING, CURSOR_PADDING})) {
auto delta = NEAREST_LAYOUT(hotBox.middle() + Vector2D{CURSOR_PADDING, CURSOR_PADDING}) - (hotBox.middle() + Vector2D{CURSOR_PADDING, CURSOR_PADDING});
hotBox.translate(delta);
}
if (!INSIDE_LAYOUT_COORD(hotBox.middle() - Vector2D{CURSOR_PADDING, CURSOR_PADDING})) {
auto delta = NEAREST_LAYOUT(hotBox.middle() - Vector2D{CURSOR_PADDING, CURSOR_PADDING}) - (hotBox.middle() - Vector2D{CURSOR_PADDING, CURSOR_PADDING});
hotBox.translate(delta);
}
if (!INSIDE_LAYOUT_COORD(hotBox.middle() + Vector2D{CURSOR_PADDING, -CURSOR_PADDING})) {
auto delta = NEAREST_LAYOUT(hotBox.middle() + Vector2D{CURSOR_PADDING, -CURSOR_PADDING}) - (hotBox.middle() + Vector2D{CURSOR_PADDING, -CURSOR_PADDING});
hotBox.translate(delta);
}
if (!INSIDE_LAYOUT_COORD(hotBox.middle() + Vector2D{-CURSOR_PADDING, CURSOR_PADDING})) {
auto delta = NEAREST_LAYOUT(hotBox.middle() + Vector2D{-CURSOR_PADDING, CURSOR_PADDING}) - (hotBox.middle() + Vector2D{-CURSOR_PADDING, CURSOR_PADDING});
hotBox.translate(delta);
}
return hotBox.middle();
}
void CPointerManager::damageIfSoftware() {
auto b = getCursorBoxGlobal().expand(4);
for (auto const& mw : monitorStates) {
if (mw->monitor.expired() || !mw->monitor->output)
continue;
if ((mw->softwareLocks > 0 || mw->hardwareFailed || g_pConfigManager->shouldUseSoftwareCursors()) && b.overlaps({mw->monitor->vecPosition, mw->monitor->vecSize})) {
g_pHyprRenderer->damageBox(&b, mw->monitor->shouldSkipScheduleFrameOnMouseEvent());
break;
}
}
}
void CPointerManager::warpTo(const Vector2D& logical) {
damageIfSoftware();
pointerPos = closestValid(logical);
if (!g_pInputManager->isLocked()) {
recheckEnteredOutputs();
onCursorMoved();
}
damageIfSoftware();
}
void CPointerManager::move(const Vector2D& deltaLogical) {
const auto oldPos = pointerPos;
auto newPos = oldPos + Vector2D{std::isnan(deltaLogical.x) ? 0.0 : deltaLogical.x, std::isnan(deltaLogical.y) ? 0.0 : deltaLogical.y};
warpTo(newPos);
}
void CPointerManager::warpAbsolute(Vector2D abs, SP<IHID> dev) {
if (!dev)
return;
if (!std::isnan(abs.x))
abs.x = std::clamp(abs.x, 0.0, 1.0);
if (!std::isnan(abs.y))
abs.y = std::clamp(abs.y, 0.0, 1.0);
// find x and y size of the entire space
const auto& MONITORS = g_pCompositor->m_vMonitors;
Vector2D topLeft = MONITORS.at(0)->vecPosition, bottomRight = MONITORS.at(0)->vecPosition + MONITORS.at(0)->vecSize;
for (size_t i = 1; i < MONITORS.size(); ++i) {
const auto EXTENT = MONITORS[i]->logicalBox().extent();
const auto POS = MONITORS[i]->logicalBox().pos();
if (EXTENT.x > bottomRight.x)
bottomRight.x = EXTENT.x;
if (EXTENT.y > bottomRight.y)
bottomRight.y = EXTENT.y;
if (POS.x < topLeft.x)
topLeft.x = POS.x;
if (POS.y < topLeft.y)
topLeft.y = POS.y;
}
CBox mappedArea = {topLeft, bottomRight - topLeft};
auto outputMappedArea = [&mappedArea](const std::string& output) {
if (output == "current") {
if (const auto PLASTMONITOR = g_pCompositor->m_pLastMonitor.lock(); PLASTMONITOR)
return PLASTMONITOR->logicalBox();
} else if (const auto PMONITOR = g_pCompositor->getMonitorFromString(output); PMONITOR)
return PMONITOR->logicalBox();
return mappedArea;
};
switch (dev->getType()) {
case HID_TYPE_TABLET: {
CTablet* TAB = reinterpret_cast<CTablet*>(dev.get());
if (!TAB->boundOutput.empty()) {
mappedArea = outputMappedArea(TAB->boundOutput);
mappedArea.translate(TAB->boundBox.pos());
} else if (TAB->absolutePos) {
mappedArea.x = TAB->boundBox.x;
mappedArea.y = TAB->boundBox.y;
} else
mappedArea.translate(TAB->boundBox.pos());
if (!TAB->boundBox.empty()) {
mappedArea.w = TAB->boundBox.w;
mappedArea.h = TAB->boundBox.h;
}
break;
}
case HID_TYPE_TOUCH: {
ITouch* TOUCH = reinterpret_cast<ITouch*>(dev.get());
if (!TOUCH->boundOutput.empty())
mappedArea = outputMappedArea(TOUCH->boundOutput);
break;
}
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case HID_TYPE_POINTER: {
IPointer* POINTER = reinterpret_cast<IPointer*>(dev.get());
if (!POINTER->boundOutput.empty())
mappedArea = outputMappedArea(POINTER->boundOutput);
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break;
}
default: break;
}
damageIfSoftware();
if (std::isnan(abs.x) || std::isnan(abs.y)) {
pointerPos.x = std::isnan(abs.x) ? pointerPos.x : mappedArea.x + mappedArea.w * abs.x;
pointerPos.y = std::isnan(abs.y) ? pointerPos.y : mappedArea.y + mappedArea.h * abs.y;
} else
pointerPos = mappedArea.pos() + mappedArea.size() * abs;
onCursorMoved();
recheckEnteredOutputs();
damageIfSoftware();
}
void CPointerManager::onMonitorLayoutChange() {
currentMonitorLayout.monitorBoxes.clear();
for (auto const& m : g_pCompositor->m_vMonitors) {
if (m->isMirror() || !m->m_bEnabled || !m->output)
continue;
currentMonitorLayout.monitorBoxes.emplace_back(CBox{m->vecPosition, m->vecSize});
}
damageIfSoftware();
pointerPos = closestValid(pointerPos);
updateCursorBackend();
recheckEnteredOutputs();
damageIfSoftware();
}
SP<CTexture> CPointerManager::getCurrentCursorTexture() {
if (!currentCursorImage.pBuffer && (!currentCursorImage.surface || !currentCursorImage.surface->resource()->current.texture))
return nullptr;
if (currentCursorImage.pBuffer) {
if (!currentCursorImage.bufferTex)
currentCursorImage.bufferTex = makeShared<CTexture>(currentCursorImage.pBuffer, true);
return currentCursorImage.bufferTex;
}
return currentCursorImage.surface->resource()->current.texture;
}
void CPointerManager::attachPointer(SP<IPointer> pointer) {
if (!pointer)
return;
static auto PMOUSEDPMS = CConfigValue<Hyprlang::INT>("misc:mouse_move_enables_dpms");
//
auto listener = pointerListeners.emplace_back(makeShared<SPointerListener>());
listener->pointer = pointer;
// clang-format off
listener->destroy = pointer->events.destroy.registerListener([this] (std::any d) {
detachPointer(nullptr);
});
listener->motion = pointer->pointerEvents.motion.registerListener([this] (std::any e) {
auto E = std::any_cast<IPointer::SMotionEvent>(e);
g_pInputManager->onMouseMoved(E);
PROTO::idle->onActivity();
if (!g_pCompositor->m_bDPMSStateON && *PMOUSEDPMS)
g_pKeybindManager->dpms("on");
});
listener->motionAbsolute = pointer->pointerEvents.motionAbsolute.registerListener([this] (std::any e) {
auto E = std::any_cast<IPointer::SMotionAbsoluteEvent>(e);
g_pInputManager->onMouseWarp(E);
PROTO::idle->onActivity();
if (!g_pCompositor->m_bDPMSStateON && *PMOUSEDPMS)
g_pKeybindManager->dpms("on");
});
listener->button = pointer->pointerEvents.button.registerListener([this] (std::any e) {
auto E = std::any_cast<IPointer::SButtonEvent>(e);
g_pInputManager->onMouseButton(E);
PROTO::idle->onActivity();
});
listener->axis = pointer->pointerEvents.axis.registerListener([this] (std::any e) {
auto E = std::any_cast<IPointer::SAxisEvent>(e);
g_pInputManager->onMouseWheel(E);
PROTO::idle->onActivity();
});
listener->frame = pointer->pointerEvents.frame.registerListener([this] (std::any e) {
bool shouldSkip = false;
if (!g_pSeatManager->mouse.expired() && g_pInputManager->isLocked()) {
auto PMONITOR = g_pCompositor->m_pLastMonitor.get();
shouldSkip = PMONITOR && PMONITOR->shouldSkipScheduleFrameOnMouseEvent();
}
g_pSeatManager->isPointerFrameSkipped = shouldSkip;
if (!g_pSeatManager->isPointerFrameSkipped)
g_pSeatManager->sendPointerFrame();
});
listener->swipeBegin = pointer->pointerEvents.swipeBegin.registerListener([this] (std::any e) {
auto E = std::any_cast<IPointer::SSwipeBeginEvent>(e);
g_pInputManager->onSwipeBegin(E);
PROTO::idle->onActivity();
if (!g_pCompositor->m_bDPMSStateON && *PMOUSEDPMS)
g_pKeybindManager->dpms("on");
});
listener->swipeEnd = pointer->pointerEvents.swipeEnd.registerListener([this] (std::any e) {
auto E = std::any_cast<IPointer::SSwipeEndEvent>(e);
g_pInputManager->onSwipeEnd(E);
PROTO::idle->onActivity();
});
listener->swipeUpdate = pointer->pointerEvents.swipeUpdate.registerListener([this] (std::any e) {
auto E = std::any_cast<IPointer::SSwipeUpdateEvent>(e);
g_pInputManager->onSwipeUpdate(E);
PROTO::idle->onActivity();
});
listener->pinchBegin = pointer->pointerEvents.pinchBegin.registerListener([this] (std::any e) {
auto E = std::any_cast<IPointer::SPinchBeginEvent>(e);
PROTO::pointerGestures->pinchBegin(E.timeMs, E.fingers);
PROTO::idle->onActivity();
if (!g_pCompositor->m_bDPMSStateON && *PMOUSEDPMS)
g_pKeybindManager->dpms("on");
});
listener->pinchEnd = pointer->pointerEvents.pinchEnd.registerListener([this] (std::any e) {
auto E = std::any_cast<IPointer::SPinchEndEvent>(e);
PROTO::pointerGestures->pinchEnd(E.timeMs, E.cancelled);
PROTO::idle->onActivity();
});
listener->pinchUpdate = pointer->pointerEvents.pinchUpdate.registerListener([this] (std::any e) {
auto E = std::any_cast<IPointer::SPinchUpdateEvent>(e);
PROTO::pointerGestures->pinchUpdate(E.timeMs, E.delta, E.scale, E.rotation);
PROTO::idle->onActivity();
});
listener->holdBegin = pointer->pointerEvents.holdBegin.registerListener([this] (std::any e) {
auto E = std::any_cast<IPointer::SHoldBeginEvent>(e);
PROTO::pointerGestures->holdBegin(E.timeMs, E.fingers);
PROTO::idle->onActivity();
});
listener->holdEnd = pointer->pointerEvents.holdEnd.registerListener([this] (std::any e) {
auto E = std::any_cast<IPointer::SHoldEndEvent>(e);
PROTO::pointerGestures->holdEnd(E.timeMs, E.cancelled);
PROTO::idle->onActivity();
});
// clang-format on
Debug::log(LOG, "Attached pointer {} to global", pointer->hlName);
}
void CPointerManager::attachTouch(SP<ITouch> touch) {
if (!touch)
return;
static auto PMOUSEDPMS = CConfigValue<Hyprlang::INT>("misc:mouse_move_enables_dpms");
//
auto listener = touchListeners.emplace_back(makeShared<STouchListener>());
listener->touch = touch;
// clang-format off
listener->destroy = touch->events.destroy.registerListener([this] (std::any d) {
detachTouch(nullptr);
});
listener->down = touch->touchEvents.down.registerListener([this] (std::any e) {
auto E = std::any_cast<ITouch::SDownEvent>(e);
g_pInputManager->onTouchDown(E);
PROTO::idle->onActivity();
if (!g_pCompositor->m_bDPMSStateON && *PMOUSEDPMS)
g_pKeybindManager->dpms("on");
});
listener->up = touch->touchEvents.up.registerListener([this] (std::any e) {
auto E = std::any_cast<ITouch::SUpEvent>(e);
g_pInputManager->onTouchUp(E);
PROTO::idle->onActivity();
});
listener->motion = touch->touchEvents.motion.registerListener([this] (std::any e) {
auto E = std::any_cast<ITouch::SMotionEvent>(e);
g_pInputManager->onTouchMove(E);
PROTO::idle->onActivity();
});
listener->cancel = touch->touchEvents.cancel.registerListener([this] (std::any e) {
//
});
listener->frame = touch->touchEvents.frame.registerListener([this] (std::any e) {
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g_pSeatManager->sendTouchFrame();
});
// clang-format on
Debug::log(LOG, "Attached touch {} to global", touch->hlName);
}
void CPointerManager::attachTablet(SP<CTablet> tablet) {
if (!tablet)
return;
static auto PMOUSEDPMS = CConfigValue<Hyprlang::INT>("misc:mouse_move_enables_dpms");
//
auto listener = tabletListeners.emplace_back(makeShared<STabletListener>());
listener->tablet = tablet;
// clang-format off
listener->destroy = tablet->events.destroy.registerListener([this] (std::any d) {
detachTablet(nullptr);
});
listener->axis = tablet->tabletEvents.axis.registerListener([this] (std::any e) {
auto E = std::any_cast<CTablet::SAxisEvent>(e);
g_pInputManager->onTabletAxis(E);
PROTO::idle->onActivity();
if (!g_pCompositor->m_bDPMSStateON && *PMOUSEDPMS)
g_pKeybindManager->dpms("on");
});
listener->proximity = tablet->tabletEvents.proximity.registerListener([this] (std::any e) {
auto E = std::any_cast<CTablet::SProximityEvent>(e);
g_pInputManager->onTabletProximity(E);
PROTO::idle->onActivity();
});
listener->tip = tablet->tabletEvents.tip.registerListener([this] (std::any e) {
auto E = std::any_cast<CTablet::STipEvent>(e);
g_pInputManager->onTabletTip(E);
PROTO::idle->onActivity();
if (!g_pCompositor->m_bDPMSStateON && *PMOUSEDPMS)
g_pKeybindManager->dpms("on");
});
listener->button = tablet->tabletEvents.button.registerListener([this] (std::any e) {
auto E = std::any_cast<CTablet::SButtonEvent>(e);
g_pInputManager->onTabletButton(E);
PROTO::idle->onActivity();
});
// clang-format on
Debug::log(LOG, "Attached tablet {} to global", tablet->hlName);
}
void CPointerManager::detachPointer(SP<IPointer> pointer) {
std::erase_if(pointerListeners, [pointer](const auto& e) { return e->pointer.expired() || e->pointer == pointer; });
}
void CPointerManager::detachTouch(SP<ITouch> touch) {
std::erase_if(touchListeners, [touch](const auto& e) { return e->touch.expired() || e->touch == touch; });
}
void CPointerManager::detachTablet(SP<CTablet> tablet) {
std::erase_if(tabletListeners, [tablet](const auto& e) { return e->tablet.expired() || e->tablet == tablet; });
}
void CPointerManager::damageCursor(PHLMONITOR pMonitor) {
for (auto const& mw : monitorStates) {
if (mw->monitor != pMonitor)
continue;
auto b = getCursorBoxGlobal().intersection(pMonitor->logicalBox());
if (b.empty())
return;
g_pHyprRenderer->damageBox(&b);
return;
}
}
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Vector2D CPointerManager::cursorSizeLogical() {
return currentCursorImage.size / currentCursorImage.scale;
}
void CPointerManager::storeMovement(uint64_t time, const Vector2D& delta, const Vector2D& deltaUnaccel) {
storedTime = time;
storedDelta += delta;
storedUnaccel += deltaUnaccel;
}
void CPointerManager::setStoredMovement(uint64_t time, const Vector2D& delta, const Vector2D& deltaUnaccel) {
storedTime = time;
storedDelta = delta;
storedUnaccel = deltaUnaccel;
}
void CPointerManager::sendStoredMovement() {
PROTO::relativePointer->sendRelativeMotion((uint64_t)storedTime * 1000, storedDelta, storedUnaccel);
storedTime = 0;
storedDelta = Vector2D{};
storedUnaccel = Vector2D{};
}