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koreader/frontend/ui/uimanager.lua
NiLuJe e7acec1526 ReaderUI: Saner FM/RD lifecycle 
* Ensure that going from one to the other tears down the former and
    its plugins before instantiating the latter and its plugins.

UIManager: Unify Event sending & broadcasting
  * Make the two behave the same way (walk the widget stack from top to
    bottom), and properly handle the window stack shrinking shrinking
    *and* growing.
    Previously, broadcasting happened bottom-to-top and didn't really
    handle the list shrinking/growing, while sending only handled the list
    shrinking by a single element, and hopefully that element being the one
    the event was just sent to.

These two items combined allowed us to optimize suboptimal
refresh behavior with Menu and other Menu classes when
opening/closing a document.
e.g., the "opening document" Notification is now properly regional,
and the "open last doc" option no longer flashes like a crazy person
anymore.

Plugins: Allow optimizing Menu refresh with custom menus, too.

Requires moving Menu's close_callback *after* onMenuSelect, which, eh,
probably makes sense, and is probably harmless in the grand scheme of
things.
2021-05-05 20:37:33 +02:00

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--[[--
This module manages widgets.
]]
local Device = require("device")
local Event = require("ui/event")
local Geom = require("ui/geometry")
local TimeVal = require("ui/timeval")
local dbg = require("dbg")
local logger = require("logger")
local ffiUtil = require("ffi/util")
local util = require("util")
local _ = require("gettext")
local Input = Device.input
local Screen = Device.screen
local DEFAULT_FULL_REFRESH_COUNT = 6
-- there is only one instance of this
local UIManager = {
-- trigger a full refresh when counter reaches FULL_REFRESH_COUNT
FULL_REFRESH_COUNT =
G_reader_settings:isTrue("night_mode") and G_reader_settings:readSetting("night_full_refresh_count") or G_reader_settings:readSetting("full_refresh_count") or DEFAULT_FULL_REFRESH_COUNT,
refresh_count = 0,
-- How long to wait between ZMQ wakeups: 50ms.
ZMQ_TIMEOUT = 50 * 1000,
event_handlers = nil,
_running = true,
_now = TimeVal:now(),
_window_stack = {},
_task_queue = {},
_task_queue_dirty = false,
_dirty = {},
_zeromqs = {},
_refresh_stack = {},
_refresh_func_stack = {},
_entered_poweroff_stage = false,
_exit_code = nil,
_prevent_standby_count = 0,
_prev_prevent_standby_count = 0,
_discard_events_till = nil,
event_hook = require("ui/hook_container"):new()
}
function UIManager:init()
self.event_handlers = {
__default__ = function(input_event)
self:sendEvent(input_event)
end,
SaveState = function()
self:flushSettings()
end,
Power = function(input_event)
Device:onPowerEvent(input_event)
end,
}
self.poweroff_action = function()
self._entered_poweroff_stage = true
Device.orig_rotation_mode = Device.screen:getRotationMode()
Screen:setRotationMode(Screen.ORIENTATION_PORTRAIT)
local Screensaver = require("ui/screensaver")
Screensaver:setup("poweroff", _("Powered off"))
if Device:hasEinkScreen() and Screensaver:modeIsImage() then
if Screensaver:withBackground() then
Screen:clear()
end
Screen:refreshFull()
end
Screensaver:show()
if Device:needsScreenRefreshAfterResume() then
Screen:refreshFull()
end
UIManager:nextTick(function()
Device:saveSettings()
if Device:isKobo() then
self._exit_code = 88
end
self:broadcastEvent(Event:new("Close"))
Device:powerOff()
end)
end
self.reboot_action = function()
self._entered_poweroff_stage = true
Device.orig_rotation_mode = Device.screen:getRotationMode()
Screen:setRotationMode(Screen.ORIENTATION_PORTRAIT)
local Screensaver = require("ui/screensaver")
Screensaver:setup("reboot", _("Rebooting…"))
if Device:hasEinkScreen() and Screensaver:modeIsImage() then
if Screensaver:withBackground() then
Screen:clear()
end
Screen:refreshFull()
end
Screensaver:show()
if Device:needsScreenRefreshAfterResume() then
Screen:refreshFull()
end
UIManager:nextTick(function()
Device:saveSettings()
if Device:isKobo() then
self._exit_code = 88
end
self:broadcastEvent(Event:new("Close"))
Device:reboot()
end)
end
if Device:isPocketBook() then
-- Only fg/bg state plugin notifiers, not real power event.
self.event_handlers["Suspend"] = function()
self:_beforeSuspend()
end
self.event_handlers["Resume"] = function()
self:_afterResume()
end
end
if Device:isKobo() then
-- We do not want auto suspend procedure to waste battery during
-- suspend. So let's unschedule it when suspending, and restart it after
-- resume. Done via the plugin's onSuspend/onResume handlers.
self.event_handlers["Suspend"] = function()
-- Ignore the accelerometer (if that's not already the case) while we're alseep
if G_reader_settings:nilOrFalse("input_ignore_gsensor") then
Device:toggleGSensor(false)
end
self:_beforeSuspend()
Device:onPowerEvent("Suspend")
end
self.event_handlers["Resume"] = function()
Device:onPowerEvent("Resume")
self:_afterResume()
-- Stop ignoring the accelerometer (unless requested) when we wakeup
if G_reader_settings:nilOrFalse("input_ignore_gsensor") then
Device:toggleGSensor(true)
end
end
self.event_handlers["PowerPress"] = function()
-- Always schedule power off.
-- Press the power button for 2+ seconds to shutdown directly from suspend.
UIManager:scheduleIn(2, self.poweroff_action)
end
self.event_handlers["PowerRelease"] = function()
if not self._entered_poweroff_stage then
UIManager:unschedule(self.poweroff_action)
-- resume if we were suspended
if Device.screen_saver_mode then
self:resume()
else
self:suspend()
end
end
end
-- Sleep Cover handling
if G_reader_settings:isTrue("ignore_power_sleepcover") then
-- NOTE: The hardware event itself will wake the kernel up if it's in suspend (:/).
-- Let the unexpected wakeup guard handle that.
self.event_handlers["SleepCoverClosed"] = nil
self.event_handlers["SleepCoverOpened"] = nil
elseif G_reader_settings:isTrue("ignore_open_sleepcover") then
-- Just ignore wakeup events, and do NOT set is_cover_closed,
-- so device/generic/device will let us use the power button to wake ;).
self.event_handlers["SleepCoverClosed"] = function()
self:suspend()
end
self.event_handlers["SleepCoverOpened"] = function()
Device.is_cover_closed = false
end
else
self.event_handlers["SleepCoverClosed"] = function()
Device.is_cover_closed = true
self:suspend()
end
self.event_handlers["SleepCoverOpened"] = function()
Device.is_cover_closed = false
self:resume()
end
end
self.event_handlers["Light"] = function()
Device:getPowerDevice():toggleFrontlight()
end
self.event_handlers["Charging"] = function()
self:_beforeCharging()
-- NOTE: Plug/unplug events will wake the device up, which is why we put it back to sleep.
if Device.screen_saver_mode then
self:suspend()
end
end
self.event_handlers["NotCharging"] = function()
-- We need to put the device into suspension, other things need to be done before it.
self:_afterNotCharging()
if Device.screen_saver_mode then
self:suspend()
end
end
self.event_handlers["UsbPlugIn"] = function()
self:_beforeCharging()
-- NOTE: Plug/unplug events will wake the device up, which is why we put it back to sleep.
if Device.screen_saver_mode then
self:suspend()
else
-- Potentially start an USBMS session
local MassStorage = require("ui/elements/mass_storage")
MassStorage:start()
end
end
self.event_handlers["UsbPlugOut"] = function()
-- We need to put the device into suspension, other things need to be done before it.
self:_afterNotCharging()
if Device.screen_saver_mode then
self:suspend()
end
end
self.event_handlers["__default__"] = function(input_event)
-- Suspension in Kobo can be interrupted by screen updates. We ignore user touch input
-- in screen_saver_mode so screen updates won't be triggered in suspend mode.
-- We should not call self:suspend() in screen_saver_mode lest we stay on forever
-- trying to reschedule suspend. Other systems take care of unintended wake-up.
if not Device.screen_saver_mode then
self:sendEvent(input_event)
end
end
elseif Device:isKindle() then
self.event_handlers["IntoSS"] = function()
self:_beforeSuspend()
Device:intoScreenSaver()
end
self.event_handlers["OutOfSS"] = function()
Device:outofScreenSaver()
self:_afterResume();
end
self.event_handlers["Charging"] = function()
self:_beforeCharging()
Device:usbPlugIn()
end
self.event_handlers["NotCharging"] = function()
Device:usbPlugOut()
self:_afterNotCharging()
end
elseif Device:isRemarkable() then
self.event_handlers["Suspend"] = function()
self:_beforeSuspend()
Device:onPowerEvent("Suspend")
end
self.event_handlers["Resume"] = function()
Device:onPowerEvent("Resume")
self:_afterResume()
end
self.event_handlers["PowerPress"] = function()
UIManager:scheduleIn(2, self.poweroff_action)
end
self.event_handlers["PowerRelease"] = function()
if not self._entered_poweroff_stage then
UIManager:unschedule(self.poweroff_action)
-- resume if we were suspended
if Device.screen_saver_mode then
self:resume()
else
self:suspend()
end
end
end
self.event_handlers["__default__"] = function(input_event)
-- Same as in Kobo: we want to ignore keys during suspension
if not Device.screen_saver_mode then
self:sendEvent(input_event)
end
end
elseif Device:isSonyPRSTUX() then
self.event_handlers["PowerPress"] = function()
UIManager:scheduleIn(2, self.poweroff_action)
end
self.event_handlers["PowerRelease"] = function()
if not self._entered_poweroff_stage then
UIManager:unschedule(self.poweroff_action)
-- resume if we were suspended
if Device.screen_saver_mode then
self:resume()
else
self:suspend()
end
end
end
self.event_handlers["Suspend"] = function()
self:_beforeSuspend()
Device:intoScreenSaver()
Device:suspend()
end
self.event_handlers["Resume"] = function()
Device:resume()
Device:outofScreenSaver()
self:_afterResume()
end
self.event_handlers["Charging"] = function()
self:_beforeCharging()
end
self.event_handlers["NotCharging"] = function()
self:_afterNotCharging()
end
self.event_handlers["UsbPlugIn"] = function()
if Device.screen_saver_mode then
Device:resume()
Device:outofScreenSaver()
self:_afterResume()
end
Device:usbPlugIn()
end
self.event_handlers["UsbPlugOut"] = function()
Device:usbPlugOut()
end
self.event_handlers["__default__"] = function(input_event)
-- Same as in Kobo: we want to ignore keys during suspension
if not Device.screen_saver_mode then
self:sendEvent(input_event)
end
end
elseif Device:isCervantes() then
self.event_handlers["Suspend"] = function()
self:_beforeSuspend()
Device:onPowerEvent("Suspend")
end
self.event_handlers["Resume"] = function()
Device:onPowerEvent("Resume")
self:_afterResume()
end
self.event_handlers["PowerPress"] = function()
UIManager:scheduleIn(2, self.poweroff_action)
end
self.event_handlers["PowerRelease"] = function()
if not self._entered_poweroff_stage then
UIManager:unschedule(self.poweroff_action)
-- resume if we were suspended
if Device.screen_saver_mode then
self:resume()
else
self:suspend()
end
end
end
self.event_handlers["Charging"] = function()
self:_beforeCharging()
if Device.screen_saver_mode then
self:suspend()
end
end
self.event_handlers["NotCharging"] = function()
self:_afterNotCharging()
if Device.screen_saver_mode then
self:suspend()
end
end
self.event_handlers["UsbPlugIn"] = function()
self:_beforeCharging()
if Device.screen_saver_mode then
self:suspend()
else
-- Potentially start an USBMS session
local MassStorage = require("ui/elements/mass_storage")
MassStorage:start()
end
end
self.event_handlers["UsbPlugOut"] = function()
self:_afterNotCharging()
if Device.screen_saver_mode then
self:suspend()
end
end
self.event_handlers["__default__"] = function(input_event)
-- Same as in Kobo: we want to ignore keys during suspension
if not Device.screen_saver_mode then
self:sendEvent(input_event)
end
end
elseif Device:isSDL() then
self.event_handlers["Suspend"] = function()
self:_beforeSuspend()
Device:simulateSuspend()
end
self.event_handlers["Resume"] = function()
Device:simulateResume()
self:_afterResume()
end
end
end
--[[--
Registers and shows a widget.
Widgets are registered in a stack, from bottom to top in registration order,
with a few tweaks to handle modals & toasts:
toast widgets are stacked together on top,
then modal widgets are stacked together, and finally come standard widgets.
If you think about how painting will be handled (also bottom to top), this makes perfect sense ;).
For more details about refreshtype, refreshregion & refreshdither see the description of `setDirty`.
If refreshtype is omitted, no refresh will be enqueued at this time.
@param widget a @{ui.widget.widget|widget} object
@string refreshtype `"full"`, `"flashpartial"`, `"flashui"`, `"partial"`, `"ui"`, `"fast"` (optional)
@param refreshregion a rectangle @{ui.geometry.Geom|Geom} object (optional, requires refreshtype to be set)
@int x horizontal screen offset (optional, `0` if omitted)
@int y vertical screen offset (optional, `0` if omitted)
@bool refreshdither `true` if widget requires dithering (optional, requires refreshtype to be set)
@see setDirty
]]
function UIManager:show(widget, refreshtype, refreshregion, x, y, refreshdither)
if not widget then
logger.dbg("widget not exist to be shown")
return
end
logger.dbg("show widget:", widget.id or widget.name or tostring(widget))
self._running = true
local window = {x = x or 0, y = y or 0, widget = widget}
-- put this window on top of the topmost non-modal window
for i = #self._window_stack, 0, -1 do
local top_window = self._window_stack[i]
-- toasts are stacked on top of other toasts,
-- then come modals, and then other widgets
if top_window and top_window.widget.toast then
if widget.toast then
table.insert(self._window_stack, i + 1, window)
break
end
elseif widget.modal or not top_window or not top_window.widget.modal then
table.insert(self._window_stack, i + 1, window)
break
end
end
-- and schedule it to be painted
self:setDirty(widget, refreshtype, refreshregion, refreshdither)
-- tell the widget that it is shown now
widget:handleEvent(Event:new("Show"))
-- check if this widget disables double tap gesture
if widget.disable_double_tap == false then
Input.disable_double_tap = false
else
Input.disable_double_tap = true
end
-- a widget may override tap interval (when it doesn't, nil restores the default)
Input.tap_interval_override = widget.tap_interval_override
end
--[[--
Unregisters a widget.
It will be removed from the stack.
Will flag uncovered widgets as dirty.
For more details about refreshtype, refreshregion & refreshdither see the description of `setDirty`.
If refreshtype is omitted, no extra refresh will be enqueued at this time, leaving only those from the uncovered widgets.
@param widget a @{ui.widget.widget|widget} object
@string refreshtype `"full"`, `"flashpartial"`, `"flashui"`, `"partial"`, `"ui"`, `"fast"` (optional)
@param refreshregion a rectangle @{ui.geometry.Geom|Geom} object (optional, requires refreshtype to be set)
@bool refreshdither `true` if the refresh requires dithering (optional, requires refreshtype to be set)
@see setDirty
]]
function UIManager:close(widget, refreshtype, refreshregion, refreshdither)
if not widget then
logger.dbg("widget to be closed does not exist")
return
end
logger.dbg("close widget:", widget.name or widget.id or tostring(widget))
local dirty = false
-- Ensure all the widgets can get onFlushSettings event.
widget:handleEvent(Event:new("FlushSettings"))
-- first send close event to widget
widget:handleEvent(Event:new("CloseWidget"))
-- make it disabled by default and check if any widget wants it disabled or enabled
Input.disable_double_tap = true
local requested_disable_double_tap = nil
local is_covered = false
local start_idx = 1
-- then remove all references to that widget on stack and refresh
for i = #self._window_stack, 1, -1 do
if self._window_stack[i].widget == widget then
self._dirty[self._window_stack[i].widget] = nil
table.remove(self._window_stack, i)
dirty = true
else
-- If anything else on the stack not already hidden by (i.e., below) a fullscreen widget was dithered, honor the hint
if self._window_stack[i].widget.dithered and not is_covered then
refreshdither = true
logger.dbg("Lower widget", self._window_stack[i].widget.name or self._window_stack[i].widget.id or tostring(self._window_stack[i].widget), "was dithered, honoring the dithering hint")
end
-- Remember the uppermost widget that covers the full screen, so we don't bother calling setDirty on hidden (i.e., lower) widgets in the following dirty loop.
-- _repaint already does that later on to skip the actual paintTo calls, so this ensures we limit the refresh queue to stuff that will actually get painted.
if not is_covered and self._window_stack[i].widget.covers_fullscreen then
is_covered = true
start_idx = i
logger.dbg("Lower widget", self._window_stack[i].widget.name or self._window_stack[i].widget.id or tostring(self._window_stack[i].widget), "covers the full screen")
if i > 1 then
logger.dbg("not refreshing", i-1, "covered widget(s)")
end
end
-- Set double tap to how the topmost specifying widget wants it
if requested_disable_double_tap == nil and self._window_stack[i].widget.disable_double_tap ~= nil then
requested_disable_double_tap = self._window_stack[i].widget.disable_double_tap
end
end
end
if requested_disable_double_tap ~= nil then
Input.disable_double_tap = requested_disable_double_tap
end
if #self._window_stack > 0 then
-- set tap interval override to what the topmost widget specifies (when it doesn't, nil restores the default)
Input.tap_interval_override = self._window_stack[#self._window_stack].widget.tap_interval_override
end
if dirty and not widget.invisible then
-- schedule the remaining visible (i.e., uncovered) widgets to be painted
for i = start_idx, #self._window_stack do
self:setDirty(self._window_stack[i].widget)
end
self:_refresh(refreshtype, refreshregion, refreshdither)
end
end
-- schedule an execution task, task queue is in ascendant order
function UIManager:schedule(time, action, ...)
local p, s, e = 1, 1, #self._task_queue
if e ~= 0 then
-- do a binary insert
repeat
p = math.floor(s + (e - s) / 2)
local p_time = self._task_queue[p].time
if time > p_time then
if s == e then
p = e + 1
break
elseif s + 1 == e then
s = e
else
s = p
end
elseif time < p_time then
e = p
if s == e then
break
end
else
-- for fairness, it's better to make p+1 is strictly less than
-- p might want to revisit here in the future
break
end
until e < s
end
table.insert(self._task_queue, p, {
time = time,
action = action,
argc = select('#', ...),
args = {...},
})
self._task_queue_dirty = true
end
dbg:guard(UIManager, 'schedule',
function(self, time, action)
assert(time.sec >= 0, "Only positive time allowed")
assert(action ~= nil)
end)
--[[--
Schedules a task to be run a certain amount of seconds from now.
@number seconds scheduling delay in seconds (supports decimal values, 1ms resolution).
@func action reference to the task to be scheduled (may be anonymous)
@param ... optional arguments passed to action
@see unschedule
]]
function UIManager:scheduleIn(seconds, action, ...)
-- We might run significantly late inside an UI frame, so we can't use the cached value here.
-- It would also cause some bad interactions with the way nextTick & co behave.
local when = TimeVal:now() + TimeVal:fromnumber(seconds)
self:schedule(when, action, ...)
end
dbg:guard(UIManager, 'scheduleIn',
function(self, seconds, action)
assert(seconds >= 0, "Only positive seconds allowed")
end)
--[[--
Schedules a task for the next UI tick.
@func action reference to the task to be scheduled (may be anonymous)
@param ... optional arguments passed to action
@see scheduleIn
]]
function UIManager:nextTick(action, ...)
return self:scheduleIn(0, action, ...)
end
--[[--
Schedules a task to be run two UI ticks from now.
Useful to run UI callbacks ASAP without skipping repaints.
@func action reference to the task to be scheduled (may be anonymous)
@param ... optional arguments passed to action
@see nextTick
]]
function UIManager:tickAfterNext(action, ...)
-- Storing varargs is a bit iffy as we don't build LuaJIT w/ 5.2 compat, so we don't have access to table.pack...
-- c.f., http://lua-users.org/wiki/VarargTheSecondClassCitizen
local n = select('#', ...)
local va = {...}
return self:nextTick(function() self:nextTick(action, unpack(va, 1, n)) end)
end
--[[
-- NOTE: This appears to work *nearly* just as well, but does sometimes go too fast (might depend on kernel HZ & NO_HZ settings?)
function UIManager:tickAfterNext(action)
return self:scheduleIn(0.001, action)
end
--]]
--[[--
Unschedules a previously scheduled task.
In order to unschedule anonymous functions, store a reference.
@func action
@see scheduleIn
@usage
self.anonymousFunction = function() self:regularFunction() end
UIManager:scheduleIn(10.5, self.anonymousFunction)
UIManager:unschedule(self.anonymousFunction)
]]
function UIManager:unschedule(action)
local removed = false
for i = #self._task_queue, 1, -1 do
if self._task_queue[i].action == action then
table.remove(self._task_queue, i)
removed = true
end
end
return removed
end
dbg:guard(UIManager, 'unschedule',
function(self, action) assert(action ~= nil) end)
--[[--
Mark a window-level widget as dirty, enqueuing a repaint & refresh request for that widget, to be processed on the next UI tick.
The second parameter (refreshtype) can either specify a refreshtype
(optionally in combination with a refreshregion - which is suggested,
and an even more optional refreshdither flag if the content requires dithering);
or a function that returns a refreshtype, refreshregion tuple (or a refreshtype, refreshregion, refreshdither triple),
which will be called *after* painting the widget.
This is an interesting distinction, because a widget's geometry,
usually stored in a field named `dimen`, is (generally) only computed at painting time (e.g., during `paintTo`).
The TL;DR being: if you already know the region, you can pass everything by value directly,
(it'll make for slightly more readable debug logs),
but if the region will only be known after the widget has been painted, pass a function.
Note that, technically, it means that stuff passed by value will be enqueued earlier in the refresh stack.
In practice, since the stack of (both types of) refreshes is optimized into as few actual refresh ioctls as possible,
and that during the next `_repaint` tick (which is when `paintTo` for dirty widgets happens),
this shouldn't change much in the grand scheme of things, but it ought to be noted ;).
See `_repaint` for more details about how the repaint & refresh queues are processed,
and `handleInput` for more details about when those queues are actually drained.
What you should essentially remember is that `setDirty` doesn't actually "do" anything visible on its own.
It doesn't block, and when it returns, nothing new has actually been painted or refreshed.
It just appends stuff to the paint and/or refresh queues.
Here's a quick rundown of what each refreshtype should be used for:
* `full`: high-fidelity flashing refresh (e.g., large images).
Highest quality, but highest latency.
Don't abuse if you only want a flash (in this case, prefer `flashui` or `flashpartial`).
* `partial`: medium fidelity refresh (e.g., text on a white background).
Can be promoted to flashing after `FULL_REFRESH_COUNT` refreshes.
Don't abuse to avoid spurious flashes.
In practice, this means this should mostly always be limited to ReaderUI.
* `ui`: medium fidelity refresh (e.g., mixed content).
Should apply to most UI elements.
When in doubt, use this.
* `fast`: low fidelity refresh (e.g., monochrome content).
Should apply to most highlighting effects achieved through inversion.
Note that if your highlighted element contains text,
you might want to keep the unhighlight refresh as `"ui"` instead, for crisper text.
(Or optimize that refresh away entirely, if you can get away with it).
* `flashui`: like `ui`, but flashing.
Can be used when showing a UI element for the first time, or when closing one, to avoid ghosting.
* `flashpartial`: like `partial`, but flashing (and not counting towards flashing promotions).
Can be used when closing an UI element (usually over ReaderUI), to avoid ghosting.
You can even drop the region in these cases, to ensure a fullscreen flash.
NOTE: On REAGL devices, `flashpartial` will NOT actually flash (by design).
As such, even onCloseWidget, you might prefer `flashui` in most instances.
NOTE: You'll notice a trend on UI elements that are usually shown *over* some kind of text (generally ReaderUI)
of using `"ui"` onShow & onUpdate, but `"partial"` onCloseWidget.
This is by design: `"partial"` is what the reader (ReaderUI) uses, as it's tailor-made for pure text
over a white background, so this ensures we resume the usual flow of the reader.
The same dynamic is true for their flashing counterparts, in the rare instances we enforce flashes.
Any kind of `"partial"` refresh *will* count towards a flashing promotion after `FULL_REFRESH_COUNT` refreshes,
so making sure your stuff only applies to the proper region is key to avoiding spurious large black flashes.
That said, depending on your use case, using `"ui"` onCloseWidget can be a perfectly valid decision,
and will ensure never seeing a flash because of that widget.
Remember that the FM uses `"ui"`, so, if said widgets are shown over the FM,
prefer using `"ui"` or `"flashui"` onCloseWidget.
The final parameter (refreshdither) is an optional hint for devices with hardware dithering support that this repaint
could benefit from dithering (e.g., because it contains an image).
As far as the actual lifecycle of a widget goes, the rules are:
* What you `show`, you `close`.
* If you know the dimensions of the widget (or simply of the region you want to refresh), you can pass it directly:
* to `show` (as `show` calls `setDirty`),
* to `close` (as `close` will also call `setDirty` on the remaining dirty and visible widgets,
and will also enqueue a refresh based on that if there are dirty widgets).
* Otherwise, you can use, respectively, a widget's `Show` & `CloseWidget` handlers for that via `setDirty` calls.
This can also be useful if *child* widgets have specific needs (e.g., flashing, dithering) that they want to inject in the refresh queue.
* Remember that events propagate children first (in array order, starting at the top), and that if *any* event handler returns true,
the propagation of that specific event for this widget tree stops *immediately*.
(This generally means that, unless you know what you're doing (e.g., a widget that will *always* be used as a parent),
you generally *don't* want to return true in `Show` or `CloseWidget` handlers).
* If any widget requires freeing non-Lua resources (e.g., FFI/C), having a `free` method called from its `CloseWidget` handler is ideal:
this'll ensure that *any* widget including it will be sure that resources are freed when it (or its parent) are closed.
* Note that there *is* a `Close` event, but it has very specific use-cases, generally involving *programmatically* `close`ing a `show`n widget:
* It is broadcast (e.g., sent to every widget in the window stack; the same rules about propagation apply, but only per *window-level widget*)
at poweroff/reboot.
* It can also be used as a keypress handler by @{ui.widget.container.inputcontainer|InputContainer}, generally bound to the Back key.
Please refrain from implementing custom `onClose` methods if that's not their intended purpose ;).
On the subject of widgets and child widgets,
you might have noticed an unspoken convention across the codebase of widgets having a field called `show_parent`.
Since handling this is entirely at the programmer's behest, here's how we usually use it:
Basically, we cascade a field named `show_parent` to every child widget that matter
(e.g., those that serve an UI purpose, as opposed to, say, a container).
This ensures that every subwidget can reference its actual parent
(ideally, all the way to the window-level widget it belongs to, i.e., the one that was passed to `show`, hence the name ;)),
to, among other things, flag the right widget for repaint via `setDirty` (c.f., those pesky debug warnings when that's done wrong ;p) when they want to request a repaint.
This is why you often see stuff doing, when instantiating a new widget, `FancyWidget:new{ show_parent = self.show_parent or self }`;
meaning, if I'm already a subwidget, cascade my parent, otherwise, it means I'm a window-level widget, so cascade myself as that widget's parent ;).
Another convention (that a few things rely on) is naming a (persistent) MovableContainer wrapping a full widget `movable`, accessible as an instance field.
This is useful when it's used for transparency purposes, which, e.g., `setDirty` and @{ui.widget.button|Button} rely on to handle updating translucent widgets properly,
by checking if self.show_parent.movable exists and is currently translucent ;).
When I mentioned passing the *right* widget to `setDirty` earlier, what I meant is that `setDirty` will only actually flag a widget for repaint
*if* that widget is a window-level widget (that is, a widget that was passed to `show` earlier and hasn't been `close`'d yet),
hence the `self.show_parent` convention detailed above to get at the proper widget from within a subwidget ;).
Otherwise, you'll notice in debug mode that a debug guard will shout at you if that contract is broken,
and what happens in practice is the same thing as if an explicit `nil` were passed: no widgets will actually be flagged for repaint,
and only the *refresh* matching the requested region *will* be enqueued.
This is why you'll find a number of valid use-cases for passing a `nil` here, when you *just* want a screen refresh without a repaint :).
The string `"all"` is also accepted in place of a widget, and will do the obvious thing: flag the *full* window stack, bottom to top, for repaint,
while still honoring the refresh region (e.g., this doesn't enforce a full-screen refresh).
@usage
UIManager:setDirty(self.widget, "partial")
UIManager:setDirty(self.widget, "partial", Geom:new{x=10,y=10,w=100,h=50})
UIManager:setDirty(self.widget, function() return "ui", self.someelement.dimen end)
@param widget a window-level widget object, `"all"`, or `nil`
@param refreshtype `"full"`, `"flashpartial"`, `"flashui"`, `"partial"`, `"ui"`, `"fast"` (or a lambda, see description above)
@param refreshregion a rectangle @{ui.geometry.Geom|Geom} object (optional, omitting it means the region will cover the full screen)
@bool refreshdither `true` if widget requires dithering (optional)
]]
function UIManager:setDirty(widget, refreshtype, refreshregion, refreshdither)
if widget then
if widget == "all" then
-- special case: set all top-level widgets as being "dirty".
for i = 1, #self._window_stack do
self._dirty[self._window_stack[i].widget] = true
-- If any of 'em were dithered, honor their dithering hint
if self._window_stack[i].widget.dithered then
-- NOTE: That works when refreshtype is NOT a function,
-- which is why _repaint does another pass of this check ;).
logger.dbg("setDirty on all widgets: found a dithered widget, infecting the refresh queue")
refreshdither = true
end
end
elseif not widget.invisible then
-- NOTE: If our widget is translucent, or belongs to a translucent MovableContainer,
-- we'll want to flag everything below it as dirty, too,
-- because doing transparency right requires having an up to date background against which to blend.
-- (The typecheck is because some widgets use an alpha boolean trap for internal alpha handling (e.g., ImageWidget)).
local handle_alpha = false
-- NOTE: We only ever check the dirty flag on top-level widgets, so only set it there!
-- Enable verbose debug to catch misbehaving widgets via our post-guard.
for i = #self._window_stack, 1, -1 do
if handle_alpha then
self._dirty[self._window_stack[i].widget] = true
logger.dbg("setDirty: Marking as dirty widget:", self._window_stack[i].widget.name or self._window_stack[i].widget.id or tostring(self._window_stack[i].widget), "because it's below translucent widget:", widget.name or widget.id or tostring(widget))
-- Stop flagging widgets at the uppermost one that covers the full screen
if self._window_stack[i].widget.covers_fullscreen then
break
end
end
if self._window_stack[i].widget == widget then
self._dirty[widget] = true
-- We've got a match, now check if it's translucent...
handle_alpha = (widget.alpha and type(widget.alpha) == "number" and widget.alpha < 1 and widget.alpha > 0)
or (widget.movable and widget.movable.alpha and widget.movable.alpha < 1 and widget.movable.alpha > 0)
-- We shouldn't be seeing the same widget at two different spots in the stack, so, we're done,
-- except when we need to keep looping to flag widgets below us in order to handle a translucent widget...
if not handle_alpha then
break
end
end
end
-- Again, if it's flagged as dithered, honor that
if widget.dithered then
refreshdither = true
end
end
else
-- Another special case: if we did NOT specify a widget, but requested a full refresh nonetheless (i.e., a diagonal swipe),
-- we'll want to check the window stack in order to honor dithering...
if refreshtype == "full" then
for i = #self._window_stack, 1, -1 do
-- If any of 'em were dithered, honor their dithering hint
if self._window_stack[i].widget.dithered then
logger.dbg("setDirty full on no specific widget: found a dithered widget, infecting the refresh queue")
refreshdither = true
-- One is enough ;)
break
end
end
end
end
-- handle refresh information
if type(refreshtype) == "function" then
-- callback, will be issued after painting
table.insert(self._refresh_func_stack, refreshtype)
if dbg.is_on then
-- NOTE: It's too early to tell what the function will return (especially the region), because the widget hasn't been painted yet.
-- Consuming the lambda now also appears have nasty side-effects that render it useless later, subtly breaking a whole lot of things...
-- Thankfully, we can track them in _refresh()'s logging very soon after that...
logger.dbg("setDirty via a func from widget", widget and (widget.name or widget.id or tostring(widget)) or "nil")
end
else
-- otherwise, enqueue refresh
self:_refresh(refreshtype, refreshregion, refreshdither)
if dbg.is_on then
if refreshregion then
logger.dbg("setDirty", refreshtype and refreshtype or "nil", "from widget", widget and (widget.name or widget.id or tostring(widget)) or "nil", "w/ region", refreshregion.x, refreshregion.y, refreshregion.w, refreshregion.h, refreshdither and "AND w/ HW dithering" or "")
else
logger.dbg("setDirty", refreshtype and refreshtype or "nil", "from widget", widget and (widget.name or widget.id or tostring(widget)) or "nil", "w/ NO region", refreshdither and "AND w/ HW dithering" or "")
end
end
end
end
dbg:guard(UIManager, 'setDirty',
nil,
function(self, widget, refreshtype, refreshregion, refreshdither)
if not widget or widget == "all" then return end
-- when debugging, we check if we were handed a valid window-level widget,
-- which would be a widget that was previously passed to `show`.
local found = false
for i = 1, #self._window_stack do
if self._window_stack[i].widget == widget then
found = true
break
end
end
if not found then
dbg:v("INFO: invalid widget for setDirty()", debug.traceback())
end
end)
--[[--
Clear the full repaint & refresh queues.
NOTE: Beware! This doesn't take any prisonners!
You shouldn't have to resort to this unless in very specific circumstances!
plugins/coverbrowser.koplugin/covermenu.lua building a franken-menu out of buttondialogtitle & buttondialog
and wanting to avoid inheriting their original paint/refresh cycle being a prime example.
--]]
function UIManager:clearRenderStack()
logger.dbg("clearRenderStack: Clearing the full render stack!")
self._dirty = {}
self._refresh_func_stack = {}
self._refresh_stack = {}
end
function UIManager:insertZMQ(zeromq)
table.insert(self._zeromqs, zeromq)
return zeromq
end
function UIManager:removeZMQ(zeromq)
for i = #self._zeromqs, 1, -1 do
if self._zeromqs[i] == zeromq then
table.remove(self._zeromqs, i)
end
end
end
--[[--
Sets the full refresh rate for e-ink screens (`FULL_REFRESH_COUNT`).
This is the amount of `"partial"` refreshes before the next one gets promoted to `"full"`.
Also makes the refresh rate persistent in global reader settings.
@see setDirty
--]]
function UIManager:setRefreshRate(rate, night_rate)
logger.dbg("set screen full refresh rate", rate, night_rate)
if G_reader_settings:isTrue("night_mode") then
if night_rate then
self.FULL_REFRESH_COUNT = night_rate
end
else
if rate then
self.FULL_REFRESH_COUNT = rate
end
end
if rate then
G_reader_settings:saveSetting("full_refresh_count", rate)
end
if night_rate then
G_reader_settings:saveSetting("night_full_refresh_count", night_rate)
end
end
--- Returns the full refresh rate for e-ink screens (`FULL_REFRESH_COUNT`).
function UIManager:getRefreshRate()
return G_reader_settings:readSetting("full_refresh_count") or DEFAULT_FULL_REFRESH_COUNT, G_reader_settings:readSetting("night_full_refresh_count") or G_reader_settings:readSetting("full_refresh_count") or DEFAULT_FULL_REFRESH_COUNT
end
--- Toggles Night Mode (i.e., inverted rendering).
function UIManager:ToggleNightMode(night_mode)
if night_mode then
self.FULL_REFRESH_COUNT = G_reader_settings:readSetting("night_full_refresh_count") or G_reader_settings:readSetting("full_refresh_count") or DEFAULT_FULL_REFRESH_COUNT
else
self.FULL_REFRESH_COUNT = G_reader_settings:readSetting("full_refresh_count") or DEFAULT_FULL_REFRESH_COUNT
end
end
--- Get top widget (name if possible, ref otherwise).
function UIManager:getTopWidget()
local top = self._window_stack[#self._window_stack]
if not top or not top.widget then
return nil
end
if top.widget.name then
return top.widget.name
end
return top.widget
end
--[[--
Get the *second* topmost widget, if there is one (name if possible, ref otherwise).
Useful when VirtualKeyboard is involved, as it *always* steals the top spot ;).
NOTE: Will skip over VirtualKeyboard instances, plural, in case there are multiple (because, apparently, we can do that.. ugh).
--]]
function UIManager:getSecondTopmostWidget()
if #self._window_stack <= 1 then
-- Not enough widgets in the stack, bye!
return nil
end
-- Because everything is terrible, you can actually instantiate multiple VirtualKeyboards,
-- and they'll stack at the top, so, loop until we get something that *isn't* VK...
for i = #self._window_stack - 1, 1, -1 do
local sec = self._window_stack[i]
if not sec or not sec.widget then
return nil
end
if sec.widget.name then
if sec.widget.name ~= "VirtualKeyboard" then
return sec.widget.name
end
-- Meaning if name is set, and is set to VK => continue, as we want the *next* widget.
-- I *really* miss the continue keyword, Lua :/.
else
return sec.widget
end
end
return nil
end
--- Check if a widget is still in the window stack, or is a subwidget of a widget still in the window stack.
function UIManager:isSubwidgetShown(widget, max_depth)
for i = #self._window_stack, 1, -1 do
local matched, depth = util.arrayReferences(self._window_stack[i].widget, widget, max_depth)
if matched then
return matched, depth, self._window_stack[i].widget
end
end
return false
end
--- Same as `isSubwidgetShown`, but only check window-level widgets (e.g., what's directly registered in the window stack), don't recurse.
function UIManager:isWidgetShown(widget)
for i = #self._window_stack, 1, -1 do
if self._window_stack[i].widget == widget then
return true
end
end
return false
end
--[[--
Returns the region of the previous refresh.
@return a rectangle @{ui.geometry.Geom|Geom} object
]]
function UIManager:getPreviousRefreshRegion()
return self._last_refresh_region
end
--- Signals to quit.
function UIManager:quit()
if not self._running then return end
logger.info("quitting uimanager")
self._task_queue_dirty = false
self._running = false
self._run_forever = nil
for i = #self._window_stack, 1, -1 do
table.remove(self._window_stack, i)
end
for i = #self._task_queue, 1, -1 do
table.remove(self._task_queue, i)
end
for i = #self._zeromqs, 1, -1 do
self._zeromqs[i]:stop()
table.remove(self._zeromqs, i)
end
if self.looper then
self.looper:close()
self.looper = nil
end
end
--[[--
Request all @{ui.event.Event|Event}s to be ignored for some duration.
@param set_or_seconds either `true`, in which case a platform-specific delay is chosen, or a duration in seconds (***int***).
]]
function UIManager:discardEvents(set_or_seconds)
if not set_or_seconds then -- remove any previously set
self._discard_events_till = nil
return
end
local delay
if set_or_seconds == true then
-- Use an adequate delay to account for device refresh duration
-- so any events happening in this delay (ie. before a widget
-- is really painted on screen) are discarded.
if Device:hasEinkScreen() then
-- A screen refresh can take a few 100ms,
-- sometimes > 500ms on some devices/temperatures.
-- So, block for 400ms (to have it displayed) + 400ms
-- for user reaction to it
delay = TimeVal:new{ sec = 0, usec = 800000 }
else
-- On non-eInk screen, display is usually instantaneous
delay = TimeVal:new{ sec = 0, usec = 400000 }
end
else -- we expect a number
delay = TimeVal:new{ sec = set_or_seconds, usec = 0 }
end
self._discard_events_till = self._now + delay
end
--[[--
Transmits an @{ui.event.Event|Event} to active widgets, top to bottom.
Stops at the first handler that returns `true`.
Note that most complex widgets are based on @{ui.widget.container.WidgetContainer|WidgetContainer},
which itself will take care of propagating an event to its members.
@param event an @{ui.event.Event|Event} object
]]
function UIManager:sendEvent(event)
if #self._window_stack == 0 then return end
-- Ensure discardEvents
if self._discard_events_till then
if TimeVal:now() < self._discard_events_till then
return
else
self._discard_events_till = nil
end
end
-- The top widget gets to be the first to get the event
local top_widget = self._window_stack[#self._window_stack]
-- A toast widget gets closed by any event, and
-- lets the event be handled by a lower widget
-- (Notification is our single widget with toast=true)
while top_widget.widget.toast do -- close them all
self:close(top_widget.widget)
if #self._window_stack == 0 then return end
top_widget = self._window_stack[#self._window_stack]
end
if top_widget.widget:handleEvent(event) then
return
end
if top_widget.widget.active_widgets then
for _, active_widget in ipairs(top_widget.widget.active_widgets) do
if active_widget:handleEvent(event) then return end
end
end
-- If the event was not consumed (no handler returned true), active widgets (from top to bottom) can access it.
-- NOTE: _window_stack can shrink/grow when widgets are closed (CloseWidget & Close events) or opened.
-- Simply looping in reverse would only cover the list shrinking, and that only by a *single* element,
-- something we can't really guarantee, hence the more dogged iterator below,
-- which relies on a hash check of already processed widgets (LuaJIT actually hashes the table's GC reference),
-- rather than a simple loop counter, and will in fact iterate *at least* #items ^ 2 times.
-- Thankfully, that list should be very small, so the overhead should be minimal.
local checked_widgets = {top_widget}
local i = #self._window_stack
while i > 0 do
local widget = self._window_stack[i]
if checked_widgets[widget] == nil then
checked_widgets[widget] = true
-- Widget's active widgets have precedence to handle this event
-- NOTE: While FileManager only has a single (screenshotter), ReaderUI has many active_widgets (each ReaderUI module gets added to the list).
if widget.widget.active_widgets then
for _, active_widget in ipairs(widget.widget.active_widgets) do
if active_widget:handleEvent(event) then return end
end
end
if widget.widget.is_always_active then
-- Widget itself is flagged always active, let it handle the event
-- NOTE: is_always_active widgets currently are widgets that want to show a VirtualKeyboard or listen to Dispatcher events
if widget.widget:handleEvent(event) then return end
end
i = #self._window_stack
else
i = i - 1
end
end
end
--[[--
Transmits an @{ui.event.Event|Event} to all registered widgets.
@param event an @{ui.event.Event|Event} object
]]
function UIManager:broadcastEvent(event)
-- Unlike sendEvent, we send the event to *all* (window-level) widgets (i.e., we don't stop, even if a handler returns true).
-- NOTE: Same defensive approach to _window_stack changing from under our feet as above.
local checked_widgets = {}
local i = #self._window_stack
while i > 0 do
local widget = self._window_stack[i]
if checked_widgets[widget] == nil then
checked_widgets[widget] = true
widget.widget:handleEvent(event)
i = #self._window_stack
else
i = i - 1
end
end
end
function UIManager:_checkTasks()
self._now = TimeVal:now()
local wait_until = nil
-- task.action may schedule other events
self._task_queue_dirty = false
while true do
local nu_task = #self._task_queue
if nu_task == 0 then
-- all tasks checked
break
end
local task = self._task_queue[1]
local task_tv = task.time or TimeVal.zero
if task_tv <= self._now then
-- remove from table
table.remove(self._task_queue, 1)
-- task is pending to be executed right now. do it.
-- NOTE: be careful that task.action() might modify
-- _task_queue here. So need to avoid race condition
task.action(unpack(task.args, 1, task.argc))
else
-- queue is sorted in ascendant order, safe to assume all items
-- are future tasks for now
wait_until = task.time
break
end
end
return wait_until, self._now
end
--[[--
Returns a TimeVal object corresponding to the last UI tick.
This is essentially a cached TimeVal:now(), computed at the top of every iteration of the main UI loop,
(right before checking/running scheduled tasks).
This is mainly useful to compute/schedule stuff in the same time scale as the UI loop (i.e., MONOTONIC),
without having to resort to a syscall.
It should never be significantly stale (i.e., it should be precise enough),
unless you're blocking the UI for a significant amount of time in the same UI tick.
Prefer the appropriate TimeVal method for your needs if you require perfect accuracy
(e.g., when you're actually working on the event loop *itself* (UIManager, Input, GestureDetector)).
This is *NOT* wall clock time (REALTIME).
]]
function UIManager:getTime()
return self._now
end
-- precedence of refresh modes:
local refresh_modes = { fast = 1, ui = 2, partial = 3, flashui = 4, flashpartial = 5, full = 6 }
-- NOTE: We might want to introduce a "force_fast" that points to fast, but has the highest priority,
-- for the few cases where we might *really* want to enforce fast (for stuff like panning or skimming?).
-- refresh methods in framebuffer implementation
local refresh_methods = {
fast = "refreshFast",
ui = "refreshUI",
partial = "refreshPartial",
flashui = "refreshFlashUI",
flashpartial = "refreshFlashPartial",
full = "refreshFull",
}
--[[
Compares refresh mode.
Will return the mode that takes precedence.
]]
local function update_mode(mode1, mode2)
if refresh_modes[mode1] > refresh_modes[mode2] then
logger.dbg("update_mode: Update refresh mode", mode2, "to", mode1)
return mode1
else
return mode2
end
end
--[[
Compares dither hints.
Dither always wins.
]]
local function update_dither(dither1, dither2)
if dither1 and not dither2 then
logger.dbg("update_dither: Update dither hint", dither2, "to", dither1)
return dither1
else
return dither2
end
end
--[[--
Enqueues a refresh.
Widgets call this in their `paintTo()` method in order to notify
UIManager that a certain part of the screen is to be refreshed.
@string mode
refresh mode (`"full"`, `"flashpartial"`, `"flashui"`, `"partial"`, `"ui"`, `"fast"`)
@param region
A rectangle @{ui.geometry.Geom|Geom} object that specifies the region to be updated.
Optional, update will affect whole screen if not specified.
Note that this should be the exception.
@bool dither
A hint to request hardware dithering (if supported).
Optional, no dithering requested if not specified or not supported.
@local Not to be used outside of UIManager!
]]
function UIManager:_refresh(mode, region, dither)
if not mode then
-- If we're trying to float a dither hint up from a lower widget after a close, mode might be nil...
-- So use the lowest priority refresh mode (short of fast, because that'd do half-toning).
if dither then
mode = "ui"
else
-- Otherwise, this is most likely from a `show` or `close` that wasn't passed specific refresh details,
-- (which is the vast majority of them), in which case we drop it to avoid enqueuing a useless full-screen refresh.
return
end
end
if not region and mode == "full" then
self.refresh_count = 0 -- reset counter on explicit full refresh
end
-- Handle downgrading flashing modes to non-flashing modes, according to user settings.
-- NOTE: Do it before "full" promotion and collision checks/update_mode.
if G_reader_settings:isTrue("avoid_flashing_ui") then
if mode == "flashui" then
mode = "ui"
logger.dbg("_refresh: downgraded flashui refresh to", mode)
elseif mode == "flashpartial" then
mode = "partial"
logger.dbg("_refresh: downgraded flashpartial refresh to", mode)
elseif mode == "partial" and region then
mode = "ui"
logger.dbg("_refresh: downgraded regional partial refresh to", mode)
end
end
-- special case: "partial" refreshes
-- will get promoted every self.FULL_REFRESH_COUNT refreshes
-- since _refresh can be called mutiple times via setDirty called in
-- different widgets before a real screen repaint, we should make sure
-- refresh_count is incremented by only once at most for each repaint
-- NOTE: Ideally, we'd only check for "partial"" w/ no region set (that neatly narrows it down to just the reader).
-- In practice, we also want to promote refreshes in a few other places, except purely text-poor UI elements.
-- (Putting "ui" in that list is problematic with a number of UI elements, most notably, ReaderHighlight,
-- because it is implemented as "ui" over the full viewport, since we can't devise a proper bounding box).
-- So we settle for only "partial", but treating full-screen ones slightly differently.
if mode == "partial" and not self.refresh_counted then
self.refresh_count = (self.refresh_count + 1) % self.FULL_REFRESH_COUNT
if self.refresh_count == self.FULL_REFRESH_COUNT - 1 then
-- NOTE: Promote to "full" if no region (reader), to "flashui" otherwise (UI)
if region then
mode = "flashui"
else
mode = "full"
end
logger.dbg("_refresh: promote refresh to", mode)
end
self.refresh_counted = true
end
-- if no region is specified, use the screen's dimensions
region = region or Geom:new{w=Screen:getWidth(), h=Screen:getHeight()}
-- if no dithering hint was specified, don't request dithering
dither = dither or false
-- NOTE: While, ideally, we shouldn't merge refreshes w/ different waveform modes,
-- this allows us to optimize away a number of quirks of our rendering stack
-- (e.g., multiple setDirty calls queued when showing/closing a widget because of update mechanisms),
-- as well as a few actually effective merges
-- (e.g., the disappearance of a selection HL with the following menu update).
for i = 1, #self._refresh_stack do
-- Check for collision with refreshes that are already enqueued
-- NOTE: intersect *means* intersect: we won't merge edge-to-edge regions (but the EPDC probably will).
if region:intersectWith(self._refresh_stack[i].region) then
-- combine both refreshes' regions
local combined = region:combine(self._refresh_stack[i].region)
-- update the mode, if needed
mode = update_mode(mode, self._refresh_stack[i].mode)
-- dithering hints are viral, one is enough to infect the whole queue
dither = update_dither(dither, self._refresh_stack[i].dither)
-- remove colliding refresh
table.remove(self._refresh_stack, i)
-- and try again with combined data
return self:_refresh(mode, combined, dither)
end
end
-- if we've stopped hitting collisions, enqueue the refresh
logger.dbg("_refresh: Enqueued", mode, "update for region", region.x, region.y, region.w, region.h, dither and "w/ HW dithering" or "")
table.insert(self._refresh_stack, {mode = mode, region = region, dither = dither})
end
--[[--
Repaints dirty widgets.
This will also drain the refresh queue, effectively refreshing the screen region(s) matching those freshly repainted widgets.
There may be refreshes enqueued without any widgets needing to be repainted (c.f., `setDirty`'s behavior when passed a `nil` widget),
in which case, nothing is repainted, but the refreshes are still drained and executed.
@local Not to be used outside of UIManager!
--]]
function UIManager:_repaint()
-- flag in which we will record if we did any repaints at all
-- will trigger a refresh if set.
local dirty = false
-- remember if any of our repaints were dithered
local dithered = false
-- We don't need to call paintTo() on widgets that are under
-- a widget that covers the full screen
local start_idx = 1
for i = #self._window_stack, 1, -1 do
if self._window_stack[i].widget.covers_fullscreen then
start_idx = i
if i > 1 then
logger.dbg("not painting", i-1, "covered widget(s)")
end
break
end
end
-- Show IDs of covered widgets when debugging
--[[
if start_idx > 1 then
for i = 1, start_idx-1 do
local widget = self._window_stack[i]
logger.dbg("NOT painting widget:", widget.widget.name or widget.widget.id or tostring(widget))
end
end
--]]
for i = start_idx, #self._window_stack do
local widget = self._window_stack[i]
-- paint if current widget or any widget underneath is dirty
if dirty or self._dirty[widget.widget] then
-- pass hint to widget that we got when setting widget dirty
-- the widget can use this to decide which parts should be refreshed
logger.dbg("painting widget:", widget.widget.name or widget.widget.id or tostring(widget))
Screen:beforePaint()
-- NOTE: Nothing actually seems to use the final argument?
-- Could be used by widgets to know whether they're being repainted because they're actually dirty (it's true),
-- or because something below them was (it's nil).
widget.widget:paintTo(Screen.bb, widget.x, widget.y, self._dirty[widget.widget])
-- and remove from list after painting
self._dirty[widget.widget] = nil
-- trigger a repaint for every widget above us, too
dirty = true
-- if any of 'em were dithered, we'll want to dither the final refresh
if widget.widget.dithered then
logger.dbg("_repaint: it was dithered, infecting the refresh queue")
dithered = true
end
end
end
-- execute pending refresh functions
for _, refreshfunc in ipairs(self._refresh_func_stack) do
local refreshtype, region, dither = refreshfunc()
-- honor dithering hints from *anywhere* in the dirty stack
dither = update_dither(dither, dithered)
if refreshtype then self:_refresh(refreshtype, region, dither) end
end
self._refresh_func_stack = {}
-- we should have at least one refresh if we did repaint. If we don't, we
-- add one now and log a warning if we are debugging
if dirty and #self._refresh_stack == 0 then
logger.dbg("no refresh got enqueued. Will do a partial full screen refresh, which might be inefficient")
self:_refresh("partial")
end
-- execute refreshes:
for _, refresh in ipairs(self._refresh_stack) do
-- Honor dithering hints from *anywhere* in the dirty stack
refresh.dither = update_dither(refresh.dither, dithered)
-- If HW dithering is disabled, unconditionally drop the dither flag
if not Screen.hw_dithering then
refresh.dither = nil
end
dbg:v("triggering refresh", refresh)
-- Remember the refresh region
self._last_refresh_region = refresh.region
Screen[refresh_methods[refresh.mode]](Screen,
refresh.region.x, refresh.region.y,
refresh.region.w, refresh.region.h,
refresh.dither)
end
-- Don't trigger afterPaint if we did not, in fact, paint anything
if dirty then
Screen:afterPaint()
end
self._refresh_stack = {}
self.refresh_counted = false
end
--- Explicitly drain the paint & refresh queues *now*, instead of waiting for the next UI tick.
function UIManager:forceRePaint()
self:_repaint()
end
--[[--
Ask the EPDC to *block* until our previous refresh ioctl has completed.
This interacts sanely with the existing low-level handling of this in `framebuffer_mxcfb`
(i.e., it doesn't even try to wait for a marker that fb has already waited for, and vice-versa).
Will return immediately if it has already completed.
If the device isn't a Linux + MXCFB device, this is a NOP.
]]
function UIManager:waitForVSync()
Screen:refreshWaitForLast()
end
--[[--
Yield to the EPDC.
This is a dumb workaround for potential races with the EPDC when we request a refresh on a specific region,
and then proceed to *write* to the framebuffer, in the same region, very, very, very soon after that.
This basically just puts ourselves to sleep for a very short amount of time, to let the kernel do its thing in peace.
@int sleep_us Amount of time to sleep for (in µs). (Optional, defaults to 1ms).
]]
function UIManager:yieldToEPDC(sleep_us)
if Device:hasEinkScreen() then
-- NOTE: Early empiric evidence suggests that going as low as 1ms is enough to do the trick.
-- Consider jumping to the jiffy resolution (100Hz/10ms) if it turns out it isn't ;).
ffiUtil.usleep(sleep_us or 1000)
end
end
--[[--
Used to repaint a specific sub-widget that isn't on the `_window_stack` itself.
Useful to avoid repainting a complex widget when we just want to invert an icon, for instance.
No safety checks on x & y *by design*. I want this to blow up if used wrong.
This is an explicit repaint *now*: it bypasses and ignores the paint queue (unlike `setDirty`).
@param widget a @{ui.widget.widget|widget} object
@int x left origin of widget (in the Screen buffer, e.g., `widget.dimen.x`)
@int y top origin of widget (in the Screen buffer, e.g., `widget.dimen.y`)
]]
function UIManager:widgetRepaint(widget, x, y)
if not widget then return end
logger.dbg("Explicit widgetRepaint:", widget.name or widget.id or tostring(widget), "@ (", x, ",", y, ")")
widget:paintTo(Screen.bb, x, y)
end
--[[--
Same idea as `widgetRepaint`, but does a simple `bb:invertRect` on the Screen buffer, without actually going through the widget's `paintTo` method.
@param widget a @{ui.widget.widget|widget} object
@int x left origin of the rectangle to invert (in the Screen buffer, e.g., `widget.dimen.x`)
@int y top origin of the rectangle (in the Screen buffer, e.g., `widget.dimen.y`)
@int w width of the rectangle (optional, will use `widget.dimen.w` like `paintTo` would if omitted)
@int h height of the rectangle (optional, will use `widget.dimen.h` like `paintTo` would if omitted)
@see widgetRepaint
--]]
function UIManager:widgetInvert(widget, x, y, w, h)
if not widget then return end
logger.dbg("Explicit widgetInvert:", widget.name or widget.id or tostring(widget), "@ (", x, ",", y, ")")
Screen.bb:invertRect(x, y, w or widget.dimen.w, h or widget.dimen.h)
end
function UIManager:setInputTimeout(timeout)
self.INPUT_TIMEOUT = timeout or 200*1000
end
function UIManager:resetInputTimeout()
self.INPUT_TIMEOUT = nil
end
function UIManager:handleInputEvent(input_event)
if input_event.handler ~= "onInputError" then
self.event_hook:execute("InputEvent", input_event)
end
local handler = self.event_handlers[input_event]
if handler then
handler(input_event)
else
self.event_handlers["__default__"](input_event)
end
end
-- Process all pending events on all registered ZMQs.
function UIManager:processZMQs()
for _, zeromq in ipairs(self._zeromqs) do
for input_event in zeromq.waitEvent, zeromq do
self:handleInputEvent(input_event)
end
end
end
function UIManager:handleInput()
local wait_until, now
-- run this in a loop, so that paints can trigger events
-- that will be honored when calculating the time to wait
-- for input events:
repeat
wait_until, now = self:_checkTasks()
--dbg("---------------------------------------------------")
--dbg("wait_until", wait_until)
--dbg("now", now)
--dbg("exec stack", self._task_queue)
--dbg("window stack", self._window_stack)
--dbg("dirty stack", self._dirty)
--dbg("---------------------------------------------------")
-- stop when we have no window to show
if #self._window_stack == 0 and not self._run_forever then
logger.info("no dialog left to show")
self:quit()
return nil
end
self:_repaint()
until not self._task_queue_dirty
-- NOTE: Compute deadline *before* processing ZMQs, in order to be able to catch tasks scheduled *during*
-- the final ZMQ callback.
-- This ensures that we get to honor a single ZMQ_TIMEOUT *after* the final ZMQ callback,
-- which gives us a chance for another iteration, meaning going through _checkTasks to catch said scheduled tasks.
-- Figure out how long to wait.
-- Ultimately, that'll be the earliest of INPUT_TIMEOUT, ZMQ_TIMEOUT or the next earliest scheduled task.
local deadline
-- Default to INPUT_TIMEOUT (which may be nil, i.e. block until an event happens).
local wait_us = self.INPUT_TIMEOUT
-- If we have any ZMQs registered, ZMQ_TIMEOUT is another upper bound.
if #self._zeromqs > 0 then
wait_us = math.min(wait_us or math.huge, self.ZMQ_TIMEOUT)
end
-- We pass that on as an absolute deadline, not a relative wait time.
if wait_us then
deadline = now + TimeVal:new{ usec = wait_us }
end
-- If there's a scheduled task pending, that puts an upper bound on how long to wait.
if wait_until and (not deadline or wait_until < deadline) then
-- ^ We don't have a TIMEOUT induced deadline, making the choice easy.
-- ^ We have a task scheduled for *before* our TIMEOUT induced deadline.
deadline = wait_until
end
-- Run ZMQs if any
self:processZMQs()
-- If allowed, entering standby (from which we can wake by input) must trigger in response to event
-- this function emits (plugin), or within waitEvent() right after (hardware).
-- Anywhere else breaks preventStandby/allowStandby invariants used by background jobs while UI is left running.
self:_standbyTransition()
-- wait for next batch of events
local input_events = Input:waitEvent(now, deadline)
-- delegate each input event to handler
if input_events then
-- Handle the full batch of events
for __, ev in ipairs(input_events) do
self:handleInputEvent(ev)
end
end
if self.looper then
logger.info("handle input in turbo I/O looper")
self.looper:add_callback(function()
--- @fixme Force close looper when there is unhandled error,
-- otherwise the looper will hang. Any better solution?
xpcall(function() self:handleInput() end, function(err)
io.stderr:write(err .. "\n")
io.stderr:write(debug.traceback() .. "\n")
io.stderr:flush()
self.looper:close()
os.exit(1, true)
end)
end)
end
end
function UIManager:onRotation()
self:setDirty("all", "full")
self:forceRePaint()
end
function UIManager:initLooper()
if DUSE_TURBO_LIB and not self.looper then
TURBO_SSL = true -- luacheck: ignore
__TURBO_USE_LUASOCKET__ = true -- luacheck: ignore
local turbo = require("turbo")
self.looper = turbo.ioloop.instance()
end
end
--[[--
This is the main loop of the UI controller.
It is intended to manage input events and delegate them to dialogs.
--]]
function UIManager:run()
self._running = true
self:initLooper()
-- currently there is no Turbo support for Windows
-- use our own main loop
if not self.looper then
while self._running do
self:handleInput()
end
else
self.looper:add_callback(function() self:handleInput() end)
self.looper:start()
end
return self._exit_code
end
-- run uimanager forever for testing purpose
function UIManager:runForever()
self._run_forever = true
return self:run()
end
-- The common operations that should be performed before suspending the device.
function UIManager:_beforeSuspend()
self:flushSettings()
self:broadcastEvent(Event:new("Suspend"))
-- Reset gesture detection state to a blank slate (anything power-management related emits KEY events, which don't need gesture detection).
Input:resetState()
end
-- The common operations that should be performed after resuming the device.
function UIManager:_afterResume()
self:broadcastEvent(Event:new("Resume"))
end
-- The common operations that should be performed when the device is plugged to a power source.
function UIManager:_beforeCharging()
if G_reader_settings:nilOrTrue("enable_charging_led") then
Device:toggleChargingLED(true)
end
self:broadcastEvent(Event:new("Charging"))
end
-- The common operations that should be performed when the device is unplugged from a power source.
function UIManager:_afterNotCharging()
if G_reader_settings:nilOrTrue("enable_charging_led") then
Device:toggleChargingLED(false)
end
self:broadcastEvent(Event:new("NotCharging"))
end
--[[--
Executes all the operations of a suspension (i.e., sleep) request.
This function usually puts the device into suspension.
]]
function UIManager:suspend()
if Device:isCervantes() or Device:isKobo() or Device:isSDL() or Device:isRemarkable() or Device:isSonyPRSTUX() then
self.event_handlers["Suspend"]()
elseif Device:isKindle() then
Device.powerd:toggleSuspend()
elseif Device.isPocketBook() and Device.canSuspend() then
Device:suspend()
end
end
--[[--
Executes all the operations of a resume (i.e., wakeup) request.
This function usually wakes up the device.
]]
function UIManager:resume()
if Device:isCervantes() or Device:isKobo() or Device:isSDL() or Device:isRemarkable() or Device:isSonyPRSTUX() then
self.event_handlers["Resume"]()
elseif Device:isKindle() then
self.event_handlers["OutOfSS"]()
end
end
--[[--
Release standby lock.
Called once we're done with whatever we were doing in the background.
Standby is re-enabled only after all issued prevents are paired with allowStandby for each one.
]]
function UIManager:allowStandby()
assert(self._prevent_standby_count > 0, "allowing standby that isn't prevented; you have an allow/prevent mismatch somewhere")
self._prevent_standby_count = self._prevent_standby_count - 1
end
--[[--
Prevent standby.
i.e., something is happening in background, yet UI may tick.
]]
function UIManager:preventStandby()
self._prevent_standby_count = self._prevent_standby_count + 1
end
-- The allow/prevent calls above can interminently allow standbys, but we're not interested until
-- the state change crosses UI tick boundary, which is what self._prev_prevent_standby_count is tracking.
function UIManager:_standbyTransition()
if self._prevent_standby_count == 0 and self._prev_prevent_standby_count > 0 then
-- edge prevent->allow
logger.dbg("allow standby")
Device:setAutoStandby(true)
self:broadcastEvent(Event:new("AllowStandby"))
elseif self._prevent_standby_count > 0 and self._prev_prevent_standby_count == 0 then
-- edge allow->prevent
logger.dbg("prevent standby")
Device:setAutoStandby(false)
self:broadcastEvent(Event:new("PreventStandby"))
end
self._prev_prevent_standby_count = self._prevent_standby_count
end
--- Broadcasts a `FlushSettings` Event to *all* widgets.
function UIManager:flushSettings()
self:broadcastEvent(Event:new("FlushSettings"))
end
--- Sanely restart KOReader (on supported platforms).
function UIManager:restartKOReader()
self:quit()
-- This is just a magic number to indicate the restart request for shell scripts.
self._exit_code = 85
end
--- Sanely abort KOReader (e.g., exit sanely, but with a non-zero return code).
function UIManager:abort()
self:quit()
self._exit_code = 1
end
UIManager:init()
return UIManager
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