libinput and Lua plugins

First of all, what's outlined here should be available in libinput 1.29 but I'm not 100% certain on all the details yet so any feedback (in the libinput issue tracker) would be appreciated. Right now this is all still sitting in the libinput!1192 merge request. I'd specifically like to see some feedback from people familiar with Lua APIs. With this out of the way:

Come libinput 1.29, libinput will support plugins written in Lua. These plugins sit logically between the kernel and libinput and allow modifying the evdev device and its events before libinput gets to see them.

The motivation for this are a few unfixable issues - issues we knew how to fix but we cannot actually implement and/or ship the fixes without breaking other devices. One example for this is the inverted Logitech MX Master 3S horizontal wheel. libinput ships quirks for the USB/Bluetooth connection but not for the Bolt receiver. Unlike the Unifying Receiver the Bolt receiver doesn't give the kernel sufficient information to know which device is currently connected. Which means our quirks could only apply to the Bolt receiver (and thus any mouse connected to it) - that's a rather bad idea though, we'd break every other mouse using the same receiver. Another example is an issue with worn out mouse buttons - on that device the behavior was predictable enough but any heuristics would catch a lot of legitimate buttons. That's fine when you know your mouse is slightly broken and at least it works again. But it's not something we can ship as a general solution. There are plenty more examples like that - custom pointer deceleration, different disable-while-typing, etc.

libinput has quirks but they are internal API and subject to change without notice at any time. They're very definitely not for configuring a device and the local quirk file libinput parses is merely to bridge over the time until libinput ships the (hopefully upstreamed) quirk.

So the obvious solution is: let the users fix it themselves. And this is where the plugins come in. They are not full access into libinput, they are closer to a udev-hid-bpf in userspace. Logically they sit between the kernel event devices and libinput: input events are read from the kernel device, passed to the plugins, then passed to libinput. A plugin can look at and modify devices (add/remove buttons for example) and look at and modify the event stream as it comes from the kernel device. For this libinput changed internally to now process something called an "evdev frame" which is a struct that contains all struct input_events up to the terminating SYN_REPORT. This is the logical grouping of events anyway but so far we didn't explicitly carry those around as such. Now we do and we can pass them through to the plugin(s) to be modified.

The aforementioned Logitech MX master plugin would look like this: it registers itself with a version number, then sets a callback for the "new-evdev-device" notification and (where the device matches) we connect that device's "evdev-frame" notification to our actual code:

libinput:register(1) -- register plugin version 1
libinput:connect("new-evdev-device", function (_, device)
    if device:vid() == 0x046D and device:pid() == 0xC548 then
        device:connect("evdev-frame", function (_, frame)
            for _, event in ipairs(frame.events) do
                if event.type == evdev.EV_REL and 
                   (event.code == evdev.REL_HWHEEL or 
                    event.code == evdev.REL_HWHEEL_HI_RES) then
                    event.value = -event.value
                end
            end
            return frame
        end)
    end
end)

This file can be dropped into /etc/libinput/plugins/10-mx-master.lua and will be loaded on context creation. I'm hoping the approach using named signals (similar to e.g. GObject) makes it easy to add different calls in future versions. Plugins also have access to a timer so you can filter events and re-send them at a later point in time. This is useful for implementing something like disable-while-typing based on certain conditions.

So why Lua? Because it's very easy to sandbox. I very explicitly did not want the plugins to be a side-channel to get into the internals of libinput - specifically no IO access to anything. This ruled out using C (or anything that's a .so file, really) because those would run a) in the address space of the compositor and b) be unrestricted in what they can do. Lua solves this easily. And, as a nice side-effect, it's also very easy to write plugins in.[1]

Whether plugins are loaded or not will depend on the compositor: an explicit call to set up the paths to load from and to actually load the plugins is required. No run-time plugin changes at this point either, they're loaded on libinput context creation and that's it. Otherwise, all the usual implementation details apply: files are sorted and if there are files with identical names the one from the highest-precedence directory will be used. Plugins that are buggy will be unloaded immediately.

If all this sounds interesting, please have a try and report back any APIs that are broken, or missing, or generally ideas of the good or bad persuation. Ideally before we ship it and the API is stable forever :)

[1] Benjamin Tissoires actually had a go at WASM plugins (via rust). But ... a lot of effort for rather small gains over Lua

libinput and 3-finger dragging

Ready in time for libinput 1.28 [1] and after a number of attempts over the years we now finally have 3-finger dragging in libinput. This is a long-requested feature that allows users to drag by using a 3-finger swipe on the touchpad. Instead of the normal swipe gesture you simply get a button down, pointer motion, button up sequence. Without having to tap or physically click and hold a button, so you might be able to see the appeal right there.

Now, as with any interaction that relies on the mere handful of fingers that are on our average user's hand, we are starting to have usage overlaps. Since the only difference between a swipe gesture and a 3-finger drag is in the intention of the user (and we can't detect that yet, stay tuned), 3-finger swipes are disabled when 3-finger dragging is enabled. Otherwise it does fit in quite nicely with the rest of the features we have though.

There really isn't much more to say about the new feature except: It's configurable to work on 4-finger drag too so if you mentally substitute all the threes with fours in this article before re-reading it that would save me having to write another blog post. Thanks.

[1] "soonish" at the time of writing

GNOME 48 and a changed tap-and-drag drag lock behaviour

This is a heads up as mutter PR!4292 got merged in time for GNOME 48. It (subtly) changes the behaviour of drag lock on touchpads, but (IMO) very much so for the better. Note that this feature is currently not exposed in GNOME Settings so users will have to set it via e.g. the gsettings commandline tool. I don't expect this change to affect many users.

This is a feature of a feature of a feature, so let's start at the top.

"Tapping" on touchpads refers to the ability to emulate button presses via short touches ("taps") on the touchpad. When enabled, a single-finger tap corresponds emulates a left mouse button click, a two-finger tap a right button click, etc. Taps are short interactions and to be recognised the finger must be set down and released again within a certain time and not move more than a certain distance. Clicking is useful but it's not everything we do with touchpads.

"Tap-and-drag" refers to the ability to keep the pointer down so it's possible to drag something while the mouse button is logically down. The sequence required to do this is a tap immediately followed by the finger down (and held down). This will press the left mouse button so that any finger movement results in a drag. Releasing the finger releases the button. This is convenient but especially on large monitors or for users with different-than-whatever-we-guessed-is-average dexterity this can make it hard to drag something to it's final position - a user may run out of touchpad space before the pointer reaches the destination. For those, the tap-and-drag "drag lock" is useful.

"Drag lock" refers to the ability of keeping the mouse button pressed until "unlocked", even if the finger moves off the touchpads. It's the same sequence as before: tap followed by the finger down and held down. But releasing the finger will not release the mouse button, instead another tap is required to unlock and release the mouse button. The whole sequence thus becomes tap, down, move.... tap with any number of finger releases in between. Sounds (and is) complicated to explain, is quite easy to try and once you're used to it it will feel quite natural.

The above behaviour is the new behaviour which non-coincidentally also matches the macOS behaviour (if you can find the toggle in the settings, good practice for easter eggs!). The previous behaviour used a timeout instead so the mouse button was released automatically if the finger was up after a certain timeout. This was less predictable and caused issues with users who weren't fast enough. The new "sticky" behaviour resolves this issue and is (alanis morissette-stylue ironically) faster to release (a tap can be performed before the previous timeout would've expired).

Anyway, TLDR, a feature that very few people use has changed defaults subtly. Bring out the pitchforks!

As said above, this is currently only accessible via gsettings and the drag-lock behaviour change only takes effect if tapping, tap-and-drag and drag lock are enabled:

  $ gsettings set org.gnome.desktop.peripherals.touchpad tap-to-click true
  $ gsettings set org.gnome.desktop.peripherals.touchpad tap-and-drag true
  $ gsettings set org.gnome.desktop.peripherals.touchpad tap-and-drag-lock true
  

All features above are actually handled by libinput, this is just about a default change in GNOME.

A new issue policy for libinput - closing and reopening issues for fun and profit

This is a heads up that if you file an issue in the libinput issue tracker, it's very likely this issue will be closed. And this post explains why that's a good thing, why it doesn't mean what you want, and most importantly why you shouldn't get angry about it.

Unfixed issues have, roughly, two states: they're either waiting for someone who can triage and ideally fix it (let's call those someones "maintainers") or they're waiting on the reporter to provide some more info or test something. Let's call the former state "actionable" and the second state "needinfo". The first state is typically not explicitly communicated but the latter can be via different means, most commonly via a "needinfo" label. Labels are of course great because you can be explicit about what is needed and with our bugbot you can automate much of this.

Alas, using labels has one disadvantage: GitLab does not allow the typical bug reporter to set or remove labels - you need to have at least the Planner role in the project (or group) and, well, suprisingly reporting an issue doesn't mean you get immediately added to the project. So setting a "needinfo" label requires the maintainer to remove the label. And until that happens you have a open bug that has needinfo set and looks like it's still needing info. Not a good look, that is.

So how about we use something other than labels, so the reporter can communicate that the bug has changed to actionable? Well, as it turns out there is exactly thing a reporter can do on their own bugs other than post comments: close it and re-open it. That's it [1]. So given this vast array of options (one button!), we shall use them (click it!).

So for the forseeable future libinput will follow the following pattern:

• Reporter files an issue
• Maintainer looks at it, posts a comment requesting some information, closes the bug
• Reporter attaches information, re-opens bug
• Maintainer looks at it and either: files a PR to fix the issue or closes the bug with the wontfix/notourbug/cantfix label

Obviously the close/reopen stage may happen a few times. For the final closing where the issue isn't fixed the labels actually work well: they preserve for posterity why the bug was closed and in this case they do not need to be changed by the reporter anyway. But until that final closing the result of this approach is that an open bug is a bug that is actionable for a maintainer.

This process should work (in libinput at least), all it requires is for reporters to not get grumpy about issue being closed. And that's where this blog post (and the comments bugbot will add when closing) come in. So here's hoping. And to stave off the first question: yes, I too wish there was a better (and equally simple) way to go about this.

[1] we shall ignore magic comments that are parsed by language-understanding bots because that future isn't yet the present

hidreport and hut: two crates for handling HID Report Descriptors and HID Reports

A while ago I was looking at Rust-based parsing of HID reports but, surprisingly, outside of C wrappers and the usual cratesquatting I couldn't find anything ready to use. So I figured, why not write my own, NIH style. Yay! Gave me a good excuse to learn API design for Rust and whatnot. Anyway, the result of this effort is the hidutils collection of repositories which includes commandline tools like hid-recorder and hid-replay but, more importantly, the hidreport (documentation) and hut (documentation) crates. Let's have a look at the latter two.

Both crates were intentionally written with minimal dependencies, they currently only depend on thiserror and arguably even that dependency can be removed.

HID Usage Tables (HUT)

As you know, HID Fields have a so-called "Usage" which is divided into a Usage Page (like a chapter) and a Usage ID. The HID Usage tells us what a sequence of bits in a HID Report represents, e.g. "this is the X axis" or "this is button number 5". These usages are specified in the HID Usage Tables (HUT) (currently at version 1.5 (PDF)). The hut crate is generated from the official HUT json file and contains all current HID Usages together with the various conversions you will need to get from a numeric value in a report descriptor to the named usage and vice versa. Which means you can do things like this:

  let gd_x = GenericDesktop::X;
  let usage_page = gd_x.usage_page();
  assert!(matches!(usage_page, UsagePage::GenericDesktop));
  

Or the more likely need: convert from a numeric page/id tuple to a named usage.

  let usage = Usage::new_from_page_and_id(0x1, 0x30); // GenericDesktop / X
  println!("Usage is {}", usage.name());
  

90% of this crate are the various conversions from a named usage to the numeric value and vice versa. It's a huge crate in that there are lots of enum values but the actual functionality is relatively simple.

hidreport - Report Descriptor parsing

The hidreport crate is the one that can take a set of HID Report Descriptor bytes obtained from a device and parse the contents. Or extract the value of a HID Field from a HID Report, given the HID Report Descriptor. So let's assume we have a bunch of bytes that are HID report descriptor read from the device (or sysfs) we can do this:

  let rdesc: ReportDescriptor = ReportDescriptor::try_from(bytes).unwrap();
  

I'm not going to copy/paste the code to run through this report descriptor but suffice to day it will give us access to the input, output and feature reports on the device together with every field inside those reports. Now let's read from the device and parse the data for whatever the first field is in the report (this is obviously device-specific, could be a button, a coordinate, anything):

   let input_report_bytes = read_from_device();
   let report = rdesc.find_input_report(&input_report_bytes).unwrap();
   let field = report.fields().first().unwrap();
   match field {
       Field::Variable(var) => {
          let val: u32 = var.extract(&input_report_bytes).unwrap().into();
          println!("Field {:?} is of value {}", field, val);
       },
       _ => {}
   }
  

The full documentation is of course on docs.rs and I'd be happy to take suggestions on how to improve the API and/or add features not currently present.

hid-recorder

The hidreport and hut crates are still quite new but we have an existing test bed that we use regularly. The venerable hid-recorder tool has been rewritten twice already. Benjamin Tissoires' first version was in C, then a Python version of it became part of hid-tools and now we have the third version written in Rust. Which has a few nice features over the Python version and we're using it heavily for e.g. udev-hid-bpf debugging and development. An examle output of that is below and it shows that you can get all the information out of the device via the hidreport and hut crates.

$ sudo hid-recorder /dev/hidraw1
# Microsoft Microsoft® 2.4GHz Transceiver v9.0
# Report descriptor length: 223 bytes
# 0x05, 0x01,                    // Usage Page (Generic Desktop)              0
# 0x09, 0x02,                    // Usage (Mouse)                             2
# 0xa1, 0x01,                    // Collection (Application)                  4
# 0x05, 0x01,                    //   Usage Page (Generic Desktop)            6
# 0x09, 0x02,                    //   Usage (Mouse)                           8
# 0xa1, 0x02,                    //   Collection (Logical)                    10
# 0x85, 0x1a,                    //     Report ID (26)                        12
# 0x09, 0x01,                    //     Usage (Pointer)                       14
# 0xa1, 0x00,                    //     Collection (Physical)                 16
# 0x05, 0x09,                    //       Usage Page (Button)                 18
# 0x19, 0x01,                    //       UsageMinimum (1)                    20
# 0x29, 0x05,                    //       UsageMaximum (5)                    22
# 0x95, 0x05,                    //       Report Count (5)                    24
# 0x75, 0x01,                    //       Report Size (1)                     26
... omitted for brevity
# 0x75, 0x01,                    //     Report Size (1)                       213
# 0xb1, 0x02,                    //     Feature (Data,Var,Abs)                215
# 0x75, 0x03,                    //     Report Size (3)                       217
# 0xb1, 0x01,                    //     Feature (Cnst,Arr,Abs)                219
# 0xc0,                          //   End Collection                          221
# 0xc0,                          // End Collection                            222
R: 223 05 01 09 02 a1 01 05 01 09 02 a1 02 85 1a 09 ... omitted for previty
N: Microsoft Microsoft® 2.4GHz Transceiver v9.0
I: 3 45e 7a5
# Report descriptor:
# ------- Input Report -------
# Report ID: 26
#    Report size: 80 bits
#  |   Bit:    8       | Usage: 0009/0001: Button / Button 1                          | Logical Range:     0..=1     |
#  |   Bit:    9       | Usage: 0009/0002: Button / Button 2                          | Logical Range:     0..=1     |
#  |   Bit:   10       | Usage: 0009/0003: Button / Button 3                          | Logical Range:     0..=1     |
#  |   Bit:   11       | Usage: 0009/0004: Button / Button 4                          | Logical Range:     0..=1     |
#  |   Bit:   12       | Usage: 0009/0005: Button / Button 5                          | Logical Range:     0..=1     |
#  |   Bits:  13..=15  | ######### Padding                                            |
#  |   Bits:  16..=31  | Usage: 0001/0030: Generic Desktop / X                        | Logical Range: -32767..=32767 |
#  |   Bits:  32..=47  | Usage: 0001/0031: Generic Desktop / Y                        | Logical Range: -32767..=32767 |
#  |   Bits:  48..=63  | Usage: 0001/0038: Generic Desktop / Wheel                    | Logical Range: -32767..=32767 | Physical Range:     0..=0     |
#  |   Bits:  64..=79  | Usage: 000c/0238: Consumer / AC Pan                          | Logical Range: -32767..=32767 | Physical Range:     0..=0     |
# ------- Input Report -------
# Report ID: 31
#    Report size: 24 bits
#  |   Bits:   8..=23  | Usage: 000c/0238: Consumer / AC Pan                          | Logical Range: -32767..=32767 | Physical Range:     0..=0     |
# ------- Feature Report -------
# Report ID: 18
#    Report size: 16 bits
#  |   Bits:   8..=9   | Usage: 0001/0048: Generic Desktop / Resolution Multiplier    | Logical Range:     0..=1     | Physical Range:     1..=12    |
#  |   Bits:  10..=11  | Usage: 0001/0048: Generic Desktop / Resolution Multiplier    | Logical Range:     0..=1     | Physical Range:     1..=12    |
#  |   Bits:  12..=15  | ######### Padding                                            |
# ------- Feature Report -------
# Report ID: 23
#    Report size: 16 bits
#  |   Bits:   8..=9   | Usage: ff00/ff06: Vendor Defined Page 0xFF00 / Vendor Usage 0xff06 | Logical Range:     0..=1     | Physical Range:     1..=12    |
#  |   Bits:  10..=11  | Usage: ff00/ff0f: Vendor Defined Page 0xFF00 / Vendor Usage 0xff0f | Logical Range:     0..=1     | Physical Range:     1..=12    |
#  |   Bit:   12       | Usage: ff00/ff04: Vendor Defined Page 0xFF00 / Vendor Usage 0xff04 | Logical Range:     0..=1     | Physical Range:     0..=0     |
#  |   Bits:  13..=15  | ######### Padding                                            |
##############################################################################
# Recorded events below in format:
# E: .  [bytes ...]
#
# Current time: 11:31:20
# Report ID: 26 /
#                Button 1:     0 | Button 2:     0 | Button 3:     0 | Button 4:     0 | Button 5:     0 | X:     5 | Y:     0 |
#                Wheel:     0 |
#                AC Pan:     0 |
E: 000000.000124 10 1a 00 05 00 00 00 00 00 00 00
  

HIOCREVOKE merged for kernel 6.12

TLDR: if you know what EVIOCREVOKE does, the same now works for hidraw devices via HIDIOCREVOKE.

The HID standard is the most common hardware protocol for input devices. In the Linux kernel HID is typically translated to the evdev protocol which is what libinput and all Xorg input drivers use. evdev is the kernel's input API and used for all devices, not just HID ones.

evdev is mostly compatible with HID but there are quite a few niche cases where they differ a fair bit. And some cases where evdev doesn't work well because of different assumptions, e.g. it's near-impossible to correctly express a device with 40 generic buttons (as opposed to named buttons like "left", "right", ...[0]). In particular for gaming devices it's quite common to access the HID device directly via the /dev/hidraw nodes. And of course for configuration of devices accessing the hidraw node is a must too (see Solaar, openrazer, libratbag, etc.). Alas, /dev/hidraw nodes are only accessible as root - right now applications work around this by either "run as root" or shipping udev rules tagging the device with uaccess.

evdev too can only be accessed as root (or the input group) but many many moons ago when dinosaurs still roamed the earth (version 3.12 to be precise), David Rheinsberg merged the EVIOCREVOKE ioctl. When called the file descriptor immediately becomes invalid, any further reads/writes will fail with ENODEV. This is a cornerstone for systemd-logind: it hands out a file descriptor via DBus to Xorg or the Wayland compositor but keeps a copy. On VT switch it calls the ioctl, thus preventing any events from reaching said X server/compositor. In turn this means that a) X no longer needs to run as root[1] since it can get input devices from logind and b) X loses access to those input devices at logind's leisure so we don't have to worry about leaking passwords.

Real-time forward to 2024 and kernel 6.12 now gained the HIDIOCREVOKE for /dev/hidraw nodes. The corresponding logind support has also been merged. The principle is the same: logind can hand out an fd to a hidraw node and can revoke it at will so we don't have to worry about data leakage to processes that should not longer receive events. This is the first of many steps towards more general HID support in userspace. It's not immediately usable since logind will only hand out those fds to the session leader (read: compositor or Xorg) so if you as application want that fd you need to convince your display server to give it to you. For that we may have something like the inputfd Wayland protocol (or maybe a portal but right now it seems a Wayland protocol is more likely). But that aside, let's hooray nonetheless. One step down, many more to go.

One of the other side-effects of this is that logind now has an fd to any device opened by a user-space process. With HID-BPF this means we can eventually "firewall" these devices from malicious applications: we could e.g. allow libratbag to configure your mouse' buttons but block any attempts to upload a new firmware. This is very much an idea for now, there's a lot of code that needs to be written to get there. But getting there we can now, so full of optimism we go[2].

[0] to illustrate: the button that goes back in your browser is actually evdev's BTN_SIDE and BTN_BACK is ... just another button assigned to nothing particular by default.
[1] and c) I have to care less about X server CVEs.
[2] mind you, optimism is just another word for naïveté

GNOME tablet support papercut fixes

Over the last months I've started looking into a few of the papercuts that affects graphics tablet users in GNOME. So now that most of those have gone in, let's see what has happened:

Calibration fixes and improvements (GNOME 47)

The calibration code, a descendent of the old xinput_calibrator tool was in a pretty rough shape and didn't work particularly well. That's now fixed and I've made the calibrator a little bit easier to use too. Previously the timeout was quite short which made calibration quite stressfull, that timeout is now per target rather than to complete the whole calibration process. Likewise, the calibration targets now accept larger variations - something probably not needed for real use-cases (you want the calibration to be exact) but it certainly makes testing easier since clicking near the target is good enough.

The other feature added was to allow calibration even when the tablet is manually mapped to a monitor. Previously this only worked in the "auto" configuration but some tablets don't correctly map to the right screen and lost calibration abilities. That's fixed now too.

A picture says a thousand words, except in this case where the screenshot provides no value whatsoever. But here you have it anyway.

Generic tablet fallback (GNOME 47)

Traditionally, GNOME would rely on libwacom to get some information about tablets so it could present users with the right configuration options. The drawback was that a tablet not recognised by libwacom didn't exist in GNOME Settings - and there was no immediately obvious way of fixing this, the panel either didn't show up or (with multiple tablets) the unrecognised one was missing. The tablet worked (because the kernel and libinput didn't require libwacom) but it just couldn't be configured.

libwacom 2.11 changed the default fallback tablet to be a built-in one since this is now the most common unsupported tablet we see. Together with the new fallback handling in GNOME settings this means that any unsupported tablet is treated as a generic built-in tablet and provides the basic configuration options for those (Map to Monitor, Calibrate, assigning stylus buttons). The tablet should still be added to libwacom but at least it's no longer a requirement for configuration. Plus there's now a link to the GNOME Help to explain things. Below is a screenshot on how this looks like (after modifying my libwacom to no longer recognise the tablet, poor Intuos).

Monitor mapping names (GNOME 47)

For historical reasons, the names of the display in the GNOME Settings Display configuration differed from the one used by the Wacom panel. Not ideal and that bit is now fixed with the Wacom panel listing the name of the monitor and the connector name if multiple monitors share the same name. You get the best value out of this if you have a monitor vendor with short names. (This is not a purchase recommendation).

Highlighted SVGs (GNOME 46)

If you're an avid tablet user, you may have multiple stylus tools - but it's also likely that you have multiple tools of the same type which makes differentiating them in the GUI hard. Which is why they're highlighted now - if you bring the tool into proximity, the matching image is highlighted to make it easier to know which stylus you're about to configure. Oh, and in the process we added a new SVG for AES styli too to make the picture look more like the actual physical tool. The <blink> tag may no longer be cool but at least we can disco our way through the stylus configuration now.

More Pressure Curves (GNOME 46)

GNOME Settings historically presents a slider from "Soft" to "Firm" to adjust the feel of the tablet tip (which influences the pressure values sent to the application). Behind the scenes this was converted into a set of 7 fixed curves but thanks to a old mutter bug those curves only covered a small amount of the possible range. This is now fixed so you can really go from pencil-hard to jelly-soft and the slider now controls an almost-continous range instead of just 7 curves. Behold, a picture of slidery goodness:

Miscellaneous fixes

And of course a bunch of miscellaneous fixes. Things that I quickly found were support for Alt in the tablet pad keymappings, fixing of erroneous backwards movement when wrapping around on the ring, a long-standing stylus button mismatch, better stylus naming and a rather odd fix causing configuration issues if the eraser was the first tool ever to be brought into proximity.

There are a few more things in the pipe but I figured this is enough to write a blog post so I no longer have to remember to write a blog post about all this.