rust-gpio-cdev is a Rust library/crate providing access to GPIO character device ABI. This API, stabilized with Linux v4.4, deprecates the legacy sysfs interface to GPIOs that is planned to be removed from the upstream kernel after year 2020 (which is coming up quickly).
Use of this API is encouraged over the sysfs API used by this crate's predecessor sysfs_gpio if you don't need to target older kernels. For more information on differences see Sysfs GPIO vs GPIO Character Device.
Add the following to your Cargo.toml
[dependencies]
gpio-cdev = "0.2"
There are several additional examples available in the examples directory.
use gpio_cdev::{Chip, LineRequestFlags};
// Read the state of GPIO4 on a raspberry pi. /dev/gpiochip0
// maps to the driver for the SoC (builtin) GPIO controller.
let mut chip = Chip::new("/dev/gpiochip0")?;
let handle = chip
.get_line(4)?
.request(LineRequestFlags::INPUT, 0, "read-input")?;
for _ in 1..4 {
println!("Value: {:?}", handle.get_value()?);
}
use gpio_cdev::{Chip, LineRequestFlags, EventRequestFlags, EventType};
// Lines are offset within gpiochip0; see docs for more info on chips/lines
//
// This function will synchronously follow the state of one line
// on gpiochip0 and mirror its state on another line. With this you
// could, for instance, control the state of an LED with a button
// if hooked up to the right pins on a raspberry pi.
fn mirror_gpio(inputline: u32, outputline: u32) -> gpio_cdev::errors::Result<()> {
let mut chip = Chip::new("/dev/gpiochip0")?;
let input = chip.get_line(inputline)?;
let output = chip.get_line(outputline)?;
let output_handle = output.request(LineRequestFlags::OUTPUT, 0, "mirror-gpio")?;
for event in input.events(
LineRequestFlags::INPUT,
EventRequestFlags::BOTH_EDGES,
"mirror-gpio",
)? {
let evt = event?;
println!("{:?}", evt);
match evt.event_type() {
EventType::RisingEdge => {
output_handle.set_value(1)?;
}
EventType::FallingEdge => {
output_handle.set_value(0)?;
}
}
}
Ok(())
}
Compared to the sysfs gpio interface (as made available by the sysfs_gpio crate) the character device has several advantages and critical design differences (some of which are driving the deprecation in the kernel).
Since many people are familiar with the sysfs interface (which is easily accessible via basic commands in the shell) and few people are familiar with the GPIO character device, an exploration of the two and key differences here may prove useful.
In the Linux kernel, individual GPIOs are exposed via drivers that on probe register
themselves as GPIO chips with the gpio subsystem. Each of these chips provides
access to a set of GPIOs. At present, when this chip is registered a global
base number is assigned to this driver. The comments from the linux kernel
gpio_chip_add_data
sum up the situation nicely when assignign the a base number to a GPIO chip
on registration.
/*
* TODO: this allocates a Linux GPIO number base in the global
* GPIO numberspace for this chip. In the long run we want to
* get *rid* of this numberspace and use only descriptors, but
* it may be a pipe dream. It will not happen before we get rid
* of the sysfs interface anyways.
*/
The entire sysfs interface to GPIO is based around offsets from the base number assigned to a GPIO chip. The base number is completely dependent on the order in which the chip was registered with the subsystem and the number of GPIOs that each of the previous chips registered. The only reason this is usable at all is that most GPIOs are accessed via SoC hardware that is registered consistently during boot. It's not great; in fact, it's not even good.
The GPIO character device ABI provides access to GPIOs owned by a GPIO chip via
a bus device, /sys/bus/gpiochipN
(or /dev/gpiochipN
). Within a chip, the
programmer will still need to know some details about how to access the GPIO but
things are generally sane. Figuring out which bus device is the desired GPIO
chip can be done by iterating over all that are present and/or setting up
appropriate udev rules. One good example of this is the lsgpio
utility in
the kernel source.
In sysfs each GPIO within a chip would be exported and used individually. The GPIO character device allows for one or more GPIOs (referenced via offsets) to be read, written, configured, and monitored via a "linehandle" fd that is created dynamically on request.
Using the sysfs API, one would write the global GPIO number to the "export" file
to perform further operations using new files on the filesystem. Using the
gpiochip character device, a handle for performing operations on one or more
GPIO offsets within a chip are available via a "linehandle" fd created using the
GPIO_GET_LINEHANDLE_IOCTL
. A consequence of this is that a line will remember
its state only for as long as the fd is open; the line's state will be reset
once the fd is closed.
When a linehandle is requested, additional information is also included about
how the individual GPIOs will be used (input, output, as-is, active-low, open
drain, open source, etc). Multiple lines can be grouped together in a single
request but they must all be configured the same way if being used in that way.
See struct gpioevent_request
.
Via sysfs, GPIOs could be read/written using the value file. For GPIO character
devices, the GPIOHANDLE_GET_LINE_VALUES_IOCTL
and
GPIOHANDLE_SET_LINE_VALUES_IOCTL
may be used to get/set the state of one or
more offsets within the chip.
Via sysfs, one could setup things up using the trigger file to notify userspace
(by polling on the value file) of a single event based on how things were setup.
With GPIO character devices, one can setup a gpio_eventrequest
that will create
a new anonymous file (fd provided) for event notifications on a lines within a
gpiochip. Contrary to sysfs gpio events, the event file will queue multiple events
and include with the event (best effort) nanosecond-precision timing and an
identifier with event type.
With this information one could more reasonably consider interpreting a basic digital signal from userspace (with rising and falling edges) from userspace using the queueing with timing information captured in the kernel. Previously, one would need to quickly handle the event notification, make another system call to the value file to see the state, etc. which had far too many variables involved to be considered reliable.
This crate is guaranteed to compile on stable Rust 1.34.0 and up. It might compile with older versions but that may change in any new patch release.
Licensed under either of
- Apache License, Version 2.0 (LICENSE-APACHE or http://www.apache.org/licenses/LICENSE-2.0)
- MIT license (LICENSE-MIT or http://opensource.org/licenses/MIT)
at your option.
Unless you explicitly state otherwise, any contribution intentionally submitted for inclusion in the work by you, as defined in the Apache-2.0 license, shall be dual licensed as above, without any additional terms or conditions.
Contribution to this crate is organized under the terms of the Rust Code of Conduct, the maintainer of this crate, the Embedded Linux Team, promises to intervene to uphold that code of conduct.