Crates.io | libremarkable |
lib.rs | libremarkable |
version | 0.6.2 |
source | src |
created_at | 2018-03-23 21:36:45.504974 |
updated_at | 2022-12-12 10:16:47.36489 |
description | The only publicly available Framework for developing applications for the Remarkable Paper Tablet w/ Low Latency Partial Refresh Support |
homepage | |
repository | https://github.com/canselcik/libremarkable |
max_upload_size | |
id | 57138 |
size | 928,987 |
Everything from low latency partial updates to the eInk display to multitouch, physical button and Wacom Digitizer input is now understood and their minimal to complete implementations can be found in this repository.
This repository implements a Rust library for providing these features.
Potentially a piston
backend might be created for Remarkable
, allowing the use of conrod
to simplify UI creation.
For further documentation see the wiki on this repository.
https://github.com/canselcik/RemarkableFramebuffer
redirects to this repository for historical purposes.
In order to build libremarkable
and the examples (spy.so
and demo
), you'll need the toolchain from Remarkable. Download the installation script (rM2) and install the toolchain. You can find more information on the wiki.
You can then set up your Rust toolchain for cross compilation with: rustup target add armv7-unknown-linux-gnueabihf
.
In order for rust to leverage the toolchain a .cargo/config
file is required. This file can be generated using gen_cargo_config.py
. First the toolchain environment must be
sourced. Its location is can be found within the toolchain installation directory. The correct path is also referenced in the toolchain wiki.
After the environment is loaded the script will read the environment variables to generate the correct .cargo/config
file for your toolchain.
The resulting config file will look something like this:
[target.armv7-unknown-linux-gnueabihf]
linker = "<toolchain_install_path>/sysroots/x86_64-codexsdk-linux/usr/bin/arm-remarkable-linux-gnueabi/arm-remarkable-linux-gnueabi-gcc"
rustflags = [
"-C", "link-arg=-march=armv7-a",
"-C", "link-arg=-marm",
"-C", "link-arg=-mfpu=neon",
"-C", "link-arg=-mfloat-abi=hard",
"-C", "link-arg=-mcpu=cortex-a9",
"-C", "link-arg=--sysroot=<toolchain_install_path>/sysroots/cortexa7hf-neon-remarkable-linux-gnueabi",
]
You can also add this snippet to the above file in order to default to cross-compiling for this project:
[build]
# Set the default --target flag
target = "armv7-unknown-linux-gnueabihf"
A simple Makefile wrapper is created for convenience. It exposes the following verbs:
examples
: Builds exampleslibrary
: Builds libraryall
: library + examplesThe provided Makefile
assumes the device is reachable at 10.11.99.1
and that SSH Key-Based Authentication is set up for SSH so that you won't be prompted a password every time. The following actions are available:
run
: Builds and runs demo.rs
on the device after stopping xochitl
start-xochitl
: Stops all xochitl
and demo
instances and starts xochitl
normallyspy-xochitl
: Builds spy.rs
and LD_PRELOAD
s it to a new instance of xochitl
after
stopping the current instance. This allows discovery of new enums used by
official programs in calls to ioctl
.If you choose to skip the Makefile
and call cargo
yourself, make sure to include --release --target=armv7-unknown-linux-gnueabihf
in your arguments like:
➜ rust-poc git:(master) ✗ cargo build --release --target=armv7-unknown-linux-gnueabihf
...
Compiling libremarkable v0.1.0 (file:///home/main/Desktop/libremarkable)
Compiling rust-poc v0.1.0 (file:///home/main/Desktop/RemarkableFramebuffer/rust-poc)
Finished dev [unoptimized + debuginfo] target(s) in 24.85 secs
The --release
argument is important as this enables optimizations and without optimizations you'll be looking at ~70% CPU utilization even when idle. With optimizations, the framework runs really light, 0% CPU utilization when idle and 1-2% at peak.
cross
Building this way does not require reMarkable's toolchain nor building on Ubuntu 16.04 with Docker so setting up should be easier.
Install cross
with cargo install cross
. Make sure the reMarkable toolchain is not in use first.
To build, deploy and run the demo
, simply:
make TARGET=armv7-unknown-linux-gnueabihf deploy-x-demo
# This builds with
# cross build --example demo --release --target=armv7-unknown-linux-gnueabihf
# then deploys the demo
musl
cross build --example demo --release --target=armv7-unknown-linux-musleabihf
(or make x-demo
)make deploy-x-demo
Regarding apps for the rM2: you will need the display package from Toltec. Only the server part though as the client is built into this lib.
The first draft of libremarkable
was a C library, built while reverse engineering the tablet.
It's no longer maintained, but can be found on the legacy-c-impl
branch.