libremarkable 0.1.11

The only publicly available Framework for developing applications for the Remarkable Paper Tablet w/ Low Latency Partial Refresh Support
Documentation

libremarkable -- Application Development Framework for Remarkable Tablet https://crates.io/crates/libremarkable

PoC

Everything from low latency partial updates to the eInk display to at least minimal multitouch, physical button and Wacom Digitizer input is now understood and their minimal to complete implementations can be found in this repository.

The focus of this repository is now going to be the Rust library for providing these features. Potentially a piston backend might be created for Remarkable, allowing the use of conrod to simplify UI creation.

In cases where Rust implementation seems to contradict with the C implementation, the former can be taken as the source of truth as the libremarkable C implementation was the first-pass that came to being during the exploration stage.

For further documentation see the wiki.

https://github.com/canselcik/RemarkableFramebuffer redirects to this repository for historical purposes.

Build Instructions

Setting up the toolchain

In order to build libremarkable and the examples (spy.so and demo), you'll need the following configuration after having installed the proper toolchain to your $PATH. The arm-linux-gnueabihf-gcc toolchain is used to build both implementations.

The toolchain that would be acquired from either of these sources would be able to cross-compile for the Remarkable Tablet:

AUR:
  https://aur.archlinux.org/packages/arm-linux-gnueabihf-gcc/
Remarkable:
  https://remarkable.engineering/deploy/sdk/poky-glibc-x86_64-meta-toolchain-qt5-cortexa9hf-neon-toolchain-2.1.3.sh

You can then set up your Rust toolchain for cross compilation with: rustup target add armv7-unknown-linux-gnueabihf.

Once that's done, you should add the following to your ~/.cargo/config:

[target.armv7-unknown-linux-gnueabihf]
linker = "arm-linux-gnueabihf-gcc"

Building libremarkable and the examples

A simple Makefile wrapper is created for convenience. It exposes the following verbs:

  • examples: Builds examples
  • library: Builds library
  • all: library + examples

Testing libremarkable and the examples on the device

The 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 normally
  • spy-xochitl: Builds spy.rs and LD_PRELOADs 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.

Further build instructions for manual builds

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.