This project provides a library to interact with the Waveshare E-Ink Displays written in OCaml. It is intended to run on a Raspberry Pi and interact with the IT8951 HAT via SPI. A future goal for this project is to provide executables which explore the usage of this library, some of which could be: a terminal, a VNC client, a kernel module to implement a graphics driver or a custom/adapted GUI library.
It is quite similar to PaperTTY(https://github.com/joukos/PaperTTY) which is implemented in Python and provides both a terminal and VNC client. As this is a personal hobby PaperTTY is superior in almost all aspects.
The source code is split into three directories:
- lib: contains the library to interact with the display, more details below
- bin: contains the executables which use the library, currently only contains the terminal emulator
- tests: contains all the tests
The library is split into four layers, each of which is concerned with a specific abstraction:
- Bus and bus.c/h: Implements the SPI interface with the IT8951
- Command: Implements the commands defined by the IT8951 and memory/register access
- Controller and State: Provides an interface to interact with the screen on a simplified level: It allows transmitting the buffer to the IT8951 and displaying it onto the E-Ink Display.
- EPD and Bresenham: Provides facilities to quickly test the library, i.e. plotting dots and lines. This layer will perhaps be moved into the bin directory.
- bcm2835 library
- OCaml compiler
- dune, ctypes, ctypes-foreign (see
dune external-lib-deps $build_target) - utop for interactive usage
Run either of the following commands. Root privileges are necessary to access the pins.
dune exec bin/term.exefor the terminal emulatordune utop libfor interactive utop REPL with the librarydune testto run the tests specified in tests/dune
My goal is to run this project on the Raspberry Pi 3A+. My distro of choice is Void Linux. Unfortunately Void does not have good support of the newer Pis and getting it to run involved some work. I chose to run U-Boot first to enable some flexibility in the future (Network boot, USB boot, independent layer below Linux which always works). This is in theory quite simple:
- Flash the Linux image
- Place the U-Boot image (see below) alongside the kernel in the /boot partition/directory
- Append to config.txt:
kernel=u-boot.img
(the following are perhaps unnecessary)
arm_64bit=1
device_tree_address=0x100
device_tree_end=0x8000\ - Freeze the kernel and firmware as updates to them break the system via
xbps-pkgdb -m hold rpi-firmware rpi-kernel
Be careful to gracefully shut down the Pi at all times as power loss corrupts the SD card (as indicated by the fsck after reboot)
The mainline U-Boot repository has support for most Raspberry Pis and their features.
The two main configuration options relevant here are:
CONFIG_BOOTARGS="root=/dev/mmcblk0p2 rw rootwait console=ttyAMA0,115200 kgdboc=ttyAMA0,115200 console=tty1 smsc95xx.turbo_mode=N dwc_otg.lpm_enable=0 loglevel=4 elevator=noop"
and
CONFIG_BOOTCOMMAND="setenv fdtfile bcm2710-rpi-3-b-plus.dtb; mmc dev 0; fatload mmc 0:1 ${kernel_addr_r} kernel.img; fatload mmc 0:1 ${fdt_addr_r} ${fdtfile}; bootefi ${kernel_addr_r} ${fdt_addr_r}"\