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Add coding retreat post
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@ -296,6 +296,10 @@ them something at the same time.
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All in all it was a fun project and excellent conference. If you're interested,
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[the Rust source for the badge is on GitHub][source].
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<div class="seperator"><hr class="left">✦<hr class="right"></div>
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Next Post: [Rebuilding My Personal Infrastructure With Alpine Linux and Docker](/technical/2019/02/alpine-linux-docker-infrastructure/)
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[BADGEr]: https://wyolum.com/projects/badger/
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[edunham-talk]: https://youtu.be/uCnnhMleoKA?t=530
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[edunham]: http://edunham.net/
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@ -4,7 +4,7 @@ extra: For linux.conf.au 2019 I built a digital conference badge using a Raspber
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kind: article
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section: technical
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created_at: 2019-01-27 11:00:00.000000000 +11:00
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updated_at: 2019-01-28T20:08:26+11:00
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updated_at: 2019-03-13T20:39:51+11:00
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keywords:
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- rust
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- linux
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@ -124,7 +124,7 @@ decided early on that these weren't really for me:
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- A lot of them build the package from source instead of just installing the
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Alpine package.
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- The Docker build was more complicated that I needed as it was trying to be
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- The Docker build was more complicated than I needed as it was trying to be
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a generic image that anyone could pull and use.
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- I wasn't a huge fan of pulling random Docker images from the Internet, even
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if they were official images.
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@ -384,6 +384,11 @@ TLS negotiations to one.
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Thanks for reading, I hope the bits didn't take too long to get from Australia
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to wherever you are. Happy computing!
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<div class="seperator"><hr class="left">✦<hr class="right"></div>
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Previous Post: [My Rust Powered linux.conf.au e-Paper Badge](/technical/2019/01/linux-conf-au-rust-epaper-badge/)
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Next Post: [A Coding Retreat and Getting Embedded Rust Running on a SensorTag](/technical/2019/03/sensortag-embedded-rust-coding-retreat/)
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[acme.sh]: https://github.com/Neilpang/acme.sh
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[Alpine Linux]: https://alpinelinux.org/
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[alpine-3.9.1]: https://alpinelinux.org/posts/Alpine-3.9.1-released.html
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@ -4,7 +4,7 @@ extra: My story of replacing three servers, across two countries, running two op
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kind: article
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section: technical
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created_at: 2019-02-28 09:45:00.000000000 +11:00
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updated_at: 2019-03-02T14:09:11+11:00
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updated_at: 2019-03-13T20:37:45+11:00
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keywords:
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- docker
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- linux
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@ -0,0 +1,241 @@
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This past long weekend some friends on I went on a coding retreat inspired by
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John Carmack doing similar in 2018. During the weekend I worked on adding
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support for the Texas Instruments SensorTag to the embedded Rust ecosystem.
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This post is a summary of the weekend and what I was able to achieve code wise.
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Back in March 2018 [John Carmack posted about a week long coding
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retreat][carmack] he went on to work on neural networks and [OpenBSD]. After
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reading the post I quoted it to some friends and commented:
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> > I finally took another week-long programming retreat, where I could work in
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> > hermit mode, away from the normal press of work.
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> > In the spirit of my retro theme, I had printed out several of Yann LeCun’s
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> > old papers and was considering doing everything completely off line, as if
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> > I was actually in a mountain cabin somewhere
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> I kind of love the idea of a week long code retreat in a cabin somewhere.
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One of my friends also liked the idea and actually made it happen! There was an
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initial attempt in June 2018 but life got in the way so it was postponed. At
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the start of the year he picked it up again and organised it for the Labour day
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long weekend, which just passed.
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We rented an Airbnb in the Dandenong Ranges, 45 minutes from Melbourne. Six
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people attended, two of which were from interstate. The setting was cozy, quiet
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and picturesque. Our days involved coding and collaborating, shared meals,
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and a walk or two around the surrounds.
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<figure>
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<img src="/images/2019/coding-retreat-sunrise.jpg" alt="Photo of a sunrise with trees and windmill visible" />
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<figcaption>The view from our accommodation one morning.</figcaption>
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</figure>
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After [linux.conf.au] I got inspired to set up some self-hosted home sensors
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and automation. I did some research and picked up two [Texas Instruments
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SensorTags][SensorTag] and a debugger add-on. It uses a [CC2650]
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microcontroller with an ARM Cortex-M3 core and has support a number for low
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power wireless standards, such as Bluetooth, ZigBee, and 6LoWPAN. The CC2650
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also has a low power 16-bit sensor controller that can be used to help achieve
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years long battery life from a single CR2032 button cell. In addition to the
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microcontroller the SensorTag also add a bunch of sensors, including:
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temperature, humidity, barometer, accelerometer, gyroscope, and light.
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<figure>
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<img src="/images/2019/sensortag.jpg" width="400" alt="Two SensorTags. One with it's rubberised case removed and debugger board attached" />
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<figcaption>Two SensorTags. One with it's rubberised case removed and
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debugger board attached.</figcaption>
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</figure>
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My project for the weekend was to try to get some [Rust] code running on the
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SensorTag. Rust has good support out of the box for targeting ARM Cortex
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microcontrollers but there were no crates to make interacting with this
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particular chip or board easy, so I set about building some.
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The first step was generating a basic crate to allow interacting with the chip
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without needing to wrap everything in an `unsafe` block and poke at random
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memory addresses. Fortunately [svd2rust] can automate this by converting System
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View Description XML files (SVD) into a Rust crate. Unfortunately TI don't
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publish SVD files for their devices. As luck would have it though, [M-Labs]
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have found that TI do publish XML descriptions in format of their own called
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DSLite. They have written a tool, [dslite2svd], that converts this to SVD, so
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you can then use `svd2rust`. It took a while to get `dslite2svd` working and I
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had to tweak to the tool to handle differences in the files I was processing,
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but eventually I was able to generate a crate that compiled.
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Now that I had an API for the chip I turned to working out how to program and
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debug the SensorTag with a very basic Rust program. I used the excellent
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[embedded Rust Discovery guide][discovery] as a basis for the configuration,
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tools, and process for getting code onto the SensorTag. Since this was a
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different chip from a different manufacturer it took a long time to work out
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which tools worked, how to configure them, what format binaries they wanted,
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create a linker script, etc. A lot of trial and error was performed, along with
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lots of searching online with less than perfect internet. However, by Sunday I
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could program the device, debug code, and verify that my very basic program,
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shown below, was running.
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```language-rust
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fn main() -> ! {
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let _y;
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let x = 42;
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_y = x;
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// infinite loop; just so we don't leave this stack frame
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loop {}
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}
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```
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The combination that worked for programming was:
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* `cargo build --target thumbv7m-none-eabi`
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* Convert ELF to BIN using `cargo objcopy`, which is part of [cargo-binutils]:
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`cargo objcopy --bin sensortag --target thumbv7m-none-eabi -- -O binary sensortag.bin`
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* Program with [UniFlash]:
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* Choose CC2650F128 and XDS1100 on the first screen
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* Do a full erase the first time to reset CCFG, etc
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* Load image (select the `.bin` file produced above)
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For debugging:
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* Build OpenOCD from git to get support for the chip and debugger (I used the
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existing [AUR package][openocd-git])
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* Run OpenOCD: `openocd -f jtag/openocd.cfg`
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* Use GDB to debug: `arm-none-eabi-gdb -x jtag/gdbinit -q target/thumbv7m-none-eabi/debug/sensortag`
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* The usual `mon reset halt` in GDB upsets the debugger connection. I found
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that `soft_reset_halt` was able to reset the target (although it complains
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about being deprecated).
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_**Note:** Files in the `jtag` path above are in my
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[sensortag repo](https://git.sr.ht/~wezm/sensortag/tree/master/jtag).
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Trying to program through `openocd` failed with an error that the `vEraseFlash`
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command failed. I'd be curious to know if anyone has got this working as I'd
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very much like to ditch the huge 526.5 MiB UniFlash desktop-web-app dependency
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in my workflow._
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Now that I could get code to run on the SensorTag I set about trying to use the
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generated chip support crate to flash one of the on board LEDs. I didn't
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succeed in getting this working by the time the retreat came to an end, but
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after I arrived home I was able to find the source of the hard faults I was
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encountering and get the LED blinking! The key was that I needed to power up
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the peripheral power domain and enable the GPIO clocks to be able to enable an
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output GPIO.
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<figure>
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<video src="/images/2019/sensortag-flashing-led.m4v" width="384" autoplay controls muted loop playsinline></video>
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<figcaption>It works!</figcaption>
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</figure>
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Below is the code that flashes the LED. It should be noted this code is
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operating with very little abstraction and is using register and field names
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that match the data sheet. Future work to implement the [embedded-hal] traits
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for this controller would make it less verbose and less cryptic.
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```language-rust
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#![deny(unsafe_code)]
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#![no_main]
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#![no_std]
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#[allow(unused_extern_crates)] // NOTE(allow) bug rust-lang/rust#53964
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extern crate panic_halt; // panic handler
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// SensorTag is using RGZ package. VQFN (RGZ) | 48 pins, 7×7 QFN
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use cc2650_hal as hal;
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use cc2650f128;
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use cortex_m_rt::entry;
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use hal::{ddi, delay::Delay, prelude::*};
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pub fn init() -> (Delay, cc2650f128::Peripherals) {
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let core_peripherals = cortex_m::Peripherals::take().unwrap();
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let device_peripherals = cc2650f128::Peripherals::take().unwrap();
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let clocks = ddi::CFGR {
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sysclk: Some(24_000_000),
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}
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.freeze();
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let delay = Delay::new(core_peripherals.SYST, clocks);
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// LEDs are connected to DIO10 and DIO15
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// Configure GPIO pins for output, maximum strength
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device_peripherals.IOC
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.iocfg10
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.modify(|_r, w| w.port_id().gpio().ie().clear_bit().iostr().max());
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device_peripherals.IOC
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.iocfg15
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.modify(|_r, w| w.port_id().gpio().ie().clear_bit().iostr().max());
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// Enable the PERIPH power domain and wait for it to be powered up
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device_peripherals.PRCM.pdctl0.modify(|_r, w| w.periph_on().set_bit());
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loop {
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if device_peripherals.PRCM.pdstat0.read().periph_on().bit_is_set() {
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break;
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}
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}
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// Enable the GPIO clock
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device_peripherals.PRCM.gpioclkgr.write(|w| w.clk_en().set_bit());
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// Load settings into CLKCTRL and wait for LOAD_DONE
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device_peripherals.PRCM.clkloadctl.modify(|_r, w| w.load().set_bit());
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loop {
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if device_peripherals.PRCM.clkloadctl.read().load_done().bit_is_set() {
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break;
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}
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}
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// Enable outputs
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device_peripherals.GPIO
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.doe31_0
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.modify(|_r, w| w.dio10().set_bit().dio15().set_bit());
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(delay, device_peripherals)
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}
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#[entry]
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fn entry() -> ! {
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let (mut delay, periphs) = init();
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let half_period = 500_u16;
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loop {
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// Turn LED on and wait half a second
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periphs.GPIO.dout11_8.modify(|_r, w| w.dio10().set_bit());
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delay.delay_ms(half_period);
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// Turn LED off and wait half a second
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periphs.GPIO.dout11_8.modify(|_r, w| w.dio10().clear_bit());
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delay.delay_ms(half_period);
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}
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}
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```
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The rest of the code is up on [Sourcehut]. It's all in a pretty rough state at
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the moment. I plan to tidy it up over the coming weeks and eventually publish
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the crates. If you're curious to see it now though, the repos are:
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* [cc2650f128](https://git.sr.ht/~wezm/cc2650f128) -- chip support crate
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generated by `dslite2svd` and `svd2rust`.
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* [cc26x0-hal](https://git.sr.ht/~wezm/cc26x0-hal) (see `wip` branch, currently
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very rough).
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* [sensortag](https://git.sr.ht/~wezm/sensortag) -- LED flashing code. I hope
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to turn this into a board support crate eventually.
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Overall the coding retreat was a great success and we hope to do another one
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next year.
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[cargo-binutils]: https://crates.io/crates/cargo-binutils
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[carmack]: https://www.facebook.com/permalink.php?story_fbid=2110408722526967&id=100006735798590
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[CC2650]: http://www.ti.com/product/CC2650
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[discovery]: https://rust-embedded.github.io/discovery/
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[dslite2svd]: https://github.com/m-labs/dslite2svd
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[embedded-hal]: https://crates.io/crates/embedded-hal
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[linux.conf.au]: /technical/2019/01/linux-conf-au-rust-epaper-badge/
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[M-Labs]: https://github.com/m-labs
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[OpenBSD]: https://www.openbsd.org/
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[openocd-git]: https://aur.archlinux.org/packages/openocd-git/
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[Rust]: https://www.rust-lang.org/
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[SensorTag]: http://www.ti.com/tool/cc2650stk
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[Sourcehut]: https://sourcehut.org/
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[svd2rust]: https://github.com/rust-embedded/svd2rust
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[UniFlash]: http://www.ti.com/tool/uniflash
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@ -0,0 +1,14 @@
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---
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title: A Coding Retreat and Getting Embedded Rust Running on a SensorTag
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extra: I attended a small coding retreat with some friends and worked on running Rust code on a CC2650 based TI SensorTag.
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kind: article
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section: technical
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created_at: 2019-03-12 19:45:00.000000000 +11:00
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#updated_at: 2019-03-02T14:09:11+11:00
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keywords:
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- rust
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- embedded
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- sensortag
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- arm
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- microcontroller
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short_url:
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output/images/2019/coding-retreat-sunrise.jpg
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output/images/2019/sensortag-flashing-led.m4v
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output/images/2019/sensortag-flashing-led.m4v
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output/images/2019/sensortag.jpg
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