# 0x06 ADC Rust Driver This repository contains a Bare-Metal Rust driver for the ADC (Analog-to-Digital Converter) peripheral on the **RP2350** (and RP2040) microcontrollers. It includes: - A thin demo (`src/main.rs`) that continuously reads the analog voltage on GPIO 26 and the internal chip temperature, printing both over UART. - A reusable library module (`src/adc.rs`) providing a hardware-agnostic `adc_lib` with helper math to map raw ADC counts to millivolts and degrees Celsius. - Board initialization logic (`src/board.rs`). ## 🚀 Getting Started from Scratch If you're starting with a fresh machine, follow these exact steps to install the toolchain, build the code, and flash it to your microcontroller. ### 1. Install Rust First, install `rustup` (the Rust toolchain installer) if you haven't already: ```bash curl --proto '=https' --tlsv1.2 -sSf https://sh.rustup.rs | sh ``` *Note: Restart your terminal or run `source $HOME/.cargo/env` after this finishes.* Ensure your Rust compiler is up to date: ```bash rustup update ``` ### 2. Install the Target Architecture This project is configured for the **RP2350** (ARM Cortex-M33). We need to install the cross-compilation target for it: ```bash rustup target add thumbv8m.main-none-eabihf ``` *(If you were targeting the RP2040, you would use `thumbv6m-none-eabi` instead).* ### 3. Install Build Tools You will need a few extra tools to help link and format the firmware for the RP-series chips. Install `flip-link` (adds zero-cost stack overflow protection): ```bash cargo install flip-link ``` Install `picotool` (used by `cargo run` to flash the chip): - **macOS:** `brew install picotool` - **Linux/Windows:** Follow the official Raspberry Pi documentation to install `picotool` or build it from source. ### 4. Building the Code To compile the code for the microcontroller, simply run: ```bash cargo build ``` To build a highly optimized release version (smaller and faster): ```bash cargo build --release ``` ### 5. Flashing to the Microcontroller This project is pre-configured in `.cargo/config.toml` to use `picotool` as the custom runner. To flash the code: 1. Hold down the **BOOTSEL** button on your RP2350 board. 2. Plug it into your computer via USB (or press the RUN/RESET button while holding BOOTSEL). 3. Run the following command: ```bash cargo run --release ``` *`cargo` will compile the code and automatically use `picotool` to upload the `.elf` file directly to your board and start executing it!* ### 6. Testing on the Host Because the ADC mathematical conversion logic is separated into a reusable math library without touching hardware registers, you can run the unit tests natively on your computer! However, because this project sets a default bare-metal target (`thumbv8m.main-none-eabihf`) in `.cargo/config.toml`, running a plain `cargo test` will fail because the standard library doesn't exist on the microcontroller. You must explicitly tell Cargo to compile the tests for your host computer's processor architecture: **Mac (Apple Silicon):** ```bash cargo test --lib --target aarch64-apple-darwin ``` **Linux (Intel/AMD 64-bit):** ```bash cargo test --lib --target x86_64-unknown-linux-gnu ``` **Windows (64-bit):** ```bash cargo test --lib --target x86_64-pc-windows-msvc ``` ## 🧠 Code Walkthrough This section explains exactly how the code works, where the entry point is, and traces the flow of execution as if you were stepping through it line-by-line. ### 1. The Entry Point (`src/main.rs`) Unlike a standard computer program, bare-metal microcontrollers do not have an operating system to call `main()`. Instead, we use the `#[entry]` macro from the HAL (Hardware Abstraction Layer) to define the very first function that runs after the chip boots up. * **`main() -> !`**: This is the absolute start of our code. It takes ownership of all the hardware peripherals (`hal::pac::Peripherals::take().unwrap()`) and immediately passes them into `board::run(...)`. The `-> !` means this function never returns (because embedded devices run in an infinite loop). ### 2. Board Initialization (`src/board.rs`) Once execution enters `board.rs`, we initialize the system clocks, pins, UART (for logging), SysTick (for delay), and the ADC (for reading analog inputs). * **`run(...)`**: The master setup function. Calls the helper initialization functions below, prints an announcement over UART, and enters the infinite ADC polling loop. * **`init_clocks(...)`**: Wakes up the external 12 MHz crystal (`XOSC`) and configures the PLLs (Phase-Locked Loops) to drive the system clock at its maximum speed. * **`init_pins(...)`**: Takes control of physical pins across `IO_BANK0`. * **`init_uart(...)`**: Configures the hardware `UART0` peripheral to operate at a standard `115200` baud rate with an `8N1` configuration for debug printing. * **`init_adc(...)`**: Initializes the hardware ADC peripheral, allocates `GPIO 26` as an analog input pin, and claims the internal chip temperature sensor. * **`adc_loop(...)`**: Loops infinitely, reading the latest voltage and temperature, formatting the line, transmitting it over UART, and sleeping for `POLL_MS` (500ms). * **`read_adc(...)`**: Queries the hardware ADC peripheral for the current 12-bit analog counts for both `GPIO 26` and the internal temp sensor, then passes those raw counts to the `adc_lib` math helpers to convert them to millivolts (mV) and degrees Celsius. * **`format_adc_line(...)`**: Safely constructs a formatted string like `ADC0: 1650 mV | Chip temp: 34.5 C\r\n` without using the heap or standard library formatting mechanisms, relying instead on custom integer-to-ascii division algorithms (`write_mv_digits`, `write_temp`, etc.). ### 3. The Reusable ADC Math Library (`src/adc.rs`) The hardware ADC returns a raw 12-bit number between `0` and `4095`. This number represents a ratio of the measured voltage compared to the ADC reference voltage (which is 3.3V, or 3300mV). * **`raw_to_mv(...)`**: Linearly maps a 12-bit ADC result (`0..=4095`) to a voltage in millivolts (`0..=3300`). * **`raw_to_celsius(...)`**: Takes a 12-bit reading from the internal temperature sensor (Channel 4) and applies the datasheet-specified polynomial equation to yield the core temperature in degrees Celsius as a floating-point number.