/microzig

Unified abstraction layer and HAL for several microcontrollers

Primary LanguageZigzlib LicenseZlib

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Note
This is in development; breaks in the API are bound to happen.

What version of Zig to use

0.11.0

Contributing

Please see the project page, it’s used as a place to brainstorm and organize work in ZEG. There will be issues marked as good first issue or drafts for larger ideas that need scoping/breaking ground on.

Introduction

This repo contains the infrastructure for getting started in an embedded Zig project; it "gets you to main()". Specifically, it offers:

  • a single easy-to-use builder function that:

    • generates your linker script

    • sets up packages and startup code

  • generalized interfaces for common devices, such as UART.

  • device drivers for interacting with external hardware

  • an uncomplicated method to define interrupts

Getting Started

Visit https://github.com/ZigEmbeddedGroup/microzig-examples to find examples for your specific board.

Design

For MicroZig internals please see the Design Document.

Does MicroZig support X hardware?

MicroZig is designed to cover as wide a swath of hardware as possible. The Zig Embedded Group has some repositories that contain hardware-specific code. You will find them with the hardware-support-package label. If you can’t find your specific device, it doesn’t mean that you can’t run Zig on it, it’s likely you’re just the first! In that case, see Getting MicroZig on New Hardware.

Start with an empty Zig project by running zig init-exe, and add the hardware support package as a submodule. We’ll use microchip-atmega in our example:

const std = @import("std");
const atmega = @import("deps/microchip-atmega/build.zig");

// the hardware support package should have microzig as a dependency
const microzig = @import("deps/hardware_support_package/deps/microzig/build.zig");

pub fn build(b: *std.build.Builder) !void {
    const optimize = b.standardOptimizeOption(.{});
    var exe = microzig.addEmbeddedExecutable( b, .{
        .name = "my-executable",
        .source_file = .{
            .path = "src/main.zig",
        },
        .backing = .{
            .board = atmega.boards.arduino_nano,

            // instead of a board, you can use the raw chip as well
            // .chip = atmega.chips.atmega328p,
        },
        .optimize = optimize,
    });
    exe.installArtifact(b);
}

zig build and now you have an executable for an Arduino Nano. In your application you can import microzig in order to interact with the hardware:

const microzig = @import("microzig");

// `microzig.config`: comptime access to configuration
// `microzig.chip`: access to register definitions, generated code
// `microzig.board`: access to board information
// `microzig.hal`: access to hand-written code for interacting with the hardware
// `microzig.cpu`: access to AVR5 specific functions

pub fn main() !void {
    // your program here
}

Getting MicroZig on New Hardware

If you have a board/chip that isn’t defined in microzig, you can set it up yourself! You need to have:

  • SVD or ATDF file defining registers

  • flash and ram address and sizes

First, use Regz to generate the register definitions for your chip and save them to a file. Then define the chip:

const nrf52832 = Chip{
    .name = "nRF52832",
    .source = .{
        .path = "path/to/generated/file.zig",
    },
    .cpu = cpus.cortex_m4,
    .memory_regions = &.{
        MemoryRegion{ .offset = 0x00000000, .length = 0x80000, .kind = .flash },
        MemoryRegion{ .offset = 0x20000000, .length = 0x10000, .kind = .ram },
    },
};

const backing = .{
    .chip = nrf52832,
};

It’s important that the chip name actually matches one of the entries under devices in the generated code.

Optional: JSON Register Schema

You can also invoke regz to generate a JSON representation of the hardware:

regz --json <path to svd/atdf>

This file could then be used by tooling. You can add it to a Chip like so:

const nrf52832 = Chip{
    .name = "nRF52832",
    .json_register_schema = .{
        .path = "path/to.json",
    },
    // ...
};

Interrupts

The currently supported architectures for interrupt vector generation are ARM and AVR. To define the Interrupt Service Routine (ISR) for a given interrupt, you create a function with the same name in an interrupts namespace, which is nested in a microzig_options namespace:

pub const microzig_options = struct {
  pub const interrupts = struct {
      pub fn PCINT0() void {
        // interrupt handling code
      }
  };
}

pub fn main() !void {
    // my application
}

We’re using compile-time checks along with the generated code to determine the list of interrupts. If a function is defined whose name is not in this list, you’ll get a compiler error with the list of interrupts/valid names.