A template for a "Hello, world!" Rust binary crate for the ESP-IDF framework. Based on cargo-generate.

This is the crate you get when running cargo new, but augmented with extra configuration so that it does build for the ESP32[XX] with ESP-IDF and (by default) with STD support.

Or if you rather

• ... want to mix Rust and C/C++ in a traditional ESP-IDF idf.py CMake project - follow these instructions
• ... want to mix Rust and C/C++ with PlatformIO - follow these instructions

For more check out the links in the additional information section

Please make sure you have installed all prerequisites first!

cargo generate esp-rs/esp-idf-template cargo

The command will display a few prompts:

• Project Name: Name of the crate.
• Which MCU to target?: SoC model, e.g. esp32, esp32s2, esp32c3 etc.
• Configure advanced template options?: If false, skips the rest of the prompts and uses their default value. If true, you will be prompted with:
  • Enable STD support?: When true (default), adds support for the Rust Standard Library. Otherwise, a no_std Rust Core Library crate would be created.
  • ESP-IDF Version: ESP-IDF branch/tag to use. Possible choices:
    • v4.4: Stable
    • v5.1: Stable
    • master: Unstable
  • Configure project to support Wokwi simulation with Wokwi VS Code extension?: Adds support for Wokwi simulation using VS Code Wokwi extension.
  • Configure project to use Dev Containers (VS Code and GitHub Codespaces)?: Adds support for:
    • VS Code Dev Containers
    • GitHub Codespaces Dev Containers also allow flashing from the container using web flash and have the VS Code Wokwi extension already installed.

cd <your-project-name>
cargo build

• Replace <your-project-name> with the name of the generated project

In the root of the generated project:

espflash flash target/<mcu-target>/debug/<your-project-name>

• espflash will print a list of the recognized USB ports for you to select the desired port, if it detectes multiple boards.
• Replace <your-project-name> with the name of the generated project
• You can include the --monitor argument to the espflash command to open a serial monitor after flashing the device.
• For more details on espflash usage see the README

espflash monitor /dev/ttyUSB0

• Replace dev/ttyUSB0 above with the USB port where you've connected the board. If you do not specify any USB port, cargo-espflash/espflash will print a list of the recognized USB ports for you to select the desired port.

The monitor should output more or less the following:

Opening /dev/tty.usbserial-0001 with speed 115200
Resetting device... done
ets Jun  8 2016 00:22:57

rst:0x1 (POWERON_RESET),boot:0x13 (SPI_FAST_FLASH_BOOT)
configsip: 0, SPIWP:0xee
clk_drv:0x00,q_drv:0x00,d_drv:0x00,cs0_drv:0x00,hd_drv:0x00,wp_drv:0x00
mode:DIO, clock div:2
load:0x3fff0048,len:12
ho 0 tail 12 room 4
load:0x3fff0054,len:4800
load:0x40078000,len:17448
load:0x4007c428,len:4840
entry 0x4007c6a0
I (178) cpu_start: Pro cpu up.
I (178) cpu_start: Starting app cpu, entry point is 0x4008115c
I (0) cpu_start: App cpu up.
I (193) cpu_start: Pro cpu start user code
I (193) cpu_start: cpu freq: 160000000
I (193) cpu_start: Application information:
I (197) cpu_start: Project name:     esp-idf
I (202) cpu_start: App version:      f08dcd7
I (207) cpu_start: Compile time:     Oct 23 2021 14:48:03
I (213) cpu_start: ELF file SHA256:  0000000000000000...
I (219) cpu_start: ESP-IDF:          4.3.0
I (224) heap_init: Initializing. RAM available for dynamic allocation:
I (231) heap_init: At 3FFAE6E0 len 00001920 (6 KiB): DRAM
I (237) heap_init: At 3FFB3498 len 0002CB68 (178 KiB): DRAM
I (243) heap_init: At 3FFE0440 len 00003AE0 (14 KiB): D/IRAM
I (250) heap_init: At 3FFE4350 len 0001BCB0 (111 KiB): D/IRAM
I (256) heap_init: At 4008C538 len 00013AC8 (78 KiB): IRAM
I (263) spi_flash: detected chip: generic
I (267) spi_flash: flash io: dio
I (272) cpu_start: Starting scheduler on PRO CPU.
I (0) cpu_start: Starting scheduler on APP CPU.
Hello, world!

For more information, check out:

• The Rust on ESP Book
• The ESP STD Embedded Training
• The esp-idf-hal project
• The embedded-hal project
• The esp-idf-svc project
• The embedded-svc project
• The esp-idf-sys project
• The Rust for Xtensa toolchain
• The Rust-with-STD demo project

Linux/Mac users: Make sure you have the dependencies installed,that are mentiond in the esp-idf install guide. You dont need to manually install esp-idf, just its dependencies.

For detailed instructions see Setting Up a Development Environment chapter of The Rust on ESP Book.

If you don't have rustup installed yet, follow the instructions on the rustup.rs site

cargo install cargo-generate
cargo install ldproxy
cargo install espup
cargo install espflash
cargo install cargo-espflash # Optional

# Debian/Ubuntu/etc.
apt-get install libudev-dev
# Fedora
dnf install systemd-devel

Also, the espflash and cargo-espflash commands shown below, assume that version 2.0 or greater.

espup install
# Unix
. $HOME/export-esp.sh

See the Installation chapter of The Rust on ESP Book for more details.

While you can target the RISC-V Espressif SOCs (esp32-cXX and esp32-hXX) with the espup installer just fine, SOCs with this architecture are also supported by the nightly Rust compiler and by recent, stock Clang compilers (as in Clang 11+):

• Install a recent Clang. See Clang Getting Started page as it contains useful guidelines on installation. Recent Linux distros come with suitable Clang already.
• Install the nightly Rust toolchain with the rust-src component included:

  rustup toolchain install nightly --component rust-src

• Run any Cargo command with the nightly toolchain override, i.e. cargo +nightly ....

You need a Python 3.7 or later installed on your machine.

• Linux, Mac OS X: if not preinstalled already, just install it with your package manager, i.e. for Debian systems: sudo apt install python3
• Windows: install it e.g. from the official Python site.

You'll also need the Python PIP and Python VENV modules. On Debian systems, you can install with:

• sudo apt install python3-pip python3-venv