Standard Setup of Toolchain for Windows
Introduction
ESP-IDF requires some prerequisite tools to be installed so you can build firmware for supported chips. The prerequisite tools include Python, Git, cross-compilers, CMake and Ninja build tools.
For this Getting Started we’re going to use the Command Prompt, but after ESP-IDF is installed you can use Eclipse Plugin or another graphical IDE with CMake support instead.
Note
Limitations: - The installation path of ESP-IDF and ESP-IDF Tools must not be longer than 90 characters. Too long installation paths might result in a failed build. - The installation path of Python or ESP-IDF must not contain white spaces or parentheses. - The installation path of Python or ESP-IDF should not contain special characters (non-ASCII) unless the operating system is configured with “Unicode UTF-8” support.
System Administrator can enable the support via Control Panel - Change date, time, or number formats - Administrative tab - Change system locale - check the option “Beta: Use Unicode UTF-8 for worldwide language support” - Ok and reboot the computer.
ESP-IDF Tools Installer
The easiest way to install ESP-IDF’s prerequisites is to download one of ESP-IDF Tools Installers.
What is the usecase for Online and Offline Installer
Online Installer is very small and allows the installation of all available releases of ESP-IDF. The installer will download only necessary dependencies including Git For Windows during the installation process. The installer stores downloaded files in the cache directory %userprofile%\.espressif
Offline Installer does not require any network connection. The installer contains all required dependencies including Git For Windows .
Components of the installation
The installer deploys the following components:
The installer also allows reusing the existing directory with ESP-IDF. The recommended directory is %userprofile%\Desktop\esp-idf
where %userprofile%
is your home directory.
Launching ESP-IDF Environment
At the end of the installation process you can check out option Run ESP-IDF PowerShell Environment
or Run ESP-IDF Command Prompt (cmd.exe)
. The installer will launch ESP-IDF environment in selected prompt.
Run ESP-IDF PowerShell Environment
:
Run ESP-IDF Command Prompt (cmd.exe)
:
Using the Command Prompt
For the remaining Getting Started steps, we’re going to use the Windows Command Prompt.
ESP-IDF Tools Installer also creates a shortcut in the Start menu to launch the ESP-IDF Command Prompt. This shortcut launches the Command Prompt (cmd.exe) and runs export.bat
script to set up the environment variables (PATH
, IDF_PATH
and others). Inside this command prompt, all the installed tools are available.
Note that this shortcut is specific to the ESP-IDF directory selected in the ESP-IDF Tools Installer. If you have multiple ESP-IDF directories on the computer (for example, to work with different versions of ESP-IDF), you have two options to use them:
Create a copy of the shortcut created by the ESP-IDF Tools Installer, and change the working directory of the new shortcut to the ESP-IDF directory you wish to use.
Alternatively, run
cmd.exe
, then change to the ESP-IDF directory you wish to use, and runexport.bat
. Note that unlike the previous option, this way requires Python and Git to be present inPATH
. If you get errors related to Python or Git not being found, use the first option.
First Steps on ESP-IDF
Now since all requirements are met, the next topic will guide you on how to start your first project.
This guide will help you on the first steps using ESP-IDF. Follow this guide to start a new project on the ESP32-C3 and build, flash, and monitor the device output.
Note
If you have not yet installed ESP-IDF, please go to Installation and follow the instruction in order to get all the software needed to use this guide.
Start a Project
Now you are ready to prepare your application for ESP32-C3. You can start with get-started/hello_world project from examples directory in ESP-IDF.
Important
The ESP-IDF build system does not support spaces in the paths to either ESP-IDF or to projects.
Copy the project get-started/hello_world to ~/esp
directory:
cd %userprofile%\esp
xcopy /e /i %IDF_PATH%\examples\get-started\hello_world hello_world
Note
There is a range of example projects in the examples directory in ESP-IDF. You can copy any project in the same way as presented above and run it. It is also possible to build examples in-place without copying them first.
Connect Your Device
Now connect your ESP32-C3 board to the computer and check under which serial port the board is visible.
Serial port names start with COM
in Windows.
If you are not sure how to check the serial port name, please refer to Establish Serial Connection with ESP32-C3 for full details.
Note
Keep the port name handy as you will need it in the next steps.
Configure Your Project
Navigate to your hello_world
directory, set ESP32-C3 as the target, and run the project configuration utility menuconfig
.
Windows
cd %userprofile%\esp\hello_world
idf.py set-target esp32c3
idf.py menuconfig
After opening a new project, you should first set the target with idf.py set-target esp32c3
. Note that existing builds and configurations in the project, if any, will be cleared and initialized in this process. The target may be saved in the environment variable to skip this step at all. See Select the Target Chip: set-target for additional information.
If the previous steps have been done correctly, the following menu appears:
You are using this menu to set up project specific variables, e.g., Wi-Fi network name and password, the processor speed, etc. Setting up the project with menuconfig may be skipped for “hello_word”, since this example runs with default configuration.
Note
The colors of the menu could be different in your terminal. You can change the appearance with the option --style
. Please run idf.py menuconfig --help
for further information.
Build the Project
Build the project by running:
idf.py build
This command will compile the application and all ESP-IDF components, then it will generate the bootloader, partition table, and application binaries.
$ idf.py build
Running cmake in directory /path/to/hello_world/build
Executing "cmake -G Ninja --warn-uninitialized /path/to/hello_world"...
Warn about uninitialized values.
-- Found Git: /usr/bin/git (found version "2.17.0")
-- Building empty aws_iot component due to configuration
-- Component names: ...
-- Component paths: ...
... (more lines of build system output)
[527/527] Generating hello_world.bin
esptool.py v2.3.1
Project build complete. To flash, run this command:
../../../components/esptool_py/esptool/esptool.py -p (PORT) -b 921600 write_flash --flash_mode dio --flash_size detect --flash_freq 40m 0x10000 build/hello_world.bin build 0x1000 build/bootloader/bootloader.bin 0x8000 build/partition_table/partition-table.bin
or run 'idf.py -p PORT flash'
If there are no errors, the build will finish by generating the firmware binary .bin files.
Flash onto the Device
To flash the binaries that you just built for the ESP32-C3 in the previous step, you need to run the following command:
idf.py -p PORT flash
Replace PORT
with your ESP32-C3 board’s USB port name. If the PORT
is not defined, the idf.py will try to connect automatically using the available USB ports.
For more information on idf.py
arguments, see idf.py.
Note
The option flash
automatically builds and flashes the project, so running idf.py build
is not necessary.
Encountered Issues While Flashing? See this Flashing Troubleshooting page or Establish Serial Connection with ESP32-C3 for more detailed information.
Normal Operation
When flashing, you will see the output log similar to the following:
...
esptool.py --chip esp32c3 -p /dev/ttyUSB0 -b 460800 --before=default_reset --after=hard_reset write_flash --flash_mode dio --flash_freq 80m --flash_size 2MB 0x8000 partition_table/partition-table.bin 0x0 bootloader/bootloader.bin 0x10000 hello_world.bin
esptool.py v3.0
Serial port /dev/ttyUSB0
Connecting....
Chip is ESP32-C3
Features: Wi-Fi
Crystal is 40MHz
MAC: 7c:df:a1:40:02:a4
Uploading stub...
Running stub...
Stub running...
Changing baud rate to 460800
Changed.
Configuring flash size...
Compressed 3072 bytes to 103...
Writing at 0x00008000... (100 %)
Wrote 3072 bytes (103 compressed) at 0x00008000 in 0.0 seconds (effective 4238.1 kbit/s)...
Hash of data verified.
Compressed 18960 bytes to 11311...
Writing at 0x00000000... (100 %)
Wrote 18960 bytes (11311 compressed) at 0x00000000 in 0.3 seconds (effective 584.9 kbit/s)...
Hash of data verified.
Compressed 145520 bytes to 71984...
Writing at 0x00010000... (20 %)
Writing at 0x00014000... (40 %)
Writing at 0x00018000... (60 %)
Writing at 0x0001c000... (80 %)
Writing at 0x00020000... (100 %)
Wrote 145520 bytes (71984 compressed) at 0x00010000 in 2.3 seconds (effective 504.4 kbit/s)...
Hash of data verified.
Leaving...
Hard resetting via RTS pin...
Done
If there are no issues by the end of the flash process, the board will reboot and start up the “hello_world” application.
If you’d like to use the Eclipse or VS Code IDE instead of running idf.py
, check out Eclipse Plugin, VSCode Extension.
Monitor the Output
To check if “hello_world” is indeed running, type idf.py -p PORT monitor
(Do not forget to replace PORT with your serial port name).
This command launches the IDF Monitor application:
$ idf.py -p <PORT> monitor
Running idf_monitor in directory [...]/esp/hello_world/build
Executing "python [...]/esp-idf/tools/idf_monitor.py -b 115200 [...]/esp/hello_world/build/hello_world.elf"...
--- idf_monitor on <PORT> 115200 ---
--- Quit: Ctrl+] | Menu: Ctrl+T | Help: Ctrl+T followed by Ctrl+H ---
ets Jun 8 2016 00:22:57
rst:0x1 (POWERON_RESET),boot:0x13 (SPI_FAST_FLASH_BOOT)
ets Jun 8 2016 00:22:57
...
After startup and diagnostic logs scroll up, you should see “Hello world!” printed out by the application.
...
Hello world!
Restarting in 10 seconds...
This is esp32c3 chip with 1 CPU core(s), WiFi/BLE, silicon revision 0, 2 MB external flash
Minimum free heap size: 337332 bytes
Restarting in 9 seconds...
Restarting in 8 seconds...
Restarting in 7 seconds...
To exit IDF monitor use the shortcut Ctrl+]
.
Note
You can combine building, flashing and monitoring into one step by running:
idf.py -p PORT flash monitor
See also:
IDF Monitor for handy shortcuts and more details on using IDF monitor.
idf.py for a full reference of
idf.py
commands and options.
That’s all that you need to get started with ESP32-C3!
Now you are ready to try some other examples, or go straight to developing your own applications.
Important
Some of examples do not support ESP32-C3 because required hardware is not included in ESP32-C3 so it cannot be supported.
If building an example, please check the README file for the Supported Targets
table. If this is present including ESP32-C3 target, or the table does not exist at all, the example will work on ESP32-C3.
Additional Tips
Permission issues /dev/ttyUSB0
With some Linux distributions, you may get the Failed to open port /dev/ttyUSB0
error message when flashing the ESP32-C3. This can be solved by adding the current user to the dialout group.
Python compatibility
ESP-IDF supports Python 3.7 or newer. It is recommended to upgrade your operating system to a recent version satisfying this requirement. Other options include the installation of Python from sources or the use of a Python version management system such as pyenv.
Flash Erase
Erasing the flash is also possible. To erase the entire flash memory you can run the following command:
idf.py -p PORT erase-flash
For erasing the OTA data, if present, you can run this command:
idf.py -p PORT erase-otadata
The flash erase command can take a while to be done. Do not disconnect your device while the flash erasing is in progress.