Linux serial port library written in C++.
Library for communicating with COM ports on a Linux system.
- Simple API
- Supports custom baud rates
cmake
based build system
-
Make sure you have
cmake
installed. -
Clone the git repo onto your local storage.
-
Change into root repo directory:
$ cd CppLinuxSerial
-
Create a new build directory and change into it:
$ mkdir build $ cd build
-
Run cmake on the parent directory to generate makefile:
$ cmake ..
-
Run make on the generated makefile to generate the static library
libCppLinuxSerial.a
and an unit test executable:$ make
-
To install the headers on your system:
$ sudo make install
-
To run the unit tests:
$ make run_unit_tests
NOTE: The unit tests used to use virtual serial ports via
stty
on Linux to do more thorough testing. I ran into permission problems running stty on TravisCI after they did an update and had to remove tests (leaving almost no tests remaining). If anyone wants to add better unit tests, it is greatly welcomed!
This project uses CMake and the export feature, so in a downstream CMake project that uses CppLinuxSerial as a dependency you should just be able to do this (thanks to https://github.com/borgmanJeremy for this contribution):
find_package(CppLinuxSerial REQUIRED)
...
...
target_link_libraries(target CppLinuxSerial::CppLinuxSerial)
#include <CppLinuxSerial/SerialPort.hpp>
using namespace mn::CppLinuxSerial;
int main() {
// Create serial port object and open serial port at 57600 baud, 8 data bits, no parity bit, one stop bit (8n1),
// and no flow control
SerialPort serialPort("/dev/ttyUSB0", BaudRate::B_57600, NumDataBits::EIGHT, Parity::NONE, NumStopBits::ONE);
// Use SerialPort serialPort("/dev/ttyACM0", 13000); instead if you want to provide a custom baud rate
serialPort.SetTimeout(100); // Block for up to 100ms to receive data
serialPort.Open();
// WARNING: If using the Arduino Uno or similar, you may want to delay here, as opening the serial port causes
// the micro to reset!
// Write some ASCII data
serialPort.Write("Hello");
// Read some data back (will block for up to 100ms due to the SetTimeout(100) call above)
std::string readData;
serialPort.Read(readData);
std::cout << "Read data = \"" << readData << "\"" << std::endl;
// Close the serial port
serialPort.Close();
}
If the above code was in a file called main.cpp
and you had installed CppLinuxSerial
following the instructions above, on a Linux system you should be able to compile the example application with:
g++ main.cpp -lCppLinuxSerial
If you wanted to enable flow control (hardware or software flow control), you can add it onto the end of the constructor as shown below. If you don't set them, they both default to OFF (the most common setting).
// Enabling hardware flow control
SerialPort serialPort("/dev/ttyUSB0", BaudRate::B_57600, NumDataBits::EIGHT, Parity::NONE, NumStopBits::ONE, HardwareFlowControl::ON, SoftwareFlowControl::OFF);
If you want to read and write binary rather than strings, you can use WriteBinary()
and ReadBinary()
which take vectors of bytes rather than std::string
:
serialPort.WriteBinary(const std::vector<uint8_t>& data);
serialPort.ReadBinary(std::vector<uint8_t>& data);
For more examples, see the files in test/
.
See GitHub Issues.
-
I get the error
Could not open device "/dev/ttyACM0". Is the device name correct and do you have read/write permissions?
, but the device is definitely there. You typically have to add your user to thedialout
group before you can accesstty
devices. -
My code stalls when calling functions like
SerialPort::Read()
. This is probably because the library is set up to do a blocking read, and not enough characters have been received to allowSerialPort::Read()
to return. CallSerialPort::SetTimeout(0)
before the serial port is open to set a non-blocking mode.
If you want to use this library in WSL, you'll have to use usbipd to pass-through the USB device.
usbipd wsl list
$ usbipd wsl list
BUSID VID:PID DEVICE STATE
1-1 046d:c332 USB Input Device Not attached
1-4 13d3:5666 USB2.0 HD UVC WebCam Not attached
1-5 2341:0043 Arduino Uno (COM4) Not attached
1-6 046d:0a9c Logitech G432 Gaming Headset, USB Input Device Not attached
1-8 0b05:1837 USB Input Device Not attached
1-9 8087:0a2a Intel(R) Wireless Bluetooth(R) Not attached
Attaching the Arduino Uno (need to be done with Admin priviliges the first time around):
usbipd wsl attach --busid=1-5
/dev/ttyACM0
now appears inside WSL, and you can use CppLinuxSerial
with this device like usual.
NOTE: Sometimes /dev/ttyACM0
is not part of the dialout group, so even with your user being part of that group, you will get permission denied errors when trying to access the serial port. Sometimes using chmod
to change the permissions works:
sudo chmod 666 /dev/ttyACM0
Serial port testing cannot really be done easily on cloud-based CICD platforms, as serial ports and devices connected to these ports are not readily available (nor configurable). CppLinuxSerial
relies on running tests manually on your local Linux OS, alongside a connected Arduino Uno configured to echo serial data back (at a later data this could be reconfigured to cycle through tests at different baud rates, parity settings, e.t.c).
You will need:
- Arduino Uno (or equivalent) dev kit.
- Linux OS.
Install the arduino-cli as per https://arduino.github.io/arduino-cli/0.21/installation/ on your local Linux machine.
Install the arduino:avr
platform:
$ arduino-cli core install arduino:avr
Make sure Arduino board is detected with:
$ arduino-cli board list
Run the following bash script:
./test/arduino/run.sh
This script will:
- Build and install
CppLinuxSerial
onto your local Linux OS. - Build and upload the test Arduino firmware to the connected Arduino Uno (it assumes it's connected to
/dev/ttyACM0
). - Build and run the test C++ application. This sends serial data to the Uno via CppLinuxSerial and expects the data to be echoed back.
See CHANGELOG.md.