Libsockcanpp
A complete C++ wrapper around socketcan.
libsockcanpp

Welcome to the documentation for libsockcanpp!
libsockcanpp is a socketcan wrapper library for C++, aimed to be easy to use without any fuss.

Build

Useful Links

Getting Started

Building

libsockcanpp was designed with use in CMake projects, but it can also easily be integrated into existing Makefile projects, as long as cmake is present on the build system.

1) clone the repository: git clone https://github.com/SimonCahill/libsockcanpp.git 2) create build directory: mkdir build && cd build 3) generate build files: cmake .. -DCMAKE_TOOLCHAIN_FILE=../toolchains/desired-toolchain.cmake 4) building library: make -j

Incorporating into Cmake projects:

1) clone the repository: git clone https://github.com/SimonCahill/libsockcanpp.git 2) add the following to CMakeLists.txt

if (NOT TARGET sockcanpp)
add_subdirectory(/path/to/libsockcanpprepo ${CMAKE_CURRENT_BUILD_DIR}/libsockcanpp)
endif()
# ...
target_link_libraries(
# ...
sockcanpp
)

3) generate and build 4) ??? profit

Using the CAN driver

libsockcanpp provides a simple interface to socketcan, which is represented by the CanDriver class.
CanDriver handles the setup of the socket; it does not however setup the CAN interface!

Instantiating CanDriver

The example below describes how to instantiate a new instance of CanDriver.
You can create as many instances as required, the resources are free'd once the instance has gone out of scope or been deleted.

The following parameters are required for correct instantiation:

1) CAN interface: [v]can[0-?] 2) CAN protocol: see linux/can.h for options 3) (optional) CAN sender ID (arbitration ID)

The following exceptions may be thrown if something went wrong during initialisation:

  • See also
    CanInitException
    • if socketcan failed to initlialise
    • if ioctl failed
    • if socket binding failed
    CanDriver is fully thread-safe and can be used in multi-threaded applications.
#include <CanDriver.hpp>
int main() {
CanDriver canDriver("can0", CAN_RAW[, 0xbad]);
return 0;
}
Contains the declarations for the SocketCAN wrapper in C++.
CanDriver class; handles communication via CAN.
Definition: CanDriver.hpp:62

Using CAN IDs

libsockcanpp provides a first-class datatype,

See also
CanId, which acts as an integer which can be either 11 or 29 bits in size.
The
CanId type is used through libsockcanpp to provide a semi fool-proof method of using CAN arbitration IDs without the pitfalls of using traditional 32-bit integers.

CanId supports the following operations:

  • bitwise AND/OR
  • casting to: [u]int16, [u]int32
  • basic comparison:
    • equal to
    • not equal to
    • greater than (or equal to)
    • less than (or equal to)
  • arithmetic:
    • addition
    • subtraction

Sending CAN frames

Sending CAN frames with sockcanpp is as easy as you could imagine.

1) instantiate a

See also
CanDriver object 2) create a
CanMessage 3) send message
#include <CanDriver.hpp>
void sendCanFrameExample() {
CanDriver canDriver("can0", CAN_RAW[, 0xd00d]);
CanMessage messageToSend(0 /*send with default ID*/, "8 bytes!" /* the data */);
auto sentByteCount = canDriver.sendMessage(messageToSend[, false /* don't force extended ID */]);
printf("Sent %d bytes via CAN!\n", sentByteCount);
}
void sendMultipleFramesExample() {
CanDriver canDriver("can1", CAN_RAW[, 0 /* no default ID */]);
queue<CanMessage> messageQueue = {
CanMessage(0x269, "somedata"),
Canmessage(0x1e9, "moredata")
};
auto sentByteCount = canDriver.sendMessageQueue(messageQueue[, milliseconds(20) /* delay between frames */[, false /* don't force extended ID */]]);
printf("Sent %d bytes via CAN!\n", sentByteCount);
}
Represents a CAN message that was received.
Definition: CanMessage.hpp:55
Represents a CAN ID in a simple and easy-to-use manner.
Definition: CanId.hpp:48

Receiving messages via CAN

Receiving CAN messages is almost as simple as sending them! Firstly, check if there are any messages in the buffer, then pull them out; either one-by-one, or all at once!

#include <CanDriver.hpp>
void receiveCanFramesExample() {
CanDriver canDriver("can2", CAN_RAW[, 0 /* no default ID */]);
if (canDriver.waitForMessages([milliseconds(3000) /* timeout */])) {
// read a single message
CanMessage receivedMessage = canDriver.readMessage();
// read all available messages
queue<CanMessage> receivedMessages = canDriver.readQueuedMessages();
// handle CAN frames
}
}