wampcc is C++ library that implements the Web Application Messaging Protocol (WAMP).
wampcc provides the WAMP basic profile for client roles and also a lightweight implementation of a WAMP router / dealer.
Features
- Builds on: Linux, Windows (Visual Studio) & Mac OS 10
- Roles: Caller, Callee, Subscriber, Publisher, Dealer, Router
- Message serializations: JSON, MessagePack
- Transports: TCP using raw-socket and web-socket
- SSL/TLS supported for both client and server sessions
- Uses modern C++
- Extensively tested
- Permissive license (MIT)
Dependencies
wampcc aims to depend mostly on C libraries, making it easier to build and work on a range of platforms.
- libuv (network IO)
- jansson (JSON encode & decode)
- http-parser
- OpenSSL
- websocketpp -- C++ header only
- msgpack-c -- C++ header only
- Modern C++ compiler, GNU autotools (Linux), CMake (Linux & Windows)
Here is what programming with wampcc looks like.
Establishing a WAMP session
Before a WAMP session can be established, a tcp_socket
has to be created and connected to a WAMP router / dealer server.
After the socket is successfully connected it is used to construct a wamp_session
. Next the HELLO sequence is initiated to establish the logical WAMP session.
All wampcc objects make use of a shared kernel
object, which provides threads for event handling and socket IO.
/* Create the wampcc kernel. */
kernel the_kernel;
/* Create the TCP socket and attempt to connect. */
std::unique_ptr<tcp_socket> socket(new tcp_socket(&the_kernel));
socket->connect("127.0.0.1", 55555).wait_for(std::chrono::seconds(3));
if (!socket->is_connected())
throw std::runtime_error("connect failed");
/* With the connected socket, create a wamp session & logon to the realm
* called 'default_realm'. */
auto session = wamp_session::create<websocket_protocol>(
&the_kernel, std::move(socket));
session->hello("default_realm").wait_for(std::chrono::seconds(3));
if (!session->is_open())
throw std::runtime_error("realm logon failed");
Calling a remote procedure
C++ lambda functions are used to handle the asynchronous result of a call request, and this usage pattern is the same for other kinds of request.
This example shows a request to call a remote procedure named math.service.add with arguments 100 & 200.
session->call("math.service.add", {}, {{100, 200}, {}},
[](wampcc::wamp_session&, wampcc::result_info result) {
if (result)
std::cout << "got result: " << result.args.args_list[0] << std::endl;
});
Registering a remote procedure
session->provide("math.service.add", {},
[](wamp_session&, registered_info info) {
if (info)
std::cout << "procedure registered with id "
<< info.registration_id << std::endl;
else
std::cout << "procedure registration failed, error "
<< info.error_uri << std::endl;
},
[](wamp_session& ws, invocation_info info) {
int total = 0;
for (auto& item : info.args.args_list)
if (item.is_int())
total += item.as_int();
ws.yield(info.request_id, {total});
});
Subscribing to a topic
session->subscribe("random_number", {},
[](wampcc::wamp_session&, subscribed_info info) {
std::cout << "subscribed "
<< (info ? "ok" : "failed")
<< std::endl;
},
[](wampcc::wamp_session&, event_info info) {
for (auto& x : info.args.args_list)
std::cout << "got update: " << x << " ";
std::cout << std::endl;
});
Publishing to a topic
int random_variable = std::rand();
session->publish("random_number", {}, {{random_variable}, {}});
Terminating a session
A thread can wait for a wamp_session
to be remotely closed by waiting on an appropriate std::future
. A wamp_session
that is no longer needed must be closed and the closure operation completed before it can be deleted.
session->closed_future().wait_for(std::chrono::minutes(10));
session->close().wait();
Embedding a wamp router
An embedded wamp router is provided by creating a wamp_router
object.
wamp_router router(&the_kernel);
It is instructed to begin listening on a particular port for new clients, together with the policy to use for authentication.
/* Accept clients on IPv4 port, without authentication. */
auto fut = router.listen(auth_provider::no_auth_required(), 55555);
if (auto ec = fut.get())
throw runtime_error(ec.message());
An individual RPC is provided by defining the realm & name through which it can be called by a WAMP session, together with the lambda function which does the actual work of generating a call result.
router.callable(
"default_realm", "greeting",
[](wamp_router&, wamp_session& caller, call_info info) {
caller.result(info.request_id, {"hello"});
});
The complete listing for these examples can be found at:
Building wampcc involves several steps, including: installation of build tools; building the dependent libraries; obtaining the source; and source configuration.
Setting up build tools
wampcc can be built on Linux using either autotools, or cmake. The latter is particularly useful for integration with IDE's, such as clion.
Building on Linux presumes that some essential programs are available, including:
- git
- autoconf (if using autotools approach)
- cmake (if using cmake approach)
- g++
- make
- wget
- libtool
- libssl headers & libraries
wampcc was developed on xubuntu and on this system these tools can be installed using the command:
sudo apt-get install cmake git autoconf gcc g++ make wget libtool libssl-dev
Building dependent libraries
wampcc requires that the C libraries libuv and jansson have already been built and installed. The location of these libraries must be provided during the wampcc source configuration step.
Obtaining the source
The latest version of wampcc can be downloaded from github using:
git clone https://github.com/darrenjs/wampcc.git
This will fetch the source files directly from github and place them in a folder
named wampcc/
.
Some third party code is directly integrated into wampcc
, and are compiled
alongside wampcc
source code. For convenience these are stored in the
3rdparty
folder; no additional download step is required to obtain them.
Autotools approach
Taking the autotools approach, if building from the git sources the configure
script must be first generated. An included helper script can do this:
./scripts/autotools_setup.sh
The source code is now ready to be configured. This is done by running the configure
script, and passing it the locations of libuv and jansson, and also the location where wampcc should finally be installed.
./configure --prefix=/var/tmp/wampcc_install --with-libuv=/opt/libuv-1.10.2 --with-jansson=/opt/jansson-2.10
Note that the locations of libuv and jansson will be specific to your host, and will unlikely match this example.
Finally the build and install steps are run:
make install
If all goes well wampcc will be installed into the prefix
location.
CMake approach
wampcc can also be built using cmake. The following instructions show how to use cmake to set up a command line build.
The preferred approach is to create a separate build folder outside of the
source tree. In this example the build folder is
/var/tmp/wmampcc_cmake_build
.
mkdir -p /var/tmp/wmampcc_cmake_build
cd /var/tmp/wmampcc_cmake_build
Next is the invocation of the cmake
program to generate the makefiles. This
tells cmake where to find the libuv and jansson libraries, where to install
the built targets, and where to find the wampcc source. The paths in this
example need to be replaced with paths specific to your system. This command
should be invoked from within the build folder.
cmake --verbose \
-DCMAKE_VERBOSE_MAKEFILE:BOOL=ON \
-DCMAKE_BUILD_TYPE=Release \
-DLIBUV_DIR=/opt/libuv-1.10.2 \
-DJANSSON_DIR=/opt/jansson-2.10 \
-DCMAKE_INSTALL_PREFIX=/var/tmp/wampcc_install \
/var/tmp/wampcc_src
If libuv and jansson are already installed on your system, rather than being separately built and provided, cmake can instead be configured to find and use them, simply by omitting the corresponding variables:
cmake -DCMAKE_INSTALL_PREFIX=/var/tmp/wampcc_install /var/tmp/wampcc_src
Following successful generation of the make files, wampcc can be built using make:
make
The following steps assume that you wish to install wampcc
and the
required dependencies in C:\build
. You may modify this by
replacing C:\build
with the path of your choice.
The dependecies are build in Release and wampcc
in Debug. You may change
these by modifying the -DCMAKE_BUILD_TYPE
CMake argument.
It's assumed that you are using Visual Studio and have NMake installed
(which comes with Visual Studio). Visual Studio also optionally comes with
CMake (this is called 'CMake Tools for Visual Studio'). However,
this tends to be out-dated and it is recommened that you use the latest version
of CMake. If you do have CMake Tools for Visual Studio installed, then you should
run the latest version of CMake by invoking C:\Program Files\CMake\bin\cmake.exe
instead of plain cmake
in the commands below.
This step compiles and sets up the dependencies.
-
Download and install CMake.
-
Download and install OpenSSL, including the headers. Here is a good source of compiled binaries.
-
Download and unzip
jansson
andlibuv
source files. -
Run the correct Visual Studio developer command prompt for the architecture (e.g. x86/x64) that you are compiling for. The architecture must match that of the OpenSSL libraries that you just installed.
For example, if you installed the 64-bit version of OpenSSL and are using Visual Studio 2017, then you must use 'x64 Native Tools Command Prompt for VS2017'. This should be available from the Visual Studio folder in the Start menu.
-
Go inside the
jansson
source folder, and run:mkdir build cd build cmake -G "NMake Makefiles" -DCMAKE_BUILD_TYPE=Release -DCMAKE_INSTALL_PREFIX=C:\build\jansson .. nmake nmake install
-
Go inside the
libuv
source folder, and run:mkdir build cd build cmake -G "NMake Makefiles" -DCMAKE_BUILD_TYPE=Release .. nmake mkdir C:\build\libuv mkdir C:\build\libuv\lib copy uv.dll C:\build\libuv\lib copy uv.lib C:\build\libuv\lib mkdir C:\build\libuv\include xcopy /E ..\include C:\build\libuv\include
Note that
libuv
does not provide aninstall
target, hence why we had to manually copy the files over.
-
Download a copy of wampcc
-
Run Visual Studio command line tools as described in the previous section
-
Run
mkdir build cd build cmake -G "NMake Makefiles" -DCMAKE_BUILD_TYPE=Debug -DCMAKE_INSTALL_PREFIX=C:\build\wampcc -DJANSSON_DIR=C:\build\jansson -DLIBUV_DIR=c:\build\libuv -DOPENSSL_ROOT_DIR="C:\Program Files\OpenSSL-Win64" .. nmake
If the paths to
libuv
,jansson
or OpenSSL are different then you will need to change the appropriate parameters in the command above. -
If you wish to install
wampcc
, you can do so:nmake install