This tutorial builds on the FIDL server tutorial. For the full set of FIDL tutorials, refer to the overview.
This tutorial implements a client for a FIDL protocol and runs it against the server created in the previous tutorial. The client in this tutorial is synchronous. There is an alternate tutorial for asynchronous clients.
If you want to write the code yourself, delete the following directories:
rm -r examples/fidl/hlcpp/client_sync/*
Note: If necessary, refer back to the previous tutorial.
Set up a hello world component in examples/fidl/hlcpp/client
. You can name the component echo-client
, and give the package a name of echo-hlcpp-client-sync
.
Once you have created your component, ensure that the following works:
fx set core.x64 --with //examples/fidl/rust/client
Build the Fuchsia image:
fx build
In a separate terminal, run:
fx serve
In a separate terminal, run:
fx shell run fuchsia-pkg://fuchsia.com/echo-hlcpp-client-sync#meta/echo-client.cmx
Add the following dependencies:
{%includecode gerrit_repo="fuchsia/fuchsia" gerrit_path="examples/fidl/hlcpp/client_sync/BUILD.gn" region_tag="deps" %}
Then, include them in main.cc
:
{%includecode gerrit_repo="fuchsia/fuchsia" gerrit_path="examples/fidl/hlcpp/client/main.cc" region_tag="includes" %}
The reason for including these dependencies is explained in the server tutorial.
Include the Echo
protocol in the client component's sandbox by editing the component manifest in client.cmx
.
{%includecode gerrit_repo="fuchsia/fuchsia" gerrit_path="examples/fidl/hlcpp/client/client.cmx" %}
This section adds code the main()
function that connects to the server and makes requests to it.
The code then creates a proxy class for the Echo
protocol, and connects it to the server. In the context of FIDL, proxy designates the code generated by the FIDL bindings that enables users to make remote procedure calls to the server. In HLCPP, the proxy takes the form of a class with methods corresponding to each FIDL protocol method.
{%includecode gerrit_repo="fuchsia/fuchsia" gerrit_path="examples/fidl/hlcpp/client_sync/main.cc" region_tag="main" highlight="2,3,4" %}
fuchsia::examples::EchoSyncPtr
is an alias for fidl::SynchronousInterfaceRequest<fuchsia::examples::Echo>
generated by the bindings. This class will proxy requests for the Echo
protocol over the channel that it is bound to.EchoSyncPtr::NewRequest()
, which will create a channel, bind the class to one end, and return the other endsys::ServiceDirectory::Connect()
.context->out()->AddPublicService()
on the server side, Connect
has an implicit second parameter here which is the protocol name ("fuchsia.examples.Echo"
). This is where the input to the handler defined in the previous tutorial comes from: the client passes it in to Connect
, which then passes it to the handler.An important point to note here is that this code assumes that /svc
already contains an instance of the Echo
protocol. This is not the case by default because of the sandboxing provided by the component framework.
The code makes two requests to the server:
EchoString
requestSendString
request{%includecode gerrit_repo="fuchsia/fuchsia" gerrit_path="examples/fidl/hlcpp/client_sync/main.cc" region_tag="main" highlight="6,7,8" %}
For EchoString
the code passes in a pointer for each response parameter (in this case, the EchoString
method only has one response parameter), which is written with the response from the server, whereas this does not apply to SendString
since it is a [fire and forget method][one-way]. The call to EchoString
will block until it receives a message from the server. Both methods will return a zx_status_t
indicating the result of the method call.
Though the server implementation sends an OnString
event in response to the SendString
request, the sync bindings do not provide a way to handle this event.
If you try running the client directly, you‘ll notice that the error handler gets called because the client does not automatically get the Echo
protocol provided in its sandbox (in /svc
). In order to get this to work, a launcher tool is provided that launches the server, creates a new Environment
for the client that provides the server’s protocol, then launches the client in it.
Configure your GN build:
fx set core.x64 --with //examples/fidl/hlcpp/server --with //examples/fidl/hlcpp/client_sync --with //examples/fidl/test:echo-launcher
Build the Fuchsia image:
fx build
Run the launcher by passing it the client URL, the server URL, and the protocol that the server provides to the client:
fx shell run fuchsia-pkg://fuchsia.com/echo-launcher#meta/launcher.cmx fuchsia-pkg://fuchsia.com/echo-hlcpp-client-sync#meta/echo-client.cmx fuchsia-pkg://fuchsia.com/echo-hlcpp-server#meta/echo-server.cmx fuchsia.examples.Echo
You should see the client print output in the QEMU console (or using fx log
).
[117942.207] 757245:757247> Running echo server [117942.223] 757349:757352> Got response: hello