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The SciViews {svSocket} server implements an R server that is mainly designed to interact with the R prompt from a separate process. The {svSocket} clients and the R console share the same global environment (
.GlobalEnv
). So, everybody interacts with the same variables. Use cases are to build a separate R console, to monitor or query an R session, or even, to build a complete GUI or IDE on top of R. Examples of such GUIs are Tinn-R and Komodo IDE with the SciViews-K extension.
The SciViews {svSocket} package provides a stateful, multi-client and
preemptive socket server. Socket transactions are operational even when
R is busy in its main event loop (calculation done at the prompt). This
R socket server uses the excellent asynchronous socket ports management
by Tcl, and thus, it needs a working version of Tcl/Tk (>= 8.4), the
{tcltk} R package, and R with
isTRUE(capabilities("tcltk"))
.
Install the {svSocket} package as usual:
(For the development version, install first devtools
or
remotes
, and then use something like
remotes::github_install("SciViews/svSocket")
)
# Start a separate R process with a script that launch a socket server on 8889
# and wait for the variable `done` in `.GlobalEnv` to finish
rscript <- Sys.which("Rscript")
system2(rscript, "--vanilla -e 'svSocket::start_socket_server(8889); while (!exists(\"done\")) Sys.sleep(1)'", wait = FALSE)
Sometimes (on MacOS Catalina or more, for instance), you are prompted to allow for R to use a socket. Of course, you have to allow to get an operational server.
What this code does is:
Rscript
using Sys.which
-Start it with a command that launches the socket server on port 88891
(svSocket::start_socket_server(8889)
)done
appears in
.GlobalEnv
as a simple mean to keep the server alive.system2()
is invoked with
wait = FALSE
, the command exits as soon as the server is
created and you can interact at the R prompt.As you can see, creating a socket server with {svSocket} is easy. Now, let’s connect to it. It is also very simple:
Here, we use the socketConnection()
that comes with base
R in non-blocking mode and a time out at 30 sec. So, {svSocket} is even
not required to connect an R client to our server. The connection is not
blocking. We have the control of the prompt immediately.
Now, we can execute code in our R server process with
svSocket::eval_socket_server()
:
The instruction is indeed executed in the server, and the result is
returned to the client transparently. You now master two separate R
process: the original one where you interact at the R prompt
(>
), and the server process that you can interact with
through eval_socket_server()
. To understand this, we will
create the variable x
on both processes, but with different
values:
Now, let’s look what is available on the server side:
Obviously, there is only one variable, x
, with value
"server"
. All right … and in our original process?
We have x
, but also con
and
rsscript
. The value of x
locally is
"local"
.
As you can see, commands and results are rather similar. And since
the processes are different, so are x
in both
processes.
If you want to transfer data to the server, you can still use
eval_socket_server()
, with the name you want for the
variable on the server instead of a string with R code, and as third
argument, the name of the local variable whose the content will be
copied to the server. eval_socket_server()
manages to send
the data to the server (by serializing the data on your side and
deserializing it on the server). Here, we will transfer the
iris
data frame to the server under the iris2
name:
data(iris)
eval_socket_server(con, iris2, iris)
eval_socket_server(con, "ls()") # iris2 is there
eval_socket_server(con, "head(iris2)") # ... and its content is OK
For more examples on using eval_socket_server
, see its
man page with ?eval_socket_server
.
The {svSocket} server also allows, of course, for a lower-level
interaction with the server, with a lot more options. Here, you send
something to the server using cat, file = con)
(make sure
to end your command by a carriage return \n
, or the server
will wait indefinitely for the next part of the instruction!), and you
read results using readLines(con)
. Of course, you must wait
that R processes the command before reading results back:
# Send a command to the R server (low-level version)
cat('{Sys.sleep(2); "Done!"}\n', file = con)
# Wait for, and get response from the server
res <- NULL
while (!length(res)) {
Sys.sleep(0.01)
res <- readLines(con)
}
res
Here you got the results send back as strings. If you want to display
them on the client’s console as if it was output there (like
eval_socket_server()
does), you should use
cat( sep = "\n")
:
For convenience, we will wrap all this a function
run_socket_server()
:
run_socket_server <- function(con, code) {
cat(code, "\n", file = con)
res <- NULL
while (!length(res)) {
Sys.sleep(0.01)
res <- readLines(con)
}
# Use this instruction to output results as if code was run at the prompt
#cat(res, "\n")
invisible(res)
}
The transaction is now much easier:
Now at the low-level (not within eval_socket_server()
but within our run_socket_server()
function), one can
insert special code <<<X>>>
with
X
being a marker that the server will use on his side. The
last instruction we send instructed the server to wait for 2 sec and
then, to return "Done!"
. We have send the instruction to
the server and wait for it to finish processing and then, we
got the results back. Thus, you original R process is locked down the
time the server processes the code. Note that we had to lock it down on
our side using the while(!length(res))
construct. It means
that communication between the server and the client is asynchronous,
but process of the command must be made synchronous. If you want to
return immediately in the calling R process before the
instruction is processed in the server, you could just consider to drop
the while(...)
section. This is not a good
idea! Indeed, R will send results back and you will read them
on the next readLines(con)
you issue, and mix it with,
perhaps, the result of the next instruction. So, here, we really must
tell the R server to send nothing back to us. This is done by inserting
the special instruction <<<h>>>
on one
line (surrounded by \n
). This way, we still have to wait
for the instruction to be processed on the server, but nothing is
returned back to the client. Also, sending
<<<H>>>
will result into an immediate
finalization of the transaction by the server before the
instruction is processed.
Here, we got the result immediately, but it is not the
results of the code execution. Our R server simply indicates that he got
our code, he parsed it and is about to process it on his side by
returning an empty string ""
.
There are several special instructions you can use. See
?par_socket_server
for further details. The server can be
configured to behave in a given way, and that configuration is
persistent from one connection to the other for the same client. The
function par_socket_server()
allows to change or query the
configuration. Its first argument is the name of the client on the
server-side… but from the client, you don’t necessarily know which name
the server gave to you (one can connect several different clients at the
same time, and default name is sock
followed by Tcl name of
the client socket connection). Using
<<<s>>>
as a placeholder for this name
circumvents the problem. par_socket_server()
returns an
environment that contains configuration variables. Here is the list of
configuration item for us:
The bare
item indicates if the server sends bare
results, or also returns a prompt, acting more like a terminal. By
default, it returns the bare results. Here is the current value:
And here is how you can change it:
(run_socket_server(con, '\n<<<H>>>svSocket::par_socket_server(<<<s>>>, bare = FALSE)'))
(run_socket_server(con, '1 + 1'))
When bare = FALSE
the server issues the formatted
command with a prompt (:>
by default) and the result.
For more information about {svSocket} server configuration, see
?par_socket_server
. There are also functions to manipulate
the pool of clients and their configurations from the server-side, and
the server can also send unattended data to client, see
?send_socket_clients
. finally, the workhorse function on
the server-side is process_socket_server()
. See
?process_socket_server
to learn more about it. You can
provide your own process function to the server if you need to.
Don’t forget to close the connection, once you have done using
close(con)
, and you can also close the server from the
server-side by using stop_socket_server()
. But never use it
from the client-side because you will obviously break in the middle of
the transaction. If you want to close the server from the client, you
have to install a mechanisms that will nicely shut down the server
after the transaction is processed. Here, we have installed
such a mechanism by detecting the presence of a variable named
done
on the server-side. So:
# Usually, the client does not stop the server, but it is possible here
eval_socket_server(con, 'done <- NULL') # The server will stop after this transaction
close(con)
You can also access the {svSocket} server from another language.
There is a very basic example written in Tcl in the /etc
subdirectory of the {svSocket} package. See the ReadMe.txt
file there. The Tcl script SimpleClient.tcl
implements a
Tcl client in a few dozens of code lines. For other examples, you can
inspect the code of SciViews-K, and the
code of Tinn-R for a Pascal
version. Writing clients in C, Java, Python, etc. should not be
difficult if you inspire you from these examples. Finally, there is
another implementation of a similar R server through HTTP in the
{svHttp} package.
Of course, this port must be free. If not, just use another value.↩︎
These binaries (installable software) and packages are in development.
They may not be fully stable and should be used with caution. We make no claims about them.