rapid-term-0.1.2.1: External terminal support for rapid

Copyright(c) 2016 Ertugrul Söylemez
LicenseBSD3
MaintainerErtugrul Söylemez <esz@posteo.de>
Safe HaskellSafe
LanguageHaskell2010

Rapid.Term

Contents

Description

When developing interactive command line applications in an editor like Emacs GHCi typically has no access to an actual terminal. This is good enough for applications that only read lines from stdin and print diagnostics to stdout, but as soon as terminal functionality is needed, the application has to be tested elsewhere.

This package provides functionality that, when used together with the rapid library, can open a persistent terminal that the application can access directly, such that terminal applications can be tested with the main GHCi instance.

Synopsis

Tutorial

This tutorial assumes that you are already familiar with the rapid library, and that you use rxvt-unicode (or at least have it installed).

Say you are writing a terminal application that requires an actual terminal that you would like to test during development. For example you are using ANSI control sequences, or perhaps you're even using a text UI based on Vty. Ideally you could use the running GHCi instance, but if you're using an editor like Emacs and haskell-interactive-mode, then that's not possible directly, because it's not attached to a terminal.

This library provides a way to fire up a separate, potentially persistent terminal as a subprocess and communicate with it through one or more Handles.

The first step to using this library is to abstract over the Handles you want to use:

module Main (main) where

import System.IO

mainWith :: Handle -> Handle -> Handle -> IO ()
mainWith hI hO hE = 

main :: IO ()
main = mainWith stdin stdout stderr

In other words: you no longer use the built-in handles, but do all your input and output in mainWith by reading from and writing to the handles explicitly passed to it. Let's use an example program that reads a line from the input handle and writes it to the output handle:

import Control.Concurrent
import System.IO

mainWith :: Handle -> Handle -> Handle -> IO ()
mainWith hI hO _ = do
    hPutStr hO "Type something: "
    hFlush hO
    line <- hGetLine hI

    hPutStrLn hO "Wait for it..."
    threadDelay 2000000
    hPutStrLn hO ("You typed: " ++ line)

Now in your DevelMain module you need three things:

  • a terminal reference,
  • a terminal thread,
  • a thread that calls your application.

This amounts to the following update action:

module DevelMain (update) where

import Main (mainWith)
import Rapid
import Rapid.Term

update :: IO ()
update =
    rapid 0 $ \r -> do
        -- Create the terminal reference
        t <- createRef r "term-ref" newTermRef

        -- Thread for the terminal
        start r "term" (runTerm urxvt t)

        -- Thread for your application
        restart r "my-app" . terminal t $ \h ->
            mainWith h h h

Now if you use update an rxvt-unicode terminal will pop up and run mainWith, which will prompt you to type something. Once you type a line into that terminal, mainWith will finish. When you update again, it will start over in the same terminal. If you actually want to open a new terminal every invocation, just use restart instead of start for the terminal thread.

You can have as many application threads using the terminal concurrently as you want. Also you can request multiple handles to the terminal e.g. to have different buffering modes for each:

restart r "my-app" . terminal t $ \hI ->
    terminal t $ \hO ->
        mainWith hI hO hO

If you would like to see a few diagnostics after each application run, just wrap your terminal action by stats:

restart r "test-app" . stats t . terminal t $ \h ->
    mainWith h h h

This also makes it easier to see when the application is finished, because otherwise there would be no indication.

Note: While we have abstracted over three handles above there is no technical reason to do that. If you don't actually use, say, stderr in your application, there is no reason to abstract over it:

mainWith :: Handle -> Handle -> IO ()
mainWith hI hO = 

Vty

Running Vty applications requires some minor setup to work properly. First of all instead of abstracting over input/output handles you should abstract over the Vty handle instead. Let's write a very simple example application:

module Main (main) where

import Graphics.Vty

mainWith :: Vty -> IO ()
mainWith vty = go ""
    where
    go inp = do
        let pic = picForImage $
                  string defAttr "Type some text:" <->
                  string defAttr inp

        update vty pic
        ev <- nextEvent vty
        case ev of
          EvKey (KChar c) _ -> go (inp ++ [c])
          EvKey KEsc _ -> pure ()
          _ -> go inp

main :: IO ()
main = do
    cfg <- standardIOConfig
    bracket (mkVty cfg) shutdown mainWith

Now in your DevelMain module you create the terminal reference and thread as usual, but in your application thread you use termFd to get a file descriptor instead of a Handle, which is exactly what Vty needs:

module DevelMain (update) where

import Control.Exception
import qualified Graphics.Vty as Vty
import Rapid
import Rapid.Term

update :: IO ()
update =
    rapid 0 $ \r -> do
        t <- createRef r "term-ref" newTermRef
        start r "term" (runTerm urxvt t)
        restart r "test-app" . stats t . termFd t $ \fd -> do
            cfg' <- Vty.standardIOConfig
            let cfg = cfg' {
                        Vty.inputFd = Just fd,
                        Vty.outputFd = Just fd,
                        Vty.termName = Just "rxvt-unicode-256color"
                      }
            bracket (Vty.mkVty cfg) Vty.shutdown mainWith

So the main differences are that you need to tell Vty explicitly which handles it should use, and that you should probably also set the name of the terminal explicitly (termName) so that Vty can find its terminfo database.

Now you can use Rapid to develop your Vty applications!

Terminal support for Rapid

data Term Source #

Handle to a terminal

newTermRef :: IO (MVar Term) Source #

Create a new terminal reference.

runTerm :: (Fd -> IO ProcessHandle) -> MVar Term -> IO () Source #

Start a terminal and update the given terminal reference for use from other threads.

termFd :: MVar Term -> (Fd -> IO r) -> IO r Source #

Provide a file descriptor to the given terminal

Given a terminal, this function duplicates its file descriptor and passes it to the given continuation. It is closed after the continuation returns.

If you need separate file descriptors for input and output, you can cascade this function in the same way as terminal.

You can use this function as often as you want, in sequence or concurrently.

terminal :: MVar Term -> (Handle -> IO r) -> IO r Source #

Provide a handle to the given terminal

Given a terminal, this function creates a handle (by duplicating the underlying file descriptor) and passes it to the given continuation. It is closed after the continuation returns.

If you need separate handles for input and output (for example to select different buffering modes), just cascade this function:

terminal t (\hI -> terminal t (\hO -> k hI hO))

You can use this function as often as you want, in sequence or concurrently.

Low-level

termFdPure :: Term -> (Fd -> IO r) -> IO r Source #

Variant of termFd that works on a pure terminal handle

terminalPure :: Term -> (Handle -> IO r) -> IO r Source #

Variant of terminal that works on a pure terminal handle

waitTerm :: Term -> IO () Source #

Wait for the given terminal subprocess to exit

withTerm Source #

Arguments

:: (Fd -> IO ProcessHandle)

Spawn function

-> (Term -> IO r)

Continuation

-> IO r 

Create a terminal using the given spawn function and pass its terminal handle to the given continuation

The subprocess is terminated and resources are cleaned up once the continuation returns.

Supported terminal emulators

rxvt-unicode

urxvt :: Fd -> IO ProcessHandle Source #

Spawns rxvt-unicode using the urxvt executable

urxvtc :: Fd -> IO ProcessHandle Source #

Spawns rxvt-unicode using the urxvtc executable

urxvtAt :: FilePath -> Fd -> IO ProcessHandle Source #

Spawns rxvt-unicode using the given executable

Helper functions

stats :: MVar Term -> IO a -> IO () Source #

Write execution diagnostics for the given action to the given terminal