I'm working on one right now as a practice project.

It's a dynamically-typed language, so variables don't have to be declared, but each value has an associated type. I implemented that using an algebraic data type in Haskell:

```
data Value = BoolValue Bool -- ^ A Boolean value.
| NumberValue Double -- ^ A numeric value.
| StringValue String -- ^ A string value.
-- (several others omitted for simplicity)
```

For execution of programs, I'm using the `StateT`

and `ErrorT`

monad transformers on top of `IO`

:

```
-- | A monad representing a step in an RPL program.
--
-- This type is an instance of 'MonadState', so each action is a function that
-- takes an 'RPLContext' as input and produces a (potentially different)
-- 'RPLContext' as its result. It is also an instance of 'MonadError', so an
-- action may fail (with 'throwRPLError'). And it is built on the 'IO' monad,
-- so 'RPL' computations can interact with the outside world.
type RPL = StateT RPLContext (ErrorT RPLError IO)
-- | Executes an 'RPL' computation.
-- The monadic result value (of type @a@) is discarded, leaving only the final
-- 'RPLContext'.
runRPL :: RPL a -- ^ The computation to run
-> RPLContext -- ^ The computation's initial context
-> IO (Either RPLError RPLContext)
-- ^ An 'IO' action that performs the operation, producing either
-- a modified context if it succeeds, or an error if it fails.
runRPL a = runErrorT . (execStateT a)
```

The "context" is a combination of a data stack (it's a stack-based language) and an "environment" that holds all the variables that are currently in scope:

```
-- | The monadic state held by an 'RPL' computation.
data RPLContext = RPLContext {
contextStack :: Stack, -- ^ The context's data stack.
contextEnv :: Env -- ^ The context's environment.
}
```

(Note that `Stack`

is just an alias for `[Value]`

.)

On top of that foundation, I have a variety of helper functions to do things like manipulate the stack in the current context (held by the `StateT`

part of the `RPL`

monad). For example, here are the functions involved in pushing a value onto the stack:

```
-- | Pushes a value onto the stack.
pushValue :: Value -> RPL ()
pushValue x = modifyStack (x:)
-- | Transforms the current stack by a function.
modifyStack :: (Stack -> Stack) -> RPL ()
modifyStack f = do
stack <- getStack
putStack $ f stack
-- | Returns the entire current stack.
getStack :: RPL Stack
getStack = fmap contextStack get
-- | Replaces the entire current stack with a new one.
putStack :: Stack -> RPL ()
putStack stack = do
context <- get
put $ context { contextStack = stack }
```

`getStack`

, `putStack`

, and `modifyStack`

are modeled after `MonadState`

's `get`

, `put`

, and `modify`

functions, but they operate on just one field of the `RPLContext`

record.

All the language's built-in commands are just actions in the `RPL`

monad, which build on top of tools like `pushValue`

.

For parsing code in my language, I'm using Parsec. It's pretty nice.

On a separate track, unrelated to my RPL interpreter, you might find "Write Yourself a Scheme in 48 Hours" helpful.