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Writing Your Own Lisp Interpreter in Haskell - Part 7

18 Feb 2025

Introduction

In this update, we’re introducing first-class functions to our Lisp interpreter! This allows users to define and use functions just like they would in a real Lisp environment.

Before this update, function definitions looked like this:

(define square (lambda (x) (* x x)))
(square 4) ;; Expected 16

This worked, but wasn’t very Lisp-like. In Lisp, we usually define functions using a shorthand syntax:

(define (square x) (* x x))
(square 4) ;; Expected 16

We’re going to support both styles while keeping our implementation clean.

Extending define

The first change we made was updating eval to detect function definitions and create a lambda automatically.

We extend define to detect function definitions and transform them into lambda expressions automatically:

eval env (List [Atom "define", List (Atom funcName : params), body]) = do
    let paramNames = map extractParam params
    defineVar env funcName (Lambda paramNames body env)
  where
    extractParam (Atom name) = name
    extractParam nonAtom = error $ "Expected parameter name, got: " ++ show nonAtom

This means that:

  • If define receives a list as the first argument, it assumes we’re defining a function.
  • The first element of that list (funcName) is the function name.
  • The remaining elements (params) are the parameter names.
  • The function body is stored as a lambda expression.

Example

With this change, both of these definitions are now equivalent:

;; Using explicit lambda
(define square (lambda (x) (* x x)))

;; Using shorthand function definition
(define (square x) (* x x))

(square 4) ;; 16

This makes function definitions much cleaner and easier to read!

Fixing if Expressions

While making these changes, we discovered a bug in our if implementation.

Previously, if did not evaluate the then or else branch before returning it:

eval env (List [Atom "if", condition, thenExpr, elseExpr]) = do
    result <- eval env condition
    case result of
        Bool True  -> return thenExpr  
        Bool False -> return elseExpr  
        _          -> throwError $ TypeMismatch "Expected boolean in if condition" result

This meant that calling:

(if (> 10 5) (* 2 2) (* 3 3))

Would return (* 2 2) instead of 4!

The Fix

We simply added eval env to ensure the chosen branch is evaluated before being returned:

eval env (List [Atom "if", condition, thenExpr, elseExpr]) = do
    result <- eval env condition
    case result of
        Bool True  -> eval env thenExpr  
        Bool False -> eval env elseExpr  
        _          -> throwError $ TypeMismatch "Expected boolean in if condition" result

Now, if expressions behave correctly:

(if (> 10 5) (* 2 2) (* 3 3)) ;; 4
(if (< 10 5) (* 2 2) (* 3 3)) ;; 9

Recursion

With function definitions and the fixed if statement, we can now write recursive functions!

Example: Factorial Function

(define (factorial n)
  (if (<= n 1)
      1
      (* n (factorial (- n 1)))))

(factorial 5) ;; 120

Example: Fibonacci Sequence

(define (fib n)
  (if (<= n 1)
      n
      (+ (fib (- n 1)) (fib (- n 2)))))

(fib 10) ;; 55

This is a huge milestone 🎉 because recursion is essential in functional programming!

Conclusion

In this update, we:

  • Added shorthand function definitions (e.g., (define (square x) (* x x))).
  • Fixed if expressions to evaluate branches properly.
  • Enabled recursion, making functions like factorial and fib possible.

Writing Your Own Lisp Interpreter in Haskell - Part 6

18 Feb 2025

Introduction

In this update, we extend our Lisp interpreter with floating point numbers and floating point math functions. This brings us closer to full numeric support, allowing for a much richer mathematical capability.

If you’re following along, you can find the implementation for this article here.

Floating Point Type

Until now, our Lisp implementation only supported integers:

data LispVal
    = Atom String
    | Number Integer
    | Bool Bool
    | String String
    | Float Double  -- Added floating point support
    | List [LispVal]
    | Pair LispVal LispVal
    | Lambda [String] LispVal Env
    | BuiltinFunc ([LispVal] -> ThrowsError LispVal)
    | BuiltinFuncIO ([LispVal] -> IOThrowsError LispVal)

We introduced a new constructor Float Double to represent floating point numbers.

Parsing

We needed to update our parser to recognize floating point literals. We do this in such a way to operate alongside the current integer math that we currently support. We don’t want to disturb the work that we’ve already done, so we’ll use that effort here.

parseInteger :: Parser LispVal
parseInteger = do
    sign <- optionMaybe (char '-')  -- Look for optional '-'
    digits <- many1 digit
    let number = read digits
    return $ Number $ case sign of
        Just _  -> -number
        Nothing -> number

parseFloat :: Parser LispVal
parseFloat = do
    sign <- optionMaybe (char '-')  -- Look for optional '-'
    whole <- many1 digit
    char '.'
    fractional <- many1 digit
    let number = read (whole ++ "." ++ fractional)
    return $ Float $ case sign of
        Just _  -> -number
        Nothing -> number

parseNumber :: Parser LispVal
parseNumber = try parseFloat <|> parseInteger

So, we changed the meaning of parseNumber from our original implementation. Instead of parseNumber handling only integers, we split the logic into parseInteger and parseFloat, ensuring both number types are correctly parsed

This ensures that expressions like 3.14 are correctly interpreted as floating point numbers, while still maintaining expressions like 3 being handled as integers.

One extra added feature here is handling negative numbers. We never observed the - symbol that can appear before some numbers, so we’ve fixed this in the parser at the same time.

Numeric Coercion

Next, we needed to handle operations between integers and floats.

Our previous numeric functions assumed only integers, so we modified them to coerce integers to floats when necessary. This means that we can use integers and floats together in our expressions.

numericAdd, numericSub, numericMul, numericDiv :: [LispVal] -> ThrowsError LispVal

numericAdd [Number a, Number b] = return $ Number (a + b)
numericAdd [Float a, Float b] = return $ Float (a + b)
numericAdd [Number a, Float b] = return $ Float (fromIntegral a + b)
numericAdd [Float a, Number b] = return $ Float (a + fromIntegral b)
numericAdd args = throwError $ TypeMismatch "Expected numbers" (List args)

This same logic was applied to subtraction, multiplication, and division.

Division Considerations

Division needed special attention because it must always return a float when dividing integers:

numericDiv [Number a, Number b] =
    if b == 0 then throwError $ TypeMismatch "Division by zero" (Number b)
    else return $ Float (fromIntegral a / fromIntegral b)
numericDiv [Float a, Float b] = return $ Float (a / b)
numericDiv [Number a, Float b] = return $ Float (fromIntegral a / b)
numericDiv [Float a, Number b] = return $ Float (a / fromIntegral b)
numericDiv args = throwError $ TypeMismatch "Expected numbers" (List args)

This ensures that (/ 3 2) evaluates to 1.5 instead of performing integer division.

Adding Floating Point Math Functions

With float support in place, we introduced math functions like sin, cos, tan, exp, log, and sqrt:

import Prelude hiding (log)

numericSin, numericCos, numericTan, numericExp, numericLog, numericSqrt :: [LispVal] -> ThrowsError LispVal

numericSin [Float a] = return $ Float (sin a)
numericSin [Number a] = return $ Float (sin (fromIntegral a))
numericSin args = throwError $ TypeMismatch "Expected a number" (List args)

numericCos [Float a] = return $ Float (cos a)
numericCos [Number a] = return $ Float (cos (fromIntegral a))
numericCos args = throwError $ TypeMismatch "Expected a number" (List args)

numericTan [Float a] = return $ Float (tan a)
numericTan [Number a] = return $ Float (tan (fromIntegral a))
numericTan args = throwError $ TypeMismatch "Expected a number" (List args)

numericExp [Float a] = return $ Float (exp a)
numericExp [Number a] = return $ Float (exp (fromIntegral a))
numericExp args = throwError $ TypeMismatch "Expected a number" (List args)

numericLog [Float a] =
    if a <= 0 then throwError $ TypeMismatch "Logarithm domain error" (Float a)
    else return $ Float (log a)
numericLog [Number a] =
    if a <= 0 then throwError $ TypeMismatch "Logarithm domain error" (Number a)
    else return $ Float (log (fromIntegral a))
numericLog args = throwError $ TypeMismatch "Expected a positive number" (List args)

numericSqrt [Float a] =
    if a < 0 then throwError $ TypeMismatch "Square root of negative number" (Float a)
    else return $ Float (sqrt a)
numericSqrt [Number a] =
    if a < 0 then throwError $ TypeMismatch "Square root of negative number" (Number a)
    else return $ Float (sqrt (fromIntegral a))
numericSqrt args = throwError $ TypeMismatch "Expected a non-negative number" (List args)

We then added them to the built-in function table:

primitives =
  [ ("sin", BuiltinFunc numericSin),
    ("cos", BuiltinFunc numericCos),
    ("tan", BuiltinFunc numericTan),
    ("exp", BuiltinFunc numericExp),
    ("log", BuiltinFunc numericLog),
    ("sqrt", BuiltinFunc numericSqrt)
  ]

Testing

With these changes, we can now perform floating point math:

(sin 0.0)   ;; 0.0
(cos 0.0)   ;; 1.0
(exp 1.0)   ;; 2.718281828
(log 10.0)  ;; 2.302585092
(sqrt 16.0) ;; 4.0

Conclusion

In this update, we:

  • Added floating point support.
  • Added negative support.
  • Introduced numeric coercion between integers and floats.
  • Implemented floating point math functions.
  • Ensured division always returns a float.

Writing Your Own Lisp Interpreter in Haskell - Part 5

16 Feb 2025

Introduction

In our previous installment, we added basic list operations to our Lisp interpreter, including cons, car, cdr, append, and reverse.

Now, we are expanding that functionality by introducing higher-order list functions:

  • map
  • filter
  • foldl and foldr
  • sort

Additionally, we’re introducing string manipulation functions that allow us to treat strings as lists of characters:

  • string->list
  • list->string

These changes bring our Lisp interpreter closer to standard Scheme-like behavior.

If you’re following along, you can find the updated implementation for this article here.

Lambda Expressions

A lambda function in computer programming is an anonymous function that we use to pass to higher-order functions.

To support map, filter, and fold, we implemented lambda functions properly. Previously, our Lisp could parse lambdas but couldn’t correctly apply them.

Adding Lambda Support

We modified eval to properly capture the current environment and store parameter names:

eval env (List [Atom "lambda", List params, body]) =
    case mapM getParamName params of
        Right paramNames -> return $ Lambda paramNames body env
        Left err -> throwError err
  where
    getParamName (Atom name) = Right name
    getParamName badArg = Left $ TypeMismatch "Expected parameter name" badArg

When a lambda function is applied, it creates a new local environment that maps function parameters to actual arguments.

apply (Lambda params body closure) args = do
    env <- liftIO $ readIORef closure
    if length params == length args
        then do
            let localEnv = Map.union (Map.fromList (zip params args)) env
            newEnvRef <- liftIO $ newIORef localEnv
            eval newEnvRef body
        else throwError $ NumArgs (length params) args

Example

Now, we can define and call lambda functions:

(define square (lambda (x) (* x x)))
(square 5)  ;; 25

Higher-Order List Functions

Now that lambda functions work, we can introduce list processing functions.

Map

map applies a function to each element in a list and returns a new list.

listMap :: [LispVal] -> IOThrowsError LispVal
listMap [Lambda params body env, List xs] =
    List <$> mapM (\x -> apply (Lambda params body env) [x]) xs
listMap args = throwError $ TypeMismatch "Expected a function and a list" (List args)

Example

(map (lambda (x) (* x 2)) '(1 2 3 4))
;; => (2 4 6 8)

Filter

filter removes elements that don’t satisfy a given predicate.

listFilter :: [LispVal] -> IOThrowsError LispVal
listFilter [func@(Lambda _ _ _), List xs] = do
    filtered <- filterM (\x -> do
        result <- apply func [x]
        case result of
            Bool True  -> return True
            Bool False -> return False
            _          -> throwError $ TypeMismatch "Expected boolean return" result
        ) xs
    return $ List filtered
listFilter args = throwError $ TypeMismatch "Expected a function and a list" (List args)

Example

(filter (lambda (x) (> x 5)) '(2 4 6 8))
;; => (6 8)

Fold (Reduce)

foldl and foldr accumulate values from left to right or right to left.

listFoldL :: [LispVal] -> IOThrowsError LispVal
listFoldL [Lambda params body env, initial, List xs] =
    foldM (\acc x -> apply (Lambda params body env) [acc, x]) initial xs
listFoldL args = throwError $ TypeMismatch "Expected a function, initial value, and a list" (List args)
listFoldR :: [LispVal] -> IOThrowsError LispVal
listFoldR [Lambda params body env, initial, List xs] =
    foldM (\acc x -> apply (Lambda params body env) [x, acc]) initial (reverse xs)
listFoldR args = throwError $ TypeMismatch "Expected a function, initial value, and a list" (List args)

Example

(foldl (lambda (acc x) (+ acc x)) 0 '(1 2 3 4 5))
;; => 15

This works like (((((0 + 1) + 2) + 3) + 4) + 5).

Whilst swapping out foldr for foldl in this scenario gives us the same result, it’s very different in execution. It ends up working like (1 + (2 + (3 + (4 + (5 + 0))))).

Sort

sort Sorts a list in ascending order by default or with a custom comparator.

listSort :: [LispVal] -> ThrowsError LispVal
listSort [List xs] =
    case xs of
        [] -> return $ List []
        (Number _:_) -> return $ List (sortBy compareNumbers xs)
        (String _:_) -> return $ List (sortBy compareStrings xs)
        _ -> throwError $ TypeMismatch "Cannot sort mixed types" (List xs)
  where
    compareNumbers (Number a) (Number b) = compare a b
    compareStrings (String a) (String b) = compare a b

listSort [Lambda params body closure, List xs] =
    case xs of
        [] -> return $ List []
        _  -> throwError $ TypeMismatch "Custom sorting requires ThrowsErrorIO" (List xs)
        -- If you later want custom sorting, you'd need `ThrowsErrorIO`
listSort args = throwError $ TypeMismatch "Expected a list (optionally with a comparator function)" (List args)

Example

(sort '(5 3 8 1 4))
;; => (1 3 4 5 8)

Optionally, the implementation allows you to specify a predicate to control the sort.

String Manipulation

Strings are now treated as lists of characters in our Lisp. This can sometimes make things easier to work with when dealing with strings.

Example

We can convert a string into a list (and therefore operate on it like it’s a list) by using string->list.

stringToList :: [LispVal] -> ThrowsError LispVal
stringToList [String s] = return $ List (map (String . (:[])) s)
stringToList args = throwError $ NumArgs 1 args
(string->list "hello")
;; => ("h" "e" "l" "l" "o")

We reverse this process with list->string.

listToString :: [LispVal] -> ThrowsError LispVal
listToString [List chars] = case mapM extractChar chars of
    Right strList -> return $ String (concat strList)
    Left err -> throwError err
  where
    extractChar (String [c]) = Right [c]
    extractChar invalid = Left $ TypeMismatch "Expected a list of single-character strings" invalid
listToString args = throwError $ NumArgs 1 args
(list->string '("h" "e" "l" "l" "o"))
;; => "hello"

Conclusion

We now how have higher order functions and lambda functions controlling our list processing. Stay tuned for further updates as we add more features to our Lisp.

Writing Your Own Lisp Interpreter in Haskell - Part 4

16 Feb 2025

Introduction

In the previous post we added conditionals to our basic Lisp interpreter. Now, it’s time to introduce list manipulation – one of Lisp’s most fundamental features.

This update brings support for:

  • Pairs (cons), first element (car), and rest (cdr)
  • List predicates (null?)
  • Common list operations (append, length, reverse)
  • Proper parsing of quoted lists ('(...))

Pairs and Lists

In Lisp, lists are built from pairs (cons cells). Each pair contains a head (car) and a tail (cdr). We’ll add Pair into our LispVal data type:

data LispVal
    = Atom String
    | Number Integer
    | Bool Bool
    | String String
    | List [LispVal]
    | Pair LispVal LispVal  
    | Lambda [String] LispVal Env
    | BuiltinFunc ([LispVal] -> ThrowsError LispVal)

This allows us to represent both lists and dotted pairs like:

(cons 1 2)    ;; (1 . 2)
(cons 1 '(2)) ;; (1 2)

cons, car, and cdr

cons is a function in most dialects of Lisp that constructs memory objects which hold two values or pointers to two values.

cons :: [LispVal] -> ThrowsError LispVal
cons [x, List xs] = return $ List (x : xs)  
cons [x, y]       = return $ Pair x y       
cons args         = throwError $ NumArgs 2 args

This allows us to build pairs and lists alike:

(cons 1 2)       ;; (1 . 2)
(cons 1 '(2 3))  ;; (1 2 3)

(car and cdr)[https://en.wikipedia.org/wiki/CAR_and_CDR] are list primitives that allow you to return the first or second component of a pair.

The expression (car (cons x y)) evaluates to x, and (cdr (const x y)) evaluates to y.

car :: [LispVal] -> ThrowsError LispVal
car [List (x : _)] = return x
car [Pair x _]     = return x  
car [List []]      = throwError $ TypeMismatch "Cannot take car of empty list" (List [])
car [arg]          = throwError $ TypeMismatch "Expected a pair or list" arg
car args           = throwError $ NumArgs 1 args

cdr :: [LispVal] -> ThrowsError LispVal
cdr [List (_ : xs)] = return $ List xs  
cdr [Pair _ y]      = return y          
cdr [List []]       = throwError $ TypeMismatch "Cannot take cdr of empty list" (List [])
cdr [arg]           = throwError $ TypeMismatch "Expected a pair or list" arg
cdr args            = throwError $ NumArgs 1 args

We can now uwe these functions to work with our lists and pairs:

(car '(1 2 3))   ;; 1
(car '(a b c))   ;; a
(car '(5 . 6))   ;; 5

(cdr '(1 2 3))   ;; (2 3)
(cdr '(a b c))   ;; (b c)
(cdr '(5 . 6))   ;; 6

Checking for Empty Lists

We need a way to determine if our list is empty, and we do that with isNull:

isNull :: [LispVal] -> ThrowsError LispVal
isNull [List []] = return $ Bool True
isNull [_]       = return $ Bool False
isNull args      = throwError $ NumArgs 1 args

This is pretty straight forward to use:

(null? '())      ;; #t
(null? '(1 2 3)) ;; #f

Extending List Operations

Going a little bit further now, we can easily implement append, length, and reverse.

listAppend :: [LispVal] -> ThrowsError LispVal
listAppend [List xs, List ys] = return $ List (xs ++ ys)
listAppend [List xs, y] = return $ List (xs ++ [y])  
listAppend [x, List ys] = return $ List ([x] ++ ys)  
listAppend args = throwError $ TypeMismatch "Expected two lists or a list and an element" (List args)

listLength :: [LispVal] -> ThrowsError LispVal
listLength [List xs] = return $ Number (toInteger (length xs))
listLength [arg] = throwError $ TypeMismatch "Expected a list" arg
listLength args = throwError $ NumArgs 1 args

listReverse :: [LispVal] -> ThrowsError LispVal
listReverse [List xs] = return $ List (reverse xs)
listReverse [arg] = throwError $ TypeMismatch "Expected a list" arg
listReverse args = throwError $ NumArgs 1 args

These functions allow us to perform some more interesting processing of our lists:

(append '(1 2) '(3 4))  ;; (1 2 3 4)
(append '(a b) 'c)      ;; (a b c)
(append 'a '(b c))      ;; (a b c)

(length '(1 2 3 4 5))   ;; 5
(length '())            ;; 0

(reverse '(1 2 3 4 5))   ;; (5 4 3 2 1)
(reverse '())            ;; ()

Quoted Lists

Finally, Lisp allows shorthand notation for quoting lists. For example, '(1 2 3) is equivalent to (quote (1 2 3)).

parseQuote :: Parser LispVal
parseQuote = do
    char '\''
    expr <- parseExpr 
    return $ List [Atom "quote", expr]

Conclusion

Our Lisp interpreter is now becoming a little more sophisticated. List processing is so fundamental to how Lisp operates that we needed to get this implemented as soon as possible. The code for this particular article is available up on GitHub to pull down and take a look at.

(define names '("Sally" "Joe" "Tracey" "Bob"))
("Sally" "Joe" "Tracey" "Bob")

(reverse names)
("Bob" "Tracey" "Joe" "Sally")

(car (cdr (reverse names)))
"Tracey"

(append names '("Stacey" "Peter"))
("Sally" "Joe" "Tracey" "Bob" "Stacey" "Peter")

Writing Your Own Lisp Interpreter in Haskell - Part 3

16 Feb 2025

Introduction

In our previous post, we introduced persistent variables into our Lisp interpreter, making it possible to store and retrieve values across expressions.

Now, it’s time to make our Lisp smarter by adding conditionals and logic.

In this post, we’ll extend our interpreter with:

  • if expressions
  • Boolean logic (and, or, xor, not)
  • String support for conditionals
  • Expanded numeric comparisons (<=, >=)

By the end of this post, you’ll be able to write real conditional logic in our Lisp, compare both numbers and strings, and use logical expressions effectively.

Adding if Statements

We start with the classic Lisp conditional expression:

(if (< 10 5) "yes" "no")  ;; Expected result: "no"
(if (= 3 3) "equal" "not equal")  ;; Expected result: "equal"

We add support for this by adjusting eval:

eval env (List [Atom "if", condition, thenExpr, elseExpr]) = do
    result <- eval env condition
    case result of
        Bool True  -> return thenExpr  -- Return without evaluating again
        Bool False -> return elseExpr  -- Return without evaluating again
        _          -> throwError $ TypeMismatch "Expected boolean in if condition" result

Testing

We can see this in action now:

λ> (if (> 10 20) "yes" "no")
"no"
λ> (if (= 42 42) "match" "no-match")
"match"
λ> (if #f 10 20)
20

Expanding Boolean Logic

Now, we’ll add some boolean operators that are standard in conditionals:

  • (and ...) → Returns #t if all values are #t.
  • (or ...) → Returns #t if at least one value is #t.
  • (xor ...) → Returns #t if exactly one value is #t.
  • (not x) → Returns #t if x is #f, otherwise returns #f.

These functions get added to Eval.hs:

booleanAnd, booleanOr, booleanXor :: [LispVal] -> ThrowsError LispVal

booleanAnd args = return $ Bool (all isTruthy args)  -- Returns true only if all args are true
booleanOr args = return $ Bool (any isTruthy args)  -- Returns true if at least one arg is true

booleanXor args =
    let countTrue = length (filter isTruthy args)
    in return $ Bool (countTrue == 1)  -- True if exactly one is true

notFunc :: [LispVal] -> ThrowsError LispVal
notFunc [Bool b] = return $ Bool (not b)  -- Negates the boolean
notFunc [val] = throwError $ TypeMismatch "Expected boolean" val
notFunc args = throwError $ NumArgs 1 args

isTruthy :: LispVal -> Bool
isTruthy (Bool False) = False  -- Only #f is false
isTruthy _ = True  -- Everything else is true

These functions get added as primitives to our Lisp:

primitives =
  [ ("not", BuiltinFunc notFunc),
    ("and", BuiltinFunc booleanAnd),
    ("or", BuiltinFunc booleanOr),
    ("xor", BuiltinFunc booleanXor)
  ]

Testing

We can now exercise these new built-ins:

λ> (and #t #t #t)
#t
λ> (or #f #f #t)
#t
λ> (xor #t #f)
#t
λ> (not #t)
#f

We now have a full suite of logical operators.

Strings

Before this point, our Lisp has been very number based. Strings haven’t really seen much attention as our focus has been on putting together basic functionality first. With conditionals being added into our system, it’s time to give strings a little bit of attention.

First job is to expand = to also support strings.

numericEquals [Number a, Number b] = return $ Bool (a == b)
numericEquals [String a, String b] = return $ Bool (a == b)  -- Added string support
numericEquals args = throwError $ TypeMismatch "Expected numbers or strings" (List args)

Testing

We can see this in action now with a string variable:

λ> (define name "Joe")
"Joe"
λ> (if (= name "Joe") "yes" "no")
"yes"
λ> (if (= name "Alice") "yes" "no")
"no"

More Numeric Comparators

To round out all of our comparison operators, we throw in implementations for <= and >=.

numericLessThanEq [Number a, Number b] = return $ Bool (a <= b)
numericLessThanEq args = throwError $ TypeMismatch "Expected numbers" (List args)

numericGreaterThanEq [Number a, Number b] = return $ Bool (a >= b)
numericGreaterThanEq args = throwError $ TypeMismatch "Expected numbers" (List args)

These also require registration in our primitive set:

primitives =
  [ ("<=", BuiltinFunc numericLessThanEq),
    (">=", BuiltinFunc numericGreaterThanEq)
  ]

Conclusion

We’ve added some great features to support conditional process here. As always part 3 of the code to follow this tutorial is available.