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Hi Language Interpreter

Thanks @int-index for such a great homework.

Project Structure

Create a .cabal file with both a library and an executable:

library
  exposed-modules:    ...
  build-depends:      ...
  ...

executable hi
  main-is:            Main.hs
  hs-source-dirs:     ...
  build-depends:      ...
  ...

In the library component, create the following modules:

HW3.Base
HW3.Parser
HW3.Pretty
HW3.Evaluator

You are allowed to add more modules to the project, but those are the required ones.

  • In HW3.Base, define the following data types:

    data HiFun     -- function names (e.g. div, sort, length, ...)
    data HiValue   -- values (numbers, booleans, strings, ...)
    data HiExpr    -- expressions (literals, function calls, ...)
    data HiError   -- evaluation errors (invalid arguments, ...)
    

    In each task, we will add constructors to these data types that are needed to implement new language features.

  • In HW3.Parser, define the following function:

    parse :: String -> Either (ParseErrorBundle String Void) HiExpr
    

    The ParseErrorBundle type comes from the megaparsec package which we will use to implement our parser.

  • In HW3.Pretty, define the following function:

    prettyValue :: HiValue -> Doc AnsiStyle
    

    The Doc and AnsiStyle types come from the prettyprinter and prettyprinter-ansi-terminal packages respectively. This function renders a value to a document, which in turn can be either printed to the terminal (with color highlighting) or converted to a string.

  • In HW3.Evaluator, define the following function:

    eval :: Monad m => HiExpr -> m (Either HiError HiValue)
    

    One might wonder why we need the Monad m part. Indeed, for arithmetic operations, a simpler type would be sufficient:

    eval :: HiExpr -> Either HiError HiValue
    

    However, the monadic context will come into play later, when we start implementing IO actions (file system access, random number generation, and so on).

The executable component consists just of a single file, Main.hs.

The REPL

Using the haskeline package, implement a REPL in Main.hs that uses parse, eval, and prettyValue defined above. It’s going to be just 15–20 lines of code, but you will use it all the time to test your implementation.

Here’s an example session that will become possible as soon as we implement arithmetic operations:

hi> mul(2, 10)
20

hi> sub(1000, 7)
993

hi> div(3, 5)
0.6

Task 1: Numbers and arithmetic

  1. Extend the data types in HW3.Base to include the following constructors:

    data HiFun =
      ...
      | HiFunDiv
      | HiFunMul
      | HiFunAdd
      | HiFunSub
    
    data HiValue =
      ...
      | HiValueNumber Rational
      | HiValueFunction HiFun
    
    data HiExpr =
      ...
      | HiExprValue HiValue
      | HiExprApply HiExpr [HiExpr]
    
    data HiError =
      ...
      | HiErrorInvalidArgument
      | HiErrorInvalidFunction
      | HiErrorArityMismatch
      | HiErrorDivideByZero
    

    Numbers are represented using the Rational type from Data.Ratio.

  2. In the parser, add support for the following constructs:

    • Built-in names div, mul, add, and sub, that are parsed into the corresponding HiFun constructors (and then wrapped in HiValueFunction).

    • Numeric literals, such as 2, 3.14, -1.618, or 1.2e5, that are parsed into HiValueNumber (tip: use Text.Megaparsec.Char.Lexer.scientific).

    • Function application f(a, b, c, ...) that is parsed into HiExprApply.

    For example, the expression div(add(10, 15.1), 3) is represented by the following syntax tree:

    HiExprApply (HiExprValue (HiValueFunction HiFunDiv))
      [
        HiExprApply (HiExprValue (HiValueFunction HiFunAdd))
          [
            HiExprValue (HiValueNumber (10 % 1)),
            HiExprValue (HiValueNumber (151 % 10))
          ],
        HiExprValue (HiValueNumber (3 % 1))
      ]
    
  3. In the evaluator, implement the arithmetic operations:

    • add(500, 12) evaluates to 512 (addition)
    • sub(10, 100) evaluates to -90 (subtraction)
    • mul(23, 768) evaluates to 17664 (multiplication)
    • div(57, 190) evaluates to 0.3 (division)

    Nested function applications are allowed:

    • div(add(mul(2, 5), 1), sub(11,6)) evaluates to 2.2

    The following errors must be returned as HiError:

    • HiErrorArityMismatch: functions called with an incorrect amount of arguments, e.g. sub(1) or sub(1, 2, 3).
    • HiErrorDivideByZero: the div function is called with 0 as its second argument, e.g. div(1, 0) or div(1, sub(5, 5)).
    • HiErrorInvalidFunction: numbers are used in function positions, e.g. 15(2).
    • HiErrorInvalidArgument: functions are used in numeric positions, e.g. sub(10, add).

    You are advised to use the ExceptT monad transformer to propagate HiError through the evaluator.

  4. In the pretty-printer, define the following special cases for rendering numbers:

    • integers: 42, -8, 15
    • finite decimal fractions: 3.14, -8.15, 77.01
    • fractions: 1/3, -1/7, 3/11
    • mixed fractions: 5 + 1/3, -10 - 1/7, 24 + 3/11

    You will find these functions useful:

    • quotRem from Prelude
    • fromRationalRepetendUnlimited from the scientific package

The following session in the REPL should be possible if you have implemented all of the above correctly:

hi> 100
100

hi> -15
-15

hi> add(100, -15)
85

hi> add(3, div(14, 100))
3.14

hi> div(10, 3)
3 + 1/3

hi> sub(mul(201, 11), 0.33)
2210.67

Task 2: Booleans and comparison

  1. Extend the data types in HW3.Base to include the following constructors:

    data HiFun =
      ...
      | HiFunNot
      | HiFunAnd
      | HiFunOr
      | HiFunLessThan
      | HiFunGreaterThan
      | HiFunEquals
      | HiFunNotLessThan
      | HiFunNotGreaterThan
      | HiFunNotEquals
      | HiFunIf
    
    data HiValue =
      ...
      | HiValueBool Bool
    
  2. In the parser, add support for the following constructs:

    • Built-in names not, and, or, less-than, greater-than, equals, not-less-than, not-greater-than, not-equals, if, that are parsed into the corresponding HiFun constructors.

    • Built-in names true and false that are parsed into HiValueBool.

  3. In the evaluator, implement the new operations.

    Boolean algebra:

    • not(true) evaluates to false (negation)
    • and(true, false) evaluates to false (conjunction)
    • or(true, false) evaluates to true (disjunction)

    Equality checking:

    • equals(10, 10) evaluates to true
    • equals(false, false) evaluates to true
    • equals(3, 10) evaluates to false
    • equals(1, true) evaluates to false (no implicit cast)

    Comparisons:

    • less-than(3, 10) evaluates to true
    • less-than(false, true) evaluates to true
    • less-than(false, 0) evaluates to true (Bool is less than Number)

    Complements:

    • for all A B, greater-than(A, B) ≡ less-than(B, A) holds
    • for all A B, not-equals(A, B) ≡ not(equals(A, B)) holds
    • for all A, B, not-less-than(A, B) ≡ not(less-than(A, B)) holds
    • for all A, B, not-greater-than(A, B) ≡ not(greater-than(A, B)) holds

    Branching:

    • for all A B, if(true, A, B) ≡ A holds
    • for all A B, if(false, A, B) ≡ B holds

The following session in the REPL should be possible:

hi> false
false

hi> equals(add(2, 2), 4)
true

hi> less-than(mul(999, 99), 10000)
false

hi> if(greater-than(div(2, 5), div(3, 7)), 1, -1)
-1

hi> and(less-than(0, 1), less-than(1, 0))
false

Note also that functions are values:

hi> if(true, add, mul)
add

hi> if(true, add, mul)(10, 10)
20

hi> if(false, add, mul)(10, 10)
100

Functions can also be tested for equality:

hi> equals(add, add)
true

hi> equals(add, mul)
false

The check is trivial: a function is equal only to itself.

Ordering of function symbols is implementation-defined, that is, it’s up to you whether less-than(add, mul) or greater-than(add, mul).

Task 3: Operators

In the parser, add support for infix operators. The precedence and associativity are the same as in Haskell.

For all A B:

  • A / B parses to div(A, B)
  • A * B parses to mul(A, B)
  • A + B parses to add(A, B)
  • A - B parses to sub(A, B)
  • A < B parses to less-than(A, B)
  • A > B parses to greater-than(A, B)
  • A >= B parses to not-less-than(A, B)
  • A <= B parses to not-greater-than(A, B)
  • A == B parses to equals(A, B)
  • A /= B parses to not-equals(A, B)
  • A && B parses to and(A, B)
  • A || B parses to or(A, B)

Tip: use makeExprParser from the parser-combinators package.

The following session in the REPL should be possible:

hi> 2 + 2
4

hi> 2 + 2 * 3
8

hi> (2 + 2) * 3
12

hi> 2 + 2 * 3 == (2 + 2) * 3
false

hi> 10 == 2*5 && 143 == 11*13
true

Task 4: Strings and slices

  1. Extend the data types in HW3.Base to include the following constructors:

    data HiFun =
      ...
      | HiFunLength
      | HiFunToUpper
      | HiFunToLower
      | HiFunReverse
      | HiFunTrim
    
    data HiValue =
      ...
      | HiValueNull
      | HiValueString Text
    

    Strings are represented using the Text type from the text package.

  2. In the parser, add support for the following constructs:

    • Bulit-in names length, to-upper, to-lower, reverse, trim, that are parsed into the corresponding HiFun constructors.

    • Built-in name null that is parsed into HiValueNull.

    • String literals, such as "hello", "42", or "header\nfooter", that are parsed into HiValueString (tip: use Text.Megaparsec.Char.Lexer.charLiteral).

  3. In the evaluator, implement the new operations:

    • length("Hello World") evaluates to 11
    • to-upper("Hello World") evaluates to "HELLO WORLD"
    • to-lower("Hello World") evaluates to "hello world"
    • reverse("stressed") evaluates to "desserts"
    • trim(" Hello World ") evaluates to "Hello World"

    Then overload existing operations to work on strings:

    • "Hello" + "World" evaluates to "HelloWorld"
    • "Cat" * 5 evaluates to "CatCatCatCatCat" (tip: use stimes)
    • "/home/user" / "hi" evaluates to "/home/user/hi"

    When a string is used as a function of one argument, perform a lookup:

    • "Hello World"(0) evaluates to "H"
    • "Hello World"(7) evaluates to "o"

    Out-of-bounds indexing returns null:

    • "Hello World"(-1) evaluates to null
    • "Hello World"(99) evaluates to null

    When a string is used as a function of two arguments, take a slice:

    • "Hello World"(0, 5) evaluates to "Hello"
    • "Hello World"(2, 4) evaluates to "ll"
  4. (Advanced) When a slice index is negative, implement the Python semantics of indexing from the end of the string:

    • "Hello World"(0, -4) evaluates to "Hello W"
    • "Hello World"(-4, -1) evaluates to "orl"

    When a slice index is null, treat it as the start/end of the string:

    • "Hello, World"(2, null) evaluates to "llo, World"
    • "Hello, World"(null, 5) evaluates to "Hello"

The following session in the REPL should be possible:

hi> to-upper("what a nice language")(7, 11)
"NICE"

hi> "Hello" == "World"
false

hi> length("Hello" + "World")
10

hi> length("hehe" * 5) / 3
6 + 2/3

Task 5: Lists and folds

  1. Extend the data types in HW3.Base to include the following constructors:

    data HiFun =
      ...
      | HiFunList
      | HiFunRange
      | HiFunFold
    
    data HiValue =
      ...
      | HiValueList (Seq HiValue)
    

    Lists are represented using the Seq type from the containers package.

  2. In the parser, add support for the following constructs:

    • Built-in names list, range, fold, that are parsed into the corresponding HiFun constructors.

    • List literals, written as [A, B, C, ...], that are parsed into function application list(A, B, C, ...).

  3. In the evaluator, implement the new operations:

    • list(1, 2, 3) constructs HiValueList containing 1, 2, 3
    • range(5, 10.3) evaluates to [5, 6, 7, 8, 9, 10]
    • fold(add, [11, 22, 33]) evaluates to 66
    • fold(mul, [11, 22, 33]) evaluates to 7986
    • fold(div, [11, 22, 33]) evaluates to 1/66 (left fold)

    Then overload existing operations to work on lists:

    • length([1, true, "Hello"]) evaluates to 3
    • reverse([1, true, "Hello"]) evaluates to ["Hello", true, 1]
    • [1, 2] + [3, 4, 5] evaluates to [1, 2, 3, 4, 5]
    • [0, "x"] * 3 evaluates to [0, "x", 0, "x", 0, "x"] (tip: use stimes)

    When a list is used as a function, perform indexing/slicing:

    • ["hello", true, "world"](1) evaluates to true
    • ["hello", true, "world"](1,3) evaluates to [true, "world"]

The following session in the REPL should be possible:

hi> list(1, 2, 3, 4, 5)
[ 1, 2, 3, 4, 5 ]

hi> fold(add, [2, 5] * 3)
21

hi> fold(mul, range(1, 10))
3628800

hi> [0, true, false, "hello", "world"](2, 4)
[ false, "hello" ]

hi> reverse(range(0.5, 70/8))
[ 8.5, 7.5, 6.5, 5.5, 4.5, 3.5, 2.5, 1.5, 0.5 ]

Task 6: Bytes and serialisation

Lists of bytes (numbers from 0 to 255) can be represented and processed more efficiently. Let us introduce a new value type for them.

  1. Extend the data types in HW3.Base to include the following constructors:

    data HiFun =
      ...
      | HiFunPackBytes
      | HiFunUnpackBytes
      | HiFunEncodeUtf8
      | HiFunDecodeUtf8
      | HiFunZip
      | HiFunUnzip
      | HiFunSerialise
      | HiFunDeserialise
    
    data HiValue =
      ...
      | HiValueBytes ByteString
    

    Bytes are represented using the strict ByteString type from the bytestring package.

  2. In the parser, add support for the following constructs:

    • Built-in names pack-bytes, unpack-bytes, zip, unzip, encode-utf8, decode-utf8, serialise, and deserialise, that are parsed into the corresponding HiFun constructors.

    • Byte array literals, such as [# 01 3f ec #] that are parsed into HiValueBytes. Each element is a two-digit hexadecimal number.

  3. In the evaluator, implement the new operations:

    • pack-bytes([ 3, 255, 158, 32 ]) evaluates to [# 03 ff 9e 20 #]
    • unpack-bytes([# 10 20 30 #]) evaluates to [16, 32, 48]
    • encode-utf8("Hello!") evaluates to [# 48 65 6c 6c 6f 21 #]
    • decode-utf8([# 48 65 6c 6c 6f #]) evaluates to "Hello"
    • decode-utf8([# c3 28 #]) evaluates to null (invalid UTF-8 byte sequence)
    • zip compresses the bytes using the zlib package (specify bestCompression)
    • serialise turns any value into bytes using the serialise package
    • for all A, unzip(zip(A)) ≡ A holds
    • for all A, deserialise(serialise(A)) ≡ A holds

    Then overload existing operations to work on bytes:

    • [# 00 ff #] + [# 01 e3 #] evaluates to [# 00 ff 01 e3 #]
    • [# 00 ff #] * 3 evaluates to [# 00 ff 00 ff 00 ff #] (tip: use stimes)

    When bytes are used as a function, perform indexing/slicing as with strings and lists:

    • [# 00 ff 01 e3 #](1) evaluates to 255
    • [# 00 ff 01 e3 #](1,3) evaluates to [# ff 01 #]

The following session in the REPL should be possible:

hi> pack-bytes(range(30, 40))
[# 1e 1f 20 21 22 23 24 25 26 27 28 #]

hi> zip(encode-utf8("Hello, World!" * 1000))
[# 78 da ed c7 31 0d 00 20 0c 00 30 2b f0 23 64 0e 30 00 df 92 25 f3 7f a0 82 af
   fd 1a 37 b3 d6 d8 d5 79 66 88 88 88 88 88 88 88 88 88 88 88 88 88 88 88 88 88
   88 88 88 88 88 88 88 88 fc c9 03 ca 0f 3b 28 #]

hi> decode-utf8([# 68 69 #] * 5)
"hihihihihi"

hi> unzip([# 78 da 63 64 62 06 00 00 0d 00 07 #])
[# 01 02 03 #]

Task 7: File I/O

In this task we extend the language with I/O capabilities. We consider it to be the most important part of the homework and it is graded with extra points.

Let us start by creating a new type in HW3.Base that encodes the available actions:

data HiAction =
    HiActionRead  FilePath
  | HiActionWrite FilePath ByteString
  | HiActionMkDir FilePath
  | HiActionChDir FilePath
  | HiActionCwd

Now recall that the type of our eval function is as follows:

eval :: Monad m => HiExpr -> m (Either HiError HiValue)

We could just require m to be IO in order to execute the actions, but that would be bad design, as it would make it impossible to do evaluation in a pure, deterministic context (e.g. for tests). Instead, let us create a new class in HW3.Base:

class Monad m => HiMonad m where
  runAction :: HiAction -> m HiValue

One could imagine at least a few possible instances of this class:

  1. IO, where those actions could interact with the actual file system

  2. Identity, where the actions do nothing and return null

  3. State FS, where FS is a pure and deterministic in-memory simulation of the file system

  4. ReaderT Permissions IO, which can be more secure than IO by controlling whether the program has read-only or read-write access

While it would be useful to implement all of those, we shall limit ourselves to the last one to avoid making the task unnecessarily tedious.

In a new module HW3.Action, declare the following:

data HiPermission =
    AllowRead
  | AllowWrite

data PermissionException =
  PermissionRequired HiPermission

instance Exception PermissionException

newtype HIO a = HIO { runHIO :: Set HiPermission -> IO a }

Finally, let us change the type of eval as follows:

- eval ::   Monad m => HiExpr -> m (Either HiError HiValue)
+ eval :: HiMonad m => HiExpr -> m (Either HiError HiValue)

With those preliminaries out of the way, we can start integrating the actions into the rest of the language.

  1. Extend the data types in HW3.Base to include the following constructors:

    data HiFun =
      ...
      | HiFunRead
      | HiFunWrite
      | HiFunMkDir
      | HiFunChDir
    
    data HiValue =
      ...
      | HiValueAction HiAction
    
    data HiExpr =
      ...
      | HiExprRun HiExpr
    
  2. In the parser, add support for the following constructs:

    • Built-in names read, write, mkdir, cd, that are parsed into the corresponding HiFun constructors.

    • Built-in name cwd that is parsed into HiValueAction HiActionCwd.

    • E! notation that is parsed into HiExprRun, e.g. read("hello.txt")!, mkdir("projects")!, or cwd!.

  3. In the evaluator, implement the new functions to return the corresponding actions:

    • read("hi.txt") evaluates to read("hi.txt"). While visually the same, internally the first one is HiExprApply and the second one is HiValueAction.
    • write("hi.txt", "Hi!") evaluates to write("hi.txt", [# 48 69 21 #])
    • mkdir("dir") evaluates to mkdir("dir")
    • cd("dir") evaluates to cd("dir")

    Then implement the HiExprRun construct, which should execute the action using runAction that we defined earlier.

  4. Define the HiMonad HIO instance, such that:

    • cwd! returns the current working directory
    • cd("mydir")! changes the current working directory to mydir
    • read("myfile")! returns the contents of myfile (use HiValueString if the contents are valid UTF-8 and HiValueBytes otherwise)
    • read("mydir")! returns the directory listing of mydir
    • write("myfile", "Hello")! writes "Hello" to myfile
    • mkdir("mydir")! creates a new directory mydir

    Use the directory package to implement all of the above.

  5. Implement permission control in HiMonad HIO, so that actions throw PermissionException (using throwIO) unless they are allowed.

    • AllowRead enables cwd, cd, read
    • AllowWrite enables write, mkdir

The following session in the REPL should be possible:

hi> mkdir("tmp")!
null

hi> read("tmp")!
[]

hi> mkdir("tmp/a")!
null

hi> mkdir("tmp/b")!
null

hi> read("tmp")!
[ "a", "b" ]

hi> write("tmp/hi.txt", "Hello")!
null

hi> cd("tmp")!
null

hi> read("hi.txt")!
"Hello"

Note that actions are just values and only ! forces their execution:

hi> read
read

hi> read("hi.txt")
read("hi.txt")

hi> read("hi.txt")!
"Hello"

Task 8: Date and time

  1. Extend the data types in HW3.Base to include the following constructors:

    data HiFun =
      ...
      | HiFunParseTime
    
    data HiValue =
      ...
      | HiValueTime UTCTime
    
    data HiAction =
      ...
      | HiActionNow
    

    Time is represented using the UTCTime type from the time package.

    Extend the data types in HW3.Action to include the following constructors:

    data HiPermission =
      ...
      | AllowTime
    
  2. In the parser, add support for the following constructs:

    • Built-in name parse-time that is parsed into the corresponding HiFun constructor.

    • Built-in name now that is parsed into the corresponding HiAction constructor.

  3. In the evaluator, implement parse-time using readMaybe to parse a HiValueString into a HiValueTime, or HiValueNull in case of failure.

  4. In the HiMonad HIO instance, implement the HiActionNow to return the current system time. It requires the AllowTime permission.

  5. In the evaluator, overload existing operations to work on time:

    • parse-time("2021-12-15 00:00:00 UTC") + 1000 evaluates to parse-time("2021-12-15 00:16:40 UTC") (use addUTCTime)
    • parse-time("2021-12-15 00:37:51.000890793 UTC") - parse-time("2021-12-15 00:37:47.649047038 UTC") evaluates to 3.351843755 (use diffUTCTime)

The following session in the REPL should be possible:

hi> now!
parse-time("2021-12-15 00:42:33.02949461 UTC")

hi> parse-time("2021-01-01 00:00:00 UTC") + 365 * 24 * 60 * 60
parse-time("2022-01-01 00:00:00 UTC")

Task 9: Random numbers

  1. Extend the data types in HW3.Base to include the following constructors:

    data HiFun =
      ...
      | HiFunRand
    
    data HiAction =
      ...
      | HiActionRand Int Int
    
  2. In the parser, add support for the built-in name rand that is parsed into the corresponding HiFun constructor.

  3. In the evaluator, implement the new function:

    • rand(0, 10) evaluates to rand(0, 10). While visually the same, internally the first one is HiExprApply and the second one is HiValueAction.
  4. Extend the HiMonad HIO instance, so that:

    • rand(0, 5)! evaluates to 0, 1, 2, 3, 4, or 5
    • the distribution of random numbers is uniform

    Tip: use the random package.

The following session in the REPL should be possible:

hi> rand
rand

hi> rand(0, 10)
rand( 0, 10 )

hi> rand(0, 10)!
8

hi> rand(0, 10)!
3

Task 10: Short-circuit evaluation

  1. Extend the data types in HW3.Base to include the following constructors:

    data HiFun =
      ...
      | HiFunEcho
    
    data HiAction =
      ...
      | HiActionEcho Text
    
  2. In the parser, add support for the built-in name echo that is parsed into the corresponding HiFun constructor.

  3. In the evaluator, implement the new function:

    • echo("Hello") evaluates to echo("Hello"). While visually the same, internally the first one is HiExprApply and the second one is HiValueAction.
  4. Extend the HiMonad HIO instance, so that echo("Hello")! prints Hello followed by a newline to stdout. It requires the AllowWrite permission.

  5. In the evaluator, ensure that if(true, A, B) does not evaluate B, and if(false, A, B) does not evaluate A.

    Then generalise A && B as follows:

    • if A is false or null, return A without evaluating B
    • otherwise, evaluate and return B

    Generalise A || B as follows:

    • if A is false or null, evaluate and return B
    • otherwise, return A without evaluating B

The following session in the REPL should be possible:

hi> echo
echo

hi> echo("Hello")
echo("Hello")

hi> echo("Hello")!
Hello
null

hi> "Hello"(0) || "Z"
"H"

hi> "Hello"(99) || "Z"
"Z"

hi> if(2 == 2, echo("OK")!, echo("WTF")!)
OK
null

hi> true || echo("Don't do this")!
true

hi> false && echo("Don't do this")!
false

hi> [# 00 ff #] && echo("Just do it")!
Just do it
null

Task 11: Dictionaries

  1. Extend the data types in HW3.Base to include the following constructors:

    data HiFun =
      ...
      | HiFunCount
      | HiFunKeys
      | HiFunValues
      | HiFunInvert
    
    data HiValue =
      ...
      | HiValueDict (Map HiValue HiValue)
    
    data HiExpr =
      ...
      | HiExprDict [(HiExpr, HiExpr)]
    

    Dictionaries are represented using the Map type from the containers package.

  2. In the parser, add support for the following constructs:

    • Built-in names count, keys, values, invert, that are parsed into the corresponding HiFun constructors.

    • Dictionary literals, written as { I: A, J: B, K: C }, for example:

      • { "width": 120, "height": 80 }
      • { 1: true, 3: true, 4: false }
    • Dot access, written as E.fld, that is parsed into function application E("fld"). For example, the following holds:

      { "width": 120, "height": 80 }.width
        ≡
      { "width": 120, "height": 80 }("width")
      
  3. In the evaluator, implement the new operations:

    • { "width": 120, "height": 80 }("width") evaluates to 120
    • keys({ "width": 120, "height": 80 }) evaluates to ["height", "width"] (sorted)
    • values({ "width": 120, "height": 80 }) evaluates to [80, 120] (sorted by key)
    • count("XXXOX") evaluates to { "O": 1, "X": 4 }
    • count([# 58 58 58 4f 58 #]) evaluates to { 79: 1, 88: 4 }
    • count([true, true, false, true]) evaluates to { false: 1, true: 3 }
    • invert({ "x": 1, "y" : 2, "z": 1 }) evaluates to { 1: [ "z", "x" ], 2: ["y"] }

The following session in the REPL should be possible:

hi> count("Hello World").o
2

hi> invert(count("big blue bag"))
{ 1: [ "u", "l", "i", "e", "a" ], 2: [ "g", " " ], 3: ["b"] }

hi> fold(add, values(count("Hello, World!")))
13

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Interpreter for Hi programming language

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