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Merge branch 'master' into merge

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This commit is contained in:
Arseny Kapoulkine 2022-09-29 15:12:30 -07:00
commit 123649d7b7
84 changed files with 54 additions and 5165 deletions
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68
.github/workflows/prototyping.yml vendored
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name: prototyping
on:
pull_request:
paths:
- '.github/workflows/prototyping.yml'
- 'prototyping/**'
jobs:
linux:
strategy:
matrix:
agda: [2.6.2.2]
hackageDate: ["2022-04-07"]
hackageTime: ["23:06:28"]
name: prototyping
runs-on: ubuntu-latest
steps:
- uses: actions/checkout@v1
- uses: actions/cache@v2
with:
path: ~/.cabal/store
key: "prototyping-${{ runner.os }}-${{ matrix.agda }}-${{ matrix.hackageDate }}-${{ matrix.hackageTime }}"
- uses: actions/cache@v2
id: luau-ast-cache
with:
path: ./build
key: prototyping-${{ runner.os }}-${{ hashFiles('Ast/**', 'Analysis/**', 'CLI/Ast.cpp', 'CLI/FileUtils.*')}}
- name: install cabal
run: sudo apt-get install -y cabal-install
- name: cabal update
working-directory: prototyping
run: cabal v2-update "hackage.haskell.org,${{ matrix.hackageDate }}T${{ matrix.hackageTime }}Z"
- name: cabal install
working-directory: prototyping
run: |
cabal install --lib scientific vector aeson --package-env .
cabal install --allow-newer Agda-${{ matrix.agda }}
- name: check targets
working-directory: prototyping
run: |
~/.cabal/bin/agda Everything.agda
- name: build executables
working-directory: prototyping
run: |
~/.cabal/bin/agda --compile PrettyPrinter.agda
~/.cabal/bin/agda --compile Interpreter.agda
- name: cmake configure
if: steps.luau-ast-cache.outputs.cache-hit != 'true'
run: |
mkdir -p build
cd build
cmake build ../
- name: cmake build luau-ast
if: steps.luau-ast-cache.outputs.cache-hit != 'true'
run: |
cmake --build ./build --target Luau.Ast.CLI
- name: run tests
working-directory: prototyping
run: |
mkdir test-failures
python tests.py -l ../build/luau-ast --write-diff-failures --diff-failure-location test-failures/
- uses: actions/upload-artifact@v2
if: failure()
with:
name: test failures
path: prototyping/test-failures
retention-days: 5

2
docs/_pages/library.md
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@ -507,7 +507,7 @@ Returns a formatted version of the input arguments using a [printf-style format
- `q`: expects a string and produces the same string quoted using double quotation marks, with escaped special characters if necessary - `q`: expects a string and produces the same string quoted using double quotation marks, with escaped special characters if necessary
- `s`: expects a string and produces the same string verbatim - `s`: expects a string and produces the same string verbatim
The formats support modifiers `-`, `+`, ` `, `#` and `0`, as well as field width and precision modifiers - with the exception of `*`. The formats support modifiers `-`, `+`, space, `#` and `0`, as well as field width and precision modifiers - with the exception of `*`.
``` ```
function string.gmatch(s: string, p: string): <iterator> function string.gmatch(s: string, p: string): <iterator>

55
docs/_pages/typecheck.md
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@ -46,11 +46,11 @@ local a2: A = b1 -- ok
local b2: B = a1 -- not ok local b2: B = a1 -- not ok
``` ```
## Primitive types ## Builtin types
Lua VM supports 8 primitive types: `nil`, `string`, `number`, `boolean`, `table`, `function`, `thread`, and `userdata`. Of these, `table` and `function` are not represented by name, but have their dedicated syntax as covered in this [syntax document](syntax), and `userdata` is represented by [concrete types](#roblox-types); other types can be specified by their name. Lua VM supports 8 primitive types: `nil`, `string`, `number`, `boolean`, `table`, `function`, `thread`, and `userdata`. Of these, `table` and `function` are not represented by name, but have their dedicated syntax as covered in this [syntax document](syntax), and `userdata` is represented by [concrete types](#roblox-types); other types can be specified by their name.
Additionally, we also have `any` which is a special built-in type. It effectively disables all type checking, and thus should be used as last resort. The type checker also provides the builtin types [`unknown`](#unknown-type), [`never`](#never-type), and [`any`](#any-type).
```lua ```lua
local s = "foo" local s = "foo"
@ -69,6 +69,57 @@ local a
local b = nil local b = nil
``` ```
### `unknown` type
`unknown` is also said to be the _top_ type, that is it's a union of all types.
```lua
local a: unknown = "hello world!"
local b: unknown = 5
local c: unknown = function() return 5 end
```
Unlike `any`, `unknown` will not allow itself to be used as a different type!
```lua
local function unknown(): unknown
return if math.random() > 0.5 then "hello world!" else 5
end
local a: string = unknown() -- not ok
local b: number = unknown() -- not ok
local c: string | number = unknown() -- not ok
```
In order to turn a variable of type `unknown` into a different type, you must apply [type refinements](#type-refinements) on that variable.
```lua
local x = unknown()
if typeof(x) == "number" then
-- x : number
end
```
### `never` type
`never` is also said to be the _bottom_ type, meaning there doesn't exist a value that inhabits the type `never`. In fact, it is the _dual_ of `unknown`. `never` is useful in many scenarios, and one such use case is when type refinements proves it impossible:
```lua
local x = unknown()
if typeof(x) == "number" and typeof(x) == "string" then
-- x : never
end
```
### `any` type
`any` is just like `unknown`, except that it allows itself to be used as an arbitrary type without further checks or annotations. Essentially, it's an opt-out from the type system entirely.
```lua
local x: any = 5
local y: string = x -- no type errors here!
```
## Function types ## Function types
Let's start with something simple. Let's start with something simple.

10
prototyping/.gitignore vendored
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@ -1,10 +0,0 @@
*~
*.agdai
Main
MAlonzo
PrettyPrinter
Interpreter
!Tests/Interpreter
!Tests/PrettyPrinter
.ghc.*
test-failures/

8
prototyping/Everything.agda
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@ -1,8 +0,0 @@
{-# OPTIONS --rewriting #-}
module Everything where
import Examples
import Properties
import PrettyPrinter
import Interpreter

7
prototyping/Examples.agda
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{-# OPTIONS --rewriting #-}
module Examples where
import Examples.Syntax
import Examples.OpSem
import Examples.Run
import Examples.Type

10
prototyping/Examples/OpSem.agda
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@ -1,10 +0,0 @@
{-# OPTIONS --rewriting #-}
module Examples.OpSem where
open import Luau.OpSem using (_⊢_⟶ᴱ_⊣_; _⊢_⟶ᴮ_⊣_; subst)
open import Luau.Syntax using (Block; var; val; nil; local_←_; _∙_; done; return; block_is_end)
open import Luau.Heap using ()
ex1 : (local (var "x") val nil return (var "x") done) ⟶ᴮ (return (val nil) done)
ex1 = subst nil

23
prototyping/Examples/Run.agda
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@ -1,23 +0,0 @@
{-# OPTIONS --rewriting #-}
module Examples.Run where
open import Agda.Builtin.Equality using (_≡_; refl)
open import Agda.Builtin.Bool using (true; false)
open import Luau.Syntax using (nil; var; _$_; function_is_end; return; _∙_; done; _⟨_⟩; number; binexp; +; <; val; bool; ~=; string)
open import Luau.Run using (run; return)
ex1 : (run (function "id" var "x" is return (var "x") done end return (var "id" $ val nil) done) return nil _)
ex1 = refl
ex2 : (run (function "fn" var "x" is return (val (number 123.0)) done end return (var "fn" $ val nil) done) return (number 123.0) _)
ex2 = refl
ex3 : (run (function "fn" var "x" is return (binexp (val (number 1.0)) + (val (number 2.0))) done end return (var "fn" $ val nil) done) return (number 3.0) _)
ex3 = refl
ex4 : (run (function "fn" var "x" is return (binexp (val (number 1.0)) < (val (number 2.0))) done end return (var "fn" $ val nil) done) return (bool true) _)
ex4 = refl
ex5 : (run (function "fn" var "x" is return (binexp (val (string "foo")) ~= (val (string "bar"))) done end return (var "fn" $ val nil) done) return (bool true) _)
ex5 = refl

24
prototyping/Examples/Syntax.agda
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@ -1,24 +0,0 @@
module Examples.Syntax where
open import Agda.Builtin.Equality using (_≡_; refl)
open import FFI.Data.String using (_++_)
open import Luau.Syntax using (var; _$_; return; val; nil; function_is_end; local_←_; done; _∙_; _⟨_⟩)
open import Luau.Syntax.ToString using (exprToString; blockToString)
ex1 : exprToString(function "" var "x" is return (var "f" $ var "x") done end)
"function(x)\n" ++
" return f(x)\n" ++
"end"
ex1 = refl
ex2 : blockToString(local var "x" (val nil) return (var "x") done)
"local x = nil\n" ++
"return x"
ex2 = refl
ex3 : blockToString(function "f" var "x" is return (var "x") done end return (var "f") done)
"local function f(x)\n" ++
" return x\n" ++
"end\n" ++
"return f"
ex3 = refl

28
prototyping/Examples/Type.agda
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@ -1,28 +0,0 @@
module Examples.Type where
open import Agda.Builtin.Equality using (_≡_; refl)
open import FFI.Data.String using (_++_)
open import Luau.Type using (nil; __; _∩_; _⇒_)
open import Luau.Type.ToString using (typeToString)
ex1 : typeToString(nil) "nil"
ex1 = refl
ex2 : typeToString(nil nil) "(nil) -> nil"
ex2 = refl
ex3 : typeToString(nil (nil nil)) "(nil) -> (nil) -> nil"
ex3 = refl
ex4 : typeToString(nil (nil (nil nil))) "((nil) -> (nil) -> nil)?"
ex4 = refl
ex5 : typeToString(nil ((nil nil) nil)) "(nil) -> ((nil) -> nil)?"
ex5 = refl
ex6 : typeToString((nil nil) (nil (nil nil))) "((nil) -> nil | (nil) -> (nil) -> nil)"
ex6 = refl
ex7 : typeToString((nil nil) ((nil (nil nil)) nil)) "((nil) -> nil | (nil) -> (nil) -> nil)?"
ex7 = refl

77
prototyping/FFI/Data/Aeson.agda
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@ -1,77 +0,0 @@
{-# OPTIONS --rewriting #-}
module FFI.Data.Aeson where
open import Agda.Builtin.Equality using (_≡_)
open import Agda.Builtin.Equality.Rewrite using ()
open import Agda.Builtin.Bool using (Bool)
open import Agda.Builtin.String using (String)
open import FFI.Data.ByteString using (ByteString)
open import FFI.Data.HaskellString using (HaskellString; pack)
open import FFI.Data.Maybe using (Maybe; just; nothing)
open import FFI.Data.Either using (Either; mapL)
open import FFI.Data.Scientific using (Scientific)
open import FFI.Data.Vector using (Vector)
open import Properties.Equality using (_≢_)
{-# FOREIGN GHC import qualified Data.Aeson #-}
{-# FOREIGN GHC import qualified Data.Aeson.Key #-}
{-# FOREIGN GHC import qualified Data.Aeson.KeyMap #-}
postulate
KeyMap : Set Set
Key : Set
fromString : String Key
toString : Key String
empty : {A} KeyMap A
singleton : {A} Key A (KeyMap A)
insert : {A} Key A (KeyMap A) (KeyMap A)
delete : {A} Key (KeyMap A) (KeyMap A)
unionWith : {A} (A A A) (KeyMap A) (KeyMap A) (KeyMap A)
lookup : {A} Key -> KeyMap A -> Maybe A
{-# POLARITY KeyMap ++ #-}
{-# COMPILE GHC KeyMap = type Data.Aeson.KeyMap.KeyMap #-}
{-# COMPILE GHC Key = type Data.Aeson.Key.Key #-}
{-# COMPILE GHC fromString = Data.Aeson.Key.fromText #-}
{-# COMPILE GHC toString = Data.Aeson.Key.toText #-}
{-# COMPILE GHC empty = \_ -> Data.Aeson.KeyMap.empty #-}
{-# COMPILE GHC singleton = \_ -> Data.Aeson.KeyMap.singleton #-}
{-# COMPILE GHC insert = \_ -> Data.Aeson.KeyMap.insert #-}
{-# COMPILE GHC delete = \_ -> Data.Aeson.KeyMap.delete #-}
{-# COMPILE GHC unionWith = \_ -> Data.Aeson.KeyMap.unionWith #-}
{-# COMPILE GHC lookup = \_ -> Data.Aeson.KeyMap.lookup #-}
postulate lookup-insert : {A} k v (m : KeyMap A) (lookup k (insert k v m) just v)
postulate lookup-empty : {A} k (lookup {A} k empty nothing)
postulate lookup-insert-not : {A} j k v (m : KeyMap A) (j k) (lookup k m lookup k (insert j v m))
postulate singleton-insert-empty : {A} k (v : A) (singleton k v insert k v empty)
postulate insert-swap : {A} j k (v w : A) m (j k) insert j v (insert k w m) insert k w (insert j v m)
postulate insert-over : {A} j k (v w : A) m (j k) insert j v (insert k w m) insert j v m
postulate to-from : k toString(fromString k) k
postulate from-to : k fromString(toString k) k
{-# REWRITE lookup-insert lookup-empty singleton-insert-empty #-}
data Value : Set where
object : KeyMap Value Value
array : Vector Value Value
string : String Value
number : Scientific Value
bool : Bool Value
null : Value
{-# COMPILE GHC Value = data Data.Aeson.Value (Data.Aeson.Object|Data.Aeson.Array|Data.Aeson.String|Data.Aeson.Number|Data.Aeson.Bool|Data.Aeson.Null) #-}
Object = KeyMap Value
Array = Vector Value
postulate
decode : ByteString Maybe Value
eitherHDecode : ByteString Either HaskellString Value
{-# COMPILE GHC decode = Data.Aeson.decodeStrict #-}
{-# COMPILE GHC eitherHDecode = Data.Aeson.eitherDecodeStrict #-}
eitherDecode : ByteString Either String Value
eitherDecode bytes = mapL pack (eitherHDecode bytes)

7
prototyping/FFI/Data/ByteString.agda
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@ -1,7 +0,0 @@
module FFI.Data.ByteString where
{-# FOREIGN GHC import qualified Data.ByteString #-}
postulate ByteString : Set
{-# COMPILE GHC ByteString = type Data.ByteString.ByteString #-}

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prototyping/FFI/Data/Either.agda
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module FFI.Data.Either where
{-# FOREIGN GHC import qualified Data.Either #-}
data Either (A B : Set) : Set where
Left : A Either A B
Right : B Either A B
{-# COMPILE GHC Either = data Data.Either.Either (Data.Either.Left|Data.Either.Right) #-}
swapLR : {A B} Either A B Either B A
swapLR (Left x) = Right x
swapLR (Right x) = Left x
mapL : {A B C} (A B) Either A C Either B C
mapL f (Left x) = Left (f x)
mapL f (Right x) = Right x
mapR : {A B C} (B C) Either A B Either A C
mapR f (Left x) = Left x
mapR f (Right x) = Right (f x)
mapLR : {A B C D} (A B) (C D) Either A C Either B D
mapLR f g (Left x) = Left (f x)
mapLR f g (Right x) = Right (g x)
cond : {A B C : Set} (A C) (B C) (Either A B) C
cond f g (Left x) = f x
cond f g (Right x) = g x

14
prototyping/FFI/Data/HaskellInt.agda
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@ -1,14 +0,0 @@
module FFI.Data.HaskellInt where
open import Agda.Builtin.Int using (Int)
{-# FOREIGN GHC import qualified Data.Int #-}
postulate HaskellInt : Set
{-# COMPILE GHC HaskellInt = type Data.Int.Int #-}
postulate
intToHaskellInt : Int HaskellInt
haskellIntToInt : HaskellInt Int
{-# COMPILE GHC intToHaskellInt = fromIntegral #-}
{-# COMPILE GHC haskellIntToInt = fromIntegral #-}

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prototyping/FFI/Data/HaskellString.agda
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@ -1,16 +0,0 @@
module FFI.Data.HaskellString where
open import Agda.Builtin.String using (String)
{-# FOREIGN GHC import qualified Data.String #-}
{-# FOREIGN GHC import qualified Data.Text #-}
postulate HaskellString : Set
{-# COMPILE GHC HaskellString = type Data.String.String #-}
postulate pack : HaskellString String
{-# COMPILE GHC pack = Data.Text.pack #-}
postulate unpack : String HaskellString
{-# COMPILE GHC unpack = Data.Text.unpack #-}

14
prototyping/FFI/Data/Maybe.agda
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@ -1,14 +0,0 @@
module FFI.Data.Maybe where
open import Agda.Builtin.Equality using (_≡_; refl)
{-# FOREIGN GHC import qualified Data.Maybe #-}
data Maybe (A : Set) : Set where
nothing : Maybe A
just : A Maybe A
{-# COMPILE GHC Maybe = data Data.Maybe.Maybe (Data.Maybe.Nothing|Data.Maybe.Just) #-}
just-inv : {A} {x y : A} (just x just y) (x y)
just-inv refl = refl

21
prototyping/FFI/Data/Scientific.agda
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@ -1,21 +0,0 @@
module FFI.Data.Scientific where
open import Agda.Builtin.Float using (Float)
open import FFI.Data.String using (String)
open import FFI.Data.HaskellString using (HaskellString; pack; unpack)
{-# FOREIGN GHC import qualified Data.Scientific #-}
{-# FOREIGN GHC import qualified Text.Show #-}
postulate Scientific : Set
{-# COMPILE GHC Scientific = type Data.Scientific.Scientific #-}
postulate
showHaskell : Scientific HaskellString
toFloat : Scientific Float
{-# COMPILE GHC showHaskell = \x -> Text.Show.show x #-}
{-# COMPILE GHC toFloat = \x -> Data.Scientific.toRealFloat x #-}
show : Scientific String
show x = pack (showHaskell x)

8
prototyping/FFI/Data/String.agda
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@ -1,8 +0,0 @@
module FFI.Data.String where
import Agda.Builtin.String
String = Agda.Builtin.String.String
infixr 5 _++_
_++_ = Agda.Builtin.String.primStringAppend

10
prototyping/FFI/Data/Text/Encoding.agda
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@ -1,10 +0,0 @@
module FFI.Data.Text.Encoding where
open import Agda.Builtin.String using (String)
open import FFI.Data.ByteString using (ByteString)
{-# FOREIGN GHC import qualified Data.Text.Encoding #-}
postulate encodeUtf8 : String ByteString
{-# COMPILE GHC encodeUtf8 = Data.Text.Encoding.encodeUtf8 #-}

53
prototyping/FFI/Data/Vector.agda
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@ -1,53 +0,0 @@
{-# OPTIONS --rewriting #-}
module FFI.Data.Vector where
open import Agda.Builtin.Equality using (_≡_)
open import Agda.Builtin.Equality.Rewrite using ()
open import Agda.Builtin.Int using (Int; pos; negsuc)
open import Agda.Builtin.Nat using (Nat)
open import Agda.Builtin.Bool using (Bool; false; true)
open import FFI.Data.HaskellInt using (HaskellInt; haskellIntToInt; intToHaskellInt)
open import FFI.Data.Maybe using (Maybe; just; nothing)
open import Properties.Equality using (_≢_)
{-# FOREIGN GHC import qualified Data.Vector #-}
postulate Vector : Set Set
{-# POLARITY Vector ++ #-}
{-# COMPILE GHC Vector = type Data.Vector.Vector #-}
postulate
empty : {A} (Vector A)
null : {A} (Vector A) Bool
unsafeHead : {A} (Vector A) A
unsafeTail : {A} (Vector A) (Vector A)
length : {A} (Vector A) Nat
lookup : {A} (Vector A) Nat (Maybe A)
snoc : {A} (Vector A) A (Vector A)
{-# COMPILE GHC empty = \_ -> Data.Vector.empty #-}
{-# COMPILE GHC null = \_ -> Data.Vector.null #-}
{-# COMPILE GHC unsafeHead = \_ -> Data.Vector.unsafeHead #-}
{-# COMPILE GHC unsafeTail = \_ -> Data.Vector.unsafeTail #-}
{-# COMPILE GHC length = \_ -> (fromIntegral . Data.Vector.length) #-}
{-# COMPILE GHC lookup = \_ v -> ((v Data.Vector.!?) . fromIntegral) #-}
{-# COMPILE GHC snoc = \_ -> Data.Vector.snoc #-}
postulate length-empty : {A} (length (empty {A}) 0)
postulate lookup-empty : {A} n (lookup (empty {A}) n nothing)
postulate lookup-snoc : {A} (x : A) (v : Vector A) (lookup (snoc v x) (length v) just x)
postulate lookup-length : {A} (v : Vector A) (lookup v (length v) nothing)
postulate lookup-snoc-empty : {A} (x : A) (lookup (snoc empty x) 0 just x)
postulate lookup-snoc-not : {A n} (x : A) (v : Vector A) (n length v) (lookup v n lookup (snoc v x) n)
{-# REWRITE length-empty lookup-snoc lookup-length lookup-snoc-empty lookup-empty #-}
head : {A} (Vector A) (Maybe A)
head vec with null vec
head vec | false = just (unsafeHead vec)
head vec | true = nothing
tail : {A} (Vector A) Vector A
tail vec with null vec
tail vec | false = unsafeTail vec
tail vec | true = empty

34
prototyping/FFI/IO.agda
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@ -1,34 +0,0 @@
module FFI.IO where
open import Agda.Builtin.IO using (IO)
open import Agda.Builtin.Unit using ()
open import Agda.Builtin.String using (String)
open import FFI.Data.HaskellString using (HaskellString; pack ; unpack)
infixl 1 _>>=_
infixl 1 _>>_
postulate
return : {a} {A : Set a} A IO A
_>>=_ : {a b} {A : Set a} {B : Set b} IO A (A IO B) IO B
fmap : {a b} {A : Set a} {B : Set b} (A B) IO A IO B
{-# COMPILE GHC return = \_ _ -> return #-}
{-# COMPILE GHC _>>=_ = \_ _ _ _ -> (>>=) #-}
{-# COMPILE GHC fmap = \_ _ _ _ -> fmap #-}
postulate getHContents : IO HaskellString
{-# COMPILE GHC getHContents = getContents #-}
postulate putHStrLn : HaskellString IO
{-# COMPILE GHC putHStrLn = putStrLn #-}
getContents : IO String
getContents = fmap pack getHContents
putStrLn : String IO
putStrLn txt = putHStrLn (unpack txt)
_>>_ : {a} {A : Set a} IO IO A IO A
a >> b = a >>= (λ _ b )

29
prototyping/FFI/System/Exit.agda
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@ -1,29 +0,0 @@
module FFI.System.Exit where
open import Agda.Builtin.Int using (Int)
open import Agda.Builtin.IO using (IO)
open import Agda.Builtin.Unit using ()
data ExitCode : Set where
ExitSuccess : ExitCode
ExitFailure : Int ExitCode
{-# FOREIGN GHC data AgdaExitCode = AgdaExitSuccess | AgdaExitFailure Integer #-}
{-# COMPILE GHC ExitCode = data AgdaExitCode (AgdaExitSuccess | AgdaExitFailure) #-}
{-# FOREIGN GHC import qualified System.Exit #-}
{-# FOREIGN GHC
toExitCode :: AgdaExitCode -> System.Exit.ExitCode
toExitCode AgdaExitSuccess = System.Exit.ExitSuccess
toExitCode (AgdaExitFailure n) = System.Exit.ExitFailure (fromIntegral n)
fromExitCode :: System.Exit.ExitCode -> AgdaExitCode
fromExitCode System.Exit.ExitSuccess = AgdaExitSuccess
fromExitCode (System.Exit.ExitFailure n) = AgdaExitFailure (fromIntegral n)
#-}
postulate
exitWith : ExitCode IO
{-# COMPILE GHC exitWith = System.Exit.exitWith . toExitCode #-}

50
prototyping/Interpreter.agda
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{-# OPTIONS --rewriting #-}
module Interpreter where
open import Agda.Builtin.IO using (IO)
open import Agda.Builtin.Int using (pos)
open import Agda.Builtin.Unit using ()
open import FFI.IO using (getContents; putStrLn; _>>=_; _>>_)
open import FFI.Data.Aeson using (Value; eitherDecode)
open import FFI.Data.Either using (Left; Right)
open import FFI.Data.Maybe using (just; nothing)
open import FFI.Data.String using (String; _++_)
open import FFI.Data.Text.Encoding using (encodeUtf8)
open import FFI.System.Exit using (exitWith; ExitFailure)
open import Luau.StrictMode.ToString using (warningToStringᴮ)
open import Luau.Syntax using (Block; yes; maybe; isAnnotatedᴮ)
open import Luau.Syntax.FromJSON using (blockFromJSON)
open import Luau.Syntax.ToString using (blockToString; valueToString)
open import Luau.Run using (run; return; done; error)
open import Luau.RuntimeError.ToString using (errToStringᴮ)
open import Properties.StrictMode using (wellTypedProgramsDontGoWrong)
runBlock : a Block a IO
runBlock a block with run block
runBlock a block | return V D = putStrLn ("\nRAN WITH RESULT: " ++ valueToString V)
runBlock a block | done D = putStrLn ("\nRAN")
runBlock maybe block | error E D = putStrLn ("\nRUNTIME ERROR:\n" ++ errToStringᴮ _ E)
runBlock yes block | error E D with wellTypedProgramsDontGoWrong _ block _ D E
runBlock yes block | error E D | W = putStrLn ("\nRUNTIME ERROR:\n" ++ errToStringᴮ _ E ++ "\n\nTYPE ERROR:\n" ++ warningToStringᴮ _ W)
runBlock : Block maybe IO
runBlock B with isAnnotatedᴮ B
runBlock B | nothing = putStrLn ("UNANNOTATED PROGRAM:\n" ++ blockToString B) >> runBlock maybe B
runBlock B | just B = putStrLn ("ANNOTATED PROGRAM:\n" ++ blockToString B) >> runBlock yes B
runJSON : Value IO
runJSON value with blockFromJSON(value)
runJSON value | (Left err) = putStrLn ("LUAU ERROR: " ++ err) >> exitWith (ExitFailure (pos 1))
runJSON value | (Right block) = runBlock block
runString : String IO
runString txt with eitherDecode (encodeUtf8 txt)
runString txt | (Left err) = putStrLn ("JSON ERROR: " ++ err) >> exitWith (ExitFailure (pos 1))
runString txt | (Right value) = runJSON value
main : IO
main = getContents >>= runString

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module Luau.Addr where
open import Agda.Builtin.Bool using (true; false)
open import Agda.Builtin.Equality using (_≡_)
open import Agda.Builtin.Nat using (Nat; _==_)
open import Agda.Builtin.String using (String)
open import Agda.Builtin.TrustMe using (primTrustMe)
open import Properties.Dec using (Dec; yes; no)
open import Properties.Equality using (_≢_)
Addr : Set
Addr = Nat
_≡ᴬ_ : (a b : Addr) Dec (a b)
a ≡ᴬ b with a == b
a ≡ᴬ b | false = no p where postulate p : (a b)
a ≡ᴬ b | true = yes primTrustMe

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module Luau.Addr.ToString where
open import Agda.Builtin.String using (String; primStringAppend)
open import Luau.Addr using (Addr)
open import Agda.Builtin.Int using (Int; primShowInteger; pos)
addrToString : Addr String
addrToString a = primStringAppend "a" (primShowInteger (pos a))

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{-# OPTIONS --rewriting #-}
module Luau.Heap where
open import Agda.Builtin.Equality using (_≡_; refl)
open import FFI.Data.Maybe using (Maybe; just; nothing)
open import FFI.Data.Vector using (Vector; length; snoc; empty; lookup-snoc-not)
open import Luau.Addr using (Addr; _≡ᴬ_)
open import Luau.Var using (Var)
open import Luau.Syntax using (Block; Expr; Annotated; FunDec; nil; function_is_end)
open import Properties.Equality using (_≢_; trans)
open import Properties.Remember using (remember; _,_)
open import Properties.Dec using (yes; no)
-- Heap-allocated objects
data Object (a : Annotated) : Set where
function_is_end : FunDec a Block a Object a
Heap : Annotated Set
Heap a = Vector (Object a)
data _≡_⊕_↦_ {a} : Heap a Heap a Addr Object a Set where
defn : {H val}
-----------------------------------
(snoc H val) H (length H) val
_[_] : {a} Heap a Addr Maybe (Object a)
_[_] = FFI.Data.Vector.lookup
: {a} Heap a
= empty
data AllocResult a (H : Heap a) (V : Object a) : Set where
ok : b H (H H b V) AllocResult a H V
alloc : {a} H V AllocResult a H V
alloc H V = ok (length H) (snoc H V) defn
next : {a} Heap a Addr
next = length
allocated : {a} Heap a Object a Heap a
allocated = snoc
lookup-not-allocated : {a} {H H : Heap a} {b c O} (H H b O) (c b) (H [ c ] H [ c ])
lookup-not-allocated {H = H} {O = O} defn p = lookup-snoc-not O H p

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{-# OPTIONS --rewriting #-}
module Luau.OpSem where
open import Agda.Builtin.Equality using (_≡_)
open import Agda.Builtin.Float using (Float; primFloatPlus; primFloatMinus; primFloatTimes; primFloatDiv; primFloatEquality; primFloatLess; primFloatInequality)
open import Agda.Builtin.Bool using (Bool; true; false)
open import Agda.Builtin.String using (primStringEquality; primStringAppend)
open import Utility.Bool using (not; _or_; _and_)
open import Agda.Builtin.Nat using () renaming (_==_ to _==ᴬ_)
open import FFI.Data.Maybe using (Maybe; just; nothing)
open import Luau.Heap using (Heap; _≡_⊕_↦_; _[_]; function_is_end)
open import Luau.Substitution using (_[_/_]ᴮ)
open import Luau.Syntax using (Value; Expr; Stat; Block; nil; addr; val; var; function_is_end; _$_; block_is_end; local_←_; _∙_; done; return; name; fun; arg; binexp; BinaryOperator; +; -; *; /; <; >; ==; ~=; <=; >=; ··; number; bool; string)
open import Luau.RuntimeType using (RuntimeType; valueType)
open import Properties.Product using (_×_; _,_)
evalEqOp : Value Value Bool
evalEqOp Value.nil Value.nil = true
evalEqOp (addr x) (addr y) = (x == y)
evalEqOp (number x) (number y) = primFloatEquality x y
evalEqOp (bool true) (bool y) = y
evalEqOp (bool false) (bool y) = not y
evalEqOp _ _ = false
evalNeqOp : Value Value Bool
evalNeqOp (number x) (number y) = primFloatInequality x y
evalNeqOp x y = not (evalEqOp x y)
data _⟦_⟧_⟶_ : Value BinaryOperator Value Value Set where
+ : m n (number m) + (number n) number (primFloatPlus m n)
- : m n (number m) - (number n) number (primFloatMinus m n)
/ : m n (number m) / (number n) number (primFloatTimes m n)
* : m n (number m) * (number n) number (primFloatDiv m n)
< : m n (number m) < (number n) bool (primFloatLess m n)
> : m n (number m) > (number n) bool (primFloatLess n m)
<= : m n (number m) <= (number n) bool ((primFloatLess m n) or (primFloatEquality m n))
>= : m n (number m) >= (number n) bool ((primFloatLess n m) or (primFloatEquality m n))
== : v w v == w bool (evalEqOp v w)
~= : v w v ~= w bool (evalNeqOp v w)
·· : x y (string x) ·· (string y) string (primStringAppend x y)
data _⊢_⟶ᴮ_⊣_ {a} : Heap a Block a Block a Heap a Set
data _⊢_⟶ᴱ_⊣_ {a} : Heap a Expr a Expr a Heap a Set
data _⊢_⟶ᴱ_⊣_ where
function : a {H H F B}
H H a (function F is B end)
-------------------------------------------
H (function F is B end) ⟶ᴱ val(addr a) H
app₁ : {H H M M N}
H M ⟶ᴱ M H
-----------------------------
H (M $ N) ⟶ᴱ (M $ N) H
app₂ : v {H H N N}
H N ⟶ᴱ N H
-----------------------------
H (val v $ N) ⟶ᴱ (val v $ N) H
beta : O v {H a F B}
(O function F is B end)
H [ a ] just(O)
-----------------------------------------------------------------------------
H (val (addr a) $ val v) ⟶ᴱ (block (fun F) is (B [ v / name(arg F) ]ᴮ) end) H
block : {H H B B b}
H B ⟶ᴮ B H
----------------------------------------------------
H (block b is B end) ⟶ᴱ (block b is B end) H
return : v {H B b}
--------------------------------------------------------
H (block b is return (val v) B end) ⟶ᴱ val v H
done : {H b}
--------------------------------------------
H (block b is done end) ⟶ᴱ (val nil) H
binOp₀ : {H op v₁ v₂ w}
v₁ op v₂ w
--------------------------------------------------
H (binexp (val v₁) op (val v₂)) ⟶ᴱ (val w) H
binOp₁ : {H H x x op y}
H x ⟶ᴱ x H
---------------------------------------------
H (binexp x op y) ⟶ᴱ (binexp x op y) H
binOp₂ : {H H x op y y}
H y ⟶ᴱ y H
---------------------------------------------
H (binexp x op y) ⟶ᴱ (binexp x op y) H
data _⊢_⟶ᴮ_⊣_ where
local : {H H x M M B}
H M ⟶ᴱ M H
-------------------------------------------------
H (local x M B) ⟶ᴮ (local x M B) H
subst : v {H x B}
------------------------------------------------------
H (local x val v B) ⟶ᴮ (B [ v / name x ]ᴮ) H
function : a {H H F B C}
H H a (function F is C end)
--------------------------------------------------------------
H (function F is C end B) ⟶ᴮ (B [ addr a / name(fun F) ]ᴮ) H
return : {H H M M B}
H M ⟶ᴱ M H
--------------------------------------------
H (return M B) ⟶ᴮ (return M B) H
data _⊢_⟶*_⊣_ {a} : Heap a Block a Block a Heap a Set where
refl : {H B}
----------------
H B ⟶* B H
step : {H H H″ B B B″}
H B ⟶ᴮ B H
H B ⟶* B″ H″
------------------
H B ⟶* B″ H″

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{-# OPTIONS --rewriting #-}
module Luau.ResolveOverloads where
open import FFI.Data.Either using (Left; Right)
open import Luau.Subtyping using (_<:_; _≮:_; Language; witness; scalar; unknown; never; function-ok)
open import Luau.Type using (Type ; _⇒_; _∩_; __; unknown; never)
open import Luau.TypeSaturation using (saturate)
open import Luau.TypeNormalization using (normalize)
open import Properties.Contradiction using (CONTRADICTION)
open import Properties.DecSubtyping using (dec-subtyping; dec-subtypingⁿ; <:-impl-<:ᵒ)
open import Properties.Functions using (_∘_)
open import Properties.Subtyping using (<:-refl; <:-trans; <:-trans-≮:; ≮:-trans-<:; <:-∩-left; <:-∩-right; <:-∩-glb; <:-impl-¬≮:; <:-unknown; <:-function; function-≮:-never; <:-never; unknown-≮:-function; scalar-≮:-function; ≮:--right; scalar-≮:-never; <:--left; <:--right)
open import Properties.TypeNormalization using (Normal; FunType; normal; _⇒_; _∩_; __; never; unknown; <:-normalize; normalize-<:; fun-≮:-never; unknown-≮:-fun; scalar-≮:-fun)
open import Properties.TypeSaturation using (Overloads; Saturated; _⊆ᵒ_; _<:ᵒ_; normal-saturate; saturated; <:-saturate; saturate-<:; defn; here; left; right)
-- The domain of a normalized type
srcⁿ : Type Type
srcⁿ (S T) = S
srcⁿ (S T) = srcⁿ S srcⁿ T
srcⁿ never = unknown
srcⁿ T = never
-- To get the domain of a type, we normalize it first We need to do
-- this, since if we try to use it on non-normalized types, we get
--
-- src(number ∩ string) = src(number) src(string) = never never
-- src(never) = unknown
--
-- so src doesn't respect type equivalence.
src : Type Type
src (S T) = S
src T = srcⁿ(normalize T)
-- Calculate the result of applying a function type `F` to an argument type `V`.
-- We do this by finding an overload of `F` that has the most precise type,
-- that is an overload `(Sʳ ⇒ Tʳ)` where `V <: Sʳ` and moreover
-- for any other such overload `(S ⇒ T)` we have that `Tʳ <: T`.
-- For example if `F` is `(number -> number) & (nil -> nil) & (number? -> number?)`
-- then to resolve `F` with argument type `number`, we pick the `number -> number`
-- overload, but if the argument is `number?`, we pick `number? -> number?`./
-- Not all types have such a most precise overload, but saturated ones do.
data ResolvedTo F G V : Set where
yes :
Overloads F ( )
(V <: )
( {S T} Overloads G (S T) (V <: S) ( <: T))
--------------------------------------------
ResolvedTo F G V
no :
( {S T} Overloads G (S T) (V ≮: S))
--------------------------------------------
ResolvedTo F G V
Resolved : Type Type Set
Resolved F V = ResolvedTo F F V
target : {F V} Resolved F V Type
target (yes _ T _ _ _) = T
target (no _) = unknown
-- We can resolve any saturated function type
resolveˢ : {F G V} FunType G Saturated F Normal V (G ⊆ᵒ F) ResolvedTo F G V
resolveˢ (Sⁿ Tⁿ) (defn sat-∩ sat-) Vⁿ G⊆F with dec-subtypingⁿ Vⁿ Sⁿ
resolveˢ (Sⁿ Tⁿ) (defn sat-∩ sat-) Vⁿ G⊆F | Left V≮:S = no (λ { here V≮:S })
resolveˢ (Sⁿ Tⁿ) (defn sat-∩ sat-) Vⁿ G⊆F | Right V<:S = yes _ _ (G⊆F here) V<:S (λ { here _ <:-refl })
resolveˢ (Gᶠ Hᶠ) (defn sat-∩ sat-) Vⁿ G⊆F with resolveˢ Gᶠ (defn sat-∩ sat-) Vⁿ (G⊆F left) | resolveˢ Hᶠ (defn sat-∩ sat-) Vⁿ (G⊆F right)
resolveˢ (Gᶠ Hᶠ) (defn sat-∩ sat-) Vⁿ G⊆F | yes S₁ T₁ o₁ V<:S₁ tgt₁ | yes S₂ T₂ o₂ V<:S₂ tgt₂ with sat-∩ o₁ o₂
resolveˢ (Gᶠ Hᶠ) (defn sat-∩ sat-) Vⁿ G⊆F | yes S₁ T₁ o₁ V<:S₁ tgt₁ | yes S₂ T₂ o₂ V<:S₂ tgt₂ | defn o p₁ p₂ =
yes _ _ o (<:-trans (<:-∩-glb V<:S₁ V<:S₂) p₁) (λ { (left o) p <:-trans p₂ (<:-trans <:-∩-left (tgt₁ o p)) ; (right o) p <:-trans p₂ (<:-trans <:-∩-right (tgt₂ o p)) })
resolveˢ (Gᶠ Hᶠ) (defn sat-∩ sat-) Vⁿ G⊆F | yes S₁ T₁ o₁ V<:S₁ tgt₁ | no src₂ =
yes _ _ o₁ V<:S₁ (λ { (left o) p tgt₁ o p ; (right o) p CONTRADICTION (<:-impl-¬≮: p (src₂ o)) })
resolveˢ (Gᶠ Hᶠ) (defn sat-∩ sat-) Vⁿ G⊆F | no src₁ | yes S₂ T₂ o₂ V<:S₂ tgt₂ =
yes _ _ o₂ V<:S₂ (λ { (left o) p CONTRADICTION (<:-impl-¬≮: p (src₁ o)) ; (right o) p tgt₂ o p })
resolveˢ (Gᶠ Hᶠ) (defn sat-∩ sat-) Vⁿ G⊆F | no src₁ | no src₂ =
no (λ { (left o) src₁ o ; (right o) src₂ o })
-- Which means we can resolve any normalized type, by saturating it first
resolveᶠ : {F V} FunType F Normal V Type
resolveᶠ Fᶠ Vⁿ = target (resolveˢ (normal-saturate Fᶠ) (saturated Fᶠ) Vⁿ (λ o o))
resolveⁿ : {F V} Normal F Normal V Type
resolveⁿ (Sⁿ Tⁿ) Vⁿ = resolveᶠ (Sⁿ Tⁿ) Vⁿ
resolveⁿ (Fᶠ Gᶠ) Vⁿ = resolveᶠ (Fᶠ Gᶠ) Vⁿ
resolveⁿ (Sⁿ ) Vⁿ = unknown
resolveⁿ unknown Vⁿ = unknown
resolveⁿ never Vⁿ = never
-- Which means we can resolve any type, by normalizing it first
resolve : Type Type Type
resolve F V = resolveⁿ (normal F) (normal V)

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{-# OPTIONS --rewriting #-}
module Luau.Run where
open import Agda.Builtin.Equality using (_≡_; refl)
open import Luau.Heap using (Heap; )
open import Luau.Syntax using (Block; val; return; _∙_; done)
open import Luau.OpSem using (_⊢_⟶*_⊣_; refl; step)
open import Properties.Step using (stepᴮ; step; return; done; error)
open import Luau.RuntimeError using (RuntimeErrorᴮ)
data RunResult {a} (H : Heap a) (B : Block a) : Set where
return : v {B H} (H B ⟶* (return (val v) B) H) RunResult H B
done : {H} (H B ⟶* done H) RunResult H B
error : {B H} (RuntimeErrorᴮ H B) (H B ⟶* B H) RunResult H B
{-# TERMINATING #-}
run : {a} H B RunResult {a} H B
run H B with stepᴮ H B
run H B | step H B D with run H B
run H B | step H B D | return V D = return V (step D D)
run H B | step H B D | done D = done (step D D)
run H B | step H B D | error E D = error E (step D D)
run H _ | return V refl = return V refl
run H _ | done refl = done refl
run H B | error E = error E refl
run : {a} B RunResult {a} B
run = run

41
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{-# OPTIONS --rewriting #-}
module Luau.RuntimeError where
open import Agda.Builtin.Equality using (_≡_)
open import Luau.Heap using (Heap; _[_])
open import FFI.Data.Maybe using (just; nothing)
open import FFI.Data.String using (String)
open import Luau.Syntax using (BinaryOperator; Block; Expr; nil; var; val; addr; block_is_end; _$_; local_←_; return; done; _∙_; number; string; binexp; +; -; *; /; <; >; <=; >=; ··)
open import Luau.RuntimeType using (RuntimeType; valueType; function; number; string)
open import Properties.Equality using (_≢_)
data BinOpError : BinaryOperator RuntimeType Set where
+ : {t} (t number) BinOpError + t
- : {t} (t number) BinOpError - t
* : {t} (t number) BinOpError * t
/ : {t} (t number) BinOpError / t
< : {t} (t number) BinOpError < t
> : {t} (t number) BinOpError > t
<= : {t} (t number) BinOpError <= t
>= : {t} (t number) BinOpError >= t
·· : {t} (t string) BinOpError ·· t
data RuntimeErrorᴮ {a} (H : Heap a) : Block a Set
data RuntimeErrorᴱ {a} (H : Heap a) : Expr a Set
data RuntimeErrorᴱ H where
FunctionMismatch : v w (valueType v function) RuntimeErrorᴱ H (val v $ val w)
BinOpMismatch₁ : v w {op} (BinOpError op (valueType v)) RuntimeErrorᴱ H (binexp (val v) op (val w))
BinOpMismatch₂ : v w {op} (BinOpError op (valueType w)) RuntimeErrorᴱ H (binexp (val v) op (val w))
UnboundVariable : {x} RuntimeErrorᴱ H (var x)
SEGV : {a} (H [ a ] nothing) RuntimeErrorᴱ H (val (addr a))
app₁ : {M N} RuntimeErrorᴱ H M RuntimeErrorᴱ H (M $ N)
app₂ : {M N} RuntimeErrorᴱ H N RuntimeErrorᴱ H (M $ N)
block : {b B} RuntimeErrorᴮ H B RuntimeErrorᴱ H (block b is B end)
bin₁ : {M N op} RuntimeErrorᴱ H M RuntimeErrorᴱ H (binexp M op N)
bin₂ : {M N op} RuntimeErrorᴱ H N RuntimeErrorᴱ H (binexp M op N)
data RuntimeErrorᴮ H where
local : {x M B} RuntimeErrorᴱ H M RuntimeErrorᴮ H (local x M B)
return : {M B} RuntimeErrorᴱ H M RuntimeErrorᴮ H (return M B)

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{-# OPTIONS --rewriting #-}
module Luau.RuntimeError.ToString where
open import Agda.Builtin.Float using (primShowFloat)
open import FFI.Data.String using (String; _++_)
open import Luau.RuntimeError using (RuntimeErrorᴮ; RuntimeErrorᴱ; local; return; FunctionMismatch; BinOpMismatch₁; BinOpMismatch₂; UnboundVariable; SEGV; app₁; app₂; block; bin₁; bin₂)
open import Luau.RuntimeType.ToString using (runtimeTypeToString)
open import Luau.Addr.ToString using (addrToString)
open import Luau.Syntax.ToString using (valueToString; exprToString)
open import Luau.Var.ToString using (varToString)
open import Luau.Syntax using (var; val; addr; binexp; block_is_end; local_←_; return; _∙_; name; _$_; ··)
errToStringᴱ : {a H} M RuntimeErrorᴱ {a} H M String
errToStringᴮ : {a H} B RuntimeErrorᴮ {a} H B String
errToStringᴱ (var x) (UnboundVariable) = "variable " ++ varToString x ++ " is unbound"
errToStringᴱ (val (addr a)) (SEGV p) = "address " ++ addrToString a ++ " is unallocated"
errToStringᴱ (M $ N) (FunctionMismatch v w p) = "value " ++ (valueToString v) ++ " is not a function"
errToStringᴱ (M $ N) (app₁ E) = errToStringᴱ M E
errToStringᴱ (M $ N) (app₂ E) = errToStringᴱ N E
errToStringᴱ (binexp M ·· N) (BinOpMismatch₁ v w p) = "value " ++ (valueToString v) ++ " is not a string"
errToStringᴱ (binexp M ·· N) (BinOpMismatch₂ v w p) = "value " ++ (valueToString w) ++ " is not a string"
errToStringᴱ (binexp M op N) (BinOpMismatch₁ v w p) = "value " ++ (valueToString v) ++ " is not a number"
errToStringᴱ (binexp M op N) (BinOpMismatch₂ v w p) = "value " ++ (valueToString w) ++ " is not a number"
errToStringᴱ (binexp M op N) (bin₁ E) = errToStringᴱ M E
errToStringᴱ (binexp M op N) (bin₂ E) = errToStringᴱ N E
errToStringᴱ (block b is B end) (block E) = errToStringᴮ B E ++ "\n in call of function " ++ varToString (name b)
errToStringᴮ (local x M B) (local E) = errToStringᴱ M E ++ "\n in definition of " ++ varToString (name x)
errToStringᴮ (return M B) (return E) = errToStringᴱ M E ++ "\n in return statement"

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module Luau.RuntimeType where
open import Luau.Syntax using (Value; nil; addr; number; bool; string)
data RuntimeType : Set where
function : RuntimeType
number : RuntimeType
nil : RuntimeType
boolean : RuntimeType
string : RuntimeType
valueType : Value RuntimeType
valueType nil = nil
valueType (addr a) = function
valueType (number n) = number
valueType (bool b) = boolean
valueType (string x) = string

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prototyping/Luau/RuntimeType/ToString.agda
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module Luau.RuntimeType.ToString where
open import FFI.Data.String using (String)
open import Luau.RuntimeType using (RuntimeType; function; number; nil; boolean; string)
runtimeTypeToString : RuntimeType String
runtimeTypeToString function = "function"
runtimeTypeToString number = "number"
runtimeTypeToString nil = "nil"
runtimeTypeToString boolean = "boolean"
runtimeTypeToString string = "string"

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{-# OPTIONS --rewriting #-}
module Luau.StrictMode where
open import Agda.Builtin.Equality using (_≡_)
open import FFI.Data.Maybe using (just; nothing)
open import Luau.Syntax using (Expr; Stat; Block; BinaryOperator; yes; nil; addr; var; binexp; var_∈_; _⟨_⟩∈_; function_is_end; _$_; block_is_end; local_←_; _∙_; done; return; name; +; -; *; /; <; >; <=; >=; ··)
open import Luau.Type using (Type; nil; number; string; boolean; _⇒_; __; _∩_)
open import Luau.ResolveOverloads using (src; resolve)
open import Luau.Subtyping using (_≮:_)
open import Luau.Heap using (Heap; function_is_end) renaming (_[_] to _[_]ᴴ)
open import Luau.VarCtxt using (VarCtxt; ∅; _⋒_; _↦_; _⊕_↦_; _⊝_) renaming (_[_] to _[_]ⱽ)
open import Luau.TypeCheck using (_⊢ᴮ_∈_; _⊢ᴱ_∈_; ⊢ᴴ_; ⊢ᴼ_; _⊢ᴴᴱ_▷_∈_; _⊢ᴴᴮ_▷_∈_; var; addr; app; binexp; block; return; local; function; srcBinOp)
open import Properties.Contradiction using (¬)
open import Properties.TypeCheck using (typeCheckᴮ)
open import Properties.Product using (_,_)
data Warningᴱ (H : Heap yes) {Γ} : {M T} (Γ ⊢ᴱ M T) Set
data Warningᴮ (H : Heap yes) {Γ} : {B T} (Γ ⊢ᴮ B T) Set
data Warningᴱ H {Γ} where
UnallocatedAddress : {a T}
(H [ a ]ᴴ nothing)
---------------------
Warningᴱ H (addr {a} T)
UnboundVariable : {x T p}
(Γ [ x ]ⱽ nothing)
------------------------
Warningᴱ H (var {x} {T} p)
FunctionCallMismatch : {M N T U} {D₁ : Γ ⊢ᴱ M T} {D₂ : Γ ⊢ᴱ N U}
(U ≮: src T)
-----------------
Warningᴱ H (app D₁ D₂)
app₁ : {M N T U} {D₁ : Γ ⊢ᴱ M T} {D₂ : Γ ⊢ᴱ N U}
Warningᴱ H D₁
-----------------
Warningᴱ H (app D₁ D₂)
app₂ : {M N T U} {D₁ : Γ ⊢ᴱ M T} {D₂ : Γ ⊢ᴱ N U}
Warningᴱ H D₂
-----------------
Warningᴱ H (app D₁ D₂)
BinOpMismatch₁ : {op M N T U} {D₁ : Γ ⊢ᴱ M T} {D₂ : Γ ⊢ᴱ N U}
(T ≮: srcBinOp op)
------------------------------
Warningᴱ H (binexp {op} D₁ D₂)
BinOpMismatch₂ : {op M N T U} {D₁ : Γ ⊢ᴱ M T} {D₂ : Γ ⊢ᴱ N U}
(U ≮: srcBinOp op)
------------------------------
Warningᴱ H (binexp {op} D₁ D₂)
bin₁ : {op M N T U} {D₁ : Γ ⊢ᴱ M T} {D₂ : Γ ⊢ᴱ N U}
Warningᴱ H D₁
------------------------------
Warningᴱ H (binexp {op} D₁ D₂)
bin₂ : {op M N T U} {D₁ : Γ ⊢ᴱ M T} {D₂ : Γ ⊢ᴱ N U}
Warningᴱ H D₂
------------------------------
Warningᴱ H (binexp {op} D₁ D₂)
FunctionDefnMismatch : {f x B T U V} {D : (Γ x T) ⊢ᴮ B V}
(V ≮: U)
-------------------------
Warningᴱ H (function {f} {U = U} D)
function₁ : {f x B T U V} {D : (Γ x T) ⊢ᴮ B V}
Warningᴮ H D
-------------------------
Warningᴱ H (function {f} {U = U} D)
BlockMismatch : {b B T U} {D : Γ ⊢ᴮ B U}
(U ≮: T)
------------------------------
Warningᴱ H (block {b} {T = T} D)
block₁ : {b B T U} {D : Γ ⊢ᴮ B U}
Warningᴮ H D
------------------------------
Warningᴱ H (block {b} {T = T} D)
data Warningᴮ H {Γ} where
return : {M B T U} {D₁ : Γ ⊢ᴱ M T} {D₂ : Γ ⊢ᴮ B U}
Warningᴱ H D₁
------------------
Warningᴮ H (return D₁ D₂)
LocalVarMismatch : {x M B T U V} {D₁ : Γ ⊢ᴱ M U} {D₂ : (Γ x T) ⊢ᴮ B V}
(U ≮: T)
--------------------
Warningᴮ H (local D₁ D₂)
local₁ : {x M B T U V} {D₁ : Γ ⊢ᴱ M U} {D₂ : (Γ x T) ⊢ᴮ B V}
Warningᴱ H D₁
--------------------
Warningᴮ H (local D₁ D₂)
local₂ : {x M B T U V} {D₁ : Γ ⊢ᴱ M U} {D₂ : (Γ x T) ⊢ᴮ B V}
Warningᴮ H D₂
--------------------
Warningᴮ H (local D₁ D₂)
FunctionDefnMismatch : {f x B C T U V W} {D₁ : (Γ x T) ⊢ᴮ C V} {D₂ : (Γ f (T U)) ⊢ᴮ B W}
(V ≮: U)
-------------------------------------
Warningᴮ H (function D₁ D₂)
function₁ : {f x B C T U V W} {D₁ : (Γ x T) ⊢ᴮ C V} {D₂ : (Γ f (T U)) ⊢ᴮ B W}
Warningᴮ H D₁
--------------------
Warningᴮ H (function D₁ D₂)
function₂ : {f x B C T U V W} {D₁ : (Γ x T) ⊢ᴮ C V} {D₂ : (Γ f (T U)) ⊢ᴮ B W}
Warningᴮ H D₂
--------------------
Warningᴮ H (function D₁ D₂)
data Warningᴼ (H : Heap yes) : {V} (⊢ᴼ V) Set where
FunctionDefnMismatch : {f x B T U V} {D : (x T) ⊢ᴮ B V}
(V ≮: U)
---------------------------------
Warningᴼ H (function {f} {U = U} D)
function₁ : {f x B T U V} {D : (x T) ⊢ᴮ B V}
Warningᴮ H D
---------------------------------
Warningᴼ H (function {f} {U = U} D)
data Warningᴴ H (D : ⊢ᴴ H) : Set where
addr : a {O}
(p : H [ a ]ᴴ O)
Warningᴼ H (D a p)
---------------
Warningᴴ H D
data Warningᴴᴱ H {Γ M T} : (Γ ⊢ᴴᴱ H M T) Set where
heap : {D₁ : ⊢ᴴ H} {D₂ : Γ ⊢ᴱ M T}
Warningᴴ H D₁
-----------------
Warningᴴᴱ H (D₁ , D₂)
expr : {D₁ : ⊢ᴴ H} {D₂ : Γ ⊢ᴱ M T}
Warningᴱ H D₂
---------------------
Warningᴴᴱ H (D₁ , D₂)
data Warningᴴᴮ H {Γ B T} : (Γ ⊢ᴴᴮ H B T) Set where
heap : {D₁ : ⊢ᴴ H} {D₂ : Γ ⊢ᴮ B T}
Warningᴴ H D₁
-----------------
Warningᴴᴮ H (D₁ , D₂)
block : {D₁ : ⊢ᴴ H} {D₂ : Γ ⊢ᴮ B T}
Warningᴮ H D₂
---------------------
Warningᴴᴮ H (D₁ , D₂)

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prototyping/Luau/StrictMode/ToString.agda
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{-# OPTIONS --rewriting #-}
module Luau.StrictMode.ToString where
open import Agda.Builtin.Nat using (Nat; suc)
open import FFI.Data.String using (String; _++_)
open import Luau.Subtyping using (_≮:_; Tree; witness; scalar; function; function-ok; function-err; function-tgt)
open import Luau.StrictMode using (Warningᴱ; Warningᴮ; UnallocatedAddress; UnboundVariable; FunctionCallMismatch; FunctionDefnMismatch; BlockMismatch; app₁; app₂; BinOpMismatch₁; BinOpMismatch₂; bin₁; bin₂; block₁; return; LocalVarMismatch; local₁; local₂; function₁; function₂; heap; expr; block; addr)
open import Luau.Syntax using (Expr; val; yes; var; var_∈_; _⟨_⟩∈_; _$_; addr; number; binexp; nil; function_is_end; block_is_end; done; return; local_←_; _∙_; fun; arg; name)
open import Luau.Type using (number; boolean; string; nil)
open import Luau.TypeCheck using (_⊢ᴮ_∈_; _⊢ᴱ_∈_)
open import Luau.Addr.ToString using (addrToString)
open import Luau.Var.ToString using (varToString)
open import Luau.Type.ToString using (typeToString)
open import Luau.Syntax.ToString using (binOpToString)
tmp : Nat String
tmp 0 = "w"
tmp 1 = "x"
tmp 2 = "y"
tmp 3 = "z"
tmp (suc (suc (suc n))) = tmp n ++ "'"
treeToString : Tree Nat String String
treeToString (scalar number) n v = v ++ " is a number"
treeToString (scalar boolean) n v = v ++ " is a boolean"
treeToString (scalar string) n v = v ++ " is a string"
treeToString (scalar nil) n v = v ++ " is nil"
treeToString function n v = v ++ " is a function"
treeToString (function-ok s t) n v = treeToString t (suc n) (v ++ "(" ++ w ++ ")") ++ " when\n " ++ treeToString s (suc n) w where w = tmp n
treeToString (function-err t) n v = v ++ "(" ++ w ++ ") can error when\n " ++ treeToString t (suc n) w where w = tmp n
treeToString (function-tgt t) n v = treeToString t n (v ++ "()")
subtypeWarningToString : {T U} (T ≮: U) String
subtypeWarningToString (witness t p q) = "\n because provided type contains v, where " ++ treeToString t 0 "v"
warningToStringᴱ : {H Γ T} M {D : Γ ⊢ᴱ M T} Warningᴱ H D String
warningToStringᴮ : {H Γ T} B {D : Γ ⊢ᴮ B T} Warningᴮ H D String
warningToStringᴱ (var x) (UnboundVariable p) = "Unbound variable " ++ varToString x
warningToStringᴱ (val (addr a)) (UnallocatedAddress p) = "Unallocated address " ++ addrToString a
warningToStringᴱ (M $ N) (FunctionCallMismatch {T = T} {U = U} p) = "Function has type " ++ typeToString T ++ " but argument has type " ++ typeToString U ++ subtypeWarningToString p
warningToStringᴱ (M $ N) (app₁ W) = warningToStringᴱ M W
warningToStringᴱ (M $ N) (app₂ W) = warningToStringᴱ N W
warningToStringᴱ (function f var x T ⟩∈ U is B end) (FunctionDefnMismatch {V = V} p) = "Function expresion " ++ varToString f ++ " has return type " ++ typeToString U ++ " but body returns " ++ typeToString V ++ subtypeWarningToString p
warningToStringᴱ (function f var x T ⟩∈ U is B end) (function₁ W) = warningToStringᴮ B W ++ "\n in function expression " ++ varToString f
warningToStringᴱ block var b T is B end (BlockMismatch {U = U} p) = "Block " ++ varToString b ++ " has type " ++ typeToString T ++ " but body returns " ++ typeToString U ++ subtypeWarningToString p
warningToStringᴱ block var b T is B end (block₁ W) = warningToStringᴮ B W ++ "\n in block " ++ varToString b
warningToStringᴱ (binexp M op N) (BinOpMismatch₁ {T = T} p) = "Binary operator " ++ binOpToString op ++ " lhs has type " ++ typeToString T ++ subtypeWarningToString p
warningToStringᴱ (binexp M op N) (BinOpMismatch₂ {U = U} p) = "Binary operator " ++ binOpToString op ++ " rhs has type " ++ typeToString U ++ subtypeWarningToString p
warningToStringᴱ (binexp M op N) (bin₁ W) = warningToStringᴱ M W
warningToStringᴱ (binexp M op N) (bin₂ W) = warningToStringᴱ N W
warningToStringᴮ (function f var x T ⟩∈ U is C end B) (FunctionDefnMismatch {V = V} p) = "Function declaration " ++ varToString f ++ " has return type " ++ typeToString U ++ " but body returns " ++ typeToString V ++ subtypeWarningToString p
warningToStringᴮ (function f var x T ⟩∈ U is C end B) (function₁ W) = warningToStringᴮ C W ++ "\n in function declaration " ++ varToString f
warningToStringᴮ (function f var x T ⟩∈ U is C end B) (function₂ W) = warningToStringᴮ B W
warningToStringᴮ (local var x T M B) (LocalVarMismatch {U = U} p) = "Local variable " ++ varToString x ++ " has type " ++ typeToString T ++ " but expression has type " ++ typeToString U ++ subtypeWarningToString p
warningToStringᴮ (local var x T M B) (local₁ W) = warningToStringᴱ M W ++ "\n in local variable declaration " ++ varToString x
warningToStringᴮ (local var x T M B) (local₂ W) = warningToStringᴮ B W
warningToStringᴮ (return M B) (return W) = warningToStringᴱ M W ++ "\n in return statement"

28
prototyping/Luau/Substitution.agda
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module Luau.Substitution where
open import Luau.Syntax using (Value; Expr; Stat; Block; val; nil; bool; addr; var; function_is_end; _$_; block_is_end; local_←_; _∙_; done; return; _⟨_⟩ ; name; fun; arg; number; binexp)
open import Luau.Var using (Var; _≡ⱽ_)
open import Properties.Dec using (Dec; yes; no)
_[_/_]ᴱ : {a} Expr a Value Var Expr a
_[_/_]ᴮ : {a} Block a Value Var Block a
var_[_/_]ᴱwhenever_ : {a P} Var Value Var (Dec P) Expr a
_[_/_]ᴮunless_ : {a P} Block a Value Var (Dec P) Block a
val w [ v / x ]ᴱ = val w
var y [ v / x ]ᴱ = var y [ v / x ]ᴱwhenever (x ≡ⱽ y)
(M $ N) [ v / x ]ᴱ = (M [ v / x ]ᴱ) $ (N [ v / x ]ᴱ)
function F is C end [ v / x ]ᴱ = function F is C [ v / x ]ᴮunless (x ≡ⱽ name(arg F)) end
block b is C end [ v / x ]ᴱ = block b is C [ v / x ]ᴮ end
(binexp e₁ op e₂) [ v / x ]ᴱ = binexp (e₁ [ v / x ]ᴱ) op (e₂ [ v / x ]ᴱ)
(function F is C end B) [ v / x ]ᴮ = function F is (C [ v / x ]ᴮunless (x ≡ⱽ name(arg F))) end (B [ v / x ]ᴮunless (x ≡ⱽ name(fun F)))
(local y M B) [ v / x ]ᴮ = local y (M [ v / x ]ᴱ) (B [ v / x ]ᴮunless (x ≡ⱽ name y))
(return M B) [ v / x ]ᴮ = return (M [ v / x ]ᴱ) (B [ v / x ]ᴮ)
done [ v / x ]ᴮ = done
var y [ v / x ]ᴱwhenever yes p = val v
var y [ v / x ]ᴱwhenever no p = var y
B [ v / x ]ᴮunless yes p = B
B [ v / x ]ᴮunless no p = B [ v / x ]ᴮ

67
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{-# OPTIONS --rewriting #-}
open import Luau.Type using (Type; Scalar; nil; number; string; boolean; never; unknown; _⇒_; __; _∩_)
open import Properties.Equality using (_≢_)
module Luau.Subtyping where
-- An implementation of semantic subtyping
-- We think of types as languages of trees
data Tree : Set where
scalar : {T} Scalar T Tree
function : Tree
function-ok : Tree Tree Tree
function-err : Tree Tree
function-tgt : Tree Tree
data Language : Type Tree Set
data ¬Language : Type Tree Set
data Language where
scalar : {T} (s : Scalar T) Language T (scalar s)
function : {T U} Language (T U) function
function-ok₁ : {T U t u} (¬Language T t) Language (T U) (function-ok t u)
function-ok₂ : {T U t u} (Language U u) Language (T U) (function-ok t u)
function-err : {T U t} (¬Language T t) Language (T U) (function-err t)
function-tgt : {T U t} (Language U t) Language (T U) (function-tgt t)
left : {T U t} Language T t Language (T U) t
right : {T U u} Language U u Language (T U) u
_,_ : {T U t} Language T t Language U t Language (T U) t
unknown : {t} Language unknown t
data ¬Language where
scalar-scalar : {S T} (s : Scalar S) (Scalar T) (S T) ¬Language T (scalar s)
scalar-function : {S} (Scalar S) ¬Language S function
scalar-function-ok : {S t u} (Scalar S) ¬Language S (function-ok t u)
scalar-function-err : {S t} (Scalar S) ¬Language S (function-err t)
scalar-function-tgt : {S t} (Scalar S) ¬Language S (function-tgt t)
function-scalar : {S T U} (s : Scalar S) ¬Language (T U) (scalar s)
function-ok : {T U t u} (Language T t) (¬Language U u) ¬Language (T U) (function-ok t u)
function-err : {T U t} (Language T t) ¬Language (T U) (function-err t)
function-tgt : {T U t} (¬Language U t) ¬Language (T U) (function-tgt t)
_,_ : {T U t} ¬Language T t ¬Language U t ¬Language (T U) t
left : {T U t} ¬Language T t ¬Language (T U) t
right : {T U u} ¬Language U u ¬Language (T U) u
never : {t} ¬Language never t
-- Subtyping as language inclusion
_<:_ : Type Type Set
(T <: U) = t (Language T t) (Language U t)
-- For warnings, we are interested in failures of subtyping,
-- which is whrn there is a tree in T's language that isn't in U's.
data _≮:_ (T U : Type) : Set where
witness : t
Language T t
¬Language U t
-----------------
T ≮: U

110
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module Luau.Syntax where
open import Agda.Builtin.Equality using (_≡_)
open import Agda.Builtin.Bool using (Bool; true; false)
open import Agda.Builtin.Float using (Float)
open import Agda.Builtin.String using (String)
open import Luau.Var using (Var)
open import Luau.Addr using (Addr)
open import Luau.Type using (Type)
open import FFI.Data.Maybe using (Maybe; just; nothing)
infixr 5 _∙_
data Annotated : Set where
maybe : Annotated
yes : Annotated
data VarDec : Annotated Set where
var : Var VarDec maybe
var_∈_ : {a} Var Type VarDec a
name : {a} VarDec a Var
name (var x) = x
name (var x T) = x
data FunDec : Annotated Set where
_⟨_⟩∈_ : {a} Var VarDec a Type FunDec a
_⟨_⟩ : Var VarDec maybe FunDec maybe
fun : {a} FunDec a VarDec a
fun (f x ⟩∈ T) = (var f T)
fun (f x ) = (var f)
arg : {a} FunDec a VarDec a
arg (f x ⟩∈ T) = x
arg (f x ) = x
data BinaryOperator : Set where
+ : BinaryOperator
- : BinaryOperator
* : BinaryOperator
/ : BinaryOperator
< : BinaryOperator
> : BinaryOperator
== : BinaryOperator
~= : BinaryOperator
<= : BinaryOperator
>= : BinaryOperator
·· : BinaryOperator
data Value : Set where
nil : Value
addr : Addr Value
number : Float Value
bool : Bool Value
string : String Value
data Block (a : Annotated) : Set
data Stat (a : Annotated) : Set
data Expr (a : Annotated) : Set
data Block a where
_∙_ : Stat a Block a Block a
done : Block a
data Stat a where
function_is_end : FunDec a Block a Stat a
local_←_ : VarDec a Expr a Stat a
return : Expr a Stat a
data Expr a where
var : Var Expr a
val : Value Expr a
_$_ : Expr a Expr a Expr a
function_is_end : FunDec a Block a Expr a
block_is_end : VarDec a Block a Expr a
binexp : Expr a BinaryOperator Expr a Expr a
isAnnotatedᴱ : {a} Expr a Maybe (Expr yes)
isAnnotatedᴮ : {a} Block a Maybe (Block yes)
isAnnotatedᴱ (var x) = just (var x)
isAnnotatedᴱ (val v) = just (val v)
isAnnotatedᴱ (M $ N) with isAnnotatedᴱ M | isAnnotatedᴱ N
isAnnotatedᴱ (M $ N) | just M | just N = just (M $ N)
isAnnotatedᴱ (M $ N) | _ | _ = nothing
isAnnotatedᴱ (function f var x T ⟩∈ U is B end) with isAnnotatedᴮ B
isAnnotatedᴱ (function f var x T ⟩∈ U is B end) | just B = just (function f var x T ⟩∈ U is B end)
isAnnotatedᴱ (function f var x T ⟩∈ U is B end) | _ = nothing
isAnnotatedᴱ (function _ is B end) = nothing
isAnnotatedᴱ (block var b T is B end) with isAnnotatedᴮ B
isAnnotatedᴱ (block var b T is B end) | just B = just (block var b T is B end)
isAnnotatedᴱ (block var b T is B end) | _ = nothing
isAnnotatedᴱ (block _ is B end) = nothing
isAnnotatedᴱ (binexp M op N) with isAnnotatedᴱ M | isAnnotatedᴱ N
isAnnotatedᴱ (binexp M op N) | just M | just N = just (binexp M op N)
isAnnotatedᴱ (binexp M op N) | _ | _ = nothing
isAnnotatedᴮ (function f var x T ⟩∈ U is C end B) with isAnnotatedᴮ B | isAnnotatedᴮ C
isAnnotatedᴮ (function f var x T ⟩∈ U is C end B) | just B | just C = just (function f var x T ⟩∈ U is C end B)
isAnnotatedᴮ (function f var x T ⟩∈ U is C end B) | _ | _ = nothing
isAnnotatedᴮ (function _ is C end B) = nothing
isAnnotatedᴮ (local var x T M B) with isAnnotatedᴱ M | isAnnotatedᴮ B
isAnnotatedᴮ (local var x T M B) | just M | just B = just (local var x T M B)
isAnnotatedᴮ (local var x T M B) | _ | _ = nothing
isAnnotatedᴮ (local _ M B) = nothing
isAnnotatedᴮ (return M B) with isAnnotatedᴱ M | isAnnotatedᴮ B
isAnnotatedᴮ (return M B) | just M | just B = just (return M B)
isAnnotatedᴮ (return M B) | _ | _ = nothing
isAnnotatedᴮ done = just done

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prototyping/Luau/Syntax/FromJSON.agda
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{-# OPTIONS --rewriting #-}
module Luau.Syntax.FromJSON where
open import Luau.Syntax using (Block; Stat ; Expr; _$_; val; nil; bool; number; var; var_∈_; function_is_end; _⟨_⟩; _⟨_⟩∈_; local_←_; return; done; _∙_; maybe; VarDec; binexp; BinaryOperator; +; -; *; /; ==; ~=; <; >; <=; >=; ··; string)
open import Luau.Type.FromJSON using (typeFromJSON)
open import Agda.Builtin.List using (List; _∷_; [])
open import Agda.Builtin.Bool using (true; false)
open import FFI.Data.Aeson using (Value; Array; Object; object; array; string; fromString; lookup)
open import FFI.Data.Either using (Either; Left; Right)
open import FFI.Data.Maybe using (Maybe; nothing; just)
open import FFI.Data.Scientific using (toFloat)
open import FFI.Data.String using (String; _++_)
open import FFI.Data.Vector using (head; tail; null; empty)
args = fromString "args"
body = fromString "body"
func = fromString "func"
lokal = fromString "local"
list = fromString "list"
name = fromString "name"
type = fromString "type"
value = fromString "value"
values = fromString "values"
vars = fromString "vars"
op = fromString "op"
left = fromString "left"
right = fromString "right"
returnAnnotation = fromString "returnAnnotation"
types = fromString "types"
data Lookup : Set where
_,_ : String Value Lookup
nil : Lookup
lookupIn : List String Object Lookup
lookupIn [] obj = nil
lookupIn (key keys) obj with lookup (fromString key) obj
lookupIn (key keys) obj | nothing = lookupIn keys obj
lookupIn (key keys) obj | just value = (key , value)
binOpFromJSON : Value Either String BinaryOperator
binOpFromString : String Either String BinaryOperator
varDecFromJSON : Value Either String (VarDec maybe)
varDecFromObject : Object Either String (VarDec maybe)
exprFromJSON : Value Either String (Expr maybe)
exprFromObject : Object Either String (Expr maybe)
statFromJSON : Value Either String (Stat maybe)
statFromObject : Object Either String (Stat maybe)
blockFromJSON : Value Either String (Block maybe)
blockFromArray : Array Either String (Block maybe)
binOpFromJSON (string s) = binOpFromString s
binOpFromJSON _ = Left "Binary operator not a string"
binOpFromString "Add" = Right +
binOpFromString "Sub" = Right -
binOpFromString "Mul" = Right *
binOpFromString "Div" = Right /
binOpFromString "CompareEq" = Right ==
binOpFromString "CompareNe" = Right ~=
binOpFromString "CompareLt" = Right <
binOpFromString "CompareLe" = Right <=
binOpFromString "CompareGt" = Right >
binOpFromString "CompareGe" = Right >=
binOpFromString "Concat" = Right ··
binOpFromString s = Left ("'" ++ s ++ "' is not a valid operator")
varDecFromJSON (object arg) = varDecFromObject arg
varDecFromJSON _ = Left "VarDec not an object"
varDecFromObject obj with lookup name obj | lookup type obj
varDecFromObject obj | just (string name) | nothing = Right (var name)
varDecFromObject obj | just (string name) | just Value.null = Right (var name)
varDecFromObject obj | just (string name) | just tyValue with typeFromJSON tyValue
varDecFromObject obj | just (string name) | just tyValue | Right ty = Right (var name ty)
varDecFromObject obj | just (string name) | just tyValue | Left err = Left err
varDecFromObject obj | just _ | _ = Left "AstLocal name is not a string"
varDecFromObject obj | nothing | _ = Left "AstLocal missing name"
exprFromJSON (object obj) = exprFromObject obj
exprFromJSON _ = Left "AstExpr not an object"
exprFromObject obj with lookup type obj
exprFromObject obj | just (string "AstExprCall") with lookup func obj | lookup args obj
exprFromObject obj | just (string "AstExprCall") | just value | just (array arr) with head arr
exprFromObject obj | just (string "AstExprCall") | just value | just (array arr) | just value2 with exprFromJSON value | exprFromJSON value2
exprFromObject obj | just (string "AstExprCall") | just value | just (array arr) | just value2 | Right fun | Right arg = Right (fun $ arg)
exprFromObject obj | just (string "AstExprCall") | just value | just (array arr) | just value2 | Left err | _ = Left err
exprFromObject obj | just (string "AstExprCall") | just value | just (array arr) | just value2 | _ | Left err = Left err
exprFromObject obj | just (string "AstExprCall") | just value | just (array arr) | nothing = Left ("AstExprCall empty args")
exprFromObject obj | just (string "AstExprCall") | just value | just _ = Left ("AstExprCall args not an array")
exprFromObject obj | just (string "AstExprCall") | nothing | _ = Left ("AstExprCall missing func")
exprFromObject obj | just (string "AstExprCall") | _ | nothing = Left ("AstExprCall missing args")
exprFromObject obj | just (string "AstExprConstantNil") = Right (val nil)
exprFromObject obj | just (string "AstExprFunction") with lookup args obj | lookup body obj | lookup returnAnnotation obj
exprFromObject obj | just (string "AstExprFunction") | just (array arr) | just blockValue | rtn with head arr | blockFromJSON blockValue
exprFromObject obj | just (string "AstExprFunction") | just (array arr) | just blockValue | rtn | just argValue | Right B with varDecFromJSON argValue
exprFromObject obj | just (string "AstExprFunction") | just (array arr) | just blockValue | just (object rtnObj) | just argValue | Right B | Right arg with lookup types rtnObj
exprFromObject obj | just (string "AstExprFunction") | just (array arr) | just blockValue | just (object rtnObj) | just argValue | Right B | Right arg | just (array rtnTypes) with head rtnTypes
exprFromObject obj | just (string "AstExprFunction") | just (array arr) | just blockValue | just (object rtnObj) | just argValue | Right B | Right arg | just (array rtnTypes) | just rtnType with typeFromJSON rtnType
exprFromObject obj | just (string "AstExprFunction") | just (array arr) | just blockValue | just (object rtnObj) | just argValue | Right B | Right arg | just (array rtnTypes) | just rtnType | Left err = Left err
exprFromObject obj | just (string "AstExprFunction") | just (array arr) | just blockValue | just (object rtnObj) | just argValue | Right B | Right arg | just (array rtnTypes) | just rtnType | Right T = Right (function "" arg ⟩∈ T is B end)
exprFromObject obj | just (string "AstExprFunction") | just (array arr) | just blockValue | just (object rtnObj) | just argValue | Right B | Right arg | just (array rtnTypes) | nothing = Right (function "" arg is B end)
exprFromObject obj | just (string "AstExprFunction") | just (array arr) | just blockValue | just (object rtnObj) | just argValue | Right B | Right arg | just _ = Left "returnAnnotation types not an array"
exprFromObject obj | just (string "AstExprFunction") | just (array arr) | just blockValue | just (object rtnObj) | just argValue | Right B | Right arg | nothing = Left "returnAnnotation missing types"
exprFromObject obj | just (string "AstExprFunction") | just (array arr) | just blockValue | just _ | just argValue | Right B | Right arg = Left "returnAnnotation not an object"
exprFromObject obj | just (string "AstExprFunction") | just (array arr) | just blockValue | nothing | just argValue | Right B | Right arg = Right (function "" arg is B end)
exprFromObject obj | just (string "AstExprFunction") | just (array arr) | just blockValue | rtn | just argValue | Right B | Left err = Left err
exprFromObject obj | just (string "AstExprFunction") | just (array arr) | just blockValue | rtn | nothing | Right B = Left "Unsupported AstExprFunction empty args"
exprFromObject obj | just (string "AstExprFunction") | just (array arr) | just blockValue | rtn | _ | Left err = Left err
exprFromObject obj | just (string "AstExprFunction") | just _ | just _ | rtn = Left "AstExprFunction args not an array"
exprFromObject obj | just (string "AstExprFunction") | nothing | _ | rtn = Left "AstExprFunction missing args"
exprFromObject obj | just (string "AstExprFunction") | _ | nothing | rtn = Left "AstExprFunction missing body"
exprFromObject obj | just (string "AstExprLocal") with lookup lokal obj
exprFromObject obj | just (string "AstExprLocal") | just x with varDecFromJSON x
exprFromObject obj | just (string "AstExprLocal") | just x | Right x = Right (var (Luau.Syntax.name x))
exprFromObject obj | just (string "AstExprLocal") | just x | Left err = Left err
exprFromObject obj | just (string "AstExprLocal") | nothing = Left "AstExprLocal missing local"
exprFromObject obj | just (string "AstExprConstantNumber") with lookup value obj
exprFromObject obj | just (string "AstExprConstantNumber") | just (FFI.Data.Aeson.Value.number x) = Right (val (number (toFloat x)))
exprFromObject obj | just (string "AstExprConstantNumber") | just _ = Left "AstExprConstantNumber value is not a number"
exprFromObject obj | just (string "AstExprConstantNumber") | nothing = Left "AstExprConstantNumber missing value"
exprFromObject obj | just (string "AstExprConstantString") with lookup value obj
exprFromObject obj | just (string "AstExprConstantString") | just (string x) = Right (val (string x))
exprFromObject obj | just (string "AstExprConstantString") | just _ = Left "AstExprConstantString value is not a string"
exprFromObject obj | just (string "AstExprConstantString") | nothing = Left "AstExprConstantString missing value"
exprFromObject obj | just (string "AstExprConstantBool") with lookup value obj
exprFromObject obj | just (string "AstExprConstantBool") | just (FFI.Data.Aeson.Value.bool b) = Right (val (bool b))
exprFromObject obj | just (string "AstExprConstantBool") | just _ = Left "AstExprConstantBool value is not a bool"
exprFromObject obj | just (string "AstExprConstantBool") | nothing = Left "AstExprConstantBool missing value"
exprFromObject obj | just (string "AstExprBinary") with lookup op obj | lookup left obj | lookup right obj
exprFromObject obj | just (string "AstExprBinary") | just o | just l | just r with binOpFromJSON o | exprFromJSON l | exprFromJSON r
exprFromObject obj | just (string "AstExprBinary") | just o | just l | just r | Right o | Right l | Right r = Right (binexp l o r)
exprFromObject obj | just (string "AstExprBinary") | just o | just l | just r | Left err | _ | _ = Left err
exprFromObject obj | just (string "AstExprBinary") | just o | just l | just r | _ | Left err | _ = Left err
exprFromObject obj | just (string "AstExprBinary") | just o | just l | just r | _ | _ | Left err = Left err
exprFromObject obj | just (string "AstExprBinary") | nothing | _ | _ = Left "Missing 'op' in AstExprBinary"
exprFromObject obj | just (string "AstExprBinary") | _ | nothing | _ = Left "Missing 'left' in AstExprBinary"
exprFromObject obj | just (string "AstExprBinary") | _ | _ | nothing = Left "Missing 'right' in AstExprBinary"
exprFromObject obj | just (string ty) = Left ("TODO: Unsupported AstExpr " ++ ty)
exprFromObject obj | just _ = Left "AstExpr type not a string"
exprFromObject obj | nothing = Left "AstExpr missing type"
{-# NON_TERMINATING #-}
statFromJSON (object obj) = statFromObject obj
statFromJSON _ = Left "AstStat not an object"
statFromObject obj with lookup type obj
statFromObject obj | just(string "AstStatLocal") with lookup vars obj | lookup values obj
statFromObject obj | just(string "AstStatLocal") | just(array arr1) | just(array arr2) with head(arr1) | head(arr2)
statFromObject obj | just(string "AstStatLocal") | just(array arr1) | just(array arr2) | just(x) | just(value) with varDecFromJSON(x) | exprFromJSON(value)
statFromObject obj | just(string "AstStatLocal") | just(array arr1) | just(array arr2) | just(x) | just(value) | Right x | Right M = Right (local x M)
statFromObject obj | just(string "AstStatLocal") | just(array arr1) | just(array arr2) | just(x) | just(value) | Left err | _ = Left err
statFromObject obj | just(string "AstStatLocal") | just(array arr1) | just(array arr2) | just(x) | just(value) | _ | Left err = Left err
statFromObject obj | just(string "AstStatLocal") | just(array arr1) | just(array arr2) | just(x) | nothing = Left "AstStatLocal empty values"
statFromObject obj | just(string "AstStatLocal") | just(array arr1) | just(array arr2) | nothing | _ = Left "AstStatLocal empty vars"
statFromObject obj | just(string "AstStatLocal") | just(array arr1) | just(_) = Left "AstStatLocal values not an array"
statFromObject obj | just(string "AstStatLocal") | just(_) | just(_) = Left "AstStatLocal vars not an array"
statFromObject obj | just(string "AstStatLocal") | just(_) | nothing = Left "AstStatLocal missing values"
statFromObject obj | just(string "AstStatLocal") | nothing | _ = Left "AstStatLocal missing vars"
statFromObject obj | just(string "AstStatLocalFunction") with lookup name obj | lookup func obj
statFromObject obj | just(string "AstStatLocalFunction") | just fnName | just value with varDecFromJSON fnName | exprFromJSON value
statFromObject obj | just(string "AstStatLocalFunction") | just fnName | just value | Right fnVar | Right (function "" x is B end) = Right (function (Luau.Syntax.name fnVar) x is B end)
statFromObject obj | just(string "AstStatLocalFunction") | just fnName | just value | Right fnVar | Right (function "" x ⟩∈ T is B end) = Right (function (Luau.Syntax.name fnVar) x ⟩∈ T is B end)
statFromObject obj | just(string "AstStatLocalFunction") | just fnName | just value | Left err | _ = Left err
statFromObject obj | just(string "AstStatLocalFunction") | just fnName | just value | _ | Left err = Left err
statFromObject obj | just(string "AstStatLocalFunction") | just _ | just _ | Right _ | Right _ = Left "AstStatLocalFunction func is not an AstExprFunction"
statFromObject obj | just(string "AstStatLocalFunction") | nothing | _ = Left "AstStatFunction missing name"
statFromObject obj | just(string "AstStatLocalFunction") | _ | nothing = Left "AstStatFunction missing func"
statFromObject obj | just(string "AstStatReturn") with lookup list obj
statFromObject obj | just(string "AstStatReturn") | just(array arr) with head arr
statFromObject obj | just(string "AstStatReturn") | just(array arr) | just value with exprFromJSON value
statFromObject obj | just(string "AstStatReturn") | just(array arr) | just value | Right M = Right (return M)
statFromObject obj | just(string "AstStatReturn") | just(array arr) | just value | Left err = Left err
statFromObject obj | just(string "AstStatReturn") | just(array arr) | nothing = Left "AstStatReturn empty list"
statFromObject obj | just(string "AstStatReturn") | just(_) = Left "AstStatReturn list not an array"
statFromObject obj | just(string "AstStatReturn") | nothing = Left "AstStatReturn missing list"
statFromObject obj | just (string ty) = Left ("TODO: Unsupported AstStat " ++ ty)
statFromObject obj | just _ = Left "AstStat type not a string"
statFromObject obj | nothing = Left "AstStat missing type"
blockFromJSON (array arr) = blockFromArray arr
blockFromJSON (object obj) with lookup type obj | lookup body obj
blockFromJSON (object obj) | just (string "AstStatBlock") | just value = blockFromJSON value
blockFromJSON (object obj) | just (string "AstStatBlock") | nothing = Left "AstStatBlock missing body"
blockFromJSON (object obj) | just (string ty) | _ = Left ("Unsupported AstBlock " ++ ty)
blockFromJSON (object obj) | just _ | _ = Left "AstStatBlock type not a string"
blockFromJSON (object obj) | nothing | _ = Left "AstStatBlock missing type"
blockFromJSON _ = Left "AstBlock not an array or AstStatBlock object"
blockFromArray arr with head arr
blockFromArray arr | nothing = Right done
blockFromArray arr | just value with statFromJSON value
blockFromArray arr | just value | Left err = Left err
blockFromArray arr | just value | Right S with blockFromArray(tail arr)
blockFromArray arr | just value | Right S | Left err = Left (err)
blockFromArray arr | just value | Right S | Right B = Right (S B)

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module Luau.Syntax.ToString where
open import Agda.Builtin.Bool using (true; false)
open import Agda.Builtin.Float using (primShowFloat)
open import Agda.Builtin.String using (primShowString)
open import Luau.Syntax using (Value; Block; Stat; Expr; VarDec; FunDec; nil; bool; val; var; var_∈_; addr; _$_; function_is_end; return; local_←_; _∙_; done; block_is_end; _⟨_⟩; _⟨_⟩∈_; number; BinaryOperator; +; -; *; /; <; >; ==; ~=; <=; >=; ··; binexp; string)
open import FFI.Data.String using (String; _++_)
open import Luau.Addr.ToString using (addrToString)
open import Luau.Type.ToString using (typeToString)
open import Luau.Var.ToString using (varToString)
varDecToString : {a} VarDec a String
varDecToString (var x) = varToString x
varDecToString (var x T) = varToString x ++ " : " ++ typeToString T
funDecToString : {a} FunDec a String
funDecToString ("" x ⟩∈ T) = "function(" ++ varDecToString x ++ "): " ++ typeToString T
funDecToString ("" x ) = "function(" ++ varDecToString x ++ ")"
funDecToString (f x ⟩∈ T) = "function " ++ varToString f ++ "(" ++ varDecToString x ++ "): " ++ typeToString T
funDecToString (f x ) = "function " ++ varToString f ++ "(" ++ varDecToString x ++ ")"
binOpToString : BinaryOperator String
binOpToString + = "+"
binOpToString - = "-"
binOpToString * = "*"
binOpToString / = "/"
binOpToString < = "<"
binOpToString > = ">"
binOpToString == = "=="
binOpToString ~= = "~="
binOpToString <= = "<="
binOpToString >= = ">="
binOpToString ·· = ".."
valueToString : Value String
valueToString nil = "nil"
valueToString (addr a) = addrToString a
valueToString (number x) = primShowFloat x
valueToString (bool false) = "false"
valueToString (bool true) = "true"
valueToString (string x) = primShowString x
exprToString : {a} String Expr a String
statToString : {a} String Stat a String
blockToString : {a} String Block a String
exprToString lb (val v) =
valueToString(v)
exprToString lb (var x) =
varToString(x)
exprToString lb (M $ N) =
(exprToString lb M) ++ "(" ++ (exprToString lb N) ++ ")"
exprToString lb (function F is B end) =
funDecToString F ++ lb ++
" " ++ (blockToString (lb ++ " ") B) ++ lb ++
"end"
exprToString lb (block b is B end) =
"(" ++ varDecToString b ++ "()" ++ lb ++
" " ++ (blockToString (lb ++ " ") B) ++ lb ++
"end)()"
exprToString lb (binexp x op y) = exprToString lb x ++ " " ++ binOpToString op ++ " " ++ exprToString lb y
statToString lb (function F is B end) =
"local " ++ funDecToString F ++ lb ++
" " ++ (blockToString (lb ++ " ") B) ++ lb ++
"end"
statToString lb (local x M) =
"local " ++ varDecToString x ++ " = " ++ (exprToString lb M)
statToString lb (return M) =
"return " ++ (exprToString lb M)
blockToString lb (S done) = statToString lb S
blockToString lb (S B) = statToString lb S ++ lb ++ blockToString lb B
blockToString lb (done) = ""
exprToString : {a} Expr a String
exprToString = exprToString "\n"
statToString : {a} Stat a String
statToString = statToString "\n"
blockToString : {a} Block a String
blockToString = blockToString "\n"

164
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module Luau.Type where
open import FFI.Data.Maybe using (Maybe; just; nothing; just-inv)
open import Agda.Builtin.Equality using (_≡_; refl)
open import Properties.Dec using (Dec; yes; no)
open import Properties.Equality using (cong)
open import FFI.Data.Maybe using (Maybe; just; nothing)
data Type : Set where
nil : Type
_⇒_ : Type Type Type
never : Type
unknown : Type
boolean : Type
number : Type
string : Type
__ : Type Type Type
_∩_ : Type Type Type
data Scalar : Type Set where
number : Scalar number
boolean : Scalar boolean
string : Scalar string
nil : Scalar nil
skalar = number (string (nil boolean))
lhs : Type Type
lhs (T _) = T
lhs (T _) = T
lhs (T _) = T
lhs nil = nil
lhs never = never
lhs unknown = unknown
lhs number = number
lhs boolean = boolean
lhs string = string
rhs : Type Type
rhs (_ T) = T
rhs (_ T) = T
rhs (_ T) = T
rhs nil = nil
rhs never = never
rhs unknown = unknown
rhs number = number
rhs boolean = boolean
rhs string = string
_≡ᵀ_ : (T U : Type) Dec(T U)
nil ≡ᵀ nil = yes refl
nil ≡ᵀ (S T) = no (λ ())
nil ≡ᵀ never = no (λ ())
nil ≡ᵀ unknown = no (λ ())
nil ≡ᵀ number = no (λ ())
nil ≡ᵀ boolean = no (λ ())
nil ≡ᵀ (S T) = no (λ ())
nil ≡ᵀ (S T) = no (λ ())
nil ≡ᵀ string = no (λ ())
(S T) ≡ᵀ string = no (λ ())
never ≡ᵀ string = no (λ ())
unknown ≡ᵀ string = no (λ ())
boolean ≡ᵀ string = no (λ ())
number ≡ᵀ string = no (λ ())
(S T) ≡ᵀ string = no (λ ())
(S T) ≡ᵀ string = no (λ ())
(S T) ≡ᵀ nil = no (λ ())
(S T) ≡ᵀ (U V) with (S ≡ᵀ U) | (T ≡ᵀ V)
(S T) ≡ᵀ (S T) | yes refl | yes refl = yes refl
(S T) ≡ᵀ (U V) | _ | no p = no (λ q p (cong rhs q))
(S T) ≡ᵀ (U V) | no p | _ = no (λ q p (cong lhs q))
(S T) ≡ᵀ never = no (λ ())
(S T) ≡ᵀ unknown = no (λ ())
(S T) ≡ᵀ number = no (λ ())
(S T) ≡ᵀ boolean = no (λ ())
(S T) ≡ᵀ (U V) = no (λ ())
(S T) ≡ᵀ (U V) = no (λ ())
never ≡ᵀ nil = no (λ ())
never ≡ᵀ (U V) = no (λ ())
never ≡ᵀ never = yes refl
never ≡ᵀ unknown = no (λ ())
never ≡ᵀ number = no (λ ())
never ≡ᵀ boolean = no (λ ())
never ≡ᵀ (U V) = no (λ ())
never ≡ᵀ (U V) = no (λ ())
unknown ≡ᵀ nil = no (λ ())
unknown ≡ᵀ (U V) = no (λ ())
unknown ≡ᵀ never = no (λ ())
unknown ≡ᵀ unknown = yes refl
unknown ≡ᵀ number = no (λ ())
unknown ≡ᵀ boolean = no (λ ())
unknown ≡ᵀ (U V) = no (λ ())
unknown ≡ᵀ (U V) = no (λ ())
number ≡ᵀ nil = no (λ ())
number ≡ᵀ (T U) = no (λ ())
number ≡ᵀ never = no (λ ())
number ≡ᵀ unknown = no (λ ())
number ≡ᵀ number = yes refl
number ≡ᵀ boolean = no (λ ())
number ≡ᵀ (T U) = no (λ ())
number ≡ᵀ (T U) = no (λ ())
boolean ≡ᵀ nil = no (λ ())
boolean ≡ᵀ (T U) = no (λ ())
boolean ≡ᵀ never = no (λ ())
boolean ≡ᵀ unknown = no (λ ())
boolean ≡ᵀ boolean = yes refl
boolean ≡ᵀ number = no (λ ())
boolean ≡ᵀ (T U) = no (λ ())
boolean ≡ᵀ (T U) = no (λ ())
string ≡ᵀ nil = no (λ ())
string ≡ᵀ (x x₁) = no (λ ())
string ≡ᵀ never = no (λ ())
string ≡ᵀ unknown = no (λ ())
string ≡ᵀ boolean = no (λ ())
string ≡ᵀ number = no (λ ())
string ≡ᵀ string = yes refl
string ≡ᵀ (U V) = no (λ ())
string ≡ᵀ (U V) = no (λ ())
(S T) ≡ᵀ nil = no (λ ())
(S T) ≡ᵀ (U V) = no (λ ())
(S T) ≡ᵀ never = no (λ ())
(S T) ≡ᵀ unknown = no (λ ())
(S T) ≡ᵀ number = no (λ ())
(S T) ≡ᵀ boolean = no (λ ())
(S T) ≡ᵀ (U V) with (S ≡ᵀ U) | (T ≡ᵀ V)
(S T) ≡ᵀ (S T) | yes refl | yes refl = yes refl
(S T) ≡ᵀ (U V) | _ | no p = no (λ q p (cong rhs q))
(S T) ≡ᵀ (U V) | no p | _ = no (λ q p (cong lhs q))
(S T) ≡ᵀ (U V) = no (λ ())
(S T) ≡ᵀ nil = no (λ ())
(S T) ≡ᵀ (U V) = no (λ ())
(S T) ≡ᵀ never = no (λ ())
(S T) ≡ᵀ unknown = no (λ ())
(S T) ≡ᵀ number = no (λ ())
(S T) ≡ᵀ boolean = no (λ ())
(S T) ≡ᵀ (U V) = no (λ ())
(S T) ≡ᵀ (U V) with (S ≡ᵀ U) | (T ≡ᵀ V)
(S T) ≡ᵀ (U V) | yes refl | yes refl = yes refl
(S T) ≡ᵀ (U V) | _ | no p = no (λ q p (cong rhs q))
(S T) ≡ᵀ (U V) | no p | _ = no (λ q p (cong lhs q))
_≡ᴹᵀ_ : (T U : Maybe Type) Dec(T U)
nothing ≡ᴹᵀ nothing = yes refl
nothing ≡ᴹᵀ just U = no (λ ())
just T ≡ᴹᵀ nothing = no (λ ())
just T ≡ᴹᵀ just U with T ≡ᵀ U
(just T ≡ᴹᵀ just T) | yes refl = yes refl
(just T ≡ᴹᵀ just U) | no p = no (λ q p (just-inv q))
optional : Type Type
optional nil = nil
optional (T nil) = (T nil)
optional T = (T nil)
normalizeOptional : Type Type
normalizeOptional (S T) with normalizeOptional S | normalizeOptional T
normalizeOptional (S T) | (S nil) | (T nil) = (S T) nil
normalizeOptional (S T) | S | (T nil) = (S T) nil
normalizeOptional (S T) | (S nil) | T = (S T) nil
normalizeOptional (S T) | S | nil = optional S
normalizeOptional (S T) | nil | T = optional T
normalizeOptional (S T) | S | T = S T
normalizeOptional T = T

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{-# OPTIONS --rewriting #-}
module Luau.Type.FromJSON where
open import Luau.Type using (Type; nil; _⇒_; __; _∩_; unknown; never; number; string)
open import Agda.Builtin.List using (List; _∷_; [])
open import Agda.Builtin.Bool using (true; false)
open import FFI.Data.Aeson using (Value; Array; Object; object; array; string; fromString; lookup)
open import FFI.Data.Either using (Either; Left; Right)
open import FFI.Data.Maybe using (Maybe; nothing; just)
open import FFI.Data.String using (String; _++_)
open import FFI.Data.Vector using (head; tail; null; empty)
name = fromString "name"
type = fromString "type"
argTypes = fromString "argTypes"
returnTypes = fromString "returnTypes"
types = fromString "types"
{-# TERMINATING #-}
typeFromJSON : Value Either String Type
compoundFromArray : (Type Type Type) Array Either String Type
typeFromJSON (object o) with lookup type o
typeFromJSON (object o) | just (string "AstTypeFunction") with lookup argTypes o | lookup returnTypes o
typeFromJSON (object o) | just (string "AstTypeFunction") | just (object argsSet) | just (object retsSet) with lookup types argsSet | lookup types retsSet
typeFromJSON (object o) | just (string "AstTypeFunction") | just (object argsSet) | just (object retsSet) | just (array args) | just (array rets) with head args | head rets
typeFromJSON (object o) | just (string "AstTypeFunction") | just (object argsSet) | just (object retsSet) | just (array args) | just (array rets) | just argValue | just retValue with typeFromJSON argValue | typeFromJSON retValue
typeFromJSON (object o) | just (string "AstTypeFunction") | just (object argsSet) | just (object retsSet) | just (array args) | just (array rets) | just argValue | just retValue | Right arg | Right ret = Right (arg ret)
typeFromJSON (object o) | just (string "AstTypeFunction") | just (object argsSet) | just (object retsSet) | just (array args) | just (array rets) | just argValue | just retValue | Left err | _ = Left err
typeFromJSON (object o) | just (string "AstTypeFunction") | just (object argsSet) | just (object retsSet) | just (array args) | just (array rets) | just argValue | just retValue | _ | Left err = Left err
typeFromJSON (object o) | just (string "AstTypeFunction") | just (object argsSet) | just (object retsSet) | just (array args) | just (array rets) | _ | nothing = Left "No return type"
typeFromJSON (object o) | just (string "AstTypeFunction") | just (object argsSet) | just (object retsSet) | just (array args) | just (array rets) | nothing | _ = Left "No argument type"
typeFromJSON (object o) | just (string "AstTypeFunction") | just (object argsSet) | just (object retsSet) | just _ | _ = Left "argTypes.types is not an array"
typeFromJSON (object o) | just (string "AstTypeFunction") | just (object argsSet) | just (object retsSet) | _ | just _ = Left "retTypes.types is not an array"
typeFromJSON (object o) | just (string "AstTypeFunction") | just (object argsSet) | just (object retsSet) | nothing | _ = Left "argTypes.types does not exist"
typeFromJSON (object o) | just (string "AstTypeFunction") | _ | just _ = Left "argTypes is not an object"
typeFromJSON (object o) | just (string "AstTypeFunction") | just _ | _ = Left "returnTypes is not an object"
typeFromJSON (object o) | just (string "AstTypeFunction") | nothing | nothing = Left "Missing argTypes and returnTypes"
typeFromJSON (object o) | just (string "AstTypeReference") with lookup name o
typeFromJSON (object o) | just (string "AstTypeReference") | just (string "nil") = Right nil
typeFromJSON (object o) | just (string "AstTypeReference") | just (string "any") = Right unknown -- not quite right
typeFromJSON (object o) | just (string "AstTypeReference") | just (string "unknown") = Right unknown
typeFromJSON (object o) | just (string "AstTypeReference") | just (string "never") = Right never
typeFromJSON (object o) | just (string "AstTypeReference") | just (string "number") = Right number
typeFromJSON (object o) | just (string "AstTypeReference") | just (string "string") = Right string
typeFromJSON (object o) | just (string "AstTypeReference") | _ = Left "Unknown referenced type"
typeFromJSON (object o) | just (string "AstTypeUnion") with lookup types o
typeFromJSON (object o) | just (string "AstTypeUnion") | just (array types) = compoundFromArray __ types
typeFromJSON (object o) | just (string "AstTypeUnion") | _ = Left "`types` field must be an array"
typeFromJSON (object o) | just (string "AstTypeIntersection") with lookup types o
typeFromJSON (object o) | just (string "AstTypeIntersection") | just (array types) = compoundFromArray _∩_ types
typeFromJSON (object o) | just (string "AstTypeIntersection") | _ = Left "`types` field must be an array"
typeFromJSON (object o) | just (string ty) = Left ("Unsupported type " ++ ty)
typeFromJSON (object o) | just _ = Left "`type` field must be a string"
typeFromJSON (object o) | nothing = Left "No `type` field"
typeFromJSON _ = Left "Unsupported JSON type"
compoundFromArray ctor ts with head ts | tail ts
compoundFromArray ctor ts | just hd | tl with null tl
compoundFromArray ctor ts | just hd | tl | true = typeFromJSON hd
compoundFromArray ctor ts | just hd | tl | false with typeFromJSON hd | compoundFromArray ctor tl
compoundFromArray ctor ts | just hd | tl | false | Right hdTy | Right tlTy = Right (ctor hdTy tlTy)
compoundFromArray ctor ts | just hd | tl | false | Left err | _ = Left err
compoundFromArray ctor ts | just hd | tl | false | _ | Left Err = Left Err
compoundFromArray ctor ts | nothing | empty = Left "Empty types array?"

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module Luau.Type.ToString where
open import FFI.Data.String using (String; _++_)
open import Luau.Type using (Type; nil; _⇒_; never; unknown; number; boolean; string; __; _∩_; normalizeOptional)
{-# TERMINATING #-}
typeToString : Type String
typeToStringᵁ : Type String
typeToStringᴵ : Type String
typeToString nil = "nil"
typeToString (S T) = "(" ++ (typeToString S) ++ ") -> " ++ (typeToString T)
typeToString never = "never"
typeToString unknown = "unknown"
typeToString number = "number"
typeToString boolean = "boolean"
typeToString string = "string"
typeToString (S T) with normalizeOptional(S T)
typeToString (S T) | ((S T) nil) = "(" ++ typeToString (S T) ++ ")?"
typeToString (S T) | (S nil) = typeToString S ++ "?"
typeToString (S T) | (S T) = "(" ++ typeToStringᵁ (S T) ++ ")"
typeToString (S T) | T = typeToString T
typeToString (S T) = "(" ++ typeToStringᴵ (S T) ++ ")"
typeToStringᵁ (S T) = (typeToStringᵁ S) ++ " | " ++ (typeToStringᵁ T)
typeToStringᵁ T = typeToString T
typeToStringᴵ (S T) = (typeToStringᴵ S) ++ " & " ++ (typeToStringᴵ T)
typeToStringᴵ T = typeToString T

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{-# OPTIONS --rewriting #-}
module Luau.TypeCheck where
open import Agda.Builtin.Equality using (_≡_)
open import FFI.Data.Either using (Either; Left; Right)
open import FFI.Data.Maybe using (Maybe; just)
open import Luau.ResolveOverloads using (resolve)
open import Luau.Syntax using (Expr; Stat; Block; BinaryOperator; yes; nil; addr; number; bool; string; val; var; var_∈_; _⟨_⟩∈_; function_is_end; _$_; block_is_end; binexp; local_←_; _∙_; done; return; name; +; -; *; /; <; >; ==; ~=; <=; >=; ··)
open import Luau.Var using (Var)
open import Luau.Addr using (Addr)
open import Luau.Heap using (Heap; Object; function_is_end) renaming (_[_] to _[_]ᴴ)
open import Luau.Type using (Type; nil; unknown; number; boolean; string; _⇒_)
open import Luau.VarCtxt using (VarCtxt; ∅; _⋒_; _↦_; _⊕_↦_; _⊝_) renaming (_[_] to _[_]ⱽ)
open import FFI.Data.Vector using (Vector)
open import FFI.Data.Maybe using (Maybe; just; nothing)
open import Properties.DecSubtyping using (dec-subtyping)
open import Properties.Product using (_×_; _,_)
orUnknown : Maybe Type Type
orUnknown nothing = unknown
orUnknown (just T) = T
srcBinOp : BinaryOperator Type
srcBinOp + = number
srcBinOp - = number
srcBinOp * = number
srcBinOp / = number
srcBinOp < = number
srcBinOp > = number
srcBinOp == = unknown
srcBinOp ~= = unknown
srcBinOp <= = number
srcBinOp >= = number
srcBinOp ·· = string
tgtBinOp : BinaryOperator Type
tgtBinOp + = number
tgtBinOp - = number
tgtBinOp * = number
tgtBinOp / = number
tgtBinOp < = boolean
tgtBinOp > = boolean
tgtBinOp == = boolean
tgtBinOp ~= = boolean
tgtBinOp <= = boolean
tgtBinOp >= = boolean
tgtBinOp ·· = string
data _⊢ᴮ_∈_ : VarCtxt Block yes Type Set
data _⊢ᴱ_∈_ : VarCtxt Expr yes Type Set
data _⊢ᴮ_∈_ where
done : {Γ}
---------------
Γ ⊢ᴮ done nil
return : {M B T U Γ}
Γ ⊢ᴱ M T
Γ ⊢ᴮ B U
---------------------
Γ ⊢ᴮ return M B T
local : {x M B T U V Γ}
Γ ⊢ᴱ M U
(Γ x T) ⊢ᴮ B V
--------------------------------
Γ ⊢ᴮ local var x T M B V
function : {f x B C T U V W Γ}
(Γ x T) ⊢ᴮ C V
(Γ f (T U)) ⊢ᴮ B W
-------------------------------------------------
Γ ⊢ᴮ function f var x T ⟩∈ U is C end B W
data _⊢ᴱ_∈_ where
nil : {Γ}
--------------------
Γ ⊢ᴱ (val nil) nil
var : {x T Γ}
T orUnknown(Γ [ x ]ⱽ)
----------------
Γ ⊢ᴱ (var x) T
addr : {a Γ} T
-----------------
Γ ⊢ᴱ val(addr a) T
number : {n Γ}
---------------------------
Γ ⊢ᴱ val(number n) number
bool : {b Γ}
--------------------------
Γ ⊢ᴱ val(bool b) boolean
string : {x Γ}
---------------------------
Γ ⊢ᴱ val(string x) string
app : {M N T U Γ}
Γ ⊢ᴱ M T
Γ ⊢ᴱ N U
----------------------------
Γ ⊢ᴱ (M $ N) (resolve T U)
function : {f x B T U V Γ}
(Γ x T) ⊢ᴮ B V
-----------------------------------------------------
Γ ⊢ᴱ (function f var x T ⟩∈ U is B end) (T U)
block : {b B T U Γ}
Γ ⊢ᴮ B U
------------------------------------
Γ ⊢ᴱ (block var b T is B end) T
binexp : {op Γ M N T U}
Γ ⊢ᴱ M T
Γ ⊢ᴱ N U
----------------------------------
Γ ⊢ᴱ (binexp M op N) tgtBinOp op
data ⊢ᴼ_ : Maybe(Object yes) Set where
nothing :
---------
⊢ᴼ nothing
function : {f x T U V B}
(x T) ⊢ᴮ B V
----------------------------------------------
⊢ᴼ (just function f var x T ⟩∈ U is B end)
⊢ᴴ_ : Heap yes Set
⊢ᴴ H = a {O} (H [ a ]ᴴ O) (⊢ᴼ O)
_⊢ᴴᴱ_▷_∈_ : VarCtxt Heap yes Expr yes Type Set
(Γ ⊢ᴴᴱ H M T) = (⊢ᴴ H) × (Γ ⊢ᴱ M T)
_⊢ᴴᴮ_▷_∈_ : VarCtxt Heap yes Block yes Type Set
(Γ ⊢ᴴᴮ H B T) = (⊢ᴴ H) × (Γ ⊢ᴮ B T)

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module Luau.TypeNormalization where
open import Luau.Type using (Type; nil; number; string; boolean; never; unknown; _⇒_; __; _∩_)
-- Operations on normalized types
_ᶠ_ : Type Type Type
_ⁿˢ_ : Type Type Type
_∩ⁿˢ_ : Type Type Type
_ⁿ_ : Type Type Type
_∩ⁿ_ : Type Type Type
-- Union of function types
(F₁ F₂) ∪ᶠ G = (F₁ ∪ᶠ G) (F₂ ∪ᶠ G)
F ∪ᶠ (G₁ G₂) = (F ∪ᶠ G₁) (F ∪ᶠ G₂)
(R S) ∪ᶠ (T U) = (R ∩ⁿ T) (S ∪ⁿ U)
F ∪ᶠ G = F G
-- Union of normalized types
S ∪ⁿ (T₁ T₂) = (S ∪ⁿ T₁) T₂
S ∪ⁿ unknown = unknown
S ∪ⁿ never = S
never ∪ⁿ T = T
unknown ∪ⁿ T = unknown
(S₁ S₂) ∪ⁿ G = (S₁ ∪ⁿ G) S₂
F ∪ⁿ G = F ∪ᶠ G
-- Intersection of normalized types
S ∩ⁿ (T₁ T₂) = (S ∩ⁿ T₁) ∪ⁿˢ (S ∩ⁿˢ T₂)
S ∩ⁿ unknown = S
S ∩ⁿ never = never
(S₁ S₂) ∩ⁿ G = (S₁ ∩ⁿ G)
unknown ∩ⁿ G = G
never ∩ⁿ G = never
F ∩ⁿ G = F G
-- Intersection of normalized types with a scalar
(S₁ nil) ∩ⁿˢ nil = nil
(S₁ boolean) ∩ⁿˢ boolean = boolean
(S₁ number) ∩ⁿˢ number = number
(S₁ string) ∩ⁿˢ string = string
(S₁ S₂) ∩ⁿˢ T = S₁ ∩ⁿˢ T
unknown ∩ⁿˢ T = T
F ∩ⁿˢ T = never
-- Union of normalized types with an optional scalar
S ∪ⁿˢ never = S
unknown ∪ⁿˢ T = unknown
(S₁ nil) ∪ⁿˢ nil = S₁ nil
(S₁ boolean) ∪ⁿˢ boolean = S₁ boolean
(S₁ number) ∪ⁿˢ number = S₁ number
(S₁ string) ∪ⁿˢ string = S₁ string
(S₁ S₂) ∪ⁿˢ T = (S₁ ∪ⁿˢ T) S₂
F ∪ⁿˢ T = F T
-- Normalize!
normalize : Type Type
normalize nil = never nil
normalize (S T) = (normalize S normalize T)
normalize never = never
normalize unknown = unknown
normalize boolean = never boolean
normalize number = never number
normalize string = never string
normalize (S T) = normalize S ∪ⁿ normalize T
normalize (S T) = normalize S ∩ⁿ normalize T

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module Luau.TypeSaturation where
open import Luau.Type using (Type; _⇒_; _∩_; __)
open import Luau.TypeNormalization using (_ⁿ_; _∩ⁿ_)
-- So, there's a problem with overloaded functions
-- (of the form (S_1 ⇒ T_1) ∩⋯∩ (S_n ⇒ T_n))
-- which is that it's not good enough to compare them
-- for subtyping by comparing all of their overloads.
-- For example (nil → nil) is a subtype of (number? → number?) ∩ (string? → string?)
-- but not a subtype of any of its overloads.
-- To fix this, we adapt the semantic subtyping algorithm for
-- function types, given in
-- https://www.irif.fr/~gc/papers/covcon-again.pdf and
-- https://pnwamk.github.io/sst-tutorial/
-- A function type is *intersection-saturated* if for any overloads
-- (S₁ ⇒ T₁) and (S₂ ⇒ T₂), there exists an overload which is a subtype
-- of ((S₁ ∩ S₂) ⇒ (T₁ ∩ T₂)).
-- A function type is *union-saturated* if for any overloads
-- (S₁ ⇒ T₁) and (S₂ ⇒ T₂), there exists an overload which is a subtype
-- of ((S₁ S₂) ⇒ (T₁ T₂)).
-- A function type is *saturated* if it is both intersection- and
-- union-saturated.
-- For example (number? → number?) ∩ (string? → string?)
-- is not saturated, but (number? → number?) ∩ (string? → string?) ∩ (nil → nil) ∩ ((number string)? → (number string)?)
-- is.
-- Saturated function types have the nice property that they can ber
-- compared by just comparing their overloads: F <: G whenever for any
-- overload of G, there is an overload os F which is a subtype of it.
-- Forunately every function type can be saturated!
_⋓_ : Type Type Type
(S₁ T₁) (S₂ T₂) = (S₁ ∪ⁿ S₂) (T₁ ∪ⁿ T₂)
(F₁ G₁) F₂ = (F₁ F₂) (G₁ F₂)
F₁ (F₂ G₂) = (F₁ F₂) (F₁ G₂)
F G = F G
_⋒_ : Type Type Type
(S₁ T₁) (S₂ T₂) = (S₁ ∩ⁿ S₂) (T₁ ∩ⁿ T₂)
(F₁ G₁) F₂ = (F₁ F₂) (G₁ F₂)
F₁ (F₂ G₂) = (F₁ F₂) (F₁ G₂)
F G = F G
_∩ᵘ_ : Type Type Type
F ∩ᵘ G = (F G) (F G)
_∩ⁱ_ : Type Type Type
F ∩ⁱ G = (F G) (F G)
-saturate : Type Type
-saturate (F G) = (-saturate F ∩ᵘ -saturate G)
-saturate F = F
∩-saturate : Type Type
∩-saturate (F G) = (∩-saturate F ∩ⁱ ∩-saturate G)
∩-saturate F = F
saturate : Type Type
saturate F = -saturate (∩-saturate F)

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module Luau.Var where
open import Agda.Builtin.Bool using (true; false)
open import Agda.Builtin.Equality using (_≡_)
open import Agda.Builtin.String using (String; primStringEquality)
open import Agda.Builtin.TrustMe using (primTrustMe)
open import Properties.Dec using (Dec; yes; no)
open import Properties.Equality using (_≢_)
Var : Set
Var = String
_≡ⱽ_ : (a b : Var) Dec (a b)
a ≡ⱽ b with primStringEquality a b
a ≡ⱽ b | false = no p where postulate p : (a b)
a ≡ⱽ b | true = yes primTrustMe

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prototyping/Luau/Var/ToString.agda
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module Luau.Var.ToString where
open import Agda.Builtin.String using (String)
open import Luau.Var using (Var)
varToString : Var String
varToString x = x

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{-# OPTIONS --rewriting #-}
module Luau.VarCtxt where
open import Agda.Builtin.Equality using (_≡_)
open import Luau.Type using (Type; __; _∩_)
open import Luau.Var using (Var)
open import FFI.Data.Aeson using (KeyMap; Key; empty; unionWith; singleton; insert; delete; lookup; toString; fromString; lookup-insert; lookup-insert-not; lookup-empty; to-from; insert-swap; insert-over)
open import FFI.Data.Maybe using (Maybe; just; nothing)
open import Properties.Equality using (_≢_; cong; sym; trans)
VarCtxt : Set
VarCtxt = KeyMap Type
: VarCtxt
= empty
_⋒_ : VarCtxt VarCtxt VarCtxt
_⋒_ = unionWith _∩_
_⋓_ : VarCtxt VarCtxt VarCtxt
_⋓_ = unionWith __
_[_] : VarCtxt Var Maybe Type
Γ [ x ] = lookup (fromString x) Γ
_⊝_ : VarCtxt Var VarCtxt
Γ x = delete (fromString x) Γ
_↦_ : Var Type VarCtxt
x T = singleton (fromString x) T
_⊕_↦_ : VarCtxt Var Type VarCtxt
Γ x T = insert (fromString x) T Γ
⊕-over : {Γ x y T U} (x y) ((Γ x T) y U) (Γ y U)
⊕-over p = insert-over _ _ _ _ _ (cong fromString (sym p))
⊕-swap : {Γ x y T U} (x y) ((Γ x T) y U) ((Γ y U) x T)
⊕-swap p = insert-swap _ _ _ _ _ (λ q p (trans (sym (to-from _)) (trans (cong toString (sym q) ) (to-from _))) )
⊕-lookup-miss : x y T Γ (x y) (Γ [ y ] (Γ x T) [ y ])
⊕-lookup-miss x y T Γ p = lookup-insert-not (fromString x) (fromString y) T Γ λ q p (trans (sym (to-from x)) (trans (cong toString q) (to-from y)))

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{-# OPTIONS --rewriting #-}
module PrettyPrinter where
open import Agda.Builtin.IO using (IO)
open import Agda.Builtin.Int using (pos)
open import Agda.Builtin.Unit using ()
open import FFI.IO using (getContents; putStrLn; _>>=_; _>>_)
open import FFI.Data.Aeson using (Value; eitherDecode)
open import FFI.Data.Either using (Left; Right)
open import FFI.Data.String using (String; _++_)
open import FFI.Data.Text.Encoding using (encodeUtf8)
open import FFI.System.Exit using (exitWith; ExitFailure)
open import Luau.Syntax using (Block)
open import Luau.Syntax.FromJSON using (blockFromJSON)
open import Luau.Syntax.ToString using (blockToString)
runBlock : {a} Block a IO
runBlock block = putStrLn (blockToString block)
runJSON : Value IO
runJSON value with blockFromJSON(value)
runJSON value | (Left err) = putStrLn ("Luau error: " ++ err) >> exitWith (ExitFailure (pos 1))
runJSON value | (Right block) = runBlock block
runString : String IO
runString txt with eitherDecode (encodeUtf8 txt)
runString txt | (Left err) = putStrLn ("JSON error: " ++ err) >> exitWith (ExitFailure (pos 1))
runString txt | (Right value) = runJSON value
main : IO
main = getContents >>= runString

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{-# OPTIONS --rewriting #-}
module Properties where
import Properties.Contradiction
import Properties.Dec
import Properties.DecSubtyping
import Properties.Equality
import Properties.Functions
import Properties.Remember
import Properties.Step
import Properties.StrictMode
import Properties.Subtyping
import Properties.TypeCheck
import Properties.TypeNormalization

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module Properties.Contradiction where
data : Set where
¬ : Set Set
¬ A = A
CONTRADICTION : {A : Set} A
CONTRADICTION ()

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module Properties.Dec where
open import Properties.Contradiction using (¬)
data Dec(A : Set) : Set where
yes : A Dec A
no : ¬ A Dec A

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{-# OPTIONS --rewriting #-}
module Properties.DecSubtyping where
open import Agda.Builtin.Equality using (_≡_; refl)
open import FFI.Data.Either using (Either; Left; Right; mapLR; swapLR; cond)
open import Luau.Subtyping using (_<:_; _≮:_; Tree; Language; ¬Language; witness; unknown; never; scalar; function; scalar-function; scalar-function-ok; scalar-function-err; scalar-function-tgt; scalar-scalar; function-scalar; function-ok; function-ok₁; function-ok₂; function-err; function-tgt; left; right; _,_)
open import Luau.Type using (Type; Scalar; nil; number; string; boolean; never; unknown; _⇒_; __; _∩_)
open import Luau.TypeNormalization using (_ⁿ_; _∩ⁿ_)
open import Luau.TypeSaturation using (saturate)
open import Properties.Contradiction using (CONTRADICTION; ¬)
open import Properties.Functions using (_∘_)
open import Properties.Subtyping using (<:-refl; <:-trans; ≮:-trans-<:; <:-trans-≮:; <:-never; <:-unknown; <:--left; <:--right; <:--lub; ≮:--left; ≮:--right; <:-∩-left; <:-∩-right; <:-∩-glb; ≮:-∩-left; ≮:-∩-right; dec-language; scalar-<:; <:-everything; <:-function; ≮:-function-left; ≮:-function-right; <:-impl-¬≮:; <:-intersect; <:-function-∩-; <:-function-∩; <:-union; ≮:-left-; ≮:-right-; <:-∩-distr-; <:-impl-⊇; language-comp)
open import Properties.TypeNormalization using (FunType; Normal; never; unknown; _∩_; __; _⇒_; normal; <:-normalize; normalize-<:; normal-∩ⁿ; normal-∪ⁿ; -<:-∪ⁿ; ∪ⁿ-<:-; ∩ⁿ-<:-∩; ∩-<:-∩ⁿ; normalᶠ; fun-top; fun-function; fun-¬scalar)
open import Properties.TypeSaturation using (Overloads; Saturated; _⊆ᵒ_; _<:ᵒ_; defn; here; left; right; ov-language; ov-<:; saturated; normal-saturate; normal-overload-src; normal-overload-tgt; saturate-<:; <:-saturate; <:ᵒ-impl-<:; _>>=ˡ_; _>>=ʳ_)
open import Properties.Equality using (_≢_)
-- Honest this terminates, since saturation maintains the depth of nested arrows
{-# TERMINATING #-}
dec-subtypingˢⁿ : {T U} Scalar T Normal U Either (T ≮: U) (T <: U)
dec-subtypingˢᶠ : {F G} FunType F Saturated F FunType G Either (F ≮: G) (F <:ᵒ G)
dec-subtypingᶠ : {F G} FunType F FunType G Either (F ≮: G) (F <: G)
dec-subtypingᶠⁿ : {F U} FunType F Normal U Either (F ≮: U) (F <: U)
dec-subtypingⁿ : {T U} Normal T Normal U Either (T ≮: U) (T <: U)
dec-subtyping : T U Either (T ≮: U) (T <: U)
dec-subtypingˢⁿ T U with dec-language _ (scalar T)
dec-subtypingˢⁿ T U | Left p = Left (witness (scalar T) (scalar T) p)
dec-subtypingˢⁿ T U | Right p = Right (scalar-<: T p)
dec-subtypingˢᶠ {F} {S T} Fᶠ (defn sat-∩ sat-) (Sⁿ Tⁿ) = result (top Fᶠ (λ o o)) where
data Top G : Set where
defn : Sᵗ Tᵗ
Overloads F (Sᵗ Tᵗ)
( {S T} Overloads G (S T) (S <: Sᵗ))
-------------
Top G
top : {G} (FunType G) (G ⊆ᵒ F) Top G
top {S T} _ G⊆F = defn S T (G⊆F here) (λ { here <:-refl })
top (Gᶠ Hᶠ) G⊆F with top Gᶠ (G⊆F left) | top Hᶠ (G⊆F right)
top (Gᶠ Hᶠ) G⊆F | defn Rᵗ Sᵗ p p₁ | defn Tᵗ Uᵗ q q₁ with sat- p q
top (Gᶠ Hᶠ) G⊆F | defn Rᵗ Sᵗ p p₁ | defn Tᵗ Uᵗ q q₁ | defn n r r₁ = defn _ _ n
(λ { (left o) <:-trans (<:-trans (p₁ o) <:--left) r ; (right o) <:-trans (<:-trans (q₁ o) <:--right) r })
result : Top F Either (F ≮: (S T)) (F <:ᵒ (S T))
result (defn Sᵗ Tᵗ oᵗ srcᵗ) with dec-subtypingⁿ Sⁿ (normal-overload-src Fᶠ oᵗ)
result (defn Sᵗ Tᵗ oᵗ srcᵗ) | Left (witness s Ss ¬Sᵗs) = Left (witness (function-err s) (ov-language Fᶠ (λ o function-err (<:-impl-⊇ (srcᵗ o) s ¬Sᵗs))) (function-err Ss))
result (defn Sᵗ Tᵗ oᵗ srcᵗ) | Right S<:Sᵗ = result₀ (largest Fᶠ (λ o o)) where
data LargestSrc (G : Type) : Set where
yes : S₀ T₀
Overloads F (S₀ T₀)
T₀ <: T
( {S T} Overloads G (S T) T <: T (S <: S₀))
-----------------------
LargestSrc G
no : S₀ T₀
Overloads F (S₀ T₀)
T₀ ≮: T
( {S T} Overloads G (S T) T₀ <: T)
-----------------------
LargestSrc G
largest : {G} (FunType G) (G ⊆ᵒ F) LargestSrc G
largest {S T} (S T) G⊆F with dec-subtypingⁿ T Tⁿ
largest {S T} (S T) G⊆F | Left T≮:T = no S T (G⊆F here) T≮:T λ { here <:-refl }
largest {S T} (S T) G⊆F | Right T<:T = yes S T (G⊆F here) T<:T (λ { here _ <:-refl })
largest (Gᶠ Hᶠ) GH⊆F with largest Gᶠ (GH⊆F left) | largest Hᶠ (GH⊆F right)
largest (Gᶠ Hᶠ) GH⊆F | no S₁ T₁ o₁ T₁≮:T tgt₁ | no S₂ T₂ o₂ T₂≮:T tgt₂ with sat-∩ o₁ o₂
largest (Gᶠ Hᶠ) GH⊆F | no S₁ T₁ o₁ T₁≮:T tgt₁ | no S₂ T₂ o₂ T₂≮:T tgt₂ | defn o src tgt with dec-subtypingⁿ (normal-overload-tgt Fᶠ o) Tⁿ
largest (Gᶠ Hᶠ) GH⊆F | no S₁ T₁ o₁ T₁≮:T tgt₁ | no S₂ T₂ o₂ T₂≮:T tgt₂ | defn o src tgt | Left T₀≮:T = no _ _ o T₀≮:T (λ { (left o) <:-trans tgt (<:-trans <:-∩-left (tgt₁ o)) ; (right o) <:-trans tgt (<:-trans <:-∩-right (tgt₂ o)) })
largest (Gᶠ Hᶠ) GH⊆F | no S₁ T₁ o₁ T₁≮:T tgt₁ | no S₂ T₂ o₂ T₂≮:T tgt₂ | defn o src tgt | Right T₀<:T = yes _ _ o T₀<:T (λ { (left o) p CONTRADICTION (<:-impl-¬≮: p (<:-trans-≮: (tgt₁ o) T₁≮:T)) ; (right o) p CONTRADICTION (<:-impl-¬≮: p (<:-trans-≮: (tgt₂ o) T₂≮:T)) })
largest (Gᶠ Hᶠ) GH⊆F | no S₁ T₁ o₁ T₁≮:T tgt₁ | yes S₂ T₂ o₂ T₂<:T src₂ = yes S₂ T₂ o₂ T₂<:T (λ { (left o) p CONTRADICTION (<:-impl-¬≮: p (<:-trans-≮: (tgt₁ o) T₁≮:T)) ; (right o) p src₂ o p })
largest (Gᶠ Hᶠ) GH⊆F | yes S₁ T₁ o₁ T₁<:T src₁ | no S₂ T₂ o₂ T₂≮:T tgt₂ = yes S₁ T₁ o₁ T₁<:T (λ { (left o) p src₁ o p ; (right o) p CONTRADICTION (<:-impl-¬≮: p (<:-trans-≮: (tgt₂ o) T₂≮:T)) })
largest (Gᶠ Hᶠ) GH⊆F | yes S₁ T₁ o₁ T₁<:T src₁ | yes S₂ T₂ o₂ T₂<:T src₂ with sat- o₁ o₂
largest (Gᶠ Hᶠ) GH⊆F | yes S₁ T₁ o₁ T₁<:T src₁ | yes S₂ T₂ o₂ T₂<:T src₂ | defn o src tgt = yes _ _ o (<:-trans tgt (<:--lub T₁<:T T₂<:T))
(λ { (left o) T<:T <:-trans (src₁ o T<:T) (<:-trans <:--left src)
; (right o) T<:T <:-trans (src₂ o T<:T) (<:-trans <:--right src)
})
result₀ : LargestSrc F Either (F ≮: (S T)) (F <:ᵒ (S T))
result₀ (no S₀ T₀ o₀ (witness t T₀t ¬Tt) tgt₀) = Left (witness (function-tgt t) (ov-language Fᶠ (λ o function-tgt (tgt₀ o t T₀t))) (function-tgt ¬Tt))
result₀ (yes S₀ T₀ o₀ T₀<:T src₀) with dec-subtypingⁿ Sⁿ (normal-overload-src Fᶠ o₀)
result₀ (yes S₀ T₀ o₀ T₀<:T src₀) | Right S<:S₀ = Right λ { here defn o₀ S<:S₀ T₀<:T }
result₀ (yes S₀ T₀ o₀ T₀<:T src₀) | Left (witness s Ss ¬S₀s) = Left (result₁ (smallest Fᶠ (λ o o))) where
data SmallestTgt (G : Type) : Set where
defn : S₁ T₁
Overloads F (S₁ T₁)
Language S₁ s
( {S T} Overloads G (S T) Language S s (T₁ <: T))
-----------------------
SmallestTgt G
smallest : {G} (FunType G) (G ⊆ᵒ F) SmallestTgt G
smallest {S T} _ G⊆F with dec-language S s
smallest {S T} _ G⊆F | Left ¬Ss = defn Sᵗ Tᵗ oᵗ (S<:Sᵗ s Ss) λ { here Ss CONTRADICTION (language-comp s ¬Ss Ss) }
smallest {S T} _ G⊆F | Right Ss = defn S T (G⊆F here) Ss (λ { here _ <:-refl })
smallest (Gᶠ Hᶠ) GH⊆F with smallest Gᶠ (GH⊆F left) | smallest Hᶠ (GH⊆F right)
smallest (Gᶠ Hᶠ) GH⊆F | defn S₁ T₁ o₁ R₁s tgt₁ | defn S₂ T₂ o₂ R₂s tgt₂ with sat-∩ o₁ o₂
smallest (Gᶠ Hᶠ) GH⊆F | defn S₁ T₁ o₁ R₁s tgt₁ | defn S₂ T₂ o₂ R₂s tgt₂ | defn o src tgt = defn _ _ o (src s (R₁s , R₂s))
(λ { (left o) Ss <:-trans (<:-trans tgt <:-∩-left) (tgt₁ o Ss)
; (right o) Ss <:-trans (<:-trans tgt <:-∩-right) (tgt₂ o Ss)
})
result₁ : SmallestTgt F (F ≮: (S T))
result₁ (defn S₁ T₁ o₁ S₁s tgt₁) with dec-subtypingⁿ (normal-overload-tgt Fᶠ o₁) Tⁿ
result₁ (defn S₁ T₁ o₁ S₁s tgt₁) | Right T₁<:T = CONTRADICTION (language-comp s ¬S₀s (src₀ o₁ T₁<:T s S₁s))
result₁ (defn S₁ T₁ o₁ S₁s tgt₁) | Left (witness t T₁t ¬Tt) = witness (function-ok s t) (ov-language Fᶠ lemma) (function-ok Ss ¬Tt) where
lemma : {S T} Overloads F (S T) Language (S T) (function-ok s t)
lemma {S} o with dec-language S s
lemma {S} o | Left ¬Ss = function-ok₁ ¬Ss
lemma {S} o | Right Ss = function-ok₂ (tgt₁ o Ss t T₁t)
dec-subtypingˢᶠ F (G H) with dec-subtypingˢᶠ F G | dec-subtypingˢᶠ F H
dec-subtypingˢᶠ F (G H) | Left F≮:G | _ = Left (≮:-∩-left F≮:G)
dec-subtypingˢᶠ F (G H) | _ | Left F≮:H = Left (≮:-∩-right F≮:H)
dec-subtypingˢᶠ F (G H) | Right F<:G | Right F<:H = Right (λ { (left o) F<:G o ; (right o) F<:H o })
dec-subtypingᶠ F G with dec-subtypingˢᶠ (normal-saturate F) (saturated F) G
dec-subtypingᶠ F G | Left H≮:G = Left (<:-trans-≮: (saturate-<: F) H≮:G)
dec-subtypingᶠ F G | Right H<:G = Right (<:-trans (<:-saturate F) (<:ᵒ-impl-<: (normal-saturate F) G H<:G))
dec-subtypingᶠⁿ T never = Left (witness function (fun-function T) never)
dec-subtypingᶠⁿ T unknown = Right <:-unknown
dec-subtypingᶠⁿ T (U V) = dec-subtypingᶠ T (U V)
dec-subtypingᶠⁿ T (U V) = dec-subtypingᶠ T (U V)
dec-subtypingᶠⁿ T (U V) with dec-subtypingᶠⁿ T U
dec-subtypingᶠⁿ T (U V) | Left (witness t p q) = Left (witness t p (q , fun-¬scalar V T p))
dec-subtypingᶠⁿ T (U V) | Right p = Right (<:-trans p <:--left)
dec-subtypingⁿ never U = Right <:-never
dec-subtypingⁿ unknown unknown = Right <:-refl
dec-subtypingⁿ unknown U with dec-subtypingᶠⁿ (never unknown) U
dec-subtypingⁿ unknown U | Left p = Left (<:-trans-≮: <:-unknown p)
dec-subtypingⁿ unknown U | Right p₁ with dec-subtypingˢⁿ number U
dec-subtypingⁿ unknown U | Right p₁ | Left p = Left (<:-trans-≮: <:-unknown p)
dec-subtypingⁿ unknown U | Right p₁ | Right p₂ with dec-subtypingˢⁿ string U
dec-subtypingⁿ unknown U | Right p₁ | Right p₂ | Left p = Left (<:-trans-≮: <:-unknown p)
dec-subtypingⁿ unknown U | Right p₁ | Right p₂ | Right p₃ with dec-subtypingˢⁿ nil U
dec-subtypingⁿ unknown U | Right p₁ | Right p₂ | Right p₃ | Left p = Left (<:-trans-≮: <:-unknown p)
dec-subtypingⁿ unknown U | Right p₁ | Right p₂ | Right p₃ | Right p₄ with dec-subtypingˢⁿ boolean U
dec-subtypingⁿ unknown U | Right p₁ | Right p₂ | Right p₃ | Right p₄ | Left p = Left (<:-trans-≮: <:-unknown p)
dec-subtypingⁿ unknown U | Right p₁ | Right p₂ | Right p₃ | Right p₄ | Right p₅ = Right (<:-trans <:-everything (<:--lub p₁ (<:--lub p₂ (<:--lub p₃ (<:--lub p₄ p₅)))))
dec-subtypingⁿ (S T) U = dec-subtypingᶠⁿ (S T) U
dec-subtypingⁿ (S T) U = dec-subtypingᶠⁿ (S T) U
dec-subtypingⁿ (S T) U with dec-subtypingⁿ S U | dec-subtypingˢⁿ T U
dec-subtypingⁿ (S T) U | Left p | q = Left (≮:--left p)
dec-subtypingⁿ (S T) U | Right p | Left q = Left (≮:--right q)
dec-subtypingⁿ (S T) U | Right p | Right q = Right (<:--lub p q)
dec-subtyping T U with dec-subtypingⁿ (normal T) (normal U)
dec-subtyping T U | Left p = Left (<:-trans-≮: (normalize-<: T) (≮:-trans-<: p (<:-normalize U)))
dec-subtyping T U | Right p = Right (<:-trans (<:-normalize T) (<:-trans p (normalize-<: U)))
-- As a corollary, for saturated functions
-- <:ᵒ coincides with <:, that is F is a subtype of (S ⇒ T) precisely
-- when one of its overloads is.
<:-impl-<:ᵒ : {F G} FunType F Saturated F FunType G (F <: G) (F <:ᵒ G)
<:-impl-<: {F} {G} Fᶠ Gᶠ F<:G with dec-subtypingˢᶠ Fᶠ Gᶠ
<:-impl-<: {F} {G} Fᶠ Gᶠ F<:G | Left F≮:G = CONTRADICTION (<:-impl-¬≮: F<:G F≮:G)
<:-impl-<: {F} {G} Fᶠ Gᶠ F<:G | Right F<:ᵒG = F<:ᵒG

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module Properties.Equality where
open import Agda.Builtin.Equality using (_≡_; refl)
open import Properties.Contradiction using (¬)
sym : {A : Set} {a b : A} (a b) (b a)
sym refl = refl
trans : {A : Set} {a b c : A} (a b) (b c) (a c)
trans refl refl = refl
cong : {A B : Set} {a b : A} (f : A B) (a b) (f a f b)
cong f refl = refl
subst₁ : {A : Set} {a b : A} (F : A Set) (a b) (F a) (F b)
subst₁ F refl x = x
subst₂ : {A B : Set} {a b : A} {c d : B} (F : A B Set) (a b) (c d) (F a c) (F b d)
subst₂ F refl refl x = x
_≢_ : {A : Set} A A Set
(a b) = ¬(a b)

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module Properties.Functions where
infixr 5 _∘_
_∘_ : {A B C : Set} (B C) (A B) (A C)
(f g) x = f (g x)

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module Properties.Product where
infixr 5 _×_ _,_
record Σ {A : Set} (B : A Set) : Set where
constructor _,_
field fst : A
field snd : B fst
open Σ public
_×_ : Set Set Set
A × B = Σ (λ (a : A) B)

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module Properties.Remember where
open import Agda.Builtin.Equality using (_≡_; refl)
data Remember {A : Set} (a : A) : Set where
_,_ : b (a b) Remember(a)
remember : {A} (a : A) Remember(a)
remember a = (a , refl)

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{-# OPTIONS --rewriting #-}
module Properties.ResolveOverloads where
open import FFI.Data.Either using (Left; Right)
open import Luau.ResolveOverloads using (Resolved; src; srcⁿ; resolve; resolveⁿ; resolveᶠ; resolveˢ; target; yes; no)
open import Luau.Subtyping using (_<:_; _≮:_; Language; ¬Language; witness; scalar; unknown; never; function; function-ok; function-err; function-tgt; function-scalar; function-ok₁; function-ok₂; scalar-scalar; scalar-function; scalar-function-ok; scalar-function-err; scalar-function-tgt; _,_; left; right)
open import Luau.Type using (Type ; Scalar; _⇒_; _∩_; __; nil; boolean; number; string; unknown; never)
open import Luau.TypeSaturation using (saturate)
open import Luau.TypeNormalization using (normalize)
open import Properties.Contradiction using (CONTRADICTION)
open import Properties.DecSubtyping using (dec-subtyping; dec-subtypingⁿ; <:-impl-<:ᵒ)
open import Properties.Functions using (_∘_)
open import Properties.Subtyping using (<:-refl; <:-trans; <:-trans-≮:; ≮:-trans-<:; <:-∩-left; <:-∩-right; <:-∩-glb; <:-impl-¬≮:; <:-unknown; <:-function; function-≮:-never; <:-never; unknown-≮:-function; scalar-≮:-function; ≮:--right; scalar-≮:-never; <:--left; <:--right; <:-impl-⊇; language-comp)
open import Properties.TypeNormalization using (Normal; FunType; normal; _⇒_; _∩_; __; never; unknown; <:-normalize; normalize-<:; fun-≮:-never; unknown-≮:-fun; scalar-≮:-fun)
open import Properties.TypeSaturation using (Overloads; Saturated; _⊆ᵒ_; _<:ᵒ_; normal-saturate; saturated; <:-saturate; saturate-<:; defn; here; left; right)
-- Properties of src
function-err-srcⁿ : {T t} (FunType T) (¬Language (srcⁿ T) t) Language T (function-err t)
function-err-srcⁿ (S T) p = function-err p
function-err-srcⁿ (S T) (p₁ , p₂) = (function-err-srcⁿ S p₁ , function-err-srcⁿ T p₂)
¬function-err-srcᶠ : {T t} (FunType T) (Language (srcⁿ T) t) ¬Language T (function-err t)
¬function-err-srcᶠ (S T) p = function-err p
¬function-err-srcᶠ (S T) (left p) = left (¬function-err-srcᶠ S p)
¬function-err-srcᶠ (S T) (right p) = right (¬function-err-srcᶠ T p)
¬function-err-srcⁿ : {T t} (Normal T) (Language (srcⁿ T) t) ¬Language T (function-err t)
¬function-err-srcⁿ never p = never
¬function-err-srcⁿ unknown (scalar ())
¬function-err-srcⁿ (S T) p = function-err p
¬function-err-srcⁿ (S T) (left p) = left (¬function-err-srcᶠ S p)
¬function-err-srcⁿ (S T) (right p) = right (¬function-err-srcᶠ T p)
¬function-err-srcⁿ (S T) (scalar ())
¬function-err-src : {T t} (Language (src T) t) ¬Language T (function-err t)
¬function-err-src {T = S T} p = function-err p
¬function-err-src {T = nil} p = scalar-function-err nil
¬function-err-src {T = never} p = never
¬function-err-src {T = unknown} (scalar ())
¬function-err-src {T = boolean} p = scalar-function-err boolean
¬function-err-src {T = number} p = scalar-function-err number
¬function-err-src {T = string} p = scalar-function-err string
¬function-err-src {T = S T} p = <:-impl-⊇ (<:-normalize (S T)) _ (¬function-err-srcⁿ (normal (S T)) p)
¬function-err-src {T = S T} p = <:-impl-⊇ (<:-normalize (S T)) _ (¬function-err-srcⁿ (normal (S T)) p)
src-¬function-errᶠ : {T t} (FunType T) Language T (function-err t) (¬Language (srcⁿ T) t)
src-¬function-errᶠ (S T) (function-err p) = p
src-¬function-errᶠ (S T) (p₁ , p₂) = (src-¬function-errᶠ S p₁ , src-¬function-errᶠ T p₂)
src-¬function-errⁿ : {T t} (Normal T) Language T (function-err t) (¬Language (srcⁿ T) t)
src-¬function-errⁿ unknown p = never
src-¬function-errⁿ (S T) (function-err p) = p
src-¬function-errⁿ (S T) (p₁ , p₂) = (src-¬function-errᶠ S p₁ , src-¬function-errᶠ T p₂)
src-¬function-errⁿ (S T) p = never
src-¬function-err : {T t} Language T (function-err t) (¬Language (src T) t)
src-¬function-err {T = S T} (function-err p) = p
src-¬function-err {T = unknown} p = never
src-¬function-err {T = S T} p = src-¬function-errⁿ (normal (S T)) (<:-normalize (S T) _ p)
src-¬function-err {T = S T} p = src-¬function-errⁿ (normal (S T)) (<:-normalize (S T) _ p)
fun-¬scalar : {S T} (s : Scalar S) FunType T ¬Language T (scalar s)
fun-¬scalar s (S T) = function-scalar s
fun-¬scalar s (S T) = left (fun-¬scalar s S)
¬fun-scalar : {S T t} (s : Scalar S) FunType T Language T t ¬Language S t
¬fun-scalar s (S T) function = scalar-function s
¬fun-scalar s (S T) (function-ok₁ p) = scalar-function-ok s
¬fun-scalar s (S T) (function-ok₂ p) = scalar-function-ok s
¬fun-scalar s (S T) (function-err p) = scalar-function-err s
¬fun-scalar s (S T) (function-tgt p) = scalar-function-tgt s
¬fun-scalar s (S T) (p₁ , p₂) = ¬fun-scalar s T p₂
fun-function : {T} FunType T Language T function
fun-function (S T) = function
fun-function (S T) = (fun-function S , fun-function T)
srcⁿ-¬scalar : {S T t} (s : Scalar S) Normal T Language T (scalar s) (¬Language (srcⁿ T) t)
srcⁿ-¬scalar s never (scalar ())
srcⁿ-¬scalar s unknown p = never
srcⁿ-¬scalar s (S T) (scalar ())
srcⁿ-¬scalar s (S T) (p₁ , p₂) = CONTRADICTION (language-comp (scalar s) (fun-¬scalar s S) p₁)
srcⁿ-¬scalar s (S T) p = never
src-¬scalar : {S T t} (s : Scalar S) Language T (scalar s) (¬Language (src T) t)
src-¬scalar {T = nil} s p = never
src-¬scalar {T = T U} s (scalar ())
src-¬scalar {T = never} s (scalar ())
src-¬scalar {T = unknown} s p = never
src-¬scalar {T = boolean} s p = never
src-¬scalar {T = number} s p = never
src-¬scalar {T = string} s p = never
src-¬scalar {T = T U} s p = srcⁿ-¬scalar s (normal (T U)) (<:-normalize (T U) (scalar s) p)
src-¬scalar {T = T U} s p = srcⁿ-¬scalar s (normal (T U)) (<:-normalize (T U) (scalar s) p)
srcⁿ-unknown-≮: : {T U} (Normal U) (T ≮: srcⁿ U) (U ≮: (T unknown))
srcⁿ-unknown-≮: never (witness t p q) = CONTRADICTION (language-comp t q unknown)
srcⁿ-unknown-≮: unknown (witness t p q) = witness (function-err t) unknown (function-err p)
srcⁿ-unknown-≮: (U V) (witness t p q) = witness (function-err t) (function-err q) (function-err p)
srcⁿ-unknown-≮: (U V) (witness t p q) = witness (function-err t) (function-err-srcⁿ (U V) q) (function-err p)
srcⁿ-unknown-≮: (U V) (witness t p q) = witness (scalar V) (right (scalar V)) (function-scalar V)
src-unknown-≮: : {T U} (T ≮: src U) (U ≮: (T unknown))
src-unknown-≮: {U = nil} (witness t p q) = witness (scalar nil) (scalar nil) (function-scalar nil)
src-unknown-≮: {U = T U} (witness t p q) = witness (function-err t) (function-err q) (function-err p)
src-unknown-≮: {U = never} (witness t p q) = CONTRADICTION (language-comp t q unknown)
src-unknown-≮: {U = unknown} (witness t p q) = witness (function-err t) unknown (function-err p)
src-unknown-≮: {U = boolean} (witness t p q) = witness (scalar boolean) (scalar boolean) (function-scalar boolean)
src-unknown-≮: {U = number} (witness t p q) = witness (scalar number) (scalar number) (function-scalar number)
src-unknown-≮: {U = string} (witness t p q) = witness (scalar string) (scalar string) (function-scalar string)
src-unknown-≮: {U = T U} p = <:-trans-≮: (normalize-<: (T U)) (srcⁿ-unknown-≮: (normal (T U)) p)
src-unknown-≮: {U = T U} p = <:-trans-≮: (normalize-<: (T U)) (srcⁿ-unknown-≮: (normal (T U)) p)
unknown-src-≮: : {S T U} (U ≮: S) (T ≮: (U unknown)) (U ≮: src T)
unknown-src-≮: (witness t x x₁) (witness (scalar s) p (function-scalar s)) = witness t x (src-¬scalar s p)
unknown-src-≮: r (witness (function-ok s .(scalar s₁)) p (function-ok x (scalar-scalar s₁ () x₂)))
unknown-src-≮: r (witness (function-ok s .function) p (function-ok x (scalar-function ())))
unknown-src-≮: r (witness (function-ok s .(function-ok _ _)) p (function-ok x (scalar-function-ok ())))
unknown-src-≮: r (witness (function-ok s .(function-err _)) p (function-ok x (scalar-function-err ())))
unknown-src-≮: r (witness (function-err t) p (function-err q)) = witness t q (src-¬function-err p)
unknown-src-≮: r (witness (function-tgt t) p (function-tgt (scalar-function-tgt ())))
-- Properties of resolve
resolveˢ-<:-⇒ : {F V U} (FunType F) (Saturated F) (FunType (V U)) (r : Resolved F V) (F <: (V U)) (target r <: U)
resolveˢ-<:-⇒ Fᶠ V⇒Uᶠ r F<:V⇒U with <:-impl-<:ᵒ Fᶠ V⇒Uᶠ F<:V⇒U here
resolveˢ-<:-⇒ Fᶠ V⇒Uᶠ (yes V<:Sʳ tgtʳ) F<:V⇒U | defn o o₁ o₂ = <:-trans (tgtʳ o o₁) o₂
resolveˢ-<:-⇒ Fᶠ V⇒Uᶠ (no tgtʳ) F<:V⇒U | defn o o₁ o₂ = CONTRADICTION (<:-impl-¬≮: o₁ (tgtʳ o))
resolveⁿ-<:-⇒ : {F V U} (Fⁿ : Normal F) (Vⁿ : Normal V) (Uⁿ : Normal U) (F <: (V U)) (resolveⁿ Fⁿ Vⁿ <: U)
resolveⁿ-<:-⇒ (Sⁿ Tⁿ) Vⁿ Uⁿ F<:V⇒U = resolveˢ-<:-⇒ (normal-saturate (Sⁿ Tⁿ)) (saturated (Sⁿ Tⁿ)) (Vⁿ Uⁿ) (resolveˢ (normal-saturate (Sⁿ Tⁿ)) (saturated (Sⁿ Tⁿ)) Vⁿ (λ o o)) F<:V⇒U
resolveⁿ-<:-⇒ (Fⁿ Gⁿ) Vⁿ Uⁿ F<:V⇒U = resolveˢ-<:-⇒ (normal-saturate (Fⁿ Gⁿ)) (saturated (Fⁿ Gⁿ)) (Vⁿ Uⁿ) (resolveˢ (normal-saturate (Fⁿ Gⁿ)) (saturated (Fⁿ Gⁿ)) Vⁿ (λ o o)) (<:-trans (saturate-<: (Fⁿ Gⁿ)) F<:V⇒U)
resolveⁿ-<:-⇒ (Sⁿ ) Vⁿ Uⁿ F<:V⇒U = CONTRADICTION (<:-impl-¬≮: F<:V⇒U (<:-trans-≮: <:--right (scalar-≮:-function )))
resolveⁿ-<:-⇒ never Vⁿ Uⁿ F<:V⇒U = <:-never
resolveⁿ-<:-⇒ unknown Vⁿ Uⁿ F<:V⇒U = CONTRADICTION (<:-impl-¬≮: F<:V⇒U unknown-≮:-function)
resolve-<:-⇒ : {F V U} (F <: (V U)) (resolve F V <: U)
resolve-<:-⇒ {F} {V} {U} F<:V⇒U = <:-trans (resolveⁿ-<:-⇒ (normal F) (normal V) (normal U) (<:-trans (normalize-<: F) (<:-trans F<:V⇒U (<:-normalize (V U))))) (normalize-<: U)
resolve-≮:-⇒ : {F V U} (resolve F V ≮: U) (F ≮: (V U))
resolve-≮:-⇒ {F} {V} {U} FV≮:U with dec-subtyping F (V U)
resolve-≮:-⇒ {F} {V} {U} FV≮:U | Left F≮:V⇒U = F≮:V⇒U
resolve-≮:-⇒ {F} {V} {U} FV≮:U | Right F<:V⇒U = CONTRADICTION (<:-impl-¬≮: (resolve-<:-⇒ F<:V⇒U) FV≮:U)
<:-resolveˢ-⇒ : {S T V} (r : Resolved (S T) V) (V <: S) T <: target r
<:-resolveˢ-⇒ (yes S T here _ _) V<:S = <:-refl
<:-resolveˢ-⇒ (no _) V<:S = <:-unknown
<:-resolveⁿ-⇒ : {S T V} (Sⁿ : Normal S) (Tⁿ : Normal T) (Vⁿ : Normal V) (V <: S) T <: resolveⁿ (Sⁿ Tⁿ) Vⁿ
<:-resolveⁿ-⇒ Sⁿ Tⁿ Vⁿ V<:S = <:-resolveˢ-⇒ (resolveˢ (Sⁿ Tⁿ) (saturated (Sⁿ Tⁿ)) Vⁿ (λ o o)) V<:S
<:-resolve-⇒ : {S T V} (V <: S) T <: resolve (S T) V
<:-resolve-⇒ {S} {T} {V} V<:S = <:-trans (<:-normalize T) (<:-resolveⁿ-⇒ (normal S) (normal T) (normal V) (<:-trans (normalize-<: V) (<:-trans V<:S (<:-normalize S))))
<:-resolveˢ : {F G V W} (r : Resolved F V) (s : Resolved G W) (F <:ᵒ G) (V <: W) target r <: target s
<:-resolveˢ (yes V<:Sʳ tgtʳ) (yes W<:Sˢ tgtˢ) F<:G V<:W with F<:G
<:-resolveˢ (yes V<:Sʳ tgtʳ) (yes W<:Sˢ tgtˢ) F<:G V<:W | defn o o₁ o₂ = <:-trans (tgtʳ o (<:-trans (<:-trans V<:W W<:Sˢ) o₁)) o₂
<:-resolveˢ (no r) (yes W<:Sˢ tgtˢ) F<:G V<:W with F<:G
<:-resolveˢ (no r) (yes W<:Sˢ tgtˢ) F<:G V<:W | defn o o₁ o₂ = CONTRADICTION (<:-impl-¬≮: (<:-trans V<:W (<:-trans W<:Sˢ o₁)) (r o))
<:-resolveˢ r (no s) F<:G V<:W = <:-unknown
<:-resolveᶠ : {F G V W} (Fᶠ : FunType F) (Gᶠ : FunType G) (Vⁿ : Normal V) (Wⁿ : Normal W) (F <: G) (V <: W) resolveᶠ Fᶠ Vⁿ <: resolveᶠ Gᶠ Wⁿ
<:-resolveᶠ Fᶠ Gᶠ Vⁿ Wⁿ F<:G V<:W = <:-resolveˢ
(resolveˢ (normal-saturate Fᶠ) (saturated Fᶠ) Vⁿ (λ o o))
(resolveˢ (normal-saturate Gᶠ) (saturated Gᶠ) Wⁿ (λ o o))
(<:-impl-<:ᵒ (normal-saturate Fᶠ) (saturated Fᶠ) (normal-saturate Gᶠ) (<:-trans (saturate-<: Fᶠ) (<:-trans F<:G (<:-saturate Gᶠ))))
V<:W
<:-resolveⁿ : {F G V W} (Fⁿ : Normal F) (Gⁿ : Normal G) (Vⁿ : Normal V) (Wⁿ : Normal W) (F <: G) (V <: W) resolveⁿ Fⁿ Vⁿ <: resolveⁿ Gⁿ Wⁿ
<:-resolveⁿ (Rⁿ Sⁿ) (Tⁿ Uⁿ) Vⁿ Wⁿ F<:G V<:W = <:-resolveᶠ (Rⁿ Sⁿ) (Tⁿ Uⁿ) Vⁿ Wⁿ F<:G V<:W
<:-resolveⁿ (Rⁿ Sⁿ) (Gⁿ Hⁿ) Vⁿ Wⁿ F<:G V<:W = <:-resolveᶠ (Rⁿ Sⁿ) (Gⁿ Hⁿ) Vⁿ Wⁿ F<:G V<:W
<:-resolveⁿ (Eⁿ Fⁿ) (Tⁿ Uⁿ) Vⁿ Wⁿ F<:G V<:W = <:-resolveᶠ (Eⁿ Fⁿ) (Tⁿ Uⁿ) Vⁿ Wⁿ F<:G V<:W
<:-resolveⁿ (Eⁿ Fⁿ) (Gⁿ Hⁿ) Vⁿ Wⁿ F<:G V<:W = <:-resolveᶠ (Eⁿ Fⁿ) (Gⁿ Hⁿ) Vⁿ Wⁿ F<:G V<:W
<:-resolveⁿ (Fⁿ ) (Tⁿ Uⁿ) Vⁿ Wⁿ F<:G V<:W = CONTRADICTION (<:-impl-¬≮: F<:G (≮:--right (scalar-≮:-function )))
<:-resolveⁿ unknown (Tⁿ Uⁿ) Vⁿ Wⁿ F<:G V<:W = CONTRADICTION (<:-impl-¬≮: F<:G unknown-≮:-function)
<:-resolveⁿ (Fⁿ ) (Gⁿ Hⁿ) Vⁿ Wⁿ F<:G V<:W = CONTRADICTION (<:-impl-¬≮: F<:G (≮:--right (scalar-≮:-fun (Gⁿ Hⁿ) )))
<:-resolveⁿ unknown (Gⁿ Hⁿ) Vⁿ Wⁿ F<:G V<:W = CONTRADICTION (<:-impl-¬≮: F<:G (unknown-≮:-fun (Gⁿ Hⁿ)))
<:-resolveⁿ (Rⁿ Sⁿ) never Vⁿ Wⁿ F<:G V<:W = CONTRADICTION (<:-impl-¬≮: F<:G (fun-≮:-never (Rⁿ Sⁿ)))
<:-resolveⁿ (Eⁿ Fⁿ) never Vⁿ Wⁿ F<:G V<:W = CONTRADICTION (<:-impl-¬≮: F<:G (fun-≮:-never (Eⁿ Fⁿ)))
<:-resolveⁿ (Fⁿ ) never Vⁿ Wⁿ F<:G V<:W = CONTRADICTION (<:-impl-¬≮: F<:G (≮:--right (scalar-≮:-never )))
<:-resolveⁿ unknown never Vⁿ Wⁿ F<:G V<:W = F<:G
<:-resolveⁿ never Gⁿ Vⁿ Wⁿ F<:G V<:W = <:-never
<:-resolveⁿ Fⁿ (Gⁿ ) Vⁿ Wⁿ F<:G V<:W = <:-unknown
<:-resolveⁿ Fⁿ unknown Vⁿ Wⁿ F<:G V<:W = <:-unknown
<:-resolve : {F G V W} (F <: G) (V <: W) resolve F V <: resolve G W
<:-resolve {F} {G} {V} {W} F<:G V<:W = <:-resolveⁿ (normal F) (normal G) (normal V) (normal W)
(<:-trans (normalize-<: F) (<:-trans F<:G (<:-normalize G)))
(<:-trans (normalize-<: V) (<:-trans V<:W (<:-normalize W)))

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{-# OPTIONS --rewriting #-}
module Properties.Step where
open import Agda.Builtin.Equality using (_≡_; refl)
open import Agda.Builtin.Float using (primFloatPlus; primFloatMinus; primFloatTimes; primFloatDiv; primFloatEquality; primFloatLess)
open import Agda.Builtin.Bool using (true; false)
open import Agda.Builtin.String using (primStringAppend)
open import FFI.Data.Maybe using (just; nothing)
open import Luau.Heap using (Heap; _[_]; alloc; ok; function_is_end)
open import Luau.Syntax using (Block; Expr; nil; var; val; addr; bool; function_is_end; block_is_end; _$_; local_←_; return; done; _∙_; name; fun; arg; number; binexp; +; -; *; /; <; >; <=; >=; ==; ~=; ··; string)
open import Luau.OpSem using (_⟦_⟧_⟶_; _⊢_⟶ᴱ_⊣_; _⊢_⟶ᴮ_⊣_; app₁ ; app₂ ; beta; function; block; return; done; local; subst; binOp₀; binOp₁; binOp₂; +; -; *; /; <; >; <=; >=; ==; ~=; ··; evalEqOp; evalNeqOp)
open import Luau.RuntimeError using (BinOpError; RuntimeErrorᴱ; RuntimeErrorᴮ; FunctionMismatch; BinOpMismatch₁; BinOpMismatch₂; UnboundVariable; SEGV; app₁; app₂; block; local; return; bin₁; bin₂; +; -; *; /; <; >; <=; >=; ··)
open import Luau.RuntimeType using (valueType; function; number)
open import Luau.Substitution using (_[_/_]ᴮ)
open import Properties.Remember using (remember; _,_)
open import Utility.Bool using (not; _or_)
data BinOpStepResult v op w : Set where
step : x (v op w x) BinOpStepResult v op w
error₁ : BinOpError op (valueType(v)) BinOpStepResult v op w
error₂ : BinOpError op (valueType(w)) BinOpStepResult v op w
binOpStep : v op w BinOpStepResult v op w
binOpStep nil + w = error₁ (+ (λ ()))
binOpStep (addr a) + w = error₁ (+ (λ ()))
binOpStep (number m) + nil = error₂ (+ (λ ()))
binOpStep (number m) + (addr a) = error₂ (+ (λ ()))
binOpStep (number m) + (number n) = step (number (primFloatPlus m n)) (+ m n)
binOpStep (number m) + (bool b) = error₂ (+ (λ ()))
binOpStep (number m) + (string x) = error₂ (+ (λ ()))
binOpStep (number m) - (string x) = error₂ (- (λ ()))
binOpStep (number m) * (string x) = error₂ (* (λ ()))
binOpStep (number m) / (string x) = error₂ (/ (λ ()))
binOpStep (number m) < (string x) = error₂ (< (λ ()))
binOpStep (number m) > (string x) = error₂ (> (λ ()))
binOpStep (number m) == (string x) = step (bool false) (== (number m) (string x))
binOpStep (number m) ~= (string x) = step (bool true) (~= (number m) (string x))
binOpStep (number m) <= (string x) = error₂ (<= (λ ()))
binOpStep (number m) >= (string x) = error₂ (>= (λ ()))
binOpStep (bool b) + w = error₁ (+ (λ ()))
binOpStep nil - w = error₁ (- (λ ()))
binOpStep (addr a) - w = error₁ (- (λ ()))
binOpStep (number x) - nil = error₂ (- (λ ()))
binOpStep (number x) - (addr a) = error₂ (- (λ ()))
binOpStep (number x) - (number n) = step (number (primFloatMinus x n)) (- x n)
binOpStep (number x) - (bool b) = error₂ (- (λ ()))
binOpStep (bool b) - w = error₁ (- (λ ()))
binOpStep nil * w = error₁ (* (λ ()))
binOpStep (addr a) * w = error₁ (* (λ ()))
binOpStep (number m) * nil = error₂ (* (λ ()))
binOpStep (number m) * (addr a) = error₂ (* (λ ()))
binOpStep (number m) * (number n) = step (number (primFloatDiv m n)) (* m n)
binOpStep (number m) * (bool b) = error₂ (* (λ ()))
binOpStep (bool b) * w = error₁ (* (λ ()))
binOpStep nil / w = error₁ (/ (λ ()))
binOpStep (addr a) / w = error₁ (/ (λ ()))
binOpStep (number m) / nil = error₂ (/ (λ ()))
binOpStep (number m) / (addr a) = error₂ (/ (λ ()))
binOpStep (number m) / (number n) = step (number (primFloatTimes m n)) (/ m n)
binOpStep (number m) / (bool b) = error₂ (/ (λ ()))
binOpStep (bool b) / w = error₁ (/ (λ ()))
binOpStep nil < w = error₁ (< (λ ()))
binOpStep (addr a) < w = error₁ (< (λ ()))
binOpStep (number m) < nil = error₂ (< (λ ()))
binOpStep (number m) < (addr a) = error₂ (< (λ ()))
binOpStep (number m) < (number n) = step (bool (primFloatLess m n)) (< m n)
binOpStep (number m) < (bool b) = error₂ (< (λ ()))
binOpStep (bool b) < w = error₁ (< (λ ()))
binOpStep nil > w = error₁ (> (λ ()))
binOpStep (addr a) > w = error₁ (> (λ ()))
binOpStep (number m) > nil = error₂ (> (λ ()))
binOpStep (number m) > (addr a) = error₂ (> (λ ()))
binOpStep (number m) > (number n) = step (bool (primFloatLess n m)) (> m n)
binOpStep (number m) > (bool b) = error₂ (> (λ ()))
binOpStep (bool b) > w = error₁ (> (λ ()))
binOpStep v == w = step (bool (evalEqOp v w)) (== v w)
binOpStep v ~= w = step (bool (evalNeqOp v w)) (~= v w)
binOpStep nil <= w = error₁ (<= (λ ()))
binOpStep (addr a) <= w = error₁ (<= (λ ()))
binOpStep (number m) <= nil = error₂ (<= (λ ()))
binOpStep (number m) <= (addr a) = error₂ (<= (λ ()))
binOpStep (number m) <= (number n) = step (bool (primFloatLess m n or primFloatEquality m n)) (<= m n)
binOpStep (number m) <= (bool b) = error₂ (<= (λ ()))
binOpStep (bool b) <= w = error₁ (<= (λ ()))
binOpStep nil >= w = error₁ (>= (λ ()))
binOpStep (addr a) >= w = error₁ (>= (λ ()))
binOpStep (number m) >= nil = error₂ (>= (λ ()))
binOpStep (number m) >= (addr a) = error₂ (>= (λ ()))
binOpStep (number m) >= (number n) = step (bool (primFloatLess n m or primFloatEquality m n)) (>= m n)
binOpStep (number m) >= (bool b) = error₂ (>= (λ ()))
binOpStep (bool b) >= w = error₁ (>= (λ ()))
binOpStep (string x) + w = error₁ (+ (λ ()))
binOpStep (string x) - w = error₁ (- (λ ()))
binOpStep (string x) * w = error₁ (* (λ ()))
binOpStep (string x) / w = error₁ (/ (λ ()))
binOpStep (string x) < w = error₁ (< (λ ()))
binOpStep (string x) > w = error₁ (> (λ ()))
binOpStep (string x) <= w = error₁ (<= (λ ()))
binOpStep (string x) >= w = error₁ (>= (λ ()))
binOpStep nil ·· y = error₁ (·· (λ ()))
binOpStep (addr x) ·· y = error₁ (BinOpError.·· (λ ()))
binOpStep (number x) ·· y = error₁ (BinOpError.·· (λ ()))
binOpStep (bool x) ·· y = error₁ (BinOpError.·· (λ ()))
binOpStep (string x) ·· nil = error₂ (·· (λ ()))
binOpStep (string x) ·· (addr y) = error₂ (·· (λ ()))
binOpStep (string x) ·· (number y) = error₂ (·· (λ ()))
binOpStep (string x) ·· (bool y) = error₂ (·· (λ ()))
binOpStep (string x) ·· (string y) = step (string (primStringAppend x y)) (·· x y)
data StepResultᴮ {a} (H : Heap a) (B : Block a) : Set
data StepResultᴱ {a} (H : Heap a) (M : Expr a) : Set
data StepResultᴮ H B where
step : H B (H B ⟶ᴮ B H) StepResultᴮ H B
return : v {B} (B (return (val v) B)) StepResultᴮ H B
done : (B done) StepResultᴮ H B
error : (RuntimeErrorᴮ H B) StepResultᴮ H B
data StepResultᴱ H M where
step : H M (H M ⟶ᴱ M H) StepResultᴱ H M
value : V (M val V) StepResultᴱ H M
error : (RuntimeErrorᴱ H M) StepResultᴱ H M
stepᴱ : {a} H M StepResultᴱ {a} H M
stepᴮ : {a} H B StepResultᴮ {a} H B
stepᴱ H (val v) = value v refl
stepᴱ H (var x) = error UnboundVariable
stepᴱ H (M $ N) with stepᴱ H M
stepᴱ H (M $ N) | step H M D = step H (M $ N) (app₁ D)
stepᴱ H (_ $ N) | value v refl with stepᴱ H N
stepᴱ H (_ $ N) | value v refl | step H N s = step H (val v $ N) (app₂ v s)
stepᴱ H (_ $ _) | value (addr a) refl | value w refl with remember (H [ a ])
stepᴱ H (_ $ _) | value (addr a) refl | value w refl | (nothing , p) = error (app₁ (SEGV p))
stepᴱ H (_ $ _) | value (addr a) refl | value w refl | (just(function F is B end) , p) = step H (block (fun F) is B [ w / name (arg F) ]ᴮ end) (beta function F is B end w refl p)
stepᴱ H (_ $ _) | value nil refl | value w refl = error (FunctionMismatch nil w (λ ()))
stepᴱ H (_ $ _) | value (number m) refl | value w refl = error (FunctionMismatch (number m) w (λ ()))
stepᴱ H (_ $ _) | value (bool b) refl | value w refl = error (FunctionMismatch (bool b) w (λ ()))
stepᴱ H (_ $ _) | value (string x) refl | value w refl = error (FunctionMismatch (string x) w (λ ()))
stepᴱ H (M $ N) | value V p | error E = error (app₂ E)
stepᴱ H (M $ N) | error E = error (app₁ E)
stepᴱ H (block b is B end) with stepᴮ H B
stepᴱ H (block b is B end) | step H B D = step H (block b is B end) (block D)
stepᴱ H (block b is (return _ B) end) | return v refl = step H (val v) (return v)
stepᴱ H (block b is done end) | done refl = step H (val nil) done
stepᴱ H (block b is B end) | error E = error (block E)
stepᴱ H (function F is C end) with alloc H (function F is C end)
stepᴱ H function F is C end | ok a H p = step H (val (addr a)) (function a p)
stepᴱ H (binexp M op N) with stepᴱ H M
stepᴱ H (binexp M op N) | step H M s = step H (binexp M op N) (binOp₁ s)
stepᴱ H (binexp M op N) | error E = error (bin₁ E)
stepᴱ H (binexp M op N) | value v refl with stepᴱ H N
stepᴱ H (binexp M op N) | value v refl | step H N s = step H (binexp (val v) op N) (binOp₂ s)
stepᴱ H (binexp M op N) | value v refl | error E = error (bin₂ E)
stepᴱ H (binexp M op N) | value v refl | value w refl with binOpStep v op w
stepᴱ H (binexp M op N) | value v refl | value w refl | step x p = step H (val x) (binOp₀ p)
stepᴱ H (binexp M op N) | value v refl | value w refl | error₁ E = error (BinOpMismatch₁ v w E)
stepᴱ H (binexp M op N) | value v refl | value w refl | error₂ E = error (BinOpMismatch₂ v w E)
stepᴮ H (function F is C end B) with alloc H (function F is C end)
stepᴮ H (function F is C end B) | ok a H p = step H (B [ addr a / name (fun F) ]ᴮ) (function a p)
stepᴮ H (local x M B) with stepᴱ H M
stepᴮ H (local x M B) | step H M D = step H (local x M B) (local D)
stepᴮ H (local x _ B) | value v refl = step H (B [ v / name x ]ᴮ) (subst v)
stepᴮ H (local x M B) | error E = error (local E)
stepᴮ H (return M B) with stepᴱ H M
stepᴮ H (return M B) | step H M D = step H (return M B) (return D)
stepᴮ H (return _ B) | value V refl = return V refl
stepᴮ H (return M B) | error E = error (return E)
stepᴮ H done = done refl

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{-# OPTIONS --rewriting #-}
module Properties.StrictMode where
import Agda.Builtin.Equality.Rewrite
open import Agda.Builtin.Equality using (_≡_; refl)
open import FFI.Data.Either using (Either; Left; Right; mapL; mapR; mapLR; swapLR; cond)
open import FFI.Data.Maybe using (Maybe; just; nothing)
open import Luau.Heap using (Heap; Object; function_is_end; defn; alloc; ok; next; lookup-not-allocated) renaming (_≡_⊕_↦_ to _≡ᴴ_⊕_↦_; _[_] to _[_]ᴴ; to ∅ᴴ)
open import Luau.ResolveOverloads using (src; resolve)
open import Luau.StrictMode using (Warningᴱ; Warningᴮ; Warningᴼ; Warningᴴ; UnallocatedAddress; UnboundVariable; FunctionCallMismatch; app₁; app₂; BinOpMismatch₁; BinOpMismatch₂; bin₁; bin₂; BlockMismatch; block₁; return; LocalVarMismatch; local₁; local₂; FunctionDefnMismatch; function₁; function₂; heap; expr; block; addr)
open import Luau.Substitution using (_[_/_]ᴮ; _[_/_]ᴱ; _[_/_]ᴮunless_; var_[_/_]ᴱwhenever_)
open import Luau.Subtyping using (_<:_; _≮:_; witness; unknown; never; scalar; function; scalar-function; scalar-function-ok; scalar-function-err; scalar-scalar; function-scalar; function-ok; function-err; left; right; _,_; Tree; Language; ¬Language)
open import Luau.Syntax using (Expr; yes; var; val; var_∈_; _⟨_⟩∈_; _$_; addr; number; bool; string; binexp; nil; function_is_end; block_is_end; done; return; local_←_; _∙_; fun; arg; name; ==; ~=)
open import Luau.Type using (Type; nil; number; boolean; string; _⇒_; never; unknown; _∩_; __; _≡ᵀ_; _≡ᴹᵀ_)
open import Luau.TypeCheck using (_⊢ᴮ_∈_; _⊢ᴱ_∈_; _⊢ᴴᴮ_▷_∈_; _⊢ᴴᴱ_▷_∈_; nil; var; addr; app; function; block; done; return; local; orUnknown; srcBinOp; tgtBinOp)
open import Luau.Var using (_≡ⱽ_)
open import Luau.Addr using (_≡ᴬ_)
open import Luau.VarCtxt using (VarCtxt; ∅; _⋒_; _↦_; _⊕_↦_; _⊝_; ⊕-lookup-miss; ⊕-swap; ⊕-over) renaming (_[_] to _[_]ⱽ)
open import Luau.VarCtxt using (VarCtxt; )
open import Properties.Remember using (remember; _,_)
open import Properties.Equality using (_≢_; sym; cong; trans; subst₁)
open import Properties.Dec using (Dec; yes; no)
open import Properties.Contradiction using (CONTRADICTION; ¬)
open import Properties.Functions using (_∘_)
open import Properties.DecSubtyping using (dec-subtyping)
open import Properties.Subtyping using (unknown-≮:; ≡-trans-≮:; ≮:-trans-≡; ≮:-trans; ≮:-refl; scalar-≢-impl-≮:; function-≮:-scalar; scalar-≮:-function; function-≮:-never; unknown-≮:-scalar; scalar-≮:-never; unknown-≮:-never; <:-refl; <:-unknown; <:-impl-¬≮:)
open import Properties.ResolveOverloads using (src-unknown-≮:; unknown-src-≮:; <:-resolve; resolve-<:-⇒; <:-resolve-⇒)
open import Properties.Subtyping using (unknown-≮:; ≡-trans-≮:; ≮:-trans-≡; ≮:-trans; <:-trans-≮:; ≮:-refl; scalar-≢-impl-≮:; function-≮:-scalar; scalar-≮:-function; function-≮:-never; unknown-≮:-scalar; scalar-≮:-never; unknown-≮:-never; ≡-impl-<:; ≡-trans-<:; <:-trans-≡; ≮:-trans-<:; <:-trans)
open import Properties.TypeCheck using (typeOfᴼ; typeOfᴹᴼ; typeOfⱽ; typeOfᴱ; typeOfᴮ; typeCheckᴱ; typeCheckᴮ; typeCheckᴼ; typeCheckᴴ)
open import Luau.OpSem using (_⟦_⟧_⟶_; _⊢_⟶*_⊣_; _⊢_⟶ᴮ_⊣_; _⊢_⟶ᴱ_⊣_; app₁; app₂; function; beta; return; block; done; local; subst; binOp₀; binOp₁; binOp₂; refl; step; +; -; *; /; <; >; ==; ~=; <=; >=; ··)
open import Luau.RuntimeError using (BinOpError; RuntimeErrorᴱ; RuntimeErrorᴮ; FunctionMismatch; BinOpMismatch₁; BinOpMismatch₂; UnboundVariable; SEGV; app₁; app₂; bin₁; bin₂; block; local; return; +; -; *; /; <; >; <=; >=; ··)
open import Luau.RuntimeType using (RuntimeType; valueType; number; string; boolean; nil; function)
data _⊑_ (H : Heap yes) : Heap yes Set where
refl : (H H)
snoc : {H a O} (H ≡ᴴ H a O) (H H)
rednᴱ⊑ : {H H M M} (H M ⟶ᴱ M H) (H H)
rednᴮ⊑ : {H H B B} (H B ⟶ᴮ B H) (H H)
rednᴱ⊑ (function a p) = snoc p
rednᴱ⊑ (app₁ s) = rednᴱ⊑ s
rednᴱ⊑ (app₂ p s) = rednᴱ⊑ s
rednᴱ⊑ (beta O v p q) = refl
rednᴱ⊑ (block s) = rednᴮ⊑ s
rednᴱ⊑ (return v) = refl
rednᴱ⊑ done = refl
rednᴱ⊑ (binOp₀ p) = refl
rednᴱ⊑ (binOp₁ s) = rednᴱ⊑ s
rednᴱ⊑ (binOp₂ s) = rednᴱ⊑ s
rednᴮ⊑ (local s) = rednᴱ⊑ s
rednᴮ⊑ (subst v) = refl
rednᴮ⊑ (function a p) = snoc p
rednᴮ⊑ (return s) = rednᴱ⊑ s
data LookupResult (H : Heap yes) a V : Set where
just : (H [ a ]ᴴ just V) LookupResult H a V
nothing : (H [ a ]ᴴ nothing) LookupResult H a V
lookup-⊑-nothing : {H H} a (H H) (H [ a ]ᴴ nothing) (H [ a ]ᴴ nothing)
lookup-⊑-nothing {H} a refl p = p
lookup-⊑-nothing {H} a (snoc defn) p with a ≡ᴬ next H
lookup-⊑-nothing {H} a (snoc defn) p | yes refl = refl
lookup-⊑-nothing {H} a (snoc o) p | no q = trans (lookup-not-allocated o q) p
<:-heap-weakeningᴱ : Γ H M {H} (H H) (typeOfᴱ H Γ M <: typeOfᴱ H Γ M)
<:-heap-weakeningᴱ Γ H (var x) h = <:-refl
<:-heap-weakeningᴱ Γ H (val nil) h = <:-refl
<:-heap-weakeningᴱ Γ H (val (addr a)) refl = <:-refl
<:-heap-weakeningᴱ Γ H (val (addr a)) (snoc {a = b} q) with a ≡ᴬ b
<:-heap-weakeningᴱ Γ H (val (addr a)) (snoc {a = a} defn) | yes refl = <:-unknown
<:-heap-weakeningᴱ Γ H (val (addr a)) (snoc {a = b} q) | no r = ≡-impl-<: (sym (cong orUnknown (cong typeOfᴹᴼ (lookup-not-allocated q r))))
<:-heap-weakeningᴱ Γ H (val (number n)) h = <:-refl
<:-heap-weakeningᴱ Γ H (val (bool b)) h = <:-refl
<:-heap-weakeningᴱ Γ H (val (string s)) h = <:-refl
<:-heap-weakeningᴱ Γ H (M $ N) h = <:-resolve (<:-heap-weakeningᴱ Γ H M h) (<:-heap-weakeningᴱ Γ H N h)
<:-heap-weakeningᴱ Γ H (function f var x S ⟩∈ T is B end) h = <:-refl
<:-heap-weakeningᴱ Γ H (block var b T is N end) h = <:-refl
<:-heap-weakeningᴱ Γ H (binexp M op N) h = <:-refl
<:-heap-weakeningᴮ : Γ H B {H} (H H) (typeOfᴮ H Γ B <: typeOfᴮ H Γ B)
<:-heap-weakeningᴮ Γ H (function f var x T ⟩∈ U is C end B) h = <:-heap-weakeningᴮ (Γ f (T U)) H B h
<:-heap-weakeningᴮ Γ H (local var x T M B) h = <:-heap-weakeningᴮ (Γ x T) H B h
<:-heap-weakeningᴮ Γ H (return M B) h = <:-heap-weakeningᴱ Γ H M h
<:-heap-weakeningᴮ Γ H done h = <:-refl
≮:-heap-weakeningᴱ : Γ H M {H U} (H H) (typeOfᴱ H Γ M ≮: U) (typeOfᴱ H Γ M ≮: U)
:-heap-weakeningᴱ Γ H M h p = <:-trans-≮: (<:-heap-weakeningᴱ Γ H M h) p
≮:-heap-weakeningᴮ : Γ H B {H U} (H H) (typeOfᴮ H Γ B ≮: U) (typeOfᴮ H Γ B ≮: U)
:-heap-weakeningᴮ Γ H B h p = <:-trans-≮: (<:-heap-weakeningᴮ Γ H B h) p
binOpPreservation : H {op v w x} (v op w x) (tgtBinOp op typeOfᴱ H (val x))
binOpPreservation H (+ m n) = refl
binOpPreservation H (- m n) = refl
binOpPreservation H (/ m n) = refl
binOpPreservation H (* m n) = refl
binOpPreservation H (< m n) = refl
binOpPreservation H (> m n) = refl
binOpPreservation H (<= m n) = refl
binOpPreservation H (>= m n) = refl
binOpPreservation H (== v w) = refl
binOpPreservation H (~= v w) = refl
binOpPreservation H (·· v w) = refl
<:-substitutivityᴱ : {Γ T} H M v x (typeOfᴱ H (val v) <: T) (typeOfᴱ H Γ (M [ v / x ]ᴱ) <: typeOfᴱ H (Γ x T) M)
<:-substitutivityᴱ-whenever : {Γ T} H v x y (r : Dec(x y)) (typeOfᴱ H (val v) <: T) (typeOfᴱ H Γ (var y [ v / x ]ᴱwhenever r) <: typeOfᴱ H (Γ x T) (var y))
<:-substitutivityᴮ : {Γ T} H B v x (typeOfᴱ H (val v) <: T) (typeOfᴮ H Γ (B [ v / x ]ᴮ) <: typeOfᴮ H (Γ x T) B)
<:-substitutivityᴮ-unless : {Γ T U} H B v x y (r : Dec(x y)) (typeOfᴱ H (val v) <: T) (typeOfᴮ H (Γ y U) (B [ v / x ]ᴮunless r) <: typeOfᴮ H ((Γ x T) y U) B)
<:-substitutivityᴮ-unless-yes : {Γ Γ′} H B v x y (r : x y) (Γ′ Γ) (typeOfᴮ H Γ (B [ v / x ]ᴮunless yes r) <: typeOfᴮ H Γ′ B)
<:-substitutivityᴮ-unless-no : {Γ Γ′ T} H B v x y (r : x y) (Γ′ Γ x T) (typeOfᴱ H (val v) <: T) (typeOfᴮ H Γ (B [ v / x ]ᴮunless no r) <: typeOfᴮ H Γ′ B)
<:-substitutivityᴱ H (var y) v x p = <:-substitutivityᴱ-whenever H v x y (x ≡ⱽ y) p
<:-substitutivityᴱ H (val w) v x p = <:-refl
<:-substitutivityᴱ H (binexp M op N) v x p = <:-refl
<:-substitutivityᴱ H (M $ N) v x p = <:-resolve (<:-substitutivityᴱ H M v x p) (<:-substitutivityᴱ H N v x p)
<:-substitutivityᴱ H (function f var y T ⟩∈ U is B end) v x p = <:-refl
<:-substitutivityᴱ H (block var b T is B end) v x p = <:-refl
<:-substitutivityᴱ-whenever H v x x (yes refl) p = p
<:-substitutivityᴱ-whenever H v x y (no o) p = (≡-impl-<: (cong orUnknown (⊕-lookup-miss x y _ _ o)))
<:-substitutivityᴮ H (function f var y T ⟩∈ U is C end B) v x p = <:-substitutivityᴮ-unless H B v x f (x ≡ⱽ f) p
<:-substitutivityᴮ H (local var y T M B) v x p = <:-substitutivityᴮ-unless H B v x y (x ≡ⱽ y) p
<:-substitutivityᴮ H (return M B) v x p = <:-substitutivityᴱ H M v x p
<:-substitutivityᴮ H done v x p = <:-refl
<:-substitutivityᴮ-unless H B v x y (yes r) p = <:-substitutivityᴮ-unless-yes H B v x y r (⊕-over r)
<:-substitutivityᴮ-unless H B v x y (no r) p = <:-substitutivityᴮ-unless-no H B v x y r (⊕-swap r) p
<:-substitutivityᴮ-unless-yes H B v x y refl refl = <:-refl
<:-substitutivityᴮ-unless-no H B v x y r refl p = <:-substitutivityᴮ H B v x p
≮:-substitutivityᴱ : {Γ T U} H M v x (typeOfᴱ H Γ (M [ v / x ]ᴱ) ≮: U) Either (typeOfᴱ H (Γ x T) M ≮: U) (typeOfᴱ H (val v) ≮: T)
:-substitutivityᴱ {T = T} H M v x p with dec-subtyping (typeOfᴱ H (val v)) T
:-substitutivityᴱ H M v x p | Left q = Right q
:-substitutivityᴱ H M v x p | Right q = Left (<:-trans-≮: (<:-substitutivityᴱ H M v x q) p)
≮:-substitutivityᴮ : {Γ T U} H B v x (typeOfᴮ H Γ (B [ v / x ]ᴮ) ≮: U) Either (typeOfᴮ H (Γ x T) B ≮: U) (typeOfᴱ H (val v) ≮: T)
:-substitutivityᴮ {T = T} H M v x p with dec-subtyping (typeOfᴱ H (val v)) T
:-substitutivityᴮ H M v x p | Left q = Right q
:-substitutivityᴮ H M v x p | Right q = Left (<:-trans-≮: (<:-substitutivityᴮ H M v x q) p)
≮:-substitutivityᴮ-unless : {Γ T U V} H B v x y (r : Dec(x y)) (typeOfᴮ H (Γ y U) (B [ v / x ]ᴮunless r) ≮: V) Either (typeOfᴮ H ((Γ x T) y U) B ≮: V) (typeOfᴱ H (val v) ≮: T)
:-substitutivityᴮ-unless {T = T} H B v x y r p with dec-subtyping (typeOfᴱ H (val v)) T
:-substitutivityᴮ-unless H B v x y r p | Left q = Right q
:-substitutivityᴮ-unless H B v x y r p | Right q = Left (<:-trans-≮: (<:-substitutivityᴮ-unless H B v x y r q) p)
<:-reductionᴱ : H M {H M} (H M ⟶ᴱ M H) Either (typeOfᴱ H M <: typeOfᴱ H M) (Warningᴱ H (typeCheckᴱ H M))
<:-reductionᴮ : H B {H B} (H B ⟶ᴮ B H) Either (typeOfᴮ H B <: typeOfᴮ H B) (Warningᴮ H (typeCheckᴮ H B))
<:-reductionᴱ H (M $ N) (app₁ s) = mapLR (λ p <:-resolve p (<:-heap-weakeningᴱ H N (rednᴱ⊑ s))) app₁ (<:-reductionᴱ H M s)
<:-reductionᴱ H (M $ N) (app₂ q s) = mapLR (λ p <:-resolve (<:-heap-weakeningᴱ H M (rednᴱ⊑ s)) p) app₂ (<:-reductionᴱ H N s)
<:-reductionᴱ H (M $ N) (beta (function f var y S ⟩∈ U is B end) v refl q) with dec-subtyping (typeOfᴱ H (val v)) S
<:-reductionᴱ H (M $ N) (beta (function f var y S ⟩∈ U is B end) v refl q) | Left r = Right (FunctionCallMismatch (≮:-trans-≡ r (cong src (cong orUnknown (cong typeOfᴹᴼ (sym q))))))
<:-reductionᴱ H (M $ N) (beta (function f var y S ⟩∈ U is B end) v refl q) | Right r = Left (<:-trans-≡ (<:-resolve-⇒ r) (cong (λ F resolve F (typeOfᴱ H N)) (cong orUnknown (cong typeOfᴹᴼ (sym q)))))
<:-reductionᴱ H (function f var x T ⟩∈ U is B end) (function a defn) = Left <:-refl
<:-reductionᴱ H (block var b T is B end) (block s) = Left <:-refl
<:-reductionᴱ H (block var b T is return (val v) B end) (return v) with dec-subtyping (typeOfᴱ H (val v)) T
<:-reductionᴱ H (block var b T is return (val v) B end) (return v) | Left p = Right (BlockMismatch p)
<:-reductionᴱ H (block var b T is return (val v) B end) (return v) | Right p = Left p
<:-reductionᴱ H (block var b T is done end) done with dec-subtyping nil T
<:-reductionᴱ H (block var b T is done end) done | Left p = Right (BlockMismatch p)
<:-reductionᴱ H (block var b T is done end) done | Right p = Left p
<:-reductionᴱ H (binexp M op N) (binOp₀ s) = Left (≡-impl-<: (sym (binOpPreservation H s)))
<:-reductionᴱ H (binexp M op N) (binOp₁ s) = Left <:-refl
<:-reductionᴱ H (binexp M op N) (binOp₂ s) = Left <:-refl
<:-reductionᴮ H (function f var x T ⟩∈ U is C end B) (function a defn) = Left (<:-trans (<:-substitutivityᴮ _ B (addr a) f <:-refl) (<:-heap-weakeningᴮ (f (T U)) H B (snoc defn)))
<:-reductionᴮ H (local var x T M B) (local s) = Left (<:-heap-weakeningᴮ (x T) H B (rednᴱ⊑ s))
<:-reductionᴮ H (local var x T M B) (subst v) with dec-subtyping (typeOfᴱ H (val v)) T
<:-reductionᴮ H (local var x T M B) (subst v) | Left p = Right (LocalVarMismatch p)
<:-reductionᴮ H (local var x T M B) (subst v) | Right p = Left (<:-substitutivityᴮ H B v x p)
<:-reductionᴮ H (return M B) (return s) = mapR return (<:-reductionᴱ H M s)
≮:-reductionᴱ : H M {H M T} (H M ⟶ᴱ M H) (typeOfᴱ H M ≮: T) Either (typeOfᴱ H M ≮: T) (Warningᴱ H (typeCheckᴱ H M))
:-reductionᴱ H M s p = mapL (λ q <:-trans-≮: q p) (<:-reductionᴱ H M s)
≮:-reductionᴮ : H B {H B T} (H B ⟶ᴮ B H) (typeOfᴮ H B ≮: T) Either (typeOfᴮ H B ≮: T) (Warningᴮ H (typeCheckᴮ H B))
:-reductionᴮ H B s p = mapL (λ q <:-trans-≮: q p) (<:-reductionᴮ H B s)
reflect-substitutionᴱ : {Γ T} H M v x Warningᴱ H (typeCheckᴱ H Γ (M [ v / x ]ᴱ)) Either (Warningᴱ H (typeCheckᴱ H (Γ x T) M)) (Either (Warningᴱ H (typeCheckᴱ H (val v))) (typeOfᴱ H (val v) ≮: T))
reflect-substitutionᴱ-whenever : {Γ T} H v x y (p : Dec(x y)) Warningᴱ H (typeCheckᴱ H Γ (var y [ v / x ]ᴱwhenever p)) Either (Warningᴱ H (typeCheckᴱ H (Γ x T) (var y))) (Either (Warningᴱ H (typeCheckᴱ H (val v))) (typeOfᴱ H (val v) ≮: T))
reflect-substitutionᴮ : {Γ T} H B v x Warningᴮ H (typeCheckᴮ H Γ (B [ v / x ]ᴮ)) Either (Warningᴮ H (typeCheckᴮ H (Γ x T) B)) (Either (Warningᴱ H (typeCheckᴱ H (val v))) (typeOfᴱ H (val v) ≮: T))
reflect-substitutionᴮ-unless : {Γ T U} H B v x y (r : Dec(x y)) Warningᴮ H (typeCheckᴮ H (Γ y U) (B [ v / x ]ᴮunless r)) Either (Warningᴮ H (typeCheckᴮ H ((Γ x T) y U) B)) (Either (Warningᴱ H (typeCheckᴱ H (val v))) (typeOfᴱ H (val v) ≮: T))
reflect-substitutionᴮ-unless-yes : {Γ Γ′ T} H B v x y (r : x y) (Γ′ Γ) Warningᴮ H (typeCheckᴮ H Γ (B [ v / x ]ᴮunless yes r)) Either (Warningᴮ H (typeCheckᴮ H Γ′ B)) (Either (Warningᴱ H (typeCheckᴱ H (val v))) (typeOfᴱ H (val v) ≮: T))
reflect-substitutionᴮ-unless-no : {Γ Γ′ T} H B v x y (r : x y) (Γ′ Γ x T) Warningᴮ H (typeCheckᴮ H Γ (B [ v / x ]ᴮunless no r)) Either (Warningᴮ H (typeCheckᴮ H Γ′ B)) (Either (Warningᴱ H (typeCheckᴱ H (val v))) (typeOfᴱ H (val v) ≮: T))
reflect-substitutionᴱ H (var y) v x W = reflect-substitutionᴱ-whenever H v x y (x ≡ⱽ y) W
reflect-substitutionᴱ H (val (addr a)) v x (UnallocatedAddress r) = Left (UnallocatedAddress r)
reflect-substitutionᴱ H (M $ N) v x (FunctionCallMismatch p) with ≮:-substitutivityᴱ H N v x p
reflect-substitutionᴱ H (M $ N) v x (FunctionCallMismatch p) | Right W = Right (Right W)
reflect-substitutionᴱ H (M $ N) v x (FunctionCallMismatch p) | Left q with ≮:-substitutivityᴱ H M v x (src-unknown-≮: q)
reflect-substitutionᴱ H (M $ N) v x (FunctionCallMismatch p) | Left q | Left r = Left ((FunctionCallMismatch unknown-src-≮: q) r)
reflect-substitutionᴱ H (M $ N) v x (FunctionCallMismatch p) | Left q | Right W = Right (Right W)
reflect-substitutionᴱ H (M $ N) v x (app₁ W) = mapL app₁ (reflect-substitutionᴱ H M v x W)
reflect-substitutionᴱ H (M $ N) v x (app₂ W) = mapL app₂ (reflect-substitutionᴱ H N v x W)
reflect-substitutionᴱ H (function f var y T ⟩∈ U is B end) v x (FunctionDefnMismatch q) = mapLR FunctionDefnMismatch Right (≮:-substitutivityᴮ-unless H B v x y (x ≡ⱽ y) q)
reflect-substitutionᴱ H (function f var y T ⟩∈ U is B end) v x (function₁ W) = mapL function₁ (reflect-substitutionᴮ-unless H B v x y (x ≡ⱽ y) W)
reflect-substitutionᴱ H (block var b T is B end) v x (BlockMismatch q) = mapLR BlockMismatch Right (≮:-substitutivityᴮ H B v x q)
reflect-substitutionᴱ H (block var b T is B end) v x (block₁ W) = mapL block₁ (reflect-substitutionᴮ H B v x W)
reflect-substitutionᴱ H (binexp M op N) v x (BinOpMismatch₁ q) = mapLR BinOpMismatch₁ Right (≮:-substitutivityᴱ H M v x q)
reflect-substitutionᴱ H (binexp M op N) v x (BinOpMismatch₂ q) = mapLR BinOpMismatch₂ Right (≮:-substitutivityᴱ H N v x q)
reflect-substitutionᴱ H (binexp M op N) v x (bin₁ W) = mapL bin₁ (reflect-substitutionᴱ H M v x W)
reflect-substitutionᴱ H (binexp M op N) v x (bin₂ W) = mapL bin₂ (reflect-substitutionᴱ H N v x W)
reflect-substitutionᴱ-whenever H a x x (yes refl) (UnallocatedAddress p) = Right (Left (UnallocatedAddress p))
reflect-substitutionᴱ-whenever H v x y (no p) (UnboundVariable q) = Left (UnboundVariable (trans (sym (⊕-lookup-miss x y _ _ p)) q))
reflect-substitutionᴮ H (function f var y T ⟩∈ U is C end B) v x (FunctionDefnMismatch q) = mapLR FunctionDefnMismatch Right (≮:-substitutivityᴮ-unless H C v x y (x ≡ⱽ y) q)
reflect-substitutionᴮ H (function f var y T ⟩∈ U is C end B) v x (function₁ W) = mapL function₁ (reflect-substitutionᴮ-unless H C v x y (x ≡ⱽ y) W)
reflect-substitutionᴮ H (function f var y T ⟩∈ U is C end B) v x (function₂ W) = mapL function₂ (reflect-substitutionᴮ-unless H B v x f (x ≡ⱽ f) W)
reflect-substitutionᴮ H (local var y T M B) v x (LocalVarMismatch q) = mapLR LocalVarMismatch Right (≮:-substitutivityᴱ H M v x q)
reflect-substitutionᴮ H (local var y T M B) v x (local₁ W) = mapL local₁ (reflect-substitutionᴱ H M v x W)
reflect-substitutionᴮ H (local var y T M B) v x (local₂ W) = mapL local₂ (reflect-substitutionᴮ-unless H B v x y (x ≡ⱽ y) W)
reflect-substitutionᴮ H (return M B) v x (return W) = mapL return (reflect-substitutionᴱ H M v x W)
reflect-substitutionᴮ-unless H B v x y (yes p) W = reflect-substitutionᴮ-unless-yes H B v x y p (⊕-over p) W
reflect-substitutionᴮ-unless H B v x y (no p) W = reflect-substitutionᴮ-unless-no H B v x y p (⊕-swap p) W
reflect-substitutionᴮ-unless-yes H B v x x refl refl W = Left W
reflect-substitutionᴮ-unless-no H B v x y p refl W = reflect-substitutionᴮ H B v x W
reflect-weakeningᴱ : Γ H M {H} (H H) Warningᴱ H (typeCheckᴱ H Γ M) Warningᴱ H (typeCheckᴱ H Γ M)
reflect-weakeningᴮ : Γ H B {H} (H H) Warningᴮ H (typeCheckᴮ H Γ B) Warningᴮ H (typeCheckᴮ H Γ B)
reflect-weakeningᴱ Γ H (var x) h (UnboundVariable p) = (UnboundVariable p)
reflect-weakeningᴱ Γ H (val (addr a)) h (UnallocatedAddress p) = UnallocatedAddress (lookup-⊑-nothing a h p)
reflect-weakeningᴱ Γ H (M $ N) h (FunctionCallMismatch p) = FunctionCallMismatch (≮:-heap-weakeningᴱ Γ H N h (unknown-src-≮: p (≮:-heap-weakeningᴱ Γ H M h (src-unknown-≮: p))))
reflect-weakeningᴱ Γ H (M $ N) h (app₁ W) = app₁ (reflect-weakeningᴱ Γ H M h W)
reflect-weakeningᴱ Γ H (M $ N) h (app₂ W) = app₂ (reflect-weakeningᴱ Γ H N h W)
reflect-weakeningᴱ Γ H (binexp M op N) h (BinOpMismatch₁ p) = BinOpMismatch₁ (≮:-heap-weakeningᴱ Γ H M h p)
reflect-weakeningᴱ Γ H (binexp M op N) h (BinOpMismatch₂ p) = BinOpMismatch₂ (≮:-heap-weakeningᴱ Γ H N h p)
reflect-weakeningᴱ Γ H (binexp M op N) h (bin₁ W) = bin₁ (reflect-weakeningᴱ Γ H M h W)
reflect-weakeningᴱ Γ H (binexp M op N) h (bin₂ W) = bin₂ (reflect-weakeningᴱ Γ H N h W)
reflect-weakeningᴱ Γ H (function f var y T ⟩∈ U is B end) h (FunctionDefnMismatch p) = FunctionDefnMismatch (≮:-heap-weakeningᴮ (Γ y T) H B h p)
reflect-weakeningᴱ Γ H (function f var y T ⟩∈ U is B end) h (function₁ W) = function₁ (reflect-weakeningᴮ (Γ y T) H B h W)
reflect-weakeningᴱ Γ H (block var b T is B end) h (BlockMismatch p) = BlockMismatch (≮:-heap-weakeningᴮ Γ H B h p)
reflect-weakeningᴱ Γ H (block var b T is B end) h (block₁ W) = block₁ (reflect-weakeningᴮ Γ H B h W)
reflect-weakeningᴮ Γ H (return M B) h (return W) = return (reflect-weakeningᴱ Γ H M h W)
reflect-weakeningᴮ Γ H (local var y T M B) h (LocalVarMismatch p) = LocalVarMismatch (≮:-heap-weakeningᴱ Γ H M h p)
reflect-weakeningᴮ Γ H (local var y T M B) h (local₁ W) = local₁ (reflect-weakeningᴱ Γ H M h W)
reflect-weakeningᴮ Γ H (local var y T M B) h (local₂ W) = local₂ (reflect-weakeningᴮ (Γ y T) H B h W)
reflect-weakeningᴮ Γ H (function f var x T ⟩∈ U is C end B) h (FunctionDefnMismatch p) = FunctionDefnMismatch (≮:-heap-weakeningᴮ (Γ x T) H C h p)
reflect-weakeningᴮ Γ H (function f var x T ⟩∈ U is C end B) h (function₁ W) = function₁ (reflect-weakeningᴮ (Γ x T) H C h W)
reflect-weakeningᴮ Γ H (function f var x T ⟩∈ U is C end B) h (function₂ W) = function₂ (reflect-weakeningᴮ (Γ f (T U)) H B h W)
reflect-weakeningᴼ : H O {H} (H H) Warningᴼ H (typeCheckᴼ H O) Warningᴼ H (typeCheckᴼ H O)
reflect-weakeningᴼ H (just function f var x T ⟩∈ U is B end) h (FunctionDefnMismatch p) = FunctionDefnMismatch (≮:-heap-weakeningᴮ (x T) H B h p)
reflect-weakeningᴼ H (just function f var x T ⟩∈ U is B end) h (function₁ W) = function₁ (reflect-weakeningᴮ (x T) H B h W)
reflectᴱ : H M {H M} (H M ⟶ᴱ M H) Warningᴱ H (typeCheckᴱ H M) Either (Warningᴱ H (typeCheckᴱ H M)) (Warningᴴ H (typeCheckᴴ H))
reflectᴮ : H B {H B} (H B ⟶ᴮ B H) Warningᴮ H (typeCheckᴮ H B) Either (Warningᴮ H (typeCheckᴮ H B)) (Warningᴴ H (typeCheckᴴ H))
reflectᴱ H (M $ N) (app₁ s) (FunctionCallMismatch p) = cond (Left FunctionCallMismatch ≮:-heap-weakeningᴱ H N (rednᴱ⊑ s) unknown-src-≮: p) (Left app₁) (≮:-reductionᴱ H M s (src-unknown-≮: p))
reflectᴱ H (M $ N) (app₁ s) (app₁ W) = mapL app₁ (reflectᴱ H M s W)
reflectᴱ H (M $ N) (app₁ s) (app₂ W) = Left (app₂ (reflect-weakeningᴱ H N (rednᴱ⊑ s) W))
reflectᴱ H (M $ N) (app₂ p s) (FunctionCallMismatch q) = cond (λ r Left (FunctionCallMismatch (unknown-src-≮: r (≮:-heap-weakeningᴱ H M (rednᴱ⊑ s) (src-unknown-≮: r))))) (Left app₂) (≮:-reductionᴱ H N s q)
reflectᴱ H (M $ N) (app₂ p s) (app₁ W) = Left (app₁ (reflect-weakeningᴱ H M (rednᴱ⊑ s) W))
reflectᴱ H (M $ N) (app₂ p s) (app₂ W) = mapL app₂ (reflectᴱ H N s W)
reflectᴱ H (val (addr a) $ N) (beta (function f var x T ⟩∈ U is B end) v refl p) (BlockMismatch q) with ≮:-substitutivityᴮ H B v x q
reflectᴱ H (val (addr a) $ N) (beta (function f var x T ⟩∈ U is B end) v refl p) (BlockMismatch q) | Left r = Right (addr a p (FunctionDefnMismatch r))
reflectᴱ H (val (addr a) $ N) (beta (function f var x T ⟩∈ U is B end) v refl p) (BlockMismatch q) | Right r = Left (FunctionCallMismatch (≮:-trans-≡ r ((cong src (cong orUnknown (cong typeOfᴹᴼ (sym p)))))))
reflectᴱ H (val (addr a) $ N) (beta (function f var x T ⟩∈ U is B end) v refl p) (block₁ W) with reflect-substitutionᴮ _ B v x W
reflectᴱ H (val (addr a) $ N) (beta (function f var x T ⟩∈ U is B end) v refl p) (block₁ W) | Left W = Right (addr a p (function₁ W))
reflectᴱ H (val (addr a) $ N) (beta (function f var x T ⟩∈ U is B end) v refl p) (block₁ W) | Right (Left W) = Left (app₂ W)
reflectᴱ H (val (addr a) $ N) (beta (function f var x T ⟩∈ U is B end) v refl p) (block₁ W) | Right (Right q) = Left (FunctionCallMismatch (≮:-trans-≡ q (cong src (cong orUnknown (cong typeOfᴹᴼ (sym p))))))
reflectᴱ H (block var b T is B end) (block s) (BlockMismatch p) = Left (cond BlockMismatch block₁ (≮:-reductionᴮ H B s p))
reflectᴱ H (block var b T is B end) (block s) (block₁ W) = mapL block₁ (reflectᴮ H B s W)
reflectᴱ H (block var b T is B end) (return v) W = Left (block₁ (return W))
reflectᴱ H (function f var x T ⟩∈ U is B end) (function a defn) (UnallocatedAddress ())
reflectᴱ H (binexp M op N) (binOp₀ ()) (UnallocatedAddress p)
reflectᴱ H (binexp M op N) (binOp₁ s) (BinOpMismatch₁ p) = Left (cond BinOpMismatch₁ bin₁ (≮:-reductionᴱ H M s p))
reflectᴱ H (binexp M op N) (binOp₁ s) (BinOpMismatch₂ p) = Left (BinOpMismatch₂ (≮:-heap-weakeningᴱ H N (rednᴱ⊑ s) p))
reflectᴱ H (binexp M op N) (binOp₁ s) (bin₁ W) = mapL bin₁ (reflectᴱ H M s W)
reflectᴱ H (binexp M op N) (binOp₁ s) (bin₂ W) = Left (bin₂ (reflect-weakeningᴱ H N (rednᴱ⊑ s) W))
reflectᴱ H (binexp M op N) (binOp₂ s) (BinOpMismatch₁ p) = Left (BinOpMismatch₁ (≮:-heap-weakeningᴱ H M (rednᴱ⊑ s) p))
reflectᴱ H (binexp M op N) (binOp₂ s) (BinOpMismatch₂ p) = Left (cond BinOpMismatch₂ bin₂ (≮:-reductionᴱ H N s p))
reflectᴱ H (binexp M op N) (binOp₂ s) (bin₁ W) = Left (bin₁ (reflect-weakeningᴱ H M (rednᴱ⊑ s) W))
reflectᴱ H (binexp M op N) (binOp₂ s) (bin₂ W) = mapL bin₂ (reflectᴱ H N s W)
reflectᴮ H (local var x T M B) (local s) (LocalVarMismatch p) = Left (cond LocalVarMismatch local₁ (≮:-reductionᴱ H M s p))
reflectᴮ H (local var x T M B) (local s) (local₁ W) = mapL local₁ (reflectᴱ H M s W)
reflectᴮ H (local var x T M B) (local s) (local₂ W) = Left (local₂ (reflect-weakeningᴮ (x T) H B (rednᴱ⊑ s) W))
reflectᴮ H (local var x T M B) (subst v) W = Left (cond local₂ (cond local₁ LocalVarMismatch) (reflect-substitutionᴮ H B v x W))
reflectᴮ H (function f var y T ⟩∈ U is C end B) (function a defn) W with reflect-substitutionᴮ _ B (addr a) f W
reflectᴮ H (function f var y T ⟩∈ U is C end B) (function a defn) W | Left W = Left (function₂ (reflect-weakeningᴮ (f (T U)) H B (snoc defn) W))
reflectᴮ H (function f var y T ⟩∈ U is C end B) (function a defn) W | Right (Left (UnallocatedAddress ()))
reflectᴮ H (function f var y T ⟩∈ U is C end B) (function a defn) W | Right (Right p) = CONTRADICTION (≮:-refl p)
reflectᴮ H (return M B) (return s) (return W) = mapL return (reflectᴱ H M s W)
reflectᴴᴱ : H M {H M} (H M ⟶ᴱ M H) Warningᴴ H (typeCheckᴴ H) Either (Warningᴱ H (typeCheckᴱ H M)) (Warningᴴ H (typeCheckᴴ H))
reflectᴴᴮ : H B {H B} (H B ⟶ᴮ B H) Warningᴴ H (typeCheckᴴ H) Either (Warningᴮ H (typeCheckᴮ H B)) (Warningᴴ H (typeCheckᴴ H))
reflectᴴᴱ H (M $ N) (app₁ s) W = mapL app₁ (reflectᴴᴱ H M s W)
reflectᴴᴱ H (M $ N) (app₂ v s) W = mapL app₂ (reflectᴴᴱ H N s W)
reflectᴴᴱ H (M $ N) (beta O v refl p) W = Right W
reflectᴴᴱ H (function f var x T ⟩∈ U is B end) (function a p) (addr b refl W) with b ≡ᴬ a
reflectᴴᴱ H (function f var x T ⟩∈ U is B end) (function a defn) (addr b refl (FunctionDefnMismatch p)) | yes refl = Left (FunctionDefnMismatch (≮:-heap-weakeningᴮ (x T) H B (snoc defn) p))
reflectᴴᴱ H (function f var x T ⟩∈ U is B end) (function a defn) (addr b refl (function₁ W)) | yes refl = Left (function₁ (reflect-weakeningᴮ (x T) H B (snoc defn) W))
reflectᴴᴱ H (function f var x T ⟩∈ U is B end) (function a p) (addr b refl W) | no q = Right (addr b (lookup-not-allocated p q) (reflect-weakeningᴼ H _ (snoc p) W))
reflectᴴᴱ H (block var b T is B end) (block s) W = mapL block₁ (reflectᴴᴮ H B s W)
reflectᴴᴱ H (block var b T is return (val v) B end) (return v) W = Right W
reflectᴴᴱ H (block var b T is done end) done W = Right W
reflectᴴᴱ H (binexp M op N) (binOp₀ s) W = Right W
reflectᴴᴱ H (binexp M op N) (binOp₁ s) W = mapL bin₁ (reflectᴴᴱ H M s W)
reflectᴴᴱ H (binexp M op N) (binOp₂ s) W = mapL bin₂ (reflectᴴᴱ H N s W)
reflectᴴᴮ H (function f var x T ⟩∈ U is C end B) (function a p) (addr b refl W) with b ≡ᴬ a
reflectᴴᴮ H (function f var x T ⟩∈ U is C end B) (function a defn) (addr b refl (FunctionDefnMismatch p)) | yes refl = Left (FunctionDefnMismatch (≮:-heap-weakeningᴮ (x T) H C (snoc defn) p))
reflectᴴᴮ H (function f var x T ⟩∈ U is C end B) (function a defn) (addr b refl (function₁ W)) | yes refl = Left (function₁ (reflect-weakeningᴮ (x T) H C (snoc defn) W))
reflectᴴᴮ H (function f var x T ⟩∈ U is C end B) (function a p) (addr b refl W) | no q = Right (addr b (lookup-not-allocated p q) (reflect-weakeningᴼ H _ (snoc p) W))
reflectᴴᴮ H (local var x T M B) (local s) W = mapL local₁ (reflectᴴᴱ H M s W)
reflectᴴᴮ H (local var x T M B) (subst v) W = Right W
reflectᴴᴮ H (return M B) (return s) W = mapL return (reflectᴴᴱ H M s W)
reflect* : H B {H B} (H B ⟶* B H) Either (Warningᴮ H (typeCheckᴮ H B)) (Warningᴴ H (typeCheckᴴ H)) Either (Warningᴮ H (typeCheckᴮ H B)) (Warningᴴ H (typeCheckᴴ H))
reflect* H B refl W = W
reflect* H B (step s t) W = cond (reflectᴮ H B s) (reflectᴴᴮ H B s) (reflect* _ _ t W)
isntNumber : H v (valueType v number) (typeOfᴱ H (val v) ≮: number)
isntNumber H nil p = scalar-≢-impl-≮: nil number (λ ())
isntNumber H (addr a) p with remember (H [ a ]ᴴ)
isntNumber H (addr a) p | (just (function f var x T ⟩∈ U is B end) , q) = ≡-trans-≮: (cong orUnknown (cong typeOfᴹᴼ q)) (function-≮:-scalar number)
isntNumber H (addr a) p | (nothing , q) = ≡-trans-≮: (cong orUnknown (cong typeOfᴹᴼ q)) (unknown-≮:-scalar number)
isntNumber H (number x) p = CONTRADICTION (p refl)
isntNumber H (bool x) p = scalar-≢-impl-≮: boolean number (λ ())
isntNumber H (string x) p = scalar-≢-impl-≮: string number (λ ())
isntString : H v (valueType v string) (typeOfᴱ H (val v) ≮: string)
isntString H nil p = scalar-≢-impl-≮: nil string (λ ())
isntString H (addr a) p with remember (H [ a ]ᴴ)
isntString H (addr a) p | (just (function f var x T ⟩∈ U is B end) , q) = ≡-trans-≮: (cong orUnknown (cong typeOfᴹᴼ q)) (function-≮:-scalar string)
isntString H (addr a) p | (nothing , q) = ≡-trans-≮: (cong orUnknown (cong typeOfᴹᴼ q)) (unknown-≮:-scalar string)
isntString H (number x) p = scalar-≢-impl-≮: number string (λ ())
isntString H (bool x) p = scalar-≢-impl-≮: boolean string (λ ())
isntString H (string x) p = CONTRADICTION (p refl)
isntFunction : H v {T U} (valueType v function) (typeOfᴱ H (val v) ≮: (T U))
isntFunction H nil p = scalar-≮:-function nil
isntFunction H (addr a) p = CONTRADICTION (p refl)
isntFunction H (number x) p = scalar-≮:-function number
isntFunction H (bool x) p = scalar-≮:-function boolean
isntFunction H (string x) p = scalar-≮:-function string
isntEmpty : H v (typeOfᴱ H (val v) ≮: never)
isntEmpty H nil = scalar-≮:-never nil
isntEmpty H (addr a) with remember (H [ a ]ᴴ)
isntEmpty H (addr a) | (just (function f var x T ⟩∈ U is B end) , p) = ≡-trans-≮: (cong orUnknown (cong typeOfᴹᴼ p)) function-≮:-never
isntEmpty H (addr a) | (nothing , p) = ≡-trans-≮: (cong orUnknown (cong typeOfᴹᴼ p)) unknown-≮:-never
isntEmpty H (number x) = scalar-≮:-never number
isntEmpty H (bool x) = scalar-≮:-never boolean
isntEmpty H (string x) = scalar-≮:-never string
runtimeBinOpWarning : H {op} v BinOpError op (valueType v) (typeOfᴱ H (val v) ≮: srcBinOp op)
runtimeBinOpWarning H v (+ p) = isntNumber H v p
runtimeBinOpWarning H v (- p) = isntNumber H v p
runtimeBinOpWarning H v (* p) = isntNumber H v p
runtimeBinOpWarning H v (/ p) = isntNumber H v p
runtimeBinOpWarning H v (< p) = isntNumber H v p
runtimeBinOpWarning H v (> p) = isntNumber H v p
runtimeBinOpWarning H v (<= p) = isntNumber H v p
runtimeBinOpWarning H v (>= p) = isntNumber H v p
runtimeBinOpWarning H v (·· p) = isntString H v p
runtimeWarningᴱ : H M RuntimeErrorᴱ H M Warningᴱ H (typeCheckᴱ H M)
runtimeWarningᴮ : H B RuntimeErrorᴮ H B Warningᴮ H (typeCheckᴮ H B)
runtimeWarningᴱ H (var x) UnboundVariable = UnboundVariable refl
runtimeWarningᴱ H (val (addr a)) (SEGV p) = UnallocatedAddress p
runtimeWarningᴱ H (M $ N) (FunctionMismatch v w p) = FunctionCallMismatch (unknown-src-≮: (isntEmpty H w) (isntFunction H v p))
runtimeWarningᴱ H (M $ N) (app₁ err) = app₁ (runtimeWarningᴱ H M err)
runtimeWarningᴱ H (M $ N) (app₂ err) = app₂ (runtimeWarningᴱ H N err)
runtimeWarningᴱ H (block var b T is B end) (block err) = block₁ (runtimeWarningᴮ H B err)
runtimeWarningᴱ H (binexp M op N) (BinOpMismatch₁ v w p) = BinOpMismatch₁ (runtimeBinOpWarning H v p)
runtimeWarningᴱ H (binexp M op N) (BinOpMismatch₂ v w p) = BinOpMismatch₂ (runtimeBinOpWarning H w p)
runtimeWarningᴱ H (binexp M op N) (bin₁ err) = bin₁ (runtimeWarningᴱ H M err)
runtimeWarningᴱ H (binexp M op N) (bin₂ err) = bin₂ (runtimeWarningᴱ H N err)
runtimeWarningᴮ H (local var x T M B) (local err) = local₁ (runtimeWarningᴱ H M err)
runtimeWarningᴮ H (return M B) (return err) = return (runtimeWarningᴱ H M err)
wellTypedProgramsDontGoWrong : H B B (∅ᴴ B ⟶* B H) (RuntimeErrorᴮ H B) Warningᴮ ∅ᴴ (typeCheckᴮ ∅ᴴ B)
wellTypedProgramsDontGoWrong H B B t err with reflect* ∅ᴴ B t (Left (runtimeWarningᴮ H B err))
wellTypedProgramsDontGoWrong H B B t err | Right (addr a refl ())
wellTypedProgramsDontGoWrong H B B t err | Left W = W

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prototyping/Properties/Subtyping.agda
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{-# OPTIONS --rewriting #-}
module Properties.Subtyping where
open import Agda.Builtin.Equality using (_≡_; refl)
open import FFI.Data.Either using (Either; Left; Right; mapLR; swapLR; cond)
open import FFI.Data.Maybe using (Maybe; just; nothing)
open import Luau.Subtyping using (_<:_; _≮:_; Tree; Language; ¬Language; witness; unknown; never; scalar; function; scalar-function; scalar-function-ok; scalar-function-err; scalar-function-tgt; scalar-scalar; function-scalar; function-ok; function-ok₁; function-ok₂; function-err; function-tgt; left; right; _,_)
open import Luau.Type using (Type; Scalar; nil; number; string; boolean; never; unknown; _⇒_; __; _∩_; skalar)
open import Properties.Contradiction using (CONTRADICTION; ¬; )
open import Properties.Equality using (_≢_)
open import Properties.Functions using (_∘_)
open import Properties.Product using (_×_; _,_)
-- Language membership is decidable
dec-language : T t Either (¬Language T t) (Language T t)
dec-language nil (scalar number) = Left (scalar-scalar number nil (λ ()))
dec-language nil (scalar boolean) = Left (scalar-scalar boolean nil (λ ()))
dec-language nil (scalar string) = Left (scalar-scalar string nil (λ ()))
dec-language nil (scalar nil) = Right (scalar nil)
dec-language nil function = Left (scalar-function nil)
dec-language nil (function-ok s t) = Left (scalar-function-ok nil)
dec-language nil (function-err t) = Left (scalar-function-err nil)
dec-language boolean (scalar number) = Left (scalar-scalar number boolean (λ ()))
dec-language boolean (scalar boolean) = Right (scalar boolean)
dec-language boolean (scalar string) = Left (scalar-scalar string boolean (λ ()))
dec-language boolean (scalar nil) = Left (scalar-scalar nil boolean (λ ()))
dec-language boolean function = Left (scalar-function boolean)
dec-language boolean (function-ok s t) = Left (scalar-function-ok boolean)
dec-language boolean (function-err t) = Left (scalar-function-err boolean)
dec-language number (scalar number) = Right (scalar number)
dec-language number (scalar boolean) = Left (scalar-scalar boolean number (λ ()))
dec-language number (scalar string) = Left (scalar-scalar string number (λ ()))
dec-language number (scalar nil) = Left (scalar-scalar nil number (λ ()))
dec-language number function = Left (scalar-function number)
dec-language number (function-ok s t) = Left (scalar-function-ok number)
dec-language number (function-err t) = Left (scalar-function-err number)
dec-language string (scalar number) = Left (scalar-scalar number string (λ ()))
dec-language string (scalar boolean) = Left (scalar-scalar boolean string (λ ()))
dec-language string (scalar string) = Right (scalar string)
dec-language string (scalar nil) = Left (scalar-scalar nil string (λ ()))
dec-language string function = Left (scalar-function string)
dec-language string (function-ok s t) = Left (scalar-function-ok string)
dec-language string (function-err t) = Left (scalar-function-err string)
dec-language (T₁ T₂) (scalar s) = Left (function-scalar s)
dec-language (T₁ T₂) function = Right function
dec-language (T₁ T₂) (function-ok s t) = cond (Right function-ok₁) (λ p mapLR (function-ok p) function-ok₂ (dec-language T₂ t)) (dec-language T₁ s)
dec-language (T₁ T₂) (function-err t) = mapLR function-err function-err (swapLR (dec-language T₁ t))
dec-language never t = Left never
dec-language unknown t = Right unknown
dec-language (T₁ T₂) t = cond (λ p cond (Left _,_ p) (Right right) (dec-language T₂ t)) (Right left) (dec-language T₁ t)
dec-language (T₁ T₂) t = cond (Left left) (λ p cond (Left right) (Right _,_ p) (dec-language T₂ t)) (dec-language T₁ t)
dec-language nil (function-tgt t) = Left (scalar-function-tgt nil)
dec-language (T₁ T₂) (function-tgt t) = mapLR function-tgt function-tgt (dec-language T₂ t)
dec-language boolean (function-tgt t) = Left (scalar-function-tgt boolean)
dec-language number (function-tgt t) = Left (scalar-function-tgt number)
dec-language string (function-tgt t) = Left (scalar-function-tgt string)
-- ¬Language T is the complement of Language T
language-comp : {T} t ¬Language T t ¬(Language T t)
language-comp t (p₁ , p₂) (left q) = language-comp t p₁ q
language-comp t (p₁ , p₂) (right q) = language-comp t p₂ q
language-comp t (left p) (q₁ , q₂) = language-comp t p q₁
language-comp t (right p) (q₁ , q₂) = language-comp t p q₂
language-comp (scalar s) (scalar-scalar s p₁ p₂) (scalar s) = p₂ refl
language-comp (scalar s) (function-scalar s) (scalar s) = language-comp function (scalar-function s) function
language-comp (scalar s) never (scalar ())
language-comp function (scalar-function ()) function
language-comp (function-ok s t) (scalar-function-ok ()) (function-ok₁ p)
language-comp (function-ok s t) (function-ok p₁ p₂) (function-ok₁ q) = language-comp s q p₁
language-comp (function-ok s t) (function-ok p₁ p₂) (function-ok₂ q) = language-comp t p₂ q
language-comp (function-err t) (function-err p) (function-err q) = language-comp t q p
language-comp (function-tgt t) (scalar-function-tgt ()) (function-tgt q)
language-comp (function-tgt t) (function-tgt p) (function-tgt q) = language-comp t p q
-- ≮: is the complement of <:
¬≮:-impl-<: : {T U} ¬(T ≮: U) (T <: U)
¬≮:-impl-<: {T} {U} p t q with dec-language U t
¬≮:-impl-<: {T} {U} p t q | Left r = CONTRADICTION (p (witness t q r))
¬≮:-impl-<: {T} {U} p t q | Right r = r
<:-impl-¬≮: : {T U} (T <: U) ¬(T ≮: U)
<:-impl-¬≮: p (witness t q r) = language-comp t r (p t q)
<:-impl-⊇ : {T U} (T <: U) t ¬Language U t ¬Language T t
<:-impl-⊇ {T} p t q with dec-language T t
<:-impl-⊇ {_} p t q | Left r = r
<:-impl-⊇ {_} p t q | Right r = CONTRADICTION (language-comp t q (p t r))
-- reflexivity
≮:-refl : {T} ¬(T ≮: T)
:-refl (witness t p q) = language-comp t q p
<:-refl : {T} (T <: T)
<:-refl = ¬≮:-impl-<: ≮:-refl
-- transititivity
≮:-trans-≡ : {S T U} (S ≮: T) (T U) (S ≮: U)
:-trans-≡ p refl = p
<:-trans-≡ : {S T U} (S <: T) (T U) (S <: U)
<:-trans-≡ p refl = p
≡-impl-<: : {T U} (T U) (T <: U)
≡-impl-<: refl = <:-refl
≡-trans-≮: : {S T U} (S T) (T ≮: U) (S ≮: U)
≡-trans-≮: refl p = p
≡-trans-<: : {S T U} (S T) (T <: U) (S <: U)
≡-trans-<: refl p = p
≮:-trans : {S T U} (S ≮: U) Either (S ≮: T) (T ≮: U)
:-trans {T = T} (witness t p q) = mapLR (witness t p) (λ z witness t z q) (dec-language T t)
<:-trans : {S T U} (S <: T) (T <: U) (S <: U)
<:-trans p q t r = q t (p t r)
<:-trans-≮: : {S T U} (S <: T) (S ≮: U) (T ≮: U)
<:-trans-≮: p (witness t q r) = witness t (p t q) r
≮:-trans-<: : {S T U} (S ≮: U) (T <: U) (S ≮: T)
≮:-trans-<: (witness t p q) r = witness t p (<:-impl-⊇ r t q)
-- Properties of union
<:-union : {R S T U} (R <: T) (S <: U) ((R S) <: (T U))
<:-union p q t (left r) = left (p t r)
<:-union p q t (right r) = right (q t r)
<:--left : {S T} S <: (S T)
<:--left t p = left p
<:--right : {S T} T <: (S T)
<:--right t p = right p
<:--lub : {S T U} (S <: U) (T <: U) ((S T) <: U)
<:--lub p q t (left r) = p t r
<:--lub p q t (right r) = q t r
<:--symm : {T U} (T U) <: (U T)
<:--symm t (left p) = right p
<:--symm t (right p) = left p
<:--assocl : {S T U} (S (T U)) <: ((S T) U)
<:--assocl t (left p) = left (left p)
<:--assocl t (right (left p)) = left (right p)
<:--assocl t (right (right p)) = right p
<:--assocr : {S T U} ((S T) U) <: (S (T U))
<:--assocr t (left (left p)) = left p
<:--assocr t (left (right p)) = right (left p)
<:--assocr t (right p) = right (right p)
≮:--left : {S T U} (S ≮: U) ((S T) ≮: U)
:--left (witness t p q) = witness t (left p) q
≮:--right : {S T U} (T ≮: U) ((S T) ≮: U)
:--right (witness t p q) = witness t (right p) q
≮:-left- : {S T U} (S ≮: (T U)) (S ≮: T)
:-left- (witness t p (q₁ , q₂)) = witness t p q₁
≮:-right- : {S T U} (S ≮: (T U)) (S ≮: U)
:-right- (witness t p (q₁ , q₂)) = witness t p q₂
-- Properties of intersection
<:-intersect : {R S T U} (R <: T) (S <: U) ((R S) <: (T U))
<:-intersect p q t (r₁ , r₂) = (p t r₁ , q t r₂)
<:-∩-left : {S T} (S T) <: S
<:-∩-left t (p , _) = p
<:-∩-right : {S T} (S T) <: T
<:-∩-right t (_ , p) = p
<:-∩-glb : {S T U} (S <: T) (S <: U) (S <: (T U))
<:-∩-glb p q t r = (p t r , q t r)
<:-∩-symm : {T U} (T U) <: (U T)
<:-∩-symm t (p₁ , p₂) = (p₂ , p₁)
<:-∩-assocl : {S T U} (S (T U)) <: ((S T) U)
<:-∩-assocl t (p , (p₁ , p₂)) = (p , p₁) , p₂
<:-∩-assocr : {S T U} ((S T) U) <: (S (T U))
<:-∩-assocr t ((p , p₁) , p₂) = p , (p₁ , p₂)
≮:-∩-left : {S T U} (S ≮: T) (S ≮: (T U))
:-∩-left (witness t p q) = witness t p (left q)
≮:-∩-right : {S T U} (S ≮: U) (S ≮: (T U))
:-∩-right (witness t p q) = witness t p (right q)
-- Distribution properties
<:-∩-distl- : {S T U} (S (T U)) <: ((S T) (S U))
<:-∩-distl- t (p₁ , left p₂) = left (p₁ , p₂)
<:-∩-distl- t (p₁ , right p₂) = right (p₁ , p₂)
∩-distl--<: : {S T U} ((S T) (S U)) <: (S (T U))
∩-distl--<: t (left (p₁ , p₂)) = (p₁ , left p₂)
∩-distl--<: t (right (p₁ , p₂)) = (p₁ , right p₂)
<:-∩-distr- : {S T U} ((S T) U) <: ((S U) (T U))
<:-∩-distr- t (left p₁ , p₂) = left (p₁ , p₂)
<:-∩-distr- t (right p₁ , p₂) = right (p₁ , p₂)
∩-distr--<: : {S T U} ((S U) (T U)) <: ((S T) U)
∩-distr--<: t (left (p₁ , p₂)) = (left p₁ , p₂)
∩-distr--<: t (right (p₁ , p₂)) = (right p₁ , p₂)
<:--distl-∩ : {S T U} (S (T U)) <: ((S T) (S U))
<:--distl-∩ t (left p) = (left p , left p)
<:--distl-∩ t (right (p₁ , p₂)) = (right p₁ , right p₂)
-distl-∩-<: : {S T U} ((S T) (S U)) <: (S (T U))
-distl-∩-<: t (left p₁ , p₂) = left p₁
-distl-∩-<: t (right p₁ , left p₂) = left p₂
-distl-∩-<: t (right p₁ , right p₂) = right (p₁ , p₂)
<:--distr-∩ : {S T U} ((S T) U) <: ((S U) (T U))
<:--distr-∩ t (left (p₁ , p₂)) = left p₁ , left p₂
<:--distr-∩ t (right p) = (right p , right p)
-distr-∩-<: : {S T U} ((S U) (T U)) <: ((S T) U)
-distr-∩-<: t (left p₁ , left p₂) = left (p₁ , p₂)
-distr-∩-<: t (left p₁ , right p₂) = right p₂
-distr-∩-<: t (right p₁ , p₂) = right p₁
∩-<:- : {S T} (S T) <: (S T)
∩-<:- t (p , _) = left p
-- Properties of functions
<:-function : {R S T U} (R <: S) (T <: U) (S T) <: (R U)
<:-function p q function function = function
<:-function p q (function-ok s t) (function-ok₁ r) = function-ok₁ (<:-impl-⊇ p s r)
<:-function p q (function-ok s t) (function-ok₂ r) = function-ok₂ (q t r)
<:-function p q (function-err s) (function-err r) = function-err (<:-impl-⊇ p s r)
<:-function p q (function-tgt t) (function-tgt r) = function-tgt (q t r)
<:-function-∩-∩ : {R S T U} ((R T) (S U)) <: ((R S) (T U))
<:-function-∩-∩ function (function , function) = function
<:-function-∩-∩ (function-ok s t) (function-ok₁ p , q) = function-ok₁ (left p)
<:-function-∩-∩ (function-ok s t) (function-ok₂ p , function-ok₁ q) = function-ok₁ (right q)
<:-function-∩-∩ (function-ok s t) (function-ok₂ p , function-ok₂ q) = function-ok₂ (p , q)
<:-function-∩-∩ (function-err s) (function-err p , q) = function-err (left p)
<:-function-∩-∩ (function-tgt s) (function-tgt p , function-tgt q) = function-tgt (p , q)
<:-function-∩- : {R S T U} ((R T) (S U)) <: ((R S) (T U))
<:-function-∩- function (function , function) = function
<:-function-∩- (function-ok s t) (function-ok₁ p₁ , function-ok₁ p₂) = function-ok₁ (p₁ , p₂)
<:-function-∩- (function-ok s t) (p₁ , function-ok₂ p₂) = function-ok₂ (right p₂)
<:-function-∩- (function-ok s t) (function-ok₂ p₁ , p₂) = function-ok₂ (left p₁)
<:-function-∩- (function-err s) (function-err p₁ , function-err q₂) = function-err (p₁ , q₂)
<:-function-∩- (function-tgt t) (function-tgt p , q) = function-tgt (left p)
<:-function-∩ : {S T U} ((S T) (S U)) <: (S (T U))
<:-function-∩ function (function , function) = function
<:-function-∩ (function-ok s t) (p₁ , function-ok₁ p₂) = function-ok₁ p₂
<:-function-∩ (function-ok s t) (function-ok₁ p₁ , p₂) = function-ok₁ p₁
<:-function-∩ (function-ok s t) (function-ok₂ p₁ , function-ok₂ p₂) = function-ok₂ (p₁ , p₂)
<:-function-∩ (function-err s) (function-err p₁ , function-err p₂) = function-err p₂
<:-function-∩ (function-tgt t) (function-tgt p₁ , function-tgt p₂) = function-tgt (p₁ , p₂)
<:-function- : {R S T U} ((R S) (T U)) <: ((R T) (S U))
<:-function- function (left function) = function
<:-function- (function-ok s t) (left (function-ok₁ p)) = function-ok₁ (left p)
<:-function- (function-ok s t) (left (function-ok₂ p)) = function-ok₂ (left p)
<:-function- (function-err s) (left (function-err p)) = function-err (left p)
<:-function- (scalar s) (left (scalar ()))
<:-function- function (right function) = function
<:-function- (function-ok s t) (right (function-ok₁ p)) = function-ok₁ (right p)
<:-function- (function-ok s t) (right (function-ok₂ p)) = function-ok₂ (right p)
<:-function- (function-err s) (right (function-err x)) = function-err (right x)
<:-function- (scalar s) (right (scalar ()))
<:-function- (function-tgt t) (left (function-tgt p)) = function-tgt (left p)
<:-function- (function-tgt t) (right (function-tgt p)) = function-tgt (right p)
<:-function--∩ : {R S T U} ((R S) (T U)) <: ((R T) (S U))
<:-function--∩ function function = left function
<:-function--∩ (function-ok s t) (function-ok₁ (left p)) = left (function-ok₁ p)
<:-function--∩ (function-ok s t) (function-ok₂ (left p)) = left (function-ok₂ p)
<:-function--∩ (function-ok s t) (function-ok₁ (right p)) = right (function-ok₁ p)
<:-function--∩ (function-ok s t) (function-ok₂ (right p)) = right (function-ok₂ p)
<:-function--∩ (function-err s) (function-err (left p)) = left (function-err p)
<:-function--∩ (function-err s) (function-err (right p)) = right (function-err p)
<:-function--∩ (function-tgt t) (function-tgt (left p)) = left (function-tgt p)
<:-function--∩ (function-tgt t) (function-tgt (right p)) = right (function-tgt p)
<:-function-left : {R S T U} (S T) <: (R U) (R <: S)
<:-function-left {R} {S} p s Rs with dec-language S s
<:-function-left p s Rs | Right Ss = Ss
<:-function-left p s Rs | Left ¬Ss with p (function-err s) (function-err ¬Ss)
<:-function-left p s Rs | Left ¬Ss | function-err ¬Rs = CONTRADICTION (language-comp s ¬Rs Rs)
<:-function-right : {R S T U} (S T) <: (R U) (T <: U)
<:-function-right p t Tt with p (function-tgt t) (function-tgt Tt)
<:-function-right p t Tt | function-tgt St = St
≮:-function-left : {R S T U} (R ≮: S) (S T) ≮: (R U)
:-function-left (witness t p q) = witness (function-err t) (function-err q) (function-err p)
≮:-function-right : {R S T U} (T ≮: U) (S T) ≮: (R U)
:-function-right (witness t p q) = witness (function-tgt t) (function-tgt p) (function-tgt q)
-- Properties of scalars
skalar-function-ok : {s t} (¬Language skalar (function-ok s t))
skalar-function-ok = (scalar-function-ok number , (scalar-function-ok string , (scalar-function-ok nil , scalar-function-ok boolean)))
scalar-<: : {S T} (s : Scalar S) Language T (scalar s) (S <: T)
scalar-<: number p (scalar number) (scalar number) = p
scalar-<: boolean p (scalar boolean) (scalar boolean) = p
scalar-<: string p (scalar string) (scalar string) = p
scalar-<: nil p (scalar nil) (scalar nil) = p
scalar-∩-function-<:-never : {S T U} (Scalar S) ((T U) S) <: never
scalar-∩-function-<:-never number .(scalar number) (() , scalar number)
scalar-∩-function-<:-never boolean .(scalar boolean) (() , scalar boolean)
scalar-∩-function-<:-never string .(scalar string) (() , scalar string)
scalar-∩-function-<:-never nil .(scalar nil) (() , scalar nil)
function-≮:-scalar : {S T U} (Scalar U) ((S T) ≮: U)
function-≮:-scalar s = witness function function (scalar-function s)
scalar-≮:-function : {S T U} (Scalar U) (U ≮: (S T))
scalar-≮:-function s = witness (scalar s) (scalar s) (function-scalar s)
unknown-≮:-scalar : {U} (Scalar U) (unknown ≮: U)
unknown-≮:-scalar s = witness function unknown (scalar-function s)
scalar-≮:-never : {U} (Scalar U) (U ≮: never)
scalar-≮:-never s = witness (scalar s) (scalar s) never
scalar-≢-impl-≮: : {T U} (Scalar T) (Scalar U) (T U) (T ≮: U)
scalar-≢-impl-≮: s₁ s₂ p = witness (scalar s₁) (scalar s₁) (scalar-scalar s₁ s₂ p)
scalar-≢-∩-<:-never : {T U V} (Scalar T) (Scalar U) (T U) (T U) <: V
scalar-≢-∩-<:-never s t p u (scalar s₁ , scalar s₂) = CONTRADICTION (p refl)
skalar-scalar : {T} (s : Scalar T) (Language skalar (scalar s))
skalar-scalar number = left (scalar number)
skalar-scalar boolean = right (right (right (scalar boolean)))
skalar-scalar string = right (left (scalar string))
skalar-scalar nil = right (right (left (scalar nil)))
-- Properties of unknown and never
unknown-≮: : {T U} (T ≮: U) (unknown ≮: U)
unknown-≮: (witness t p q) = witness t unknown q
never-≮: : {T U} (T ≮: U) (T ≮: never)
never-≮: (witness t p q) = witness t p never
unknown-≮:-never : (unknown ≮: never)
unknown-≮:-never = witness (scalar nil) unknown never
unknown-≮:-function : {S T} (unknown ≮: (S T))
unknown-≮:-function = witness (scalar nil) unknown (function-scalar nil)
function-≮:-never : {T U} ((T U) ≮: never)
function-≮:-never = witness function function never
<:-never : {T} (never <: T)
<:-never t (scalar ())
≮:-never-left : {S T U} (S <: (T U)) (S ≮: T) (S U) ≮: never
:-never-left p (witness t q₁ q₂) with p t q₁
:-never-left p (witness t q₁ q₂) | left r = CONTRADICTION (language-comp t q₂ r)
:-never-left p (witness t q₁ q₂) | right r = witness t (q₁ , r) never
≮:-never-right : {S T U} (S <: (T U)) (S ≮: U) (S T) ≮: never
:-never-right p (witness t q₁ q₂) with p t q₁
:-never-right p (witness t q₁ q₂) | left r = witness t (q₁ , r) never
:-never-right p (witness t q₁ q₂) | right r = CONTRADICTION (language-comp t q₂ r)
<:-unknown : {T} (T <: unknown)
<:-unknown t p = unknown
<:-everything : unknown <: ((never unknown) skalar)
<:-everything (scalar s) p = right (skalar-scalar s)
<:-everything function p = left function
<:-everything (function-ok s t) p = left (function-ok₁ never)
<:-everything (function-err s) p = left (function-err never)
<:-everything (function-tgt t) p = left (function-tgt unknown)
-- A Gentle Introduction To Semantic Subtyping (https://www.cduce.org/papers/gentle.pdf)
-- defines a "set-theoretic" model (sec 2.5)
-- Unfortunately we don't quite have this property, due to uninhabited types,
-- for example (never -> T) is equivalent to (never -> U)
-- when types are interpreted as sets of syntactic values.
_⊆_ : {A : Set} (A Set) (A Set) Set
(P Q) = a (P a) (Q a)
_⊗_ : {A B : Set} (A Set) (B Set) ((A × B) Set)
(P Q) (a , b) = (P a) × (Q b)
Comp : {A : Set} (A Set) (A Set)
Comp P a = ¬(P a)
Lift : {A : Set} (A Set) (Maybe A Set)
Lift P nothing =
Lift P (just a) = P a
set-theoretic-if : {S₁ T₁ S₂ T₂}
-- This is the "if" part of being a set-theoretic model
-- though it uses the definition from Frisch's thesis
-- rather than from the Gentle Introduction. The difference
-- being the presence of Lift, (written D_Ω in Defn 4.2 of
-- https://www.cduce.org/papers/frisch_phd.pdf).
(Language (S₁ T₁) Language (S₂ T₂))
( Q Q Comp((Language S₁) Comp(Lift(Language T₁))) Q Comp((Language S₂) Comp(Lift(Language T₂))))
set-theoretic-if {S₁} {T₁} {S₂} {T₂} p Q q (t , just u) Qtu (S₂t , ¬T₂u) = q (t , just u) Qtu (S₁t , ¬T₁u) where
S₁t : Language S₁ t
S₁t with dec-language S₁ t
S₁t | Left ¬S₁t with p (function-err t) (function-err ¬S₁t)
S₁t | Left ¬S₁t | function-err ¬S₂t = CONTRADICTION (language-comp t ¬S₂t S₂t)
S₁t | Right r = r
¬T₁u : ¬(Language T₁ u)
¬T₁u T₁u with p (function-ok t u) (function-ok₂ T₁u)
¬T₁u T₁u | function-ok₁ ¬S₂t = language-comp t ¬S₂t S₂t
¬T₁u T₁u | function-ok₂ T₂u = ¬T₂u T₂u
set-theoretic-if {S₁} {T₁} {S₂} {T₂} p Q q (t , nothing) Qt- (S₂t , _) = q (t , nothing) Qt- (S₁t , λ ()) where
S₁t : Language S₁ t
S₁t with dec-language S₁ t
S₁t | Left ¬S₁t with p (function-err t) (function-err ¬S₁t)
S₁t | Left ¬S₁t | function-err ¬S₂t = CONTRADICTION (language-comp t ¬S₂t S₂t)
S₁t | Right r = r
not-quite-set-theoretic-only-if : {S₁ T₁ S₂ T₂}
-- We don't quite have that this is a set-theoretic model
-- it's only true when Language S₂ is inhabited
-- in particular it's not true when S₂ is never,
s₂ Language S₂ s₂
-- This is the "only if" part of being a set-theoretic model
( Q Q Comp((Language S₁) Comp(Lift(Language T₁))) Q Comp((Language S₂) Comp(Lift(Language T₂))))
(Language (S₁ T₁) Language (S₂ T₂))
not-quite-set-theoretic-only-if {S₁} {T₁} {S₂} {T₂} s₂ S₂s₂ p = r where
Q : (Tree × Maybe Tree) Set
Q (t , just u) = Either (¬Language S₁ t) (Language T₁ u)
Q (t , nothing) = ¬Language S₁ t
q : Q Comp(Language S₁ Comp(Lift(Language T₁)))
q (t , just u) (Left ¬S₁t) (S₁t , ¬T₁u) = language-comp t ¬S₁t S₁t
q (t , just u) (Right T₂u) (S₁t , ¬T₁u) = ¬T₁u T₂u
q (t , nothing) ¬S₁t (S₁t , _) = language-comp t ¬S₁t S₁t
r : Language (S₁ T₁) Language (S₂ T₂)
r function function = function
r (function-err s) (function-err ¬S₁s) with dec-language S₂ s
r (function-err s) (function-err ¬S₁s) | Left ¬S₂s = function-err ¬S₂s
r (function-err s) (function-err ¬S₁s) | Right S₂s = CONTRADICTION (p Q q (s , nothing) ¬S₁s (S₂s , λ ()))
r (function-ok s t) (function-ok₁ ¬S₁s) with dec-language S₂ s
r (function-ok s t) (function-ok₁ ¬S₁s) | Left ¬S₂s = function-ok₁ ¬S₂s
r (function-ok s t) (function-ok₁ ¬S₁s) | Right S₂s = CONTRADICTION (p Q q (s , nothing) ¬S₁s (S₂s , λ ()))
r (function-ok s t) (function-ok₂ T₁t) with dec-language T₂ t
r (function-ok s t) (function-ok₂ T₁t) | Left ¬T₂t with dec-language S₂ s
r (function-ok s t) (function-ok₂ T₁t) | Left ¬T₂t | Left ¬S₂s = function-ok₁ ¬S₂s
r (function-ok s t) (function-ok₂ T₁t) | Left ¬T₂t | Right S₂s = CONTRADICTION (p Q q (s , just t) (Right T₁t) (S₂s , language-comp t ¬T₂t))
r (function-ok s t) (function-ok₂ T₁t) | Right T₂t = function-ok₂ T₂t
r (function-tgt t) (function-tgt T₁t) with dec-language T₂ t
r (function-tgt t) (function-tgt T₁t) | Left ¬T₂t = CONTRADICTION (p Q q (s₂ , just t) (Right T₁t) (S₂s₂ , language-comp t ¬T₂t))
r (function-tgt t) (function-tgt T₁t) | Right T₂t = function-tgt T₂t
-- A counterexample when the argument type is empty.
set-theoretic-counterexample-one : ( Q Q Comp((Language never) Comp(Lift(Language number))) Q Comp((Language never) Comp(Lift(Language string))))
set-theoretic-counterexample-one Q q ((scalar s) , u) Qtu (scalar () , p)
set-theoretic-counterexample-two : (never number) ≮: (never string)
set-theoretic-counterexample-two = witness (function-tgt (scalar number)) (function-tgt (scalar number)) (function-tgt (scalar-scalar number string (λ ())))

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prototyping/Properties/TypeCheck.agda
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@ -1,100 +0,0 @@
{-# OPTIONS --rewriting #-}
module Properties.TypeCheck where
open import Agda.Builtin.Equality using (_≡_; refl)
open import Agda.Builtin.Bool using (Bool; true; false)
open import FFI.Data.Maybe using (Maybe; just; nothing)
open import FFI.Data.Either using (Either)
open import Luau.ResolveOverloads using (resolve)
open import Luau.TypeCheck using (_⊢ᴱ_∈_; _⊢ᴮ_∈_; ⊢ᴼ_; ⊢ᴴ_; _⊢ᴴᴱ_▷_∈_; _⊢ᴴᴮ_▷_∈_; nil; var; addr; number; bool; string; app; function; block; binexp; done; return; local; nothing; orUnknown; tgtBinOp)
open import Luau.Syntax using (Block; Expr; Value; BinaryOperator; yes; nil; addr; number; bool; string; val; var; binexp; _$_; function_is_end; block_is_end; _∙_; return; done; local_←_; _⟨_⟩; _⟨_⟩∈_; var_∈_; name; fun; arg; +; -; *; /; <; >; ==; ~=; <=; >=)
open import Luau.Type using (Type; nil; unknown; never; number; boolean; string; _⇒_)
open import Luau.RuntimeType using (RuntimeType; nil; number; function; string; valueType)
open import Luau.VarCtxt using (VarCtxt; ∅; _↦_; _⊕_↦_; _⋒_; _⊝_) renaming (_[_] to _[_]ⱽ)
open import Luau.Addr using (Addr)
open import Luau.Var using (Var; _≡ⱽ_)
open import Luau.Heap using (Heap; Object; function_is_end) renaming (_[_] to _[_]ᴴ)
open import Properties.Contradiction using (CONTRADICTION)
open import Properties.Dec using (yes; no)
open import Properties.Equality using (_≢_; sym; trans; cong)
open import Properties.Product using (_×_; _,_)
open import Properties.Remember using (Remember; remember; _,_)
typeOfᴼ : Object yes Type
typeOfᴼ (function f var x S ⟩∈ T is B end) = (S T)
typeOfᴹᴼ : Maybe(Object yes) Maybe Type
typeOfᴹᴼ nothing = nothing
typeOfᴹᴼ (just O) = just (typeOfᴼ O)
typeOfⱽ : Heap yes Value Maybe Type
typeOfⱽ H nil = just nil
typeOfⱽ H (bool b) = just boolean
typeOfⱽ H (addr a) = typeOfᴹᴼ (H [ a ]ᴴ)
typeOfⱽ H (number n) = just number
typeOfⱽ H (string x) = just string
typeOfᴱ : Heap yes VarCtxt (Expr yes) Type
typeOfᴮ : Heap yes VarCtxt (Block yes) Type
typeOfᴱ H Γ (var x) = orUnknown(Γ [ x ]ⱽ)
typeOfᴱ H Γ (val v) = orUnknown(typeOfⱽ H v)
typeOfᴱ H Γ (M $ N) = resolve (typeOfᴱ H Γ M) (typeOfᴱ H Γ N)
typeOfᴱ H Γ (function f var x S ⟩∈ T is B end) = S T
typeOfᴱ H Γ (block var b T is B end) = T
typeOfᴱ H Γ (binexp M op N) = tgtBinOp op
typeOfᴮ H Γ (function f var x S ⟩∈ T is C end B) = typeOfᴮ H (Γ f (S T)) B
typeOfᴮ H Γ (local var x T M B) = typeOfᴮ H (Γ x T) B
typeOfᴮ H Γ (return M B) = typeOfᴱ H Γ M
typeOfᴮ H Γ done = nil
mustBeNumber : H Γ v (typeOfᴱ H Γ (val v) number) (valueType(v) number)
mustBeNumber H Γ (addr a) p with remember (H [ a ]ᴴ)
mustBeNumber H Γ (addr a) p | (just O , q) with trans (cong orUnknown (cong typeOfᴹᴼ (sym q))) p
mustBeNumber H Γ (addr a) p | (just function f var x T ⟩∈ U is B end , q) | ()
mustBeNumber H Γ (addr a) p | (nothing , q) with trans (cong orUnknown (cong typeOfᴹᴼ (sym q))) p
mustBeNumber H Γ (addr a) p | nothing , q | ()
mustBeNumber H Γ (number n) p = refl
mustBeString : H Γ v (typeOfᴱ H Γ (val v) string) (valueType(v) string)
mustBeString H Γ (addr a) p with remember (H [ a ]ᴴ)
mustBeString H Γ (addr a) p | (just O , q) with trans (cong orUnknown (cong typeOfᴹᴼ (sym q))) p
mustBeString H Γ (addr a) p | (just function f var x T ⟩∈ U is B end , q) | ()
mustBeString H Γ (addr a) p | (nothing , q) with trans (cong orUnknown (cong typeOfᴹᴼ (sym q))) p
mustBeString H Γ (addr a) p | (nothing , q) | ()
mustBeString H Γ (string x) p = refl
typeCheckᴱ : H Γ M (Γ ⊢ᴱ M (typeOfᴱ H Γ M))
typeCheckᴮ : H Γ B (Γ ⊢ᴮ B (typeOfᴮ H Γ B))
typeCheckᴱ H Γ (var x) = var refl
typeCheckᴱ H Γ (val nil) = nil
typeCheckᴱ H Γ (val (addr a)) = addr (orUnknown (typeOfᴹᴼ (H [ a ]ᴴ)))
typeCheckᴱ H Γ (val (number n)) = number
typeCheckᴱ H Γ (val (bool b)) = bool
typeCheckᴱ H Γ (val (string x)) = string
typeCheckᴱ H Γ (M $ N) = app (typeCheckᴱ H Γ M) (typeCheckᴱ H Γ N)
typeCheckᴱ H Γ (function f var x T ⟩∈ U is B end) = function (typeCheckᴮ H (Γ x T) B)
typeCheckᴱ H Γ (block var b T is B end) = block (typeCheckᴮ H Γ B)
typeCheckᴱ H Γ (binexp M op N) = binexp (typeCheckᴱ H Γ M) (typeCheckᴱ H Γ N)
typeCheckᴮ H Γ (function f var x T ⟩∈ U is C end B) = function (typeCheckᴮ H (Γ x T) C) (typeCheckᴮ H (Γ f (T U)) B)
typeCheckᴮ H Γ (local var x T M B) = local (typeCheckᴱ H Γ M) (typeCheckᴮ H (Γ x T) B)
typeCheckᴮ H Γ (return M B) = return (typeCheckᴱ H Γ M) (typeCheckᴮ H Γ B)
typeCheckᴮ H Γ done = done
typeCheckᴼ : H O (⊢ᴼ O)
typeCheckᴼ H nothing = nothing
typeCheckᴼ H (just function f var x T ⟩∈ U is B end) = function (typeCheckᴮ H (x T) B)
typeCheckᴴ : H (⊢ᴴ H)
typeCheckᴴ H a {O} p = typeCheckᴼ H (O)
typeCheckᴴᴱ : H Γ M (Γ ⊢ᴴᴱ H M typeOfᴱ H Γ M)
typeCheckᴴᴱ H Γ M = (typeCheckᴴ H , typeCheckᴱ H Γ M)
typeCheckᴴᴮ : H Γ M (Γ ⊢ᴴᴮ H M typeOfᴮ H Γ M)
typeCheckᴴᴮ H Γ M = (typeCheckᴴ H , typeCheckᴮ H Γ M)

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prototyping/Properties/TypeNormalization.agda
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{-# OPTIONS --rewriting #-}
module Properties.TypeNormalization where
open import Luau.Type using (Type; Scalar; nil; number; string; boolean; never; unknown; _⇒_; __; _∩_)
open import Luau.Subtyping using (Tree; Language; ¬Language; function; scalar; unknown; left; right; function-ok₁; function-ok₂; function-err; function-tgt; scalar-function; scalar-function-ok; scalar-function-err; scalar-function-tgt; function-scalar; _,_)
open import Luau.TypeNormalization using (_ⁿ_; _∩ⁿ_; _ᶠ_; _ⁿˢ_; _∩ⁿˢ_; normalize)
open import Luau.Subtyping using (_<:_; _≮:_; witness; never)
open import Properties.Subtyping using (<:-trans; <:-refl; <:-unknown; <:-never; <:--left; <:--right; <:--lub; <:-∩-left; <:-∩-right; <:-∩-glb; <:-∩-symm; <:-function; <:-function--∩; <:-function-∩-; <:-function-; <:-everything; <:-union; <:--assocl; <:--assocr; <:--symm; <:-intersect; -distl-∩-<:; -distr-∩-<:; <:--distr-∩; <:--distl-∩; ∩-distl--<:; <:-∩-distl-; <:-∩-distr-; scalar-∩-function-<:-never; scalar-≢-∩-<:-never)
-- Normal forms for types
data FunType : Type Set
data Normal : Type Set
data FunType where
_⇒_ : {S T} Normal S Normal T FunType (S T)
_∩_ : {F G} FunType F FunType G FunType (F G)
data Normal where
_⇒_ : {S T} Normal S Normal T Normal (S T)
_∩_ : {F G} FunType F FunType G Normal (F G)
__ : {S T} Normal S Scalar T Normal (S T)
never : Normal never
unknown : Normal unknown
data OptScalar : Type Set where
never : OptScalar never
number : OptScalar number
boolean : OptScalar boolean
string : OptScalar string
nil : OptScalar nil
-- Top function type
fun-top : {F} (FunType F) (F <: (never unknown))
fun-top (S T) = <:-function <:-never <:-unknown
fun-top (F G) = <:-trans <:-∩-left (fun-top F)
-- function types are inhabited
fun-function : {F} FunType F Language F function
fun-function (S T) = function
fun-function (F G) = (fun-function F , fun-function G)
fun-≮:-never : {F} FunType F (F ≮: never)
fun-≮:-never F = witness function (fun-function F) never
-- function types aren't scalars
fun-¬scalar : {F S t} (s : Scalar S) FunType F Language F t ¬Language S t
fun-¬scalar s (S T) function = scalar-function s
fun-¬scalar s (S T) (function-ok₁ p) = scalar-function-ok s
fun-¬scalar s (S T) (function-ok₂ p) = scalar-function-ok s
fun-¬scalar s (S T) (function-err p) = scalar-function-err s
fun-¬scalar s (S T) (function-tgt p) = scalar-function-tgt s
fun-¬scalar s (F G) (p₁ , p₂) = fun-¬scalar s G p₂
¬scalar-fun : {F S} FunType F (s : Scalar S) ¬Language F (scalar s)
¬scalar-fun (S T) s = function-scalar s
¬scalar-fun (F G) s = left (¬scalar-fun F s)
scalar-≮:-fun : {F S} FunType F Scalar S S ≮: F
scalar-≮:-fun F s = witness (scalar s) (scalar s) (¬scalar-fun F s)
unknown-≮:-fun : {F} FunType F unknown ≮: F
unknown-≮:-fun F = witness (scalar nil) unknown (¬scalar-fun F nil)
-- Normalization produces normal types
normal : T Normal (normalize T)
normalᶠ : {F} FunType F Normal F
normal-∪ⁿ : {S T} Normal S Normal T Normal (S ∪ⁿ T)
normal-∩ⁿ : {S T} Normal S Normal T Normal (S ∩ⁿ T)
normal-∪ⁿˢ : {S T} Normal S OptScalar T Normal (S ∪ⁿˢ T)
normal-∩ⁿˢ : {S T} Normal S Scalar T OptScalar (S ∩ⁿˢ T)
normal-∪ᶠ : {F G} FunType F FunType G FunType (F ∪ᶠ G)
normal nil = never nil
normal (S T) = (normal S) (normal T)
normal never = never
normal unknown = unknown
normal boolean = never boolean
normal number = never number
normal string = never string
normal (S T) = normal-∪ⁿ (normal S) (normal T)
normal (S T) = normal-∩ⁿ (normal S) (normal T)
normalᶠ (S T) = S T
normalᶠ (F G) = F G
normal-∪ⁿ S (T₁ T₂) = (normal-∪ⁿ S T₁) T₂
normal-∪ⁿ S never = S
normal-∪ⁿ S unknown = unknown
normal-∪ⁿ never (T U) = T U
normal-∪ⁿ never (G₁ G₂) = G₁ G₂
normal-∪ⁿ unknown (T U) = unknown
normal-∪ⁿ unknown (G₁ G₂) = unknown
normal-∪ⁿ (R S) (T U) = normalᶠ (normal-∪ᶠ (R S) (T U))
normal-∪ⁿ (R S) (G₁ G₂) = normalᶠ (normal-∪ᶠ (R S) (G₁ G₂))
normal-∪ⁿ (F₁ F₂) (T U) = normalᶠ (normal-∪ᶠ (F₁ F₂) (T U))
normal-∪ⁿ (F₁ F₂) (G₁ G₂) = normalᶠ (normal-∪ᶠ (F₁ F₂) (G₁ G₂))
normal-∪ⁿ (S₁ S₂) (T₁ T₂) = normal-∪ⁿ S₁ (T₁ T₂) S₂
normal-∪ⁿ (S₁ S₂) (G₁ G₂) = normal-∪ⁿ S₁ (G₁ G₂) S₂
normal-∩ⁿ S never = never
normal-∩ⁿ S unknown = S
normal-∩ⁿ S (T U) = normal-∪ⁿˢ (normal-∩ⁿ S T) (normal-∩ⁿˢ S U )
normal-∩ⁿ never (T U) = never
normal-∩ⁿ unknown (T U) = T U
normal-∩ⁿ (R S) (T U) = (R S) (T U)
normal-∩ⁿ (R S) (T U) = (R S) (T U)
normal-∩ⁿ (R S) (T U) = normal-∩ⁿ R (T U)
normal-∩ⁿ never (T U) = never
normal-∩ⁿ unknown (T U) = T U
normal-∩ⁿ (R S) (T U) = (R S) (T U)
normal-∩ⁿ (R S) (T U) = (R S) (T U)
normal-∩ⁿ (R S) (T U) = normal-∩ⁿ R (T U)
normal-∪ⁿˢ S never = S
normal-∪ⁿˢ never number = never number
normal-∪ⁿˢ unknown number = unknown
normal-∪ⁿˢ (R S) number = (R S) number
normal-∪ⁿˢ (R S) number = (R S) number
normal-∪ⁿˢ (R number) number = R number
normal-∪ⁿˢ (R boolean) number = normal-∪ⁿˢ R number boolean
normal-∪ⁿˢ (R string) number = normal-∪ⁿˢ R number string
normal-∪ⁿˢ (R nil) number = normal-∪ⁿˢ R number nil
normal-∪ⁿˢ never boolean = never boolean
normal-∪ⁿˢ unknown boolean = unknown
normal-∪ⁿˢ (R S) boolean = (R S) boolean
normal-∪ⁿˢ (R S) boolean = (R S) boolean
normal-∪ⁿˢ (R number) boolean = normal-∪ⁿˢ R boolean number
normal-∪ⁿˢ (R boolean) boolean = R boolean
normal-∪ⁿˢ (R string) boolean = normal-∪ⁿˢ R boolean string
normal-∪ⁿˢ (R nil) boolean = normal-∪ⁿˢ R boolean nil
normal-∪ⁿˢ never string = never string
normal-∪ⁿˢ unknown string = unknown
normal-∪ⁿˢ (R S) string = (R S) string
normal-∪ⁿˢ (R S) string = (R S) string
normal-∪ⁿˢ (R number) string = normal-∪ⁿˢ R string number
normal-∪ⁿˢ (R boolean) string = normal-∪ⁿˢ R string boolean
normal-∪ⁿˢ (R string) string = R string
normal-∪ⁿˢ (R nil) string = normal-∪ⁿˢ R string nil
normal-∪ⁿˢ never nil = never nil
normal-∪ⁿˢ unknown nil = unknown
normal-∪ⁿˢ (R S) nil = (R S) nil
normal-∪ⁿˢ (R S) nil = (R S) nil
normal-∪ⁿˢ (R number) nil = normal-∪ⁿˢ R nil number
normal-∪ⁿˢ (R boolean) nil = normal-∪ⁿˢ R nil boolean
normal-∪ⁿˢ (R string) nil = normal-∪ⁿˢ R nil string
normal-∪ⁿˢ (R nil) nil = R nil
normal-∩ⁿˢ never number = never
normal-∩ⁿˢ never boolean = never
normal-∩ⁿˢ never string = never
normal-∩ⁿˢ never nil = never
normal-∩ⁿˢ unknown number = number
normal-∩ⁿˢ unknown boolean = boolean
normal-∩ⁿˢ unknown string = string
normal-∩ⁿˢ unknown nil = nil
normal-∩ⁿˢ (R S) number = never
normal-∩ⁿˢ (R S) boolean = never
normal-∩ⁿˢ (R S) string = never
normal-∩ⁿˢ (R S) nil = never
normal-∩ⁿˢ (R S) number = never
normal-∩ⁿˢ (R S) boolean = never
normal-∩ⁿˢ (R S) string = never
normal-∩ⁿˢ (R S) nil = never
normal-∩ⁿˢ (R number) number = number
normal-∩ⁿˢ (R boolean) number = normal-∩ⁿˢ R number
normal-∩ⁿˢ (R string) number = normal-∩ⁿˢ R number
normal-∩ⁿˢ (R nil) number = normal-∩ⁿˢ R number
normal-∩ⁿˢ (R number) boolean = normal-∩ⁿˢ R boolean
normal-∩ⁿˢ (R boolean) boolean = boolean
normal-∩ⁿˢ (R string) boolean = normal-∩ⁿˢ R boolean
normal-∩ⁿˢ (R nil) boolean = normal-∩ⁿˢ R boolean
normal-∩ⁿˢ (R number) string = normal-∩ⁿˢ R string
normal-∩ⁿˢ (R boolean) string = normal-∩ⁿˢ R string
normal-∩ⁿˢ (R string) string = string
normal-∩ⁿˢ (R nil) string = normal-∩ⁿˢ R string
normal-∩ⁿˢ (R number) nil = normal-∩ⁿˢ R nil
normal-∩ⁿˢ (R boolean) nil = normal-∩ⁿˢ R nil
normal-∩ⁿˢ (R string) nil = normal-∩ⁿˢ R nil
normal-∩ⁿˢ (R nil) nil = nil
normal-∪ᶠ (R S) (T U) = (normal-∩ⁿ R T) (normal-∪ⁿ S U)
normal-∪ᶠ (R S) (G H) = normal-∪ᶠ (R S) G normal-∪ᶠ (R S) H
normal-∪ᶠ (E F) G = normal-∪ᶠ E G normal-∪ᶠ F G
scalar-∩-fun-<:-never : {F S} FunType F Scalar S (F S) <: never
scalar-∩-fun-<:-never (T U) S = scalar-∩-function-<:-never S
scalar-∩-fun-<:-never (F G) S = <:-trans (<:-intersect <:-∩-left <:-refl) (scalar-∩-fun-<:-never F S)
flipper : {S T U} ((S T) U) <: ((S U) T)
flipper = <:-trans <:--assocr (<:-trans (<:-union <:-refl <:--symm) <:--assocl)
∩-<:-∩ⁿ : {S T} Normal S Normal T (S T) <: (S ∩ⁿ T)
∩ⁿ-<:-∩ : {S T} Normal S Normal T (S ∩ⁿ T) <: (S T)
∩-<:-∩ⁿˢ : {S T} Normal S Scalar T (S T) <: (S ∩ⁿˢ T)
∩ⁿˢ-<:-∩ : {S T} Normal S Scalar T (S ∩ⁿˢ T) <: (S T)
∪ᶠ-<:- : {F G} FunType F FunType G (F ∪ᶠ G) <: (F G)
∪ⁿ-<:- : {S T} Normal S Normal T (S ∪ⁿ T) <: (S T)
-<:-∪ⁿ : {S T} Normal S Normal T (S T) <: (S ∪ⁿ T)
∪ⁿˢ-<:- : {S T} Normal S OptScalar T (S ∪ⁿˢ T) <: (S T)
-<:-∪ⁿˢ : {S T} Normal S OptScalar T (S T) <: (S ∪ⁿˢ T)
∩-<:-∩ⁿ S never = <:-∩-right
∩-<:-∩ⁿ S unknown = <:-∩-left
∩-<:-∩ⁿ S (T U) = <:-trans <:-∩-distl- (<:-trans (<:-union (∩-<:-∩ⁿ S T) (∩-<:-∩ⁿˢ S U)) (-<:-∪ⁿˢ (normal-∩ⁿ S T) (normal-∩ⁿˢ S U)) )
∩-<:-∩ⁿ never (T U) = <:-∩-left
∩-<:-∩ⁿ unknown (T U) = <:-∩-right
∩-<:-∩ⁿ (R S) (T U) = <:-refl
∩-<:-∩ⁿ (R S) (T U) = <:-refl
∩-<:-∩ⁿ (R S) (T U) = <:-trans <:-∩-distr- (<:-trans (<:-union (∩-<:-∩ⁿ R (T U)) (<:-trans <:-∩-symm (∩-<:-∩ⁿˢ (T U) S))) (<:--lub <:-refl <:-never))
∩-<:-∩ⁿ never (T U) = <:-∩-left
∩-<:-∩ⁿ unknown (T U) = <:-∩-right
∩-<:-∩ⁿ (R S) (T U) = <:-refl
∩-<:-∩ⁿ (R S) (T U) = <:-refl
∩-<:-∩ⁿ (R S) (T U) = <:-trans <:-∩-distr- (<:-trans (<:-union (∩-<:-∩ⁿ R (T U)) (<:-trans <:-∩-symm (∩-<:-∩ⁿˢ (T U) S))) (<:--lub <:-refl <:-never))
∩ⁿ-<:-∩ S never = <:-never
∩ⁿ-<:-∩ S unknown = <:-∩-glb <:-refl <:-unknown
∩ⁿ-<:-∩ S (T U) = <:-trans (∪ⁿˢ-<:- (normal-∩ⁿ S T) (normal-∩ⁿˢ S U)) (<:-trans (<:-union (∩ⁿ-<:-∩ S T) (∩ⁿˢ-<:-∩ S U)) ∩-distl--<:)
∩ⁿ-<:-∩ never (T U) = <:-never
∩ⁿ-<:-∩ unknown (T U) = <:-∩-glb <:-unknown <:-refl
∩ⁿ-<:-∩ (R S) (T U) = <:-refl
∩ⁿ-<:-∩ (R S) (T U) = <:-refl
∩ⁿ-<:-∩ (R S) (T U) = <:-trans (∩ⁿ-<:-∩ R (T U)) (<:-∩-glb (<:-trans <:-∩-left <:--left) <:-∩-right)
∩ⁿ-<:-∩ never (T U) = <:-never
∩ⁿ-<:-∩ unknown (T U) = <:-∩-glb <:-unknown <:-refl
∩ⁿ-<:-∩ (R S) (T U) = <:-refl
∩ⁿ-<:-∩ (R S) (T U) = <:-refl
∩ⁿ-<:-∩ (R S) (T U) = <:-trans (∩ⁿ-<:-∩ R (T U)) (<:-∩-glb (<:-trans <:-∩-left <:--left) <:-∩-right)
∩-<:-∩ⁿˢ never number = <:-∩-left
∩-<:-∩ⁿˢ never boolean = <:-∩-left
∩-<:-∩ⁿˢ never string = <:-∩-left
∩-<:-∩ⁿˢ never nil = <:-∩-left
∩-<:-∩ⁿˢ unknown T = <:-∩-right
∩-<:-∩ⁿˢ (R S) T = scalar-∩-fun-<:-never (R S) T
∩-<:-∩ⁿˢ (F G) T = scalar-∩-fun-<:-never (F G) T
∩-<:-∩ⁿˢ (R number) number = <:-∩-right
∩-<:-∩ⁿˢ (R boolean) number = <:-trans <:-∩-distr- (<:--lub (∩-<:-∩ⁿˢ R number) (scalar-≢-∩-<:-never boolean number (λ ())))
∩-<:-∩ⁿˢ (R string) number = <:-trans <:-∩-distr- (<:--lub (∩-<:-∩ⁿˢ R number) (scalar-≢-∩-<:-never string number (λ ())))
∩-<:-∩ⁿˢ (R nil) number = <:-trans <:-∩-distr- (<:--lub (∩-<:-∩ⁿˢ R number) (scalar-≢-∩-<:-never nil number (λ ())))
∩-<:-∩ⁿˢ (R number) boolean = <:-trans <:-∩-distr- (<:--lub (∩-<:-∩ⁿˢ R boolean) (scalar-≢-∩-<:-never number boolean (λ ())))
∩-<:-∩ⁿˢ (R boolean) boolean = <:-∩-right
∩-<:-∩ⁿˢ (R string) boolean = <:-trans <:-∩-distr- (<:--lub (∩-<:-∩ⁿˢ R boolean) (scalar-≢-∩-<:-never string boolean (λ ())))
∩-<:-∩ⁿˢ (R nil) boolean = <:-trans <:-∩-distr- (<:--lub (∩-<:-∩ⁿˢ R boolean) (scalar-≢-∩-<:-never nil boolean (λ ())))
∩-<:-∩ⁿˢ (R number) string = <:-trans <:-∩-distr- (<:--lub (∩-<:-∩ⁿˢ R string) (scalar-≢-∩-<:-never number string (λ ())))
∩-<:-∩ⁿˢ (R boolean) string = <:-trans <:-∩-distr- (<:--lub (∩-<:-∩ⁿˢ R string) (scalar-≢-∩-<:-never boolean string (λ ())))
∩-<:-∩ⁿˢ (R string) string = <:-∩-right
∩-<:-∩ⁿˢ (R nil) string = <:-trans <:-∩-distr- (<:--lub (∩-<:-∩ⁿˢ R string) (scalar-≢-∩-<:-never nil string (λ ())))
∩-<:-∩ⁿˢ (R number) nil = <:-trans <:-∩-distr- (<:--lub (∩-<:-∩ⁿˢ R nil) (scalar-≢-∩-<:-never number nil (λ ())))
∩-<:-∩ⁿˢ (R boolean) nil = <:-trans <:-∩-distr- (<:--lub (∩-<:-∩ⁿˢ R nil) (scalar-≢-∩-<:-never boolean nil (λ ())))
∩-<:-∩ⁿˢ (R string) nil = <:-trans <:-∩-distr- (<:--lub (∩-<:-∩ⁿˢ R nil) (scalar-≢-∩-<:-never string nil (λ ())))
∩-<:-∩ⁿˢ (R nil) nil = <:-∩-right
∩ⁿˢ-<:-∩ never T = <:-never
∩ⁿˢ-<:-∩ unknown T = <:-∩-glb <:-unknown <:-refl
∩ⁿˢ-<:-∩ (R S) T = <:-never
∩ⁿˢ-<:-∩ (F G) T = <:-never
∩ⁿˢ-<:-∩ (R number) number = <:-∩-glb <:--right <:-refl
∩ⁿˢ-<:-∩ (R boolean) number = <:-trans (∩ⁿˢ-<:-∩ R number) (<:-intersect <:--left <:-refl)
∩ⁿˢ-<:-∩ (R string) number = <:-trans (∩ⁿˢ-<:-∩ R number) (<:-intersect <:--left <:-refl)
∩ⁿˢ-<:-∩ (R nil) number = <:-trans (∩ⁿˢ-<:-∩ R number) (<:-intersect <:--left <:-refl)
∩ⁿˢ-<:-∩ (R number) boolean = <:-trans (∩ⁿˢ-<:-∩ R boolean) (<:-intersect <:--left <:-refl)
∩ⁿˢ-<:-∩ (R boolean) boolean = <:-∩-glb <:--right <:-refl
∩ⁿˢ-<:-∩ (R string) boolean = <:-trans (∩ⁿˢ-<:-∩ R boolean) (<:-intersect <:--left <:-refl)
∩ⁿˢ-<:-∩ (R nil) boolean = <:-trans (∩ⁿˢ-<:-∩ R boolean) (<:-intersect <:--left <:-refl)
∩ⁿˢ-<:-∩ (R number) string = <:-trans (∩ⁿˢ-<:-∩ R string) (<:-intersect <:--left <:-refl)
∩ⁿˢ-<:-∩ (R boolean) string = <:-trans (∩ⁿˢ-<:-∩ R string) (<:-intersect <:--left <:-refl)
∩ⁿˢ-<:-∩ (R string) string = <:-∩-glb <:--right <:-refl
∩ⁿˢ-<:-∩ (R nil) string = <:-trans (∩ⁿˢ-<:-∩ R string) (<:-intersect <:--left <:-refl)
∩ⁿˢ-<:-∩ (R number) nil = <:-trans (∩ⁿˢ-<:-∩ R nil) (<:-intersect <:--left <:-refl)
∩ⁿˢ-<:-∩ (R boolean) nil = <:-trans (∩ⁿˢ-<:-∩ R nil) (<:-intersect <:--left <:-refl)
∩ⁿˢ-<:-∩ (R string) nil = <:-trans (∩ⁿˢ-<:-∩ R nil) (<:-intersect <:--left <:-refl)
∩ⁿˢ-<:-∩ (R nil) nil = <:-∩-glb <:--right <:-refl
∪ᶠ-<:- (R S) (T U) = <:-trans (<:-function (∩-<:-∩ⁿ R T) (∪ⁿ-<:- S U)) <:-function--∩
∪ᶠ-<:- (R S) (G H) = <:-trans (<:-intersect (∪ᶠ-<:- (R S) G) (∪ᶠ-<:- (R S) H)) -distl-∩-<:
∪ᶠ-<:- (E F) G = <:-trans (<:-intersect (∪ᶠ-<:- E G) (∪ᶠ-<:- F G)) -distr-∩-<:
-<:-∪ᶠ : {F G} FunType F FunType G (F G) <: (F ∪ᶠ G)
-<:-∪ᶠ (R S) (T U) = <:-trans <:-function- (<:-function (∩ⁿ-<:-∩ R T) (-<:-∪ⁿ S U))
-<:-∪ᶠ (R S) (G H) = <:-trans <:--distl-∩ (<:-intersect (-<:-∪ᶠ (R S) G) (-<:-∪ᶠ (R S) H))
-<:-∪ᶠ (E F) G = <:-trans <:--distr-∩ (<:-intersect (-<:-∪ᶠ E G) (-<:-∪ᶠ F G))
∪ⁿˢ-<:- S never = <:--left
∪ⁿˢ-<:- never number = <:-refl
∪ⁿˢ-<:- never boolean = <:-refl
∪ⁿˢ-<:- never string = <:-refl
∪ⁿˢ-<:- never nil = <:-refl
∪ⁿˢ-<:- unknown number = <:--left
∪ⁿˢ-<:- unknown boolean = <:--left
∪ⁿˢ-<:- unknown string = <:--left
∪ⁿˢ-<:- unknown nil = <:--left
∪ⁿˢ-<:- (R S) number = <:-refl
∪ⁿˢ-<:- (R S) boolean = <:-refl
∪ⁿˢ-<:- (R S) string = <:-refl
∪ⁿˢ-<:- (R S) nil = <:-refl
∪ⁿˢ-<:- (R S) number = <:-refl
∪ⁿˢ-<:- (R S) boolean = <:-refl
∪ⁿˢ-<:- (R S) string = <:-refl
∪ⁿˢ-<:- (R S) nil = <:-refl
∪ⁿˢ-<:- (R number) number = <:-union <:--left <:-refl
∪ⁿˢ-<:- (R boolean) number = <:-trans (<:-union (∪ⁿˢ-<:- R number) <:-refl) flipper
∪ⁿˢ-<:- (R string) number = <:-trans (<:-union (∪ⁿˢ-<:- R number) <:-refl) flipper
∪ⁿˢ-<:- (R nil) number = <:-trans (<:-union (∪ⁿˢ-<:- R number) <:-refl) flipper
∪ⁿˢ-<:- (R number) boolean = <:-trans (<:-union (∪ⁿˢ-<:- R boolean) <:-refl) flipper
∪ⁿˢ-<:- (R boolean) boolean = <:-union <:--left <:-refl
∪ⁿˢ-<:- (R string) boolean = <:-trans (<:-union (∪ⁿˢ-<:- R boolean) <:-refl) flipper
∪ⁿˢ-<:- (R nil) boolean = <:-trans (<:-union (∪ⁿˢ-<:- R boolean) <:-refl) flipper
∪ⁿˢ-<:- (R number) string = <:-trans (<:-union (∪ⁿˢ-<:- R string) <:-refl) flipper
∪ⁿˢ-<:- (R boolean) string = <:-trans (<:-union (∪ⁿˢ-<:- R string) <:-refl) flipper
∪ⁿˢ-<:- (R string) string = <:-union <:--left <:-refl
∪ⁿˢ-<:- (R nil) string = <:-trans (<:-union (∪ⁿˢ-<:- R string) <:-refl) flipper
∪ⁿˢ-<:- (R number) nil = <:-trans (<:-union (∪ⁿˢ-<:- R nil) <:-refl) flipper
∪ⁿˢ-<:- (R boolean) nil = <:-trans (<:-union (∪ⁿˢ-<:- R nil) <:-refl) flipper
∪ⁿˢ-<:- (R string) nil = <:-trans (<:-union (∪ⁿˢ-<:- R nil) <:-refl) flipper
∪ⁿˢ-<:- (R nil) nil = <:-union <:--left <:-refl
-<:-∪ⁿˢ T never = <:--lub <:-refl <:-never
-<:-∪ⁿˢ never number = <:-refl
-<:-∪ⁿˢ never boolean = <:-refl
-<:-∪ⁿˢ never string = <:-refl
-<:-∪ⁿˢ never nil = <:-refl
-<:-∪ⁿˢ unknown number = <:-unknown
-<:-∪ⁿˢ unknown boolean = <:-unknown
-<:-∪ⁿˢ unknown string = <:-unknown
-<:-∪ⁿˢ unknown nil = <:-unknown
-<:-∪ⁿˢ (R S) number = <:-refl
-<:-∪ⁿˢ (R S) boolean = <:-refl
-<:-∪ⁿˢ (R S) string = <:-refl
-<:-∪ⁿˢ (R S) nil = <:-refl
-<:-∪ⁿˢ (R S) number = <:-refl
-<:-∪ⁿˢ (R S) boolean = <:-refl
-<:-∪ⁿˢ (R S) string = <:-refl
-<:-∪ⁿˢ (R S) nil = <:-refl
-<:-∪ⁿˢ (R number) number = <:--lub <:-refl <:--right
-<:-∪ⁿˢ (R boolean) number = <:-trans flipper (<:-union (-<:-∪ⁿˢ R number) <:-refl)
-<:-∪ⁿˢ (R string) number = <:-trans flipper (<:-union (-<:-∪ⁿˢ R number) <:-refl)
-<:-∪ⁿˢ (R nil) number = <:-trans flipper (<:-union (-<:-∪ⁿˢ R number) <:-refl)
-<:-∪ⁿˢ (R number) boolean = <:-trans flipper (<:-union (-<:-∪ⁿˢ R boolean) <:-refl)
-<:-∪ⁿˢ (R boolean) boolean = <:--lub <:-refl <:--right
-<:-∪ⁿˢ (R string) boolean = <:-trans flipper (<:-union (-<:-∪ⁿˢ R boolean) <:-refl)
-<:-∪ⁿˢ (R nil) boolean = <:-trans flipper (<:-union (-<:-∪ⁿˢ R boolean) <:-refl)
-<:-∪ⁿˢ (R number) string = <:-trans flipper (<:-union (-<:-∪ⁿˢ R string) <:-refl)
-<:-∪ⁿˢ (R boolean) string = <:-trans flipper (<:-union (-<:-∪ⁿˢ R string) <:-refl)
-<:-∪ⁿˢ (R string) string = <:--lub <:-refl <:--right
-<:-∪ⁿˢ (R nil) string = <:-trans flipper (<:-union (-<:-∪ⁿˢ R string) <:-refl)
-<:-∪ⁿˢ (R number) nil = <:-trans flipper (<:-union (-<:-∪ⁿˢ R nil) <:-refl)
-<:-∪ⁿˢ (R boolean) nil = <:-trans flipper (<:-union (-<:-∪ⁿˢ R nil) <:-refl)
-<:-∪ⁿˢ (R string) nil = <:-trans flipper (<:-union (-<:-∪ⁿˢ R nil) <:-refl)
-<:-∪ⁿˢ (R nil) nil = <:--lub <:-refl <:--right
∪ⁿ-<:- S never = <:--left
∪ⁿ-<:- S unknown = <:--right
∪ⁿ-<:- never (T U) = <:--right
∪ⁿ-<:- unknown (T U) = <:--left
∪ⁿ-<:- (R S) (T U) = ∪ᶠ-<:- (R S) (T U)
∪ⁿ-<:- (R S) (T U) = ∪ᶠ-<:- (R S) (T U)
∪ⁿ-<:- (R S) (T U) = <:-trans (<:-union (∪ⁿ-<:- R (T U)) <:-refl) (<:--lub (<:--lub (<:-trans <:--left <:--left) <:--right) (<:-trans <:--right <:--left))
∪ⁿ-<:- never (T U) = <:--right
∪ⁿ-<:- unknown (T U) = <:--left
∪ⁿ-<:- (R S) (T U) = ∪ᶠ-<:- (R S) (T U)
∪ⁿ-<:- (R S) (T U) = ∪ᶠ-<:- (R S) (T U)
∪ⁿ-<:- (R S) (T U) = <:-trans (<:-union (∪ⁿ-<:- R (T U)) <:-refl) (<:--lub (<:--lub (<:-trans <:--left <:--left) <:--right) (<:-trans <:--right <:--left))
∪ⁿ-<:- S (T U) = <:--lub (<:-trans (∪ⁿ-<:- S T) (<:-union <:-refl <:--left)) (<:-trans <:--right <:--right)
-<:-∪ⁿ S never = <:--lub <:-refl <:-never
-<:-∪ⁿ S unknown = <:-unknown
-<:-∪ⁿ never (T U) = <:--lub <:-never <:-refl
-<:-∪ⁿ unknown (T U) = <:-unknown
-<:-∪ⁿ (R S) (T U) = -<:-∪ᶠ (R S) (T U)
-<:-∪ⁿ (R S) (T U) = -<:-∪ᶠ (R S) (T U)
-<:-∪ⁿ (R S) (T U) = <:-trans <:--assocr (<:-trans (<:-union <:-refl <:--symm) (<:-trans <:--assocl (<:-union (-<:-∪ⁿ R (T U)) <:-refl)))
-<:-∪ⁿ never (T U) = <:--lub <:-never <:-refl
-<:-∪ⁿ unknown (T U) = <:-unknown
-<:-∪ⁿ (R S) (T U) = -<:-∪ᶠ (R S) (T U)
-<:-∪ⁿ (R S) (T U) = -<:-∪ᶠ (R S) (T U)
-<:-∪ⁿ (R S) (T U) = <:-trans <:--assocr (<:-trans (<:-union <:-refl <:--symm) (<:-trans <:--assocl (<:-union (-<:-∪ⁿ R (T U)) <:-refl)))
-<:-∪ⁿ never (T U) = <:-trans <:--assocl (<:-union (-<:-∪ⁿ never T) <:-refl)
-<:-∪ⁿ unknown (T U) = <:-trans <:--assocl (<:-union (-<:-∪ⁿ unknown T) <:-refl)
-<:-∪ⁿ (R S) (T U) = <:-trans <:--assocl (<:-union (-<:-∪ⁿ (R S) T) <:-refl)
-<:-∪ⁿ (R S) (T U) = <:-trans <:--assocl (<:-union (-<:-∪ⁿ (R S) T) <:-refl)
-<:-∪ⁿ (R S) (T U) = <:-trans <:--assocl (<:-union (-<:-∪ⁿ (R S) T) <:-refl)
normalize-<: : T normalize T <: T
<:-normalize : T T <: normalize T
<:-normalize nil = <:--right
<:-normalize (S T) = <:-function (normalize-<: S) (<:-normalize T)
<:-normalize never = <:-refl
<:-normalize unknown = <:-refl
<:-normalize boolean = <:--right
<:-normalize number = <:--right
<:-normalize string = <:--right
<:-normalize (S T) = <:-trans (<:-union (<:-normalize S) (<:-normalize T)) (-<:-∪ⁿ (normal S) (normal T))
<:-normalize (S T) = <:-trans (<:-intersect (<:-normalize S) (<:-normalize T)) (∩-<:-∩ⁿ (normal S) (normal T))
normalize-<: nil = <:--lub <:-never <:-refl
normalize-<: (S T) = <:-function (<:-normalize S) (normalize-<: T)
normalize-<: never = <:-refl
normalize-<: unknown = <:-refl
normalize-<: boolean = <:--lub <:-never <:-refl
normalize-<: number = <:--lub <:-never <:-refl
normalize-<: string = <:--lub <:-never <:-refl
normalize-<: (S T) = <:-trans (∪ⁿ-<:- (normal S) (normal T)) (<:-union (normalize-<: S) (normalize-<: T))
normalize-<: (S T) = <:-trans (∩ⁿ-<:-∩ (normal S) (normal T)) (<:-intersect (normalize-<: S) (normalize-<: T))

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{-# OPTIONS --rewriting #-}
module Properties.TypeSaturation where
open import Agda.Builtin.Equality using (_≡_; refl)
open import FFI.Data.Either using (Either; Left; Right)
open import Luau.Subtyping using (Tree; Language; ¬Language; _<:_; _≮:_; witness; scalar; function; function-err; function-ok; function-ok₁; function-ok₂; scalar-function; _,_; never)
open import Luau.Type using (Type; _⇒_; _∩_; __; never; unknown)
open import Luau.TypeNormalization using (_∩ⁿ_; _ⁿ_)
open import Luau.TypeSaturation using (_⋓_; _⋒_; _∩ᵘ_; _∩ⁱ_; -saturate; ∩-saturate; saturate)
open import Properties.Subtyping using (dec-language; language-comp; <:-impl-⊇; <:-refl; <:-trans; <:-trans-≮:; <:-impl-¬≮: ; <:-never; <:-unknown; <:-function; <:-union; <:--symm; <:--left; <:--right; <:--lub; <:--assocl; <:--assocr; <:-intersect; <:-∩-symm; <:-∩-left; <:-∩-right; <:-∩-glb; ≮:-function-left; ≮:-function-right; <:-function-∩-; <:-function-∩-∩; <:-∩-assocl; <:-∩-assocr; ∩-<:-; <:-∩-distl-; ∩-distl--<:; <:-∩-distr-; ∩-distr--<:)
open import Properties.TypeNormalization using (Normal; FunType; _⇒_; _∩_; __; never; unknown; normal-∪ⁿ; normal-∩ⁿ; ∪ⁿ-<:-; -<:-∪ⁿ; ∩ⁿ-<:-∩; ∩-<:-∩ⁿ)
open import Properties.Contradiction using (CONTRADICTION)
open import Properties.Functions using (_∘_)
-- Saturation preserves normalization
normal-⋒ : {F G} FunType F FunType G FunType (F G)
normal-⋒ (R S) (T U) = (normal-∩ⁿ R T) (normal-∩ⁿ S U)
normal-⋒ (R S) (G H) = normal-⋒ (R S) G normal-⋒ (R S) H
normal-⋒ (E F) G = normal-⋒ E G normal-⋒ F G
normal-⋓ : {F G} FunType F FunType G FunType (F G)
normal-⋓ (R S) (T U) = (normal-∪ⁿ R T) (normal-∪ⁿ S U)
normal-⋓ (R S) (G H) = normal-⋓ (R S) G normal-⋓ (R S) H
normal-⋓ (E F) G = normal-⋓ E G normal-⋓ F G
normal-∩-saturate : {F} FunType F FunType (∩-saturate F)
normal-∩-saturate (S T) = S T
normal-∩-saturate (F G) = (normal-∩-saturate F normal-∩-saturate G) normal-⋒ (normal-∩-saturate F) (normal-∩-saturate G)
normal--saturate : {F} FunType F FunType (-saturate F)
normal--saturate (S T) = S T
normal--saturate (F G) = (normal--saturate F normal--saturate G) normal-⋓ (normal--saturate F) (normal--saturate G)
normal-saturate : {F} FunType F FunType (saturate F)
normal-saturate F = normal--saturate (normal-∩-saturate F)
-- Saturation resects subtyping
-saturate-<: : {F} FunType F -saturate F <: F
-saturate-<: (S T) = <:-refl
-saturate-<: (F G) = <:-trans <:-∩-left (<:-intersect (-saturate-<: F) (-saturate-<: G))
∩-saturate-<: : {F} FunType F ∩-saturate F <: F
∩-saturate-<: (S T) = <:-refl
∩-saturate-<: (F G) = <:-trans <:-∩-left (<:-intersect (∩-saturate-<: F) (∩-saturate-<: G))
saturate-<: : {F} FunType F saturate F <: F
saturate-<: F = <:-trans (-saturate-<: (normal-∩-saturate F)) (∩-saturate-<: F)
∩-<:-⋓ : {F G} FunType F FunType G (F G) <: (F G)
∩-<:-⋓ (R S) (T U) = <:-trans <:-function-∩- (<:-function (∪ⁿ-<:- R T) (-<:-∪ⁿ S U))
∩-<:-⋓ (R S) (G H) = <:-trans (<:-∩-glb (<:-intersect <:-refl <:-∩-left) (<:-intersect <:-refl <:-∩-right)) (<:-intersect (∩-<:-⋓ (R S) G) (∩-<:-⋓ (R S) H))
∩-<:-⋓ (E F) G = <:-trans (<:-∩-glb (<:-intersect <:-∩-left <:-refl) (<:-intersect <:-∩-right <:-refl)) (<:-intersect (∩-<:-⋓ E G) (∩-<:-⋓ F G))
∩-<:-⋒ : {F G} FunType F FunType G (F G) <: (F G)
∩-<:-⋒ (R S) (T U) = <:-trans <:-function-∩-∩ (<:-function (∩ⁿ-<:-∩ R T) (∩-<:-∩ⁿ S U))
∩-<:-⋒ (R S) (G H) = <:-trans (<:-∩-glb (<:-intersect <:-refl <:-∩-left) (<:-intersect <:-refl <:-∩-right)) (<:-intersect (∩-<:-⋒ (R S) G) (∩-<:-⋒ (R S) H))
∩-<:-⋒ (E F) G = <:-trans (<:-∩-glb (<:-intersect <:-∩-left <:-refl) (<:-intersect <:-∩-right <:-refl)) (<:-intersect (∩-<:-⋒ E G) (∩-<:-⋒ F G))
<:--saturate : {F} FunType F F <: -saturate F
<:--saturate (S T) = <:-refl
<:--saturate (F G) = <:-∩-glb (<:-intersect (<:--saturate F) (<:--saturate G)) (<:-trans (<:-intersect (<:--saturate F) (<:--saturate G)) (∩-<:-⋓ (normal--saturate F) (normal--saturate G)))
<:-∩-saturate : {F} FunType F F <: ∩-saturate F
<:-∩-saturate (S T) = <:-refl
<:-∩-saturate (F G) = <:-∩-glb (<:-intersect (<:-∩-saturate F) (<:-∩-saturate G)) (<:-trans (<:-intersect (<:-∩-saturate F) (<:-∩-saturate G)) (∩-<:-⋒ (normal-∩-saturate F) (normal-∩-saturate G)))
<:-saturate : {F} FunType F F <: saturate F
<:-saturate F = <:-trans (<:-∩-saturate F) (<:--saturate (normal-∩-saturate F))
-- Overloads F is the set of overloads of F
data Overloads : Type Type Set where
here : {S T} Overloads (S T) (S T)
left : {S T F G} Overloads F (S T) Overloads (F G) (S T)
right : {S T F G} Overloads G (S T) Overloads (F G) (S T)
normal-overload-src : {F S T} FunType F Overloads F (S T) Normal S
normal-overload-src (S T) here = S
normal-overload-src (F G) (left o) = normal-overload-src F o
normal-overload-src (F G) (right o) = normal-overload-src G o
normal-overload-tgt : {F S T} FunType F Overloads F (S T) Normal T
normal-overload-tgt (S T) here = T
normal-overload-tgt (F G) (left o) = normal-overload-tgt F o
normal-overload-tgt (F G) (right o) = normal-overload-tgt G o
-- An inductive presentation of the overloads of F ⋓ G
data -Lift (P Q : Type Set) : Type Set where
union : {R S T U}
P (R S)
Q (T U)
--------------------
-Lift P Q ((R T) (S U))
-- An inductive presentation of the overloads of F ⋒ G
data ∩-Lift (P Q : Type Set) : Type Set where
intersect : {R S T U}
P (R S)
Q (T U)
--------------------
∩-Lift P Q ((R T) (S U))
-- An inductive presentation of the overloads of -saturate F
data -Saturate (P : Type Set) : Type Set where
base : {S T}
P (S T)
--------------------
-Saturate P (S T)
union : {R S T U}
-Saturate P (R S)
-Saturate P (T U)
--------------------
-Saturate P ((R T) (S U))
-- An inductive presentation of the overloads of ∩-saturate F
data ∩-Saturate (P : Type Set) : Type Set where
base : {S T}
P (S T)
--------------------
∩-Saturate P (S T)
intersect : {R S T U}
∩-Saturate P (R S)
∩-Saturate P (T U)
--------------------
∩-Saturate P ((R T) (S U))
-- The <:-up-closure of a set of function types
data <:-Close (P : Type Set) : Type Set where
defn : {R S T U}
P (S T)
R <: S
T <: U
------------------
<:-Close P (R U)
-- F ⊆ᵒ G whenever every overload of F is an overload of G
_⊆ᵒ_ : Type Type Set
F ⊆ᵒ G = {S T} Overloads F (S T) Overloads G (S T)
-- F <:ᵒ G when every overload of G is a supertype of an overload of F
_<:ᵒ_ : Type Type Set
_<:ᵒ_ F G = {S T} Overloads G (S T) <:-Close (Overloads F) (S T)
-- P ⊂: Q when any type in P is a subtype of some type in Q
_⊂:_ : (Type Set) (Type Set) Set
P ⊂: Q = {S T} P (S T) <:-Close Q (S T)
-- <:-Close is a monad
just : {P S T} P (S T) <:-Close P (S T)
just p = defn p <:-refl <:-refl
infixl 5 _>>=_ _>>=ˡ_ _>>=ʳ_
_>>=_ : {P Q S T} <:-Close P (S T) (P ⊂: Q) <:-Close Q (S T)
(defn p p₁ p₂) >>= P⊂Q with P⊂Q p
(defn p p₁ p₂) >>= P⊂Q | defn q q₁ q₂ = defn q (<:-trans p₁ q₁) (<:-trans q₂ p₂)
_>>=ˡ_ : {P R S T} <:-Close P (S T) (R <: S) <:-Close P (R T)
(defn p p₁ p₂) >>=ˡ q = defn p (<:-trans q p₁) p₂
_>>=ʳ_ : {P S T U} <:-Close P (S T) (T <: U) <:-Close P (S U)
(defn p p₁ p₂) >>=ʳ q = defn p p₁ (<:-trans p₂ q)
-- Properties of ⊂:
⊂:-refl : {P} P ⊂: P
:-refl p = just p
_[]_ : {P Q R S T U} <:-Close P (R S) <:-Close Q (T U) <:-Close (-Lift P Q) ((R T) (S U))
(defn p p₁ p₂) [] (defn q q₁ q₂) = defn (union p q) (<:-union p₁ q₁) (<:-union p₂ q₂)
_[∩]_ : {P Q R S T U} <:-Close P (R S) <:-Close Q (T U) <:-Close (∩-Lift P Q) ((R T) (S U))
(defn p p₁ p₂) [∩] (defn q q₁ q₂) = defn (intersect p q) (<:-intersect p₁ q₁) (<:-intersect p₂ q₂)
⊂:-∩-saturate-inj : {P} P ⊂: ∩-Saturate P
:-∩-saturate-inj p = defn (base p) <:-refl <:-refl
⊂:--saturate-inj : {P} P ⊂: -Saturate P
:--saturate-inj p = just (base p)
⊂:-∩-lift-saturate : {P} ∩-Lift (∩-Saturate P) (∩-Saturate P) ⊂: ∩-Saturate P
:-∩-lift-saturate (intersect p q) = just (intersect p q)
⊂:--lift-saturate : {P} -Lift (-Saturate P) (-Saturate P) ⊂: -Saturate P
:--lift-saturate (union p q) = just (union p q)
⊂:-∩-lift : {P Q R S} (P ⊂: Q) (R ⊂: S) (∩-Lift P R ⊂: ∩-Lift Q S)
:-∩-lift P⊂Q R⊂S (intersect n o) = P⊂Q n [∩] R⊂S o
⊂:--lift : {P Q R S} (P ⊂: Q) (R ⊂: S) (-Lift P R ⊂: -Lift Q S)
:--lift P⊂Q R⊂S (union n o) = P⊂Q n [] R⊂S o
⊂:-∩-saturate : {P Q} (P ⊂: Q) (∩-Saturate P ⊂: ∩-Saturate Q)
:-∩-saturate P⊂Q (base p) = P⊂Q p >>= ⊂:-∩-saturate-inj
:-∩-saturate P⊂Q (intersect p q) = (⊂:-∩-saturate P⊂Q p [∩] ⊂:-∩-saturate P⊂Q q) >>= ⊂:-∩-lift-saturate
⊂:--saturate : {P Q} (P ⊂: Q) (-Saturate P ⊂: -Saturate Q)
:--saturate P⊂Q (base p) = P⊂Q p >>= ⊂:--saturate-inj
:--saturate P⊂Q (union p q) = (⊂:--saturate P⊂Q p [] ⊂:--saturate P⊂Q q) >>= ⊂:--lift-saturate
⊂:-∩-saturate-indn : {P Q} (P ⊂: Q) (∩-Lift Q Q ⊂: Q) (∩-Saturate P ⊂: Q)
:-∩-saturate-indn P⊂Q QQ⊂Q (base p) = P⊂Q p
:-∩-saturate-indn P⊂Q QQ⊂Q (intersect p q) = (⊂:-∩-saturate-indn P⊂Q QQ⊂Q p [∩] ⊂:-∩-saturate-indn P⊂Q QQ⊂Q q) >>= QQ⊂Q
⊂:--saturate-indn : {P Q} (P ⊂: Q) (-Lift Q Q ⊂: Q) (-Saturate P ⊂: Q)
:--saturate-indn P⊂Q QQ⊂Q (base p) = P⊂Q p
:--saturate-indn P⊂Q QQ⊂Q (union p q) = (⊂:--saturate-indn P⊂Q QQ⊂Q p [] ⊂:--saturate-indn P⊂Q QQ⊂Q q) >>= QQ⊂Q
-saturate-resp-∩-saturation : {P} (∩-Lift P P ⊂: P) (∩-Lift (-Saturate P) (-Saturate P) ⊂: -Saturate P)
-saturate-resp-∩-saturation ∩P⊂P (intersect (base p) (base q)) = ∩P⊂P (intersect p q) >>= ⊂:--saturate-inj
-saturate-resp-∩-saturation ∩P⊂P (intersect p (union q q₁)) = (-saturate-resp-∩-saturation ∩P⊂P (intersect p q) [] -saturate-resp-∩-saturation ∩P⊂P (intersect p q₁)) >>= ⊂:--lift-saturate >>=ˡ <:-∩-distl- >>=ʳ ∩-distl--<:
-saturate-resp-∩-saturation ∩P⊂P (intersect (union p p₁) q) = (-saturate-resp-∩-saturation ∩P⊂P (intersect p q) [] -saturate-resp-∩-saturation ∩P⊂P (intersect p₁ q)) >>= ⊂:--lift-saturate >>=ˡ <:-∩-distr- >>=ʳ ∩-distr--<:
ov-language : {F t} FunType F ( {S T} Overloads F (S T) Language (S T) t) Language F t
ov-language (S T) p = p here
ov-language (F G) p = (ov-language F (p left) , ov-language G (p right))
ov-<: : {F R S T U} FunType F Overloads F (R S) ((R S) <: (T U)) F <: (T U)
ov-<: F here p = p
ov-<: (F G) (left o) p = <:-trans <:-∩-left (ov-<: F o p)
ov-<: (F G) (right o) p = <:-trans <:-∩-right (ov-<: G o p)
<:ᵒ-impl-<: : {F G} FunType F FunType G (F <:ᵒ G) (F <: G)
<:ᵒ-impl-<: F (T U) F<G with F<G here
<:ᵒ-impl-<: F (T U) F<G | defn o o₁ o₂ = ov-<: F o (<:-function o₁ o₂)
<:ᵒ-impl-<: F (G H) F<G = <:-∩-glb (<:ᵒ-impl-<: F G (F<G left)) (<:ᵒ-impl-<: F H (F<G right))
⊂:-overloads-left : {F G} Overloads F ⊂: Overloads (F G)
:-overloads-left p = just (left p)
⊂:-overloads-right : {F G} Overloads G ⊂: Overloads (F G)
:-overloads-right p = just (right p)
⊂:-overloads-⋒ : {F G} FunType F FunType G ∩-Lift (Overloads F) (Overloads G) ⊂: Overloads (F G)
:-overloads-⋒ (R S) (T U) (intersect here here) = defn here (∩-<:-∩ⁿ R T) (∩ⁿ-<:-∩ S U)
:-overloads-⋒ (R S) (G H) (intersect here (left o)) = ⊂:-overloads-⋒ (R S) G (intersect here o) >>= ⊂:-overloads-left
:-overloads-⋒ (R S) (G H) (intersect here (right o)) = ⊂:-overloads-⋒ (R S) H (intersect here o) >>= ⊂:-overloads-right
:-overloads-⋒ (E F) G (intersect (left n) o) = ⊂:-overloads-⋒ E G (intersect n o) >>= ⊂:-overloads-left
:-overloads-⋒ (E F) G (intersect (right n) o) = ⊂:-overloads-⋒ F G (intersect n o) >>= ⊂:-overloads-right
⊂:-⋒-overloads : {F G} FunType F FunType G Overloads (F G) ⊂: ∩-Lift (Overloads F) (Overloads G)
:-⋒-overloads (R S) (T U) here = defn (intersect here here) (∩ⁿ-<:-∩ R T) (∩-<:-∩ⁿ S U)
:-⋒-overloads (R S) (G H) (left o) = ⊂:-⋒-overloads (R S) G o >>= ⊂:-∩-lift ⊂:-refl ⊂:-overloads-left
:-⋒-overloads (R S) (G H) (right o) = ⊂:-⋒-overloads (R S) H o >>= ⊂:-∩-lift ⊂:-refl ⊂:-overloads-right
:-⋒-overloads (E F) G (left o) = ⊂:-⋒-overloads E G o >>= ⊂:-∩-lift ⊂:-overloads-left ⊂:-refl
:-⋒-overloads (E F) G (right o) = ⊂:-⋒-overloads F G o >>= ⊂:-∩-lift ⊂:-overloads-right ⊂:-refl
⊂:-overloads-⋓ : {F G} FunType F FunType G -Lift (Overloads F) (Overloads G) ⊂: Overloads (F G)
:-overloads-⋓ (R S) (T U) (union here here) = defn here (-<:-∪ⁿ R T) (∪ⁿ-<:- S U)
:-overloads-⋓ (R S) (G H) (union here (left o)) = ⊂:-overloads-⋓ (R S) G (union here o) >>= ⊂:-overloads-left
:-overloads-⋓ (R S) (G H) (union here (right o)) = ⊂:-overloads-⋓ (R S) H (union here o) >>= ⊂:-overloads-right
:-overloads-⋓ (E F) G (union (left n) o) = ⊂:-overloads-⋓ E G (union n o) >>= ⊂:-overloads-left
:-overloads-⋓ (E F) G (union (right n) o) = ⊂:-overloads-⋓ F G (union n o) >>= ⊂:-overloads-right
⊂:-⋓-overloads : {F G} FunType F FunType G Overloads (F G) ⊂: -Lift (Overloads F) (Overloads G)
:-⋓-overloads (R S) (T U) here = defn (union here here) (∪ⁿ-<:- R T) (-<:-∪ⁿ S U)
:-⋓-overloads (R S) (G H) (left o) = ⊂:-⋓-overloads (R S) G o >>= ⊂:--lift ⊂:-refl ⊂:-overloads-left
:-⋓-overloads (R S) (G H) (right o) = ⊂:-⋓-overloads (R S) H o >>= ⊂:--lift ⊂:-refl ⊂:-overloads-right
:-⋓-overloads (E F) G (left o) = ⊂:-⋓-overloads E G o >>= ⊂:--lift ⊂:-overloads-left ⊂:-refl
:-⋓-overloads (E F) G (right o) = ⊂:-⋓-overloads F G o >>= ⊂:--lift ⊂:-overloads-right ⊂:-refl
-saturate-overloads : {F} FunType F Overloads (-saturate F) ⊂: -Saturate (Overloads F)
-saturate-overloads (S T) here = just (base here)
-saturate-overloads (F G) (left (left o)) = -saturate-overloads F o >>= ⊂:--saturate ⊂:-overloads-left
-saturate-overloads (F G) (left (right o)) = -saturate-overloads G o >>= ⊂:--saturate ⊂:-overloads-right
-saturate-overloads (F G) (right o) =
:-⋓-overloads (normal--saturate F) (normal--saturate G) o >>=
:--lift (-saturate-overloads F) (-saturate-overloads G) >>=
:--lift (⊂:--saturate ⊂:-overloads-left) (⊂:--saturate ⊂:-overloads-right) >>=
:--lift-saturate
overloads--saturate : {F} FunType F -Saturate (Overloads F) ⊂: Overloads (-saturate F)
overloads--saturate F = ⊂:--saturate-indn (inj F) (step F) where
inj : {F} FunType F Overloads F ⊂: Overloads (-saturate F)
inj (S T) here = just here
inj (F G) (left p) = inj F p >>= ⊂:-overloads-left >>= ⊂:-overloads-left
inj (F G) (right p) = inj G p >>= ⊂:-overloads-right >>= ⊂:-overloads-left
step : {F} FunType F -Lift (Overloads (-saturate F)) (Overloads (-saturate F)) ⊂: Overloads (-saturate F)
step (S T) (union here here) = defn here (<:--lub <:-refl <:-refl) <:--left
step (F G) (union (left (left p)) (left (left q))) = step F (union p q) >>= ⊂:-overloads-left >>= ⊂:-overloads-left
step (F G) (union (left (left p)) (left (right q))) = ⊂:-overloads-⋓ (normal--saturate F) (normal--saturate G) (union p q) >>= ⊂:-overloads-right
step (F G) (union (left (right p)) (left (left q))) = ⊂:-overloads-⋓ (normal--saturate F) (normal--saturate G) (union q p) >>= ⊂:-overloads-right >>=ˡ <:--symm >>=ʳ <:--symm
step (F G) (union (left (right p)) (left (right q))) = step G (union p q) >>= ⊂:-overloads-right >>= ⊂:-overloads-left
step (F G) (union p (right q)) with ⊂:-⋓-overloads (normal--saturate F) (normal--saturate G) q
step (F G) (union (left (left p)) (right q)) | defn (union q₁ q₂) q₃ q₄ =
(step F (union p q₁) [] just q₂) >>=
:-overloads-⋓ (normal--saturate F) (normal--saturate G) >>=
:-overloads-right >>=ˡ
<:-trans (<:-union <:-refl q₃) <:--assocl >>=ʳ
<:-trans <:--assocr (<:-union <:-refl q₄)
step (F G) (union (left (right p)) (right q)) | defn (union q₁ q₂) q₃ q₄ =
(just q₁ [] step G (union p q₂)) >>=
:-overloads-⋓ (normal--saturate F) (normal--saturate G) >>=
:-overloads-right >>=ˡ
<:-trans (<:-union <:-refl q₃) (<:--lub (<:-trans <:--left <:--right) (<:--lub <:--left (<:-trans <:--right <:--right))) >>=ʳ
<:-trans (<:--lub (<:-trans <:--left <:--right) (<:--lub <:--left (<:-trans <:--right <:--right))) (<:-union <:-refl q₄)
step (F G) (union (right p) (right q)) | defn (union q₁ q₂) q₃ q₄ with ⊂:-⋓-overloads (normal--saturate F) (normal--saturate G) p
step (F G) (union (right p) (right q)) | defn (union q₁ q₂) q₃ q₄ | defn (union p₁ p₂) p₃ p₄ =
(step F (union p₁ q₁) [] step G (union p₂ q₂)) >>=
:-overloads-⋓ (normal--saturate F) (normal--saturate G) >>=
:-overloads-right >>=ˡ
<:-trans (<:-union p₃ q₃) (<:--lub (<:-union <:--left <:--left) (<:-union <:--right <:--right)) >>=ʳ
<:-trans (<:--lub (<:-union <:--left <:--left) (<:-union <:--right <:--right)) (<:-union p₄ q₄)
step (F G) (union (right p) q) with ⊂:-⋓-overloads (normal--saturate F) (normal--saturate G) p
step (F G) (union (right p) (left (left q))) | defn (union p₁ p₂) p₃ p₄ =
(step F (union p₁ q) [] just p₂) >>=
:-overloads-⋓ (normal--saturate F) (normal--saturate G) >>=
:-overloads-right >>=ˡ
<:-trans (<:-union p₃ <:-refl) (<:--lub (<:-union <:--left <:-refl) (<:-trans <:--right <:--left)) >>=ʳ
<:-trans (<:--lub (<:-union <:--left <:-refl) (<:-trans <:--right <:--left)) (<:-union p₄ <:-refl)
step (F G) (union (right p) (left (right q))) | defn (union p₁ p₂) p₃ p₄ =
(just p₁ [] step G (union p₂ q)) >>=
:-overloads-⋓ (normal--saturate F) (normal--saturate G) >>=
:-overloads-right >>=ˡ
<:-trans (<:-union p₃ <:-refl) <:--assocr >>=ʳ
<:-trans <:--assocl (<:-union p₄ <:-refl)
step (F G) (union (right p) (right q)) | defn (union p₁ p₂) p₃ p₄ with ⊂:-⋓-overloads (normal--saturate F) (normal--saturate G) q
step (F G) (union (right p) (right q)) | defn (union p₁ p₂) p₃ p₄ | defn (union q₁ q₂) q₃ q₄ =
(step F (union p₁ q₁) [] step G (union p₂ q₂)) >>=
:-overloads-⋓ (normal--saturate F) (normal--saturate G) >>=
:-overloads-right >>=ˡ
<:-trans (<:-union p₃ q₃) (<:--lub (<:-union <:--left <:--left) (<:-union <:--right <:--right)) >>=ʳ
<:-trans (<:--lub (<:-union <:--left <:--left) (<:-union <:--right <:--right)) (<:-union p₄ q₄)
-saturated : {F} FunType F -Lift (Overloads (-saturate F)) (Overloads (-saturate F)) ⊂: Overloads (-saturate F)
-saturated F o =
:--lift (-saturate-overloads F) (-saturate-overloads F) o >>=
:--lift-saturate >>=
overloads--saturate F
∩-saturate-overloads : {F} FunType F Overloads (∩-saturate F) ⊂: ∩-Saturate (Overloads F)
∩-saturate-overloads (S T) here = just (base here)
∩-saturate-overloads (F G) (left (left o)) = ∩-saturate-overloads F o >>= ⊂:-∩-saturate ⊂:-overloads-left
∩-saturate-overloads (F G) (left (right o)) = ∩-saturate-overloads G o >>= ⊂:-∩-saturate ⊂:-overloads-right
∩-saturate-overloads (F G) (right o) =
:-⋒-overloads (normal-∩-saturate F) (normal-∩-saturate G) o >>=
:-∩-lift (∩-saturate-overloads F) (∩-saturate-overloads G) >>=
:-∩-lift (⊂:-∩-saturate ⊂:-overloads-left) (⊂:-∩-saturate ⊂:-overloads-right) >>=
:-∩-lift-saturate
overloads-∩-saturate : {F} FunType F ∩-Saturate (Overloads F) ⊂: Overloads (∩-saturate F)
overloads-∩-saturate F = ⊂:-∩-saturate-indn (inj F) (step F) where
inj : {F} FunType F Overloads F ⊂: Overloads (∩-saturate F)
inj (S T) here = just here
inj (F G) (left p) = inj F p >>= ⊂:-overloads-left >>= ⊂:-overloads-left
inj (F G) (right p) = inj G p >>= ⊂:-overloads-right >>= ⊂:-overloads-left
step : {F} FunType F ∩-Lift (Overloads (∩-saturate F)) (Overloads (∩-saturate F)) ⊂: Overloads (∩-saturate F)
step (S T) (intersect here here) = defn here <:-∩-left (<:-∩-glb <:-refl <:-refl)
step (F G) (intersect (left (left p)) (left (left q))) = step F (intersect p q) >>= ⊂:-overloads-left >>= ⊂:-overloads-left
step (F G) (intersect (left (left p)) (left (right q))) = ⊂:-overloads-⋒ (normal-∩-saturate F) (normal-∩-saturate G) (intersect p q) >>= ⊂:-overloads-right
step (F G) (intersect (left (right p)) (left (left q))) = ⊂:-overloads-⋒ (normal-∩-saturate F) (normal-∩-saturate G) (intersect q p) >>= ⊂:-overloads-right >>=ˡ <:-∩-symm >>=ʳ <:-∩-symm
step (F G) (intersect (left (right p)) (left (right q))) = step G (intersect p q) >>= ⊂:-overloads-right >>= ⊂:-overloads-left
step (F G) (intersect (right p) q) with ⊂:-⋒-overloads (normal-∩-saturate F) (normal-∩-saturate G) p
step (F G) (intersect (right p) (left (left q))) | defn (intersect p₁ p₂) p₃ p₄ =
(step F (intersect p₁ q) [∩] just p₂) >>=
:-overloads-⋒ (normal-∩-saturate F) (normal-∩-saturate G) >>=
:-overloads-right >>=ˡ
<:-trans (<:-intersect p₃ <:-refl) (<:-∩-glb (<:-intersect <:-∩-left <:-refl) (<:-trans <:-∩-left <:-∩-right)) >>=ʳ
<:-trans (<:-∩-glb (<:-intersect <:-∩-left <:-refl) (<:-trans <:-∩-left <:-∩-right)) (<:-intersect p₄ <:-refl)
step (F G) (intersect (right p) (left (right q))) | defn (intersect p₁ p₂) p₃ p₄ =
(just p₁ [∩] step G (intersect p₂ q)) >>=
:-overloads-⋒ (normal-∩-saturate F) (normal-∩-saturate G) >>=
:-overloads-right >>=ˡ
<:-trans (<:-intersect p₃ <:-refl) <:-∩-assocr >>=ʳ
<:-trans <:-∩-assocl (<:-intersect p₄ <:-refl)
step (F G) (intersect (right p) (right q)) | defn (intersect p₁ p₂) p₃ p₄ with ⊂:-⋒-overloads (normal-∩-saturate F) (normal-∩-saturate G) q
step (F G) (intersect (right p) (right q)) | defn (intersect p₁ p₂) p₃ p₄ | defn (intersect q₁ q₂) q₃ q₄ =
(step F (intersect p₁ q₁) [∩] step G (intersect p₂ q₂)) >>=
:-overloads-⋒ (normal-∩-saturate F) (normal-∩-saturate G) >>=
:-overloads-right >>=ˡ
<:-trans (<:-intersect p₃ q₃) (<:-∩-glb (<:-intersect <:-∩-left <:-∩-left) (<:-intersect <:-∩-right <:-∩-right)) >>=ʳ
<:-trans (<:-∩-glb (<:-intersect <:-∩-left <:-∩-left) (<:-intersect <:-∩-right <:-∩-right)) (<:-intersect p₄ q₄)
step (F G) (intersect p (right q)) with ⊂:-⋒-overloads (normal-∩-saturate F) (normal-∩-saturate G) q
step (F G) (intersect (left (left p)) (right q)) | defn (intersect q₁ q₂) q₃ q₄ =
(step F (intersect p q₁) [∩] just q₂) >>=
:-overloads-⋒ (normal-∩-saturate F) (normal-∩-saturate G) >>=
:-overloads-right >>=ˡ
<:-trans (<:-intersect <:-refl q₃) <:-∩-assocl >>=ʳ
<:-trans <:-∩-assocr (<:-intersect <:-refl q₄)
step (F G) (intersect (left (right p)) (right q)) | defn (intersect q₁ q₂) q₃ q₄ =
(just q₁ [∩] step G (intersect p q₂) ) >>=
:-overloads-⋒ (normal-∩-saturate F) (normal-∩-saturate G) >>=
:-overloads-right >>=ˡ
<:-trans (<:-intersect <:-refl q₃) (<:-∩-glb (<:-trans <:-∩-right <:-∩-left) (<:-∩-glb <:-∩-left (<:-trans <:-∩-right <:-∩-right))) >>=ʳ
<:-∩-glb (<:-trans <:-∩-right <:-∩-left) (<:-trans (<:-∩-glb <:-∩-left (<:-trans <:-∩-right <:-∩-right)) q₄)
step (F G) (intersect (right p) (right q)) | defn (intersect q₁ q₂) q₃ q₄ with ⊂:-⋒-overloads (normal-∩-saturate F) (normal-∩-saturate G) p
step (F G) (intersect (right p) (right q)) | defn (intersect q₁ q₂) q₃ q₄ | defn (intersect p₁ p₂) p₃ p₄ =
(step F (intersect p₁ q₁) [∩] step G (intersect p₂ q₂)) >>=
:-overloads-⋒ (normal-∩-saturate F) (normal-∩-saturate G) >>=
:-overloads-right >>=ˡ
<:-trans (<:-intersect p₃ q₃) (<:-∩-glb (<:-intersect <:-∩-left <:-∩-left) (<:-intersect <:-∩-right <:-∩-right)) >>=ʳ
<:-trans (<:-∩-glb (<:-intersect <:-∩-left <:-∩-left) (<:-intersect <:-∩-right <:-∩-right)) (<:-intersect p₄ q₄)
saturate-overloads : {F} FunType F Overloads (saturate F) ⊂: -Saturate (∩-Saturate (Overloads F))
saturate-overloads F o = -saturate-overloads (normal-∩-saturate F) o >>= (⊂:--saturate (∩-saturate-overloads F))
overloads-saturate : {F} FunType F -Saturate (∩-Saturate (Overloads F)) ⊂: Overloads (saturate F)
overloads-saturate F o = ⊂:--saturate (overloads-∩-saturate F) o >>= overloads--saturate (normal-∩-saturate F)
-- Saturated F whenever
-- * if F has overloads (R ⇒ S) and (T ⇒ U) then F has an overload which is a subtype of ((R ∩ T) ⇒ (S ∩ U))
-- * ditto union
data Saturated (F : Type) : Set where
defn :
( {R S T U} Overloads F (R S) Overloads F (T U) <:-Close (Overloads F) ((R T) (S U)))
( {R S T U} Overloads F (R S) Overloads F (T U) <:-Close (Overloads F) ((R T) (S U)))
-----------
Saturated F
-- saturated F is saturated!
saturated : {F} FunType F Saturated (saturate F)
saturated F = defn
(λ n o (saturate-overloads F n [∩] saturate-overloads F o) >>= -saturate-resp-∩-saturation ⊂:-∩-lift-saturate >>= overloads-saturate F)
(λ n o -saturated (normal-∩-saturate F) (union n o))

45
prototyping/README.md
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@ -1,45 +0,0 @@
# Prototyping Luau
![prototyping workflow](https://github.com/Roblox/luau/actions/workflows/prototyping.yml/badge.svg)
An experimental prototyping system for the Luau type system. This is
intended to allow core language features to be tested quickly, without
having to interact with all the features of production Lua.
## Building
First install Haskell and Agda.
Install dependencies:
```
cabal update
cabal install --lib aeson scientific vector
```
Then compile
```
agda --compile PrettyPrinter.agda
```
and run!
```
luau-ast Examples/SmokeTest.lua | ./PrettyPrinter
```
## Testing
We have a series of snapshot tests in the `Tests/` directory. You interact with the tests using the `tests` Python script in the `prototyping` directory. To simply run the tests, run:
```sh
tests --luau-cli ../build/luau-ast --build
```
This will build the test targets and run them. Run `tests --help` for information about all the command-line options.
### Adding a new test
To add a new test, add it to `Tests/{SUITE_NAME}/{CASE_NAME}`. You'll need an `in.lua` file and an `out.txt` file. The `in.lua` file is the input Luau source code, while the `out.txt` file is the expected output after running `luau-ast in.lua | test_executable`.
### Updating a test
If you make a change to the prototype that results in an expected change in behavior, you might want to update the test cases automatically. To do this, run `tests` with the `--accept-new-output` (`-a` for short) flag. Rather than diffing the output, this will overwrite the `out.txt` files for each test case with the actual result. Commit the resulting changes with your PR.

1
prototyping/Tests/Interpreter/binary_equality_bools/in.lua
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@ -1 +0,0 @@
return true == false

4
prototyping/Tests/Interpreter/binary_equality_bools/out.txt
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@ -1,4 +0,0 @@
ANNOTATED PROGRAM:
return true == false
RAN WITH RESULT: false

1
prototyping/Tests/Interpreter/binary_equality_numbers/in.lua
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@ -1 +0,0 @@
return 1 == 1

4
prototyping/Tests/Interpreter/binary_equality_numbers/out.txt
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@ -1,4 +0,0 @@
ANNOTATED PROGRAM:
return 1.0 == 1.0
RAN WITH RESULT: true

1
prototyping/Tests/Interpreter/binary_exps/in.lua
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@ -1 +0,0 @@
return 1 + 2 - 2 * 2 / 2

4
prototyping/Tests/Interpreter/binary_exps/out.txt
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@ -1,4 +0,0 @@
ANNOTATED PROGRAM:
return 1.0 + 2.0 - 2.0 * 2.0 / 2.0
RAN WITH RESULT: 1.0

3
prototyping/Tests/Interpreter/concat_number_and_string/in.lua
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@ -1,3 +0,0 @@
local x: string = "hello"
local y: string = 37
return x .. y

12
prototyping/Tests/Interpreter/concat_number_and_string/out.txt
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@ -1,12 +0,0 @@
ANNOTATED PROGRAM:
local x : string = "hello"
local y : string = 37.0
return x .. y
RUNTIME ERROR:
value 37.0 is not a string
in return statement
TYPE ERROR:
Local variable y has type string but expression has type number
because provided type contains v, where v is a number

3
prototyping/Tests/Interpreter/concat_two_strings/in.lua
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@ -1,3 +0,0 @@
local x: string = "hello"
local y: string = "world"
return x .. y

6
prototyping/Tests/Interpreter/concat_two_strings/out.txt
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@ -1,6 +0,0 @@
ANNOTATED PROGRAM:
local x : string = "hello"
local y : string = "world"
return x .. y
RAN WITH RESULT: "helloworld"

5
prototyping/Tests/Interpreter/return_nil/in.lua
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@ -1,5 +0,0 @@
local function foo(x)
return nil
end
return foo(nil)

7
prototyping/Tests/Interpreter/return_nil/out.txt
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@ -1,7 +0,0 @@
UNANNOTATED PROGRAM:
local function foo(x)
return nil
end
return foo(nil)
RAN WITH RESULT: nil

1
prototyping/Tests/Interpreter/return_string/in.lua
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@ -1 +0,0 @@
return "foo bar"

4
prototyping/Tests/Interpreter/return_string/out.txt
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@ -1,4 +0,0 @@
ANNOTATED PROGRAM:
return "foo bar"
RAN WITH RESULT: "foo bar"

19
prototyping/Tests/PrettyPrinter/smoke_test/in.lua
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@ -1,19 +0,0 @@
local function id(x)
return x
end
local function comp(f)
return function(g)
return function(x)
return f(g(x))
end
end
end
local id2 = comp(id)(id)
local nil2 = id2(nil)
local a : any = nil
local b : nil = nil
local c : (nil) -> nil = nil
local d : (any & nil) = nil
local e : any? = nil
local f : number = 123
return id2(nil2)

19
prototyping/Tests/PrettyPrinter/smoke_test/out.txt
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@ -1,19 +0,0 @@
local function id(x)
return x
end
local function comp(f)
return function(g)
return function(x)
return f(g(x))
end
end
end
local id2 = comp(id)(id)
local nil2 = id2(nil)
local a : unknown = nil
local b : nil = nil
local c : (nil) -> nil = nil
local d : (unknown & nil) = nil
local e : unknown? = nil
local f : number = 123.0
return id2(nil2)

16
prototyping/Utility/Bool.agda
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module Utility.Bool where
open import Agda.Builtin.Bool using (Bool; true; false)
not : Bool Bool
not false = true
not true = false
_or_ : Bool Bool Bool
true or _ = true
_ or true = true
_ or _ = false
_and_ : Bool Bool Bool
true and true = true
_ and _ = false

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prototyping/tests.py
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#!/usr/bin/python
import argparse
import difflib
import enum
import os
import os.path
import subprocess
import sys
SUITES = ["interpreter", "prettyprinter"]
IN_FILE_NAME = "in.lua"
OUT_FILE_NAME = "out.txt"
SUITE_EXE_NAMES = {
"interpreter": "Interpreter",
"prettyprinter": "PrettyPrinter",
}
SUITE_ENTRY_POINTS = {
"interpreter": "Interpreter.agda",
"prettyprinter": "PrettyPrinter.agda",
}
SUITE_ROOTS = {
"interpreter": "Tests/Interpreter",
"prettyprinter": "Tests/PrettyPrinter",
}
class TestResultStatus(enum.Enum):
CLI_ERROR = 0
EXE_ERROR = 1
DIFF_ERROR = 2
SUCCESS = 3
WROTE_NEW = 4
class DiffFailure:
def __init__(self, expected, actual):
self.expected = expected
self.actual = actual
def diff_text(self):
diff_generator = difflib.context_diff(self.expected.splitlines(), self.actual.splitlines(), fromfile="expected", tofile="actual", n=3)
return "".join(diff_generator)
def diff_html(self):
differ = difflib.HtmlDiff(tabsize=4)
return differ.make_file(self.expected.splitlines(), self.actual.splitlines(), fromdesc="Expected", todesc="Actual", context=True, numlines=5)
class TestCaseResult:
def __init__(self, suite, case, status, details):
self.suite = suite
self.case = case
self.status = status
self.details = details
def did_pass(self):
return self.status == TestResultStatus.SUCCESS or self.status == TestResultStatus.WROTE_NEW
def to_string(self):
prefix = f"[{self.suite}/{self.case}]: "
if self.status == TestResultStatus.CLI_ERROR:
return f"{prefix}CLI ERROR: {self.details}"
elif self.status == TestResultStatus.EXE_ERROR:
return f"{prefix}EXE ERROR: {self.details}"
elif self.status == TestResultStatus.DIFF_ERROR:
text_diff = self.details.diff_text()
return f"{prefix}FAILED:\n{text_diff}"
elif self.status == TestResultStatus.SUCCESS:
return f"{prefix}SUCCEEDED"
elif self.status == TestResultStatus.WROTE_NEW:
return f"{prefix}WROTE NEW RESULT"
def write_artifact(self, artifact_root):
if self.status != TestResultStatus.DIFF_ERROR:
return
filename = f"{self.suite}-{self.case}.out.html"
path = os.path.join(artifact_root, filename)
html = self.details.diff_html()
with open(path, "w") as file:
file.write(html)
parser = argparse.ArgumentParser(description="Runs prototype test cases")
parser.add_argument("--luau-cli", "-l", dest="cli_location", required=True, help="The location of luau-cli")
parser.add_argument("--root", "-r", dest="prototype_root", required=False, default=os.getcwd(), help="The root of the prototype")
parser.add_argument("--build", "-b", dest="build", action="store_true", default=True, help="Whether to automatically build required test binaries")
parser.add_argument("--suite", "-s", dest="suites", action="append", default=[], choices=SUITES, help="Which test suites to run")
parser.add_argument("--case", "-c", dest="cases", action="append", default=[], help="Which test cases to run")
parser.add_argument("--accept-new-output", "-a", dest="snapshot", action="store_true", default=False, help="Whether to write the new output to files, instead of diffing against it")
parser.add_argument("--write-diff-failures", dest="write_diffs", action="store_true", default=False, help="Whether to write test failure diffs to files")
parser.add_argument("--diff-failure-location", dest="diff_location", default=None, help="Where to write diff failure files to")
def build_suite(root, suite):
entry_point = SUITE_ENTRY_POINTS.get(suite)
if entry_point is None:
return (False, "Invalid suite")
result = subprocess.run(["~/.cabal/bin/agda", "--compile", entry_point], shell=True, cwd=root, stdout=subprocess.PIPE, stderr=subprocess.STDOUT)
if result.returncode == 0:
return (True, None)
else:
return (False, result.stdout)
def run_test(in_path, out_path, cli_path, exe_path, snapshot):
cli_result = subprocess.run([cli_path, in_path], capture_output=True)
if cli_result.returncode != 0:
return (TestResultStatus.CLI_ERROR, f"CLI error: {cli_result.stderr}")
exe_result = subprocess.run(exe_path, input=cli_result.stdout, capture_output=True)
if exe_result.returncode != 0:
return (TestResultStatus.EXE_ERROR, f"Executable error; stdout:{exe_result.stdout}\n\nstderr: {exe_result.stderr}")
actual_result = exe_result.stdout.decode("utf-8")
if snapshot:
with open(out_path, "w") as out_file:
out_file.write(actual_result)
return (TestResultStatus.WROTE_NEW, None)
else:
with open(out_path, "r") as out_file:
expected_result = out_file.read()
if expected_result != actual_result:
return (TestResultStatus.DIFF_ERROR, DiffFailure(expected_result, actual_result))
return (TestResultStatus.SUCCESS, None)
def should_run_case(case_name, filters):
if len(filters) == 0:
return True
return any([f in case_name for f in filters])
def run_test_suite(args, suite, suite_root, suite_exe):
results = []
for entry in os.listdir(suite_root):
if not should_run_case(entry, args.cases):
continue
case_path = os.path.join(suite_root, entry)
if os.path.isdir(case_path):
in_path = os.path.join(case_path, IN_FILE_NAME)
out_path = os.path.join(case_path, OUT_FILE_NAME)
if not os.path.exists(in_path) or not os.path.exists(out_path):
continue
status, details = run_test(in_path, out_path, args.cli_location, suite_exe, args.snapshot)
result = TestCaseResult(suite, entry, status, details)
results.append(result)
return results
def main():
args = parser.parse_args()
suites = args.suites if len(args.suites) > 0 else SUITES
root = os.path.abspath(args.prototype_root)
if args.build:
for suite in suites:
success, reason = build_suite(root, suite)
if not success:
print(f"Error building executable for test suite {suite}:\n{reason}")
sys.exit(1)
else:
print(f"Built executable for test suite {suite} successfully.")
failed = False
for suite in suites:
suite_root = os.path.join(root, SUITE_ROOTS.get(suite))
suite_exe = os.path.join(root, SUITE_EXE_NAMES.get(suite))
print(f"Running test suite {suite}...")
results = run_test_suite(args, suite, suite_root, suite_exe)
passed = 0
total = len(results)
for result in results:
if result.did_pass():
passed += 1
else:
failed = True
print(f"Suite {suite} [{passed} / {total} passed]:")
for result in results:
print(result.to_string())
if args.write_diffs:
result.write_artifact(args.diff_location)
if failed:
sys.exit(1)
if __name__ == "__main__":
main()