Correct multiplicities when checking Pi binders

We've always just used 0, which isn't correct if the function is going
to be used in a runtime pattern match. Now calculate correctly so that
we're explicit about which type level variables are used at runtime.

This might cause some programs to fail to compile, if they use functions
that calculate Pi types. The solution is to make those functions
explicitly 0 multiplicity. If that doesn't work, you may have been
accidentally trying to use compile-time only data at run time!

Fixes #1163
This commit is contained in:
Edwin Brady 2021-03-09 17:23:05 +00:00
parent 72b68fd813
commit 04a0f5001f
15 changed files with 64 additions and 16 deletions

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@ -9,9 +9,9 @@ import Data.Telescope.Segment
import Data.Telescope.SimpleFun
public export
Fun : (env : Left.Environment gamma) -> {n : Nat} -> (0 delta : Segment n gamma)
-> (cod : SimpleFun env delta Type)
-> Type
0 Fun : (env : Left.Environment gamma) -> {n : Nat} -> (0 delta : Segment n gamma)
-> (cod : SimpleFun env delta Type)
-> Type
Fun env {n = 0 } [] cod = cod
Fun env {n = S n} (ty :: delta) cod = (x : ty env) -> Fun (env ** x) delta (cod x)

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@ -10,8 +10,8 @@ import Data.Telescope.Segment
||| An n-ary function whose codomain does not depend on its
||| arguments. The arguments may have dependencies.
public export
SimpleFun : (env : Left.Environment gamma) -> {n : Nat} -> (0 delta : Segment n gamma)
-> (cod : Type) -> Type
0 SimpleFun : (env : Left.Environment gamma) -> {n : Nat} -> (0 delta : Segment n gamma)
-> (cod : Type) -> Type
SimpleFun env {n = 0 } [] cod = cod
SimpleFun env {n = S n} (ty :: delta) cod = (x : ty env) -> SimpleFun (env ** x) delta cod

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@ -287,7 +287,10 @@ mutual
where
rig : RigCount
rig = case b of
Pi _ _ _ _ => erased
Pi _ _ _ _ =>
if isErased rig_in
then erased
else top -- checking as if an inspectable run-time type
_ => if isErased rig_in
then erased
else linear
@ -391,7 +394,7 @@ mutual
(valv, valt, vs) <- lcheck (rig |*| rigc) erase env val
pure (Let fc rigc valv tyv, tyt, vs)
lcheckBinder rig erase env (Pi fc c x ty)
= do (tyv, tyt, _) <- lcheck erased erase env ty
= do (tyv, tyt, _) <- lcheck (rig |*| c) erase env ty
pure (Pi fc c x tyv, tyt, [])
lcheckBinder rig erase env (PVar fc c p ty)
= do (tyv, tyt, _) <- lcheck erased erase env ty

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@ -704,9 +704,11 @@ topDecl fname indents
visOpts <- many visOpt
vis <- getVisibility Nothing visOpts
let opts = mapMaybe getRight visOpts
m <- multiplicity
rig <- getMult m
claim <- tyDecl fname indents
end <- location
pure (IClaim (MkFC fname start end) top vis opts claim)
pure (IClaim (MkFC fname start end) rig vis opts claim)
<|> recordDecl fname indents
<|> directive fname indents
<|> definition fname indents

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@ -122,7 +122,7 @@ idrisTestsRegression = MkTestPool []
"reg015", "reg016", "reg017", "reg018", "reg019", "reg020", "reg021",
"reg022", "reg023", "reg024", "reg025", "reg026", "reg027", "reg028",
"reg029", "reg030", "reg031", "reg032", "reg033", "reg034", "reg035",
"reg036", "reg037"]
"reg036", "reg037", "reg038"]
idrisTests : TestPool
idrisTests = MkTestPool []

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@ -1,6 +1,6 @@
public export
interface Do (0 m : Type) where
Next : m -> Type
0 Next : m -> Type
bind : (x : m) -> Next x
-- Test that the implicits don't turn into as patterns on the LHS - they

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@ -1,6 +1,6 @@
public export
interface Do (0 m : Type) where
Next : (a : Type) -> (b : Type) -> m -> Type
0 Next : (a : Type) -> (b : Type) -> m -> Type
bind : (x : m) -> Next a b x
-- This won't actually achieve anything useful, but we're testing whether

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@ -1,6 +1,6 @@
public export
interface Do (0 m : Type) where
Next : m -> Type
0 Next : m -> Type
bind : (x : m) -> Next x
public export

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@ -51,11 +51,11 @@ MultiplicativeStruct m = MkMultiplicative (Mult $ Struct m)
(Unit $ Struct m)
-----------------------------------------------------
Commutative : MonoidOver a -> Type
0 Commutative : MonoidOver a -> Type
Commutative m = (x,y : a) -> let _ = AdditiveStruct m in
x .+. y = y .+. x
Commute : (Additive a, Additive2 a) => Type
0 Commute : (Additive a, Additive2 a) => Type
Commute =
(x11,x12,x21,x22 : a) ->
((x11 :+: x12) .+. (x21 :+: x22))

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@ -12,7 +12,7 @@ countArgs _ = 0
-- %logging 5
public export
genEq : Name -> Elab (t -> t -> Bool)
genEq : {t : _} -> Name -> Elab (t -> t -> Bool)
genEq typeName = do
let pos : FC = MkFC "generated code" (0,0) (0,0)
[(n, _)] <- getType typeName

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@ -0,0 +1,9 @@
data Foo : Nat -> Type where
G : (0 yv : Nat) -> Type
G yv = Foo yv -> Bool
partial
f : (0 x : Nat) -> Nat
f x = case G x of
(Foo x' -> _) => x'

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@ -0,0 +1,9 @@
data Foo : Nat -> Type where
0 G : (0 yv : Nat) -> Type
G yv = Foo yv -> Bool
partial
f : (0 x : Nat) -> Nat
f x = case G x of
(Foo x' -> _) => x'

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@ -0,0 +1,21 @@
1/1: Building Test1 (Test1.idr)
Error: While processing right hand side of G. yv is not accessible in this context.
Test1.idr:4:12--4:14
1 | data Foo : Nat -> Type where
2 |
3 | G : (0 yv : Nat) -> Type
4 | G yv = Foo yv -> Bool
^^
1/1: Building Test2 (Test2.idr)
Error: While processing right hand side of f. Main.G is not accessible in this context.
Test2.idr:8:12--8:13
4 | G yv = Foo yv -> Bool
5 |
6 | partial
7 | f : (0 x : Nat) -> Nat
8 | f x = case G x of
^

4
tests/idris2/reg038/run Executable file
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@ -0,0 +1,4 @@
$1 --no-color --console-width 0 Test1.idr --check
$1 --no-color --console-width 0 Test2.idr --check
rm -rf build

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@ -1,4 +1,4 @@
IdType : Type
0 IdType : Type
IdType = {0 a : Type} -> a -> a
id : IdType