Agda-2.6.4.1: A dependently typed functional programming language and proof assistant
Safe HaskellNone
LanguageHaskell2010

Agda.TypeChecking.SizedTypes

Synopsis

SIZELT stuff

checkSizeLtSat :: Term -> TCM () Source #

Check whether a type is either not a SIZELT or a SIZELT that is non-empty.

checkSizeNeverZero :: Term -> TCM Bool Source #

Precondition: Term is reduced and not blocked. Throws a patternViolation if undecided

checkSizeVarNeverZero :: Int -> TCM Bool Source #

Checks that a size variable is ensured to be > 0. E.g. variable i cannot be zero in context (i : Size) (j : Size< ↑ ↑ i) (k : Size< j) (k' : Size< k). Throws a patternViolation if undecided.

isBounded :: PureTCM m => Nat -> m BoundedSize Source #

Check whether a variable in the context is bounded by a size expression. If x : Size< a, then a is returned.

boundedSizeMetaHook :: (MonadConstraint m, MonadTCEnv m, ReadTCState m, MonadAddContext m, HasOptions m, HasBuiltins m) => Term -> Telescope -> Type -> m () Source #

Whenever we create a bounded size meta, add a constraint expressing the bound. First argument is the new meta and must be a MetaV{}. In boundedSizeMetaHook v tel a, tel includes the current context.

trySizeUniv :: MonadConversion m => Comparison -> CompareAs -> Term -> Term -> QName -> Elims -> QName -> Elims -> m () Source #

trySizeUniv cmp t m n x els1 y els2 is called as a last resort when conversion checking m cmp n : t failed for definitions m = x els1 and n = y els2, where the heads x and y are not equal.

trySizeUniv accounts for subtyping between SIZELT and SIZE, like Size< i =< Size.

If it does not succeed it reports failure of conversion check.

Size views that reduce.

deepSizeView :: (PureTCM m, MonadTCError m) => Term -> m DeepSizeView Source #

Compute the deep size view of a term. Precondition: sized types are enabled.

Size comparison that might add constraints.

compareSizes :: MonadConversion m => Comparison -> Term -> Term -> m () Source #

Compare two sizes.

compareMaxViews :: MonadConversion m => Comparison -> SizeMaxView -> SizeMaxView -> m () Source #

Compare two sizes in max view.

compareBelowMax :: MonadConversion m => DeepSizeView -> SizeMaxView -> m () Source #

compareBelowMax u vs checks u <= max vs. Precondition: size vs >= 2

giveUp :: MonadConversion m => Comparison -> Type -> Term -> Term -> m () Source #

If envAssignMetas then postpone as constraint, otherwise, fail hard. Failing is required if we speculatively test several alternatives.

trivial :: MonadConversion m => Term -> Term -> m Bool Source #

Checked whether a size constraint is trivial (like X <= X+1).

Size constraints.

isSizeProblem :: (ReadTCState m, HasOptions m, HasBuiltins m) => ProblemId -> m Bool Source #

Test whether a problem consists only of size constraints.

isSizeConstraint :: (HasOptions m, HasBuiltins m) => (Comparison -> Bool) -> Closure Constraint -> m Bool Source #

Test whether a constraint speaks about sizes.

isSizeConstraint_ Source #

Arguments

:: (Type -> Bool)

Test for being a sized type

-> (Comparison -> Bool)

Restriction to these directions.

-> Closure Constraint 
-> Bool 

takeSizeConstraints :: (Comparison -> Bool) -> TCM [ProblemConstraint] Source #

Take out all size constraints of the given direction (DANGER!).

getSizeConstraints :: (Comparison -> Bool) -> TCM [ProblemConstraint] Source #

Find the size constraints of the matching direction.

getSizeMetas :: Bool -> TCM [(MetaId, Type, Telescope)] Source #

Return a list of size metas and their context.

Size constraint solving.

data OldSizeExpr Source #

Atomic size expressions.

Constructors

SizeMeta MetaId [Int]

A size meta applied to de Bruijn indices.

Rigid Int

A de Bruijn index.

data OldSizeConstraint Source #

Size constraints we can solve.

Constructors

Leq OldSizeExpr Int OldSizeExpr

Leq a +n b represents a =< b + n. Leq a -n b represents a + n =< b.

oldComputeSizeConstraints :: [ProblemConstraint] -> TCM [OldSizeConstraint] Source #

Compute a set of size constraints that all live in the same context from constraints over terms of type size that may live in different contexts.

cf. simplifyLevelConstraint

oldComputeSizeConstraint :: Constraint -> TCM (Maybe OldSizeConstraint) Source #

Turn a constraint over de Bruijn indices into a size constraint.

oldSizeExpr :: (PureTCM m, MonadBlock m) => Term -> m (OldSizeExpr, Int) Source #

Turn a term with de Bruijn indices into a size expression with offset.

Throws a patternViolation if the term isn't a proper size expression.

flexibleVariables :: OldSizeConstraint -> [(MetaId, [Int])] Source #

Compute list of size metavariables with their arguments appearing in a constraint.

oldCanonicalizeSizeConstraint :: OldSizeConstraint -> Maybe OldSizeConstraint Source #

Convert size constraint into form where each meta is applied to indices 0,1,..,n-1 where n is the arity of that meta.

X[σ] <= t becomes X[id] <= t[σ^-1]

X[σ] ≤ Y[τ] becomes X[id] ≤ Y[τ[σ^-1]] or X[σ[τ^1]] ≤ Y[id] whichever is defined. If none is defined, we give up.