Agda-2.6.2.2: A dependently typed functional programming language and proof assistant
Safe HaskellNone
LanguageHaskell2010

Agda.TypeChecking.Monad.Signature

Synopsis

Documentation

addConstant :: QName -> Definition -> TCM () Source #

Add a constant to the signature. Lifts the definition to top level.

addConstant' :: QName -> ArgInfo -> QName -> Type -> Defn -> TCM () Source #

A combination of addConstant and defaultDefn. The Language does not need to be supplied.

setTerminates :: QName -> Bool -> TCM () Source #

Set termination info of a defined function symbol.

setCompiledClauses :: QName -> CompiledClauses -> TCM () Source #

Set CompiledClauses of a defined function symbol.

setSplitTree :: QName -> SplitTree -> TCM () Source #

Set SplitTree of a defined function symbol.

modifyFunClauses :: QName -> ([Clause] -> [Clause]) -> TCM () Source #

Modify the clauses of a function.

addClauses :: QName -> [Clause] -> TCM () Source #

Lifts clauses to the top-level and adds them to definition. Also adjusts the funCopatternLHS field if necessary.

addPragma :: BackendName -> QName -> String -> TCM () Source #

Add a compiler pragma `{-# COMPILE backend name text #-}`

addSection :: ModuleName -> TCM () Source #

Add a section to the signature.

The current context will be stored as the cumulative module parameters for this section.

setModuleCheckpoint :: ModuleName -> TCM () Source #

Sets the checkpoint for the given module to the current checkpoint.

getSection :: (Functor m, ReadTCState m) => ModuleName -> m (Maybe Section) Source #

Get a section.

Why Maybe? The reason is that we look up all prefixes of a module to compute number of parameters, and for hierarchical top-level modules, A.B.C say, A and A.B do not exist.

lookupSection :: (Functor m, ReadTCState m) => ModuleName -> m Telescope Source #

Lookup a section telescope.

If it doesn't exist, like in hierarchical top-level modules, the section telescope is empty.

addDisplayForms :: QName -> TCM () Source #

Add display forms for a name f copied by a module application. Essentially if f can reduce to

λ xs → A.B.C.f vs

by unfolding module application copies (defCopy), then we add a display form

A.B.C.f vs ==> f xs

applySection Source #

Arguments

:: ModuleName

Name of new module defined by the module macro.

-> Telescope

Parameters of new module.

-> ModuleName

Name of old module applied to arguments.

-> Args

Arguments of module application.

-> ScopeCopyInfo

Imported names and modules

-> TCM () 

Module application (followed by module parameter abstraction).

addDisplayForm :: QName -> DisplayForm -> TCM () Source #

Add a display form to a definition (could be in this or imported signature).

chaseDisplayForms :: QName -> TCM (Set QName) Source #

Find all names used (recursively) by display forms of a given name.

hasLoopingDisplayForm :: QName -> TCM Bool Source #

Check if a display form is looping.

whatInduction :: MonadTCM tcm => QName -> tcm Induction Source #

Can be called on either a (co)datatype, a record type or a (co)constructor.

singleConstructorType :: QName -> TCM Bool Source #

Does the given constructor come from a single-constructor type?

Precondition: The name has to refer to a constructor.

data SigError Source #

Signature lookup errors.

Constructors

SigUnknown String

The name is not in the signature; default error message.

SigAbstract

The name is not available, since it is abstract.

sigError :: (String -> a) -> a -> SigError -> a Source #

Standard eliminator for SigError.

class (Functor m, Applicative m, MonadFail m, HasOptions m, MonadDebug m, MonadTCEnv m) => HasConstInfo m where Source #

Minimal complete definition

Nothing

Methods

getConstInfo :: QName -> m Definition Source #

Lookup the definition of a name. The result is a closed thing, all free variables have been abstracted over.

getConstInfo' :: QName -> m (Either SigError Definition) Source #

Version that reports exceptions:

getRewriteRulesFor :: QName -> m RewriteRules Source #

Lookup the rewrite rules with the given head symbol.

Instances

Instances details
HasConstInfo ReduceM Source # 
Instance details

Defined in Agda.TypeChecking.Reduce.Monad

HasConstInfo NLM Source # 
Instance details

Defined in Agda.TypeChecking.Rewriting.NonLinMatch

HasConstInfo TerM Source # 
Instance details

Defined in Agda.Termination.Monad

HasConstInfo m => HasConstInfo (MaybeT m) Source # 
Instance details

Defined in Agda.TypeChecking.Monad.Signature

HasConstInfo m => HasConstInfo (ListT m) Source # 
Instance details

Defined in Agda.TypeChecking.Monad.Signature

HasConstInfo (TCMT IO) Source # 
Instance details

Defined in Agda.TypeChecking.Monad.Signature

HasConstInfo m => HasConstInfo (ChangeT m) Source # 
Instance details

Defined in Agda.TypeChecking.Monad.Signature

HasConstInfo m => HasConstInfo (BlockT m) Source # 
Instance details

Defined in Agda.TypeChecking.Monad.Signature

HasConstInfo m => HasConstInfo (NamesT m) Source # 
Instance details

Defined in Agda.TypeChecking.Names

HasConstInfo m => HasConstInfo (PureConversionT m) Source # 
Instance details

Defined in Agda.TypeChecking.Conversion.Pure

HasConstInfo m => HasConstInfo (IdentityT m) Source # 
Instance details

Defined in Agda.TypeChecking.Monad.Signature

HasConstInfo m => HasConstInfo (ExceptT err m) Source # 
Instance details

Defined in Agda.TypeChecking.Monad.Signature

HasConstInfo m => HasConstInfo (ReaderT r m) Source # 
Instance details

Defined in Agda.TypeChecking.Monad.Signature

(Monoid w, HasConstInfo m) => HasConstInfo (WriterT w m) Source # 
Instance details

Defined in Agda.TypeChecking.Monad.Signature

HasConstInfo m => HasConstInfo (StateT s m) Source # 
Instance details

Defined in Agda.TypeChecking.Monad.Signature

getOriginalConstInfo :: (ReadTCState m, HasConstInfo m) => QName -> m Definition Source #

The computation getConstInfo sometimes tweaks the returned Definition, depending on the current Language and the Language of the Definition. This variant of getConstInfo does not perform any tweaks.

getOriginalProjection :: HasConstInfo m => QName -> m QName Source #

Get the original name of the projection (the current one could be from a module application).

getPolarity :: HasConstInfo m => QName -> m [Polarity] Source #

Look up the polarity of a definition.

getPolarity' :: HasConstInfo m => Comparison -> QName -> m [Polarity] Source #

Look up polarity of a definition and compose with polarity represented by Comparison.

setPolarity :: (MonadTCState m, MonadDebug m) => QName -> [Polarity] -> m () Source #

Set the polarity of a definition.

getForcedArgs :: HasConstInfo m => QName -> m [IsForced] Source #

Look up the forced arguments of a definition.

getArgOccurrence :: QName -> Nat -> TCM Occurrence Source #

Get argument occurrence info for argument i of definition d (never fails).

setArgOccurrences :: MonadTCState m => QName -> [Occurrence] -> m () Source #

Sets the defArgOccurrences for the given identifier (which should already exist in the signature).

getErasedConArgs :: HasConstInfo m => QName -> m [Bool] Source #

Returns a list of length conArity. If no erasure analysis has been performed yet, this will be a list of Falses.

addDataCons :: QName -> [QName] -> TCM () Source #

add data constructors to a datatype

getMutual :: QName -> TCM (Maybe [QName]) Source #

Get the mutually recursive identifiers of a symbol from the signature.

getMutual_ :: Defn -> Maybe [QName] Source #

Get the mutually recursive identifiers from a Definition.

setMutual :: QName -> [QName] -> TCM () Source #

Set the mutually recursive identifiers.

mutuallyRecursive :: QName -> QName -> TCM Bool Source #

Check whether two definitions are mutually recursive.

definitelyNonRecursive_ :: Defn -> Bool Source #

A functiondatarecord definition is nonRecursive if it is not even mutually recursive with itself.

getCurrentModuleFreeVars :: TCM Nat Source #

Get the number of parameters to the current module.

getDefFreeVars :: (Functor m, Applicative m, ReadTCState m, MonadTCEnv m) => QName -> m Nat Source #

Compute the number of free variables of a defined name. This is the sum of number of parameters shared with the current module and the number of anonymous variables (if the name comes from a let-bound module).

moduleParamsToApply :: (Functor m, Applicative m, HasOptions m, MonadTCEnv m, ReadTCState m, MonadDebug m) => ModuleName -> m Args Source #

Compute the context variables to apply a definition to.

We have to insert the module telescope of the common prefix of the current module and the module where the definition comes from. (Properly raised to the current context.)

Example: module M₁ Γ where module M₁ Δ where f = ... module M₃ Θ where ... M₁.M₂.f [insert Γ raised by Θ]

inFreshModuleIfFreeParams :: TCM a -> TCM a Source #

Unless all variables in the context are module parameters, create a fresh module to capture the non-module parameters. Used when unquoting to make sure generated definitions work properly.

instantiateDef :: (Functor m, HasConstInfo m, HasOptions m, ReadTCState m, MonadTCEnv m, MonadDebug m) => Definition -> m Definition Source #

Instantiate a closed definition with the correct part of the current context.

makeAbstract :: Definition -> Maybe Definition Source #

Give the abstract view of a definition.

inAbstractMode :: MonadTCEnv m => m a -> m a Source #

Enter abstract mode. Abstract definition in the current module are transparent.

inConcreteMode :: MonadTCEnv m => m a -> m a Source #

Not in abstract mode. All abstract definitions are opaque.

ignoreAbstractMode :: MonadTCEnv m => m a -> m a Source #

Ignore abstract mode. All abstract definitions are transparent.

inConcreteOrAbstractMode :: (MonadTCEnv m, HasConstInfo m) => QName -> (Definition -> m a) -> m a Source #

Enter concrete or abstract mode depending on whether the given identifier is concrete or abstract.

treatAbstractly :: MonadTCEnv m => QName -> m Bool Source #

Check whether a name might have to be treated abstractly (either if we're inAbstractMode or it's not a local name). Returns true for things not declared abstract as well, but for those makeAbstract will have no effect.

treatAbstractly' :: QName -> TCEnv -> Bool Source #

Andreas, 2015-07-01: If the current module is a weak suffix of the identifier module, we can see through its abstract definition if we are abstract. (Then treatAbstractly' returns False).

If I am not mistaken, then we cannot see definitions in the where block of an abstract function from the perspective of the function, because then the current module is a strict prefix of the module of the local identifier. This problem is fixed by removing trailing anonymous module name parts (underscores) from both names.

typeOfConst :: (HasConstInfo m, ReadTCState m) => QName -> m Type Source #

Get type of a constant, instantiated to the current context.

relOfConst :: HasConstInfo m => QName -> m Relevance Source #

Get relevance of a constant.

modalityOfConst :: HasConstInfo m => QName -> m Modality Source #

Get modality of a constant.

droppedPars :: Definition -> Int Source #

The number of dropped parameters for a definition. 0 except for projection(-like) functions and constructors.

isProjection :: HasConstInfo m => QName -> m (Maybe Projection) Source #

Is it the name of a record projection?

isRelevantProjection :: HasConstInfo m => QName -> m (Maybe Projection) Source #

Is it the name of a non-irrelevant record projection?

isStaticFun :: Defn -> Bool Source #

Is it a function marked STATIC?

isInlineFun :: Defn -> Bool Source #

Is it a function marked INLINE?

isProperProjection :: Defn -> Bool Source #

Returns True if we are dealing with a proper projection, i.e., not a projection-like function nor a record field value (projection applied to argument).

projectionArgs :: Definition -> Int Source #

Number of dropped initial arguments of a projection(-like) function.

usesCopatterns :: HasConstInfo m => QName -> m Bool Source #

Check whether a definition uses copatterns.

applyDef :: HasConstInfo m => ProjOrigin -> QName -> Arg Term -> m Term Source #

Apply a function f to its first argument, producing the proper postfix projection if f is a projection which is not irrelevant.