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(;module:
  lux
  (lux (control monad)
       (data text/format
             (coll [list "L/" Functor<List>]))
       [macro #+ Monad<Lux>]
       [type]
       (type ["TC" check]))
  (luxc ["&" base]
        (lang ["la" analysis #+ Analysis])
        (analyser ["&;" common])))

## When doing inference, type-variables often need to be created in
## order to figure out which types are present in the expression being
## inferred.
## If a type-variable never gets bound/resolved to a type, then that
## means the expression can be generalized through universal
## quantification.
## When that happens, the type-variable must be replaced by an
## argument to the universally-quantified type.
(def: #export (replace-var var-id bound-idx type)
  (-> Nat Nat Type Type)
  (case type
    (#;Host name params)
    (#;Host name (L/map (replace-var var-id bound-idx) params))

    (^template [<tag>]
      (<tag> left right)
      (<tag> (replace-var var-id bound-idx left)
             (replace-var var-id bound-idx right)))
    ([#;Sum]
     [#;Product]
     [#;Function]
     [#;App])
    
    (#;Var id)
    (if (n.= var-id id)
      (#;Bound bound-idx)
      type)

    (^template [<tag>]
      (<tag> env quantified)
      (<tag> (L/map (replace-var var-id bound-idx) env)
             (replace-var var-id (n.+ +2 bound-idx) quantified)))
    ([#;UnivQ]
     [#;ExQ])
    
    (#;Named name unnamedT)
    (#;Named name
             (replace-var var-id bound-idx unnamedT))

    _
    type))

## Type-inference works by applying some (potentially quantified) type
## to a sequence of values.
## Function types are used for this, although inference is not always
## done for function application (alternative uses may be records and
## tagged variants).
## But, so long as the type being used for the inference can be trated
## as a function type, this method of inference should work.
(def: #export (apply-function analyse funcT args)
  (-> &;Analyser Type (List Code) (Lux [Type (List Analysis)]))
  (case args
    #;Nil
    (:: Monad<Lux> wrap [funcT (list)])
    
    (#;Cons arg args')
    (case funcT
      (#;Named name unnamedT)
      (apply-function analyse unnamedT args)

      (#;UnivQ _)
      (&common;with-var
        (function [[var-id varT]]
          (do Monad<Lux>
            [[outputT argsA] (apply-function analyse (assume (type;apply-type funcT varT)) args)]
            (do @
              [? (&;within-type-env
                  (TC;bound? var-id))
               ## Quantify over the type if genericity/parametricity
               ## is discovered.
               outputT' (if ?
                          (&;within-type-env
                           (TC;clean var-id outputT))
                          (wrap (type;univ-q +1 (replace-var var-id +1 outputT))))]
              (wrap [outputT' argsA])))))

      (#;ExQ _)
      (do Monad<Lux>
        [[ex-id exT] (&;within-type-env
                      TC;existential)]
        (apply-function analyse (assume (type;apply-type funcT exT)) args))

      ## Arguments are inferred back-to-front because, by convention,
      ## Lux functions take the most important arguments *last*, which
      ## means that the most information for doing proper inference is
      ## located in the last arguments to a function call.
      ## By inferring back-to-front, a lot of type-annotations can be
      ## avoided in Lux code, since the inference algorithm can piece
      ## things together more easily.
      (#;Function inputT outputT)
      (do Monad<Lux>
        [[outputT' args'A] (apply-function analyse outputT args')
         argA (&;with-stacked-errors
                (function [_] (format "Expected type: " (%type inputT) "\n"
                                      " For argument: " (%code arg)))
                (&;with-expected-type inputT
                  (analyse arg)))]
        (wrap [outputT' (list& argA args'A)]))

      _
      (&;fail (format "Cannot apply a non-function: " (%type funcT))))
    ))

## Turns a record type into the kind of function type suitable for inference.
(def: #export (record-inference-type type)
  (-> Type (Lux Type))
  (case type
    (#;Named name unnamedT)
    (do Monad<Lux>
      [unnamedT+ (record-inference-type unnamedT)]
      (wrap (#;Named name unnamedT+)))

    (^template [<tag>]
      (<tag> env bodyT)
      (do Monad<Lux>
        [bodyT+ (record-inference-type bodyT)]
        (wrap (<tag> env bodyT+))))
    ([#;UnivQ]
     [#;ExQ])

    (#;Product _)
    (:: Monad<Lux> wrap (type;function (type;flatten-tuple type) type))

    _
    (&;fail (format "Not a record type: " (%type type)))))

## Turns a variant type into the kind of function type suitable for inference.
(def: #export (variant-inference-type tag expected-size type)
  (-> Nat Nat Type (Lux Type))
  (case type
    (#;Named name unnamedT)
    (do Monad<Lux>
      [unnamedT+ (variant-inference-type tag expected-size unnamedT)]
      (wrap (#;Named name unnamedT+)))

    (^template [<tag>]
      (<tag> env bodyT)
      (do Monad<Lux>
        [bodyT+ (variant-inference-type tag expected-size bodyT)]
        (wrap (<tag> env bodyT+))))
    ([#;UnivQ]
     [#;ExQ])

    (#;Sum _)
    (let [cases (type;flatten-variant type)
          actual-size (list;size cases)
          boundary (n.dec expected-size)]
      (cond (or (n.= expected-size actual-size)
                (and (n.> expected-size actual-size)
                     (n.< boundary tag)))
            (case (list;nth tag cases)
              (#;Some caseT)
              (:: Monad<Lux> wrap (type;function (list caseT) type))

              #;None
              (&common;variant-out-of-bounds-error type expected-size tag))
            
            (n.< expected-size actual-size)
            (&;fail (format "Variant type is smaller than expected." "\n"
                            "Expected: " (%i (nat-to-int expected-size)) "\n"
                            "  Actual: " (%i (nat-to-int actual-size))))

            (n.= boundary tag)
            (let [caseT (type;variant (list;drop boundary cases))]
              (:: Monad<Lux> wrap (type;function (list caseT) type)))
            
            ## else
            (&common;variant-out-of-bounds-error type expected-size tag)))

    _
    (&;fail (format "Not a variant type: " (%type type)))))