------------------------------------------------------------------------
-- The Agda standard library
--
-- Pointers into star-lists
------------------------------------------------------------------------

{-# OPTIONS --with-K --safe #-}

module Data.Star.Pointer {} {I : Set } where

open import Data.Maybe.Base using (Maybe; nothing; just)
open import Data.Star.Decoration
open import Data.Unit.Base
open import Function.Base using (const)
open import Level
open import Relation.Binary.Core using (Rel)
open import Relation.Binary.Definitions using (NonEmpty; nonEmpty)
open import Relation.Binary.Construct.Closure.ReflexiveTransitive

private
  variable
    r p q : Level

-- Pointers into star-lists. The edge pointed to is decorated with Q,
-- while other edges are decorated with P.

data Pointer {T : Rel I r}
             (P : EdgePred p T) (Q : EdgePred q T)
             : Rel (Maybe (NonEmpty (Star T))) (  r  p  q) where
  step :  {i j k} {x : T i j} {xs : Star T j k}
         (p : P x)  Pointer P Q (just (nonEmpty (x  xs)))
                                 (just (nonEmpty xs))
  done :  {i j k} {x : T i j} {xs : Star T j k}
         (q : Q x)  Pointer P Q (just (nonEmpty (x  xs))) nothing

-- Any P Q xs means that some edge in xs satisfies Q, while all
-- preceding edges satisfy P. A star-list of type Any Always Always xs
-- is basically a prefix of xs; the existence of such a prefix
-- guarantees that xs is non-empty.

Any : {T : Rel I r} (P : EdgePred p T) (Q : EdgePred q T) 
      EdgePred (  (r  (p  q))) (Star T)
Any P Q xs = Star (Pointer P Q) (just (nonEmpty xs)) nothing

module _ {T : Rel I r} {P : EdgePred p T} {Q : EdgePred q T} where

  this :  {i j k} {x : T i j} {xs : Star T j k} 
         Q x  Any P Q (x  xs)
  this q = done q  ε

  that :  {i j k} {x : T i j} {xs : Star T j k} 
         P x  Any P Q xs  Any P Q (x  xs)
  that p = _◅_ (step p)

-- Safe lookup.

data Result (T : Rel I r)
            (P : EdgePred p T) (Q : EdgePred q T) : Set (  r  p  q) where
  result :  {i j} {x : T i j} (p : P x) (q : Q x)  Result T P Q

-- The first argument points out which edge to extract. The edge is
-- returned, together with proofs that it satisfies Q and R.

module _ {T : Rel I r} {P : EdgePred p T} {Q : EdgePred q T} where

  lookup :  {r} {R : EdgePred r T} {i j} {xs : Star T i j} 
           All R xs  Any P Q xs  Result T Q R
  lookup ( r  _)  (done q  ε)  = result q r
  lookup ( _  rs) (step p  ps) = lookup rs ps

-- We can define something resembling init.

  prefixIndex :  {i j} {xs : Star T i j}  Any P Q xs  I
  prefixIndex (done {i = i} q  _)  = i
  prefixIndex (step p          ps) = prefixIndex ps

  prefix :  {i j} {xs : Star T i j} 
           (ps : Any P Q xs)  Star T i (prefixIndex ps)
  prefix (done q          _)  = ε
  prefix (step {x = x} p  ps) = x  prefix ps

-- Here we are taking the initial segment of ps (all elements but the
-- last, i.e. all edges satisfying P).

  init :  {i j} {xs : Star T i j} 
        (ps : Any P Q xs)  All P (prefix ps)
  init (done q  _)  = ε
  init (step p  ps) =  p  init ps

-- One can simplify the implementation by not carrying around the
-- indices in the type:

  last :  {i j} {xs : Star T i j} 
         Any P Q xs  NonEmptyEdgePred T Q
  last ps with lookup {r = p} (decorate (const (lift tt)) _) ps
  ... | result q _ = nonEmptyEdgePred q