david-christiansen · October 26, 2017 22:21
diff --git a/NatInd.idr b/NatInd.idr
 module NatInd

 import Language.Reflection.Elab
 import Language.Reflection.Utils

 %default total

 trivial : Elab ()
 trivial = do compute
             g <- snd <$> getGoal
             case !(forgetTypes g) of
               `((=) {A=~A} {B=~_} ~x ~_) =>
                  apply [| (Var (UN "Refl")) A x |]
               `(():Type) =>
                 apply `(():())
               _ => fail [TermPart g, TextPart "is not trivial"]

 test1 : 2 + 4 = 6
 test1 = %runElab (trivial *> solve)

 test2 : if True then () else Nat
 test2  = %runElab (trivial *> solve)


 natInd : (P : Nat -> Type) -> P Z -> ((n : Nat) -> P n -> P (S n)) -> (n : Nat) -> P n
 natInd P z s Z     = z
 natInd P z s (S k) = s k (natInd P z s k)

 ||| Perform induction over the natural numbers.  Returns a pair
 ||| consisting of the names of the holes left for the base and step
 ||| cases.
 induction : TTName -> Elab (TTName, TTName)
 induction n =
  do g <- snd <$> getGoal
     motive <- RBind n (Lam `(Nat)) <$> forgetTypes g
     baseH <- gensym "base"
     claim baseH [| motive `(Z) |]
     unfocus baseH
     stepH <- gensym "step"
     claim stepH `((k : Nat) ->
                   ~(RApp motive (Var (UN "k"))) ->
                   ~(RApp motive (RApp `(S) (Var (UN "k")))))
     unfocus stepH
     apply `(natInd ~motive ~(Var baseH) ~(Var stepH) ~(Var n))
     solve
     return (baseH, stepH)

 total
 theorem : (n : Nat) -> plus n 1 = S n
 theorem n =
  %runElab (do names <- induction `{n}
               focus (fst names);
                 do trivial ; solve
               focus (snd names);
                 do compute
                    attack
                    intro (Just (UN "x"))
                    intro (Just (UN "ih"))
                    rewriteWith (Var (UN "ih"))
                    trivial
                    solve
               solve)

 ||| Do Nat induction in the easy way - by encapsulating the common
 ||| pattern of a trivial base case and an induction step that just
 ||| rewrites with the hypothesis.
 easyInduction : TTName -> Elab ()
 easyInduction n = (do names <- induction n
                      focus (fst names);
                        do trivial ; solve
                      focus (snd names);
                        do compute
                           attack
                           m <- gensym "m"
                           ih <- gensym "ih"
                           intro (Just m)
                           intro (Just ih)
                           rewriteWith (Var ih)
                           trivial
                           solve
                      solve)
                  <|> (do g <- snd <$> getGoal
                          fail [ TextPart "Can't solve goal "
                               , TermPart g
                               , TextPart "with easy induction."])




 theorem' : (n : Nat) -> n + 1 = S n
 theorem' n = %runElab (easyInduction `{n})


 plusSuccR : (n, m : Nat) -> n + (S m) = S (n + m)
 plusSuccR n m = %runElab (easyInduction `{n})

 plusZeroRightId : (n : Nat) -> n + 0 = n
 plusZeroRightId n = %runElab (easyInduction `{n})

 assoc : (n,m,o : Nat) -> n + (m + o) = (n + m) + o
 assoc n m o = %runElab (easyInduction `{n})
	module NatInd

	import Language.Reflection.Elab
	import Language.Reflection.Utils

	%default total

	trivial : Elab ()
	trivial = do compute
	g <- snd <$> getGoal
	case !(forgetTypes g) of
	`((=) {A=~A} {B=~_} ~x ~_) =>
	apply [\| (Var (UN "Refl")) A x \|]
	`(():Type) =>
	apply `(():())
	_ => fail [TermPart g, TextPart "is not trivial"]

	test1 : 2 + 4 = 6
	test1 = %runElab (trivial *> solve)

	test2 : if True then () else Nat
	test2 = %runElab (trivial *> solve)


	natInd : (P : Nat -> Type) -> P Z -> ((n : Nat) -> P n -> P (S n)) -> (n : Nat) -> P n
	natInd P z s Z = z
	natInd P z s (S k) = s k (natInd P z s k)

	\|\|\| Perform induction over the natural numbers. Returns a pair
	\|\|\| consisting of the names of the holes left for the base and step
	\|\|\| cases.
	induction : TTName -> Elab (TTName, TTName)
	induction n =
	do g <- snd <$> getGoal
	motive <- RBind n (Lam `(Nat)) <$> forgetTypes g
	baseH <- gensym "base"
	claim baseH [\| motive `(Z) \|]
	unfocus baseH
	stepH <- gensym "step"
	claim stepH `((k : Nat) ->
	~(RApp motive (Var (UN "k"))) ->
	~(RApp motive (RApp `(S) (Var (UN "k")))))
	unfocus stepH
	apply `(natInd ~motive ~(Var baseH) ~(Var stepH) ~(Var n))
	solve
	return (baseH, stepH)

	total
	theorem : (n : Nat) -> plus n 1 = S n
	theorem n =
	%runElab (do names <- induction `{n}
	focus (fst names);
	do trivial ; solve
	focus (snd names);
	do compute
	attack
	intro (Just (UN "x"))
	intro (Just (UN "ih"))
	rewriteWith (Var (UN "ih"))
	trivial
	solve
	solve)

	\|\|\| Do Nat induction in the easy way - by encapsulating the common
	\|\|\| pattern of a trivial base case and an induction step that just
	\|\|\| rewrites with the hypothesis.
	easyInduction : TTName -> Elab ()
	easyInduction n = (do names <- induction n
	focus (fst names);
	do trivial ; solve
	focus (snd names);
	do compute
	attack
	m <- gensym "m"
	ih <- gensym "ih"
	intro (Just m)
	intro (Just ih)
	rewriteWith (Var ih)
	trivial
	solve
	solve)
	<\|> (do g <- snd <$> getGoal
	fail [ TextPart "Can't solve goal "
	, TermPart g
	, TextPart "with easy induction."])




	theorem' : (n : Nat) -> n + 1 = S n
	theorem' n = %runElab (easyInduction `{n})


	plusSuccR : (n, m : Nat) -> n + (S m) = S (n + m)
	plusSuccR n m = %runElab (easyInduction `{n})

	plusZeroRightId : (n : Nat) -> n + 0 = n
	plusZeroRightId n = %runElab (easyInduction `{n})

	assoc : (n,m,o : Nat) -> n + (m + o) = (n + m) + o
	assoc n m o = %runElab (easyInduction `{n})