universe u namespace GraphPath variable {V : Type u} def Edge (V : Type u) := V → V → Prop inductive Path (E : Edge V) : V → V → Prop | nil : ∀ v, Path E v v | step : ∀ {u v w}, Path E u v → E v w → Path E u w variable {E : Edge V} theorem refl (v : V) : Path (E:=E) v v := Path.nil v theorem trans {u v w : V} : Path (E:=E) u v → Path (E:=E) v w → Path (E:=E) u w := by intro p1 p2; induction p2 with | nil => simpa using p1 | step p2' evw ih => exact Path.step ih evw def Erev (E : Edge V) : Edge V := fun x y => E y x def undirected (E : Edge V) : Prop := ∀ x y, E x y → E y x theorem reverse_path {u v : V} (hE : undirected E) : Path (E:=E) u v → Path (E:=E) v u := by intro p; induction p with | nil => exact Path.nil _ | step p' evw ih => have hwv : Path (E:=E) _ _ := Path.step (E:=E) (Path.nil _) (hE _ _ evw) exact trans (E:=E) hwv ih theorem concat_edge_right {u v w : V} : Path (E:=E) u v → E v w → Path (E:=E) u w := by intro p evw; exact Path.step p evw theorem concat {u v w : V} : Path (E:=E) u v → Path (E:=E) v w → Path (E:=E) u w := by intro p q; exact trans p q theorem edge_path {u v : V} : E u v → Path (E:=E) u v := by intro euv; exact Path.step (Path.nil u) euv theorem concat_edge_left {u v w : V} : E u v → Path (E:=E) v w → Path (E:=E) u w := by intro euv pvw; exact trans (edge_path (E:=E) euv) pvw theorem concat3 {u v w t : V} : Path (E:=E) u v → Path (E:=E) v w → Path (E:=E) w t → Path (E:=E) u t := by intro puv pvw pwt; exact trans (trans puv pvw) pwt theorem reverse_in_Erev {u v : V} : Path (E:=E) u v → Path (E:=Erev E) v u := by intro p; induction p with | nil => exact Path.nil _ | step p' evw ih => have hwv : Path (E:=Erev E) _ _ := Path.step (Path.nil _) evw exact trans hwv ih theorem cycle_refl {v w : V} : Path (E:=E) v w → Path (E:=E) w v → Path (E:=E) v v := by intro pvw pwv; exact trans pvw pwv end GraphPath