lean2/tests/lean/hott/congr_tac.hlean

example (f : nat → nat → nat) (a b c : nat) : b = c → f a b = f a c :=
begin
  intro bc,
  congruence,
  assumption
end

example (f g : nat → nat → nat) (a b c : nat) : f = g → b = c → f a b = g a c :=
begin
  intro fg bc,
  congruence,
  exact fg,
  exact bc
end

example (f g : nat → nat → nat) (a b c : nat) : f = g → b = c → f a b = g a c :=
by intros; congruence; repeat assumption

inductive list (A : Type) :=
| nil {} : list A
| cons   : A → list A → list A

namespace list
notation `[` a `]` := list.cons a list.nil
notation `[` l:(foldr `,` (h t, cons h t) nil `]`) := l
notation h :: t  := cons h t
variable {T : Type}
definition append : list T → list T → list T
| []       l := l
| (h :: s) t := h :: (append s t)
notation l₁ ++ l₂ := append l₁ l₂
end list
open list

example (a b : nat) : a = b → [a] ++ [b] = [b] ++ [a] :=
begin
  intro ab,
  congruence,
  {congruence,
   exact ab},
  {congruence,
   exact (eq.symm ab)}
end

example (a b : nat) : a = b → [a] ++ [b] = [b] ++ [a] :=
by intros; repeat (congruence | assumption | apply eq.symm)
feat(library/tactic): add 'congruence' tactic It is the f_equal described at issue #500. 2015-05-02 19:58:46 +00:00			`example (f : nat → nat → nat) (a b c : nat) : b = c → f a b = f a c :=`
			`begin`
			`intro bc,`
			`congruence,`
			`assumption`
			`end`

			`example (f g : nat → nat → nat) (a b c : nat) : f = g → b = c → f a b = g a c :=`
			`begin`
			`intro fg bc,`
			`congruence,`
			`exact fg,`
			`exact bc`
			`end`

			`example (f g : nat → nat → nat) (a b c : nat) : f = g → b = c → f a b = g a c :=`
feat(library/tactic): improve 'assumption' tactic - It uses the unifier in "conservative" mode - It only affects the current goal closes #570 2015-05-03 00:32:03 +00:00			`by intros; congruence; repeat assumption`
feat(library/tactic): add 'congruence' tactic It is the f_equal described at issue #500. 2015-05-02 19:58:46 +00:00
			`inductive list (A : Type) :=`
			`\| nil {} : list A`
			`\| cons : A → list A → list A`

			`namespace list`
			notation `[` a `]` := list.cons a list.nil
			notation `[` l:(foldr `,` (h t, cons h t) nil `]`) := l
			`notation h :: t := cons h t`
			`variable {T : Type}`
			`definition append : list T → list T → list T`
			`\| [] l := l`
			`\| (h :: s) t := h :: (append s t)`
			`notation l₁ ++ l₂ := append l₁ l₂`
			`end list`
			`open list`

			`example (a b : nat) : a = b → [a] ++ [b] = [b] ++ [a] :=`
			`begin`
			`intro ab,`
			`congruence,`
			`{congruence,`
			`exact ab},`
			`{congruence,`
			`exact (eq.symm ab)}`
			`end`

			`example (a b : nat) : a = b → [a] ++ [b] = [b] ++ [a] :=`
			`by intros; repeat (congruence \| assumption \| apply eq.symm)`