/- Copyright (c) 2014 Microsoft Corporation. All rights reserved. Released under Apache 2.0 license as described in the file LICENSE. Author: Leonardo de Moura This is just a trick to embed the 'tactic language' as a Lean expression. We should view 'tactic' as automation that when execute produces a term. tactic.builtin is just a "dummy" for creating the definitions that are actually implemented in C++ -/ prelude import init.datatypes init.reserved_notation inductive tactic : Type := builtin : tactic namespace tactic -- Remark the following names are not arbitrary, the tactic module -- uses them when converting Lean expressions into actual tactic objects. -- The bultin 'by' construct triggers the process of converting a -- a term of type 'tactic' into a tactic that sythesizes a term opaque definition and_then (t1 t2 : tactic) : tactic := builtin opaque definition or_else (t1 t2 : tactic) : tactic := builtin opaque definition append (t1 t2 : tactic) : tactic := builtin opaque definition interleave (t1 t2 : tactic) : tactic := builtin opaque definition par (t1 t2 : tactic) : tactic := builtin opaque definition fixpoint (f : tactic → tactic) : tactic := builtin opaque definition repeat (t : tactic) : tactic := builtin opaque definition at_most (t : tactic) (k : num) : tactic := builtin opaque definition discard (t : tactic) (k : num) : tactic := builtin opaque definition focus_at (t : tactic) (i : num) : tactic := builtin opaque definition try_for (t : tactic) (ms : num) : tactic := builtin opaque definition now : tactic := builtin opaque definition assumption : tactic := builtin opaque definition eassumption : tactic := builtin opaque definition state : tactic := builtin opaque definition fail : tactic := builtin opaque definition id : tactic := builtin opaque definition beta : tactic := builtin opaque definition info : tactic := builtin opaque definition whnf : tactic := builtin opaque definition rotate_left (k : num) := builtin opaque definition rotate_right (k : num) := builtin definition rotate (k : num) := rotate_left k -- This is just a trick to embed expressions into tactics. -- The nested expressions are "raw". They tactic should -- elaborate them when it is executed. inductive expr : Type := builtin : expr opaque definition apply (e : expr) : tactic := builtin opaque definition rapply (e : expr) : tactic := builtin opaque definition fapply (e : expr) : tactic := builtin opaque definition rename (a b : expr) : tactic := builtin opaque definition intro (e : expr) : tactic := builtin opaque definition generalize (e : expr) : tactic := builtin opaque definition clear (e : expr) : tactic := builtin opaque definition revert (e : expr) : tactic := builtin opaque definition unfold (e : expr) : tactic := builtin opaque definition exact (e : expr) : tactic := builtin opaque definition trace (s : string) : tactic := builtin opaque definition inversion (id : expr) : tactic := builtin notation a `↦` b:max := rename a b inductive expr_list : Type := nil : expr_list, cons : expr → expr_list → expr_list opaque definition inversion_with (id : expr) (ids : expr_list) : tactic := builtin notation `cases` a:max := inversion a notation `cases` a:max `with` `(` l:(foldr `,` (h t, expr_list.cons h t) expr_list.nil) `)` := inversion_with a l opaque definition intro_lst (ids : expr_list) : tactic := builtin notation `intros` := intro_lst expr_list.nil notation `intros` `(` l:(foldr `,` (h t, expr_list.cons h t) expr_list.nil) `)` := intro_lst l opaque definition generalize_lst (es : expr_list) : tactic := builtin notation `generalizes` `(` l:(foldr `,` (h t, expr_list.cons h t) expr_list.nil) `)` := generalize_lst l opaque definition clear_lst (ids : expr_list) : tactic := builtin notation `clears` `(` l:(foldr `,` (h t, expr_list.cons h t) expr_list.nil) `)` := clear_lst l opaque definition revert_lst (ids : expr_list) : tactic := builtin notation `reverts` `(` l:(foldr `,` (h t, expr_list.cons h t) expr_list.nil) `)` := revert_lst l opaque definition assert_hypothesis (id : expr) (e : expr) : tactic := builtin notation `assert` `(` id `:` ty `)` := assert_hypothesis id ty infixl `;`:15 := and_then notation `[` h:10 `|`:10 r:(foldl:10 `|` (e r, or_else r e) h) `]` := r definition try (t : tactic) : tactic := [t | id] definition repeat1 (t : tactic) : tactic := t ; repeat t definition focus (t : tactic) : tactic := focus_at t 0 definition determ (t : tactic) : tactic := at_most t 1 end tactic