Documentation

Std.Tactic.Init

Simple tactics that are used throughout Std. #

exfalso converts a goal ⊢ tgt into False by applying False.elim.

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    _ in tactic position acts like the done tactic: it fails and gives the list of goals if there are any. It is useful as a placeholder after starting a tactic block such as by _ to make it syntactically correct and show the current goal.

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      fail_if_success t fails if the tactic t succeeds.

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        rwa calls rw, then closes any remaining goals using assumption.

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          Like exact, but takes a list of terms and checks that all goals are discharged after the tactic.

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            by_contra h proves ⊢ p by contradiction, introducing a hypothesis h : ¬p and proving False.

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              Given a proof h of p, absurd h changes the goal to ⊢ ¬ p. If p is a negation ¬q then the goal is changed to ⊢ q instead.

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                split_ands applies And.intro until it does not make progress.

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                  fapply e is like apply e but it adds goals in the order they appear, rather than putting the dependent goals first.

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                    eapply e is like apply e but it does not add subgoals for variables that appear in the types of other goals. Note that this can lead to a failure where there are no goals remaining but there are still metavariables in the term:

                    example (h : ∀ x : Nat, x = x → True) : True := by
                      eapply h
                      rfl
                      -- no goals
                    -- (kernel) declaration has metavariables '_example'
                    
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                      Tries to solve the goal using a canonical proof of True, or the rfl tactic. Unlike trivial or trivial', does not use the contradiction tactic.

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                        conv tactic to close a goal using an equality theorem.

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                          The conv tactic equals claims that the currently focused subexpression is equal to the given expression, and proves this claim using the given tactic.

                          example (P : (Nat → Nat) → Prop) : P (fun n => n - n) := by
                            conv in (_ - _) => equals 0 =>
                              -- current goal: ⊢ n - n = 0
                              apply Nat.sub_self
                            -- current goal: P (fun n => 0)
                          
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