diff options
Diffstat (limited to 'backends/lean/Base/Progress')
-rw-r--r-- | backends/lean/Base/Progress/Base.lean | 2 | ||||
-rw-r--r-- | backends/lean/Base/Progress/Progress.lean | 107 |
2 files changed, 77 insertions, 32 deletions
diff --git a/backends/lean/Base/Progress/Base.lean b/backends/lean/Base/Progress/Base.lean index 613f38f8..a288d889 100644 --- a/backends/lean/Base/Progress/Base.lean +++ b/backends/lean/Base/Progress/Base.lean @@ -60,7 +60,7 @@ section Methods trace[Progress] "Theorem: {th}" -- Dive into the quantified variables and the assumptions forallTelescope th fun fvars th => do - trace[Progress] "All argumens: {fvars}" + trace[Progress] "All arguments: {fvars}" /- -- Filter the argumens which are not propositions let rec getFirstPropIdx (i : Nat) : MetaM Nat := do if i ≥ fargs.size then pure i diff --git a/backends/lean/Base/Progress/Progress.lean b/backends/lean/Base/Progress/Progress.lean index a4df5c96..b0db465d 100644 --- a/backends/lean/Base/Progress/Progress.lean +++ b/backends/lean/Base/Progress/Progress.lean @@ -21,24 +21,11 @@ namespace Test #eval pspecAttr.find? ``Primitives.Vec.index end Test -def progressLookupTheorem (asmTac : TacticM Unit) : TacticM Unit := do - withMainContext do - -- Retrieve the goal - let mgoal ← Tactic.getMainGoal - let goalTy ← mgoal.getType - -- Dive into the goal to lookup the theorem - let (fName, fLevels, args) ← do - withPSpec goalTy fun desc => - -- TODO: check that no universally quantified variables in the arguments - pure (desc.fName, desc.fLevels, desc.args) - -- TODO: also try the assumptions - trace[Progress] "Function: {fName}" - -- TODO: use a list of theorems, and try them one by one? - let thName ← do - match ← pspecAttr.find? fName with - | none => throwError "Could not find a pspec theorem for {fName}" - | some thName => pure thName - trace[Progress] "Lookuped up: {thName}" +inductive TheoremOrLocal where +| Theorem (thName : Name) +| Local (asm : LocalDecl) + +def progressWith (fnExpr : Expr) (th : TheoremOrLocal) (ids : Array Name) (asmTac : TacticM Unit) : TacticM Unit := do /- Apply the theorem We try to match the theorem with the goal In order to do so, we introduce meta-variables for all the parameters @@ -48,10 +35,14 @@ def progressLookupTheorem (asmTac : TacticM Unit) : TacticM Unit := do quantified). We also make sure that all the meta variables which appear in the function arguments have been instantiated - -/ + -/ let env ← getEnv - let thDecl := env.constants.find! thName - let thTy := thDecl.type + let thTy ← do + match th with + | .Theorem thName => + let thDecl := env.constants.find! thName + pure thDecl.type + | .Local asmDecl => pure asmDecl.type -- TODO: the tactic fails if we uncomment withNewMCtxDepth -- withNewMCtxDepth do let (mvars, binders, thExBody) ← forallMetaTelescope thTy @@ -63,18 +54,19 @@ def progressLookupTheorem (asmTac : TacticM Unit) : TacticM Unit := do -- There shouldn't be any existential variables in thBody pure thBody -- Match the body with the target - let target := mkAppN (.const fName fLevels) args - trace[Progress] "mvars:\n{mvars.map Expr.mvarId!}" - trace[Progress] "thBody: {thBody}" - trace[Progress] "target: {target}" - let ok ← isDefEq thBody target - if ¬ ok then throwError "Could not unify the theorem with the target:\n- theorem: {thBody}\n- target: {target}" + trace[Progress] "Maching `{thBody}` with `{fnExpr}`" + let ok ← isDefEq thBody fnExpr + if ¬ ok then throwError "Could not unify the theorem with the target:\n- theorem: {thBody}\n- target: {fnExpr}" + let mgoal ← Tactic.getMainGoal postprocessAppMVars `progress mgoal mvars binders true true Term.synthesizeSyntheticMVarsNoPostponing let thBody ← instantiateMVars thBody trace[Progress] "thBody (after instantiation): {thBody}" -- Add the instantiated theorem to the assumptions (we apply it on the metavariables). - let th ← mkAppOptM thName (mvars.map some) + let th ← do + match th with + | .Theorem thName => mkAppOptM thName (mvars.map some) + | .Local decl => mkAppOptM' (mkFVar decl.fvarId) (mvars.map some) let asmName ← mkFreshUserName `h let thTy ← inferType th let thAsm ← Utils.addDeclTac asmName th thTy (asLet := false) @@ -112,18 +104,71 @@ def progressLookupTheorem (asmTac : TacticM Unit) : TacticM Unit := do -- pure () -elab "progress" : tactic => do - progressLookupTheorem (firstTac [assumptionTac, Arith.scalarTac]) +-- The array of ids are identifiers to use when introducing fresh variables +def progressAsmsOrLookupTheorem (ids : Array Name) (asmTac : TacticM Unit) : TacticM Unit := do + withMainContext do + -- Retrieve the goal + let mgoal ← Tactic.getMainGoal + let goalTy ← mgoal.getType + -- Dive into the goal to lookup the theorem + let (fName, fLevels, args) ← do + withPSpec goalTy fun desc => + -- TODO: check that no universally quantified variables in the arguments + pure (desc.fName, desc.fLevels, desc.args) + -- TODO: this should be in the pspec desc + let fnExpr := mkAppN (.const fName fLevels) args + trace[Progress] "Function: {fName}" + -- Try all the assumptions one by one and if it fails try to lookup a theorem + let ctx ← Lean.MonadLCtx.getLCtx + let decls ← ctx.getDecls + for decl in decls.reverse do + trace[Progress] "Trying assumption: {decl.userName} : {decl.type}" + try + progressWith fnExpr (.Local decl) ids asmTac + return () + catch _ => continue + -- It failed: try to lookup a theorem + -- TODO: use a list of theorems, and try them one by one? + trace[Progress] "No assumption succeeded: trying to lookup a theorem" + let thName ← do + match ← pspecAttr.find? fName with + | none => throwError "Could not find a pspec theorem for {fName}" + | some thName => pure thName + trace[Progress] "Lookuped up: {thName}" + -- Apply the theorem + progressWith fnExpr (.Theorem thName) ids asmTac + +#check Syntax +syntax progressArgs := ("as" " ⟨ " (ident)+ " ⟩")? + +def evalProgress (args : TSyntax `Progress.progressArgs) : TacticM Unit := do + let args := args.raw + -- Process the arguments to retrieve the identifiers to use + trace[Progress] "Progressing arguments: {args}" + let args := args.getArgs + let ids := + if args.size > 0 then + let args := (args.get! 0).getArgs + let args := (args.get! 2).getArgs + args.map Syntax.getId + else #[] + trace[Progress] "Ids: {ids}" + --if args[0] ≠ some "as" then throwError "Invalid syntax: should be: `progress as ⟨ ... ⟩`" + progressAsmsOrLookupTheorem ids (firstTac [assumptionTac, Arith.scalarTac]) + +elab "progress" args:progressArgs : tactic => + evalProgress args namespace Test open Primitives set_option trace.Progress true + set_option pp.rawOnError true @[pspec] theorem vec_index_test2 (α : Type u) (v: Vec α) (i: Usize) (h: i.val < v.val.length) : ∃ (x: α), v.index α i = .ret x := by - progress + progress as ⟨ x y z ⟩ simp set_option trace.Progress false |