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Diffstat (limited to 'backend/Tunnelingproof.v')
-rw-r--r-- | backend/Tunnelingproof.v | 714 |
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diff --git a/backend/Tunnelingproof.v b/backend/Tunnelingproof.v deleted file mode 100644 index 68913fc9..00000000 --- a/backend/Tunnelingproof.v +++ /dev/null @@ -1,714 +0,0 @@ -(* *********************************************************************) -(* *) -(* The Compcert verified compiler *) -(* *) -(* Xavier Leroy, INRIA Paris-Rocquencourt *) -(* *) -(* Copyright Institut National de Recherche en Informatique et en *) -(* Automatique. All rights reserved. This file is distributed *) -(* under the terms of the INRIA Non-Commercial License Agreement. *) -(* *) -(* *********************************************************************) - -(** Correctness proof for the branch tunneling optimization. *) - -Require Import FunInd. -Require Import Coqlib Maps UnionFind. -Require Import AST Linking. -Require Import Values Memory Events Globalenvs Smallstep. -Require Import Op Locations LTL. -Require Import Tunneling. - -Definition match_prog (p tp: program) := - match_program (fun ctx f tf => tf = tunnel_fundef f) eq p tp. - -Lemma transf_program_match: - forall p, match_prog p (tunnel_program p). -Proof. - intros. eapply match_transform_program; eauto. -Qed. - -(** * Properties of the branch map computed using union-find. *) - -Section BRANCH_MAP_CORRECT. - -Variable fn: LTL.function. - -Definition measure_branch (u: U.t) (pc s: node) (f: node -> nat) : node -> nat := - fun x => if peq (U.repr u s) pc then f x - else if peq (U.repr u x) pc then (f x + f s + 1)%nat - else f x. - -Definition measure_cond (u: U.t) (pc s1 s2: node) (f: node -> nat) : node -> nat := - fun x => if peq (U.repr u s1) pc then f x - else if peq (U.repr u x) pc then (f x + Nat.max (f s1) (f s2) + 1)%nat - else f x. - -Definition branch_map_correct_1 (c: code) (u: U.t) (f: node -> nat): Prop := - forall pc, - match c!pc with - | Some(Lbranch s :: b) => - U.repr u pc = pc \/ (U.repr u pc = U.repr u s /\ f s < f pc)%nat - | _ => - U.repr u pc = pc - end. - -Lemma record_branch_correct: - forall c u f pc b, - branch_map_correct_1 (PTree.remove pc c) u f -> - c!pc = Some b -> - { f' | branch_map_correct_1 c (record_branch u pc b) f' }. -Proof. - intros c u f pc b BMC GET1. - assert (PC: U.repr u pc = pc). - { specialize (BMC pc). rewrite PTree.grs in BMC. auto. } - assert (DFL: { f | branch_map_correct_1 c u f }). - { exists f. intros p. destruct (peq p pc). - - subst p. rewrite GET1. destruct b as [ | [] b ]; auto. - - specialize (BMC p). rewrite PTree.gro in BMC by auto. exact BMC. - } - unfold record_branch. destruct b as [ | [] b ]; auto. - exists (measure_branch u pc s f). intros p. destruct (peq p pc). -+ subst p. rewrite GET1. unfold measure_branch. - rewrite (U.repr_union_2 u pc s); auto. rewrite U.repr_union_3. - destruct (peq (U.repr u s) pc); auto. rewrite PC, peq_true. right; split; auto. lia. -+ specialize (BMC p). rewrite PTree.gro in BMC by auto. - assert (U.repr u p = p -> U.repr (U.union u pc s) p = p). - { intro. rewrite <- H at 2. apply U.repr_union_1. congruence. } - destruct (c!p) as [ [ | [] _ ] | ]; auto. - destruct BMC as [A | [A B]]. auto. - right; split. apply U.sameclass_union_2; auto. - unfold measure_branch. destruct (peq (U.repr u s) pc). auto. - rewrite A. destruct (peq (U.repr u s0) pc); lia. -Qed. - -Lemma record_branches_correct: - { f | branch_map_correct_1 fn.(fn_code) (record_branches fn) f }. -Proof. - unfold record_branches. apply PTree_Properties.fold_ind. -- (* base case *) - intros m EMPTY. exists (fun _ => O). - red; intros. rewrite EMPTY. apply U.repr_empty. -- (* inductive case *) - intros m u pc bb GET1 GET2 [f BMC]. eapply record_branch_correct; eauto. -Qed. - -Definition branch_map_correct_2 (c: code) (u: U.t) (f: node -> nat): Prop := - forall pc, - match fn.(fn_code)!pc with - | Some(Lbranch s :: b) => - U.repr u pc = pc \/ (U.repr u pc = U.repr u s /\ f s < f pc)%nat - | Some(Lcond cond args s1 s2 :: b) => - U.repr u pc = pc \/ (c!pc = None /\ U.repr u pc = U.repr u s1 /\ U.repr u pc = U.repr u s2 /\ f s1 < f pc /\ f s2 < f pc)%nat - | _ => - U.repr u pc = pc - end. - -Lemma record_cond_correct: - forall c u changed f pc b, - branch_map_correct_2 c u f -> - fn.(fn_code)!pc = Some b -> - c!pc <> None -> - let '(c1, u1, _) := record_cond (c, u, changed) pc b in - { f' | branch_map_correct_2 c1 u1 f' }. -Proof. - intros c u changed f pc b BMC GET1 GET2. - assert (DFL: { f' | branch_map_correct_2 c u f' }). - { exists f; auto. } - unfold record_cond. destruct b as [ | [] b ]; auto. - destruct (peq (U.repr u s1) (U.repr u s2)); auto. - exists (measure_cond u pc s1 s2 f). - assert (PC: U.repr u pc = pc). - { specialize (BMC pc). rewrite GET1 in BMC. intuition congruence. } - intro p. destruct (peq p pc). -- subst p. rewrite GET1. unfold measure_cond. - rewrite U.repr_union_2 by auto. rewrite <- e, PC, peq_true. - destruct (peq (U.repr u s1) pc); auto. - right; repeat split. - + apply PTree.grs. - + rewrite U.repr_union_3. auto. - + rewrite U.repr_union_1 by congruence. auto. - + lia. - + lia. -- assert (P: U.repr u p = p -> U.repr (U.union u pc s1) p = p). - { intros. rewrite U.repr_union_1 by congruence. auto. } - specialize (BMC p). destruct (fn_code fn)!p as [ [ | [] bb ] | ]; auto. - + destruct BMC as [A | (A & B)]; auto. right; split. - * apply U.sameclass_union_2; auto. - * unfold measure_cond. rewrite <- A. - destruct (peq (U.repr u s1) pc). auto. - destruct (peq (U.repr u p) pc); lia. - + destruct BMC as [A | (A & B & C & D & E)]; auto. right; split; [ | split; [ | split]]. - * rewrite PTree.gro by auto. auto. - * apply U.sameclass_union_2; auto. - * apply U.sameclass_union_2; auto. - * unfold measure_cond. rewrite <- B, <- C. - destruct (peq (U.repr u s1) pc). auto. - destruct (peq (U.repr u p) pc); lia. -Qed. - -Definition code_compat (c: code) : Prop := - forall pc b, c!pc = Some b -> fn.(fn_code)!pc = Some b. - -Definition code_invariant (c0 c1 c2: code) : Prop := - forall pc, c0!pc = None -> c1!pc = c2!pc. - -Lemma record_conds_1_correct: - forall c u f, - branch_map_correct_2 c u f -> - code_compat c -> - let '(c', u', _) := record_conds_1 (c, u) in - (code_compat c' * { f' | branch_map_correct_2 c' u' f' })%type. -Proof. - intros c0 u0 f0 BMC0 COMPAT0. - unfold record_conds_1. - set (x := PTree.fold record_cond c0 (c0, u0, false)). - set (P := fun (cd: code) (cuc: code * U.t * bool) => - (code_compat (fst (fst cuc)) * - code_invariant cd (fst (fst cuc)) c0 * - { f | branch_map_correct_2 (fst (fst cuc)) (snd (fst cuc)) f })%type). - assert (REC: P c0 x). - { unfold x; apply PTree_Properties.fold_ind. - - intros cd EMPTY. split; [split|]; simpl. - + auto. - + red; auto. - + exists f0; auto. - - intros cd [[c u] changed] pc b GET1 GET2 [[COMPAT INV] [f BMC]]. simpl in *. - split; [split|]. - + unfold record_cond; destruct b as [ | [] b]; simpl; auto. - destruct (peq (U.repr u s1) (U.repr u s2)); simpl; auto. - red; intros. rewrite PTree.grspec in H. destruct (PTree.elt_eq pc0 pc). discriminate. auto. - + assert (DFL: code_invariant cd c c0). - { intros p GET. apply INV. rewrite PTree.gro by congruence. auto. } - unfold record_cond; destruct b as [ | [] b]; simpl; auto. - destruct (peq (U.repr u s1) (U.repr u s2)); simpl; auto. - intros p GET. rewrite PTree.gro by congruence. apply INV. rewrite PTree.gro by congruence. auto. - + assert (GET3: c!pc = Some b). - { rewrite <- GET2. apply INV. apply PTree.grs. } - assert (X: fn.(fn_code)!pc = Some b) by auto. - assert (Y: c!pc <> None) by congruence. - generalize (record_cond_correct c u changed f pc b BMC X Y). - destruct (record_cond (c, u, changed) pc b) as [[c1 u1] changed1]; simpl. - auto. - } - destruct x as [[c1 u1] changed1]; destruct REC as [[COMPAT1 INV1] BMC1]; auto. -Qed. - -Definition branch_map_correct (u: U.t) (f: node -> nat): Prop := - forall pc, - match fn.(fn_code)!pc with - | Some(Lbranch s :: b) => - U.repr u pc = pc \/ (U.repr u pc = U.repr u s /\ f s < f pc)%nat - | Some(Lcond cond args s1 s2 :: b) => - U.repr u pc = pc \/ (U.repr u pc = U.repr u s1 /\ U.repr u pc = U.repr u s2 /\ f s1 < f pc /\ f s2 < f pc)%nat - | _ => - U.repr u pc = pc - end. - -Lemma record_conds_correct: - forall cu, - { f | branch_map_correct_2 (fst cu) (snd cu) f } -> - code_compat (fst cu) -> - { f | branch_map_correct (record_conds cu) f }. -Proof. - intros cu0. functional induction (record_conds cu0); intros. -- destruct cu as [c u], cu' as [c' u'], H as [f BMC]. - generalize (record_conds_1_correct c u f BMC H0). - rewrite e. intros [U V]. apply IHt; auto. -- destruct cu as [c u], H as [f BMC]. - exists f. intros pc. specialize (BMC pc); simpl in *. - destruct (fn_code fn)!pc as [ [ | [] b ] | ]; tauto. -Qed. - -Lemma record_gotos_correct_1: - { f | branch_map_correct (record_gotos fn) f }. -Proof. - apply record_conds_correct; simpl. -- destruct record_branches_correct as [f BMC]. - exists f. intros pc. specialize (BMC pc); simpl in *. - destruct (fn_code fn)!pc as [ [ | [] b ] | ]; auto. -- red; auto. -Qed. - -Definition branch_target (pc: node) : node := - U.repr (record_gotos fn) pc. - -Definition count_gotos (pc: node) : nat := - proj1_sig record_gotos_correct_1 pc. - -Theorem record_gotos_correct: - forall pc, - match fn.(fn_code)!pc with - | Some(Lbranch s :: b) => - branch_target pc = pc \/ - (branch_target pc = branch_target s /\ count_gotos s < count_gotos pc)%nat - | Some(Lcond cond args s1 s2 :: b) => - branch_target pc = pc \/ - (branch_target pc = branch_target s1 /\ branch_target pc = branch_target s2 - /\ count_gotos s1 < count_gotos pc /\ count_gotos s2 < count_gotos pc)%nat - | _ => - branch_target pc = pc - end. -Proof. - intros. unfold count_gotos. destruct record_gotos_correct_1 as [f P]; simpl. - apply P. -Qed. - -End BRANCH_MAP_CORRECT. - -(** * Preservation of semantics *) - -Section PRESERVATION. - -Variables prog tprog: program. -Hypothesis TRANSL: match_prog prog tprog. -Let ge := Genv.globalenv prog. -Let tge := Genv.globalenv tprog. - -Lemma functions_translated: - forall v f, - Genv.find_funct ge v = Some f -> - Genv.find_funct tge v = Some (tunnel_fundef f). -Proof (Genv.find_funct_transf TRANSL). - -Lemma function_ptr_translated: - forall v f, - Genv.find_funct_ptr ge v = Some f -> - Genv.find_funct_ptr tge v = Some (tunnel_fundef f). -Proof (Genv.find_funct_ptr_transf TRANSL). - -Lemma symbols_preserved: - forall id, - Genv.find_symbol tge id = Genv.find_symbol ge id. -Proof (Genv.find_symbol_transf TRANSL). - -Lemma senv_preserved: - Senv.equiv ge tge. -Proof (Genv.senv_transf TRANSL). - -Lemma sig_preserved: - forall f, funsig (tunnel_fundef f) = funsig f. -Proof. - destruct f; reflexivity. -Qed. - -(** The proof of semantic preservation is a simulation argument - based on diagrams of the following form: -<< - st1 --------------- st2 - | | - t| ?|t - | | - v v - st1'--------------- st2' ->> - The [match_states] predicate, defined below, captures the precondition - between states [st1] and [st2], as well as the postcondition between - [st1'] and [st2']. One transition in the source code (left) can correspond - to zero or one transition in the transformed code (right). The - "zero transition" case occurs when executing a [Lgoto] instruction - in the source code that has been removed by tunneling. - - In the definition of [match_states], what changes between the original and - transformed codes is mainly the control-flow - (in particular, the current program point [pc]), but also some values - and memory states, since some [Vundef] values can become more defined - as a consequence of eliminating useless [Lcond] instructions. *) - -Definition tunneled_block (f: function) (b: bblock) := - tunnel_block (record_gotos f) b. - -Definition tunneled_code (f: function) := - PTree.map1 (tunneled_block f) (fn_code f). - -Definition locmap_lessdef (ls1 ls2: locset) : Prop := - forall l, Val.lessdef (ls1 l) (ls2 l). - -Inductive match_stackframes: stackframe -> stackframe -> Prop := - | match_stackframes_intro: - forall f sp ls0 bb tls0, - locmap_lessdef ls0 tls0 -> - match_stackframes - (Stackframe f sp ls0 bb) - (Stackframe (tunnel_function f) sp tls0 (tunneled_block f bb)). - -Inductive match_states: state -> state -> Prop := - | match_states_intro: - forall s f sp pc ls m ts tls tm - (STK: list_forall2 match_stackframes s ts) - (LS: locmap_lessdef ls tls) - (MEM: Mem.extends m tm), - match_states (State s f sp pc ls m) - (State ts (tunnel_function f) sp (branch_target f pc) tls tm) - | match_states_block: - forall s f sp bb ls m ts tls tm - (STK: list_forall2 match_stackframes s ts) - (LS: locmap_lessdef ls tls) - (MEM: Mem.extends m tm), - match_states (Block s f sp bb ls m) - (Block ts (tunnel_function f) sp (tunneled_block f bb) tls tm) - | match_states_interm_branch: - forall s f sp pc bb ls m ts tls tm - (STK: list_forall2 match_stackframes s ts) - (LS: locmap_lessdef ls tls) - (MEM: Mem.extends m tm), - match_states (Block s f sp (Lbranch pc :: bb) ls m) - (State ts (tunnel_function f) sp (branch_target f pc) tls tm) - | match_states_interm_cond: - forall s f sp cond args pc1 pc2 bb ls m ts tls tm - (STK: list_forall2 match_stackframes s ts) - (LS: locmap_lessdef ls tls) - (MEM: Mem.extends m tm) - (SAME: branch_target f pc1 = branch_target f pc2), - match_states (Block s f sp (Lcond cond args pc1 pc2 :: bb) ls m) - (State ts (tunnel_function f) sp (branch_target f pc1) tls tm) - | match_states_call: - forall s f ls m ts tls tm - (STK: list_forall2 match_stackframes s ts) - (LS: locmap_lessdef ls tls) - (MEM: Mem.extends m tm), - match_states (Callstate s f ls m) - (Callstate ts (tunnel_fundef f) tls tm) - | match_states_return: - forall s ls m ts tls tm - (STK: list_forall2 match_stackframes s ts) - (LS: locmap_lessdef ls tls) - (MEM: Mem.extends m tm), - match_states (Returnstate s ls m) - (Returnstate ts tls tm). - -(** Properties of [locmap_lessdef] *) - -Lemma reglist_lessdef: - forall rl ls1 ls2, - locmap_lessdef ls1 ls2 -> Val.lessdef_list (reglist ls1 rl) (reglist ls2 rl). -Proof. - induction rl; simpl; intros; auto. -Qed. - -Lemma locmap_set_lessdef: - forall ls1 ls2 v1 v2 l, - locmap_lessdef ls1 ls2 -> Val.lessdef v1 v2 -> locmap_lessdef (Locmap.set l v1 ls1) (Locmap.set l v2 ls2). -Proof. - intros; red; intros l'. unfold Locmap.set. destruct (Loc.eq l l'). -- destruct l; auto using Val.load_result_lessdef. -- destruct (Loc.diff_dec l l'); auto. -Qed. - -Lemma locmap_set_undef_lessdef: - forall ls1 ls2 l, - locmap_lessdef ls1 ls2 -> locmap_lessdef (Locmap.set l Vundef ls1) ls2. -Proof. - intros; red; intros l'. unfold Locmap.set. destruct (Loc.eq l l'). -- destruct l; auto. destruct ty; auto. -- destruct (Loc.diff_dec l l'); auto. -Qed. - -Lemma locmap_undef_regs_lessdef: - forall rl ls1 ls2, - locmap_lessdef ls1 ls2 -> locmap_lessdef (undef_regs rl ls1) (undef_regs rl ls2). -Proof. - induction rl as [ | r rl]; intros; simpl. auto. apply locmap_set_lessdef; auto. -Qed. - -Lemma locmap_undef_regs_lessdef_1: - forall rl ls1 ls2, - locmap_lessdef ls1 ls2 -> locmap_lessdef (undef_regs rl ls1) ls2. -Proof. - induction rl as [ | r rl]; intros; simpl. auto. apply locmap_set_undef_lessdef; auto. -Qed. - -(* -Lemma locmap_undef_lessdef: - forall ll ls1 ls2, - locmap_lessdef ls1 ls2 -> locmap_lessdef (Locmap.undef ll ls1) (Locmap.undef ll ls2). -Proof. - induction ll as [ | l ll]; intros; simpl. auto. apply IHll. apply locmap_set_lessdef; auto. -Qed. - -Lemma locmap_undef_lessdef_1: - forall ll ls1 ls2, - locmap_lessdef ls1 ls2 -> locmap_lessdef (Locmap.undef ll ls1) ls2. -Proof. - induction ll as [ | l ll]; intros; simpl. auto. apply IHll. apply locmap_set_undef_lessdef; auto. -Qed. -*) - -Lemma locmap_getpair_lessdef: - forall p ls1 ls2, - locmap_lessdef ls1 ls2 -> Val.lessdef (Locmap.getpair p ls1) (Locmap.getpair p ls2). -Proof. - intros; destruct p; simpl; auto using Val.longofwords_lessdef. -Qed. - -Lemma locmap_getpairs_lessdef: - forall pl ls1 ls2, - locmap_lessdef ls1 ls2 -> - Val.lessdef_list (map (fun p => Locmap.getpair p ls1) pl) (map (fun p => Locmap.getpair p ls2) pl). -Proof. - intros. induction pl; simpl; auto using locmap_getpair_lessdef. -Qed. - -Lemma locmap_setpair_lessdef: - forall p ls1 ls2 v1 v2, - locmap_lessdef ls1 ls2 -> Val.lessdef v1 v2 -> locmap_lessdef (Locmap.setpair p v1 ls1) (Locmap.setpair p v2 ls2). -Proof. - intros; destruct p; simpl; auto using locmap_set_lessdef, Val.loword_lessdef, Val.hiword_lessdef. -Qed. - -Lemma locmap_setres_lessdef: - forall res ls1 ls2 v1 v2, - locmap_lessdef ls1 ls2 -> Val.lessdef v1 v2 -> locmap_lessdef (Locmap.setres res v1 ls1) (Locmap.setres res v2 ls2). -Proof. - induction res; intros; simpl; auto using locmap_set_lessdef, Val.loword_lessdef, Val.hiword_lessdef. -Qed. - -Lemma locmap_undef_caller_save_regs_lessdef: - forall ls1 ls2, - locmap_lessdef ls1 ls2 -> locmap_lessdef (undef_caller_save_regs ls1) (undef_caller_save_regs ls2). -Proof. - intros; red; intros. unfold undef_caller_save_regs. - destruct l. -- destruct (Conventions1.is_callee_save r); auto. -- destruct sl; auto. -Qed. - -Lemma find_function_translated: - forall ros ls tls fd, - locmap_lessdef ls tls -> - find_function ge ros ls = Some fd -> - find_function tge ros tls = Some (tunnel_fundef fd). -Proof. - intros. destruct ros; simpl in *. -- assert (E: tls (R m) = ls (R m)). - { exploit Genv.find_funct_inv; eauto. intros (b & EQ). - generalize (H (R m)). rewrite EQ. intros LD; inv LD. auto. } - rewrite E. apply functions_translated; auto. -- rewrite symbols_preserved. destruct (Genv.find_symbol ge i); inv H0. - apply function_ptr_translated; auto. -Qed. - -Lemma call_regs_lessdef: - forall ls1 ls2, locmap_lessdef ls1 ls2 -> locmap_lessdef (call_regs ls1) (call_regs ls2). -Proof. - intros; red; intros. destruct l as [r | [] ofs ty]; simpl; auto. -Qed. - -Lemma return_regs_lessdef: - forall caller1 callee1 caller2 callee2, - locmap_lessdef caller1 caller2 -> - locmap_lessdef callee1 callee2 -> - locmap_lessdef (return_regs caller1 callee1) (return_regs caller2 callee2). -Proof. - intros; red; intros. destruct l; simpl. -- destruct (Conventions1.is_callee_save r); auto. -- destruct sl; auto. -Qed. - -(** To preserve non-terminating behaviours, we show that the transformed - code cannot take an infinity of "zero transition" cases. - We use the following [measure] function over source states, - which decreases strictly in the "zero transition" case. *) - -Definition measure (st: state) : nat := - match st with - | State s f sp pc ls m => (count_gotos f pc * 2)%nat - | Block s f sp (Lbranch pc :: _) ls m => (count_gotos f pc * 2 + 1)%nat - | Block s f sp (Lcond _ _ pc1 pc2 :: _) ls m => (Nat.max (count_gotos f pc1) (count_gotos f pc2) * 2 + 1)%nat - | Block s f sp bb ls m => 0%nat - | Callstate s f ls m => 0%nat - | Returnstate s ls m => 0%nat - end. - -Lemma match_parent_locset: - forall s ts, - list_forall2 match_stackframes s ts -> - locmap_lessdef (parent_locset s) (parent_locset ts). -Proof. - induction 1; simpl. -- red; auto. -- inv H; auto. -Qed. - -Lemma tunnel_step_correct: - forall st1 t st2, step ge st1 t st2 -> - forall st1' (MS: match_states st1 st1'), - (exists st2', step tge st1' t st2' /\ match_states st2 st2') - \/ (measure st2 < measure st1 /\ t = E0 /\ match_states st2 st1')%nat. -Proof. - induction 1; intros; try inv MS. - -- (* entering a block *) - assert (DEFAULT: branch_target f pc = pc -> - (exists st2' : state, - step tge (State ts (tunnel_function f) sp (branch_target f pc) tls tm) E0 st2' - /\ match_states (Block s f sp bb rs m) st2')). - { intros. rewrite H0. econstructor; split. - econstructor. simpl. rewrite PTree.gmap1. rewrite H. simpl. eauto. - econstructor; eauto. } - - generalize (record_gotos_correct f pc). rewrite H. - destruct bb; auto. destruct i; auto. -+ (* Lbranch *) - intros [A | [B C]]. auto. - right. split. simpl. lia. - split. auto. - rewrite B. econstructor; eauto. -+ (* Lcond *) - intros [A | (B & C & D & E)]. auto. - right. split. simpl. lia. - split. auto. - rewrite B. econstructor; eauto. congruence. - -- (* Lop *) - exploit eval_operation_lessdef. apply reglist_lessdef; eauto. eauto. eauto. - intros (tv & EV & LD). - left; simpl; econstructor; split. - eapply exec_Lop with (v := tv); eauto. - rewrite <- EV. apply eval_operation_preserved. exact symbols_preserved. - econstructor; eauto using locmap_set_lessdef, locmap_undef_regs_lessdef. -- (* Lload *) - exploit eval_addressing_lessdef. apply reglist_lessdef; eauto. eauto. - intros (ta & EV & LD). - exploit Mem.loadv_extends. eauto. eauto. eexact LD. - intros (tv & LOAD & LD'). - left; simpl; econstructor; split. - eapply exec_Lload with (a := ta). - rewrite <- EV. apply eval_addressing_preserved. exact symbols_preserved. - eauto. eauto. - econstructor; eauto using locmap_set_lessdef, locmap_undef_regs_lessdef. -- (* Lgetstack *) - left; simpl; econstructor; split. - econstructor; eauto. - econstructor; eauto using locmap_set_lessdef, locmap_undef_regs_lessdef. -- (* Lsetstack *) - left; simpl; econstructor; split. - econstructor; eauto. - econstructor; eauto using locmap_set_lessdef, locmap_undef_regs_lessdef. -- (* Lstore *) - exploit eval_addressing_lessdef. apply reglist_lessdef; eauto. eauto. - intros (ta & EV & LD). - exploit Mem.storev_extends. eauto. eauto. eexact LD. apply LS. - intros (tm' & STORE & MEM'). - left; simpl; econstructor; split. - eapply exec_Lstore with (a := ta). - rewrite <- EV. apply eval_addressing_preserved. exact symbols_preserved. - eauto. eauto. - econstructor; eauto using locmap_undef_regs_lessdef. -- (* Lcall *) - left; simpl; econstructor; split. - eapply exec_Lcall with (fd := tunnel_fundef fd); eauto. - eapply find_function_translated; eauto. - rewrite sig_preserved. auto. - econstructor; eauto. - constructor; auto. - constructor; auto. -- (* Ltailcall *) - exploit Mem.free_parallel_extends. eauto. eauto. intros (tm' & FREE & MEM'). - left; simpl; econstructor; split. - eapply exec_Ltailcall with (fd := tunnel_fundef fd); eauto. - eapply find_function_translated; eauto using return_regs_lessdef, match_parent_locset. - apply sig_preserved. - econstructor; eauto using return_regs_lessdef, match_parent_locset. -- (* Lbuiltin *) - exploit eval_builtin_args_lessdef. eexact LS. eauto. eauto. intros (tvargs & EVA & LDA). - exploit external_call_mem_extends; eauto. intros (tvres & tm' & A & B & C & D). - left; simpl; econstructor; split. - eapply exec_Lbuiltin; eauto. - eapply eval_builtin_args_preserved with (ge1 := ge); eauto. exact symbols_preserved. - eapply external_call_symbols_preserved. apply senv_preserved. eauto. - econstructor; eauto using locmap_setres_lessdef, locmap_undef_regs_lessdef. -- (* Lbranch (preserved) *) - left; simpl; econstructor; split. - eapply exec_Lbranch; eauto. - fold (branch_target f pc). econstructor; eauto. -- (* Lbranch (eliminated) *) - right; split. simpl. lia. split. auto. constructor; auto. - -- (* Lcond (preserved) *) - simpl tunneled_block. - set (s1 := U.repr (record_gotos f) pc1). set (s2 := U.repr (record_gotos f) pc2). - destruct (peq s1 s2). -+ left; econstructor; split. - eapply exec_Lbranch. - set (pc := if b then pc1 else pc2). - replace s1 with (branch_target f pc) by (unfold pc; destruct b; auto). - constructor; eauto using locmap_undef_regs_lessdef_1. -+ left; econstructor; split. - eapply exec_Lcond; eauto. eapply eval_condition_lessdef; eauto using reglist_lessdef. - destruct b; econstructor; eauto using locmap_undef_regs_lessdef. -- (* Lcond (eliminated) *) - right; split. simpl. destruct b; lia. - split. auto. - set (pc := if b then pc1 else pc2). - replace (branch_target f pc1) with (branch_target f pc) by (unfold pc; destruct b; auto). - econstructor; eauto. - -- (* Ljumptable *) - assert (tls (R arg) = Vint n). - { generalize (LS (R arg)); rewrite H; intros LD; inv LD; auto. } - left; simpl; econstructor; split. - eapply exec_Ljumptable. - eauto. rewrite list_nth_z_map. change U.elt with node. rewrite H0. reflexivity. eauto. - econstructor; eauto using locmap_undef_regs_lessdef. -- (* Lreturn *) - exploit Mem.free_parallel_extends. eauto. eauto. intros (tm' & FREE & MEM'). - left; simpl; econstructor; split. - eapply exec_Lreturn; eauto. - constructor; eauto using return_regs_lessdef, match_parent_locset. -- (* internal function *) - exploit Mem.alloc_extends. eauto. eauto. apply Z.le_refl. apply Z.le_refl. - intros (tm' & ALLOC & MEM'). - left; simpl; econstructor; split. - eapply exec_function_internal; eauto. - simpl. econstructor; eauto using locmap_undef_regs_lessdef, call_regs_lessdef. -- (* external function *) - exploit external_call_mem_extends; eauto using locmap_getpairs_lessdef. - intros (tvres & tm' & A & B & C & D). - left; simpl; econstructor; split. - eapply exec_function_external; eauto. - eapply external_call_symbols_preserved; eauto. apply senv_preserved. - simpl. econstructor; eauto using locmap_setpair_lessdef, locmap_undef_caller_save_regs_lessdef. -- (* return *) - inv STK. inv H1. - left; econstructor; split. - eapply exec_return; eauto. - constructor; auto. -Qed. - -Lemma transf_initial_states: - forall st1, initial_state prog st1 -> - exists st2, initial_state tprog st2 /\ match_states st1 st2. -Proof. - intros. inversion H. - exists (Callstate nil (tunnel_fundef f) (Locmap.init Vundef) m0); split. - econstructor; eauto. - apply (Genv.init_mem_transf TRANSL); auto. - rewrite (match_program_main TRANSL). - rewrite symbols_preserved. eauto. - apply function_ptr_translated; auto. - rewrite <- H3. apply sig_preserved. - constructor. constructor. red; simpl; auto. apply Mem.extends_refl. -Qed. - -Lemma transf_final_states: - forall st1 st2 r, - match_states st1 st2 -> final_state st1 r -> final_state st2 r. -Proof. - intros. inv H0. inv H. inv STK. - set (p := map_rpair R (Conventions1.loc_result signature_main)) in *. - generalize (locmap_getpair_lessdef p _ _ LS). rewrite H1; intros LD; inv LD. - econstructor; eauto. -Qed. - -Theorem transf_program_correct: - forward_simulation (LTL.semantics prog) (LTL.semantics tprog). -Proof. - eapply forward_simulation_opt. - apply senv_preserved. - eexact transf_initial_states. - eexact transf_final_states. - eexact tunnel_step_correct. -Qed. - -End PRESERVATION. |