Recognition of tail calls: correctness proof

Require Import Coqlib.
Require Import Maps.
Require Import AST.
Require Import Integers.
Require Import Values.
Require Import Memory.
Require Import Op.
Require Import Events.
Require Import Globalenvs.
Require Import Smallstep.
Require Import Registers.
Require Import RTL.
Require Import Conventions.
Require Import Tailcall.

Syntactic properties of the code transformation

Measuring the number of instructions eliminated

The return_measure c pc function counts the number of instructions eliminated by the code transformation, where pc is the successor of a call turned into a tailcall. This is the length of the move/nop/return sequence recognized by the is_return boolean function.

Fixpoint return_measure_rec (n: nat) (c: code) (pc: node)
                            {struct n}: nat :=
  match n with
  | O => O
  | S n' =>
      match c!pc with
      | Some(Inop s) => S(return_measure_rec n' c s)
      | Some(Iop op args dst s) => S(return_measure_rec n' c s)
      | _ => O
      end
  end.

Definition return_measure (c: code) (pc: node) :=
  return_measure_rec niter c pc.

Lemma return_measure_bounds:
  forall f pc, (return_measure f pc <= niter)%nat.

Proof.

  intro f.
  assert (forall n pc, (return_measure_rec n f pc <= n)%nat).
    induction n; intros; simpl.
    omega.
    destruct (f!pc); try omega.
    destruct i; try omega.
    generalize (IHn n0). omega.
    generalize (IHn n0). omega.
  intros. unfold return_measure. apply H.
Qed.

Remark return_measure_rec_incr:
  forall f n1 n2 pc,
  (n1 <= n2)%nat ->
  (return_measure_rec n1 f pc <= return_measure_rec n2 f pc)%nat.

Proof.

  induction n1; intros; simpl.
  omega.
  destruct n2. omegaContradiction. assert (n1 <= n2)%nat by omega.
  simpl. destruct f!pc; try omega. destruct i; try omega.
  generalize (IHn1 n2 n H0). omega.
  generalize (IHn1 n2 n H0). omega.
Qed.

Lemma is_return_measure_rec:
  forall f n n' pc r,
  is_return n f pc r = true -> (n <= n')%nat ->
  return_measure_rec n f.(fn_code) pc = return_measure_rec n' f.(fn_code) pc.

Proof.

  induction n; simpl; intros.
  congruence.
  destruct n'. omegaContradiction. simpl.
  destruct (fn_code f)!pc; try congruence.
  destruct i; try congruence.
  decEq. apply IHn with r. auto. omega.
  destruct (is_move_operation o l); try congruence.
  destruct (Reg.eq r r1); try congruence.
  decEq. apply IHn with r0. auto. omega.
Qed.

Relational characterization of the code transformation

The is_return_spec characterizes the instruction sequences recognized by the is_return boolean function.

Inductive is_return_spec (f:function): node -> reg -> Prop :=
  | is_return_none: forall pc r,
      f.(fn_code)!pc = Some(Ireturn None) ->
      is_return_spec f pc r
  | is_return_some: forall pc r,
      f.(fn_code)!pc = Some(Ireturn (Some r)) ->
      is_return_spec f pc r
  | is_return_nop: forall pc r s,
      f.(fn_code)!pc = Some(Inop s) ->
      is_return_spec f s r ->
      (return_measure f.(fn_code) s < return_measure f.(fn_code) pc)%nat ->
      is_return_spec f pc r
  | is_return_move: forall pc r r' s,
      f.(fn_code)!pc = Some(Iop Omove (r::nil) r' s) ->
      is_return_spec f s r' ->
      (return_measure f.(fn_code) s < return_measure f.(fn_code) pc)%nat ->
     is_return_spec f pc r.

Lemma is_return_charact:
  forall f n pc rret,
  is_return n f pc rret = true -> (n <= niter)%nat ->
  is_return_spec f pc rret.

Proof.

  induction n; intros.
  simpl in H. congruence.
  generalize H. simpl.
  caseEq ((fn_code f)!pc); try congruence.
  intro i. caseEq i; try congruence.
  intros s; intros. eapply is_return_nop; eauto. eapply IHn; eauto. omega.
  unfold return_measure.
  rewrite <- (is_return_measure_rec f (S n) niter pc rret); auto.
  rewrite <- (is_return_measure_rec f n niter s rret); auto.
  simpl. rewrite H2. omega. omega.

  intros op args dst s EQ1 EQ2.
  caseEq (is_move_operation op args); try congruence.
  intros src IMO. destruct (Reg.eq rret src); try congruence.
  subst rret. intro.
  exploit is_move_operation_correct; eauto. intros [A B]. subst.
  eapply is_return_move; eauto. eapply IHn; eauto. omega.
  unfold return_measure.
  rewrite <- (is_return_measure_rec f (S n) niter pc src); auto.
  rewrite <- (is_return_measure_rec f n niter s dst); auto.
  simpl. rewrite EQ2. omega. omega.

  intros or EQ1 EQ2. destruct or; intros.
  assert (r = rret). eapply proj_sumbool_true; eauto. subst r.
  apply is_return_some; auto.
  apply is_return_none; auto.
Qed.

The transf_instr_spec predicate relates one instruction in the initial code with its possible transformations in the optimized code.

Inductive transf_instr_spec (f: function): instruction -> instruction -> Prop :=
  | transf_instr_tailcall: forall sig ros args res s,
      f.(fn_stacksize) = 0 ->
      is_return_spec f s res ->
      transf_instr_spec f (Icall sig ros args res s) (Itailcall sig ros args)
  | transf_instr_default: forall i,
      transf_instr_spec f i i.

Lemma transf_instr_charact:
  forall f pc instr,
  f.(fn_stacksize) = 0 ->
  transf_instr_spec f instr (transf_instr f pc instr).

Proof.

  intros. unfold transf_instr. destruct instr; try constructor.
  caseEq (is_return niter f n r && tailcall_is_possible s &&
          opt_typ_eq (sig_res s) (sig_res (fn_sig f))); intros.
  destruct (andb_prop _ _ H0). destruct (andb_prop _ _ H1).
  eapply transf_instr_tailcall; eauto.
  eapply is_return_charact; eauto.
  constructor.
Qed.

Lemma transf_instr_lookup:
  forall f pc i,
  f.(fn_code)!pc = Some i ->
  exists i', (transf_function f).(fn_code)!pc = Some i' /\ transf_instr_spec f i i'.

Proof.

  intros. unfold transf_function.
  destruct (zeq (fn_stacksize f) 0).
  simpl. rewrite PTree.gmap. rewrite H. simpl.
  exists (transf_instr f pc i); split. auto. apply transf_instr_charact; auto.
  exists i; split. auto. constructor.
Qed.

Semantic properties of the code transformation

The ``less defined than'' relation between register states

A call followed by a return without an argument can be turned into a tail call. In this case, the original function returns Vundef, while the transformed function can return any value. We account for this situation by using the ``less defined than'' relation between values and between memory states. We need to extend it pointwise to register states.

Lemma regs_lessdef_init_regs:
  forall params vl vl',
  Val.lessdef_list vl vl' ->
  regs_lessdef (init_regs vl params) (init_regs vl' params).

Proof.

  induction params; intros.
  simpl. red; intros. rewrite Regmap.gi. constructor.
  simpl. inv H. red; intros. rewrite Regmap.gi. constructor.
  apply set_reg_lessdef. auto. auto.
Qed.

Proof of semantic preservation

Section PRESERVATION.

Variable prog: program.
Let tprog := transf_program prog.
Let ge := Genv.globalenv prog.
Let tge := Genv.globalenv tprog.

Lemma symbols_preserved:
  forall (s: ident), Genv.find_symbol tge s = Genv.find_symbol ge s.
Proof (Genv.find_symbol_transf transf_fundef prog).

Lemma public_preserved:
  forall (s: ident), Genv.public_symbol tge s = Genv.public_symbol ge s.
Proof (Genv.public_symbol_transf transf_fundef prog).

Lemma varinfo_preserved:
  forall b, Genv.find_var_info tge b = Genv.find_var_info ge b.
Proof (Genv.find_var_info_transf transf_fundef prog).

Lemma functions_translated:
  forall (v: val) (f: RTL.fundef),
  Genv.find_funct ge v = Some f ->
  Genv.find_funct tge v = Some (transf_fundef f).
Proof (@Genv.find_funct_transf _ _ _ transf_fundef prog).

Lemma funct_ptr_translated:
  forall (b: block) (f: RTL.fundef),
  Genv.find_funct_ptr ge b = Some f ->
  Genv.find_funct_ptr tge b = Some (transf_fundef f).
Proof (@Genv.find_funct_ptr_transf _ _ _ transf_fundef prog).

Lemma sig_preserved:
  forall f, funsig (transf_fundef f) = funsig f.

Proof.

destruct f; auto. simpl. unfold transf_function.
destruct (zeq (fn_stacksize f) 0); auto.
Qed.

Lemma stacksize_preserved:
forall f, fn_stacksize (transf_function f) = fn_stacksize f.

Proof.

unfold transf_function. intros.
destruct (zeq (fn_stacksize f) 0); auto.
Qed.

Lemma find_function_translated:
  forall ros rs rs' f,
  find_function ge ros rs = Some f ->
  regs_lessdef rs rs' ->
  find_function tge ros rs' = Some (transf_fundef f).

Proof.

  intros until f; destruct ros; simpl.
  intros.
  assert (rs'#r = rs#r).
    exploit Genv.find_funct_inv; eauto. intros [b EQ].
    generalize (H0 r). rewrite EQ. intro LD. inv LD. auto.
  rewrite H1. apply functions_translated; auto.
  rewrite symbols_preserved. destruct (Genv.find_symbol ge i); intros.
  apply funct_ptr_translated; auto.
  discriminate.
Qed.

Consider an execution of a call/move/nop/return sequence in the original code and the corresponding tailcall in the transformed code. The transition sequences are of the following form (left: original code, right: transformed code). f is the calling function and fd the called function.

     State stk f (Icall instruction)       State stk' f' (Itailcall)

     Callstate (frame::stk) fd args        Callstate stk' fd' args'
            .                                       .
            .                                       .
            .                                       .
     Returnstate (frame::stk) res          Returnstate stk' res'

     State stk f (move/nop/return seq)
            .
            .
            .
     State stk f (return instr)

     Returnstate stk res

The simulation invariant must therefore account for two kinds of mismatches between the transition sequences:

The call stack of the original program can contain more frames than that of the transformed program (e.g. frame in the example above).
The regular states corresponding to executing the move/nop/return sequence must all correspond to the single Returnstate stk' res' state of the transformed program.

We first define the simulation invariant between call stacks. The first two cases are standard, but the third case corresponds to a frame that was eliminated by the transformation.

Inductive match_stackframes: list stackframe -> list stackframe -> Prop :=
  | match_stackframes_nil:
      match_stackframes nil nil
  | match_stackframes_normal: forall stk stk' res sp pc rs rs' f,
      match_stackframes stk stk' ->
      regs_lessdef rs rs' ->
      match_stackframes
        (Stackframe res f (Vptr sp Int.zero) pc rs :: stk)
        (Stackframe res (transf_function f) (Vptr sp Int.zero) pc rs' :: stk')
  | match_stackframes_tail: forall stk stk' res sp pc rs f,
      match_stackframes stk stk' ->
      is_return_spec f pc res ->
      f.(fn_stacksize) = 0 ->
      match_stackframes
        (Stackframe res f (Vptr sp Int.zero) pc rs :: stk)
        stk'.

Here is the invariant relating two states. The first three cases are standard. Note the ``less defined than'' conditions over values and register states, and the corresponding ``extends'' relation over memory states.

Inductive match_states: state -> state -> Prop :=
  | match_states_normal:
      forall s sp pc rs m s' rs' m' f
             (STACKS: match_stackframes s s')
             (RLD: regs_lessdef rs rs')
             (MLD: Mem.extends m m'),
      match_states (State s f (Vptr sp Int.zero) pc rs m)
                   (State s' (transf_function f) (Vptr sp Int.zero) pc rs' m')
  | match_states_call:
      forall s f args m s' args' m',
      match_stackframes s s' ->
      Val.lessdef_list args args' ->
      Mem.extends m m' ->
      match_states (Callstate s f args m)
                   (Callstate s' (transf_fundef f) args' m')
  | match_states_return:
      forall s v m s' v' m',
      match_stackframes s s' ->
      Val.lessdef v v' ->
      Mem.extends m m' ->
      match_states (Returnstate s v m)
                   (Returnstate s' v' m')
  | match_states_interm:
      forall s sp pc rs m s' m' f r v'
             (STACKS: match_stackframes s s')
             (MLD: Mem.extends m m'),
      is_return_spec f pc r ->
      f.(fn_stacksize) = 0 ->
      Val.lessdef (rs#r) v' ->
      match_states (State s f (Vptr sp Int.zero) pc rs m)
                   (Returnstate s' v' m').

The last case of match_states corresponds to the execution of a move/nop/return sequence in the original code that was eliminated by the transformation:

     State stk f (move/nop/return seq)  ~~  Returnstate stk' res'
            .
            .
            .
     State stk f (return instr)         ~~  Returnstate stk' res'

To preserve non-terminating behaviors, we need to make sure that the execution of this sequence in the original code cannot diverge. For this, we introduce the following complicated measure over states, which will decrease strictly whenever the original code makes a transition but the transformed code does not.

Definition measure (st: state) : nat :=
  match st with
  | State s f sp pc rs m => (List.length s * (niter + 2) + return_measure f.(fn_code) pc + 1)%nat
  | Callstate s f args m => 0%nat
  | Returnstate s v m => (List.length s * (niter + 2))%nat
  end.

Ltac TransfInstr :=
  match goal with
  | H: (PTree.get _ (fn_code _) = _) |- _ =>
      destruct (transf_instr_lookup _ _ _ H) as [i' [TINSTR TSPEC]]; inv TSPEC
  end.

Ltac EliminatedInstr :=
  match goal with
  | H: (is_return_spec _ _ _) |- _ => inv H; try congruence
  | _ => idtac
  end.

The proof of semantic preservation, then, is a simulation diagram of the ``option'' kind.

Lemma transf_step_correct:
  forall s1 t s2, step ge s1 t s2 ->
  forall s1' (MS: match_states s1 s1'),
  (exists s2', step tge s1' t s2' /\ match_states s2 s2')
  \/ (measure s2 < measure s1 /\ t = E0 /\ match_states s2 s1')%nat.

Proof.

  induction 1; intros; inv MS; EliminatedInstr.

nop *)  TransfInstr. left. econstructor; split.
  eapply exec_Inop; eauto. constructor; auto.
eliminated nop *)  assert (s0 = pc') by congruence. subst s0.
  right. split. simpl. omega. split. auto.
  econstructor; eauto.

op *)  TransfInstr.
  assert (Val.lessdef_list (rs##args) (rs'##args)). apply regs_lessdef_regs; auto.
  exploit eval_operation_lessdef; eauto.
  intros [v' [EVAL' VLD]].
  left. exists (State s' (transf_function f) (Vptr sp0 Int.zero) pc' (rs'#res <- v') m'); split.
  eapply exec_Iop; eauto. rewrite <- EVAL'.
  apply eval_operation_preserved. exact symbols_preserved.
  econstructor; eauto. apply set_reg_lessdef; auto.
eliminated move *)  rewrite H1 in H. clear H1. inv H.
  right. split. simpl. omega. split. auto.
  econstructor; eauto. simpl in H0. rewrite PMap.gss. congruence.

load *)  TransfInstr.
  assert (Val.lessdef_list (rs##args) (rs'##args)). apply regs_lessdef_regs; auto.
  exploit eval_addressing_lessdef; eauto.
  intros [a' [ADDR' ALD]].
  exploit Mem.loadv_extends; eauto.
  intros [v' [LOAD' VLD]].
  left. exists (State s' (transf_function f) (Vptr sp0 Int.zero) pc' (rs'#dst <- v') m'); split.
  eapply exec_Iload with (a := a'). eauto. rewrite <- ADDR'.
  apply eval_addressing_preserved. exact symbols_preserved. eauto.
  econstructor; eauto. apply set_reg_lessdef; auto.

store *)  TransfInstr.
  assert (Val.lessdef_list (rs##args) (rs'##args)). apply regs_lessdef_regs; auto.
  exploit eval_addressing_lessdef; eauto.
  intros [a' [ADDR' ALD]].
  exploit Mem.storev_extends. 2: eexact H1. eauto. eauto. apply RLD.
  intros [m'1 [STORE' MLD']].
  left. exists (State s' (transf_function f) (Vptr sp0 Int.zero) pc' rs' m'1); split.
  eapply exec_Istore with (a := a'). eauto. rewrite <- ADDR'.
  apply eval_addressing_preserved. exact symbols_preserved. eauto.
  destruct a; simpl in H1; try discriminate.
  econstructor; eauto.

call *)  exploit find_function_translated; eauto. intro FIND'.
  TransfInstr.
call turned tailcall *)  assert ({ m'' | Mem.free m' sp0 0 (fn_stacksize (transf_function f)) = Some m''}).
    apply Mem.range_perm_free. rewrite stacksize_preserved. rewrite H7.
    red; intros; omegaContradiction.
  destruct X as [m'' FREE].
  left. exists (Callstate s' (transf_fundef fd) (rs'##args) m''); split.
  eapply exec_Itailcall; eauto. apply sig_preserved.
  constructor. eapply match_stackframes_tail; eauto. apply regs_lessdef_regs; auto.
  eapply Mem.free_right_extends; eauto.
  rewrite stacksize_preserved. rewrite H7. intros. omegaContradiction.
call that remains a call *)  left. exists (Callstate (Stackframe res (transf_function f) (Vptr sp0 Int.zero) pc' rs' :: s')
                          (transf_fundef fd) (rs'##args) m'); split.
  eapply exec_Icall; eauto. apply sig_preserved.
  constructor. constructor; auto. apply regs_lessdef_regs; auto. auto.

tailcall *)  exploit find_function_translated; eauto. intro FIND'.
  exploit Mem.free_parallel_extends; eauto. intros [m'1 [FREE EXT]].
  TransfInstr.
  left. exists (Callstate s' (transf_fundef fd) (rs'##args) m'1); split.
  eapply exec_Itailcall; eauto. apply sig_preserved.
  rewrite stacksize_preserved; auto.
  constructor. auto. apply regs_lessdef_regs; auto. auto.

builtin *)  TransfInstr.
  exploit (@eval_builtin_args_lessdef _ ge (fun r => rs#r) (fun r => rs'#r)); eauto.
  intros (vargs' & P & Q).
  exploit external_call_mem_extends; eauto.
  intros [v' [m'1 [A [B [C D]]]]].
  left. exists (State s' (transf_function f) (Vptr sp0 Int.zero) pc' (regmap_setres res v' rs') m'1); split.
  eapply exec_Ibuiltin; eauto.
  eapply eval_builtin_args_preserved with (ge1 := ge); eauto. exact symbols_preserved.
  eapply external_call_symbols_preserved; eauto.
  exact symbols_preserved. exact public_preserved. exact varinfo_preserved.
  econstructor; eauto. apply set_res_lessdef; auto.

cond *)  TransfInstr.
  left. exists (State s' (transf_function f) (Vptr sp0 Int.zero) (if b then ifso else ifnot) rs' m'); split.
  eapply exec_Icond; eauto.
  apply eval_condition_lessdef with (rs##args) m; auto. apply regs_lessdef_regs; auto.
  constructor; auto.

jumptable *)  TransfInstr.
  left. exists (State s' (transf_function f) (Vptr sp0 Int.zero) pc' rs' m'); split.
  eapply exec_Ijumptable; eauto.
  generalize (RLD arg). rewrite H0. intro. inv H2. auto.
  constructor; auto.

return *)  exploit Mem.free_parallel_extends; eauto. intros [m'1 [FREE EXT]].
  TransfInstr.
  left. exists (Returnstate s' (regmap_optget or Vundef rs') m'1); split.
  apply exec_Ireturn; auto. rewrite stacksize_preserved; auto.
  constructor. auto.
  destruct or; simpl. apply RLD. constructor.
  auto.

eliminated return None *)  assert (or = None) by congruence. subst or.
  right. split. simpl. omega. split. auto.
  constructor. auto.
  simpl. constructor.
  eapply Mem.free_left_extends; eauto.

eliminated return Some *)  assert (or = Some r) by congruence. subst or.
  right. split. simpl. omega. split. auto.
  constructor. auto.
  simpl. auto.
  eapply Mem.free_left_extends; eauto.

internal call *)  exploit Mem.alloc_extends; eauto.
    instantiate (1 := 0). omega.
    instantiate (1 := fn_stacksize f). omega.
  intros [m'1 [ALLOC EXT]].
  assert (fn_stacksize (transf_function f) = fn_stacksize f /\
          fn_entrypoint (transf_function f) = fn_entrypoint f /\
          fn_params (transf_function f) = fn_params f).
    unfold transf_function. destruct (zeq (fn_stacksize f) 0); auto.
  destruct H0 as [EQ1 [EQ2 EQ3]].
  left. econstructor; split.
  simpl. eapply exec_function_internal; eauto. rewrite EQ1; eauto.
  rewrite EQ2. rewrite EQ3. constructor; auto.
  apply regs_lessdef_init_regs. auto.

external call *)  exploit external_call_mem_extends; eauto.
  intros [res' [m2' [A [B [C D]]]]].
  left. exists (Returnstate s' res' m2'); split.
  simpl. econstructor; eauto.
  eapply external_call_symbols_preserved; eauto.
  exact symbols_preserved. exact public_preserved. exact varinfo_preserved.
  constructor; auto.

returnstate *)  inv H2.
synchronous return in both programs *)  left. econstructor; split.
  apply exec_return.
  constructor; auto. apply set_reg_lessdef; auto.
return instr in source program, eliminated because of tailcall *)  right. split. unfold measure. simpl length.
  change (S (length s) * (niter + 2))%nat
   with ((niter + 2) + (length s) * (niter + 2))%nat.
  generalize (return_measure_bounds (fn_code f) pc). omega.
  split. auto.
  econstructor; eauto.
  rewrite Regmap.gss. auto.
Qed.

Lemma transf_initial_states:
forall st1, initial_state prog st1 ->
exists st2, initial_state tprog st2 /\ match_states st1 st2.

Proof.

  intros. inv H.
  exploit funct_ptr_translated; eauto. intro FIND.
  exists (Callstate nil (transf_fundef f) nil m0); split.
  econstructor; eauto. apply Genv.init_mem_transf. auto.
  replace (prog_main tprog) with (prog_main prog).
  rewrite symbols_preserved. eauto.
  reflexivity.
  rewrite <- H3. apply sig_preserved.
  constructor. constructor. constructor. 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 H5. inv H3. constructor.
Qed.

The preservation of the observable behavior of the program then follows.

Theorem transf_program_correct:
forward_simulation (RTL.semantics prog) (RTL.semantics tprog).

Proof.

  eapply forward_simulation_opt with (measure := measure); eauto.
  eexact public_preserved.
  eexact transf_initial_states.
  eexact transf_final_states.
  exact transf_step_correct.
Qed.

End PRESERVATION.

Module Tailcallproof

Syntactic properties of the code transformation

Measuring the number of instructions eliminated

Relational characterization of the code transformation

Semantic properties of the code transformation

The ``less defined than'' relation between register states

Proof of semantic preservation