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LoweringCorrectness.v
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LoweringCorrectness.v
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(*! Circuits | Proof of correctness for the lowering phase !*)
Require Import Coq.setoid_ring.Ring_theory Coq.setoid_ring.Ring Coq.setoid_ring.Ring.
Require Import Koika.Common Koika.Environments Koika.Syntax
Koika.SemanticProperties Koika.PrimitiveProperties Koika.SyntaxMacros Koika.Lowering.
Require Koika.TypedSemantics Koika.LoweredSemantics.
Section LoweringCorrectness.
Context {pos_t var_t fn_name_t rule_name_t reg_t ext_fn_t: Type}.
Context {R: reg_t -> type}.
Context {Sigma: ext_fn_t -> ExternalSignature}.
Notation CR := (lower_R R).
Notation CSigma := (lower_Sigma Sigma).
Context {REnv: Env reg_t}.
Context (r: REnv.(env_t) R).
Context (sigma: forall f, Sig_denote (Sigma f)).
Notation lr := (lower_r r).
Notation lsigma := (lower_sigma sigma).
Lemma lower_r_eqn:
forall idx, getenv REnv lr idx = bits_of_value (getenv REnv r idx).
Proof.
unfold lower_r; intros; rewrite getenv_map; reflexivity.
Qed.
Lemma lower_sigma_eqn:
forall (fn : ext_fn_t) (v : arg1Sig (Sigma fn)),
lsigma fn (bits_of_value v) = bits_of_value (sigma fn v).
Proof.
unfold lsigma; intros; rewrite value_of_bits_of_value; reflexivity.
Qed.
Notation taction := (TypedSyntax.action pos_t var_t fn_name_t R Sigma).
Notation laction := (LoweredSyntax.action pos_t var_t CR CSigma).
Notation tinterp := (TypedSemantics.interp_action r sigma).
Notation linterp := (LoweredSemantics.interp_action lr lsigma).
Notation tcontext := TypedSemantics.tcontext.
Notation lcontext := LoweredSemantics.lcontext.
Notation tlog := (Logs.Log R REnv).
Notation llog := (Logs.CLog CR REnv).
Context {var_t_eq_dec: EqDec var_t}.
Ltac lower_op_t :=
match goal with
| _ => progress intros
| _ => progress simpl in *
| _ => progress unfold Bits.extend_beginning, Bits.extend_end,
struct_sz, field_sz, array_sz, element_sz
| _ => rewrite bits_of_value_of_bits
| [ H: linterp _ _ _ _ = _ |- _ ] => rewrite H
| [ |- context[match ?d with _ => _ end] ] => is_var d; destruct d
| [ |- context[eq_rect _ _ _ _ ?pr] ] => destruct pr
| [ |- Some (_, _, _) = Some (_, _, _) ] => repeat f_equal
| [ |- Some _ = Some _ ] => f_equal
| _ => (apply _eq_of_value ||
apply _neq_of_value ||
apply get_field_bits_slice ||
apply subst_field_bits_slice_subst ||
apply get_element_bits_slice ||
apply subst_element_bits_slice_subst)
| _ => rewrite sel_msb, vect_repeat_single_const
| _ => solve [eauto]
end.
Ltac lower_op_correct_t :=
repeat match goal with
| _ => progress intros
| [ |- context[match linterp _ _ _ ?a with _ => _ end] ] =>
let v := fresh "v" in
let Heq := fresh "Heq" in
destruct (linterp _ _ _ a) as [((?, v), ?) | ] eqn:Heq; cbn;
[ rewrite <- (bits_of_value_of_bits _ v) in Heq;
remember (value_of_bits v) in *; clear dependent v | ]
| [ fn: PrimTyped.fn1 |- _ ] => destruct fn; repeat lower_op_t
| [ fn: PrimTyped.fn2 |- _ ] => destruct fn; repeat lower_op_t
end.
Theorem lower_unop_correct {sig lGamma lL ll}:
forall fn (a: laction sig _),
linterp lGamma lL ll (lower_unop fn a) =
match linterp lGamma lL ll a with
| Some (ll', bs, lGamma') =>
let v := value_of_bits bs in
Some (ll', bits_of_value (PrimSpecs.sigma1 fn v), lGamma')
| None => None
end.
Proof.
lower_op_correct_t.
Qed.
Theorem lower_binop_correct {sig lGamma lL ll}:
forall fn (a1 a2: laction sig _),
linterp lGamma lL ll (lower_binop fn a1 a2) =
match linterp lGamma lL ll a1 with
| Some (ll1, v1, lGamma1) =>
match linterp lGamma1 lL ll1 a2 with
| Some (ll2, v2, lGamma2) =>
let v1 := value_of_bits v1 in
let v2 := value_of_bits v2 in
Some (ll2, bits_of_value (PrimSpecs.sigma2 fn v1 v2), lGamma2)
| None => None
end
| None => None
end.
Proof.
lower_op_correct_t.
Qed.
Definition lower_context {sig}
(tGamma: tcontext sig) :=
cmap (V := fun k_tau => type_denote (snd k_tau))
(V' := Bits.bits)
(fun k_tau => type_sz (@snd var_t type k_tau))
(fun _ v => bits_of_value v)
tGamma.
Arguments lower_context : simpl never.
Definition context_equiv {sig}
(tGamma: tcontext sig)
(lGamma: lcontext (lsig_of_tsig sig)) :=
lGamma = lower_context tGamma.
Lemma context_equiv_cassoc {sig: tsig var_t} :
forall (tGamma: tcontext sig) {k tau} (m: member (k, tau) sig),
cassoc (lower_member m) (lower_context tGamma) =
bits_of_value (cassoc m tGamma).
Proof.
intros; rewrite <- (cmap_cassoc _ (fun _ v => bits_of_value v) _ m); reflexivity.
Qed.
Lemma context_equiv_creplace:
forall {sig: tsig var_t} {k: var_t} {tau: type}
(m: member (k, tau) sig) (v: tau)
(tGamma: tcontext sig),
context_equiv
(creplace m v tGamma)
(creplace (lower_member m) (bits_of_value v) (lower_context tGamma)).
Proof.
unfold context_equiv, lower_member, lower_context; intros.
rewrite cmap_creplace; reflexivity.
Qed.
Lemma context_equiv_CtxCons:
forall (sig: tsig var_t) (tau: type) (k: var_t) (v: tau) (tGamma: tcontext sig),
context_equiv (CtxCons (k, tau) v tGamma)
(CtxCons (type_sz tau) (bits_of_value v) (lower_context tGamma)).
Proof. reflexivity. Qed.
Lemma context_equiv_ctl:
forall (sig: tsig var_t) (tau: type) (k: var_t)
(tGamma: tcontext ((k, tau) :: sig)),
context_equiv (ctl tGamma) (ctl (lower_context tGamma)).
Proof.
unfold context_equiv, lower_context; intros; rewrite cmap_ctl; reflexivity.
Qed.
Definition lower_log (tL: tlog) : llog :=
log_map_values (fun idx => bits_of_value) tL.
Arguments lower_log : simpl never.
Definition log_equiv (tL: tlog) (lL: llog) : Prop :=
lL = lower_log tL.
Lemma log_equiv_empty:
log_equiv log_empty log_empty.
Proof.
unfold log_equiv; symmetry; apply log_map_values_empty.
Qed.
Lemma log_equiv_cons:
forall (tL: tlog) idx tle,
log_equiv (log_cons idx tle tL)
(log_cons idx (LogEntry_map bits_of_value tle) (lower_log tL)).
Proof.
intros; red; unfold lower_log; rewrite log_map_values_cons; reflexivity.
Qed.
Lemma log_equiv_app:
forall (tL tl: tlog),
log_equiv (log_app tL tl)
(log_app (lower_log tL) (lower_log tl)).
Proof.
unfold log_equiv, lower_log; intros.
rewrite <- log_map_values_log_app; reflexivity.
Qed.
Lemma log_equiv_may_read:
forall (tL: tlog) (port: Port) (idx: reg_t),
Logs.may_read tL port idx =
Logs.may_read (lower_log tL) port idx.
Proof. intros; symmetry; apply may_read_log_map_values. Qed.
Lemma log_equiv_may_write:
forall (tL tl: tlog) (port: Port) (idx: reg_t),
Logs.may_write tL tl port idx =
Logs.may_write (lower_log tL) (lower_log tl) port idx.
Proof. intros; symmetry; apply may_write_log_map_values. Qed.
Lemma log_equiv_latest_write0:
forall (tl: tlog) idx,
latest_write0 (lower_log tl) idx =
match latest_write0 tl idx with
| Some v => Some (bits_of_value v)
| None => None
end.
Proof.
intros; unfold lower_log; rewrite latest_write0_log_map_values; reflexivity.
Qed.
Definition lower_result {sig tau} (r: option (tlog * type_denote tau * tcontext sig))
: option (llog * bits (type_sz tau) * lcontext (lsig_of_tsig sig)) :=
match r with
| None => None
| Some (tl, tv, tGamma) =>
Some (lower_log tl, bits_of_value tv, lower_context tGamma)
end.
Definition lower_results {sig argspec} (r: option (tlog * tcontext argspec * tcontext sig))
: option (llog * lcontext _ * lcontext (lsig_of_tsig sig)) :=
match r with
| None => None
| Some (tl, tvs, tGamma) =>
Some (lower_log tl,
cmap (fun (k_tau: var_t * type) => type_sz (snd k_tau))
(fun k v => bits_of_value v)
tvs,
lower_context tGamma)
end.
Definition lacontext (sig arg_sigs: lsig) :=
context (fun sz => laction sig sz) arg_sigs.
Fixpoint linterp_args
{sig: lsig}
(Gamma: lcontext sig)
(sched_log: llog)
(action_log: llog)
{arg_sigs: lsig}
(args: context (fun sz => var_t * laction sig sz)%type arg_sigs)
: option (llog * lcontext arg_sigs * (lcontext sig)) :=
match args with
| CtxEmpty => Some (action_log, CtxEmpty, Gamma)
| @CtxCons _ _ arg_sigs k_tau (k, arg) args =>
let/opt3 action_log, ctx, Gamma := linterp_args Gamma sched_log action_log args in
let/opt3 action_log, v, Gamma := linterp Gamma sched_log action_log arg in
Some (action_log, CtxCons _ v ctx, Gamma)
end.
Lemma interp_infixed':
forall {sg: lsig} {sz: nat} (a: laction sg sz) {sig sig'} (Heq: sg = sig ++ sig')
{infix: lsig} (gamma: lcontext infix) (Gamma : lcontext sg)
(L l: llog),
linterp (infix_context gamma (rew Heq in Gamma)) L l
(infix_action infix (rew [fun sg => laction sg sz] Heq in a)) =
match linterp Gamma L l a with
| Some (l, v, Gamma) => Some (l, v, infix_context gamma (rew Heq in Gamma))
| None => None
end.
Proof.
Arguments infix_context : simpl never.
induction a;
repeat match goal with
| _ => reflexivity
| _ => progress intros
| _ => progress subst
| _ => progress cbn
| _ => progress change (CtxCons ?sz ?v (infix_context ?gamma ?Gamma)) with
(infix_context (sig := sz :: _) gamma (CtxCons sz v Gamma))
| [ H: forall _ _ (Heq: _ = _), _ |- _ ] =>
change (?x :: ?a ++ ?b) with ((x :: a) ++ b) in H;
specialize (H _ _ eq_refl); cbn in H
| [ H: context[_ = _] |- _ ] => rewrite H
| [ |- context[if ?x then _ else _] ] => destruct x
| _ => destruct linterp as [((?, ?), ?) | ]; [ | reflexivity ]
| _ => rewrite ?cassoc_minfix, ?creplace_minfix
end.
Qed.
Lemma interp_infixed:
forall {sig sig': lsig} {sz: nat} (a: laction (sig ++ sig') sz)
{infix: lsig} (gamma: lcontext infix) (Gamma : lcontext (sig ++ sig'))
(L l: llog),
linterp (infix_context gamma Gamma) L l (infix_action infix a) =
match linterp Gamma L l a with
| Some (l, v, Gamma) => Some (l, v, infix_context gamma Gamma)
| None => None
end.
Proof. intros; apply (interp_infixed' a eq_refl). Qed.
Lemma interp_prefixed:
forall {sig: lsig} {sz: nat} (a: laction sig sz)
{prefix: lsig} (gamma: lcontext prefix) (Gamma : lcontext sig)
(L l: llog),
linterp (capp gamma Gamma) L l (prefix_action prefix a) =
match linterp Gamma L l a with
| Some (l, v, Gamma) => Some (l, v, capp gamma Gamma)
| None => None
end.
Proof. intros; apply (@interp_infixed []). Qed.
Lemma linterp_cast:
forall {sg: lsig} {sz: nat} f (a: laction (f sg) sz) {sg'} (Heq: sg = sg')
(Gamma : lcontext (f sg)) (L l: llog),
linterp (rew [fun sg => lcontext (f sg)] Heq in Gamma) L l
(rew [fun sg => laction (f sg) sz] Heq in a) =
rew [fun sg => option (llog * bits sz * lcontext (f sg))] Heq in
(linterp Gamma L l a).
Proof. destruct Heq; cbn; reflexivity. Qed.
Lemma interp_suffixed:
forall {sig: lsig} {sz: nat} (a: laction sig sz)
{suffix: lsig} (gamma: lcontext suffix) (Gamma : lcontext sig)
(L l: llog),
linterp (capp Gamma gamma) L l (suffix_action suffix a) =
match linterp Gamma L l a with
| Some (l, v, Gamma) => Some (l, v, capp Gamma gamma)
| None => None
end.
Proof. unfold suffix_action; intros.
rewrite capp_as_infix.
rewrite linterp_cast.
unfold eq_rect_r; rewrite interp_infixed'.
destruct linterp as [((?, ?), ?) | ]; cbn.
- rewrite capp_as_infix.
destruct (capp_nil_r suffix); cbn.
reflexivity.
- destruct capp_nil_r; reflexivity.
Qed.
Theorem InternalCall'_linterp_args :
forall {sig sz argspec} (args: context (fun sz => var_t * laction sig sz)%type argspec)
Gamma L l (body: laction (argspec ++ sig) sz),
linterp Gamma L l (InternalCall' args body) =
(let/opt3 l', results, Gamma' := linterp_args Gamma L l args in
let/opt3 l'', v, Gamma'' := linterp (capp results Gamma') L l' body in
Some (l'', v, snd (csplit Gamma''))).
Proof.
induction args as [ | sig' sz' (var, arg) tl IH ]; cbn; intros.
- destruct linterp as [((?, ?), ?) | ]; reflexivity.
- rewrite IH; cbn.
destruct linterp_args as [((?, ?), ?) | ]; cbn; try reflexivity.
rewrite interp_prefixed.
repeat (destruct linterp as [((?, ?), ?) | ]; cbn; try reflexivity).
Qed.
Section Args.
Context (IH: forall sig tau (v: taction sig tau) (Gamma: tcontext sig) tL tl,
linterp (lower_context Gamma) (lower_log tL) (lower_log tl) (lower_action v) =
lower_result (tinterp Gamma tL tl v)).
Lemma linterp_args_correct:
forall {sig argspec} (args : context (fun k_tau : var_t * type => taction sig (snd k_tau)) argspec)
(tGamma: tcontext sig) tL tl,
linterp_args (lower_context tGamma) (lower_log tL) (lower_log tl) (lower_args args) =
lower_results (interp_args r sigma tGamma tL tl args).
Proof.
induction args; cbn; intros.
- reflexivity.
- rewrite IHargs by eauto.
destruct (interp_args _ _ _ _ _ _) as [((?, ?), ?) | ]; cbn; try reflexivity.
rewrite IH; destruct tinterp as [((?, ?), ?) | ]; reflexivity.
Defined.
Lemma InternalCall_correct:
forall {sig argspec} (args : context (fun k_tau : var_t * type => taction sig (snd k_tau)) argspec)
{tau} (ta: taction argspec tau) (tGamma : tcontext sig) tL tl,
linterp (lower_context tGamma) (lower_log tL) (lower_log tl)
(InternalCall (lower_args args) (lower_action ta)) =
lower_result
(let/opt3 action_log, results, Gamma := interp_args r sigma tGamma tL tl args in
let/opt3 action_log0, v, _ := tinterp results tL action_log ta in
Some (action_log0, v, Gamma)).
Proof.
unfold InternalCall; intros.
rewrite InternalCall'_linterp_args.
rewrite linterp_args_correct by auto.
destruct (interp_args r sigma tGamma tL tl args) as [((?, ?), ?) | ]; cbn; try reflexivity.
rewrite interp_suffixed.
rewrite IH.
destruct tinterp as [((?, ?), ?) | ]; cbn.
- rewrite csplit_capp; reflexivity.
- reflexivity.
Defined.
End Args.
Create HintDb lowering.
Hint Rewrite @context_equiv_cassoc : lowering.
Hint Rewrite @context_equiv_creplace : lowering.
Hint Rewrite @context_equiv_CtxCons : lowering.
Hint Rewrite @context_equiv_ctl : lowering.
Hint Rewrite <- @log_equiv_cons : lowering.
Hint Rewrite @lower_unop_correct : lowering.
Hint Rewrite @lower_binop_correct : lowering.
Hint Rewrite @value_of_bits_of_value : lowering.
Hint Rewrite @lower_r_eqn : lowering.
Hint Rewrite @lower_sigma_eqn : lowering.
Hint Rewrite @log_equiv_may_read : lowering.
Hint Rewrite @log_equiv_may_write : lowering.
Hint Rewrite @log_equiv_latest_write0 : lowering.
Hint Rewrite @latest_write0_app : lowering.
Hint Rewrite @csplit_capp : lowering.
Hint Rewrite @InternalCall_correct : lowering.
Ltac destruct_res r :=
destruct r as [((?, ?), ?) | ] eqn:?; cbn.
Ltac lowering_correct_t_step :=
match goal with
| _ => cleanup_step
| _ => progress (subst; unfold opt_bind)
| _ => progress autorewrite with lowering
| [ H: context[linterp _ _ _ _ = _] |-
context[linterp (lower_context ?G) (lower_log ?L) (lower_log ?l) (lower_action ?ta)] ] =>
setoid_rewrite (H _ _ ta G L l)
| [ |- context[linterp (CtxCons _ _ _) _ _ _] ] => setoid_rewrite context_equiv_CtxCons
| [ |- context[ctl (lower_context _)] ] => setoid_rewrite context_equiv_ctl
| [ |- context[tinterp] ] => destruct tinterp as [((?, ?), ?) | ]
| [ |- context[latest_write0] ] => destruct latest_write0
| [ |- context[if ?x then _ else _] ] => destruct x
| _ => eauto using InternalCall_correct
end.
Ltac lowering_correct_t :=
repeat lowering_correct_t_step.
Theorem action_lowering_correct:
forall {sig tau} (ta: taction sig tau) tGamma tL tl,
linterp (lower_context tGamma) (lower_log tL) (lower_log tl) (lower_action ta) =
lower_result (tinterp tGamma tL tl ta).
Proof.
fix IHta 3; destruct ta; simpl; intros; cbn.
- lowering_correct_t.
- lowering_correct_t.
- lowering_correct_t.
- lowering_correct_t.
- lowering_correct_t.
- lowering_correct_t.
- lowering_correct_t.
- lowering_correct_t.
- lowering_correct_t.
- lowering_correct_t.
- lowering_correct_t.
- lowering_correct_t.
- lowering_correct_t.
- lowering_correct_t.
Qed.
Context (rules: rule_name_t -> TypedSyntax.rule pos_t var_t fn_name_t R Sigma).
Notation lrules r := (lower_action (rules r)).
Lemma scheduler_lowering_correct':
forall s L,
LoweredSemantics.interp_scheduler' lr lsigma (fun r => lrules r) (lower_log L) s =
lower_log (TypedSemantics.interp_scheduler' r sigma rules L s).
Proof.
induction s; intros; cbn;
unfold TypedSemantics.interp_rule, LoweredSemantics.interp_rule.
- reflexivity.
- rewrite log_equiv_empty.
setoid_rewrite (action_lowering_correct (rules r0) CtxEmpty L log_empty).
destruct tinterp as [((?, ?), ?) | ]; cbn;
try rewrite log_equiv_app; eauto.
- rewrite log_equiv_empty.
setoid_rewrite (action_lowering_correct (rules r0) CtxEmpty L log_empty).
destruct tinterp as [((?, ?), ?) | ]; cbn;
try rewrite log_equiv_app; eauto.
- eauto.
Qed.
Theorem scheduler_lowering_correct:
forall s,
LoweredSemantics.interp_scheduler lr lsigma (fun r => lrules r) s =
lower_log (TypedSemantics.interp_scheduler r sigma rules s).
Proof.
unfold TypedSemantics.interp_scheduler; intros.
rewrite <- scheduler_lowering_correct', <- log_equiv_empty; reflexivity.
Qed.
Theorem cycle_lowering_correct:
forall s,
LoweredSemantics.interp_cycle lsigma (fun r => lrules r) s lr =
lower_r (TypedSemantics.interp_cycle sigma rules s r).
Proof.
unfold TypedSemantics.interp_cycle, LoweredSemantics.interp_cycle; intros.
rewrite scheduler_lowering_correct.
unfold lower_r, lower_log;
rewrite SemanticProperties.commit_update_log_map_values;
reflexivity.
Qed.
End LoweringCorrectness.