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TypeInference.v
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TypeInference.v
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(*! Frontend | Type inference and typechecking !*)
Require Import
Koika.Common Koika.Environments
Koika.Syntax Koika.TypedSyntax Koika.SyntaxMacros
Koika.Desugaring Koika.ErrorReporting.
Section ErrorReporting.
Context {pos_t var_t fn_name_t reg_t ext_fn_t: Type}.
Context {R: reg_t -> type}
{Sigma: ext_fn_t -> ExternalSignature}.
Definition lift_basic_error_message
(pos: pos_t) {sig tau} (e: action pos_t var_t R Sigma sig tau)
(err: basic_error_message) : error pos_t var_t fn_name_t :=
{| epos := pos;
emsg := BasicError err;
esource := ErrSrc e |}.
Definition lift_fn1_tc_result
{A sig tau}
pos (e: action pos_t var_t R Sigma sig tau)
(r: result A fn_tc_error)
: result A (error pos_t var_t fn_name_t) :=
result_map_failure (fun '(side, err) => lift_basic_error_message pos e err) r.
Definition lift_fn2_tc_result
{A sig1 tau1 sig2 tau2}
pos1 (e1: action pos_t var_t R Sigma sig1 tau1)
pos2 (e2: action pos_t var_t R Sigma sig2 tau2)
(r: result A fn_tc_error)
: result A (error pos_t var_t fn_name_t) :=
result_map_failure (fun '(side, err) =>
match side with
| Arg1 => lift_basic_error_message pos1 e1 err
| Arg2 => lift_basic_error_message pos2 e2 err
end) r.
End ErrorReporting.
Section TypeInference.
Context {pos_t rule_name_t fn_name_t var_t reg_t ext_fn_t: Type}.
Context {var_t_eq_dec: EqDec var_t}.
Context (R: reg_t -> type).
Context (Sigma: ext_fn_t -> ExternalSignature).
Notation usugar := (usugar pos_t var_t fn_name_t).
Notation uaction := (uaction pos_t var_t fn_name_t).
Notation action := (action pos_t var_t R Sigma).
Notation rule := (rule pos_t var_t R Sigma).
Notation scheduler := (scheduler pos_t rule_name_t).
Section Action.
Notation error := (error pos_t var_t fn_name_t).
Notation error_message := (error_message var_t fn_name_t).
Notation result A := (result A error).
Definition mkerror {T} pos msg (src: T) : error :=
{| epos := pos; emsg := msg; esource := ErrSrc src |}.
Notation "` x" := (projT1 x) (at level 0).
Notation "`` x" := (projT2 x) (at level 0).
Definition cast_action' (pos: pos_t)
{sig tau1} tau2 (e: action sig tau1) (emsg: error_message)
: result (action sig tau2).
Proof.
destruct (eq_dec tau1 tau2); subst.
- exact (Success e).
- exact (Failure (mkerror pos emsg e)).
Defined.
Definition cast_action pos {sig tau1} tau2 (e: action sig tau1) :=
cast_action' pos tau2 e (BasicError (TypeMismatch tau1 tau2)).
Definition cast_rule (pos: pos_t) {tau} (e: action [] tau) :=
cast_action' pos (bits_t 0) e (IncorrectRuleType tau).
Notation EX Px := (existT _ _ Px).
Fixpoint actpos {reg_t ext_fn_t} pos (e: uaction reg_t ext_fn_t) :=
match e with
| UAPos p _ => p
| _ => pos
end.
Fixpoint assert_argtypes' {T} {sig} (src: T) nexpected (fn_name: fn_name_t) pos
(args_desc: tsig var_t)
(args: list (pos_t * {tau : type & action sig tau}))
: result (context (K := (var_t * type)) (fun '(_, tau) => action sig tau) args_desc) :=
match args_desc, args with
| [], [] => Success CtxEmpty
| [], _ => Failure (mkerror pos (TooManyArguments fn_name nexpected (List.length args)) src)
| _, [] => Failure (mkerror pos (TooFewArguments fn_name nexpected (List.length args_desc)) src)
| (name1, tau1) :: fn_sig, (pos1, arg1) :: args =>
let/res arg1 := cast_action pos1 tau1 ``arg1 in
let/res ctx := assert_argtypes' src nexpected fn_name pos fn_sig args in
Success (CtxCons (name1, tau1) arg1 ctx)
end.
Definition assert_argtypes {T} {sig}
(src: T)
(fn_name: fn_name_t) pos
(args_desc: tsig var_t)
(args: list (pos_t * {tau : type & action sig tau}))
: result (context (K := (var_t * type)) (fun '(_, tau) => action sig tau) args_desc) :=
assert_argtypes' src (List.length args_desc) fn_name pos args_desc args.
Fixpoint type_action
(pos: pos_t) (sig: tsig var_t)
(e: uaction reg_t ext_fn_t) {struct e}
: result ({ tau: type & action sig tau }) :=
match e with
| UError err => Failure err
| USugar _ => Failure (mkerror pos SugaredConstructorInAst e)
| UFail tau => Success (EX (Fail tau))
| UVar var =>
let/res tau_m := opt_result (assoc var sig) (mkerror pos (UnboundVariable var) e) in
Success (EX (Var ``tau_m))
| UConst cst => Success (EX (Const cst))
| UAssign var ex =>
let/res tau_m := opt_result (assoc var sig) (mkerror pos (UnboundVariable var) e) in
let/res ex' := type_action pos sig ex in
let/res ex' := cast_action (actpos pos ex) `tau_m (``ex') in
Success (EX (Assign (k := var) (tau := `tau_m) ``tau_m ex'))
| USeq r1 r2 =>
let/res r1' := type_action pos sig r1 in
let/res r1' := cast_action (actpos pos r1) unit_t (``r1') in
let/res r2' := type_action pos sig r2 in
Success (EX (Seq r1' ``r2'))
| UBind v ex body =>
let/res ex := type_action pos sig ex in
let/res body := type_action pos ((v, `ex) :: sig) body in
Success (EX (Bind v ``ex ``body))
| UIf cond tbranch fbranch =>
let/res cond' := type_action pos sig cond in
let/res cond' := cast_action (actpos pos cond) (bits_t 1) (``cond') in
let/res tbranch' := type_action pos sig tbranch in
let/res fbranch' := type_action pos sig fbranch in
let/res fbranch' := cast_action (actpos pos fbranch) (`tbranch') (``fbranch') in
Success (EX (If cond' ``tbranch' fbranch'))
| URead port idx => Success (EX (Read port idx))
| UWrite port idx value =>
let/res value' := type_action pos sig value in
let/res value' := cast_action (actpos pos value) (R idx) (``value') in
Success (EX (Write port idx value'))
| UInternalCall fn args =>
let/res tc_args := result_list_map (type_action pos sig) args in
let arg_positions := List.map (actpos pos) args in
let tc_args_w_pos := List.combine arg_positions tc_args in
let/res arg_ctx := assert_argtypes e fn.(int_name) pos fn.(int_argspec) tc_args_w_pos in
let/res fn_body' := type_action (actpos pos fn.(int_body)) fn.(int_argspec) fn.(int_body) in
let/res fn_body' := cast_action (actpos pos fn.(int_body)) fn.(int_retSig) (``fn_body') in
Success (EX (InternalCall sig fn.(int_argspec) fn_body' arg_ctx))
| UUnop fn arg1 =>
let pos1 := actpos pos arg1 in
let/res arg1' := type_action pos sig arg1 in
let/res fn := lift_fn1_tc_result pos1 ``arg1' (PrimTypeInference.tc1 fn `arg1') in
let/res arg1' := cast_action pos1 (PrimSignatures.Sigma1 fn).(arg1Sig) (``arg1') in
Success (EX (Unop fn arg1'))
| UBinop fn arg1 arg2 =>
let pos1 := actpos pos arg1 in
let pos2 := actpos pos arg2 in
let/res arg1' := type_action pos sig arg1 in
let/res arg2' := type_action pos sig arg2 in
let/res fn := lift_fn2_tc_result pos1 ``arg1' pos2 ``arg2' (PrimTypeInference.tc2 fn `arg1' `arg2') in
let/res arg1' := cast_action pos1 (PrimSignatures.Sigma2 fn).(arg1Sig) (``arg1') in
let/res arg2' := cast_action pos2 (PrimSignatures.Sigma2 fn).(arg2Sig) (``arg2') in
Success (EX (Binop fn arg1' arg2'))
| UExternalCall fn arg1 =>
let pos1 := actpos pos arg1 in
let/res arg1' := type_action pos1 sig arg1 in
let/res arg1' := cast_action pos1 (Sigma fn).(arg1Sig) (``arg1') in
Success (EX (ExternalCall fn arg1'))
| UAPos pos e =>
let/res e := type_action pos sig e in
Success (EX (APos pos ``e))
end.
Definition type_rule (pos: pos_t) (e: uaction reg_t ext_fn_t) : result rule :=
let/res rl := type_action pos [] e in
cast_rule pos (``rl).
End Action.
End TypeInference.