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-rw-r--r--src/InterpreterStatements.ml19
-rw-r--r--src/PrintPure.ml21
-rw-r--r--src/Pure.ml6
-rw-r--r--src/SymbolicAst.ml20
-rw-r--r--src/SymbolicToPure.ml20
5 files changed, 69 insertions, 17 deletions
diff --git a/src/InterpreterStatements.ml b/src/InterpreterStatements.ml
index e31a2152..09f13240 100644
--- a/src/InterpreterStatements.ml
+++ b/src/InterpreterStatements.ml
@@ -730,11 +730,22 @@ let rec eval_statement (config : C.config) (st : A.statement) : st_cm_fun =
let cf_assign cf (res : (V.typed_value, eval_error) result) ctx =
match res with
| Error EPanic -> cf Panic ctx
- | Ok rvalue ->
- let expr = assign_to_place config rvalue p (cf Unit) ctx in
- (* Update the synthesized AST - here we store meta-information *)
- S.synthesize_assignment (S.mk_mplace p ctx) rvalue expr
+ | Ok rv -> (
+ let expr = assign_to_place config rv p (cf Unit) ctx in
+ (* Update the synthesized AST - here we store meta-information.
+ * We do it only in specific cases (it is not always useful, and
+ * also it can lead to issues - for instance, if we borrow an
+ * inactivated borrow, we later can't translate it to pure values...) *)
+ match rvalue with
+ | E.Use _
+ | E.Ref (_, (E.Shared | E.Mut))
+ | E.UnaryOp _ | E.BinaryOp _ | E.Discriminant _ | E.Aggregate _ ->
+ S.synthesize_assignment (S.mk_mplace p ctx) rv expr
+ | E.Ref (_, E.TwoPhaseMut) ->
+ (* Two-phase borrow: don't synthesize meta-information *)
+ expr)
in
+
(* Compose and apply *)
comp cf_eval_rvalue cf_assign cf ctx
| A.FakeRead p ->
diff --git a/src/PrintPure.ml b/src/PrintPure.ml
index 6f56c379..5223fb21 100644
--- a/src/PrintPure.ml
+++ b/src/PrintPure.ml
@@ -333,6 +333,23 @@ let fun_id_to_string (fmt : ast_formatter) (fun_id : fun_id) : string =
| Binop (binop, int_ty) ->
binop_to_string binop ^ "<" ^ integer_type_to_string int_ty ^ ">"
+let mplace_to_string (fmt : ast_formatter) (p : mplace) : string =
+ let name = match p.name with None -> "_" | Some name -> name in
+ projection_to_string fmt name p.projection
+
+let meta_to_string (fmt : ast_formatter) (meta : meta) : string =
+ let meta =
+ match meta with
+ | Aggregate (p, rv) ->
+ let p = match p with None -> "_" | Some p -> mplace_to_string fmt p in
+ "@aggregate(" ^ p ^ " := " ^ typed_rvalue_to_string fmt rv ^ ")"
+ | Assignment (p, rv) ->
+ "@assign(" ^ mplace_to_string fmt p ^ " := "
+ ^ typed_rvalue_to_string fmt rv
+ ^ ")"
+ in
+ "@meta[" ^ meta ^ "]"
+
let rec expression_to_string (fmt : ast_formatter) (indent : string)
(indent_incr : string) (e : expression) : string =
match e with
@@ -341,6 +358,10 @@ let rec expression_to_string (fmt : ast_formatter) (indent : string)
| Let (lb, e) -> let_to_string fmt indent indent_incr lb e
| Switch (scrutinee, _, body) ->
switch_to_string fmt indent indent_incr scrutinee body
+ | Meta (meta, e) ->
+ let meta = meta_to_string fmt meta in
+ let e = expression_to_string fmt indent indent_incr e in
+ indent ^ meta ^ "\n" ^ e
and let_to_string (fmt : ast_formatter) (indent : string) (indent_incr : string)
(lb : let_bindings) (e : expression) : string =
diff --git a/src/Pure.ml b/src/Pure.ml
index ba0c9837..89748bdd 100644
--- a/src/Pure.ml
+++ b/src/Pure.ml
@@ -200,6 +200,11 @@ type let_bindings =
code if we detect there is exactly one variant?...
*)
+(** Meta-information stored in the AST *)
+type meta =
+ | Aggregate of mplace option * typed_rvalue
+ | Assignment of mplace * typed_rvalue
+
(** **Rk.:** here, [expression] is not at all equivalent to the expressions
used in CFIM. They are lambda-calculus expressions, and are thus actually
more general than the CFIM statements, in a sense.
@@ -215,6 +220,7 @@ type expression =
| Let of let_bindings * expression
(** Let bindings include the let-bindings introduced because of function calls *)
| Switch of typed_rvalue * mplace option * switch_body
+ | Meta of meta * expression (** Meta-information *)
and switch_body =
| If of expression * expression
diff --git a/src/SymbolicAst.ml b/src/SymbolicAst.ml
index 3148f833..07afd914 100644
--- a/src/SymbolicAst.ml
+++ b/src/SymbolicAst.ml
@@ -45,6 +45,16 @@ type call = {
dest_place : mplace option; (** Meta information *)
}
+(** Meta information, not necessary for synthesis but useful to guide it to
+ generate a pretty output.
+ *)
+
+type meta =
+ | Aggregate of mplace option * V.typed_value
+ (** We generated an aggregate value *)
+ | Assignment of mplace * V.typed_value
+ (** We generated an assignment (destination, assigned value) *)
+
(** **Rk.:** here, [expression] is not at all equivalent to the expressions
used in CFIM: they are a first step towards lambda-calculus expressions.
*)
@@ -87,13 +97,3 @@ and expansion =
T.integer_type * (V.scalar_value * expression) list * expression
(** An integer expansion (i.e, a switch over an integer). The last
expression is for the "otherwise" branch. *)
-
-(** Meta information, not necessary for synthesis but useful to guide it to
- generate a pretty output.
- *)
-
-and meta =
- | Aggregate of mplace option * V.typed_value
- (** We generated an aggregate value *)
- | Assignment of mplace * V.typed_value
- (** We generated an assignment (destination, assigned value) *)
diff --git a/src/SymbolicToPure.ml b/src/SymbolicToPure.ml
index 63d0df1d..4fa8e54c 100644
--- a/src/SymbolicToPure.ml
+++ b/src/SymbolicToPure.ml
@@ -879,9 +879,7 @@ let rec translate_expression (e : S.expression) (ctx : bs_ctx) : expression =
| FunCall (call, e) -> translate_function_call call e ctx
| EndAbstraction (abs, e) -> translate_end_abstraction abs e ctx
| Expansion (p, sv, exp) -> translate_expansion p sv exp ctx
- | Meta (_, e) ->
- (* We ignore the meta information *)
- translate_expression e ctx
+ | Meta (meta, e) -> translate_meta meta e ctx
and translate_return (opt_v : V.typed_value option) (ctx : bs_ctx) : expression
=
@@ -1243,6 +1241,22 @@ and translate_expansion (p : S.mplace option) (sv : V.symbolic_value)
Switch
(scrutinee, scrutinee_mplace, SwitchInt (int_ty, branches, otherwise))
+and translate_meta (meta : S.meta) (e : S.expression) (ctx : bs_ctx) :
+ expression =
+ let e = translate_expression e ctx in
+ let meta =
+ match meta with
+ | S.Aggregate (p, rv) ->
+ let p = translate_opt_mplace p in
+ let rv = typed_value_to_rvalue ctx rv in
+ Aggregate (p, rv)
+ | S.Assignment (p, rv) ->
+ let p = translate_mplace p in
+ let rv = typed_value_to_rvalue ctx rv in
+ Assignment (p, rv)
+ in
+ Meta (meta, e)
+
let translate_fun_def (ctx : bs_ctx) (body : S.expression) : fun_def =
let def = ctx.fun_def in
let bid = ctx.bid in