3 files changed, 32 insertions, 10 deletions

diff --git a/src/lem_interp/interp.lem b/src/lem_interp/interp.lem
index ef0dbc00..5556a61b 100644
--- a/src/lem_interp/interp.lem
+++ b/src/lem_interp/interp.lem
@@ -97,20 +97,39 @@ type env = list (id * value)
 
 let emem = LMem 1 Map.empty
 
-(* These may need to be refined or expanded based on memory requirement *)
+type read_kind = Read_plain | Read_reserve | Read_acquire
+type write_kind = Write_plain | Write_conditional | Write_release
+
+(*type outcome =  (* these should be related to the Sail effect language, obviously...*)
+  | Read_mem of read_kind * value (*the address*) * (value -> instruction_state)      (* the continuation parameterised just on a value or on a write? *)
+  | Write_mem of write_kind * value (*the address*) * value (*the value*) * (bool (*ss wcond success*) -> instruction state)    
+  | Barrier of barrier_kind * instruction_state
+  | Read_reg of reg_name * (value -> instruction_state)
+  | Write_reg of reg_name * value * instruction_state
+  | Write_next_instruction_address of value * instruction_state  (* separate out NIA and _PC from the real Write_reg? *)
+  | Internal of instruction_state   (* normally we'll want the system to eagerly do these, either within the interpreter or outside.  But not always: sometimes we'll want to single-step through them - or at the block-level or somesuch *)
+  | Nondet_choice of list instruction_state    (* for (1) explicit nondet choices of single bits in the ISA, (2) interpreting conditionals that hit a "don't know" value in register/memory footprint calculation, and perhaps (3) interpreting intra-instruction parallelism, eg for load-multiple *)
+  | Done
+  | Error of ...   (* for internal errors that should all be prevented by Sail typechecking and careful writing of the ISA semantics *)
+  | Undefined_instruction of ...   (* for dynamically detected occurrences of UNPREDICTABLE *)
+*)
+
 type action = 
  | Read_reg of reg_form * maybe (integer * integer)
  | Write_reg of reg_form * maybe (integer* integer) * value
  | Read_mem of id * value * maybe (integer * integer)
  | Write_mem of id * value * maybe (integer * integer) * value
+ | Barrier of id * value
+ | Write_next_IA of value
+ | Nondet of list (exp tannot)
+ | Debug of l
  | Call_extern of string * value
 
-(* Inverted call stack, where top item on the stack is waiting for an action and all other frames for the right stack *)
+(* Inverted call stack, where top item on the stack is waiting for an action to resolve and all other frames for the right stack *)
 type stack = 
  | Top
  | Frame of id * exp tannot * env * lmem * stack
 
-(* Either a case must be added for parallel options or action must be tied to a list *)
 type outcome =
  | Value of value * tag (* If tag is external and value is register, then register value should be read *)
  | Action of action * stack
diff --git a/src/lem_interp/interp_lib.lem b/src/lem_interp/interp_lib.lem
index a7cf265f..753de883 100644
--- a/src/lem_interp/interp_lib.lem
+++ b/src/lem_interp/interp_lib.lem
@@ -66,9 +66,12 @@ let arith_op op (V_tuple args) = match args with
   | [V_lit(L_aux (L_num x) lx); V_lit(L_aux (L_num y) ly)] -> V_lit(L_aux (L_num (op x y)) lx)
   end ;;
 let arith_op_vec op (V_tuple args) = match args with
-  | [(V_vector _ _ _ as l1);(V_vector _ _ _ as l2)] ->
+  | [(V_vector b ord cs as l1);(V_vector _ _ _ as l2)] ->
     let (l1',l2') = (to_num true l1,to_num true l2) in
-    arith_op op (V_tuple [l1';l2'])
+    let n = arith_op op (V_tuple [l1';l2']) in
+    if ord 
+    then to_vec_inc (List.length cs) n
+    else to_vec_dec (List.length cs) n
 end ;;
 let arith_op_range_vec op (V_tuple args) = match args with
   | [l1; (V_vector _ _ _ as l2)] ->
diff --git a/src/type_internal.ml b/src/type_internal.ml
index 827c5525..26a03d6a 100644
--- a/src/type_internal.ml
+++ b/src/type_internal.ml
@@ -544,7 +544,7 @@ let initial_typ_env =
                    Base(((mk_nat_params ["n";"o";"p"])@(mk_ord_params ["ord"]),
                          (mk_pure_fun (mk_tup [mk_vector bit_t (Ovar "ord") (Nvar "o") (Nvar "n");
                                                mk_vector bit_t (Ovar "ord") (Nvar "p") (Nvar "n")])
-                                      (mk_range {nexp = Nconst 0} {nexp = N2n (mk_nv "n")}))), External (Some "add_vec"),[],pure_e);
+                                      (mk_vector bit_t (Ovar "ord") (Nvar "o") (Nvar "n")))), External (Some "add_vec"),[],pure_e);
                    Base(((mk_nat_params ["n";"m";"o";"p"])@(mk_ord_params ["ord"]),
                         (mk_pure_fun (mk_tup [mk_vector bit_t (Ovar "ord") (Nvar "n") (Nvar "m");
                                               mk_range (mk_nv "o") (mk_nv "p")])
@@ -1070,7 +1070,7 @@ let rec type_coerce_internal co d_env t1 cs1 e t2 cs2 =
 and type_coerce co d_env t1 e t2 = type_coerce_internal co d_env t1 [] e t2 [];;
 
 let rec conforms_to_t spec actual =
-  let _ = Printf.printf "conforms_to_t called with %s, %s\n" (t_to_string spec) (t_to_string actual) in
+  (*let _ = Printf.printf "conforms_to_t called with %s, %s\n" (t_to_string spec) (t_to_string actual) in*)
   match spec.t,actual.t with
     | Tuvar _,_ -> true
     | Ttup ss, Ttup acs -> (List.length ss = List.length acs) && List.for_all2 conforms_to_t ss acs
@@ -1080,20 +1080,20 @@ let rec conforms_to_t spec actual =
       then List.for_all2 conforms_to_ta tas [TA_typ t]
       else conforms_to_t spec t
     | Tapp(is,tas), Tapp(ia, taa) -> 
-      let _ = Printf.printf "conforms to given two apps: %b, %b\n" (is = ia) (List.length tas = List.length taa) in
+      (*let _ = Printf.printf "conforms to given two apps: %b, %b\n" (is = ia) (List.length tas = List.length taa) in*)
       (is = ia) && (List.length tas = List.length taa) && (List.for_all2 conforms_to_ta tas taa)
     | Tabbrev(_,s),a -> conforms_to_t s actual
     | s,Tabbrev(_,a) -> conforms_to_t spec a
     | _,_ -> false
 and conforms_to_ta spec actual =
-  let _ = Printf.printf "conforms_to_ta called with %s, %s\n" (targ_to_string spec) (targ_to_string actual) in
+  (*let _ = Printf.printf "conforms_to_ta called with %s, %s\n" (targ_to_string spec) (targ_to_string actual) in*)
   match spec,actual with
     | TA_typ  s, TA_typ  a -> conforms_to_t s a
     | TA_nexp s, TA_nexp a -> conforms_to_n s a
     | TA_ord  s, TA_ord  a -> conforms_to_o s a
     | TA_eft  s, TA_eft  a -> conforms_to_e s a
 and conforms_to_n spec actual =
-  let _ = Printf.printf "conforms_to_n called with %s, %s\n" (n_to_string spec) (n_to_string actual) in
+  (*let _ = Printf.printf "conforms_to_n called with %s, %s\n" (n_to_string spec) (n_to_string actual) in*)
   match spec.nexp,actual.nexp with
     | Nuvar _,_ -> true
     | Nconst si,Nconst ai -> si==ai