@ -31,7 +31,6 @@ type vertex = ToplAutomaton.vindex [@@deriving compare]
type register = ToplAst . register_name [ @@ deriving compare ]
(* TODO ( rgrigore ) : Change the memory assoc list to a Map. *)
type configuration = { vertex : vertex ; memory : ( register * value ) list } [ @@ deriving compare ]
type predicate = Binop . t * PathCondition . operand * PathCondition . operand [ @@ deriving compare ]
@ -362,24 +361,48 @@ let sub_simple_state (sub, {pre; post; pruned; last_step}) =
( sub , { pre ; post ; pruned ; last_step } )
let sub_state = sub_list sub_simple_state
let normalize_memory memory = List . sort ~ compare : [ % compare : register * value ] memory
let normalize_configuration { vertex ; memory } = { vertex ; memory = normalize_memory memory }
let normalize_pruned pruned = List . sort ~ compare : compare_predicate pruned
let normalize_simple_state { pre ; post ; pruned ; last_step } =
{ pre = normalize_configuration pre
; post = normalize_configuration post
; pruned = normalize_pruned pruned
; last_step }
let normalize_state state = List . map ~ f : normalize_simple_state state
let large_step ~ call_location ~ callee_proc_name ~ substitution ~ condition ~ callee_prepost state =
let seq ( ( p : simple_state ) , ( q : simple_state ) ) =
if not ( Int . equal p . post . vertex q . pre . vertex ) then None
else
let add_eq eqs ( register , value_a ) =
let value_b =
match List . Assoc . find ~ equal : String . equal q . pre . memory register with
| Some x ->
x
| None ->
L . die InternalError " PulseTopl expects all registers in memory "
let substitution , new_eqs =
(* Update the substitution, matching formals with actuals. We work a bit to avoid introducing
equalities , because a growing [ pruned ] leads to quadratic behaviour . * )
let mk_eq val1 val2 =
let op x = PathCondition . AbstractValueOperand x in
( Binop . Eq , op val1 , op val2 )
in
let f ( sub , eqs ) ( reg1 , val1 ) ( reg2 , val2 ) =
if not ( String . equal reg1 reg2 ) then
L . die InternalError
" PulseTopl: normalized memories are expected to have the same domain "
else
match AbstractValue . Map . find_opt val2 sub with
| Some ( old_val1 , _ history ) ->
if AbstractValue . equal old_val1 val1 then ( sub , eqs )
else ( sub , mk_eq old_val1 val1 :: eqs )
| None ->
( AbstractValue . Map . add val2 ( val1 , [] ) sub , eqs )
in
let op x = PathCondition . AbstractValueOperand x in
( Binop . Eq , op value_a , op value_b ) :: eqs
of_unequal ( List . fold2 p . post . memory q . pre . memory ~ init : ( substitution , [] ) ~ f )
in
let pruned = List . fold ~ init : ( p . pruned @ q . pruned ) ~ f : add_eq p . post . memory in
let _ substitution , q = sub_simple_state ( substitution , q ) in
let pruned = new_eqs @ q . pruned @ p . pruned in
let last_step =
Some
{ step_location = call_location
@ -388,8 +411,9 @@ let large_step ~call_location ~callee_proc_name ~substitution ~condition ~callee
in
Some { pre = p . pre ; post = q . post ; pruned ; last_step }
in
let _ updated_substitution , callee_prepost = sub_state ( substitution , callee_prepost ) in
(* TODO ( rgrigore ) : may be worth optimizing the cartesian_product *)
let state = normalize_state state in
let callee_prepost = normalize_state callee_prepost in
let new_state = List . filter_map ~ f : seq ( List . cartesian_product state callee_prepost ) in
let result = drop_infeasible condition new_state in
L . d_printfln " @[<2>PulseTopl.large_step:@;callee_prepost=%a@;%a@ -> %a@] " pp_state callee_prepost