path: root/src/gen_lib/sail2_prompt_monad.lem

open import Pervasives_extra
(*open import Sail_impl_base*)
open import Sail2_instr_kinds
open import Sail2_values

type register_name = string
type address = list bitU

type monad 'regval 'a 'e =
  | Done of 'a
  (* Read a number of bytes from memory, returned in little endian order,
     with or without a tag.  The first nat specifies the address, the second
     the number of bytes. *)
  | Read_mem of read_kind * nat * nat * (list memory_byte -> monad 'regval 'a 'e)
  | Read_memt of read_kind * nat * nat * ((list memory_byte * bitU) -> monad 'regval 'a 'e)
  (* Tell the system a write is imminent, at the given address and with the
     given size. *)
  | Write_ea of write_kind * nat * nat * monad 'regval 'a 'e
  (* Request the result of store-exclusive *)
  | Excl_res of (bool -> monad 'regval 'a 'e)
  (* Request to write a memory value of the given size at the given address,
     with or without a tag. *)
  | Write_mem of write_kind * nat * nat * list memory_byte * (bool -> monad 'regval 'a 'e)
  | Write_memt of write_kind * nat * nat * list memory_byte * bitU * (bool -> monad 'regval 'a 'e)
  (* Tell the system to dynamically recalculate dependency footprint *)
  | Footprint of monad 'regval 'a 'e
  (* Request a memory barrier *)
  | Barrier of barrier_kind * monad 'regval 'a 'e
  (* Request to read register, will track dependency when mode.track_values *)
  | Read_reg of register_name * ('regval -> monad 'regval 'a 'e)
  (* Request to write register *)
  | Write_reg of register_name * 'regval * monad 'regval 'a 'e
  (* Request to choose a Boolean, e.g. to resolve an undefined bit. The string
     argument may be used to provide information to the system about what the
     Boolean is going to be used for. *)
  | Choose of string * (bool -> monad 'regval 'a 'e)
  (* Print debugging or tracing information *)
  | Print of string * monad 'regval 'a 'e
  (*Result of a failed assert with possible error message to report*)
  | Fail of string
  (* Exception of type 'e *)
  | Exception of 'e

type event 'regval =
  | E_read_mem of read_kind * nat * nat * list memory_byte
  | E_read_memt of read_kind * nat * nat * (list memory_byte * bitU)
  | E_write_mem of write_kind * nat * nat * list memory_byte * bool
  | E_write_memt of write_kind * nat * nat * list memory_byte * bitU * bool
  | E_write_ea of write_kind * nat * nat
  | E_excl_res of bool
  | E_barrier of barrier_kind
  | E_footprint
  | E_read_reg of register_name * 'regval
  | E_write_reg of register_name * 'regval
  | E_choose of string * bool
  | E_print of string

type trace 'regval = list (event 'regval)

val return : forall 'rv 'a 'e. 'a -> monad 'rv 'a 'e
let return a = Done a

val bind : forall 'rv 'a 'b 'e. monad 'rv 'a 'e -> ('a -> monad 'rv 'b 'e) -> monad 'rv 'b 'e
let rec bind m f = match m with
  | Done a -> f a
  | Read_mem rk a sz k ->       Read_mem rk a sz       (fun v -> bind (k v) f)
  | Read_memt rk a sz k ->      Read_memt rk a sz      (fun v -> bind (k v) f)
  | Write_mem wk a sz v k ->    Write_mem wk a sz v    (fun v -> bind (k v) f)
  | Write_memt wk a sz v t k -> Write_memt wk a sz v t (fun v -> bind (k v) f)
  | Read_reg descr k ->         Read_reg descr         (fun v -> bind (k v) f)
  | Excl_res k ->               Excl_res               (fun v -> bind (k v) f)
  | Choose descr k ->           Choose descr           (fun v -> bind (k v) f)
  | Write_ea wk a sz k ->       Write_ea wk a sz       (bind k f)
  | Footprint k ->              Footprint              (bind k f)
  | Barrier bk k ->             Barrier bk             (bind k f)
  | Write_reg r v k ->          Write_reg r v          (bind k f)
  | Print msg k ->              Print msg              (bind k f)
  | Fail descr ->               Fail descr
  | Exception e ->              Exception e
end

val exit : forall 'rv 'a 'e. unit -> monad 'rv 'a 'e
let exit () = Fail "exit"

val choose_bool : forall 'rv 'e. string -> monad 'rv bool 'e
let choose_bool descr = Choose descr return

val undefined_bool : forall 'rv 'e. unit -> monad 'rv bool 'e
let undefined_bool () = choose_bool "undefined_bool"

val assert_exp : forall 'rv 'e. bool -> string -> monad 'rv unit 'e
let assert_exp exp msg = if exp then Done () else Fail msg

val throw : forall 'rv 'a 'e. 'e -> monad 'rv 'a 'e
let throw e = Exception e

val try_catch : forall 'rv 'a 'e1 'e2. monad 'rv 'a 'e1 -> ('e1 -> monad 'rv 'a 'e2) -> monad 'rv 'a 'e2
let rec try_catch m h = match m with
  | Done a -> Done a
  | Read_mem rk a sz k ->       Read_mem rk a sz       (fun v -> try_catch (k v) h)
  | Read_memt rk a sz k ->      Read_memt rk a sz      (fun v -> try_catch (k v) h)
  | Write_mem wk a sz v k ->    Write_mem wk a sz v    (fun v -> try_catch (k v) h)
  | Write_memt wk a sz v t k -> Write_memt wk a sz v t (fun v -> try_catch (k v) h)
  | Read_reg descr k ->         Read_reg descr         (fun v -> try_catch (k v) h)
  | Excl_res k ->               Excl_res               (fun v -> try_catch (k v) h)
  | Choose descr k ->           Choose descr           (fun v -> try_catch (k v) h)
  | Write_ea wk a sz k ->       Write_ea wk a sz       (try_catch k h)
  | Footprint k ->              Footprint              (try_catch k h)
  | Barrier bk k ->             Barrier bk             (try_catch k h)
  | Write_reg r v k ->          Write_reg r v          (try_catch k h)
  | Print msg k ->              Print msg              (try_catch k h)
  | Fail descr ->               Fail descr
  | Exception e ->              h e
end

(* For early return, we abuse exceptions by throwing and catching
   the return value. The exception type is "either 'r 'e", where "Right e"
   represents a proper exception and "Left r" an early return of value "r". *)
type monadR 'rv 'a 'r 'e = monad 'rv 'a (either 'r 'e)

val early_return : forall 'rv 'a 'r 'e. 'r -> monadR 'rv 'a 'r 'e
let early_return r = throw (Left r)

val catch_early_return : forall 'rv 'a 'e. monadR 'rv 'a 'a 'e -> monad 'rv 'a 'e
let catch_early_return m =
  try_catch m
    (function
      | Left a -> return a
      | Right e -> throw e
     end)

(* Lift to monad with early return by wrapping exceptions *)
val liftR : forall 'rv 'a 'r 'e. monad 'rv 'a 'e -> monadR 'rv 'a 'r 'e
let liftR m = try_catch m (fun e -> throw (Right e))

(* Catch exceptions in the presence of early returns *)
val try_catchR : forall 'rv 'a 'r 'e1 'e2. monadR 'rv 'a 'r 'e1 -> ('e1 -> monadR 'rv 'a 'r 'e2) ->  monadR 'rv 'a 'r 'e2
let try_catchR m h =
  try_catch m
    (function
      | Left r -> throw (Left r)
      | Right e -> h e
     end)

val maybe_fail : forall 'rv 'a 'e. string -> maybe 'a -> monad 'rv 'a 'e
let maybe_fail msg = function
  | Just a -> return a
  | Nothing -> Fail msg
end

val read_memt_bytes : forall 'rv 'a 'b 'e. Bitvector 'a, Bitvector 'b => read_kind -> 'a -> integer -> monad 'rv (list memory_byte * bitU) 'e
let read_memt_bytes rk addr sz =
  bind
    (maybe_fail "nat_of_bv" (nat_of_bv addr))
    (fun addr -> Read_memt rk addr (nat_of_int sz) return)

val read_memt : forall 'rv 'a 'b 'e. Bitvector 'a, Bitvector 'b => read_kind -> 'a -> integer -> monad 'rv ('b * bitU) 'e
let read_memt rk addr sz =
  bind
    (read_memt_bytes rk addr sz)
    (fun (bytes, tag) ->
       match of_bits (bits_of_mem_bytes bytes) with
         | Just v -> return (v, tag)
         | Nothing -> Fail "bits_of_mem_bytes"
       end)

val read_mem_bytes : forall 'rv 'a 'b 'e. Bitvector 'a, Bitvector 'b => read_kind -> 'a -> integer -> monad 'rv (list memory_byte) 'e
let read_mem_bytes rk addr sz =
  bind
    (maybe_fail "nat_of_bv" (nat_of_bv addr))
    (fun addr -> Read_mem rk addr (nat_of_int sz) return)

val read_mem : forall 'rv 'a 'b 'e 'addrsize. Bitvector 'a, Bitvector 'b => read_kind -> 'addrsize -> 'a -> integer -> monad 'rv 'b 'e
let read_mem rk addr_sz addr sz =
  bind
    (read_mem_bytes rk addr sz)
    (fun bytes ->
       match of_bits (bits_of_mem_bytes bytes) with
         | Just v -> return v
         | Nothing -> Fail "bits_of_mem_bytes"
       end)

val excl_result : forall 'rv 'e. unit -> monad 'rv bool 'e
let excl_result () =
  let k successful = (return successful) in
  Excl_res k

val write_mem_ea : forall 'rv 'a 'e 'addrsize. Bitvector 'a => write_kind -> 'addrsize -> 'a -> integer -> monad 'rv unit 'e
let write_mem_ea wk addr_size addr sz =
  bind
    (maybe_fail "nat_of_bv" (nat_of_bv addr))
    (fun addr -> Write_ea wk addr (nat_of_int sz) (Done ()))

val write_mem : forall 'rv 'a 'b 'e 'addrsize. Bitvector 'a, Bitvector 'b =>
  write_kind -> 'addrsize -> 'a -> integer -> 'b -> monad 'rv bool 'e
let write_mem wk addr_size addr sz v =
  match (mem_bytes_of_bits v, nat_of_bv addr) with
    | (Just v, Just addr) ->
       Write_mem wk addr (nat_of_int sz) v return
    | _ -> Fail "write_mem"
  end

val write_memt : forall 'rv 'a 'b 'e. Bitvector 'a, Bitvector 'b =>
  write_kind -> 'a -> integer -> 'b -> bitU -> monad 'rv bool 'e
let write_memt wk addr sz v tag =
  match (mem_bytes_of_bits v, nat_of_bv addr) with
    | (Just v, Just addr) ->
       Write_memt wk addr (nat_of_int sz) v tag return
    | _ -> Fail "write_mem"
  end

val read_reg : forall 's 'rv 'a 'e. register_ref 's 'rv 'a -> monad 'rv 'a 'e
let read_reg reg =
  let k v =
    match reg.of_regval v with
      | Just v -> Done v
      | Nothing -> Fail "read_reg: unrecognised value"
    end
  in
  Read_reg reg.name k

(* TODO
val read_reg_range : forall 's 'r 'rv 'a 'e. Bitvector 'a => register_ref 's 'rv 'r -> integer -> integer -> monad 'rv 'a 'e
let read_reg_range reg i j =
  read_reg_aux of_bits (external_reg_slice reg (nat_of_int i,nat_of_int j))

let read_reg_bit reg i =
  read_reg_aux (fun v -> v) (external_reg_slice reg (nat_of_int i,nat_of_int i)) >>= fun v ->
  return (extract_only_element v)

let read_reg_field reg regfield =
  read_reg_aux (external_reg_field_whole reg regfield)

let read_reg_bitfield reg regfield =
  read_reg_aux (external_reg_field_whole reg regfield) >>= fun v ->
  return (extract_only_element v)*)

let inline reg_deref = read_reg

val write_reg : forall 's 'rv 'a 'e. register_ref 's 'rv 'a -> 'a -> monad 'rv unit 'e
let write_reg reg v = Write_reg reg.name (reg.regval_of v) (Done ())

(* TODO
let write_reg reg v =
  write_reg_aux (external_reg_whole reg) v
let write_reg_range reg i j v =
  write_reg_aux (external_reg_slice reg (nat_of_int i,nat_of_int j)) v
let write_reg_pos reg i v =
  let iN = nat_of_int i in
  write_reg_aux (external_reg_slice reg (iN,iN)) [v]
let write_reg_bit = write_reg_pos
let write_reg_field reg regfield v =
  write_reg_aux (external_reg_field_whole reg regfield.field_name) v
let write_reg_field_bit reg regfield bit =
  write_reg_aux (external_reg_field_whole reg regfield.field_name)
                (Vector [bit] 0 (is_inc_of_reg reg))
let write_reg_field_range reg regfield i j v =
  write_reg_aux (external_reg_field_slice reg regfield.field_name (nat_of_int i,nat_of_int j)) v
let write_reg_field_pos reg regfield i v =
  write_reg_field_range reg regfield i i [v]
let write_reg_field_bit = write_reg_field_pos*)

val barrier : forall 'rv 'e. barrier_kind -> monad 'rv unit 'e
let barrier bk = Barrier bk (Done ())

val footprint : forall 'rv 'e. unit -> monad 'rv unit 'e
let footprint _ = Footprint (Done ())

(* Event traces *)

val emitEvent : forall 'regval 'a 'e. Eq 'regval => monad 'regval 'a 'e -> event 'regval -> maybe (monad 'regval 'a 'e)
let emitEvent m e = match (e, m) with
  | (E_read_mem rk a sz v, Read_mem rk' a' sz' k) ->
     if rk' = rk && a' = a && sz' = sz then Just (k v) else Nothing
  | (E_read_memt rk a sz vt, Read_memt rk' a' sz' k) ->
     if rk' = rk && a' = a && sz' = sz then Just (k vt) else Nothing
  | (E_write_mem wk a sz v r, Write_mem wk' a' sz' v' k) ->
     if wk' = wk && a' = a && sz' = sz && v' = v then Just (k r) else Nothing
  | (E_write_memt wk a sz v tag r, Write_memt wk' a' sz' v' tag' k) ->
     if wk' = wk && a' = a && sz' = sz && v' = v && tag' = tag then Just (k r) else Nothing
  | (E_read_reg r v, Read_reg r' k) ->
     if r' = r then Just (k v) else Nothing
  | (E_write_reg r v, Write_reg r' v' k) ->
     if r' = r && v' = v then Just k else Nothing
  | (E_write_ea wk a sz, Write_ea wk' a' sz' k) ->
     if wk' = wk && a' = a && sz' = sz then Just k else Nothing
  | (E_barrier bk, Barrier bk' k) ->
     if bk' = bk then Just k else Nothing
  | (E_print m, Print m' k) ->
     if m' = m then Just k else Nothing
  | (E_excl_res v, Excl_res k) -> Just (k v)
  | (E_choose descr v, Choose descr' k) -> if descr' = descr then Just (k v) else Nothing
  | (E_footprint, Footprint k) -> Just k
  | _ -> Nothing
end

val runTrace : forall 'regval 'a 'e. Eq 'regval => trace 'regval -> monad 'regval 'a 'e -> maybe (monad 'regval 'a 'e)
let rec runTrace t m = match t with
  | [] -> Just m
  | e :: t' -> Maybe.bind (emitEvent m e) (runTrace t')
end

declare {isabelle} termination_argument runTrace = automatic

val final : forall 'regval 'a 'e. monad 'regval 'a 'e -> bool
let final = function
  | Done _ -> true
  | Fail _ -> true
  | Exception _ -> true
  | _ -> false
end

val hasTrace : forall 'regval 'a 'e. Eq 'regval => trace 'regval -> monad 'regval 'a 'e -> bool
let hasTrace t m = match runTrace t m with
  | Just m -> final m
  | Nothing -> false
end

val hasException : forall 'regval 'a 'e. Eq 'regval => trace 'regval -> monad 'regval 'a 'e -> bool
let hasException t m = match runTrace t m with
  | Just (Exception _) -> true
  | _ -> false
end

val hasFailure : forall 'regval 'a 'e. Eq 'regval => trace 'regval -> monad 'regval 'a 'e -> bool
let hasFailure t m = match runTrace t m with
  | Just (Fail _) -> true
  | _ -> false
end

(* Define a type synonym that also takes the register state as a type parameter,
   in order to make switching to the state monad without changing generated
   definitions easier, see also lib/hol/prompt_monad.lem. *)

type base_monad 'regval 'regstate 'a 'e = monad 'regval 'a 'e
type base_monadR 'regval 'regstate 'a 'r 'e = monadR 'regval 'a 'r 'e