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|
open Big_int
type 'a return = { return : 'b . 'a -> 'b }
let with_return (type t) (f : _ -> t) =
let module M =
struct exception Return of t end
in
let return = { return = (fun x -> raise (M.Return x)); } in
try f return with M.Return x -> x
type bit = B0 | B1
let and_bit = function
| B1, B1 -> B1
| _, _ -> B0
let or_bit = function
| B0, B0 -> B0
| _, _ -> B1
let and_vec (xs, ys) =
assert (List.length xs = List.length ys);
List.map2 (fun x y -> and_bit (x, y)) xs ys
let and_bool (b1, b2) = b1 && b2
let or_vec (xs, ys) =
assert (List.length xs = List.length ys);
List.map2 (fun x y -> or_bit (x, y)) xs ys
let or_bool (b1, b2) = b1 || b2
let undefined_bit () =
if Random.bool () then B0 else B1
let undefined_bool () = Random.bool ()
let rec undefined_vector (start_index, len, item) =
if eq_big_int len zero_big_int
then []
else item :: undefined_vector (start_index, sub_big_int len unit_big_int, item)
let undefined_string () = ""
let undefined_unit () = ()
let undefined_int () =
big_int_of_int (Random.int 0xFFFF)
let internal_pick list =
List.nth list (Random.int (List.length list))
let eq_int (n, m) = eq_big_int n m
let rec drop n xs =
match n, xs with
| 0, xs -> xs
| n, [] -> []
| n, (x :: xs) -> drop (n -1) xs
let rec take n xs =
match n, xs with
| 0, xs -> []
| n, (x :: xs) -> x :: take (n - 1) xs
| n, [] -> []
let subrange (list, n, m) =
let n = int_of_big_int n in
let m = int_of_big_int m in
List.rev (take (n - (m - 1)) (drop m (List.rev list)))
let eq_list (xs, ys) = List.for_all2 (fun x y -> x == y) xs ys
let access (xs, n) = List.nth (List.rev xs) (int_of_big_int n)
let append (xs, ys) = xs @ ys
let update (xs, n, x) =
let n = (List.length xs - int_of_big_int n) - 1 in
take n xs @ [x] @ drop (n + 1) xs
let update_subrange (xs, n, m, ys) =
let rec aux xs o = function
| [] -> xs
| (y :: ys) -> aux (update (xs, o, y)) (sub_big_int o unit_big_int) ys
in
aux xs n ys
let length xs = big_int_of_int (List.length xs)
let big_int_of_bit = function
| B0 -> zero_big_int
| B1 -> unit_big_int
let uint xs =
let uint_bit x (n, pos) =
add_big_int n (mult_big_int (power_int_positive_int 2 pos) (big_int_of_bit x)), pos + 1
in
fst (List.fold_right uint_bit xs (zero_big_int, 0))
let sint = function
| [] -> zero_big_int
| [msb] -> minus_big_int (big_int_of_bit msb)
| msb :: xs ->
let msb_pos = List.length xs in
let complement =
minus_big_int (mult_big_int (power_int_positive_int 2 msb_pos) (big_int_of_bit msb))
in
add_big_int complement (uint xs)
let add (x, y) = add_big_int x y
let sub (x, y) = sub_big_int x y
let mult (x, y) = mult_big_int x y
let quotient (x, y) = fst (quomod_big_int x y)
let modulus (x, y) = snd (quomod_big_int x y)
let add_bit_with_carry (x, y, carry) =
match x, y, carry with
| B0, B0, B0 -> B0, B0
| B0, B1, B0 -> B1, B0
| B1, B0, B0 -> B1, B0
| B1, B1, B0 -> B0, B1
| B0, B0, B1 -> B1, B0
| B0, B1, B1 -> B0, B1
| B1, B0, B1 -> B0, B1
| B1, B1, B1 -> B1, B1
let sub_bit_with_carry (x, y, carry) =
match x, y, carry with
| B0, B0, B0 -> B0, B0
| B0, B1, B0 -> B0, B1
| B1, B0, B0 -> B1, B0
| B1, B1, B0 -> B0, B0
| B0, B0, B1 -> B1, B0
| B0, B1, B1 -> B0, B0
| B1, B0, B1 -> B1, B1
| B1, B1, B1 -> B1, B0
let not_bit = function
| B0 -> B1
| B1 -> B0
let not_vec xs = List.map not_bit xs
let add_vec_carry (xs, ys) =
assert (List.length xs = List.length ys);
let (carry, result) =
List.fold_right2 (fun x y (c, result) -> let (z, c) = add_bit_with_carry (x, y, c) in (c, z :: result)) xs ys (B0, [])
in
carry, result
let add_vec (xs, ys) = snd (add_vec_carry (xs, ys))
let rec replicate_bits (bits, n) =
if le_big_int n zero_big_int
then []
else bits @ replicate_bits (bits, sub_big_int n unit_big_int)
let identity x = x
let rec bits_of_big_int bit n =
if not (eq_big_int bit zero_big_int)
then
begin
if gt_big_int (div_big_int n bit) zero_big_int
then B1 :: bits_of_big_int (div_big_int bit (big_int_of_int 2)) (sub_big_int n bit)
else B0 :: bits_of_big_int (div_big_int bit (big_int_of_int 2)) n
end
else []
let add_vec_int (v, n) =
let n_bits = bits_of_big_int (power_int_positive_int 2 (List.length v - 1)) n in
add_vec(v, n_bits)
let sub_vec (xs, ys) = add_vec (xs, add_vec_int (not_vec ys, unit_big_int))
let sub_vec_int (v, n) =
let n_bits = bits_of_big_int (power_int_positive_int 2 (List.length v - 1)) n in
sub_vec(v, n_bits)
let get_slice_int (n, m, o) =
let bits = bits_of_big_int (power_int_positive_big_int 2 (add_big_int n o)) m in
let slice = List.rev (take (int_of_big_int n) (drop (int_of_big_int o) (List.rev bits))) in
slice
let hex_char = function
| '0' -> [B0; B0; B0; B0]
| '1' -> [B0; B0; B0; B1]
| '2' -> [B0; B0; B1; B0]
| '3' -> [B0; B0; B1; B1]
| '4' -> [B0; B1; B0; B0]
| '5' -> [B0; B1; B0; B1]
| '6' -> [B0; B1; B1; B0]
| '7' -> [B0; B1; B1; B1]
| '8' -> [B1; B0; B0; B0]
| '9' -> [B1; B0; B0; B1]
| 'A' | 'a' -> [B1; B0; B1; B0]
| 'B' | 'b' -> [B1; B0; B1; B1]
| 'C' | 'c' -> [B1; B1; B0; B0]
| 'D' | 'd' -> [B1; B1; B0; B1]
| 'E' | 'e' -> [B1; B1; B1; B0]
| 'F' | 'f' -> [B1; B1; B1; B1]
let list_of_string s =
let rec aux i acc =
if i < 0 then acc
else aux (i-1) (s.[i] :: acc)
in aux (String.length s - 1) []
let bits_of_string str =
List.concat (List.map hex_char (list_of_string str))
let concat_str (str1, str2) = str1 ^ str2
let rec break n = function
| [] -> []
| (_ :: _ as xs) -> [take n xs] @ break n (drop n xs)
let string_of_bit = function
| B0 -> "0"
| B1 -> "1"
let string_of_hex = function
| [B0; B0; B0; B0] -> "0"
| [B0; B0; B0; B1] -> "1"
| [B0; B0; B1; B0] -> "2"
| [B0; B0; B1; B1] -> "3"
| [B0; B1; B0; B0] -> "4"
| [B0; B1; B0; B1] -> "5"
| [B0; B1; B1; B0] -> "6"
| [B0; B1; B1; B1] -> "7"
| [B1; B0; B0; B0] -> "8"
| [B1; B0; B0; B1] -> "9"
| [B1; B0; B1; B0] -> "A"
| [B1; B0; B1; B1] -> "B"
| [B1; B1; B0; B0] -> "C"
| [B1; B1; B0; B1] -> "D"
| [B1; B1; B1; B0] -> "E"
| [B1; B1; B1; B1] -> "F"
let string_of_bits bits =
if List.length bits mod 4 == 0
then "0x" ^ String.concat "" (List.map string_of_hex (break 4 bits))
else "0b" ^ String.concat "" (List.map string_of_bit bits)
let hex_slice (str, n, m) =
let bits = List.concat (List.map hex_char (list_of_string (String.sub str 2 (String.length str - 2)))) in
let padding = replicate_bits([B0], n) in
let bits = padding @ bits in
let slice = List.rev (take (int_of_big_int n) (drop (int_of_big_int m) (List.rev bits))) in
slice
let putchar n =
print_char (char_of_int (int_of_big_int n));
flush stdout
let rec bits_of_int bit n =
if bit <> 0
then
begin
if n / bit > 0
then B1 :: bits_of_int (bit / 2) (n - bit)
else B0 :: bits_of_int (bit / 2) n
end
else []
let byte_of_int n = bits_of_int 128 n
module BigIntHash =
struct
type t = big_int
let equal i j = eq_big_int i j
let hash i = Hashtbl.hash i
end
module RAM = Hashtbl.Make(BigIntHash)
let ram : int RAM.t = RAM.create 256
let write_ram' (addr_size, data_size, hex_ram, addr, data) =
let data = List.map (fun byte -> int_of_big_int (uint byte)) (break 8 data) in
let rec write_byte i byte =
prerr_endline (Printf.sprintf "W: %s -> 0x%02X" (string_of_big_int (add_big_int addr (big_int_of_int i))) byte);
RAM.add ram (add_big_int addr (big_int_of_int i)) byte
in
List.iteri write_byte (List.rev data)
let write_ram (addr_size, data_size, hex_ram, addr, data) =
write_ram' (addr_size, data_size, hex_ram, uint addr, data)
let wram addr byte =
RAM.add ram addr byte
let read_ram (addr_size, data_size, hex_ram, addr) =
let addr = uint addr in
let rec read_byte i =
if eq_big_int i zero_big_int
then []
else
begin
let loc = sub_big_int (add_big_int addr i) unit_big_int in
let byte = try RAM.find ram loc with Not_found -> 0 in
prerr_endline (Printf.sprintf "R: %s <- 0x%02X" (string_of_big_int loc) byte);
byte_of_int byte @ read_byte (sub_big_int i unit_big_int)
end
in
read_byte data_size
(* FIXME: Casts can't be externed *)
let zcast_unit_vec x = [x]
let shl_int (n, m) = shift_left_big_int n (int_of_big_int m)
let shr_int (n, m) = shift_right_big_int n (int_of_big_int m)
let debug (str1, n, str2, v) = prerr_endline (str1 ^ string_of_big_int n ^ str2 ^ string_of_bits v)
let eq_string (str1, str2) = String.compare str1 str2 == 0
let lt_int (x, y) = lt_big_int x y
|
