module One = struct type t = int let of_int x = assert (x > 0); x let numbits _ = 63 let zero = 0 let is_zero x = x = 0 let shift_left x i = x lsl i let shift_right x i = x lsr i let shift_left_one i = 1 lsl i let testbit x i = ( (x lsr i) land 1 ) = 1 let logor a b = a lor b let neg a = - a let logxor a b = a lxor b let logand a b = a land b let lognot a = lnot a let minus_one a = a - 1 let plus_one a = a + 1 let popcount = function | 0 -> 0 | r -> Util.popcnt (Int64.of_int r) let trailing_zeros r = Util.trailz (Int64.of_int r) let hamdist a b = a lxor b |> popcount let pp ppf s = Format.fprintf ppf "@[@[%a@]@]" (Util.pp_bitstring 64) (Z.of_int s) end module Many = struct type t = Z.t let of_int = Z.of_int let of_z x = x let zero = Z.zero let is_zero x = x = Z.zero let shift_left = Z.shift_left let shift_right = Z.shift_right let shift_left_one i = Z.shift_left Z.one i let testbit = Z.testbit let logor = Z.logor let logxor = Z.logxor let logand = Z.logand let lognot = Z.lognot let neg = Z.neg let minus_one = Z.pred let plus_one = Z.succ let trailing_zeros = Z.trailing_zeros let hamdist = Z.hamdist let numbits i = max (Z.numbits i) 64 let popcount z = if z = Z.zero then 0 else Z.popcount z let pp ppf s = Format.fprintf ppf "@[@[%a@]@]" (Util.pp_bitstring (Z.numbits s)) s end type t = | One of int | Many of Z.t let of_int x = One (One.of_int x) let of_z x = if Z.numbits x < 64 then One (Z.to_int x) else Many (Many.of_z x) let zero = function | n when n < 64 -> One (One.zero) | _ -> Many (Many.zero) let numbits = function | One x -> One.numbits x | Many x -> Many.numbits x let is_zero = function | One x -> One.is_zero x | Many x -> Many.is_zero x let neg = function | One x -> One (One.neg x) | Many x -> Many (Many.neg x) let shift_left x i = match x with | One x -> One (One.shift_left x i) | Many x -> Many (Many.shift_left x i) let shift_right x i = match x with | One x -> One (One.shift_right x i) | Many x -> Many (Many.shift_right x i) let shift_left_one = function | n when n < 64 -> fun i -> One (One.shift_left_one i) | _ -> fun i -> Many (Many.shift_left_one i) let testbit = function | One x -> One.testbit x | Many x -> Many.testbit x let logor a b = match a,b with | One a, One b -> One (One.logor a b) | Many a, Many b -> Many (Many.logor a b) | _ -> invalid_arg "Bitstring.logor" let logxor a b = match a,b with | One a, One b -> One (One.logxor a b) | Many a, Many b -> Many (Many.logxor a b) | _ -> invalid_arg "Bitstring.logxor" let logand a b = match a,b with | One a, One b -> One (One.logand a b) | Many a, Many b -> Many (Many.logand a b) | _ -> invalid_arg "Bitstring.logand" let lognot = function | One x -> One (One.lognot x) | Many x -> Many (Many.lognot x) let minus_one = function | One x -> One (One.minus_one x) | Many x -> Many (Many.minus_one x) let plus_one = function | One x -> One (One.plus_one x) | Many x -> Many (Many.plus_one x) let trailing_zeros = function | One x -> One.trailing_zeros x | Many x -> Many.trailing_zeros x let hamdist a b = match a, b with | One a, One b -> One.hamdist a b | Many a, Many b -> Many.hamdist a b | _ -> invalid_arg "Bitstring.hamdist" let popcount = function | One x -> One.popcount x | Many x -> Many.popcount x let pp ppf = function | One x -> One.pp ppf x | Many x -> Many.pp ppf x let rec to_list ?(accu=[]) = function | t when (is_zero t) -> List.rev accu | t -> let newlist = (trailing_zeros t + 1)::accu in logand t @@ minus_one t |> (to_list [@tailcall]) ~accu:newlist (** [permtutations m n] generates the list of all possible [n]-bit strings with [m] bits set to 1. Algorithm adapted from {{:https://graphics.stanford.edu/~seander/bithacks.html#NextBitPermutation} Bit twiddling hacks}. Example: {[ bit_permtutations 2 4 = [ 0011 ; 0101 ; 0110 ; 1001 ; 1010 ; 1100 ] ]} *) let permtutations m n = let rec aux k u rest = if k=1 then List.rev (u :: rest) else let t = logor u @@ minus_one u in let t' = plus_one t in let not_t = lognot t in let neg_not_t = neg not_t in let t'' = shift_right (minus_one @@ logand not_t neg_not_t) (trailing_zeros u + 1) in (* let t'' = shift_right (minus_one (logand (lognot t) t')) (trailing_zeros u + 1) in *) (aux [@tailcall]) (k-1) (logor t' t'') (u :: rest) in aux (Util.binom n m) (minus_one (shift_left_one n m)) [] (*-----------------------------------------------------------------------------------*) let test_case () = let test_one_many () = let x = 8745687 in let z = Z.of_int 8745687 in let one_x = One x in let many_x = Many z in Alcotest.(check bool) "of_x" true (one_x = (of_int x)); Alcotest.(check bool) "of_z" true (one_x = (of_z z)); Alcotest.(check bool) "shift_left1" true (One (x lsl 3) = shift_left one_x 3); Alcotest.(check bool) "shift_left2" true (Many (Z.shift_left z 3) = shift_left many_x 3); Alcotest.(check bool) "shift_left3" true (Many (Z.shift_left z 100) = shift_left many_x 100); Alcotest.(check bool) "shift_right1" true (One (x lsr 3) = shift_right one_x 3); Alcotest.(check bool) "shift_right2" true (Many (Z.shift_right z 3) = shift_right many_x 3); Alcotest.(check bool) "shift_left_one1" true (One (1 lsl 3) = shift_left_one 4 3); Alcotest.(check bool) "shift_left_one2" true (Many (Z.shift_left Z.one 200) = shift_left_one 300 200); Alcotest.(check bool) "testbit1" true (testbit (One 8) 3); Alcotest.(check bool) "testbit2" false (testbit (One 8) 2); Alcotest.(check bool) "testbit3" false (testbit (One 8) 4); Alcotest.(check bool) "testbit4" true (testbit (Many (Z.of_int 8)) 3); Alcotest.(check bool) "testbit5" false (testbit (Many (Z.of_int 8)) 2); Alcotest.(check bool) "testbit6" false (testbit (Many (Z.of_int 8)) 4); Alcotest.(check bool) "logor1" true (One (1 lor 2) = logor (One 1) (One 2)); Alcotest.(check bool) "logor2" true (Many (Z.of_int (1 lor 2)) = logor (Many Z.one) (Many (Z.of_int 2))); Alcotest.(check bool) "logxor1" true (One (1 lxor 2) = logxor (One 1) (One 2)); Alcotest.(check bool) "logxor2" true (Many (Z.of_int (1 lxor 2)) = logxor (Many Z.one) (Many (Z.of_int 2))); Alcotest.(check bool) "logand1" true (One (1 land 2) = logand (One 1) (One 2)); Alcotest.(check bool) "logand2" true (Many (Z.of_int (1 land 2)) = logand (Many Z.one) (Many (Z.of_int 2))); Alcotest.(check bool) "to_list" true ([ 1 ; 3 ; 4 ; 6 ] = (to_list (One 45))); in [ "One-many", `Quick, test_one_many; ]