--- /dev/null	Thu Jan 01 00:00:00 1970 +0000
+++ b/src/fftw-3.3.8/genfft/oracle.ml	Tue Nov 19 14:52:55 2019 +0000
@@ -0,0 +1,144 @@
+(*
+ * Copyright (c) 1997-1999 Massachusetts Institute of Technology
+ * Copyright (c) 2003, 2007-14 Matteo Frigo
+ * Copyright (c) 2003, 2007-14 Massachusetts Institute of Technology
+ *
+ * This program is free software; you can redistribute it and/or modify
+ * it under the terms of the GNU General Public License as published by
+ * the Free Software Foundation; either version 2 of the License, or
+ * (at your option) any later version.
+ *
+ * This program is distributed in the hope that it will be useful,
+ * but WITHOUT ANY WARRANTY; without even the implied warranty of
+ * MERCHANTABILITY or FITNESS FOR A PARTICULAR PURPOSE.  See the
+ * GNU General Public License for more details.
+ *
+ * You should have received a copy of the GNU General Public License
+ * along with this program; if not, write to the Free Software
+ * Foundation, Inc., 51 Franklin Street, Fifth Floor, Boston, MA  02110-1301  USA
+ *
+ *)
+
+(*
+ * the oracle decrees whether the sign of an expression should
+ * be changed.
+ *
+ * Say the expression (A - B) appears somewhere.  Elsewhere in the
+ * expression dag the expression (B - A) may appear.
+ * The oracle determines which of the two forms is canonical.
+ *
+ * Algorithm: evaluate the expression at a random input, and
+ * keep the expression with the positive sign.
+ *)
+
+let make_memoizer hash equal =
+  let table = ref Assoctable.empty 
+  in 
+  (fun f k ->
+    match Assoctable.lookup hash equal k !table with
+      Some value -> value
+    | None ->
+        let value = f k in
+        begin	
+          table := Assoctable.insert hash k value !table;
+          value
+        end)
+
+let almost_equal x y = 
+  let epsilon = 1.0E-8 in
+  (abs_float (x -. y) < epsilon) ||
+  (abs_float (x -. y) < epsilon *. (abs_float x +. abs_float y)) 
+
+let absid = make_memoizer
+    (fun x -> Expr.hash_float (abs_float x))
+    (fun a b -> almost_equal a b || almost_equal (-. a) b)
+    (fun x -> x)
+
+let make_random_oracle () = make_memoizer 
+    Variable.hash 
+    Variable.same
+    (fun _ -> (float (Random.bits())) /. 1073741824.0)
+
+let the_random_oracle = make_random_oracle ()
+
+let sum_list l = List.fold_right (+.) l 0.0
+
+let eval_aux random_oracle =
+  let memoizing = make_memoizer Expr.hash (==) in
+  let rec eval x = 
+    memoizing
+      (function
+	| Expr.Num x -> Number.to_float x
+	| Expr.NaN x -> Expr.transcendent_to_float x
+	| Expr.Load v -> random_oracle v
+	| Expr.Store (v, x) -> eval x
+	| Expr.Plus l -> sum_list (List.map eval l)
+	| Expr.Times (a, b) -> (eval a) *. (eval b)
+	| Expr.CTimes (a, b) -> 
+	    1.098612288668109691395245236 +. 
+	       1.609437912434100374600759333 *. (eval a) *. (eval b)
+	| Expr.CTimesJ (a, b) -> 
+	    0.9102392266268373936142401657 +. 
+	      0.6213349345596118107071993881 *. (eval a) *. (eval b)
+	| Expr.Uminus x -> -. (eval x))
+      x
+  in eval
+
+let eval = eval_aux the_random_oracle
+
+let should_flip_sign node = 
+  let v = eval node in
+  let v' = absid v in
+  not (almost_equal v v')
+
+(*
+ * determine with high probability if two expressions are equal.
+ *
+ * The test is randomized: if the two expressions have the
+ * same value for NTESTS random inputs, then they are proclaimed
+ * equal.  (Note that two distinct linear functions L1(x0, x1, ..., xn)
+ * and L2(x0, x1, ..., xn) have the same value with probability
+ * 0 for random x's, and thus this test is way more paranoid than
+ * necessary.)
+ *)
+let likely_equal a b =
+  let tolerance = 1.0e-8
+  and ntests = 20
+  in
+  let rec loop n =
+    if n = 0 then 
+      true
+    else
+      let r = make_random_oracle () in
+      let va = eval_aux r a
+      and vb = eval_aux r b
+      in
+      if (abs_float (va -. vb)) > 
+	   tolerance *. (abs_float va +. abs_float vb +. 0.0001)
+      then
+	false
+      else
+	loop (n - 1)
+  in
+  match (a, b) with
+
+    (* 
+     * Because of the way eval is constructed, we have
+     *     eval (Store (v, x)) == eval x
+     * However, we never consider the two expressions equal
+     *)
+  | (Expr.Store _, _) -> false
+  | (_, Expr.Store _) -> false
+
+    (*
+     * Expressions of the form ``Uminus (Store _)''
+     * are artifacts of algsimp
+     *)
+  | ((Expr.Uminus (Expr.Store _)), _) -> false
+  | (_, Expr.Uminus (Expr.Store _)) -> false
+
+  | _ -> loop ntests
+
+let hash x =
+  let f = eval x in
+  truncate (f *. 65536.0)