mirror of
https://github.com/tildearrow/furnace.git
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153 lines
5.3 KiB
OCaml
153 lines
5.3 KiB
OCaml
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(*
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* Copyright (c) 1997-1999 Massachusetts Institute of Technology
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* Copyright (c) 2003, 2007-14 Matteo Frigo
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* Copyright (c) 2003, 2007-14 Massachusetts Institute of Technology
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*
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* This program is free software; you can redistribute it and/or modify
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* it under the terms of the GNU General Public License as published by
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* the Free Software Foundation; either version 2 of the License, or
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* (at your option) any later version.
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*
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* This program is distributed in the hope that it will be useful,
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* but WITHOUT ANY WARRANTY; without even the implied warranty of
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* MERCHANTABILITY or FITNESS FOR A PARTICULAR PURPOSE. See the
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* GNU General Public License for more details.
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*
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* You should have received a copy of the GNU General Public License
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* along with this program; if not, write to the Free Software
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* Foundation, Inc., 51 Franklin Street, Fifth Floor, Boston, MA 02110-1301 USA
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*
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*)
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(* Here, we define the data type encapsulating a symbolic arithmetic
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expression, and provide some routines for manipulating it. *)
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(* I will regret this hack : *)
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(* NEWS: I did *)
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type transcendent = I | MULTI_A | MULTI_B | CONJ
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type expr =
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| Num of Number.number
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| NaN of transcendent
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| Plus of expr list
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| Times of expr * expr
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| CTimes of expr * expr
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| CTimesJ of expr * expr (* CTimesJ (a, b) = conj(a) * b *)
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| Uminus of expr
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| Load of Variable.variable
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| Store of Variable.variable * expr
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type assignment = Assign of Variable.variable * expr
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(* various hash functions *)
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let hash_float x =
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let (mantissa, exponent) = frexp x
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in truncate (float_of_int(exponent) *. 1234.567 +. mantissa *. 10000.0)
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let sum_list l = List.fold_right (+) l 0
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let transcendent_to_float = function
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| I -> 2.718281828459045235360287471 (* any transcendent number will do *)
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| MULTI_A -> 0.6931471805599453094172321214
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| MULTI_B -> -0.3665129205816643270124391582
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| CONJ -> 0.6019072301972345747375400015
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let rec hash = function
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| Num x -> hash_float (Number.to_float x)
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| NaN x -> hash_float (transcendent_to_float x)
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| Load v -> 1 + 1237 * Variable.hash v
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| Store (v, x) -> 2 * Variable.hash v - 2345 * hash x
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| Plus l -> 5 + 23451 * sum_list (List.map Hashtbl.hash l)
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| Times (a, b) -> 41 + 31415 * (Hashtbl.hash a + Hashtbl.hash b)
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| CTimes (a, b) -> 49 + 3245 * (Hashtbl.hash a + Hashtbl.hash b)
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| CTimesJ (a, b) -> 31 + 3471 * (Hashtbl.hash a + Hashtbl.hash b)
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| Uminus x -> 42 + 12345 * (hash x)
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(* find all variables *)
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let rec find_vars x =
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match x with
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| Load y -> [y]
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| Plus l -> List.flatten (List.map find_vars l)
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| Times (a, b) -> (find_vars a) @ (find_vars b)
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| CTimes (a, b) -> (find_vars a) @ (find_vars b)
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| CTimesJ (a, b) -> (find_vars a) @ (find_vars b)
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| Uminus a -> find_vars a
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| _ -> []
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(* TRUE if expression is a constant *)
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let is_constant = function
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| Num _ -> true
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| NaN _ -> true
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| Load v -> Variable.is_constant v
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| _ -> false
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let is_known_constant = function
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| Num _ -> true
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| NaN _ -> true
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| _ -> false
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(* expr to string, used for debugging *)
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let rec foldr_string_concat l =
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match l with
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[] -> ""
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| [a] -> a
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| a :: b -> a ^ " " ^ (foldr_string_concat b)
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let string_of_transcendent = function
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| I -> "I"
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| MULTI_A -> "MULTI_A"
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| MULTI_B -> "MULTI_B"
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| CONJ -> "CONJ"
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let rec to_string = function
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| Load v -> Variable.unparse v
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| Num n -> string_of_float (Number.to_float n)
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| NaN n -> string_of_transcendent n
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| Plus x -> "(+ " ^ (foldr_string_concat (List.map to_string x)) ^ ")"
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| Times (a, b) -> "(* " ^ (to_string a) ^ " " ^ (to_string b) ^ ")"
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| CTimes (a, b) -> "(c* " ^ (to_string a) ^ " " ^ (to_string b) ^ ")"
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| CTimesJ (a, b) -> "(cj* " ^ (to_string a) ^ " " ^ (to_string b) ^ ")"
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| Uminus a -> "(- " ^ (to_string a) ^ ")"
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| Store (v, a) -> "(:= " ^ (Variable.unparse v) ^ " " ^
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(to_string a) ^ ")"
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let rec to_string_a d x =
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if (d = 0) then "..." else match x with
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| Load v -> Variable.unparse v
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| Num n -> Number.to_konst n
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| NaN n -> string_of_transcendent n
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| Plus x -> "(+ " ^ (foldr_string_concat (List.map (to_string_a (d - 1)) x)) ^ ")"
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| Times (a, b) -> "(* " ^ (to_string_a (d - 1) a) ^ " " ^ (to_string_a (d - 1) b) ^ ")"
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| CTimes (a, b) -> "(c* " ^ (to_string_a (d - 1) a) ^ " " ^ (to_string_a (d - 1) b) ^ ")"
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| CTimesJ (a, b) -> "(cj* " ^ (to_string_a (d - 1) a) ^ " " ^ (to_string_a (d - 1) b) ^ ")"
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| Uminus a -> "(- " ^ (to_string_a (d-1) a) ^ ")"
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| Store (v, a) -> "(:= " ^ (Variable.unparse v) ^ " " ^
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(to_string_a (d-1) a) ^ ")"
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let to_string = to_string_a 10
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let assignment_to_string = function
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| Assign (v, a) -> "(:= " ^ (Variable.unparse v) ^ " " ^ (to_string a) ^ ")"
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let dump print = List.iter (fun x -> print ((assignment_to_string x) ^ "\n"))
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(* find all constants in a given expression *)
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let rec expr_to_constants = function
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| Num n -> [n]
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| Plus a -> List.flatten (List.map expr_to_constants a)
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| Times (a, b) -> (expr_to_constants a) @ (expr_to_constants b)
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| CTimes (a, b) -> (expr_to_constants a) @ (expr_to_constants b)
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| CTimesJ (a, b) -> (expr_to_constants a) @ (expr_to_constants b)
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| Uminus a -> expr_to_constants a
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| _ -> []
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let add_float_key_value list_so_far k =
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if List.exists (fun k2 -> Number.equal k k2) list_so_far then
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list_so_far
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else
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k :: list_so_far
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let unique_constants = List.fold_left add_float_key_value []
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