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165 lines
5.6 KiB
OCaml
165 lines
5.6 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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(* The generator keeps track of numeric constants in symbolic
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expressions using the abstract number type, defined in this file.
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Our implementation of the number type uses arbitrary-precision
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arithmetic from the built-in Num package in order to maintain an
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accurate representation of constants. This allows us to output
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constants with many decimal places in the generated C code,
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ensuring that we will take advantage of the full precision
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available on current and future machines.
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Note that we have to write our own routine to compute roots of
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unity, since the Num package only supplies simple arithmetic. The
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arbitrary-precision operations in Num look like the normal
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operations except that they have an appended slash (e.g. +/ -/ */
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// etcetera). *)
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open Num
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type number = N of num
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let makeNum n = N n
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(* decimal digits of precision to maintain internally, and to print out: *)
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let precision = 50
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let print_precision = 45
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let inveps = (Int 10) **/ (Int precision)
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let epsilon = (Int 1) // inveps
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let pinveps = (Int 10) **/ (Int print_precision)
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let pepsilon = (Int 1) // pinveps
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let round x = epsilon */ (round_num (x */ inveps))
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let of_int n = N (Int n)
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let zero = of_int 0
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let one = of_int 1
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let two = of_int 2
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let mone = of_int (-1)
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(* comparison predicate for real numbers *)
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let equal (N x) (N y) = (* use both relative and absolute error *)
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let absdiff = abs_num (x -/ y) in
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absdiff <=/ pepsilon ||
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absdiff <=/ pepsilon */ (abs_num x +/ abs_num y)
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let is_zero = equal zero
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let is_one = equal one
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let is_mone = equal mone
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let is_two = equal two
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(* Note that, in the following computations, it is important to round
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to precision epsilon after each operation. Otherwise, since the
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Num package uses exact rational arithmetic, the number of digits
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quickly blows up. *)
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let mul (N a) (N b) = makeNum (round (a */ b))
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let div (N a) (N b) = makeNum (round (a // b))
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let add (N a) (N b) = makeNum (round (a +/ b))
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let sub (N a) (N b) = makeNum (round (a -/ b))
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let negative (N a) = (a </ (Int 0))
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let negate (N a) = makeNum (minus_num a)
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let greater a b = negative (sub b a)
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let epsilonsq = epsilon */ epsilon
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let epsilonsq2 = (Int 100) */ epsilonsq
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let sqr a = a */ a
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let almost_equal (N a) (N b) = (sqr (a -/ b)) <=/ epsilonsq2
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(* find square root by Newton's method *)
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let sqrt a =
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let rec sqrt_iter guess =
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let newguess = div (add guess (div a guess)) two in
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if (almost_equal newguess guess) then newguess
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else sqrt_iter newguess
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in sqrt_iter (div a two)
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let csub (xr, xi) (yr, yi) = (round (xr -/ yr), round (xi -/ yi))
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let cdiv (xr, xi) r = (round (xr // r), round (xi // r))
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let cmul (xr, xi) (yr, yi) = (round (xr */ yr -/ xi */ yi),
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round (xr */ yi +/ xi */ yr))
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let csqr (xr, xi) = (round (xr */ xr -/ xi */ xi), round ((Int 2) */ xr */ xi))
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let cabssq (xr, xi) = xr */ xr +/ xi */ xi
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let cconj (xr, xi) = (xr, minus_num xi)
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let cinv x = cdiv (cconj x) (cabssq x)
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let almost_equal_cnum (xr, xi) (yr, yi) =
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(cabssq (xr -/ yr,xi -/ yi)) <=/ epsilonsq2
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(* Put a complex number to an integer power by repeated squaring: *)
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let rec ipow_cnum x n =
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if (n == 0) then
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(Int 1, Int 0)
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else if (n < 0) then
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cinv (ipow_cnum x (- n))
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else if (n mod 2 == 0) then
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ipow_cnum (csqr x) (n / 2)
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else
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cmul x (ipow_cnum x (n - 1))
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let twopi = 6.28318530717958647692528676655900576839433879875021164194989
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(* Find the nth (complex) primitive root of unity by Newton's method: *)
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let primitive_root_of_unity n =
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let rec root_iter guess =
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let newguess = csub guess (cdiv (csub guess
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(ipow_cnum guess (1 - n)))
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(Int n)) in
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if (almost_equal_cnum guess newguess) then newguess
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else root_iter newguess
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in let float_to_num f = (Int (truncate (f *. 1.0e9))) // (Int 1000000000)
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in root_iter (float_to_num (cos (twopi /. (float n))),
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float_to_num (sin (twopi /. (float n))))
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let cexp n i =
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if ((i mod n) == 0) then
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(one,zero)
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else
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let (n2,i2) = Util.lowest_terms n i
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in let (c,s) = ipow_cnum (primitive_root_of_unity n2) i2
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in (makeNum c, makeNum s)
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let to_konst (N n) =
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let f = float_of_num n in
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let f' = if f < 0.0 then f *. (-1.0) else f in
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let f2 = if (f' >= 1.0) then (f' -. (float (truncate f'))) else f'
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in let q = string_of_int (truncate(f2 *. 1.0E9))
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in let r = "0000000000" ^ q
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in let l = String.length r
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in let prefix = if (f < 0.0) then "KN" else "KP" in
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if (f' >= 1.0) then
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(prefix ^ (string_of_int (truncate f')) ^ "_" ^
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(String.sub r (l - 9) 9))
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else
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(prefix ^ (String.sub r (l - 9) 9))
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let to_string (N n) = approx_num_fix print_precision n
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let to_float (N n) = float_of_num n
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