iup-stack/fftw/genfft/trig.ml

153 lines
4.0 KiB
OCaml

(*
* 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
*
*)
(* trigonometric transforms *)
open Util
(* DFT of real input *)
let rdft sign n input =
Fft.dft sign n (Complex.real @@ input)
(* DFT of hermitian input *)
let hdft sign n input =
Fft.dft sign n (Complex.hermitian n input)
(* DFT real transform of vectors of two real numbers,
multiplication by (NaN I), and summation *)
let dft_via_rdft sign n input =
let f = rdft sign n input
in fun i ->
Complex.plus
[Complex.real (f i);
Complex.times (Complex.nan Expr.I) (Complex.imag (f i))]
(* Discrete Hartley Transform *)
let dht sign n input =
let f = Fft.dft sign n (Complex.real @@ input) in
(fun i ->
Complex.plus [Complex.real (f i); Complex.imag (f i)])
let trigI n input =
let twon = 2 * n in
let input' = Complex.hermitian twon input
in
Fft.dft 1 twon input'
let interleave_zero input = fun i ->
if (i mod 2) == 0
then Complex.zero
else
input ((i - 1) / 2)
let trigII n input =
let fourn = 4 * n in
let input' = Complex.hermitian fourn (interleave_zero input)
in
Fft.dft 1 fourn input'
let trigIII n input =
let fourn = 4 * n in
let twon = 2 * n in
let input' = Complex.hermitian fourn
(fun i ->
if (i == 0) then
Complex.real (input 0)
else if (i == twon) then
Complex.uminus (Complex.real (input 0))
else
Complex.antihermitian twon input i)
in
let dft = Fft.dft 1 fourn input'
in fun k -> dft (2 * k + 1)
let zero_extend n input = fun i ->
if (i >= 0 && i < n)
then input i
else Complex.zero
let trigIV n input =
let fourn = 4 * n
and eightn = 8 * n in
let input' = Complex.hermitian eightn
(zero_extend fourn (Complex.antihermitian fourn
(interleave_zero input)))
in
let dft = Fft.dft 1 eightn input'
in fun k -> dft (2 * k + 1)
let make_dct scale nshift trig =
fun n input ->
trig (n - nshift) (Complex.real @@ (Complex.times scale) @@
(zero_extend n input))
(*
* DCT-I: y[k] = sum x[j] cos(pi * j * k / n)
*)
let dctI = make_dct Complex.one 1 trigI
(*
* DCT-II: y[k] = sum x[j] cos(pi * (j + 1/2) * k / n)
*)
let dctII = make_dct Complex.one 0 trigII
(*
* DCT-III: y[k] = sum x[j] cos(pi * j * (k + 1/2) / n)
*)
let dctIII = make_dct Complex.half 0 trigIII
(*
* DCT-IV y[k] = sum x[j] cos(pi * (j + 1/2) * (k + 1/2) / n)
*)
let dctIV = make_dct Complex.half 0 trigIV
let shift s input = fun i -> input (i - s)
(* DST-x input := TRIG-x (input / i) *)
let make_dst scale nshift kshift jshift trig =
fun n input ->
Complex.real @@
(shift (- jshift)
(trig (n + nshift) (Complex.uminus @@
(Complex.times Complex.i) @@
(Complex.times scale) @@
Complex.real @@
(shift kshift (zero_extend n input)))))
(*
* DST-I: y[k] = sum x[j] sin(pi * j * k / n)
*)
let dstI = make_dst Complex.one 1 1 1 trigI
(*
* DST-II: y[k] = sum x[j] sin(pi * (j + 1/2) * k / n)
*)
let dstII = make_dst Complex.one 0 0 1 trigII
(*
* DST-III: y[k] = sum x[j] sin(pi * j * (k + 1/2) / n)
*)
let dstIII = make_dst Complex.half 0 1 0 trigIII
(*
* DST-IV y[k] = sum x[j] sin(pi * (j + 1/2) * (k + 1/2) / n)
*)
let dstIV = make_dst Complex.half 0 0 0 trigIV