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75a5107c96
Signed-off-by: Francois Gouget <fgouget@codeweavers.com> Signed-off-by: Alexandre Julliard <julliard@winehq.org>
157 lines
4.9 KiB
Perl
Executable file
157 lines
4.9 KiB
Perl
Executable file
#! /usr/bin/perl -w
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#
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# DirectSound
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#
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# Copyright 2011-2012 Alexander E. Patrakov
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#
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# This library is free software; you can redistribute it and/or
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# modify it under the terms of the GNU Lesser General Public
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# License as published by the Free Software Foundation; either
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# version 2.1 of the License, or (at your option) any later version.
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#
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# This library 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 GNU
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# Lesser General Public License for more details.
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#
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# You should have received a copy of the GNU Lesser General Public
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# License along with this library; if not, write to the Free Software
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# Foundation, Inc., 51 Franklin St, Fifth Floor, Boston, MA 02110-1301, USA
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use strict;
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use Math::Trig;
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# This program generates an array of Finite Impulse Response (FIR) filter
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# values for use in resampling audio.
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#
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# Values are based on the resampler from Windows XP at the default (best)
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# quality, reverse engineered by saving kvm output to a wav file.
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# Controls how sharp the transition between passband and stopband is.
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# The transition bandwidth is approximately (1 / exp_width) of the
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# Nyquist frequency.
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my $exp_width = 41.0;
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# Controls the stopband attenuation. It is related but not proportional
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# to exp(-(PI * lobes_per_wing / exp_width) ^2) / lobes_per_wing
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my $lobes_per_wing = 28;
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# Controls the position of the transition band and thus attenuation at the
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# Nyquist frequency and above. Amended below so that the length of the FIR is
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# an integer. Essentially, this controls the trade-off between good rejection
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# of unrepresentable frequencies (those above half of the lower of the sample
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# rates) and not rejecting the wanted ones. Windows XP errs on the side of
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# letting artifacts through, which somewhat makes sense if they are above
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# 20 kHz anyway, or in the case of upsampling, where we can assume that the
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# problematic frequencies are not in the input. This, however, doesn't match
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# what linux resamplers do - so set this to 0.85 to match them. 0.98 would
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# give Windows XP behaviour.
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my $approx_bandwidth = 0.85;
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# The amended value will be stored here
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my $bandwidth;
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# The number of points per time unit equal to one period of the original
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# Nyquist frequency. The more points, the less interpolation error is.
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my $fir_step = 120;
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# Here x is measured in half-periods of the lower sample rate
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sub fir_val($)
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{
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my ($x) = @_;
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$x *= pi * $bandwidth;
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my $s = $x / $exp_width;
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my $sinc = $x ? (sin($x) / $x) : 1.0;
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my $gauss = exp(-($s * $s));
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return $sinc * $gauss;
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}
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# Linear interpolation
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sub mlinear($$$)
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{
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my ($y1, $y2, $mu) = @_;
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return $y1 * (1.0 - $mu) + $y2 * $mu;
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}
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# to_db, for printing decibel values
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sub to_db($) {
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my ($x) = @_;
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return 20.0 * log(abs($x))/log(10.0);
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}
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my $wing_len = int($lobes_per_wing / $approx_bandwidth * $fir_step + 1);
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$bandwidth = 1.0 * $lobes_per_wing / $wing_len;
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my $amended_bandwidth = $bandwidth * $fir_step;
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my $fir_len = 2 * $wing_len + 1;
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my @fir;
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# Constructing the FIR is easy
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for (my $i = 0; $i < $fir_len; $i++) {
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push @fir, fir_val($i - $wing_len);
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}
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# Now we have to test it and print some statistics to stderr.
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# Test 0: FIR size
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print STDERR "size: $fir_len\n";
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# Test 1: Interpolation noise. It should be less than -90 dB.
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# If you suspect that 0.5 is special due to some symmetry and thus yields
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# an abnormally low noise figure, change it. But really, it isn't special.
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my $testpoint = 0.5;
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my $exact_val = fir_val($testpoint);
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my $lin_approx_val = mlinear($fir[$wing_len], $fir[$wing_len + 1],
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$testpoint);
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my $lin_error_db = to_db($exact_val - $lin_approx_val);
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printf STDERR "interpolation noise: %1.2f dB\n", $lin_error_db;
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# Test 2: Passband and stopband.
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# The filter gain, ideally, should be 0.00 dB below the Nyquist
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# frequency and -inf dB above it. But it is impossible. So
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# let's settle for -80 dB above 1.08 * f_Nyquist.
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my $sum = 0.0;
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$sum += $_ for @fir;
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# Frequencies in this list are expressed as fractions
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# of the Nyquist frequency.
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my @testfreqs = (0.5, 0.8, 1.0, 1.08, 1.18, 1.33, 1.38);
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foreach my $testfreq(@testfreqs) {
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my $dct_coeff = 0.0;
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for (my $i = 0; $i < $fir_len; $i++) {
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my $x = 1.0 * ($i - $wing_len) / $fir_step;
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$dct_coeff += $fir[$i] * cos($x * $testfreq * pi);
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}
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printf STDERR "DCT: %1.2f -> %1.2f dB\n",
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$testfreq, to_db($dct_coeff / $sum);
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}
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# Now actually print the FIR to a C header file
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open FILE, ">", "fir.h";
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select FILE;
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print "/* generated by tools/make_fir; DO NOT EDIT! */\n";
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print "static const int fir_len = $fir_len;\n";
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print "static const int fir_step = $fir_step;\n";
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print "static const float fir[] = {\n";
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for (my $i = 0; $i < $fir_len; $i++) {
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printf "%10.10f", $amended_bandwidth * $fir[$i];
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if ($i == $fir_len - 1) {
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print "\n";
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} elsif (($i + 1) % 5 == 0) {
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print ",\n";
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} else {
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print ", ";
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}
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}
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print "};\n";
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