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imwrite: implement WriteMode option. * imwrite.m: document the new option WriteMode and possibility to write multipage images by passing a 4 dimensional matrix. * private/core_imwrite.m: perform input check for the quality option and the new writemode. Set defaults here and not on __magick_write__(). Give warning about the fact that writing of indexed images is not properly implemented. Change calling to ind2rgb() since it has been there and we no longer need workaround. Remove the different calls to __magick_read__() since we now have a single way to do it. Remove conversion of image types since we want to save what was actually given to us. * __magick_read__.cc (read_file): split from __magick_read__() into a separate function so it can be used by __magick_write__() when appending images to an existing file. (jpg_settings): remove function. It only checks for the quality option, which is now done by core_imwrite(). Plus, other formats support this option so it was moved into __magick_write__(). We should have functions for each option rather than per file format. (encode_map): comment whole function since it is never used and is unfinished work to implement writing of actual indexed images. (write_file): new function from part of previous write_image(). It is now the other side of read_file(). (write_image): remove function. Moved into __magick_write__(), the only function calling it. The part of writing moved into write_file(). (__magick_write__): removed most of input check which should be done by imwrite(). Removed all extra usage types. Options must be passed on a non-optional struct. Implement the Append option.
author Carnë Draug <carandraug@octave.org>
date Tue, 16 Jul 2013 17:29:45 +0100
parents b10a23fe80bb
children bc924baa2c4e
line wrap: on
line source

## Copyright (C) 1994-2012 John W. Eaton
##
## This file is part of Octave.
##
## Octave 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 3 of the License, or (at
## your option) any later version.
##
## Octave 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 Octave; see the file COPYING.  If not, see
## <http://www.gnu.org/licenses/>.

## -*- texinfo -*-
## @deftypefn  {Function File} {[@var{h}, @var{w}] =} freqz (@var{b}, @var{a}, @var{n}, "whole")
## @deftypefnx {Function File} {@var{h} =} freqz (@var{b}, @var{a}, @var{w})
## @deftypefnx {Function File} {[@dots{}] =} freqz (@dots{}, @var{Fs})
## @deftypefnx {Function File} {} freqz (@dots{})
## 
## Return the complex frequency response @var{h} of the rational IIR filter
## whose numerator and denominator coefficients are @var{b} and @var{a},
## respectively.  The response is evaluated at @var{n} angular frequencies
## between 0 and
## @ifnottex
##  2*pi.
## @end ifnottex
## @tex
##  $2\pi$.
## @end tex
##
## @noindent
## The output value @var{w} is a vector of the frequencies.
##
## If @var{a} is omitted, the denominator is assumed to be 1 (this
## corresponds to a simple FIR filter).
##
## If @var{n} is omitted, a value of 512 is assumed.
##
## For fastest computation, @var{n} should factor into a small number of
## small primes.
##
## If the fourth argument, "whole", is omitted the response is evaluated at
## frequencies between 0 and
## @ifnottex
##  pi.
## @end ifnottex
## @tex
##  $\pi$.
## @end tex
##
## @code{freqz (@var{b}, @var{a}, @var{w})}
##
## Evaluate the response at the specific frequencies in the vector @var{w}.
## The values for @var{w} are measured in radians.
##
## @code{[@dots{}] = freqz (@dots{}, @var{Fs})}
##
## Return frequencies in Hz instead of radians assuming a sampling rate
## @var{Fs}.  If you are evaluating the response at specific frequencies
## @var{w}, those frequencies should be requested in Hz rather than radians.
##
## @code{freqz (@dots{})}
##
## Plot the pass band, stop band and phase response of @var{h} rather
## than returning them.
## @end deftypefn

## Author: jwe ???

function [h_r, f_r] = freqz (b, a, n, region, Fs)

  if (nargin < 1 || nargin > 5)
    print_usage ();
  elseif (nargin == 1)
    ## Response of an FIR filter.
    a = n = region = Fs = [];
  elseif (nargin == 2)
    ## Response of an IIR filter
    n = region = Fs = [];
  elseif (nargin == 3)
    region = Fs = [];
  elseif (nargin == 4)
    Fs = [];
    if (! ischar (region) && ! isempty (region))
      Fs = region;
      region = [];
    endif
  endif

  if (isempty (b))
    b = 1;
  endif
  if (isempty (a))
    a = 1;
  endif
  if (isempty (n))
    n = 512;
  endif
  if (isempty (region))
    if (isreal (b) && isreal (a))
      region = "half";
    else
      region = "whole";
    endif
  endif
  if (isempty (Fs))
    if (nargout == 0)
      Fs = 2;
    else
      Fs = 2*pi;
    endif
  endif

  a = a(:);
  b = b(:);

  if (! isscalar (n))
    ## Explicit frequency vector given
    w = f = n;
    if (nargin == 4)
      ## Sampling rate Fs was specified
      w = 2*pi*f/Fs;
    endif
    k = max (length (b), length (a));
    hb = polyval (postpad (b, k), exp (j*w));
    ha = polyval (postpad (a, k), exp (j*w));
  else
    ## polyval(fliplr(P),exp(jw)) is O(p n) and fft(x) is O(n log(n)),
    ## where p is the order of the polynomial P.  For small p it
    ## would be faster to use polyval but in practice the overhead for
    ## polyval is much higher and the little bit of time saved isn't
    ## worth the extra code.
    k = max (length (b), length (a));
    if (k > n/2 && nargout == 0)
      ## Ensure a causal phase response.
      n = n * 2 .^ ceil (log2 (2*k/n));
    endif

    if (strcmp (region, "whole"))
      N = n;
    else
      N = 2*n;
    endif

    f = Fs * (0:n-1).' / N;

    pad_sz = N*ceil (k/N);
    b = postpad (b, pad_sz);
    a = postpad (a, pad_sz);

    hb = zeros (n, 1);
    ha = zeros (n, 1);

    for i = 1:N:pad_sz
      hb = hb + fft (postpad (b(i:i+N-1), N))(1:n);
      ha = ha + fft (postpad (a(i:i+N-1), N))(1:n);
    endfor

  endif

  h = hb ./ ha;

  if (nargout != 0)
    ## Return values and don't plot.
    h_r = h;
    f_r = f;
  else
    ## Plot and don't return values.
    freqz_plot (f, h);
  endif

endfunction


%!test # correct values and fft-polyval consistency
%! # butterworth filter, order 2, cutoff pi/2 radians
%! b = [0.292893218813452  0.585786437626905  0.292893218813452];
%! a = [1  0  0.171572875253810];
%! [h,w] = freqz (b,a,32);
%! assert (h(1),1,10*eps);
%! assert (abs (h(17)).^2,0.5,10*eps);
%! assert (h,freqz (b,a,w),10*eps); # fft should be consistent with polyval

%!test # whole-half consistency
%! b = [1 1 1]/3; # 3-sample average
%! [h,w] = freqz (b,1,32,"whole");
%! assert (h(2:16),conj (h(32:-1:18)),20*eps);
%! [h2,w2] = freqz (b,1,16,"half");
%! assert (h(1:16),h2,20*eps);
%! assert (w(1:16),w2,20*eps);

%!test # Sampling frequency properly interpreted
%! b = [1 1 1]/3; a = [1 0.2];
%! [h,f] = freqz (b,a,16,320);
%! assert (f,[0:15]'*10,10*eps);
%! [h2,f2] = freqz (b,a,[0:15]*10,320);
%! assert (f2,[0:15]*10,10*eps);
%! assert (h,h2.',20*eps);
%! [h3,f3] = freqz (b,a,32,"whole",320);
%! assert (f3,[0:31]'*10,10*eps);