Use Octave coding conventions in all m-file %!test blocks * wavread.m, acosd.m, acot.m, acotd.m, acoth.m, acsc.m, acscd.m, acsch.m, asec.m, asecd.m, asech.m, asind.m, atand.m, cosd.m, cot.m, cotd.m, coth.m, csc.m, cscd.m, csch.m, sec.m, secd.m, sech.m, sind.m, tand.m, accumarray.m, accumdim.m, bitcmp.m, bitget.m, bitset.m, blkdiag.m, cart2pol.m, cart2sph.m, celldisp.m, chop.m, circshift.m, colon.m, common_size.m, cplxpair.m, cumtrapz.m, curl.m, dblquad.m, deal.m, divergence.m, flipdim.m, fliplr.m, flipud.m, genvarname.m, gradient.m, idivide.m, int2str.m, interp1.m, interp1q.m, interp2.m, interp3.m, interpft.m, interpn.m, isa.m, isdir.m, isequal.m, isequalwithequalnans.m, issquare.m, logspace.m, nargchk.m, narginchk.m, nargoutchk.m, nextpow2.m, nthargout.m, num2str.m, pol2cart.m, polyarea.m, postpad.m, prepad.m, profile.m, profshow.m, quadgk.m, quadv.m, randi.m, rat.m, repmat.m, rot90.m, rotdim.m, shift.m, shiftdim.m, sph2cart.m, structfun.m, trapz.m, triplequad.m, convhull.m, dsearch.m, dsearchn.m, griddata3.m, griddatan.m, rectint.m, tsearchn.m, __makeinfo__.m, doc.m, get_first_help_sentence.m, help.m, type.m, unimplemented.m, which.m, imread.m, imwrite.m, dlmwrite.m, fileread.m, is_valid_file_id.m, strread.m, textread.m, textscan.m, commutation_matrix.m, cond.m, condest.m, cross.m, duplication_matrix.m, expm.m, housh.m, isdefinite.m, ishermitian.m, issymmetric.m, logm.m, normest.m, null.m, onenormest.m, orth.m, planerot.m, qzhess.m, rank.m, rref.m, trace.m, vech.m, ans.m, bincoeff.m, bug_report.m, bzip2.m, comma.m, compare_versions.m, computer.m, edit.m, fileparts.m, fullfile.m, getfield.m, gzip.m, info.m, inputname.m, isappdata.m, isdeployed.m, ismac.m, ispc.m, isunix.m, list_primes.m, ls.m, mexext.m, namelengthmax.m, news.m, orderfields.m, paren.m, recycle.m, rmappdata.m, semicolon.m, setappdata.m, setfield.m, substruct.m, symvar.m, ver.m, version.m, warning_ids.m, xor.m, fminbnd.m, fsolve.m, fzero.m, lsqnonneg.m, optimset.m, pqpnonneg.m, sqp.m, matlabroot.m, __gnuplot_drawnow__.m, __plt_get_axis_arg__.m, ancestor.m, cla.m, clf.m, close.m, colorbar.m, colstyle.m, comet3.m, contourc.m, figure.m, gca.m, gcbf.m, gcbo.m, gcf.m, ginput.m, graphics_toolkit.m, gtext.m, hggroup.m, hist.m, hold.m, isfigure.m, ishghandle.m, ishold.m, isocolors.m, isonormals.m, isosurface.m, isprop.m, legend.m, line.m, loglog.m, loglogerr.m, meshgrid.m, ndgrid.m, newplot.m, orient.m, patch.m, plot3.m, plotyy.m, __print_parse_opts__.m, quiver3.m, refreshdata.m, ribbon.m, semilogx.m, semilogxerr.m, semilogy.m, stem.m, stem3.m, subplot.m, title.m, uigetfile.m, view.m, whitebg.m, compan.m, conv.m, deconv.m, mkpp.m, mpoles.m, pchip.m, poly.m, polyaffine.m, polyder.m, polyfit.m, polygcd.m, polyint.m, polyout.m, polyval.m, polyvalm.m, ppder.m, ppint.m, ppjumps.m, ppval.m, residue.m, roots.m, spline.m, intersect.m, ismember.m, powerset.m, setdiff.m, setxor.m, union.m, unique.m, autoreg_matrix.m, bartlett.m, blackman.m, detrend.m, fftconv.m, fftfilt.m, fftshift.m, freqz.m, hamming.m, hanning.m, ifftshift.m, sinc.m, sinetone.m, sinewave.m, unwrap.m, bicg.m, bicgstab.m, gmres.m, gplot.m, nonzeros.m, pcg.m, pcr.m, spaugment.m, spconvert.m, spdiags.m, speye.m, spfun.m, spones.m, sprand.m, sprandsym.m, spstats.m, spy.m, svds.m, treelayout.m, bessel.m, beta.m, betaln.m, factor.m, factorial.m, isprime.m, lcm.m, legendre.m, nchoosek.m, nthroot.m, perms.m, pow2.m, primes.m, reallog.m, realpow.m, realsqrt.m, hadamard.m, hankel.m, hilb.m, invhilb.m, magic.m, rosser.m, vander.m, __finish__.m, center.m, cloglog.m, corr.m, cov.m, gls.m, histc.m, iqr.m, kendall.m, kurtosis.m, logit.m, mahalanobis.m, mean.m, meansq.m, median.m, mode.m, moment.m, ols.m, ppplot.m, prctile.m, probit.m, quantile.m, range.m, ranks.m, run_count.m, runlength.m, skewness.m, spearman.m, statistics.m, std.m, table.m, var.m, zscore.m, betacdf.m, betainv.m, betapdf.m, betarnd.m, binocdf.m, binoinv.m, binopdf.m, binornd.m, cauchy_cdf.m, cauchy_inv.m, cauchy_pdf.m, cauchy_rnd.m, chi2cdf.m, chi2inv.m, chi2pdf.m, chi2rnd.m, discrete_cdf.m, discrete_inv.m, discrete_pdf.m, discrete_rnd.m, empirical_cdf.m, empirical_inv.m, empirical_pdf.m, empirical_rnd.m, expcdf.m, expinv.m, exppdf.m, exprnd.m, fcdf.m, finv.m, fpdf.m, frnd.m, gamcdf.m, gaminv.m, gampdf.m, gamrnd.m, geocdf.m, geoinv.m, geopdf.m, geornd.m, hygecdf.m, hygeinv.m, hygepdf.m, hygernd.m, kolmogorov_smirnov_cdf.m, laplace_cdf.m, laplace_inv.m, laplace_pdf.m, laplace_rnd.m, logistic_cdf.m, logistic_inv.m, logistic_pdf.m, logistic_rnd.m, logncdf.m, logninv.m, lognpdf.m, lognrnd.m, nbincdf.m, nbininv.m, nbinpdf.m, nbinrnd.m, normcdf.m, norminv.m, normpdf.m, normrnd.m, poisscdf.m, poissinv.m, poisspdf.m, poissrnd.m, stdnormal_cdf.m, stdnormal_inv.m, stdnormal_pdf.m, stdnormal_rnd.m, tcdf.m, tinv.m, tpdf.m, trnd.m, unidcdf.m, unidinv.m, unidpdf.m, unidrnd.m, unifcdf.m, unifinv.m, unifpdf.m, unifrnd.m, wblcdf.m, wblinv.m, wblpdf.m, wblrnd.m, kolmogorov_smirnov_test.m, kruskal_wallis_test.m, base2dec.m, bin2dec.m, blanks.m, cstrcat.m, deblank.m, dec2base.m, dec2bin.m, dec2hex.m, findstr.m, hex2dec.m, index.m, isletter.m, mat2str.m, rindex.m, str2num.m, strcat.m, strjust.m, strmatch.m, strsplit.m, strtok.m, strtrim.m, strtrunc.m, substr.m, validatestring.m, demo.m, example.m, fail.m, speed.m, addtodate.m, asctime.m, clock.m, ctime.m, date.m, datenum.m, datetick.m, datevec.m, eomday.m, etime.m, is_leap_year.m, now.m: Use Octave coding conventions in all m-file %!test blocks

## Copyright (C) 2009-2012 Søren Hauberg
## Copyright (C) 2009 VZLU Prague
##
## 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{n} =} histc (@var{x}, @var{edges})
## @deftypefnx {Function File} {@var{n} =} histc (@var{x}, @var{edges}, @var{dim})
## @deftypefnx {Function File} {[@var{n}, @var{idx}] =} histc (@dots{})
## Produce histogram counts.
##
## When @var{x} is a vector, the function counts the number of elements of
## @var{x} that fall in the histogram bins defined by @var{edges}.  This must be
## a vector of monotonically increasing values that define the edges of the
## histogram bins.  @code{@var{n}(k)} contains the number of elements in
## @var{x} for which @code{@var{edges}(k) <= @var{x} < @var{edges}(k+1)}.
## The final element of @var{n} contains the number of elements of @var{x}
## exactly equal to the last element of @var{edges}.
##
## When @var{x} is an @math{N}-dimensional array, the computation is
## carried out along dimension @var{dim}.  If not specified @var{dim} defaults
## to the first non-singleton dimension.
##
## When a second output argument is requested an index matrix is also returned.
## The @var{idx} matrix has the same size as @var{x}.  Each element of @var{idx}
## contains the index of the histogram bin in which the corresponding element
## of @var{x} was counted.
## @seealso{hist}
## @end deftypefn

function [n, idx] = histc (x, edges, dim)

  if (nargin < 2 || nargin > 3)
    print_usage ();
  endif

  if (!isreal (x))
    error ("histc: X argument must be real-valued, not complex");
  endif

  num_edges = numel (edges);
  if (num_edges == 0)
    error ("histc: EDGES must not be empty");
  endif

  if (!isreal (edges))
    error ("histc: EDGES must be real-valued, not complex");
  else
    ## Make sure 'edges' is sorted
    edges = edges(:);
    if (!issorted (edges) || edges(1) > edges(end))
      warning ("histc: edge values not sorted on input");
      edges = sort (edges);
    endif
  endif

  nd = ndims (x);
  sz = size (x);
  if (nargin < 3)
    ## Find the first non-singleton dimension.
    (dim = find (sz > 1, 1)) || (dim = 1);
  else
    if (!(isscalar (dim) && dim == fix (dim))
        || !(1 <= dim && dim <= nd))
      error ("histc: DIM must be an integer and a valid dimension");
    endif
  endif

  nsz = sz;
  nsz(dim) = num_edges;

  ## the splitting point is 3 bins

  if (num_edges <= 3)

    ## This is the O(M*N) algorithm.

    ## Allocate the histogram
    n = zeros (nsz);

    ## Allocate 'idx'
    if (nargout > 1)
      idx = zeros (sz);
    endif

    ## Prepare indices
    idx1 = cell (1, dim-1);
    for k = 1:length (idx1)
      idx1{k} = 1:sz(k);
    endfor
    idx2 = cell (length (sz) - dim);
    for k = 1:length (idx2)
      idx2{k} = 1:sz(k+dim);
    endfor

    ## Compute the histograms
    for k = 1:num_edges-1
      b = (edges (k) <= x & x < edges (k+1));
      n(idx1{:}, k, idx2{:}) = sum (b, dim);
      if (nargout > 1)
        idx(b) = k;
      endif
    endfor
    b = (x == edges (end));
    n(idx1{:}, num_edges, idx2{:}) = sum (b, dim);
    if (nargout > 1)
      idx(b) = num_edges;
    endif

  else

    ## This is the O(M*log(N) + N) algorithm.

    ## Look-up indices.
    idx = lookup (edges, x);
    ## Zero invalid ones (including NaNs). x < edges(1) are already zero.
    idx(! (x <= edges(end))) = 0;

    iidx = idx;

    ## In case of matrix input, we adjust the indices.
    if (! isvector (x))
      nl = prod (sz(1:dim-1));
      nn = sz(dim);
      nu = prod (sz(dim+1:end));
      if (nl != 1)
        iidx = (iidx-1) * nl;
        iidx += reshape (kron (ones (1, nn*nu), 1:nl), sz);
      endif
      if (nu != 1)
        ne =length (edges);
        iidx += reshape (kron (nl*ne*(0:nu-1), ones (1, nl*nn)), sz);
      endif
    endif

    ## Select valid elements.
    iidx = iidx(idx != 0);

    ## Call accumarray to sum the indexed elements.
    n = accumarray (iidx(:), 1, nsz);

  endif

endfunction


%!test
%! x = linspace (0, 10, 1001);
%! n = histc (x, 0:10);
%! assert (n, [repmat(100, 1, 10), 1]);

%!test
%! x = repmat (linspace (0, 10, 1001), [2, 1, 3]);
%! n = histc (x, 0:10, 2);
%! assert (n, repmat ([repmat(100, 1, 10), 1], [2, 1, 3]));

%!error histc ()
%!error histc (1)
%!error histc (1, 2, 3, 4)
%!error histc ([1:10 1+i], 2)
%!error histc (1:10, [])
%!error histc (1, 1, 3)