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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
| author | Rik <octave@nomad.inbox5.com> |
|---|---|
| date | Mon, 13 Feb 2012 07:29:44 -0800 |
| parents | 11949c9795a0 |
| children | 86854d032a37 |
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## Copyright (C) 2008-2012 David Bateman ## ## 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} {} datetick () ## @deftypefnx {Function File} {} datetick (@var{form}) ## @deftypefnx {Function File} {} datetick (@var{axis}, @var{form}) ## @deftypefnx {Function File} {} datetick (@dots{}, "keeplimits") ## @deftypefnx {Function File} {} datetick (@dots{}, "keepticks") ## @deftypefnx {Function File} {} datetick (@dots{ax}, @dots{}) ## Add date formatted tick labels to an axis. The axis the apply the ## ticks to is determined by @var{axis} that can take the values "x", ## "y" or "z". The default value is "x". The formatting of the labels is ## determined by the variable @var{form}, that can either be a string in ## the format needed by @code{dateform}, or a positive integer that can ## be accepted by @code{datestr}. ## @seealso{datenum, datestr} ## @end deftypefn function datetick (varargin) [h, varargin, nargin] = __plt_get_axis_arg__ ("datetick", varargin{:}); oldh = gca (); unwind_protect axes (h); __datetick__ (varargin{:}); unwind_protect_cleanup axes (oldh); end_unwind_protect endfunction %!demo %! clf; %! yr = 1900:10:2000; %! pop = [76.094, 92.407, 106.461, 123.077 131.954, 151.868, 179.979, ... %! 203.984, 227.225, 249.623, 282.224]; %! plot (datenum (yr, 1, 1), pop); %! title ("US population (millions)"); %! xlabel ("Year"); %! datetick ("x", "YYYY"); %!demo %! clf; %! yr = 1988:2:2002; %! yr = datenum (yr,1,1); %! pr = [12.1 13.3 12.6 13.1 13.3 14.1 14.4 15.2]; %! plot (yr, pr); %! xlabel ("year"); %! ylabel ("average price"); %! ax = gca; %! set (ax, "xtick", datenum (1990:5:2005,1,1)); %! datetick (2, "keepticks"); %! set (ax, "ytick", 12:16); ## Remove from test statistics. No real tests possible. %!assert (1) function __datetick__ (varargin) keeplimits = false; keepticks = false; idx = []; for i = 1 : nargin arg = varargin {i}; if (ischar (arg)) if (strcmpi (arg, "keeplimits")) keeplimits = true; idx = [idx, i]; elseif (strcmpi (arg, "keepticks")) keepticks = true; idx = [idx, i]; endif endif endfor varargin(idx) = []; nargin = length (varargin); form = []; ax = "x"; if (nargin != 0) arg = varargin{1}; if (ischar (arg) && (strcmp (arg, "x") || strcmp (arg, "y") || strcmp (arg, "z"))) ax = arg; if (nargin > 1) form = varargin{2}; varargin(1:2) = []; else varargin(1) = []; endif else form = arg; varargin(1) = []; endif endif ## Don't publish the existence of this variable for use with dateaxis if (length (varargin) > 0) startdate = varargin{1}; else startdate = []; endif if (! isempty (form)) if (isnumeric (form)) if (! isscalar (form) || floor (form) != form || form < 0) error ("datetick: expecting FORM argument to be a positive integer"); endif elseif (! ischar (form)) error ("datetick: expecting valid date format string"); endif endif if (keepticks) ticks = get (gca (), strcat (ax, "tick")); else ## Need to do our own axis tick position calculation as ## year, etc, don't fallback on nice datenum values. objs = findall (gca()); xmax = NaN; xmin = NaN; for i = 1 : length (objs) fld = get (objs (i)); if (isfield (fld, strcat (ax, "data"))) xdata = getfield (fld, strcat (ax, "data"))(:); xmin = min (xmin, min (xdata)); xmax = max (xmax, max (xdata)); endif endfor if (isnan (xmin) || isnan (xmax)) xmin = 0; xmax = 1; elseif (xmin == xmax) xmax = xmin + 1; endif N = 3; if (xmax - xmin < N) ## Day scale or less if (xmax - xmin < N / 24 / 60 / 60) scl = 1 / 24 / 60 / 60; elseif (xmax - xmin < N / 24 / 6) scl = 1 / 24 / 60; else scl = 1 / 24; endif sep = __calc_tick_sep__ (xmin / scl , xmax / scl); xmin = sep * floor (xmin / scl / sep); xmax = sep * ceil (xmax / scl / sep); nticks = (xmax - xmin) / sep + 1; xmin *= scl; xmax *= scl; else [ymin, mmin, dmin] = datevec (xmin); [ymax, mmax, dmax] = datevec (xmax); minyear = ymin + (mmin - 1) / 12 + (dmin - 1) / 12 / 30; maxyear = ymax + (mmax - 1) / 12 + (dmax - 1) / 12 / 30; minmonth = mmin + (dmin - 1) / 30; maxmonth = (ymax - ymin) * 12 + mmax + (dmax - 1) / 30; if (maxmonth - minmonth < N) sep = __calc_tick_sep__ (xmin, xmax); xmin = sep * floor (xmin / sep); xmax = sep * ceil (xmax / sep); nticks = (xmax - xmin) / sep + 1; elseif (maxyear - minyear < N) sep = __calc_tick_sep__ (minmonth , maxmonth); xmin = datenum (ymin, sep * floor (minmonth / sep), 1); xmax = datenum (ymin, sep * ceil (maxmonth / sep), 1); nticks = ceil (maxmonth / sep) - floor (minmonth / sep) + 1; else sep = __calc_tick_sep__ (minyear , maxyear); xmin = datenum (sep * floor (minyear / sep), 1, 1); xmax = datenum (sep * ceil (maxyear / sep), 1, 1); nticks = ceil (maxyear / sep) - floor (minyear / sep) + 1; endif endif ticks = xmin + [0 : nticks - 1] / (nticks - 1) * (xmax - xmin); endif if (isempty (form)) r = max(ticks) - min(ticks); if r < 10/60/24 ## minutes and seconds form = 13; elseif r < 2 ## hours form = 15; elseif r < 15 ## days form = 8; elseif r < 365 ## FIXME -- FORM should be 19 for European users who use dd/mm ## instead of mm/dd. How can that be determined automatically? ## months form = 6; elseif r < 90*12 ## quarters form = 27; else ## years form = 10; endif endif if (length (ticks) == 6) ## Careful that its not treated as a datevec if (! isempty (startdate)) sticks = strvcat (datestr (ticks(1:end-1) - ticks(1) + startdate, form), datestr (ticks(end) - ticks(1) + startdate, form)); else sticks = strvcat (datestr (ticks(1:end-1), form), datestr (ticks(end), form)); endif else if (! isempty (startdate)) sticks = datestr (ticks - ticks(1) + startdate, form); else sticks = datestr (ticks, form); endif endif sticks = mat2cell (sticks, ones (rows (sticks), 1), columns (sticks)); if (keepticks) if (keeplimits) set (gca(), strcat (ax, "ticklabel"), sticks); else set (gca(), strcat (ax, "ticklabel"), sticks, strcat (ax, "lim"), [min(ticks), max(ticks)]); endif else if (keeplimits) set (gca(), strcat (ax, "tick"), ticks, strcat (ax, "ticklabel"), sticks); else set (gca(), strcat (ax, "tick"), ticks, strcat (ax, "ticklabel"), sticks, strcat (ax, "lim"), [min(ticks), max(ticks)]); endif endif endfunction function [a, b] = __magform__ (x) if (x == 0) a = 0; b = 0; else l = log10 (abs (x)); r = fmod (l, 1); a = 10 .^ r; b = fix (l - r); if (a < 1) a *= 10; b -= 1; endif if (x < 0) a = -a; endif endif endfunction ## A translation from Tom Holoryd's python code at ## http://kurage.nimh.nih.gov/tomh/tics.py function sep = __calc_tick_sep__ (lo, hi) persistent sqrt_2 = sqrt (2.0); persistent sqrt_10 = sqrt (10.0); persistent sqrt_50 = sqrt (50.0); ticint = 5; ## Reference: Lewart, C. R., "Algorithms SCALE1, SCALE2, and ## SCALE3 for Determination of Scales on Computer Generated ## Plots", Communications of the ACM, 10 (1973), 639-640. ## Also cited as ACM Algorithm 463. [a, b] = __magform__ ((hi - lo) / ticint); if (a < sqrt_2) x = 1; elseif (a < sqrt_10) x = 2; elseif (a < sqrt_50) x = 5; else x = 10; endif sep = x * 10 .^ b; endfunction