Mercurial > hg > octave-nkf
view scripts/testfun/assert.m @ 20579:131ce8cfaa80
Relax input in functions that convert between colorspaces (bug #45456)
* scripts/image/hsv2rgb.m, scripts/image/ntsc2rgb.m, scripts/image/rgb2hsv.m,
scripts/image/rgb2ntsc.m: remove all input check and leave it up to new
private functions handled by all. This adds support for ND images, drops
check for values in the [0 1] range, allows integer images, and allows
sparse matrices. Also adjust tests and add extra ones.
* scripts/image/private/colorspace_conversion_input_check.m,
scripts/image/private/colorspace_conversion_revert.m: all of this functions
handle input check in the same way. In the same way, they need to prepare
the output in the same way based on what preparation was done during input
check (transforming image into colormap). So we create two new private
functions to avoid repeated code. All code was adapted from hsv2rgb.
| author | Carnë Draug <carandraug@octave.org> |
|---|---|
| date | Sun, 19 Jul 2015 17:41:21 +0100 |
| parents | aa36fb998a4d |
| children |
line wrap: on
line source
## Copyright (C) 2000-2015 Paul Kienzle ## ## 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} {} assert (@var{cond}) ## @deftypefnx {Function File} {} assert (@var{cond}, @var{errmsg}) ## @deftypefnx {Function File} {} assert (@var{cond}, @var{errmsg}, @dots{}) ## @deftypefnx {Function File} {} assert (@var{cond}, @var{msg_id}, @var{errmsg}, @dots{}) ## @deftypefnx {Function File} {} assert (@var{observed}, @var{expected}) ## @deftypefnx {Function File} {} assert (@var{observed}, @var{expected}, @var{tol}) ## ## Produce an error if the specified condition is not met. ## ## @code{assert} can be called in three different ways. ## ## @table @code ## @item assert (@var{cond}) ## @itemx assert (@var{cond}, @var{errmsg}) ## @itemx assert (@var{cond}, @var{errmsg}, @dots{}) ## @itemx assert (@var{cond}, @var{msg_id}, @var{errmsg}, @dots{}) ## Called with a single argument @var{cond}, @code{assert} produces an error if ## @var{cond} is false (numeric zero). ## ## Any additional arguments are passed to the @code{error} function for ## processing. ## ## @item assert (@var{observed}, @var{expected}) ## Produce an error if observed is not the same as expected. ## ## Note that @var{observed} and @var{expected} can be scalars, vectors, ## matrices, strings, cell arrays, or structures. ## ## @item assert (@var{observed}, @var{expected}, @var{tol}) ## Produce an error if observed is not the same as expected but equality ## comparison for numeric data uses a tolerance @var{tol}. ## ## If @var{tol} is positive then it is an absolute tolerance which will produce ## an error if @code{abs (@var{observed} - @var{expected}) > abs (@var{tol})}. ## ## If @var{tol} is negative then it is a relative tolerance which will produce ## an error if @code{abs (@var{observed} - @var{expected}) > ## abs (@var{tol} * @var{expected})}. ## ## If @var{expected} is zero @var{tol} will always be interpreted as an ## absolute tolerance. ## ## If @var{tol} is not scalar its dimensions must agree with those of ## @var{observed} and @var{expected} and tests are performed on an ## element-by-element basis. ## @end table ## @seealso{fail, test, error, isequal} ## @end deftypefn function assert (cond, varargin) if (nargin == 0) print_usage (); endif persistent call_depth = -1; persistent errmsg; unwind_protect call_depth++; if (call_depth == 0) errmsg = ""; endif if (nargin == 1 || (nargin > 1 && islogical (cond) && ischar (varargin{1}))) if ((! isnumeric (cond) && ! islogical (cond)) || isempty (cond) || ! all (cond(:))) if (nargin == 1) ## Perhaps, say which elements failed? argin = ["(" strjoin(cellstr (argn), ",") ")"]; error ("assert %s failed", argin); else error (varargin{:}); endif endif else expected = varargin{1}; if (nargin < 3) tol = 0; elseif (nargin == 3) tol = varargin{2}; else print_usage (); endif ## Add to list as the errors accumulate. If empty at end then no errors. err.index = {}; err.observed = {}; err.expected = {}; err.reason = {}; if (ischar (expected)) if (! ischar (cond)) err.index{end+1} = "."; err.expected{end+1} = expected; if (isnumeric (cond)) err.observed{end+1} = num2str (cond); err.reason{end+1} = "Expected string, but observed number"; else err.observed{end+1} = "O"; err.reason{end+1} = ["Expected string, but observed " class(cond)]; endif elseif (! strcmp (cond, expected)) err.index{end+1} = "[]"; err.observed{end+1} = cond; err.expected{end+1} = expected; err.reason{end+1} = "Strings don't match"; endif elseif (iscell (expected)) if (! iscell (cond)) err.index{end+1} = "."; err.observed{end+1} = "O"; err.expected{end+1} = "E"; err.reason{end+1} = ["Expected cell, but observed " class(cond)]; elseif (ndims (cond) != ndims (expected) || any (size (cond) != size (expected))) err.index{end+1} = "."; err.observed{end+1} = ["O(" sprintf("%dx", size(cond))(1:end-1) ")"]; err.expected{end+1} = ["E(" sprintf("%dx", size(expected))(1:end-1) ")"]; err.reason{end+1} = "Dimensions don't match"; else try ## Recursively compare cell arrays for i = 1:length (expected(:)) assert (cond{i}, expected{i}, tol); endfor catch err.index{end+1} = "{}"; err.observed{end+1} = "O"; err.expected{end+1} = "E"; err.reason{end+1} = "Cell configuration error"; end_try_catch endif elseif (is_function_handle (expected)) if (! is_function_handle (cond)) err.index{end+1} = "@"; err.observed{end+1} = "O"; err.expected{end+1} = "E"; err.reason{end+1} = ["Expected function handle, but observed " class(cond)]; elseif (! isequal (cond, expected)) err.index{end+1} = "@"; err.observed{end+1} = "O"; err.expected{end+1} = "E"; err.reason{end+1} = "Function handles don't match"; endif elseif (isstruct (expected)) if (! isstruct (cond)) err.index{end+1} = "."; err.observed{end+1} = "O"; err.expected{end+1} = "E"; err.reason{end+1} = ["Expected struct, but observed " class(cond)]; elseif (ndims (cond) != ndims (expected) || any (size (cond) != size (expected)) || numfields (cond) != numfields (expected)) err.index{end+1} = "."; err.observed{end+1} = ["O(" sprintf("%dx", size(cond))(1:end-1) ")"]; err.expected{end+1} = ["E(" sprintf("%dx", size(expected))(1:end-1) ")"]; err.reason{end+1} = "Structure sizes don't match"; else try empty = isempty (cond); normal = (numel (cond) == 1); for [v, k] = cond if (! isfield (expected, k)) err.index{end+1} = "."; err.observed{end+1} = "O"; err.expected{end+1} = "E"; err.reason{end+1} = ["'" k "'" " is not an expected field"]; endif if (empty) v = {}; elseif (normal) v = {v}; else v = v(:)'; endif ## Recursively call assert for struct array values assert (v, {expected.(k)}, tol); endfor catch err.index{end+1} = "."; err.observed{end+1} = "O"; err.expected{end+1} = "E"; err.reason{end+1} = "Structure configuration error"; end_try_catch endif elseif (ndims (cond) != ndims (expected) || any (size (cond) != size (expected))) err.index{end+1} = "."; err.observed{end+1} = ["O(" sprintf("%dx", size(cond))(1:end-1) ")"]; err.expected{end+1} = ["E(" sprintf("%dx", size(expected))(1:end-1) ")"]; err.reason{end+1} = "Dimensions don't match"; else # Numeric comparison if (nargin < 3) ## Without explicit tolerance, be more strict. if (! strcmp (class (cond), class (expected))) err.index{end+1} = "()"; err.observed{end+1} = "O"; err.expected{end+1} = "E"; err.reason{end+1} = ["Class " class(cond) " != " class(expected)]; elseif (isnumeric (cond)) if (issparse (cond) != issparse (expected)) err.index{end+1} = "()"; err.observed{end+1} = "O"; err.expected{end+1} = "E"; if (issparse (cond)) err.reason{end+1} = "sparse != non-sparse"; else err.reason{end+1} = "non-sparse != sparse"; endif elseif (iscomplex (cond) != iscomplex (expected)) err.index{end+1} = "()"; err.observed{end+1} = "O"; err.expected{end+1} = "E"; if (iscomplex (cond)) err.reason{end+1} = "complex != real"; else err.reason{end+1} = "real != complex"; endif endif endif endif if (isempty (err.index)) A = cond; B = expected; ## Check exceptional values. errvec = ( isna (real (A)) != isna (real (B)) | isna (imag (A)) != isna (imag (B))); erridx = find (errvec); if (! isempty (erridx)) err.index(end+1:end+length (erridx)) = ... ind2tuple (size (A), erridx); err.observed(end+1:end+length (erridx)) = ... strtrim (cellstr (num2str (A(erridx) (:)))); err.expected(end+1:end+length (erridx)) = ... strtrim (cellstr (num2str (B(erridx) (:)))); err.reason(end+1:end+length (erridx)) = ... repmat ({"'NA' mismatch"}, length (erridx), 1); endif errseen = errvec; errvec = ( isnan (real (A)) != isnan (real (B)) | isnan (imag (A)) != isnan (imag (B))); erridx = find (errvec & !errseen); if (! isempty (erridx)) err.index(end+1:end+length (erridx)) = ... ind2tuple (size (A), erridx); err.observed(end+1:end+length (erridx)) = ... strtrim (cellstr (num2str (A(erridx) (:)))); err.expected(end+1:end+length (erridx)) = ... strtrim (cellstr (num2str (B(erridx) (:)))); err.reason(end+1:end+length (erridx)) = ... repmat ({"'NaN' mismatch"}, length (erridx), 1); endif errseen |= errvec; errvec = ((isinf (real (A)) | isinf (real (B))) ... & (real (A) != real (B))) ... | ((isinf (imag (A)) | isinf (imag (B))) ... & (imag (A) != imag (B))); erridx = find (errvec & !errseen); if (! isempty (erridx)) err.index(end+1:end+length (erridx)) = ... ind2tuple (size (A), erridx); err.observed(end+1:end+length (erridx)) = ... strtrim (cellstr (num2str (A(erridx) (:)))); err.expected(end+1:end+length (erridx)) = ... strtrim (cellstr (num2str (B(erridx) (:)))); err.reason(end+1:end+length (erridx)) = ... repmat ({"'Inf' mismatch"}, length (erridx), 1); endif errseen |= errvec; ## Check normal values. ## Replace exceptional values already checked above by zero. A_null_real = real (A); B_null_real = real (B); exclude = errseen ... | ! isfinite (A_null_real) & ! isfinite (B_null_real); A_null_real(exclude) = 0; B_null_real(exclude) = 0; A_null_imag = imag (A); B_null_imag = imag (B); exclude = errseen ... | ! isfinite (A_null_imag) & ! isfinite (B_null_imag); A_null_imag(exclude) = 0; B_null_imag(exclude) = 0; A_null = complex (A_null_real, A_null_imag); B_null = complex (B_null_real, B_null_imag); if (isscalar (tol)) mtol = tol * ones (size (A)); else mtol = tol; endif k = (mtol == 0); erridx = find ((A_null != B_null) & k); if (! isempty (erridx)) err.index(end+1:end+length (erridx)) = ... ind2tuple (size (A), erridx); err.observed(end+1:end+length (erridx)) = ... strtrim (cellstr (num2str (A(erridx) (:)))); err.expected(end+1:end+length (erridx)) = ... strtrim (cellstr (num2str (B(erridx) (:)))); err.reason(end+1:end+length (erridx)) = ... ostrsplit (deblank (sprintf ("Abs err %.5g exceeds tol %.5g\n",... [abs(A_null(erridx) - B_null(erridx))(:) mtol(erridx)(:)]')), "\n"); endif k = (mtol > 0); erridx = find ((abs (A_null - B_null) > mtol) & k); if (! isempty (erridx)) err.index(end+1:end+length (erridx)) = ... ind2tuple (size (A), erridx); err.observed(end+1:end+length (erridx)) = ... strtrim (cellstr (num2str (A(erridx) (:)))); err.expected(end+1:end+length (erridx)) = ... strtrim (cellstr (num2str (B(erridx) (:)))); err.reason(end+1:end+length (erridx)) = ... ostrsplit (deblank (sprintf ("Abs err %.5g exceeds tol %.5g\n",... [abs(A_null(erridx) - B_null(erridx))(:) mtol(erridx)(:)]')), "\n"); endif k = (mtol < 0); if (any (k(:))) ## Test for absolute error where relative error can't be calculated. erridx = find ((B_null == 0) & abs (A_null) > abs (mtol) & k); if (! isempty (erridx)) err.index(end+1:end+length (erridx)) = ... ind2tuple (size (A), erridx); err.observed(end+1:end+length (erridx)) = ... strtrim (cellstr (num2str (A(erridx) (:)))); err.expected(end+1:end+length (erridx)) = ... strtrim (cellstr (num2str (B(erridx) (:)))); err.reason(end+1:end+length (erridx)) = ... ostrsplit (deblank (sprintf ("Abs err %.5g exceeds tol %.5g\n", [abs(A_null(erridx) - B_null(erridx)) -mtol(erridx)]')), "\n"); endif ## Test for relative error Bdiv = Inf (size (B_null)); Bdiv(k & (B_null != 0)) = B_null(k & (B_null != 0)); relerr = abs ((A_null - B_null) ./ abs (Bdiv)); erridx = find ((relerr > abs (mtol)) & k); if (! isempty (erridx)) err.index(end+1:end+length (erridx)) = ... ind2tuple (size (A), erridx); err.observed(end+1:end+length (erridx)) = ... strtrim (cellstr (num2str (A(erridx) (:)))); err.expected(end+1:end+length (erridx)) = ... strtrim (cellstr (num2str (B(erridx) (:)))); err.reason(end+1:end+length (erridx)) = ... ostrsplit (deblank (sprintf ("Rel err %.5g exceeds tol %.5g\n", [relerr(erridx)(:) -mtol(erridx)(:)]')), "\n"); endif endif endif endif ## Print any errors if (! isempty (err.index)) argin = ["(" strjoin(cellstr (argn), ",") ")"]; if (! isempty (errmsg)) errmsg = [errmsg "\n"]; endif errmsg = [errmsg, pprint(argin, err)]; endif endif unwind_protect_cleanup call_depth--; end_unwind_protect if (call_depth == -1) ## Last time through. If there were any errors on any pass, raise a flag. if (! isempty (errmsg)) error (errmsg); endif endif endfunction ## empty input %!error assert ([]) %!error assert ("") %!error assert ({}) %!error assert (struct ([])) %!assert (zeros (3,0), zeros (3,0)) %!error <O\(3x0\)\s+E\(0x2\)> assert (zeros (3,0), zeros (0,2)) %!error <Dimensions don't match> assert (zeros (3,0), []) %!error <Dimensions don't match> assert (zeros (2,0,2), zeros (2,0)) ## conditions %!assert (isempty ([])) %!assert (1) %!error assert (0) %!assert (ones (3,1)) %!assert (ones (1,3)) %!assert (ones (3,4)) %!error assert ([1,0,1]) %!error assert ([1;1;0]) %!error assert ([1,0;1,1]) %!error <2-part error> assert (false, "%s %s", "2-part", "error") %!error <2-part error> assert (false, "TST:msg_id", "%s %s", "2-part", "error") ## scalars %!error <Dimensions don't match> assert (3, [3,3]) %!error <Dimensions don't match> assert (3, [3,3; 3,3]) %!error <Dimensions don't match> assert ([3,3; 3,3], 3) %!assert (3, 3) %!error <Abs err 1 exceeds tol> assert (3, 4) %!assert (3+eps, 3, eps) %!assert (3, 3+eps, eps) %!error <Abs err 4.4409e-0?16 exceeds tol> assert (3+2*eps, 3, eps) %!error <Abs err 4.4409e-0?16 exceeds tol> assert (3, 3+2*eps, eps) ## vectors %!assert ([1,2,3],[1,2,3]); %!assert ([1;2;3],[1;2;3]); %!error <Abs err 1 exceeds tol 0> assert ([2,2,3,3],[1,2,3,4]); %!error <Abs err 1 exceeds tol 0.5> assert ([2,2,3,3],[1,2,3,4],0.5); %!error <Rel err 1 exceeds tol 0.1> assert ([2,2,3,5],[1,2,3,4],-0.1); %!error <Abs err 1 exceeds tol 0> assert ([6;6;7;7],[5;6;7;8]); %!error <Abs err 1 exceeds tol 0.5> assert ([6;6;7;7],[5;6;7;8],0.5); %!error <Rel err .* exceeds tol 0.1> assert ([6;6;7;7],[5;6;7;8],-0.1); %!error <Dimensions don't match> assert ([1,2,3],[1;2;3]); %!error <Dimensions don't match> assert ([1,2],[1,2,3]); %!error <Dimensions don't match> assert ([1;2;3],[1;2]); ## matrices %!assert ([1,2;3,4],[1,2;3,4]); %!error <\(1,2\)\s+4\s+2> assert ([1,4;3,4],[1,2;3,4]) %!error <Dimensions don't match> assert ([1,3;2,4;3,5],[1,2;3,4]) %!test # 2-D matrix %! A = [1 2 3]'*[1,2]; %! assert (A, A); %! fail ("assert (A.*(A!=2),A)"); %!test # N-D matrix %! X = zeros (2,2,3); %! Y = X; %! Y(1,2,3) = 1.5; %! fail ("assert (X,Y)", "\(1,2,3\).*Abs err 1.5 exceeds tol 0"); ## must give a small tolerance for floating point errors on relative %!assert (100+100*eps, 100, -2*eps) %!assert (100, 100+100*eps, -2*eps) %!error <Rel err .* exceeds tol> assert (100+300*eps, 100, -2*eps) %!error <Rel err .* exceeds tol> assert (100, 100+300*eps, -2*eps) ## test relative vs. absolute tolerances %!test assert (0.1+eps, 0.1, 2*eps); %!error <Rel err 2.2204e-0?15 exceeds tol> assert (0.1+eps, 0.1, -2*eps); %!test assert (100+100*eps, 100, -2*eps); %!error <Abs err 2.8422e-0?14 exceeds tol> assert (100+100*eps, 100, 2*eps); ## Corner case of relative tolerance with 0 divider %!error <Abs err 2 exceeds tol 0.1> assert (2, 0, -0.1) ## Extra checking of inputs when tolerance unspecified. %!error <Class single != double> assert (single (1), 1) %!error <Class uint8 != uint16> assert (uint8 (1), uint16 (1)) %!error <sparse != non-sparse> assert (sparse([1]), [1]) %!error <non-sparse != sparse> assert ([1], sparse([1])) %!error <complex != real> assert (1+i, 1) %!error <real != complex> assert (1, 1+i) ## exceptional values %!assert ([NaN, NA, Inf, -Inf, 1+eps, eps], [NaN, NA, Inf, -Inf, 1, 0], eps) %!error <'NaN' mismatch> assert (NaN, 1) %!error <'NaN' mismatch> assert ([NaN 1], [1 NaN]) %!test %! try %! assert ([NaN 1], [1 NaN]); %! catch %! errmsg = lasterr (); %! if (sum (errmsg () == "\n") != 4) %! error ("Too many errors reported for NaN assert"); %! elseif (strfind (errmsg, "NA")) %! error ("NA reported for NaN assert"); %! elseif (strfind (errmsg, "Abs err NaN exceeds tol 0")) %! error ("Abs err reported for NaN assert"); %! endif %! end_try_catch %!error <'NA' mismatch> assert (NA, 1) %!error assert ([NA 1]', [1 NA]') %!test %! try %! assert ([NA 1]', [1 NA]'); %! catch %! errmsg = lasterr (); %! if (sum (errmsg () == "\n") != 4) %! error ("Too many errors reported for NA assert"); %! elseif (strfind (errmsg, "NaN")) %! error ("NaN reported for NA assert"); %! elseif (strfind (errmsg, "Abs err NA exceeds tol 0")) %! error ("Abs err reported for NA assert"); %! endif %! end_try_catch %!error assert ([(complex (NA, 1)) (complex (2, NA))], [(complex (NA, 2)) 2]) %!error <'Inf' mismatch> assert (-Inf, Inf) %!error <'Inf' mismatch> assert ([-Inf Inf], [Inf -Inf]) %!test %! try %! assert (complex (Inf, 0.2), complex (-Inf, 0.2 + 2*eps), eps); %! catch %! errmsg = lasterr (); %! if (sum (errmsg () == "\n") != 3) %! error ("Too many errors reported for Inf assert"); %! elseif (strfind (errmsg, "Abs err")) %! error ("Abs err reported for Inf assert"); %! endif %! end_try_catch %!error <Abs err> assert (complex (Inf, 0.2), complex (Inf, 0.2 + 2*eps), eps) ## strings %!assert ("dog", "dog") %!error <Strings don't match> assert ("dog", "cat") %!error <Expected string, but observed number> assert (3, "dog") %!error <Class char != double> assert ("dog", [3 3 3]) %!error <Expected string, but observed cell> assert ({"dog"}, "dog") %!error <Expected string, but observed struct> assert (struct ("dog", 3), "dog") ## cell arrays %!error <Expected cell, but observed double> assert (1, {1}) %!error <Dimensions don't match> assert (cell (1,2,3), cell (3,2,1)) %!test %! x = {{{1}}, 2}; # cell with multiple levels %! y = x; %! assert (x,y); %! y{1}{1}{1} = 3; %! fail ("assert (x,y)", "Abs err 2 exceeds tol 0"); ## function handles %!assert (@sin, @sin) %!error <Function handles don't match> assert (@sin, @cos) %!error <Expected function handle, but observed double> assert (pi, @cos) %!error <Class function_handle != double> assert (@sin, pi) %!test %! x = {[3], [1,2,3]; 100+100*eps, "dog"}; %! y = x; %! assert (x, y); %! y = x; y(1,1) = [2]; %! fail ("assert (x, y)"); %! y = x; y(1,2) = [0, 2, 3]; %! fail ("assert (x, y)"); %! y = x; y(2,1) = 101; %! fail ("assert (x, y)"); %! y = x; y(2,2) = "cat"; %! fail ("assert (x, y)"); %! y = x; y(1,1) = [2]; y(1,2) = [0, 2, 3]; y(2,1) = 101; y(2,2) = "cat"; %! fail ("assert (x, y)"); ## structures %!error <Expected struct, but observed double> assert (1, struct ("a", 1)) %!error <Structure sizes don't match> %! x(1,2,3).a = 1; %! y(1,2).a = 1; %! assert (x,y); %!error <Structure sizes don't match> %! x(1,2,3).a = 1; %! y(3,2,2).a = 1; %! assert (x,y); %!error <Structure sizes don't match> %! x.a = 1; %! x.b = 1; %! y.a = 1; %! assert (x,y); %!error <'b' is not an expected field> %! x.b = 1; %! y.a = 1; %! assert (x,y); %!test %! x.a = 1; x.b=[2, 2]; %! y.a = 1; y.b=[2, 2]; %! assert (x, y); %! y.b=3; %! fail ("assert (x, y)"); %! fail ("assert (3, x)"); %! fail ("assert (x, 3)"); %! ## Empty structures %! x = resize (x, 0, 1); %! y = resize (y, 0, 1); %! assert (x, y); ## vector of tolerances %!test %! x = [-40:0]; %! y1 = (10.^x).*(10.^x); %! y2 = 10.^(2*x); %! assert (y1, y2, eps (y1)); %! fail ("assert (y1, y2 + eps*1e-70, eps (y1))"); ## Multiple tolerances %!test %! x = [1 2; 3 4]; %! y = [0 -1; 1 2]; %! tol = [-0.1 0; -0.2 0.3]; %! try %! assert (x, y, tol); %! catch %! errmsg = lasterr (); %! if (sum (errmsg () == "\n") != 6) %! error ("Incorrect number of errors reported"); %! endif %! assert (! isempty (regexp (errmsg, '\(1,2\).*Abs err 3 exceeds tol 0\>'))); %! assert (! isempty (regexp (errmsg, '\(2,2\).*Abs err 2 exceeds tol 0.3'))); %! assert (! isempty (regexp (errmsg, '\(1,1\).*Abs err 1 exceeds tol 0.1'))); %! assert (! isempty (regexp (errmsg, '\(2,1\).*Rel err 2 exceeds tol 0.2'))); %! end_try_catch ## test input validation %!error assert () %!error assert (1,2,3,4) ## Convert all error indices into tuple format function cout = ind2tuple (matsize, erridx) cout = cell (numel (erridx), 1); tmp = cell (1, numel (matsize)); [tmp{:}] = ind2sub (matsize, erridx(:)); subs = [tmp{:}]; if (numel (matsize) == 2) subs = subs(:, matsize != 1); endif for i = 1:numel (erridx) loc = sprintf ("%d,", subs(i,:)); cout{i} = ["(" loc(1:end-1) ")"]; endfor endfunction ## Pretty print the various errors in a condensed tabular format. function str = pprint (argin, err) str = ["ASSERT errors for: assert " argin "\n"]; str = [str, "\n Location | Observed | Expected | Reason\n"]; for i = 1:length (err.index) leni = length (err.index{i}); leno = length (err.observed{i}); lene = length (err.expected{i}); str = [str, sprintf("%*s%*s %*s%*s %*s%*s %s\n", 6+fix(leni/2), err.index{i} , 6-fix(leni/2), "", 6+fix(leno/2), err.observed{i}, 6-fix(leno/2), "", 6+fix(lene/2), err.expected{i}, 6-fix(lene/2), "", err.reason{i})]; endfor endfunction