Mercurial > octave-nkf
diff doc/interpreter/dynamic.txi @ 14856:c3fd61c59e9c
maint: Use Octave coding conventions for cuddling parentheses in doc directory
* OctaveFAQ.texi, basics.txi, container.txi, contrib.txi, diagperm.txi,
diffeq.txi, dynamic.txi, errors.txi, eval.txi, expr.txi, func.txi,
geometry.txi, interp.txi, intro.txi, numbers.txi, oop.txi, plot.txi, poly.txi,
quad.txi, set.txi, sparse.txi, stmt.txi, testfun.txi, vectorize.txi,
refcard.tex: Use Octave coding conventions for cuddling parentheses.
| author | Rik <octave@nomad.inbox5.com> |
|---|---|
| date | Mon, 09 Jul 2012 17:00:46 -0700 |
| parents | 460a3c6d8bf1 |
| children | 18f8f2987205 |
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--- a/doc/interpreter/dynamic.txi Mon Jul 09 13:23:31 2012 -0700 +++ b/doc/interpreter/dynamic.txi Mon Jul 09 17:00:46 2012 -0700 @@ -551,7 +551,7 @@ should use @code{numel} rather than @code{nelem}. Note that for very large matrices, where the product of the two dimensions is larger than the representation of an unsigned int, then @code{numel} can overflow. -An example is @code{speye(1e6)} which will create a matrix with a million +An example is @code{speye (1e6)} which will create a matrix with a million rows and columns, but only a million non-zero elements. Therefore the number of rows by the number of columns in this case is more than two hundred times the maximum value that can be represented by an unsigned int. @@ -901,9 +901,9 @@ @group funcdemo (@@sin,1) @result{} 0.84147 -funcdemo (@@(x) sin(x), 1) +funcdemo (@@(x) sin (x), 1) @result{} 0.84147 -funcdemo (inline ("sin(x)"), 1) +funcdemo (inline ("sin (x)"), 1) @result{} 0.84147 funcdemo ("sin",1) @result{} 0.84147 @@ -1008,7 +1008,7 @@ @result{} b = 1.00000 0.50000 0.33333 s = There are 3 values in the input vector -[b, s] = fortdemo(0:3) +[b, s] = fortdemo (0:3) error: fortsub:divide by zero error: exception encountered in Fortran subroutine fortsub_ error: fortdemo: error in Fortran @@ -1086,7 +1086,7 @@ for (octave_idx_type i = 0; i < a.nelem (); i++) @{ OCTAVE_QUIT; - b.elem(i) = 2. * a.elem(i); + b.elem (i) = 2. * a.elem (i); @} @end group @end example @@ -1195,9 +1195,9 @@ @group /* -%!error (sin()) -%!error (sin(1,1)) -%!assert (sin([1,2]),[sin(1),sin(2)]) +%!error (sin ()) +%!error (sin (1,1)) +%!assert (sin ([1,2]),[sin(1),sin(2)]) */ @end group @@ -1371,7 +1371,7 @@ mwSize *dims; UINT32_T *pr; -dims = (mwSize *) mxMalloc (2 * sizeof(mwSize)); +dims = (mwSize *) mxMalloc (2 * sizeof (mwSize)); dims[0] = 2; dims[1] = 2; m = mxCreateNumericArray (2, dims, mxUINT32_CLASS, mxREAL); @@ -1403,8 +1403,8 @@ @example @group -b = randn(4,1) + 1i * randn(4,1); -all(b.^2 == mypow2(b)) +b = randn (4,1) + 1i * randn (4,1); +all (b.^2 == mypow2 (b)) @result{} 1 @end group @end example @@ -1434,7 +1434,7 @@ @example @group -mystring(["First String"; "Second String"]) +mystring (["First String"; "Second String"]) @result{} s1 = Second String First String @end group @@ -1549,7 +1549,7 @@ @example a(1).f1 = "f11"; a(1).f2 = "f12"; a(2).f1 = "f21"; a(2).f2 = "f22"; -b = mystruct(a) +b = mystruct (a) @result{} field f1(0) = f11 field f1(1) = f21 field f2(0) = f12 @@ -1651,8 +1651,8 @@ @example @group -myfeval("sin", 1) -a = myfeval("sin", 1) +myfeval ("sin", 1) +a = myfeval ("sin", 1) @result{} Hello, World! I have 2 inputs and 1 outputs I'm going to call the interpreter function sin