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When creating simple one-shot programs it can be very convenient to
see which variables are available at the prompt. The function who
and its siblings whos
and whos_line_format
will show
different information about what is in memory, as the following shows.
str = "A random string"; who -variables -| *** local user variables: -| -| __nargin__ str
List currently defined variables matching the given patterns.
Valid pattern syntax is the same as described for the clear
command.
If no patterns are supplied, all variables are listed.
By default, only variables visible in the local scope are displayed.
The following are valid options, but may not be combined.
global
List variables in the global scope rather than the current scope.
-regexp
The patterns are considered to be regular expressions when matching the
variables to display. The same pattern syntax accepted by the regexp
function is used.
-file
The next argument is treated as a filename. All variables found within the specified file are listed. No patterns are accepted when reading variables from a file.
If called as a function, return a cell array of defined variable names matching the given patterns.
Provide detailed information on currently defined variables matching the given patterns.
Options and pattern syntax are the same as for the who
command.
Extended information about each variable is summarized in a table with the following default entries.
Attributes of the listed variable. Possible attributes are:
Variable in local scope
a
Automatic variable. An automatic variable is one created by the
interpreter, for example argn
.
c
Variable of complex type.
f
Formal parameter (function argument).
g
Variable with global scope.
p
Persistent variable.
The name of the variable.
The logical size of the variable. A scalar is 1x1, a vector is 1xN or Nx1, a 2-D matrix is MxN.
The amount of memory currently used to store the variable.
The class of the variable. Examples include double, single, char, uint16, cell, and struct.
The table can be customized to display more or less information through
the function whos_line_format
.
If whos
is called as a function, return a struct array of defined
variable names matching the given patterns. Fields in the structure
describing each variable are: name, size, bytes, class, global, sparse,
complex, nesting, persistent.
See also: who, whos_line_format.
Query or set the format string used by the command whos
.
A full format string is:
%[modifier]<command>[:width[:left-min[:balance]]];
The following command sequences are available:
%a
Prints attributes of variables (g=global, p=persistent, f=formal parameter, a=automatic variable).
%b
Prints number of bytes occupied by variables.
%c
Prints class names of variables.
%e
Prints elements held by variables.
%n
Prints variable names.
%s
Prints dimensions of variables.
%t
Prints type names of variables.
Every command may also have an alignment modifier:
l
Left alignment.
r
Right alignment (default).
c
Column-aligned (only applicable to command %s).
The width
parameter is a positive integer specifying the minimum
number of columns used for printing. No maximum is needed as the field will
auto-expand as required.
The parameters left-min
and balance
are only available when
the column-aligned modifier is used with the command ‘%s’.
balance
specifies the column number within the field width which
will be aligned between entries. Numbering starts from 0 which indicates
the leftmost column. left-min
specifies the minimum field width to
the left of the specified balance column.
The default format is:
" %a:4; %ln:6; %cs:16:6:1; %rb:12; %lc:-1;\n"
When called from inside a function with the "local"
option, the
variable is changed locally for the function and any subroutines it calls.
The original variable value is restored when exiting the function.
See also: whos.
Instead of displaying which variables are in memory, it is possible to determine if a given variable is available. That way it is possible to alter the behavior of a program depending on the existence of a variable. The following example illustrates this.
if (! exist ("meaning", "var")) disp ("The program has no 'meaning'"); endif
Check for the existence of name as a variable, function, file, directory, or class.
The return code c is one of
name is a variable.
name is an absolute filename, an ordinary file in Octave’s
path
, or (after appending ‘.m’) a function file in Octave’s
path
.
name is a ‘.oct’ or ‘.mex’ file in Octave’s path
.
name is a built-in function.
name is a directory.
name is a function not associated with a file (entered on the command line).
name does not exist.
If the optional argument type is supplied, check only for symbols of the specified type. Valid types are
"var"
Check only for variables.
"builtin"
Check only for built-in functions.
"dir"
Check only for directories.
"file"
Check only for files and directories.
"class"
Check only for classes. (Note: This option is accepted, but not currently implemented)
If no type is given, and there are multiple possible matches for name,
exist
will return a code according to the following priority list:
variable, built-in function, oct-file, directory, file, class.
exist
returns 2 if a regular file called name is present in
Octave’s search path. If you want information about other types of files
not on the search path you should use some combination of the functions
file_in_path
and stat
instead.
Programming Note: If name is implemented by a buggy .oct/.mex file, calling exist may cause Octave to crash. To maintain high performance, Octave trusts .oct/.mex files instead of sandboxing them.
See also: file_in_loadpath, file_in_path, dir_in_loadpath, stat.
Usually Octave will manage the memory, but sometimes it can be practical to remove variables from memory manually. This is usually needed when working with large variables that fill a substantial part of the memory. On a computer that uses the IEEE floating point format, the following program allocates a matrix that requires around 128 MB memory.
large_matrix = zeros (4000, 4000);
Since having this variable in memory might slow down other computations,
it can be necessary to remove it manually from memory. The clear
function allows this.
Delete the names matching the given patterns from the symbol table.
The pattern may contain the following special characters:
?
Match any single character.
*
Match zero or more characters.
[ list ]
Match the list of characters specified by list. If the first
character is !
or ^
, match all characters except those
specified by list. For example, the pattern ‘[a-zA-Z]’ will
match all lowercase and uppercase alphabetic characters.
For example, the command
clear foo b*r
clears the name foo
and all names that begin with the letter
b
and end with the letter r
.
If clear
is called without any arguments, all user-defined
variables (local and global) are cleared from the symbol table.
If clear
is called with at least one argument, only the visible
names matching the arguments are cleared. For example, suppose you have
defined a function foo
, and then hidden it by performing the
assignment foo = 2
. Executing the command clear foo once
will clear the variable definition and restore the definition of
foo
as a function. Executing clear foo a second time will
clear the function definition.
The following options are available in both long and short form
-all, -a
Clear all local and global user-defined variables and all functions from the symbol table.
-exclusive, -x
Clear the variables that don’t match the following pattern.
-functions, -f
Clear the function names and the built-in symbols names.
-global, -g
Clear global symbol names.
-variables, -v
Clear local variable names.
-classes, -c
Clears the class structure table and clears all objects.
-regexp, -r
The arguments are treated as regular expressions as any variables that match will be cleared.
With the exception of exclusive
, all long options can be used
without the dash as well.
Consolidate workspace memory in MATLAB.
This function is provided for compatibility, but does nothing in Octave.
See also: clear.
Information about a function or variable such as its location in the file system can also be acquired from within Octave. This is usually only useful during development of programs, and not within a program.
Display the contents of name which may be a file, function (m-file), variable, operator, or keyword.
type
normally prepends a header line describing the category of
name such as function or variable; The -q option suppresses
this behavior.
If no output variable is used the contents are displayed on screen. Otherwise, a cell array of strings is returned, where each element corresponds to the contents of each requested function.
Display the type of each name.
If name is defined from a function file, the full name of the file is also displayed.
List the Octave specific files in directory dir.
If dir is not specified then the current directory is used.
If a return argument is requested, the files found are returned in the structure w. The structure contains the following fields:
Full path to directory dir
Cell array of m-files
Cell array of mat files
Cell array of mex files
Cell array of oct files
Cell array of mdl files
Cell array of slx files
Cell array of p-files
Cell array of class directories (@classname/)
Cell array of package directories (+pkgname/)
Compatibility Note: Octave does not support mdl, slx, and p files; nor does
it support package directories. what
will always return an empty
list for these categories.
Previous: Persistent Variables, Up: Variables [Contents][Index]