io
Standard IO Server Interface Functions
This module provides an interface to standard Erlang IO servers.
The output functions all return ok
if they are successful,
or exit if they are not.
In the following description, all functions have an optional
parameter IoDevice
. If included, it must be the pid of a
process which handles the IO protocols. Normally, it is the
IoDevice
returned by
file:open/2.
For a description of the IO protocols refer to the STDLIB Users Guide.
Warning!
As of R13A, data supplied to the put_chars function should be in the
chardata()
format described below. This means that programs
supplying binaries to this function need to convert them to UTF-8
before trying to output the data on an
io_device()
.
If an io_device() is set in binary mode, the functions get_chars and get_line may return binaries instead of lists. The binaries will, as of R13A, be encoded in UTF-8.
To work with binaries in ISO-latin-1 encoding, use the file module instead.
For conversion functions between character encodings, see the unicode module.
DATA TYPES
io_device() as returned by file:open/2, a process handling IO protocols
unicode_binary() = binary() with characters encoded in UTF-8 coding standard unicode_char() = integer() representing valid unicode codepoint chardata() = charlist() | unicode_binary() charlist() = [unicode_char() | unicode_binary() | charlist()] a unicode_binary is allowed as the tail of the list
Functions
columns([IoDevice]) -> {ok,int()} | {error, enotsup}
IoDevice = io_device()
Retrieves the number of columns of the
IoDevice
(i.e. the width of a terminal). The function
only succeeds for terminal devices, for all other devices
the function returns {error, enotsup}
put_chars([IoDevice,] IoData) -> ok
IoDevice = io_device()
IoData = chardata()
Writes the characters of IoData
to the io_server()
(IoDevice
).
nl([IoDevice]) -> ok
IoDevice = io_device()
Writes new line to the standard output (IoDevice
).
get_chars([IoDevice,] Prompt, Count) -> Data | eof
IoDevice = io_device()
Prompt = atom() | string()
Count = int()
Data = [ unicode_char() ] | unicode_binary()
Reads Count
characters from standard input
(IoDevice
), prompting it with Prompt
. It
returns:
Data
-
The input characters. If the device supports Unicode, the data may represent codepoints larger than 255 (the latin1 range). If the io_server() is set to deliver binaries, they will be encoded in UTF-8 (regardless of if the device actually supports Unicode or not).
eof
-
End of file was encountered.
{error,Reason}
-
Other (rare) error condition, for instance
{error,estale}
if reading from an NFS file system.
get_line([IoDevice,] Prompt) -> Data | eof | {error,Reason}
IoDevice = io_device()
Prompt = atom() | string()
Data = [ unicode_char() ] | unicode_binary()
Reads a line from the standard input (IoDevice
),
prompting it with Prompt
. It returns:
Data
-
The characters in the line terminated by a LF (or end of file). If the device supports Unicode, the data may represent codepoints larger than 255 (the latin1 range). If the io_server() is set to deliver binaries, they will be encoded in UTF-8 (regardless of if the device actually supports Unicode or not).
eof
-
End of file was encountered.
{error,Reason}
-
Other (rare) error condition, for instance
{error,estale}
if reading from an NFS file system.
getopts([IoDevice]) -> Opts
IoDevice = io_device()
Opts = [Opt]
Opt = {atom(),Value}
Value = term()
This function requests all available options and their current values for a specific io_device(). Example:
1>{ok,F} = file:open("/dev/null",[read]).
{ok,<0.42.0>} 2>io:getopts(F).
[{binary,false},{encoding,latin1}]
Here the file I/O-server returns all available options for a file,
which are the expected ones, encoding
and binary
. The standard shell however has some more options:
3> io:getopts(). [{expand_fun,#Fun<group.0.120017273>}, {echo,true}, {binary,false}, {encoding,unicode}]
This example is, as can be seen, run in an environment where the terminal supports Unicode input and output.
setopts([IoDevice,] Opts) -> ok | {error, Reason}
IoDevice = io_device()
Opts = [Opt]
Opt = atom() | {atom(),Value}
Value = term()
Reason = term()
Set options for the io_device() (IoDevice
).
Possible options and values vary depending on the actual io_device(). For a list of supported options and their current values on a specific device, use the getopts/1 function.
The options and values supported by the current OTP io_devices are:
binary, list or {binary, bool()}
-
If set in binary mode (binary or {binary,true}), the io_server() sends binary data (encoded in UTF-8) as answers to the get_line, get_chars and, if possible, get_until requests (see the I/O protocol description in STDLIB User's Guide for details). The immediate effect is that
get_chars/2,3
andget_line/1,2
return UTF-8 binaries instead of lists of chars for the affected device.By default, all io_devices in OTP are set in list mode, but the io functions can handle any of these modes and so should other, user written, modules behaving as clients to I/O-servers.
This option is supported by the standard shell (group.erl), the 'oldshell' (user.erl) and the file I/O servers.
{echo, bool()}
-
Denotes if the terminal should echo input. Only supported for the standard shell I/O-server (group.erl)
{expand_fun, fun()}
-
Provide a function for tab-completion (expansion) like the erlang shell. This function is called when the user presses the Tab key. The expansion is active when calling line-reading functions such as
get_line/1,2
.The function is called with the current line, upto the cursor, as a reversed string. It should return a three-tuple:
{yes|no, string(), [string(), ...]}
. The first element gives a beep ifno
, otherwise the expansion is silent, the second is a string that will be entered at the cursor position, and the third is a list of possible expansions. If this list is non-empty, the list will be printed and the current input line will be written once again.Trivial example (beep on anything except empty line, which is expanded to "quit"):
fun("") -> {yes, "quit", []}; (_) -> {no, "", ["quit"]} end
This option is supported by the standard shell only (group.erl).
{encoding, latin1 | unicode}
-
Specifies how characters are input or output from or to the actual device, implying that i.e. a terminal is set to handle Unicode input and output or a file is set to handle UTF-8 data encoding.
The option does not affect how data is returned from the io-functions or how it is sent in the I/O-protocol, it only affects how the io_device() is to handle Unicode characters towards the "physical" device.
The standard shell will be set for either unicode or latin1 encoding when the system is started. The actual encoding is set with the help of the "LANG" or "LC_CTYPE" environment variables on Unix-like system or by other means on other systems. The bottom line is that the user can input Unicode characters and the device will be in {encoding, unicode} mode if the device supports it. The mode can be changed, if the assumption of the runtime system is wrong, by setting this option.
The io_device() used when Erlang is started with the "-oldshell" or "-noshell" flags is by default set to latin1 encoding, meaning that any characters beyond codepoint 255 will be escaped and that input is expected to be plain 8-bit ISO-latin-1. If the encoding is changed to Unicode, input and output from the standard file descriptors will be in UTF-8 (regardless of operating system).
Files can also be set in {encoding, unicode}, meaning that data is written and read as UTF-8. More encodings are possible for files, see below.
{encoding, unicode | latin1} is supported by both the standard shell (group.erl including werl on windows), the 'oldshell' (user.erl) and the file I/O servers.
{encoding, utf8 | utf16 | utf32 | {utf16,big} | {utf16,little} | {utf32,big} | {utf32,little}}
-
For disk files, the encoding can be set to various UTF variants. This will have the effect that data is expected to be read as the specified encoding from the file and the data will be written in the specified encoding to the disk file.
{encoding, utf8} will have the same effect as {encoding,unicode} on files.
The extended encodings are only supported on disk files (opened by the file:open/2 function)
write([IoDevice,] Term) -> ok
IoDevice = io_device()
Term = term()
Writes the term Term
to the standard output
(IoDevice
).
read([IoDevice,] Prompt) -> Result
IoDevice = io_device()
Prompt = atom() | string()
Result = {ok, Term} | eof | {error, ErrorInfo}
Term = term()
ErrorInfo -- see section Error Information below
Reads a term Term
from the standard input
(IoDevice
), prompting it with Prompt
. It
returns:
{ok, Term}
-
The parsing was successful.
eof
-
End of file was encountered.
{error, ErrorInfo}
-
The parsing failed.
read(IoDevice, Prompt, StartLine) -> Result
IoDevice = io_device()
Prompt = atom() | string()
StartLine = int()
Result = {ok, Term, EndLine} | {eof, EndLine} | {error, ErrorInfo, EndLine}
Term = term()
EndLine = int()
ErrorInfo -- see section Error Information below
Reads a term Term
from IoDevice
, prompting it
with Prompt
. Reading starts at line number
StartLine
. It returns:
{ok, Term, EndLine}
-
The parsing was successful.
{eof, EndLine}
-
End of file was encountered.
{error, ErrorInfo, EndLine}
-
The parsing failed.
fwrite(Format) ->
fwrite([IoDevice,] Format, Data) -> ok
format(Format) ->
format([IoDevice,] Format, Data) -> ok
IoDevice = io_device()
Format = atom() | string() | binary()
Data = [term()]
Writes the items in Data
([]
) on the standard
output (IoDevice
) in accordance with Format
.
Format
contains plain characters which are copied to
the output device, and control sequences for formatting, see
below. If Format
is an atom or a binary, it is first
converted to a list with the aid of atom_to_list/1
or binary_to_list/1
.
1> io:fwrite("Hello world!~n", []).
Hello world!
ok
The general format of a control sequence is ~F.P.PadModC
.
The character C
determines the type of control sequence
to be used, F
and P
are optional numeric
arguments. If F
, P
, or Pad
is *
,
the next argument in Data
is used as the numeric value
of F
or P
.
F
is the field width
of the printed argument. A
negative value means that the argument will be left justified
within the field, otherwise it will be right justified. If no
field width is specified, the required print width will be
used. If the field width specified is too small, then the
whole field will be filled with *
characters.
P
is the precision
of the printed argument. A
default value is used if no precision is specified. The
interpretation of precision depends on the control sequences.
Unless otherwise specified, the argument within
is used
to determine print width.
Pad
is the padding character. This is the character
used to pad the printed representation of the argument so that
it conforms to the specified field width and precision. Only
one padding character can be specified and, whenever
applicable, it is used for both the field width and precision.
The default padding character is ' '
(space).
Mod
is the control sequence modifier. It is either a
single character (currently only 't', for unicode translation,
is supported) that changes the interpretation of Data.
The following control sequences are available:
~
-
The character
~
is written. c
-
The argument is a number that will be interpreted as an ASCII code. The precision is the number of times the character is printed and it defaults to the field width, which in turn defaults to 1. The following example illustrates:
2>
io:fwrite("|~10.5c|~-10.5c|~5c|~n", [$a, $b, $c]).
| aaaaa|bbbbb |ccccc| okIf the Unicode translation modifier ('t') is in effect, the integer argument can be any number representing a valid unicode codepoint, otherwise it should be an integer less than or equal to 255, otherwise it is masked with 16#FF:
1>
io:fwrite("~tc~n",[1024]).
\x{400} ok 2>io:fwrite("~c~n",[1024]).
^@ ok f
-
The argument is a float which is written as
[-]ddd.ddd
, where the precision is the number of digits after the decimal point. The default precision is 6 and it cannot be less than 1. e
-
The argument is a float which is written as
[-]d.ddde+-ddd
, where the precision is the number of digits written. The default precision is 6 and it cannot be less than 2. g
-
The argument is a float which is written as
f
, if it is >= 0.1 and < 10000.0. Otherwise, it is written in thee
format. The precision is the number of significant digits. It defaults to 6 and should not be less than 2. If the absolute value of the float does not allow it to be written in thef
format with the desired number of significant digits, it is also written in thee
format. s
-
Prints the argument with the
string
syntax. The argument is, if no Unicode translation modifier is present, an I/O list, a binary, or an atom. If the Unicode translation modifier ('t') is in effect, the argument is chardata(), meaning that binaries are in UTF-8. The characters are printed without quotes. In this format, the printed argument is truncated to the given precision and field width.This format can be used for printing any object and truncating the output so it fits a specified field:
3>
io:fwrite("|~10w|~n", [{hey, hey, hey}]).
|**********| ok 4>io:fwrite("|~10s|~n", [io_lib:write({hey, hey, hey})]).
|{hey,hey,h| okA list with integers larger than 255 is considered an error if the Unicode translation modifier is not given:
1>
io:fwrite("~ts~n",[[1024]]).
\x{400} ok 2> io:fwrite("~s~n",[[1024]]). ** exception exit: {badarg,[{io,format,[<0.26.0>,"~s~n",[[1024]]]}, ... w
-
Writes data with the standard syntax. This is used to output Erlang terms. Atoms are printed within quotes if they contain embedded non-printable characters, and floats are printed accurately as the shortest, correctly rounded string.
p
-
Writes the data with standard syntax in the same way as
~w
, but breaks terms whose printed representation is longer than one line into many lines and indents each line sensibly. It also tries to detect lists of printable characters and to output these as strings. For example:5>
T = [{attributes,[[{id,age,1.50000},{mode,explicit},
{typename,"INTEGER"}], [{id,cho},{mode,explicit},{typename,'Cho'}]]},
{typename,'Person'},{tag,{'PRIVATE',3}},{mode,implicit}].
... 6>io:fwrite("~w~n", [T]).
[{attributes,[[{id,age,1.5},{mode,explicit},{typename, [73,78,84,69,71,69,82]}],[{id,cho},{mode,explicit},{typena me,'Cho'}]]},{typename,'Person'},{tag,{'PRIVATE',3}},{mode ,implicit}] ok 7>io:fwrite("~62p~n", [T]).
[{attributes,[[{id,age,1.5}, {mode,explicit}, {typename,"INTEGER"}], [{id,cho},{mode,explicit},{typename,'Cho'}]]}, {typename,'Person'}, {tag,{'PRIVATE',3}}, {mode,implicit}] okThe field width specifies the maximum line length. It defaults to 80. The precision specifies the initial indentation of the term. It defaults to the number of characters printed on this line in the
same
call toio:fwrite
orio:format
. For example, usingT
above:8>
io:fwrite("Here T = ~62p~n", [T]).
Here T = [{attributes,[[{id,age,1.5}, {mode,explicit}, {typename,"INTEGER"}], [{id,cho}, {mode,explicit}, {typename,'Cho'}]]}, {typename,'Person'}, {tag,{'PRIVATE',3}}, {mode,implicit}] ok W
-
Writes data in the same way as
~w
, but takes an extra argument which is the maximum depth to which terms are printed. Anything below this depth is replaced with...
. For example, usingT
above:9>
io:fwrite("~W~n", [T,9]).
[{attributes,[[{id,age,1.5},{mode,explicit},{typename,...}], [{id,cho},{mode,...},{...}]]},{typename,'Person'}, {tag,{'PRIVATE',3}},{mode,implicit}] okIf the maximum depth has been reached, then it is impossible to read in the resultant output. Also, the
,...
form in a tuple denotes that there are more elements in the tuple but these are below the print depth. P
-
Writes data in the same way as
~p
, but takes an extra argument which is the maximum depth to which terms are printed. Anything below this depth is replaced with...
. For example:10>
io:fwrite("~62P~n", [T,9]).
[{attributes,[[{id,age,1.5},{mode,explicit},{typename,...}], [{id,cho},{mode,...},{...}]]}, {typename,'Person'}, {tag,{'PRIVATE',3}}, {mode,implicit}] ok B
-
Writes an integer in base 2..36, the default base is 10. A leading dash is printed for negative integers.
The precision field selects base. For example:
11>
io:fwrite("~.16B~n", [31]).
1F ok 12>io:fwrite("~.2B~n", [-19]).
-10011 ok 13>io:fwrite("~.36B~n", [5*36+35]).
5Z ok X
-
Like
B
, but takes an extra argument that is a prefix to insert before the number, but after the leading dash, if any.The prefix can be a possibly deep list of characters or an atom.
14>
io:fwrite("~X~n", [31,"10#"]).
10#31 ok 15>io:fwrite("~.16X~n", [-31,"0x"]).
-0x1F ok #
-
Like
B
, but prints the number with an Erlang style '#'-separated base prefix.16>
io:fwrite("~.10#~n", [31]).
10#31 ok 17>io:fwrite("~.16#~n", [-31]).
-16#1F ok b
-
Like
B
, but prints lowercase letters. x
-
Like
X
, but prints lowercase letters. +
-
Like
#
, but prints lowercase letters. n
-
Writes a new line.
i
-
Ignores the next term.
Returns:
ok
-
The formatting succeeded.
If an error occurs, there is no output. For example:
18>io:fwrite("~s ~w ~i ~w ~c ~n",['abc def', 'abc def', {foo, 1},{foo, 1}, 65]).
abc def 'abc def' {foo,1} A ok 19>io:fwrite("~s", [65]).
** exception exit: {badarg,[{io,format,[<0.22.0>,"~s","A"]}, {erl_eval,do_apply,5}, {shell,exprs,6}, {shell,eval_exprs,6}, {shell,eval_loop,3}]} in function io:o_request/2
In this example, an attempt was made to output the single character '65' with the aid of the string formatting directive "~s".
fread([IoDevice,] Prompt, Format) -> Result
IoDevice = io_device()
Prompt = atom() | string()
Format = string()
Result = {ok, Terms} | eof | {error, What}
Terms = [term()]
What = term()
Reads characters from the standard input (IoDevice
),
prompting it with Prompt
. Interprets the characters in
accordance with Format
. Format
contains control
sequences which directs the interpretation of the input.
Format
may contain:
-
White space characters (SPACE, TAB and NEWLINE) which cause input to be read to the next non-white space character.
-
Ordinary characters which must match the next input character.
-
Control sequences, which have the general format
~*FMC
. The character*
is an optional return suppression character. It provides a method to specify a field which is to be omitted.F
is thefield width
of the input field,M
is an optional translation modifier (of which 't' is the only currently supported, meaning Unicode translation) andC
determines the type of control sequence.Unless otherwise specified, leading white-space is ignored for all control sequences. An input field cannot be more than one line wide. The following control sequences are available:
~
-
A single
~
is expected in the input. d
-
A decimal integer is expected.
u
-
An unsigned integer in base 2..36 is expected. The field width parameter is used to specify base. Leading white-space characters are not skipped.
-
-
An optional sign character is expected. A sign character '-' gives the return value
-1
. Sign character '+' or none gives1
. The field width parameter is ignored. Leading white-space characters are not skipped. #
-
An integer in base 2..36 with Erlang-style base prefix (for example
"16#ffff"
) is expected. f
-
A floating point number is expected. It must follow the Erlang floating point number syntax.
s
-
A string of non-white-space characters is read. If a field width has been specified, this number of characters are read and all trailing white-space characters are stripped. An Erlang string (list of characters) is returned.
If Unicode translation is in effect (~ts), characters larger than 255 are accepted, otherwise not. With the translation modifier, the list returned may as a consequence also contain integers larger than 255:
1>
io:fread("Prompt> ","~s").
Prompt><Characters beyond latin1 range not printable in this medium>
{error,{fread,string}} 2>io:fread("Prompt> ","~ts").
Prompt><Characters beyond latin1 range not printable in this medium>
{ok,[[1091,1085,1080,1094,1086,1076,1077]]} a
-
Similar to
s
, but the resulting string is converted into an atom.The Unicode translation modifier is not allowed (atoms can not contain characters beyond the latin1 range).
c
-
The number of characters equal to the field width are read (default is 1) and returned as an Erlang string. However, leading and trailing white-space characters are not omitted as they are with
s
. All characters are returned.The Unicode translation modifier works as with
s
:1>
io:fread("Prompt> ","~c").
Prompt><Character beyond latin1 range not printable in this medium>
{error,{fread,string}} 2>io:fread("Prompt> ","~tc").
Prompt><Character beyond latin1 range not printable in this medium>
{ok,[[1091]]} l
-
Returns the number of characters which have been scanned up to that point, including white-space characters.
It returns:
{ok, Terms}
-
The read was successful and
Terms
is the list of successfully matched and read items. eof
-
End of file was encountered.
{error, What}
-
The read operation failed and the parameter
What
gives a hint about the error.
Examples:
20>io:fread('enter>', "~f~f~f").
enter>1.9 35.5e3 15.0
{ok,[1.9,3.55e4,15.0]} 21>io:fread('enter>', "~10f~d").
enter>5.67899
{ok,[5.678,99]} 22>io:fread('enter>', ":~10s:~10c:").
enter>:
alan
:
joe
:
{ok, ["alan", " joe "]}
rows([IoDevice]) -> {ok,int()} | {error, enotsup}
IoDevice = io_device()
Retrieves the number of rows of the
IoDevice
(i.e. the height of a terminal). The function
only succeeds for terminal devices, for all other devices
the function returns {error, enotsup}
scan_erl_exprs(Prompt) ->
scan_erl_exprs([IoDevice,] Prompt, StartLine) -> Result
IoDevice = io_device()
Prompt = atom() | string()
StartLine = int()
Result = {ok, Tokens, EndLine} | {eof, EndLine} | {error, ErrorInfo, EndLine}
Tokens -- see erl_scan(3)
EndLine = int()
ErrorInfo -- see section Error Information below
Reads data from the standard input (IoDevice
),
prompting it with Prompt
. Reading starts at line number
StartLine
(1). The data is tokenized as if it were a
sequence of Erlang expressions until a final '.'
is
reached. This token is also returned. It returns:
{ok, Tokens, EndLine}
-
The tokenization succeeded.
{eof, EndLine}
-
End of file was encountered.
{error, ErrorInfo, EndLine}
-
An error occurred.
Example:
23>io:scan_erl_exprs('enter>').
enter>abc(), "hey".
{ok,[{atom,1,abc},{'(',1},{')',1},{',',1},{string,1,"hey"},{dot,1}],2} 24>io:scan_erl_exprs('enter>').
enter>1.0er.
{error,{1,erl_scan,{illegal,float}},2}
scan_erl_form(Prompt) ->
scan_erl_form([IoDevice,] Prompt, StartLine) -> Result
IoDevice = io_device()
Prompt = atom() | string()
StartLine = int()
Result = {ok, Tokens, EndLine} | {eof, EndLine} | {error, ErrorInfo, EndLine}
Tokens -- see erl_scan(3)
EndLine = int()
ErrorInfo -- see section Error Information below
Reads data from the standard input (IoDevice
),
prompting it with Prompt
. Starts reading at line number
StartLine
(1). The data is tokenized as if it were an
Erlang form - one of the valid Erlang expressions in an
Erlang source file - until a final '.'
is reached.
This last token is also returned. The return values are the
same as for scan_erl_exprs/1,2,3
above.
parse_erl_exprs(Prompt) ->
parse_erl_exprs([IoDevice,] Prompt, StartLine) -> Result
IoDevice = io_device()
Prompt = atom() | string()
StartLine = int()
Result = {ok, Expr_list, EndLine} | {eof, EndLine} | {error, ErrorInfo, EndLine}
Expr_list -- see erl_parse(3)
EndLine = int()
ErrorInfo -- see section Error Information below
Reads data from the standard input (IoDevice
),
prompting it with Prompt
. Starts reading at line number
StartLine
(1). The data is tokenized and parsed as if
it were a sequence of Erlang expressions until a final '.' is
reached. It returns:
{ok, Expr_list, EndLine}
-
The parsing was successful.
{eof, EndLine}
-
End of file was encountered.
{error, ErrorInfo, EndLine}
-
An error occurred.
Example:
25>io:parse_erl_exprs('enter>').
enter>abc(), "hey".
{ok, [{call,1,{atom,1,abc},[]},{string,1,"hey"}],2} 26>io:parse_erl_exprs ('enter>').
enter>abc("hey".
{error,{1,erl_parse,["syntax error before: ",["'.'"]]},2}
parse_erl_form(Prompt) ->
parse_erl_form([IoDevice,] Prompt, StartLine) -> Result
IoDevice = io_device()
Prompt = atom() | string()
StartLine = int()
Result = {ok, AbsForm, EndLine} | {eof, EndLine} | {error, ErrorInfo, EndLine}
AbsForm -- see erl_parse(3)
EndLine = int()
ErrorInfo -- see section Error Information below
Reads data from the standard input (IoDevice
),
prompting it with Prompt
. Starts reading at line number
StartLine
(1). The data is tokenized and parsed as if
it were an Erlang form - one of the valid Erlang expressions
in an Erlang source file - until a final '.' is reached. It
returns:
{ok, AbsForm, EndLine}
-
The parsing was successful.
{eof, EndLine}
-
End of file was encountered.
{error, ErrorInfo, EndLine}
-
An error occurred.
Standard Input/Output
All Erlang processes have a default standard IO device. This
device is used when no IoDevice
argument is specified in
the above function calls. However, it is sometimes desirable to
use an explicit IoDevice
argument which refers to the
default IO device. This is the case with functions that can
access either a file or the default IO device. The atom
standard_io
has this special meaning. The following example
illustrates this:
27>io:read('enter>').
enter>foo.
{ok,foo} 28>io:read(standard_io, 'enter>').
enter>bar.
{ok,bar}
There is always a process registered under the name of
user
. This can be used for sending output to the user.
Standard Error
In certain situations, especially when the standard output is redirected, access to an io_server() specific for error messages might be convenient. The io_device 'standard_error' can be used to direct output to whatever the current operating system considers a suitable device for error output. Example on a Unix-like operating system:
$ erl -noshell -noinput -eval 'io:format(standard_error,"Error: ~s~n",["error 11"]),init:stop().' > /dev/null
Error: error 11
Error Information
The ErrorInfo
mentioned above is the standard
ErrorInfo
structure which is returned from all IO modules.
It has the format:
{ErrorLine, Module, ErrorDescriptor}
A string which describes the error is obtained with the following call:
apply(Module, format_error, ErrorDescriptor)