@node I/O on Streams, Low-Level I/O, I/O Overview, Top @c %MENU% High-level, portable I/O facilities @chapter Input/Output on Streams @c fix an overfull: @tex \hyphenation{which-ever} @end tex This chapter describes the functions for creating streams and performing input and output operations on them. As discussed in @ref{I/O Overview}, a stream is a fairly abstract, high-level concept representing a communications channel to a file, device, or process. @menu * Streams:: About the data type representing a stream. * Standard Streams:: Streams to the standard input and output devices are created for you. * Opening Streams:: How to create a stream to talk to a file. * Closing Streams:: Close a stream when you are finished with it. * Simple Output:: Unformatted output by characters and lines. * Character Input:: Unformatted input by characters and words. * Line Input:: Reading a line or a record from a stream. * Unreading:: Peeking ahead/pushing back input just read. * Block Input/Output:: Input and output operations on blocks of data. * Formatted Output:: @code{printf} and related functions. * Customizing Printf:: You can define new conversion specifiers for @code{printf} and friends. * Formatted Input:: @code{scanf} and related functions. * EOF and Errors:: How you can tell if an I/O error happens. * Binary Streams:: Some systems distinguish between text files and binary files. * File Positioning:: About random-access streams. * Portable Positioning:: Random access on peculiar ISO C systems. * Stream Buffering:: How to control buffering of streams. * Other Kinds of Streams:: Streams that do not necessarily correspond to an open file. * Formatted Messages:: Print strictly formatted messages. @end menu @node Streams @section Streams For historical reasons, the type of the C data structure that represents a stream is called @code{FILE} rather than ``stream''. Since most of the library functions deal with objects of type @code{FILE *}, sometimes the term @dfn{file pointer} is also used to mean ``stream''. This leads to unfortunate confusion over terminology in many books on C. This manual, however, is careful to use the terms ``file'' and ``stream'' only in the technical sense. @cindex file pointer @pindex stdio.h The @code{FILE} type is declared in the header file @file{stdio.h}. @comment stdio.h @comment ISO @deftp {Data Type} FILE This is the data type used to represent stream objects. A @code{FILE} object holds all of the internal state information about the connection to the associated file, including such things as the file position indicator and buffering information. Each stream also has error and end-of-file status indicators that can be tested with the @code{ferror} and @code{feof} functions; see @ref{EOF and Errors}. @end deftp @code{FILE} objects are allocated and managed internally by the input/output library functions. Don't try to create your own objects of type @code{FILE}; let the library do it. Your programs should deal only with pointers to these objects (that is, @code{FILE *} values) rather than the objects themselves. @c !!! should say that FILE's have "No user-serviceable parts inside." @node Standard Streams @section Standard Streams @cindex standard streams @cindex streams, standard When the @code{main} function of your program is invoked, it already has three predefined streams open and available for use. These represent the ``standard'' input and output channels that have been established for the process. These streams are declared in the header file @file{stdio.h}. @pindex stdio.h @comment stdio.h @comment ISO @deftypevar {FILE *} stdin The @dfn{standard input} stream, which is the normal source of input for the program. @end deftypevar @cindex standard input stream @comment stdio.h @comment ISO @deftypevar {FILE *} stdout The @dfn{standard output} stream, which is used for normal output from the program. @end deftypevar @cindex standard output stream @comment stdio.h @comment ISO @deftypevar {FILE *} stderr The @dfn{standard error} stream, which is used for error messages and diagnostics issued by the program. @end deftypevar @cindex standard error stream In the GNU system, you can specify what files or processes correspond to these streams using the pipe and redirection facilities provided by the shell. (The primitives shells use to implement these facilities are described in @ref{File System Interface}.) Most other operating systems provide similar mechanisms, but the details of how to use them can vary. In the GNU C library, @code{stdin}, @code{stdout}, and @code{stderr} are normal variables which you can set just like any others. For example, to redirect the standard output to a file, you could do: @smallexample fclose (stdout); stdout = fopen ("standard-output-file", "w"); @end smallexample Note however, that in other systems @code{stdin}, @code{stdout}, and @code{stderr} are macros that you cannot assign to in the normal way. But you can use @code{freopen} to get the effect of closing one and reopening it. @xref{Opening Streams}. @node Opening Streams @section Opening Streams @cindex opening a stream Opening a file with the @code{fopen} function creates a new stream and establishes a connection between the stream and a file. This may involve creating a new file. @pindex stdio.h Everything described in this section is declared in the header file @file{stdio.h}. @comment stdio.h @comment ISO @deftypefun {FILE *} fopen (const char *@var{filename}, const char *@var{opentype}) The @code{fopen} function opens a stream for I/O to the file @var{filename}, and returns a pointer to the stream. The @var{opentype} argument is a string that controls how the file is opened and specifies attributes of the resulting stream. It must begin with one of the following sequences of characters: @table @samp @item r Open an existing file for reading only. @item w Open the file for writing only. If the file already exists, it is truncated to zero length. Otherwise a new file is created. @item a Open a file for append access; that is, writing at the end of file only. If the file already exists, its initial contents are unchanged and output to the stream is appended to the end of the file. Otherwise, a new, empty file is created. @item r+ Open an existing file for both reading and writing. The initial contents of the file are unchanged and the initial file position is at the beginning of the file. @item w+ Open a file for both reading and writing. If the file already exists, it is truncated to zero length. Otherwise, a new file is created. @item a+ Open or create file for both reading and appending. If the file exists, its initial contents are unchanged. Otherwise, a new file is created. The initial file position for reading is at the beginning of the file, but output is always appended to the end of the file. @end table As you can see, @samp{+} requests a stream that can do both input and output. The ISO standard says that when using such a stream, you must call @code{fflush} (@pxref{Stream Buffering}) or a file positioning function such as @code{fseek} (@pxref{File Positioning}) when switching from reading to writing or vice versa. Otherwise, internal buffers might not be emptied properly. The GNU C library does not have this limitation; you can do arbitrary reading and writing operations on a stream in whatever order. Additional characters may appear after these to specify flags for the call. Always put the mode (@samp{r}, @samp{w+}, etc.) first; that is the only part you are guaranteed will be understood by all systems. The GNU C library defines one additional character for use in @var{opentype}: the character @samp{x} insists on creating a new file---if a file @var{filename} already exists, @code{fopen} fails rather than opening it. If you use @samp{x} you are guaranteed that you will not clobber an existing file. This is equivalent to the @code{O_EXCL} option to the @code{open} function (@pxref{Opening and Closing Files}). The character @samp{b} in @var{opentype} has a standard meaning; it requests a binary stream rather than a text stream. But this makes no difference in POSIX systems (including the GNU system). If both @samp{+} and @samp{b} are specified, they can appear in either order. @xref{Binary Streams}. Any other characters in @var{opentype} are simply ignored. They may be meaningful in other systems. If the open fails, @code{fopen} returns a null pointer. When the sources are compiling with @code{_FILE_OFFSET_BITS == 64} on a 32 bit machine this function is in fact @code{fopen64} since the LFS interface replaces transparently the old interface. @end deftypefun You can have multiple streams (or file descriptors) pointing to the same file open at the same time. If you do only input, this works straightforwardly, but you must be careful if any output streams are included. @xref{Stream/Descriptor Precautions}. This is equally true whether the streams are in one program (not usual) or in several programs (which can easily happen). It may be advantageous to use the file locking facilities to avoid simultaneous access. @xref{File Locks}. @comment stdio.h @comment Unix98 @deftypefun {FILE *} fopen64 (const char *@var{filename}, const char *@var{opentype}) This function is similar to @code{fopen} but the stream it returns a pointer for is opened using @code{open64}. Therefore this stream can be used even on files larger then @math{2^31} bytes on 32 bit machines. Please note that the return type is still @code{FILE *}. There is no special @code{FILE} type for the LFS interface. If the sources are compiled with @code{_FILE_OFFSET_BITS == 64} on a 32 bits machine this function is available under the name @code{fopen} and so transparently replaces the old interface. @end deftypefun @comment stdio.h @comment ISO @deftypevr Macro int FOPEN_MAX The value of this macro is an integer constant expression that represents the minimum number of streams that the implementation guarantees can be open simultaneously. You might be able to open more than this many streams, but that is not guaranteed. The value of this constant is at least eight, which includes the three standard streams @code{stdin}, @code{stdout}, and @code{stderr}. In POSIX.1 systems this value is determined by the @code{OPEN_MAX} parameter; @pxref{General Limits}. In BSD and GNU, it is controlled by the @code{RLIMIT_NOFILE} resource limit; @pxref{Limits on Resources}. @end deftypevr @comment stdio.h @comment ISO @deftypefun {FILE *} freopen (const char *@var{filename}, const char *@var{opentype}, FILE *@var{stream}) This function is like a combination of @code{fclose} and @code{fopen}. It first closes the stream referred to by @var{stream}, ignoring any errors that are detected in the process. (Because errors are ignored, you should not use @code{freopen} on an output stream if you have actually done any output using the stream.) Then the file named by @var{filename} is opened with mode @var{opentype} as for @code{fopen}, and associated with the same stream object @var{stream}. If the operation fails, a null pointer is returned; otherwise, @code{freopen} returns @var{stream}. @code{freopen} has traditionally been used to connect a standard stream such as @code{stdin} with a file of your own choice. This is useful in programs in which use of a standard stream for certain purposes is hard-coded. In the GNU C library, you can simply close the standard streams and open new ones with @code{fopen}. But other systems lack this ability, so using @code{freopen} is more portable. When the sources are compiling with @code{_FILE_OFFSET_BITS == 64} on a 32 bit machine this function is in fact @code{freopen64} since the LFS interface replaces transparently the old interface. @end deftypefun @comment stdio.h @comment Unix98 @deftypefun {FILE *} freopen64 (const char *@var{filename}, const char *@var{opentype}, FILE *@var{stream}) This function is similar to @code{freopen}. The only difference is that on 32 bit machine the stream returned is able to read beyond the @math{2^31} bytes limits imposed by the normal interface. It should be noted that the stream pointed to by @var{stream} need not be opened using @code{fopen64} or @code{freopen64} since its mode is not important for this function. If the sources are compiled with @code{_FILE_OFFSET_BITS == 64} on a 32 bits machine this function is available under the name @code{freopen} and so transparently replaces the old interface. @end deftypefun @node Closing Streams @section Closing Streams @cindex closing a stream When a stream is closed with @code{fclose}, the connection between the stream and the file is cancelled. After you have closed a stream, you cannot perform any additional operations on it. @comment stdio.h @comment ISO @deftypefun int fclose (FILE *@var{stream}) This function causes @var{stream} to be closed and the connection to the corresponding file to be broken. Any buffered output is written and any buffered input is discarded. The @code{fclose} function returns a value of @code{0} if the file was closed successfully, and @code{EOF} if an error was detected. It is important to check for errors when you call @code{fclose} to close an output stream, because real, everyday errors can be detected at this time. For example, when @code{fclose} writes the remaining buffered output, it might get an error because the disk is full. Even if you know the buffer is empty, errors can still occur when closing a file if you are using NFS. The function @code{fclose} is declared in @file{stdio.h}. @end deftypefun To close all streams currently available the GNU C Library provides another function. @comment stdio.h @comment GNU @deftypefun int fcloseall (void) This function causes all open streams of the process to be closed and the connection to corresponding files to be broken. All buffered data is written and any buffered input is discarded. The @code{fcloseall} function returns a value of @code{0} if all the files were closed successfully, and @code{EOF} if an error was detected. This function should be used only in special situations, e.g., when an error occurred and the program must be aborted. Normally each single stream should be closed separately so that problems with individual streams can be identified. It is also problematic since the standard streams (@pxref{Standard Streams}) will also be closed. The function @code{fcloseall} is declared in @file{stdio.h}. @end deftypefun If the @code{main} function to your program returns, or if you call the @code{exit} function (@pxref{Normal Termination}), all open streams are automatically closed properly. If your program terminates in any other manner, such as by calling the @code{abort} function (@pxref{Aborting a Program}) or from a fatal signal (@pxref{Signal Handling}), open streams might not be closed properly. Buffered output might not be flushed and files may be incomplete. For more information on buffering of streams, see @ref{Stream Buffering}. @node Simple Output @section Simple Output by Characters or Lines @cindex writing to a stream, by characters This section describes functions for performing character- and line-oriented output. These functions are declared in the header file @file{stdio.h}. @pindex stdio.h @comment stdio.h @comment ISO @deftypefun int fputc (int @var{c}, FILE *@var{stream}) The @code{fputc} function converts the character @var{c} to type @code{unsigned char}, and writes it to the stream @var{stream}. @code{EOF} is returned if a write error occurs; otherwise the character @var{c} is returned. @end deftypefun @comment stdio.h @comment ISO @deftypefun int putc (int @var{c}, FILE *@var{stream}) This is just like @code{fputc}, except that most systems implement it as a macro, making it faster. One consequence is that it may evaluate the @var{stream} argument more than once, which is an exception to the general rule for macros. @code{putc} is usually the best function to use for writing a single character. @end deftypefun @comment stdio.h @comment ISO @deftypefun int putchar (int @var{c}) The @code{putchar} function is equivalent to @code{putc} with @code{stdout} as the value of the @var{stream} argument. @end deftypefun @comment stdio.h @comment ISO @deftypefun int fputs (const char *@var{s}, FILE *@var{stream}) The function @code{fputs} writes the string @var{s} to the stream @var{stream}. The terminating null character is not written. This function does @emph{not} add a newline character, either. It outputs only the characters in the string. This function returns @code{EOF} if a write error occurs, and otherwise a non-negative value. For example: @smallexample fputs ("Are ", stdout); fputs ("you ", stdout); fputs ("hungry?\n", stdout); @end smallexample @noindent outputs the text @samp{Are you hungry?} followed by a newline. @end deftypefun @comment stdio.h @comment ISO @deftypefun int puts (const char *@var{s}) The @code{puts} function writes the string @var{s} to the stream @code{stdout} followed by a newline. The terminating null character of the string is not written. (Note that @code{fputs} does @emph{not} write a newline as this function does.) @code{puts} is the most convenient function for printing simple messages. For example: @smallexample puts ("This is a message."); @end smallexample @noindent outputs the text @samp{This is a message.} followed by a newline. @end deftypefun @comment stdio.h @comment SVID @deftypefun int putw (int @var{w}, FILE *@var{stream}) This function writes the word @var{w} (that is, an @code{int}) to @var{stream}. It is provided for compatibility with SVID, but we recommend you use @code{fwrite} instead (@pxref{Block Input/Output}). @end deftypefun @node Character Input @section Character Input @cindex reading from a stream, by characters This section describes functions for performing character-oriented input. These functions are declared in the header file @file{stdio.h}. @pindex stdio.h These functions return an @code{int} value that is either a character of input, or the special value @code{EOF} (usually -1). It is important to store the result of these functions in a variable of type @code{int} instead of @code{char}, even when you plan to use it only as a character. Storing @code{EOF} in a @code{char} variable truncates its value to the size of a character, so that it is no longer distinguishable from the valid character @samp{(char) -1}. So always use an @code{int} for the result of @code{getc} and friends, and check for @code{EOF} after the call; once you've verified that the result is not @code{EOF}, you can be sure that it will fit in a @samp{char} variable without loss of information. @comment stdio.h @comment ISO @deftypefun int fgetc (FILE *@var{stream}) This function reads the next character as an @code{unsigned char} from the stream @var{stream} and returns its value, converted to an @code{int}. If an end-of-file condition or read error occurs, @code{EOF} is returned instead. @end deftypefun @comment stdio.h @comment ISO @deftypefun int getc (FILE *@var{stream}) This is just like @code{fgetc}, except that it is permissible (and typical) for it to be implemented as a macro that evaluates the @var{stream} argument more than once. @code{getc} is often highly optimized, so it is usually the best function to use to read a single character. @end deftypefun @comment stdio.h @comment ISO @deftypefun int getchar (void) The @code{getchar} function is equivalent to @code{getc} with @code{stdin} as the value of the @var{stream} argument. @end deftypefun Here is an example of a function that does input using @code{fgetc}. It would work just as well using @code{getc} instead, or using @code{getchar ()} instead of @w{@code{fgetc (stdin)}}. @smallexample int y_or_n_p (const char *question) @{ fputs (question, stdout); while (1) @{ int c, answer; /* @r{Write a space to separate answer from question.} */ fputc (' ', stdout); /* @r{Read the first character of the line.} @r{This should be the answer character, but might not be.} */ c = tolower (fgetc (stdin)); answer = c; /* @r{Discard rest of input line.} */ while (c != '\n' && c != EOF) c = fgetc (stdin); /* @r{Obey the answer if it was valid.} */ if (answer == 'y') return 1; if (answer == 'n') return 0; /* @r{Answer was invalid: ask for valid answer.} */ fputs ("Please answer y or n:", stdout); @} @} @end smallexample @comment stdio.h @comment SVID @deftypefun int getw (FILE *@var{stream}) This function reads a word (that is, an @code{int}) from @var{stream}. It's provided for compatibility with SVID. We recommend you use @code{fread} instead (@pxref{Block Input/Output}). Unlike @code{getc}, any @code{int} value could be a valid result. @code{getw} returns @code{EOF} when it encounters end-of-file or an error, but there is no way to distinguish this from an input word with value -1. @end deftypefun @node Line Input @section Line-Oriented Input Since many programs interpret input on the basis of lines, it's convenient to have functions to read a line of text from a stream. Standard C has functions to do this, but they aren't very safe: null characters and even (for @code{gets}) long lines can confuse them. So the GNU library provides the nonstandard @code{getline} function that makes it easy to read lines reliably. Another GNU extension, @code{getdelim}, generalizes @code{getline}. It reads a delimited record, defined as everything through the next occurrence of a specified delimiter character. All these functions are declared in @file{stdio.h}. @comment stdio.h @comment GNU @deftypefun ssize_t getline (char **@var{lineptr}, size_t *@var{n}, FILE *@var{stream}) This function reads an entire line from @var{stream}, storing the text (including the newline and a terminating null character) in a buffer and storing the buffer address in @code{*@var{lineptr}}. Before calling @code{getline}, you should place in @code{*@var{lineptr}} the address of a buffer @code{*@var{n}} bytes long, allocated with @code{malloc}. If this buffer is long enough to hold the line, @code{getline} stores the line in this buffer. Otherwise, @code{getline} makes the buffer bigger using @code{realloc}, storing the new buffer address back in @code{*@var{lineptr}} and the increased size back in @code{*@var{n}}. @xref{Unconstrained Allocation}. If you set @code{*@var{lineptr}} to a null pointer, and @code{*@var{n}} to zero, before the call, then @code{getline} allocates the initial buffer for you by calling @code{malloc}. In either case, when @code{getline} returns, @code{*@var{lineptr}} is a @code{char *} which points to the text of the line. When @code{getline} is successful, it returns the number of characters read (including the newline, but not including the terminating null). This value enables you to distinguish null characters that are part of the line from the null character inserted as a terminator. This function is a GNU extension, but it is the recommended way to read lines from a stream. The alternative standard functions are unreliable. If an error occurs or end of file is reached, @code{getline} returns @code{-1}. @end deftypefun @comment stdio.h @comment GNU @deftypefun ssize_t getdelim (char **@var{lineptr}, size_t *@var{n}, int @var{delimiter}, FILE *@var{stream}) This function is like @code{getline} except that the character which tells it to stop reading is not necessarily newline. The argument @var{delimiter} specifies the delimiter character; @code{getdelim} keeps reading until it sees that character (or end of file). The text is stored in @var{lineptr}, including the delimiter character and a terminating null. Like @code{getline}, @code{getdelim} makes @var{lineptr} bigger if it isn't big enough. @code{getline} is in fact implemented in terms of @code{getdelim}, just like this: @smallexample ssize_t getline (char **lineptr, size_t *n, FILE *stream) @{ return getdelim (lineptr, n, '\n', stream); @} @end smallexample @end deftypefun @comment stdio.h @comment ISO @deftypefun {char *} fgets (char *@var{s}, int @var{count}, FILE *@var{stream}) The @code{fgets} function reads characters from the stream @var{stream} up to and including a newline character and stores them in the string @var{s}, adding a null character to mark the end of the string. You must supply @var{count} characters worth of space in @var{s}, but the number of characters read is at most @var{count} @minus{} 1. The extra character space is used to hold the null character at the end of the string. If the system is already at end of file when you call @code{fgets}, then the contents of the array @var{s} are unchanged and a null pointer is returned. A null pointer is also returned if a read error occurs. Otherwise, the return value is the pointer @var{s}. @strong{Warning:} If the input data has a null character, you can't tell. So don't use @code{fgets} unless you know the data cannot contain a null. Don't use it to read files edited by the user because, if the user inserts a null character, you should either handle it properly or print a clear error message. We recommend using @code{getline} instead of @code{fgets}. @end deftypefun @comment stdio.h @comment ISO @deftypefn {Deprecated function} {char *} gets (char *@var{s}) The function @code{gets} reads characters from the stream @code{stdin} up to the next newline character, and stores them in the string @var{s}. The newline character is discarded (note that this differs from the behavior of @code{fgets}, which copies the newline character into the string). If @code{gets} encounters a read error or end-of-file, it returns a null pointer; otherwise it returns @var{s}. @strong{Warning:} The @code{gets} function is @strong{very dangerous} because it provides no protection against overflowing the string @var{s}. The GNU library includes it for compatibility only. You should @strong{always} use @code{fgets} or @code{getline} instead. To remind you of this, the linker (if using GNU @code{ld}) will issue a warning whenever you use @code{gets}. @end deftypefn @node Unreading @section Unreading @cindex peeking at input @cindex unreading characters @cindex pushing input back In parser programs it is often useful to examine the next character in the input stream without removing it from the stream. This is called ``peeking ahead'' at the input because your program gets a glimpse of the input it will read next. Using stream I/O, you can peek ahead at input by first reading it and then @dfn{unreading} it (also called @dfn{pushing it back} on the stream). Unreading a character makes it available to be input again from the stream, by the next call to @code{fgetc} or other input function on that stream. @menu * Unreading Idea:: An explanation of unreading with pictures. * How Unread:: How to call @code{ungetc} to do unreading. @end menu @node Unreading Idea @subsection What Unreading Means Here is a pictorial explanation of unreading. Suppose you have a stream reading a file that contains just six characters, the letters @samp{foobar}. Suppose you have read three characters so far. The situation looks like this: @smallexample f o o b a r ^ @end smallexample @noindent so the next input character will be @samp{b}. @c @group Invalid outside @example If instead of reading @samp{b} you unread the letter @samp{o}, you get a situation like this: @smallexample f o o b a r | o-- ^ @end smallexample @noindent so that the next input characters will be @samp{o} and @samp{b}. @c @end group @c @group If you unread @samp{9} instead of @samp{o}, you get this situation: @smallexample f o o b a r | 9-- ^ @end smallexample @noindent so that the next input characters will be @samp{9} and @samp{b}. @c @end group @node How Unread @subsection Using @code{ungetc} To Do Unreading The function to unread a character is called @code{ungetc}, because it reverses the action of @code{getc}. @comment stdio.h @comment ISO @deftypefun int ungetc (int @var{c}, FILE *@var{stream}) The @code{ungetc} function pushes back the character @var{c} onto the input stream @var{stream}. So the next input from @var{stream} will read @var{c} before anything else. If @var{c} is @code{EOF}, @code{ungetc} does nothing and just returns @code{EOF}. This lets you call @code{ungetc} with the return value of @code{getc} without needing to check for an error from @code{getc}. The character that you push back doesn't have to be the same as the last character that was actually read from the stream. In fact, it isn't necessary to actually read any characters from the stream before unreading them with @code{ungetc}! But that is a strange way to write a program; usually @code{ungetc} is used only to unread a character that was just read from the same stream. The GNU C library only supports one character of pushback---in other words, it does not work to call @code{ungetc} twice without doing input in between. Other systems might let you push back multiple characters; then reading from the stream retrieves the characters in the reverse order that they were pushed. Pushing back characters doesn't alter the file; only the internal buffering for the stream is affected. If a file positioning function (such as @code{fseek}, @code{fseeko} or @code{rewind}; @pxref{File Positioning}) is called, any pending pushed-back characters are discarded. Unreading a character on a stream that is at end of file clears the end-of-file indicator for the stream, because it makes the character of input available. After you read that character, trying to read again will encounter end of file. @end deftypefun Here is an example showing the use of @code{getc} and @code{ungetc} to skip over whitespace characters. When this function reaches a non-whitespace character, it unreads that character to be seen again on the next read operation on the stream. @smallexample #include #include void skip_whitespace (FILE *stream) @{ int c; do /* @r{No need to check for @code{EOF} because it is not} @r{@code{isspace}, and @code{ungetc} ignores @code{EOF}.} */ c = getc (stream); while (isspace (c)); ungetc (c, stream); @} @end smallexample @node Block Input/Output @section Block Input/Output This section describes how to do input and output operations on blocks of data. You can use these functions to read and write binary data, as well as to read and write text in fixed-size blocks instead of by characters or lines. @cindex binary I/O to a stream @cindex block I/O to a stream @cindex reading from a stream, by blocks @cindex writing to a stream, by blocks Binary files are typically used to read and write blocks of data in the same format as is used to represent the data in a running program. In other words, arbitrary blocks of memory---not just character or string objects---can be written to a binary file, and meaningfully read in again by the same program. Storing data in binary form is often considerably more efficient than using the formatted I/O functions. Also, for floating-point numbers, the binary form avoids possible loss of precision in the conversion process. On the other hand, binary files can't be examined or modified easily using many standard file utilities (such as text editors), and are not portable between different implementations of the language, or different kinds of computers. These functions are declared in @file{stdio.h}. @pindex stdio.h @comment stdio.h @comment ISO @deftypefun size_t fread (void *@var{data}, size_t @var{size}, size_t @var{count}, FILE *@var{stream}) This function reads up to @var{count} objects of size @var{size} into the array @var{data}, from the stream @var{stream}. It returns the number of objects actually read, which might be less than @var{count} if a read error occurs or the end of the file is reached. This function returns a value of zero (and doesn't read anything) if either @var{size} or @var{count} is zero. If @code{fread} encounters end of file in the middle of an object, it returns the number of complete objects read, and discards the partial object. Therefore, the stream remains at the actual end of the file. @end deftypefun @comment stdio.h @comment ISO @deftypefun size_t fwrite (const void *@var{data}, size_t @var{size}, size_t @var{count}, FILE *@var{stream}) This function writes up to @var{count} objects of size @var{size} from the array @var{data}, to the stream @var{stream}. The return value is normally @var{count}, if the call succeeds. Any other value indicates some sort of error, such as running out of space. @end deftypefun @node Formatted Output @section Formatted Output @cindex format string, for @code{printf} @cindex template, for @code{printf} @cindex formatted output to a stream @cindex writing to a stream, formatted The functions described in this section (@code{printf} and related functions) provide a convenient way to perform formatted output. You call @code{printf} with a @dfn{format string} or @dfn{template string} that specifies how to format the values of the remaining arguments. Unless your program is a filter that specifically performs line- or character-oriented processing, using @code{printf} or one of the other related functions described in this section is usually the easiest and most concise way to perform output. These functions are especially useful for printing error messages, tables of data, and the like. @menu * Formatted Output Basics:: Some examples to get you started. * Output Conversion Syntax:: General syntax of conversion specifications. * Table of Output Conversions:: Summary of output conversions and what they do. * Integer Conversions:: Details about formatting of integers. * Floating-Point Conversions:: Details about formatting of floating-point numbers. * Other Output Conversions:: Details about formatting of strings, characters, pointers, and the like. * Formatted Output Functions:: Descriptions of the actual functions. * Dynamic Output:: Functions that allocate memory for the output. * Variable Arguments Output:: @code{vprintf} and friends. * Parsing a Template String:: What kinds of args does a given template call for? * Example of Parsing:: Sample program using @code{parse_printf_format}. @end menu @node Formatted Output Basics @subsection Formatted Output Basics The @code{printf} function can be used to print any number of arguments. The template string argument you supply in a call provides information not only about the number of additional arguments, but also about their types and what style should be used for printing them. Ordinary characters in the template string are simply written to the output stream as-is, while @dfn{conversion specifications} introduced by a @samp{%} character in the template cause subsequent arguments to be formatted and written to the output stream. For example, @cindex conversion specifications (@code{printf}) @smallexample int pct = 37; char filename[] = "foo.txt"; printf ("Processing of `%s' is %d%% finished.\nPlease be patient.\n", filename, pct); @end smallexample @noindent produces output like @smallexample Processing of `foo.txt' is 37% finished. Please be patient. @end smallexample This example shows the use of the @samp{%d} conversion to specify that an @code{int} argument should be printed in decimal notation, the @samp{%s} conversion to specify printing of a string argument, and the @samp{%%} conversion to print a literal @samp{%} character. There are also conversions for printing an integer argument as an unsigned value in octal, decimal, or hexadecimal radix (@samp{%o}, @samp{%u}, or @samp{%x}, respectively); or as a character value (@samp{%c}). Floating-point numbers can be printed in normal, fixed-point notation using the @samp{%f} conversion or in exponential notation using the @samp{%e} conversion. The @samp{%g} conversion uses either @samp{%e} or @samp{%f} format, depending on what is more appropriate for the magnitude of the particular number. You can control formatting more precisely by writing @dfn{modifiers} between the @samp{%} and the character that indicates which conversion to apply. These slightly alter the ordinary behavior of the conversion. For example, most conversion specifications permit you to specify a minimum field width and a flag indicating whether you want the result left- or right-justified within the field. The specific flags and modifiers that are permitted and their interpretation vary depending on the particular conversion. They're all described in more detail in the following sections. Don't worry if this all seems excessively complicated at first; you can almost always get reasonable free-format output without using any of the modifiers at all. The modifiers are mostly used to make the output look ``prettier'' in tables. @node Output Conversion Syntax @subsection Output Conversion Syntax This section provides details about the precise syntax of conversion specifications that can appear in a @code{printf} template string. Characters in the template string that are not part of a conversion specification are printed as-is to the output stream. Multibyte character sequences (@pxref{Character Set Handling}) are permitted in a template string. The conversion specifications in a @code{printf} template string have the general form: @example % @r{[} @var{param-no} @r{$]} @var{flags} @var{width} @r{[} . @var{precision} @r{]} @var{type} @var{conversion} @end example For example, in the conversion specifier @samp{%-10.8ld}, the @samp{-} is a flag, @samp{10} specifies the field width, the precision is @samp{8}, the letter @samp{l} is a type modifier, and @samp{d} specifies the conversion style. (This particular type specifier says to print a @code{long int} argument in decimal notation, with a minimum of 8 digits left-justified in a field at least 10 characters wide.) In more detail, output conversion specifications consist of an initial @samp{%} character followed in sequence by: @itemize @bullet @item An optional specification of the parameter used for this format. Normally the parameters to the @code{printf} function a assigned to the formats in the order of appearance in the format string. But in some situations (such as message translation) this is not desirable and this extension allows to specify and explicit parameter to be used. The @var{param-no} part of the format must be an integer in the range of 1 to the maximum number of arguments present to the function call. Some implementations limit this number to a certainly upper bound. The exact limit can be retrieved by the following constant. @defvr Macro NL_ARGMAX The value of @code{ARGMAX} is the maximum value allowed for the specification of an positional parameter in a @code{printf} call. The actual value in effect at runtime can be retrieved by using @code{sysconf} using the @code{_SC_NL_ARGMAX} parameter @pxref{Sysconf Definition}. Some system have a quite low limit such as @math{9} for @w{System V} systems. The GNU C library has no real limit. @end defvr If any of the formats has a specification for the parameter position all of them in the format string shall have one. Otherwise the behaviour is undefined. @item Zero or more @dfn{flag characters} that modify the normal behavior of the conversion specification. @cindex flag character (@code{printf}) @item An optional decimal integer specifying the @dfn{minimum field width}. If the normal conversion produces fewer characters than this, the field is padded with spaces to the specified width. This is a @emph{minimum} value; if the normal conversion produces more characters than this, the field is @emph{not} truncated. Normally, the output is right-justified within the field. @cindex minimum field width (@code{printf}) You can also specify a field width of @samp{*}. This means that the next argument in the argument list (before the actual value to be printed) is used as the field width. The value must be an @code{int}. If the value is negative, this means to set the @samp{-} flag (see below) and to use the absolute value as the field width. @item An optional @dfn{precision} to specify the number of digits to be written for the numeric conversions. If the precision is specified, it consists of a period (@samp{.}) followed optionally by a decimal integer (which defaults to zero if omitted). @cindex precision (@code{printf}) You can also specify a precision of @samp{*}. This means that the next argument in the argument list (before the actual value to be printed) is used as the precision. The value must be an @code{int}, and is ignored if it is negative. If you specify @samp{*} for both the field width and precision, the field width argument precedes the precision argument. Other C library versions may not recognize this syntax. @item An optional @dfn{type modifier character}, which is used to specify the data type of the corresponding argument if it differs from the default type. (For example, the integer conversions assume a type of @code{int}, but you can specify @samp{h}, @samp{l}, or @samp{L} for other integer types.) @cindex type modifier character (@code{printf}) @item A character that specifies the conversion to be applied. @end itemize The exact options that are permitted and how they are interpreted vary between the different conversion specifiers. See the descriptions of the individual conversions for information about the particular options that they use. With the @samp{-Wformat} option, the GNU C compiler checks calls to @code{printf} and related functions. It examines the format string and verifies that the correct number and types of arguments are supplied. There is also a GNU C syntax to tell the compiler that a function you write uses a @code{printf}-style format string. @xref{Function Attributes, , Declaring Attributes of Functions, gcc.info, Using GNU CC}, for more information. @node Table of Output Conversions @subsection Table of Output Conversions @cindex output conversions, for @code{printf} Here is a table summarizing what all the different conversions do: @table @asis @item @samp{%d}, @samp{%i} Print an integer as a signed decimal number. @xref{Integer Conversions}, for details. @samp{%d} and @samp{%i} are synonymous for output, but are different when used with @code{scanf} for input (@pxref{Table of Input Conversions}). @item @samp{%o} Print an integer as an unsigned octal number. @xref{Integer Conversions}, for details. @item @samp{%u} Print an integer as an unsigned decimal number. @xref{Integer Conversions}, for details. @item @samp{%x}, @samp{%X} Print an integer as an unsigned hexadecimal number. @samp{%x} uses lower-case letters and @samp{%X} uses upper-case. @xref{Integer Conversions}, for details. @item @samp{%f} Print a floating-point number in normal (fixed-point) notation. @xref{Floating-Point Conversions}, for details. @item @samp{%e}, @samp{%E} Print a floating-point number in exponential notation. @samp{%e} uses lower-case letters and @samp{%E} uses upper-case. @xref{Floating-Point Conversions}, for details. @item @samp{%g}, @samp{%G} Print a floating-point number in either normal or exponential notation, whichever is more appropriate for its magnitude. @samp{%g} uses lower-case letters and @samp{%G} uses upper-case. @xref{Floating-Point Conversions}, for details. @item @samp{%a}, @samp{%A} Print a floating-point number in a hexadecimal fractional notation which the exponent to base 2 represented in decimal digits. @samp{%a} uses lower-case letters and @samp{%A} uses upper-case. @xref{Floating-Point Conversions}, for details. @item @samp{%c} Print a single character. @xref{Other Output Conversions}. @item @samp{%s} Print a string. @xref{Other Output Conversions}. @item @samp{%p} Print the value of a pointer. @xref{Other Output Conversions}. @item @samp{%n} Get the number of characters printed so far. @xref{Other Output Conversions}. Note that this conversion specification never produces any output. @item @samp{%m} Print the string corresponding to the value of @code{errno}. (This is a GNU extension.) @xref{Other Output Conversions}. @item @samp{%%} Print a literal @samp{%} character. @xref{Other Output Conversions}. @end table If the syntax of a conversion specification is invalid, unpredictable things will happen, so don't do this. If there aren't enough function arguments provided to supply values for all the conversion specifications in the template string, or if the arguments are not of the correct types, the results are unpredictable. If you supply more arguments than conversion specifications, the extra argument values are simply ignored; this is sometimes useful. @node Integer Conversions @subsection Integer Conversions This section describes the options for the @samp{%d}, @samp{%i}, @samp{%o}, @samp{%u}, @samp{%x}, and @samp{%X} conversion specifications. These conversions print integers in various formats. The @samp{%d} and @samp{%i} conversion specifications both print an @code{int} argument as a signed decimal number; while @samp{%o}, @samp{%u}, and @samp{%x} print the argument as an unsigned octal, decimal, or hexadecimal number (respectively). The @samp{%X} conversion specification is just like @samp{%x} except that it uses the characters @samp{ABCDEF} as digits instead of @samp{abcdef}. The following flags are meaningful: @table @asis @item @samp{-} Left-justify the result in the field (instead of the normal right-justification). @item @samp{+} For the signed @samp{%d} and @samp{%i} conversions, print a plus sign if the value is positive. @item @samp{ } For the signed @samp{%d} and @samp{%i} conversions, if the result doesn't start with a plus or minus sign, prefix it with a space character instead. Since the @samp{+} flag ensures that the result includes a sign, this flag is ignored if you supply both of them. @item @samp{#} For the @samp{%o} conversion, this forces the leading digit to be @samp{0}, as if by increasing the precision. For @samp{%x} or @samp{%X}, this prefixes a leading @samp{0x} or @samp{0X} (respectively) to the result. This doesn't do anything useful for the @samp{%d}, @samp{%i}, or @samp{%u} conversions. Using this flag produces output which can be parsed by the @code{strtoul} function (@pxref{Parsing of Integers}) and @code{scanf} with the @samp{%i} conversion (@pxref{Numeric Input Conversions}). @item @samp{'} Separate the digits into groups as specified by the locale specified for the @code{LC_NUMERIC} category; @pxref{General Numeric}. This flag is a GNU extension. @item @samp{0} Pad the field with zeros instead of spaces. The zeros are placed after any indication of sign or base. This flag is ignored if the @samp{-} flag is also specified, or if a precision is specified. @end table If a precision is supplied, it specifies the minimum number of digits to appear; leading zeros are produced if necessary. If you don't specify a precision, the number is printed with as many digits as it needs. If you convert a value of zero with an explicit precision of zero, then no characters at all are produced. Without a type modifier, the corresponding argument is treated as an @code{int} (for the signed conversions @samp{%i} and @samp{%d}) or @code{unsigned int} (for the unsigned conversions @samp{%o}, @samp{%u}, @samp{%x}, and @samp{%X}). Recall that since @code{printf} and friends are variadic, any @code{char} and @code{short} arguments are automatically converted to @code{int} by the default argument promotions. For arguments of other integer types, you can use these modifiers: @table @samp @item hh Specifies that the argument is a @code{signed char} or @code{unsigned char}, as appropriate. A @code{char} argument is converted to an @code{int} or @code{unsigned int} by the default argument promotions anyway, but the @samp{h} modifier says to convert it back to a @code{char} again. This modifier was introduced in @w{ISO C 9x}. @item h Specifies that the argument is a @code{short int} or @code{unsigned short int}, as appropriate. A @code{short} argument is converted to an @code{int} or @code{unsigned int} by the default argument promotions anyway, but the @samp{h} modifier says to convert it back to a @code{short} again. @item j Specifies that the argument is a @code{intmax_t} or @code{uintmax_t}, as appropriate. This modifier was introduced in @w{ISO C 9x}. @item l Specifies that the argument is a @code{long int} or @code{unsigned long int}, as appropriate. Two @samp{l} characters is like the @samp{L} modifier, below. @item L @itemx ll @itemx q Specifies that the argument is a @code{long long int}. (This type is an extension supported by the GNU C compiler. On systems that don't support extra-long integers, this is the same as @code{long int}.) The @samp{q} modifier is another name for the same thing, which comes from 4.4 BSD; a @w{@code{long long int}} is sometimes called a ``quad'' @code{int}. @item t Specifies that the argument is a @code{ptrdiff_t}. This modifier was introduced in @w{ISO C 9x}. @item z @itemx Z Specifies that the argument is a @code{size_t}. @samp{z} was introduced in @w{ISO C 9x}. @samp{Z} is a GNU extension predating this addition and should not be used in new code. @end table Here is an example. Using the template string: @smallexample "|%5d|%-5d|%+5d|%+-5d|% 5d|%05d|%5.0d|%5.2d|%d|\n" @end smallexample @noindent to print numbers using the different options for the @samp{%d} conversion gives results like: @smallexample | 0|0 | +0|+0 | 0|00000| | 00|0| | 1|1 | +1|+1 | 1|00001| 1| 01|1| | -1|-1 | -1|-1 | -1|-0001| -1| -01|-1| |100000|100000|+100000| 100000|100000|100000|100000|100000| @end smallexample In particular, notice what happens in the last case where the number is too large to fit in the minimum field width specified. Here are some more examples showing how unsigned integers print under various format options, using the template string: @smallexample "|%5u|%5o|%5x|%5X|%#5o|%#5x|%#5X|%#10.8x|\n" @end smallexample @smallexample | 0| 0| 0| 0| 0| 0x0| 0X0|0x00000000| | 1| 1| 1| 1| 01| 0x1| 0X1|0x00000001| |100000|303240|186a0|186A0|0303240|0x186a0|0X186A0|0x000186a0| @end smallexample @node Floating-Point Conversions @subsection Floating-Point Conversions This section discusses the conversion specifications for floating-point numbers: the @samp{%f}, @samp{%e}, @samp{%E}, @samp{%g}, and @samp{%G} conversions. The @samp{%f} conversion prints its argument in fixed-point notation, producing output of the form @w{[@code{-}]@var{ddd}@code{.}@var{ddd}}, where the number of digits following the decimal point is controlled by the precision you specify. The @samp{%e} conversion prints its argument in exponential notation, producing output of the form @w{[@code{-}]@var{d}@code{.}@var{ddd}@code{e}[@code{+}|@code{-}]@var{dd}}. Again, the number of digits following the decimal point is controlled by the precision. The exponent always contains at least two digits. The @samp{%E} conversion is similar but the exponent is marked with the letter @samp{E} instead of @samp{e}. The @samp{%g} and @samp{%G} conversions print the argument in the style of @samp{%e} or @samp{%E} (respectively) if the exponent would be less than -4 or greater than or equal to the precision; otherwise they use the @samp{%f} style. Trailing zeros are removed from the fractional portion of the result and a decimal-point character appears only if it is followed by a digit. The @samp{%a} and @samp{%A} conversions are meant for representing floating-point numbers exactly in textual form so that they can be exchanged as texts between different programs and/or machines. The numbers are represented is the form @w{[@code{-}]@code{0x}@var{h}@code{.}@var{hhh}@code{p}[@code{+}|@code{-}]@var{dd}}. At the left of the decimal-point character exactly one digit is print. This character is only @code{0} if the number is denormalized. Otherwise the value is unspecified; it is implemention dependent how many bits are used. The number of hexadecimal digits on the right side of the decimal-point character is equal to the precision. If the precision is zero it is determined to be large enough to provide an exact representation of the number (or it is large enough to distinguish two adjacent values if the @code{FLT_RADIX} is not a power of 2, @pxref{Floating Point Parameters}). For the @samp{%a} conversion lower-case characters are used to represent the hexadecimal number and the prefix and exponent sign are printed as @code{0x} and @code{p} respectively. Otherwise upper-case characters are used and @code{0X} and @code{P} are used for the representation of prefix and exponent string. The exponent to the base of two is printed as a decimal number using at least one digit but at most as many digits as necessary to represent the value exactly. If the value to be printed represents infinity or a NaN, the output is @w{[@code{-}]@code{inf}} or @code{nan} respectively if the conversion specifier is @samp{%a}, @samp{%e}, @samp{%f}, or @samp{%g} and it is @w{[@code{-}]@code{INF}} or @code{NAN} respectively if the conversion is @samp{%A}, @samp{%E}, or @samp{%G}. The following flags can be used to modify the behavior: @comment We use @asis instead of @samp so we can have ` ' as an item. @table @asis @item @samp{-} Left-justify the result in the field. Normally the result is right-justified. @item @samp{+} Always include a plus or minus sign in the result. @item @samp{ } If the result doesn't start with a plus or minus sign, prefix it with a space instead. Since the @samp{+} flag ensures that the result includes a sign, this flag is ignored if you supply both of them. @item @samp{#} Specifies that the result should always include a decimal point, even if no digits follow it. For the @samp{%g} and @samp{%G} conversions, this also forces trailing zeros after the decimal point to be left in place where they would otherwise be removed. @item @samp{'} Separate the digits of the integer part of the result into groups as specified by the locale specified for the @code{LC_NUMERIC} category; @pxref{General Numeric}. This flag is a GNU extension. @item @samp{0} Pad the field with zeros instead of spaces; the zeros are placed after any sign. This flag is ignored if the @samp{-} flag is also specified. @end table The precision specifies how many digits follow the decimal-point character for the @samp{%f}, @samp{%e}, and @samp{%E} conversions. For these conversions, the default precision is @code{6}. If the precision is explicitly @code{0}, this suppresses the decimal point character entirely. For the @samp{%g} and @samp{%G} conversions, the precision specifies how many significant digits to print. Significant digits are the first digit before the decimal point, and all the digits after it. If the precision is @code{0} or not specified for @samp{%g} or @samp{%G}, it is treated like a value of @code{1}. If the value being printed cannot be expressed accurately in the specified number of digits, the value is rounded to the nearest number that fits. Without a type modifier, the floating-point conversions use an argument of type @code{double}. (By the default argument promotions, any @code{float} arguments are automatically converted to @code{double}.) The following type modifier is supported: @table @samp @item L An uppercase @samp{L} specifies that the argument is a @code{long double}. @end table Here are some examples showing how numbers print using the various floating-point conversions. All of the numbers were printed using this template string: @smallexample "|%13.4a|%13.4f|%13.4e|%13.4g|\n" @end smallexample Here is the output: @smallexample | 0x0.0000p+0| 0.0000| 0.0000e+00| 0| | 0x1.0000p-1| 0.5000| 5.0000e-01| 0.5| | 0x1.0000p+0| 1.0000| 1.0000e+00| 1| | -0x1.0000p+0| -1.0000| -1.0000e+00| -1| | 0x1.9000p+6| 100.0000| 1.0000e+02| 100| | 0x1.f400p+9| 1000.0000| 1.0000e+03| 1000| | 0x1.3880p+13| 10000.0000| 1.0000e+04| 1e+04| | 0x1.81c8p+13| 12345.0000| 1.2345e+04| 1.234e+04| | 0x1.86a0p+16| 100000.0000| 1.0000e+05| 1e+05| | 0x1.e240p+16| 123456.0000| 1.2346e+05| 1.235e+05| @end smallexample Notice how the @samp{%g} conversion drops trailing zeros. @node Other Output Conversions @subsection Other Output Conversions This section describes miscellaneous conversions for @code{printf}. The @samp{%c} conversion prints a single character. The @code{int} argument is first converted to an @code{unsigned char}. The @samp{-} flag can be used to specify left-justification in the field, but no other flags are defined, and no precision or type modifier can be given. For example: @smallexample printf ("%c%c%c%c%c", 'h', 'e', 'l', 'l', 'o'); @end smallexample @noindent prints @samp{hello}. The @samp{%s} conversion prints a string. The corresponding argument must be of type @code{char *} (or @code{const char *}). A precision can be specified to indicate the maximum number of characters to write; otherwise characters in the string up to but not including the terminating null character are written to the output stream. The @samp{-} flag can be used to specify left-justification in the field, but no other flags or type modifiers are defined for this conversion. For example: @smallexample printf ("%3s%-6s", "no", "where"); @end smallexample @noindent prints @samp{ nowhere }. If you accidentally pass a null pointer as the argument for a @samp{%s} conversion, the GNU library prints it as @samp{(null)}. We think this is more useful than crashing. But it's not good practice to pass a null argument intentionally. The @samp{%m} conversion prints the string corresponding to the error code in @code{errno}. @xref{Error Messages}. Thus: @smallexample fprintf (stderr, "can't open `%s': %m\n", filename); @end smallexample @noindent is equivalent to: @smallexample fprintf (stderr, "can't open `%s': %s\n", filename, strerror (errno)); @end smallexample @noindent The @samp{%m} conversion is a GNU C library extension. The @samp{%p} conversion prints a pointer value. The corresponding argument must be of type @code{void *}. In practice, you can use any type of pointer. In the GNU system, non-null pointers are printed as unsigned integers, as if a @samp{%#x} conversion were used. Null pointers print as @samp{(nil)}. (Pointers might print differently in other systems.) For example: @smallexample printf ("%p", "testing"); @end smallexample @noindent prints @samp{0x} followed by a hexadecimal number---the address of the string constant @code{"testing"}. It does not print the word @samp{testing}. You can supply the @samp{-} flag with the @samp{%p} conversion to specify left-justification, but no other flags, precision, or type modifiers are defined. The @samp{%n} conversion is unlike any of the other output conversions. It uses an argument which must be a pointer to an @code{int}, but instead of printing anything it stores the number of characters printed so far by this call at that location. The @samp{h} and @samp{l} type modifiers are permitted to specify that the argument is of type @code{short int *} or @code{long int *} instead of @code{int *}, but no flags, field width, or precision are permitted. For example, @smallexample int nchar; printf ("%d %s%n\n", 3, "bears", &nchar); @end smallexample @noindent prints: @smallexample 3 bears @end smallexample @noindent and sets @code{nchar} to @code{7}, because @samp{3 bears} is seven characters. The @samp{%%} conversion prints a literal @samp{%} character. This conversion doesn't use an argument, and no flags, field width, precision, or type modifiers are permitted. @node Formatted Output Functions @subsection Formatted Output Functions This section describes how to call @code{printf} and related functions. Prototypes for these functions are in the header file @file{stdio.h}. Because these functions take a variable number of arguments, you @emph{must} declare prototypes for them before using them. Of course, the easiest way to make sure you have all the right prototypes is to just include @file{stdio.h}. @pindex stdio.h @comment stdio.h @comment ISO @deftypefun int printf (const char *@var{template}, @dots{}) The @code{printf} function prints the optional arguments under the control of the template string @var{template} to the stream @code{stdout}. It returns the number of characters printed, or a negative value if there was an output error. @end deftypefun @comment stdio.h @comment ISO @deftypefun int fprintf (FILE *@var{stream}, const char *@var{template}, @dots{}) This function is just like @code{printf}, except that the output is written to the stream @var{stream} instead of @code{stdout}. @end deftypefun @comment stdio.h @comment ISO @deftypefun int sprintf (char *@var{s}, const char *@var{template}, @dots{}) This is like @code{printf}, except that the output is stored in the character array @var{s} instead of written to a stream. A null character is written to mark the end of the string. The @code{sprintf} function returns the number of characters stored in the array @var{s}, not including the terminating null character. The behavior of this function is undefined if copying takes place between objects that overlap---for example, if @var{s} is also given as an argument to be printed under control of the @samp{%s} conversion. @xref{Copying and Concatenation}. @strong{Warning:} The @code{sprintf} function can be @strong{dangerous} because it can potentially output more characters than can fit in the allocation size of the string @var{s}. Remember that the field width given in a conversion specification is only a @emph{minimum} value. To avoid this problem, you can use @code{snprintf} or @code{asprintf}, described below. @end deftypefun @comment stdio.h @comment GNU @deftypefun int snprintf (char *@var{s}, size_t @var{size}, const char *@var{template}, @dots{}) The @code{snprintf} function is similar to @code{sprintf}, except that the @var{size} argument specifies the maximum number of characters to produce. The trailing null character is counted towards this limit, so you should allocate at least @var{size} characters for the string @var{s}. The return value is the number of characters which would be generated for the given input, excluding the trailing null. If this value is greater or equal to @var{size}, not all characters from the result have been stored in @var{s}. You should try again with a bigger output string. Here is an example of doing this: @smallexample @group /* @r{Construct a message describing the value of a variable} @r{whose name is @var{name} and whose value is @var{value}.} */ char * make_message (char *name, char *value) @{ /* @r{Guess we need no more than 100 chars of space.} */ int size = 100; char *buffer = (char *) xmalloc (size); int nchars; @end group @group /* @r{Try to print in the allocated space.} */ nchars = snprintf (buffer, size, "value of %s is %s", name, value); @end group @group if (nchars >= size) @{ /* @r{Reallocate buffer now that we know how much space is needed.} */ buffer = (char *) xrealloc (buffer, nchars + 1); /* @r{Try again.} */ snprintf (buffer, size, "value of %s is %s", name, value); @} /* @r{The last call worked, return the string.} */ return buffer; @} @end group @end smallexample In practice, it is often easier just to use @code{asprintf}, below. @strong{Attention:} In the GNU C library version 2.0 the return value is the number of characters stored, not including the terminating null. If this value equals @code{@var{size} - 1}, then there was not enough space in @var{s} for all the output. This change was necessary with the adoption of snprintf by ISO C9x. @end deftypefun @node Dynamic Output @subsection Dynamically Allocating Formatted Output The functions in this section do formatted output and place the results in dynamically allocated memory. @comment stdio.h @comment GNU @deftypefun int asprintf (char **@var{ptr}, const char *@var{template}, @dots{}) This function is similar to @code{sprintf}, except that it dynamically allocates a string (as with @code{malloc}; @pxref{Unconstrained Allocation}) to hold the output, instead of putting the output in a buffer you allocate in advance. The @var{ptr} argument should be the address of a @code{char *} object, and @code{asprintf} stores a pointer to the newly allocated string at that location. Here is how to use @code{asprintf} to get the same result as the @code{snprintf} example, but more easily: @smallexample /* @r{Construct a message describing the value of a variable} @r{whose name is @var{name} and whose value is @var{value}.} */ char * make_message (char *name, char *value) @{ char *result; asprintf (&result, "value of %s is %s", name, value); return result; @} @end smallexample @end deftypefun @comment stdio.h @comment GNU @deftypefun int obstack_printf (struct obstack *@var{obstack}, const char *@var{template}, @dots{}) This function is similar to @code{asprintf}, except that it uses the obstack @var{obstack} to allocate the space. @xref{Obstacks}. The characters are written onto the end of the current object. To get at them, you must finish the object with @code{obstack_finish} (@pxref{Growing Objects}).@refill @end deftypefun @node Variable Arguments Output @subsection Variable Arguments Output Functions The functions @code{vprintf} and friends are provided so that you can define your own variadic @code{printf}-like functions that make use of the same internals as the built-in formatted output functions. The most natural way to define such functions would be to use a language construct to say, ``Call @code{printf} and pass this template plus all of my arguments after the first five.'' But there is no way to do this in C, and it would be hard to provide a way, since at the C language level there is no way to tell how many arguments your function received. Since that method is impossible, we provide alternative functions, the @code{vprintf} series, which lets you pass a @code{va_list} to describe ``all of my arguments after the first five.'' When it is sufficient to define a macro rather than a real function, the GNU C compiler provides a way to do this much more easily with macros. For example: @smallexample #define myprintf(a, b, c, d, e, rest...) \ printf (mytemplate , ## rest...) @end smallexample @noindent @xref{Macro Varargs, , Macros with Variable Numbers of Arguments, gcc.info, Using GNU CC}, for details. But this is limited to macros, and does not apply to real functions at all. Before calling @code{vprintf} or the other functions listed in this section, you @emph{must} call @code{va_start} (@pxref{Variadic Functions}) to initialize a pointer to the variable arguments. Then you can call @code{va_arg} to fetch the arguments that you want to handle yourself. This advances the pointer past those arguments. Once your @code{va_list} pointer is pointing at the argument of your choice, you are ready to call @code{vprintf}. That argument and all subsequent arguments that were passed to your function are used by @code{vprintf} along with the template that you specified separately. In some other systems, the @code{va_list} pointer may become invalid after the call to @code{vprintf}, so you must not use @code{va_arg} after you call @code{vprintf}. Instead, you should call @code{va_end} to retire the pointer from service. However, you can safely call @code{va_start} on another pointer variable and begin fetching the arguments again through that pointer. Calling @code{vprintf} does not destroy the argument list of your function, merely the particular pointer that you passed to it. GNU C does not have such restrictions. You can safely continue to fetch arguments from a @code{va_list} pointer after passing it to @code{vprintf}, and @code{va_end} is a no-op. (Note, however, that subsequent @code{va_arg} calls will fetch the same arguments which @code{vprintf} previously used.) Prototypes for these functions are declared in @file{stdio.h}. @pindex stdio.h @comment stdio.h @comment ISO @deftypefun int vprintf (const char *@var{template}, va_list @var{ap}) This function is similar to @code{printf} except that, instead of taking a variable number of arguments directly, it takes an argument list pointer @var{ap}. @end deftypefun @comment stdio.h @comment ISO @deftypefun int vfprintf (FILE *@var{stream}, const char *@var{template}, va_list @var{ap}) This is the equivalent of @code{fprintf} with the variable argument list specified directly as for @code{vprintf}. @end deftypefun @comment stdio.h @comment ISO @deftypefun int vsprintf (char *@var{s}, const char *@var{template}, va_list @var{ap}) This is the equivalent of @code{sprintf} with the variable argument list specified directly as for @code{vprintf}. @end deftypefun @comment stdio.h @comment GNU @deftypefun int vsnprintf (char *@var{s}, size_t @var{size}, const char *@var{template}, va_list @var{ap}) This is the equivalent of @code{snprintf} with the variable argument list specified directly as for @code{vprintf}. @end deftypefun @comment stdio.h @comment GNU @deftypefun int vasprintf (char **@var{ptr}, const char *@var{template}, va_list @var{ap}) The @code{vasprintf} function is the equivalent of @code{asprintf} with the variable argument list specified directly as for @code{vprintf}. @end deftypefun @comment stdio.h @comment GNU @deftypefun int obstack_vprintf (struct obstack *@var{obstack}, const char *@var{template}, va_list @var{ap}) The @code{obstack_vprintf} function is the equivalent of @code{obstack_printf} with the variable argument list specified directly as for @code{vprintf}.@refill @end deftypefun Here's an example showing how you might use @code{vfprintf}. This is a function that prints error messages to the stream @code{stderr}, along with a prefix indicating the name of the program (@pxref{Error Messages}, for a description of @code{program_invocation_short_name}). @smallexample @group #include #include void eprintf (const char *template, ...) @{ va_list ap; extern char *program_invocation_short_name; fprintf (stderr, "%s: ", program_invocation_short_name); va_start (ap, template); vfprintf (stderr, template, ap); va_end (ap); @} @end group @end smallexample @noindent You could call @code{eprintf} like this: @smallexample eprintf ("file `%s' does not exist\n", filename); @end smallexample In GNU C, there is a special construct you can use to let the compiler know that a function uses a @code{printf}-style format string. Then it can check the number and types of arguments in each call to the function, and warn you when they do not match the format string. For example, take this declaration of @code{eprintf}: @smallexample void eprintf (const char *template, ...) __attribute__ ((format (printf, 1, 2))); @end smallexample @noindent This tells the compiler that @code{eprintf} uses a format string like @code{printf} (as opposed to @code{scanf}; @pxref{Formatted Input}); the format string appears as the first argument; and the arguments to satisfy the format begin with the second. @xref{Function Attributes, , Declaring Attributes of Functions, gcc.info, Using GNU CC}, for more information. @node Parsing a Template String @subsection Parsing a Template String @cindex parsing a template string You can use the function @code{parse_printf_format} to obtain information about the number and types of arguments that are expected by a given template string. This function permits interpreters that provide interfaces to @code{printf} to avoid passing along invalid arguments from the user's program, which could cause a crash. All the symbols described in this section are declared in the header file @file{printf.h}. @comment printf.h @comment GNU @deftypefun size_t parse_printf_format (const char *@var{template}, size_t @var{n}, int *@var{argtypes}) This function returns information about the number and types of arguments expected by the @code{printf} template string @var{template}. The information is stored in the array @var{argtypes}; each element of this array describes one argument. This information is encoded using the various @samp{PA_} macros, listed below. The @var{n} argument specifies the number of elements in the array @var{argtypes}. This is the most elements that @code{parse_printf_format} will try to write. @code{parse_printf_format} returns the total number of arguments required by @var{template}. If this number is greater than @var{n}, then the information returned describes only the first @var{n} arguments. If you want information about more than that many arguments, allocate a bigger array and call @code{parse_printf_format} again. @end deftypefun The argument types are encoded as a combination of a basic type and modifier flag bits. @comment printf.h @comment GNU @deftypevr Macro int PA_FLAG_MASK This macro is a bitmask for the type modifier flag bits. You can write the expression @code{(argtypes[i] & PA_FLAG_MASK)} to extract just the flag bits for an argument, or @code{(argtypes[i] & ~PA_FLAG_MASK)} to extract just the basic type code. @end deftypevr Here are symbolic constants that represent the basic types; they stand for integer values. @vtable @code @comment printf.h @comment GNU @item PA_INT This specifies that the base type is @code{int}. @comment printf.h @comment GNU @item PA_CHAR This specifies that the base type is @code{int}, cast to @code{char}. @comment printf.h @comment GNU @item PA_STRING This specifies that the base type is @code{char *}, a null-terminated string. @comment printf.h @comment GNU @item PA_POINTER This specifies that the base type is @code{void *}, an arbitrary pointer. @comment printf.h @comment GNU @item PA_FLOAT This specifies that the base type is @code{float}. @comment printf.h @comment GNU @item PA_DOUBLE This specifies that the base type is @code{double}. @comment printf.h @comment GNU @item PA_LAST You can define additional base types for your own programs as offsets from @code{PA_LAST}. For example, if you have data types @samp{foo} and @samp{bar} with their own specialized @code{printf} conversions, you could define encodings for these types as: @smallexample #define PA_FOO PA_LAST #define PA_BAR (PA_LAST + 1) @end smallexample @end vtable Here are the flag bits that modify a basic type. They are combined with the code for the basic type using inclusive-or. @vtable @code @comment printf.h @comment GNU @item PA_FLAG_PTR If this bit is set, it indicates that the encoded type is a pointer to the base type, rather than an immediate value. For example, @samp{PA_INT|PA_FLAG_PTR} represents the type @samp{int *}. @comment printf.h @comment GNU @item PA_FLAG_SHORT If this bit is set, it indicates that the base type is modified with @code{short}. (This corresponds to the @samp{h} type modifier.) @comment printf.h @comment GNU @item PA_FLAG_LONG If this bit is set, it indicates that the base type is modified with @code{long}. (This corresponds to the @samp{l} type modifier.) @comment printf.h @comment GNU @item PA_FLAG_LONG_LONG If this bit is set, it indicates that the base type is modified with @code{long long}. (This corresponds to the @samp{L} type modifier.) @comment printf.h @comment GNU @item PA_FLAG_LONG_DOUBLE This is a synonym for @code{PA_FLAG_LONG_LONG}, used by convention with a base type of @code{PA_DOUBLE} to indicate a type of @code{long double}. @end vtable @ifinfo For an example of using these facilities, see @ref{Example of Parsing}. @end ifinfo @node Example of Parsing @subsection Example of Parsing a Template String Here is an example of decoding argument types for a format string. We assume this is part of an interpreter which contains arguments of type @code{NUMBER}, @code{CHAR}, @code{STRING} and @code{STRUCTURE} (and perhaps others which are not valid here). @smallexample /* @r{Test whether the @var{nargs} specified objects} @r{in the vector @var{args} are valid} @r{for the format string @var{format}:} @r{if so, return 1.} @r{If not, return 0 after printing an error message.} */ int validate_args (char *format, int nargs, OBJECT *args) @{ int *argtypes; int nwanted; /* @r{Get the information about the arguments.} @r{Each conversion specification must be at least two characters} @r{long, so there cannot be more specifications than half the} @r{length of the string.} */ argtypes = (int *) alloca (strlen (format) / 2 * sizeof (int)); nwanted = parse_printf_format (string, nelts, argtypes); /* @r{Check the number of arguments.} */ if (nwanted > nargs) @{ error ("too few arguments (at least %d required)", nwanted); return 0; @} /* @r{Check the C type wanted for each argument} @r{and see if the object given is suitable.} */ for (i = 0; i < nwanted; i++) @{ int wanted; if (argtypes[i] & PA_FLAG_PTR) wanted = STRUCTURE; else switch (argtypes[i] & ~PA_FLAG_MASK) @{ case PA_INT: case PA_FLOAT: case PA_DOUBLE: wanted = NUMBER; break; case PA_CHAR: wanted = CHAR; break; case PA_STRING: wanted = STRING; break; case PA_POINTER: wanted = STRUCTURE; break; @} if (TYPE (args[i]) != wanted) @{ error ("type mismatch for arg number %d", i); return 0; @} @} return 1; @} @end smallexample @node Customizing Printf @section Customizing @code{printf} @cindex customizing @code{printf} @cindex defining new @code{printf} conversions @cindex extending @code{printf} The GNU C library lets you define your own custom conversion specifiers for @code{printf} template strings, to teach @code{printf} clever ways to print the important data structures of your program. The way you do this is by registering the conversion with the function @code{register_printf_function}; see @ref{Registering New Conversions}. One of the arguments you pass to this function is a pointer to a handler function that produces the actual output; see @ref{Defining the Output Handler}, for information on how to write this function. You can also install a function that just returns information about the number and type of arguments expected by the conversion specifier. @xref{Parsing a Template String}, for information about this. The facilities of this section are declared in the header file @file{printf.h}. @menu * Registering New Conversions:: Using @code{register_printf_function} to register a new output conversion. * Conversion Specifier Options:: The handler must be able to get the options specified in the template when it is called. * Defining the Output Handler:: Defining the handler and arginfo functions that are passed as arguments to @code{register_printf_function}. * Printf Extension Example:: How to define a @code{printf} handler function. * Predefined Printf Handlers:: Predefined @code{printf} handlers. @end menu @strong{Portability Note:} The ability to extend the syntax of @code{printf} template strings is a GNU extension. ISO standard C has nothing similar. @node Registering New Conversions @subsection Registering New Conversions The function to register a new output conversion is @code{register_printf_function}, declared in @file{printf.h}. @pindex printf.h @comment printf.h @comment GNU @deftypefun int register_printf_function (int @var{spec}, printf_function @var{handler-function}, printf_arginfo_function @var{arginfo-function}) This function defines the conversion specifier character @var{spec}. Thus, if @var{spec} is @code{'z'}, it defines the conversion @samp{%z}. You can redefine the built-in conversions like @samp{%s}, but flag characters like @samp{#} and type modifiers like @samp{l} can never be used as conversions; calling @code{register_printf_function} for those characters has no effect. The @var{handler-function} is the function called by @code{printf} and friends when this conversion appears in a template string. @xref{Defining the Output Handler}, for information about how to define a function to pass as this argument. If you specify a null pointer, any existing handler function for @var{spec} is removed. The @var{arginfo-function} is the function called by @code{parse_printf_format} when this conversion appears in a template string. @xref{Parsing a Template String}, for information about this. @c The following is not true anymore. The `parse_printf_format' function @c is now also called from `vfprintf' via `parse_one_spec'. @c --drepper@gnu, 1996/11/14 @c @c Normally, you install both functions for a conversion at the same time, @c but if you are never going to call @code{parse_printf_format}, you do @c not need to define an arginfo function. @strong{Attention:} In the GNU C library version before 2.0 the @var{arginfo-function} function did not need to be installed unless the user uses the @code{parse_printf_format} function. This changed. Now a call to any of the @code{printf} functions will call this function when this format specifier appears in the format string. The return value is @code{0} on success, and @code{-1} on failure (which occurs if @var{spec} is out of range). You can redefine the standard output conversions, but this is probably not a good idea because of the potential for confusion. Library routines written by other people could break if you do this. @end deftypefun @node Conversion Specifier Options @subsection Conversion Specifier Options If you define a meaning for @samp{%A}, what if the template contains @samp{%+23A} or @samp{%-#A}? To implement a sensible meaning for these, the handler when called needs to be able to get the options specified in the template. Both the @var{handler-function} and @var{arginfo-function} accept an argument that points to a @code{struct printf_info}, which contains information about the options appearing in an instance of the conversion specifier. This data type is declared in the header file @file{printf.h}. @pindex printf.h @comment printf.h @comment GNU @deftp {Type} {struct printf_info} This structure is used to pass information about the options appearing in an instance of a conversion specifier in a @code{printf} template string to the handler and arginfo functions for that specifier. It contains the following members: @table @code @item int prec This is the precision specified. The value is @code{-1} if no precision was specified. If the precision was given as @samp{*}, the @code{printf_info} structure passed to the handler function contains the actual value retrieved from the argument list. But the structure passed to the arginfo function contains a value of @code{INT_MIN}, since the actual value is not known. @item int width This is the minimum field width specified. The value is @code{0} if no width was specified. If the field width was given as @samp{*}, the @code{printf_info} structure passed to the handler function contains the actual value retrieved from the argument list. But the structure passed to the arginfo function contains a value of @code{INT_MIN}, since the actual value is not known. @item wchar_t spec This is the conversion specifier character specified. It's stored in the structure so that you can register the same handler function for multiple characters, but still have a way to tell them apart when the handler function is called. @item unsigned int is_long_double This is a boolean that is true if the @samp{L}, @samp{ll}, or @samp{q} type modifier was specified. For integer conversions, this indicates @code{long long int}, as opposed to @code{long double} for floating point conversions. @item unsigned int is_char This is a boolean that is true if the @samp{hh} type modifier was specified. @item unsigned int is_short This is a boolean that is true if the @samp{h} type modifier was specified. @item unsigned int is_long This is a boolean that is true if the @samp{l} type modifier was specified. @item unsigned int alt This is a boolean that is true if the @samp{#} flag was specified. @item unsigned int space This is a boolean that is true if the @samp{ } flag was specified. @item unsigned int left This is a boolean that is true if the @samp{-} flag was specified. @item unsigned int showsign This is a boolean that is true if the @samp{+} flag was specified. @item unsigned int group This is a boolean that is true if the @samp{'} flag was specified. @item unsigned int extra This flag has a special meaning depending on the context. It could be used freely by the user-defined handlers but when called from the @code{printf} function this variable always contains the value @code{0}. @item unsigned int wide This flag is set if the stream is wide oriented. @item wchar_t pad This is the character to use for padding the output to the minimum field width. The value is @code{'0'} if the @samp{0} flag was specified, and @code{' '} otherwise. @end table @end deftp @node Defining the Output Handler @subsection Defining the Output Handler Now let's look at how to define the handler and arginfo functions which are passed as arguments to @code{register_printf_function}. @strong{Compatibility Note:} The interface changed in the GNU libc version 2.0. Previously the third argument was of type @code{va_list *}. You should define your handler functions with a prototype like: @smallexample int @var{function} (FILE *stream, const struct printf_info *info, const void *const *args) @end smallexample The @var{stream} argument passed to the handler function is the stream to which it should write output. The @var{info} argument is a pointer to a structure that contains information about the various options that were included with the conversion in the template string. You should not modify this structure inside your handler function. @xref{Conversion Specifier Options}, for a description of this data structure. @c The following changes some time back. --drepper@gnu, 1996/11/14 @c @c The @code{ap_pointer} argument is used to pass the tail of the variable @c argument list containing the values to be printed to your handler. @c Unlike most other functions that can be passed an explicit variable @c argument list, this is a @emph{pointer} to a @code{va_list}, rather than @c the @code{va_list} itself. Thus, you should fetch arguments by @c means of @code{va_arg (*ap_pointer, @var{type})}. @c @c (Passing a pointer here allows the function that calls your handler @c function to update its own @code{va_list} variable to account for the @c arguments that your handler processes. @xref{Variadic Functions}.) The @var{args} is a vector of pointers to the arguments data. The number of arguments were determined by calling the argument information function provided by the user. Your handler function should return a value just like @code{printf} does: it should return the number of characters it has written, or a negative value to indicate an error. @comment printf.h @comment GNU @deftp {Data Type} printf_function This is the data type that a handler function should have. @end deftp If you are going to use @w{@code{parse_printf_format}} in your application, you must also define a function to pass as the @var{arginfo-function} argument for each new conversion you install with @code{register_printf_function}. You have to define these functions with a prototype like: @smallexample int @var{function} (const struct printf_info *info, size_t n, int *argtypes) @end smallexample The return value from the function should be the number of arguments the conversion expects. The function should also fill in no more than @var{n} elements of the @var{argtypes} array with information about the types of each of these arguments. This information is encoded using the various @samp{PA_} macros. (You will notice that this is the same calling convention @code{parse_printf_format} itself uses.) @comment printf.h @comment GNU @deftp {Data Type} printf_arginfo_function This type is used to describe functions that return information about the number and type of arguments used by a conversion specifier. @end deftp @node Printf Extension Example @subsection @code{printf} Extension Example Here is an example showing how to define a @code{printf} handler function. This program defines a data structure called a @code{Widget} and defines the @samp{%W} conversion to print information about @w{@code{Widget *}} arguments, including the pointer value and the name stored in the data structure. The @samp{%W} conversion supports the minimum field width and left-justification options, but ignores everything else. @smallexample @include rprintf.c.texi @end smallexample The output produced by this program looks like: @smallexample || | | | | @end smallexample @node Predefined Printf Handlers @subsection Predefined @code{printf} Handlers The GNU libc also contains a concrete and useful application of the @code{printf} handler extension. There are two functions available which implement a special way to print floating-point numbers. @comment printf.h @comment GNU @deftypefun int printf_size (FILE *@var{fp}, const struct printf_info *@var{info}, const void *const *@var{args}) Print a given floating point number as for the format @code{%f} except that there is a postfix character indicating the divisor for the number to make this less than 1000. There are two possible divisors: powers of 1024 or powers to 1000. Which one is used depends on the format character specified while registered this handler. If the character is of lower case, 1024 is used. For upper case characters, 1000 is used. The postfix tag corresponds to bytes, kilobytes, megabytes, gigabytes, etc. The full table is: @ifinfo @multitable @hsep @vsep {' '} {2^10 (1024)} {zetta} {Upper} {10^24 (1000)} @item low @tab Multiplier @tab From @tab Upper @tab Multiplier @item ' ' @tab 1 @tab @tab ' ' @tab 1 @item k @tab 2^10 (1024) @tab kilo @tab K @tab 10^3 (1000) @item m @tab 2^20 @tab mega @tab M @tab 10^6 @item g @tab 2^30 @tab giga @tab G @tab 10^9 @item t @tab 2^40 @tab tera @tab T @tab 10^12 @item p @tab 2^50 @tab peta @tab P @tab 10^15 @item e @tab 2^60 @tab exa @tab E @tab 10^18 @item z @tab 2^70 @tab zetta @tab Z @tab 10^21 @item y @tab 2^80 @tab yotta @tab Y @tab 10^24 @end multitable @end ifinfo @iftex @tex \hbox to\hsize{\hfil\vbox{\offinterlineskip \hrule \halign{\strut#& \vrule#\tabskip=1em plus2em& {\tt#}\hfil& \vrule#& #\hfil& \vrule#& #\hfil& \vrule#& {\tt#}\hfil& \vrule#& #\hfil& \vrule#\tabskip=0pt\cr \noalign{\hrule} \omit&height2pt&\omit&&\omit&&\omit&&\omit&&\omit&\cr && \omit low && Multiplier && From && \omit Upper && Multiplier &\cr \omit&height2pt&\omit&&\omit&&\omit&&\omit&&\omit&\cr \noalign{\hrule} && {\tt\char32} && 1 && && {\tt\char32} && 1 &\cr && k && $2^{10} = 1024$ && kilo && K && $10^3 = 1000$ &\cr && m && $2^{20}$ && mega && M && $10^6$ &\cr && g && $2^{30}$ && giga && G && $10^9$ &\cr && t && $2^{40}$ && tera && T && $10^{12}$ &\cr && p && $2^{50}$ && peta && P && $10^{15}$ &\cr && e && $2^{60}$ && exa && E && $10^{18}$ &\cr && z && $2^{70}$ && zetta && Z && $10^{21}$ &\cr && y && $2^{80}$ && yotta && Y && $10^{24}$ &\cr \noalign{\hrule}}}\hfil} @end tex @end iftex The default precision is 3, i.e., 1024 is printed with a lower-case format character as if it were @code{%.3fk} and will yield @code{1.000k}. @end deftypefun Due to the requirements of @code{register_printf_function} we must also provide the function which return information about the arguments. @comment printf.h @comment GNU @deftypefun int printf_size_info (const struct printf_info *@var{info}, size_t @var{n}, int *@var{argtypes}) This function will return in @var{argtypes} the information about the used parameters in the way the @code{vfprintf} implementation expects it. The format always takes one argument. @end deftypefun To use these functions both functions must be registered with a call like @smallexample register_printf_function ('B', printf_size, printf_size_info); @end smallexample Here we register the functions to print numbers as powers of 1000 since the format character @code{'B'} is an upper-case character. If we would additionally use @code{'b'} in a line like @smallexample register_printf_function ('b', printf_size, printf_size_info); @end smallexample @noindent we could also print using power of 1024. Please note that all what is different in these both lines in the format specifier. The @code{printf_size} function knows about the difference of low and upper case format specifiers. The use of @code{'B'} and @code{'b'} is no coincidence. Rather it is the preferred way to use this functionality since it is available on some other systems also available using the format specifiers. @node Formatted Input @section Formatted Input @cindex formatted input from a stream @cindex reading from a stream, formatted @cindex format string, for @code{scanf} @cindex template, for @code{scanf} The functions described in this section (@code{scanf} and related functions) provide facilities for formatted input analogous to the formatted output facilities. These functions provide a mechanism for reading arbitrary values under the control of a @dfn{format string} or @dfn{template string}. @menu * Formatted Input Basics:: Some basics to get you started. * Input Conversion Syntax:: Syntax of conversion specifications. * Table of Input Conversions:: Summary of input conversions and what they do. * Numeric Input Conversions:: Details of conversions for reading numbers. * String Input Conversions:: Details of conversions for reading strings. * Dynamic String Input:: String conversions that @code{malloc} the buffer. * Other Input Conversions:: Details of miscellaneous other conversions. * Formatted Input Functions:: Descriptions of the actual functions. * Variable Arguments Input:: @code{vscanf} and friends. @end menu @node Formatted Input Basics @subsection Formatted Input Basics Calls to @code{scanf} are superficially similar to calls to @code{printf} in that arbitrary arguments are read under the control of a template string. While the syntax of the conversion specifications in the template is very similar to that for @code{printf}, the interpretation of the template is oriented more towards free-format input and simple pattern matching, rather than fixed-field formatting. For example, most @code{scanf} conversions skip over any amount of ``white space'' (including spaces, tabs, and newlines) in the input file, and there is no concept of precision for the numeric input conversions as there is for the corresponding output conversions. Ordinarily, non-whitespace characters in the template are expected to match characters in the input stream exactly, but a matching failure is distinct from an input error on the stream. @cindex conversion specifications (@code{scanf}) Another area of difference between @code{scanf} and @code{printf} is that you must remember to supply pointers rather than immediate values as the optional arguments to @code{scanf}; the values that are read are stored in the objects that the pointers point to. Even experienced programmers tend to forget this occasionally, so if your program is getting strange errors that seem to be related to @code{scanf}, you might want to double-check this. When a @dfn{matching failure} occurs, @code{scanf} returns immediately, leaving the first non-matching character as the next character to be read from the stream. The normal return value from @code{scanf} is the number of values that were assigned, so you can use this to determine if a matching error happened before all the expected values were read. @cindex matching failure, in @code{scanf} The @code{scanf} function is typically used for things like reading in the contents of tables. For example, here is a function that uses @code{scanf} to initialize an array of @code{double}: @smallexample void readarray (double *array, int n) @{ int i; for (i=0; i scanf ("%a[a-zA-Z0-9] = %a[^\n]\n", &variable, &value)) @{ invalid_input_error (); return 0; @} @dots{} @} @end smallexample @node Other Input Conversions @subsection Other Input Conversions This section describes the miscellaneous input conversions. The @samp{%p} conversion is used to read a pointer value. It recognizes the same syntax as is used by the @samp{%p} output conversion for @code{printf} (@pxref{Other Output Conversions}); that is, a hexadecimal number just as the @samp{%x} conversion accepts. The corresponding argument should be of type @code{void **}; that is, the address of a place to store a pointer. The resulting pointer value is not guaranteed to be valid if it was not originally written during the same program execution that reads it in. The @samp{%n} conversion produces the number of characters read so far by this call. The corresponding argument should be of type @code{int *}. This conversion works in the same way as the @samp{%n} conversion for @code{printf}; see @ref{Other Output Conversions}, for an example. The @samp{%n} conversion is the only mechanism for determining the success of literal matches or conversions with suppressed assignments. If the @samp{%n} follows the locus of a matching failure, then no value is stored for it since @code{scanf} returns before processing the @samp{%n}. If you store @code{-1} in that argument slot before calling @code{scanf}, the presence of @code{-1} after @code{scanf} indicates an error occurred before the @samp{%n} was reached. Finally, the @samp{%%} conversion matches a literal @samp{%} character in the input stream, without using an argument. This conversion does not permit any flags, field width, or type modifier to be specified. @node Formatted Input Functions @subsection Formatted Input Functions Here are the descriptions of the functions for performing formatted input. Prototypes for these functions are in the header file @file{stdio.h}. @pindex stdio.h @comment stdio.h @comment ISO @deftypefun int scanf (const char *@var{template}, @dots{}) The @code{scanf} function reads formatted input from the stream @code{stdin} under the control of the template string @var{template}. The optional arguments are pointers to the places which receive the resulting values. The return value is normally the number of successful assignments. If an end-of-file condition is detected before any matches are performed (including matches against whitespace and literal characters in the template), then @code{EOF} is returned. @end deftypefun @comment stdio.h @comment ISO @deftypefun int fscanf (FILE *@var{stream}, const char *@var{template}, @dots{}) This function is just like @code{scanf}, except that the input is read from the stream @var{stream} instead of @code{stdin}. @end deftypefun @comment stdio.h @comment ISO @deftypefun int sscanf (const char *@var{s}, const char *@var{template}, @dots{}) This is like @code{scanf}, except that the characters are taken from the null-terminated string @var{s} instead of from a stream. Reaching the end of the string is treated as an end-of-file condition. The behavior of this function is undefined if copying takes place between objects that overlap---for example, if @var{s} is also given as an argument to receive a string read under control of the @samp{%s} conversion. @end deftypefun @node Variable Arguments Input @subsection Variable Arguments Input Functions The functions @code{vscanf} and friends are provided so that you can define your own variadic @code{scanf}-like functions that make use of the same internals as the built-in formatted output functions. These functions are analogous to the @code{vprintf} series of output functions. @xref{Variable Arguments Output}, for important information on how to use them. @strong{Portability Note:} The functions listed in this section are GNU extensions. @comment stdio.h @comment GNU @deftypefun int vscanf (const char *@var{template}, va_list @var{ap}) This function is similar to @code{scanf} except that, instead of taking a variable number of arguments directly, it takes an argument list pointer @var{ap} of type @code{va_list} (@pxref{Variadic Functions}). @end deftypefun @comment stdio.h @comment GNU @deftypefun int vfscanf (FILE *@var{stream}, const char *@var{template}, va_list @var{ap}) This is the equivalent of @code{fscanf} with the variable argument list specified directly as for @code{vscanf}. @end deftypefun @comment stdio.h @comment GNU @deftypefun int vsscanf (const char *@var{s}, const char *@var{template}, va_list @var{ap}) This is the equivalent of @code{sscanf} with the variable argument list specified directly as for @code{vscanf}. @end deftypefun In GNU C, there is a special construct you can use to let the compiler know that a function uses a @code{scanf}-style format string. Then it can check the number and types of arguments in each call to the function, and warn you when they do not match the format string. @xref{Function Attributes, , Declaring Attributes of Functions, gcc.info, Using GNU CC}, for details. @node EOF and Errors @section End-Of-File and Errors @cindex end of file, on a stream Many of the functions described in this chapter return the value of the macro @code{EOF} to indicate unsuccessful completion of the operation. Since @code{EOF} is used to report both end of file and random errors, it's often better to use the @code{feof} function to check explicitly for end of file and @code{ferror} to check for errors. These functions check indicators that are part of the internal state of the stream object, indicators set if the appropriate condition was detected by a previous I/O operation on that stream. These symbols are declared in the header file @file{stdio.h}. @pindex stdio.h @comment stdio.h @comment ISO @deftypevr Macro int EOF This macro is an integer value that is returned by a number of functions to indicate an end-of-file condition, or some other error situation. With the GNU library, @code{EOF} is @code{-1}. In other libraries, its value may be some other negative number. @end deftypevr @comment stdio.h @comment ISO @deftypefun void clearerr (FILE *@var{stream}) This function clears the end-of-file and error indicators for the stream @var{stream}. The file positioning functions (@pxref{File Positioning}) also clear the end-of-file indicator for the stream. @end deftypefun @comment stdio.h @comment ISO @deftypefun int feof (FILE *@var{stream}) The @code{feof} function returns nonzero if and only if the end-of-file indicator for the stream @var{stream} is set. @end deftypefun @comment stdio.h @comment ISO @deftypefun int ferror (FILE *@var{stream}) The @code{ferror} function returns nonzero if and only if the error indicator for the stream @var{stream} is set, indicating that an error has occurred on a previous operation on the stream. @end deftypefun In addition to setting the error indicator associated with the stream, the functions that operate on streams also set @code{errno} in the same way as the corresponding low-level functions that operate on file descriptors. For example, all of the functions that perform output to a stream---such as @code{fputc}, @code{printf}, and @code{fflush}---are implemented in terms of @code{write}, and all of the @code{errno} error conditions defined for @code{write} are meaningful for these functions. For more information about the descriptor-level I/O functions, see @ref{Low-Level I/O}. @node Binary Streams @section Text and Binary Streams The GNU system and other POSIX-compatible operating systems organize all files as uniform sequences of characters. However, some other systems make a distinction between files containing text and files containing binary data, and the input and output facilities of @w{ISO C} provide for this distinction. This section tells you how to write programs portable to such systems. @cindex text stream @cindex binary stream When you open a stream, you can specify either a @dfn{text stream} or a @dfn{binary stream}. You indicate that you want a binary stream by specifying the @samp{b} modifier in the @var{opentype} argument to @code{fopen}; see @ref{Opening Streams}. Without this option, @code{fopen} opens the file as a text stream. Text and binary streams differ in several ways: @itemize @bullet @item The data read from a text stream is divided into @dfn{lines} which are terminated by newline (@code{'\n'}) characters, while a binary stream is simply a long series of characters. A text stream might on some systems fail to handle lines more than 254 characters long (including the terminating newline character). @cindex lines (in a text file) @item On some systems, text files can contain only printing characters, horizontal tab characters, and newlines, and so text streams may not support other characters. However, binary streams can handle any character value. @item Space characters that are written immediately preceding a newline character in a text stream may disappear when the file is read in again. @item More generally, there need not be a one-to-one mapping between characters that are read from or written to a text stream, and the characters in the actual file. @end itemize Since a binary stream is always more capable and more predictable than a text stream, you might wonder what purpose text streams serve. Why not simply always use binary streams? The answer is that on these operating systems, text and binary streams use different file formats, and the only way to read or write ``an ordinary file of text'' that can work with other text-oriented programs is through a text stream. In the GNU library, and on all POSIX systems, there is no difference between text streams and binary streams. When you open a stream, you get the same kind of stream regardless of whether you ask for binary. This stream can handle any file content, and has none of the restrictions that text streams sometimes have. @node File Positioning @section File Positioning @cindex file positioning on a stream @cindex positioning a stream @cindex seeking on a stream The @dfn{file position} of a stream describes where in the file the stream is currently reading or writing. I/O on the stream advances the file position through the file. In the GNU system, the file position is represented as an integer, which counts the number of bytes from the beginning of the file. @xref{File Position}. During I/O to an ordinary disk file, you can change the file position whenever you wish, so as to read or write any portion of the file. Some other kinds of files may also permit this. Files which support changing the file position are sometimes referred to as @dfn{random-access} files. You can use the functions in this section to examine or modify the file position indicator associated with a stream. The symbols listed below are declared in the header file @file{stdio.h}. @pindex stdio.h @comment stdio.h @comment ISO @deftypefun {long int} ftell (FILE *@var{stream}) This function returns the current file position of the stream @var{stream}. This function can fail if the stream doesn't support file positioning, or if the file position can't be represented in a @code{long int}, and possibly for other reasons as well. If a failure occurs, a value of @code{-1} is returned. @end deftypefun @comment stdio.h @comment Unix98 @deftypefun off_t ftello (FILE *@var{stream}) The @code{ftello} function is similar to @code{ftell} only it corrects a problem which the POSIX type system. In this type system all file positions are described using values of type @code{off_t} which is not necessarily of the same size as @code{long int}. Therefore using @code{ftell} can lead to problems if the implementation is written on top of a POSIX compliant lowlevel I/O implementation. Therefore it is a good idea to prefer @code{ftello} whenever it is available since its functionality is (if different at all) closer the underlying definition. If this function fails it return @code{(off_t) -1}. This can happen due to missing support for file positioning or internal errors. Otherwise the return value is the current file position. The function is an extension defined in the Unix Single Specification version 2. When the sources are compiled with @code{_FILE_OFFSET_BITS == 64} on a 32 bit system this function is in fact @code{ftello64}. I.e., the LFS interface transparently replaces the old interface. @end deftypefun @comment stdio.h @comment Unix98 @deftypefun off64_t ftello64 (FILE *@var{stream}) This function is similar to @code{ftello} with the only difference that the return value is of type @code{off64_t}. This also requires that the stream @var{stream} was opened using either @code{fopen64}, @code{freopen64}, or @code{tmpfile64} since otherwise the underlying file operations to position the file pointer beyond the @math{2^31} bytes limit might fail. If the sources are compiled with @code{_FILE_OFFSET_BITS == 64} on a 32 bits machine this function is available under the name @code{ftello} and so transparently replaces the old interface. @end deftypefun @comment stdio.h @comment ISO @deftypefun int fseek (FILE *@var{stream}, long int @var{offset}, int @var{whence}) The @code{fseek} function is used to change the file position of the stream @var{stream}. The value of @var{whence} must be one of the constants @code{SEEK_SET}, @code{SEEK_CUR}, or @code{SEEK_END}, to indicate whether the @var{offset} is relative to the beginning of the file, the current file position, or the end of the file, respectively. This function returns a value of zero if the operation was successful, and a nonzero value to indicate failure. A successful call also clears the end-of-file indicator of @var{stream} and discards any characters that were ``pushed back'' by the use of @code{ungetc}. @code{fseek} either flushes any buffered output before setting the file position or else remembers it so it will be written later in its proper place in the file. @end deftypefun @comment stdio.h @comment Unix98 @deftypefun int fseeko (FILE *@var{stream}, off_t @var{offset}, int @var{whence}) This function is similar to @code{fseek} but it corrects a problem with @code{fseek} in a system with POSIX types. Using a value of type @code{long int} for the offset is not compatible with POSIX. @code{fseeko} uses the correct type @code{off_t} for the @var{offset} parameter. For this reason it is a good idea to prefer @code{ftello} whenever it is available since its functionality is (if different at all) closer the underlying definition. The functionality and return value is the same as for @code{fseek}. The function is an extension defined in the Unix Single Specification version 2. When the sources are compiled with @code{_FILE_OFFSET_BITS == 64} on a 32 bit system this function is in fact @code{fseeko64}. I.e., the LFS interface transparently replaces the old interface. @end deftypefun @comment stdio.h @comment Unix98 @deftypefun int fseeko64 (FILE *@var{stream}, off64_t @var{offset}, int @var{whence}) This function is similar to @code{fseeko} with the only difference that the @var{offset} parameter is of type @code{off64_t}. This also requires that the stream @var{stream} was opened using either @code{fopen64}, @code{freopen64}, or @code{tmpfile64} since otherwise the underlying file operations to position the file pointer beyond the @math{2^31} bytes limit might fail. If the sources are compiled with @code{_FILE_OFFSET_BITS == 64} on a 32 bits machine this function is available under the name @code{fseeko} and so transparently replaces the old interface. @end deftypefun @strong{Portability Note:} In non-POSIX systems, @code{ftell}, @code{ftello}, @code{fseek} and @code{fseeko} might work reliably only on binary streams. @xref{Binary Streams}. The following symbolic constants are defined for use as the @var{whence} argument to @code{fseek}. They are also used with the @code{lseek} function (@pxref{I/O Primitives}) and to specify offsets for file locks (@pxref{Control Operations}). @comment stdio.h @comment ISO @deftypevr Macro int SEEK_SET This is an integer constant which, when used as the @var{whence} argument to the @code{fseek} or @code{fseeko} function, specifies that the offset provided is relative to the beginning of the file. @end deftypevr @comment stdio.h @comment ISO @deftypevr Macro int SEEK_CUR This is an integer constant which, when used as the @var{whence} argument to the @code{fseek} or @code{fseeko} function, specifies that the offset provided is relative to the current file position. @end deftypevr @comment stdio.h @comment ISO @deftypevr Macro int SEEK_END This is an integer constant which, when used as the @var{whence} argument to the @code{fseek} or @code{fseeko} function, specifies that the offset provided is relative to the end of the file. @end deftypevr @comment stdio.h @comment ISO @deftypefun void rewind (FILE *@var{stream}) The @code{rewind} function positions the stream @var{stream} at the beginning of the file. It is equivalent to calling @code{fseek} or @code{fseeko} on the @var{stream} with an @var{offset} argument of @code{0L} and a @var{whence} argument of @code{SEEK_SET}, except that the return value is discarded and the error indicator for the stream is reset. @end deftypefun These three aliases for the @samp{SEEK_@dots{}} constants exist for the sake of compatibility with older BSD systems. They are defined in two different header files: @file{fcntl.h} and @file{sys/file.h}. @table @code @comment sys/file.h @comment BSD @item L_SET @vindex L_SET An alias for @code{SEEK_SET}. @comment sys/file.h @comment BSD @item L_INCR @vindex L_INCR An alias for @code{SEEK_CUR}. @comment sys/file.h @comment BSD @item L_XTND @vindex L_XTND An alias for @code{SEEK_END}. @end table @node Portable Positioning @section Portable File-Position Functions On the GNU system, the file position is truly a character count. You can specify any character count value as an argument to @code{fseek} or @code{fseeko} and get reliable results for any random access file. However, some @w{ISO C} systems do not represent file positions in this way. On some systems where text streams truly differ from binary streams, it is impossible to represent the file position of a text stream as a count of characters from the beginning of the file. For example, the file position on some systems must encode both a record offset within the file, and a character offset within the record. As a consequence, if you want your programs to be portable to these systems, you must observe certain rules: @itemize @bullet @item The value returned from @code{ftell} on a text stream has no predictable relationship to the number of characters you have read so far. The only thing you can rely on is that you can use it subsequently as the @var{offset} argument to @code{fseek} or @code{fseeko} to move back to the same file position. @item In a call to @code{fseek} or @code{fseeko} on a text stream, either the @var{offset} must either be zero; or @var{whence} must be @code{SEEK_SET} and the @var{offset} must be the result of an earlier call to @code{ftell} on the same stream. @item The value of the file position indicator of a text stream is undefined while there are characters that have been pushed back with @code{ungetc} that haven't been read or discarded. @xref{Unreading}. @end itemize But even if you observe these rules, you may still have trouble for long files, because @code{ftell} and @code{fseek} use a @code{long int} value to represent the file position. This type may not have room to encode all the file positions in a large file. Using the @code{ftello} and @code{fseeko} functions might help here since the @code{off_t} type is expected to be able to hold all file position values but this still does not help to handle additional information which must be associated with a file position. So if you do want to support systems with peculiar encodings for the file positions, it is better to use the functions @code{fgetpos} and @code{fsetpos} instead. These functions represent the file position using the data type @code{fpos_t}, whose internal representation varies from system to system. These symbols are declared in the header file @file{stdio.h}. @pindex stdio.h @comment stdio.h @comment ISO @deftp {Data Type} fpos_t This is the type of an object that can encode information about the file position of a stream, for use by the functions @code{fgetpos} and @code{fsetpos}. In the GNU system, @code{fpos_t} is equivalent to @code{off_t} or @code{long int}. In other systems, it might have a different internal representation. When compiling with @code{_FILE_OFFSET_BITS == 64} on a 32 bit machine this type is in fact equivalent to @code{off64_t} since the LFS interface transparently replaced the old interface. @end deftp @comment stdio.h @comment Unix98 @deftp {Data Type} fpos64_t This is the type of an object that can encode information about the file position of a stream, for use by the functions @code{fgetpos64} and @code{fsetpos64}. In the GNU system, @code{fpos64_t} is equivalent to @code{off64_t} or @code{long long int}. In other systems, it might have a different internal representation. @end deftp @comment stdio.h @comment ISO @deftypefun int fgetpos (FILE *@var{stream}, fpos_t *@var{position}) This function stores the value of the file position indicator for the stream @var{stream} in the @code{fpos_t} object pointed to by @var{position}. If successful, @code{fgetpos} returns zero; otherwise it returns a nonzero value and stores an implementation-defined positive value in @code{errno}. When the sources are compiled with @code{_FILE_OFFSET_BITS == 64} on a 32 bit system the function is in fact @code{fgetpos64}. I.e., the LFS interface transparently replaced the old interface. @end deftypefun @comment stdio.h @comment Unix98 @deftypefun int fgetpos64 (FILE *@var{stream}, fpos64_t *@var{position}) This function is similar to @code{fgetpos} but the file position is returned in a variable of type @code{fpos64_t} to which @var{position} points. If the sources are compiled with @code{_FILE_OFFSET_BITS == 64} on a 32 bits machine this function is available under the name @code{fgetpos} and so transparently replaces the old interface. @end deftypefun @comment stdio.h @comment ISO @deftypefun int fsetpos (FILE *@var{stream}, const fpos_t *@var{position}) This function sets the file position indicator for the stream @var{stream} to the position @var{position}, which must have been set by a previous call to @code{fgetpos} on the same stream. If successful, @code{fsetpos} clears the end-of-file indicator on the stream, discards any characters that were ``pushed back'' by the use of @code{ungetc}, and returns a value of zero. Otherwise, @code{fsetpos} returns a nonzero value and stores an implementation-defined positive value in @code{errno}. When the sources are compiled with @code{_FILE_OFFSET_BITS == 64} on a 32 bit system the function is in fact @code{fsetpos64}. I.e., the LFS interface transparently replaced the old interface. @end deftypefun @comment stdio.h @comment Unix98 @deftypefun int fsetpos64 (FILE *@var{stream}, const fpos64_t *@var{position}) This function is similar to @code{fsetpos} but the file position used for positioning is provided in a variable of type @code{fpos64_t} to which @var{position} points. If the sources are compiled with @code{_FILE_OFFSET_BITS == 64} on a 32 bits machine this function is available under the name @code{fsetpos} and so transparently replaces the old interface. @end deftypefun @node Stream Buffering @section Stream Buffering @cindex buffering of streams Characters that are written to a stream are normally accumulated and transmitted asynchronously to the file in a block, instead of appearing as soon as they are output by the application program. Similarly, streams often retrieve input from the host environment in blocks rather than on a character-by-character basis. This is called @dfn{buffering}. If you are writing programs that do interactive input and output using streams, you need to understand how buffering works when you design the user interface to your program. Otherwise, you might find that output (such as progress or prompt messages) doesn't appear when you intended it to, or other unexpected behavior. This section deals only with controlling when characters are transmitted between the stream and the file or device, and @emph{not} with how things like echoing, flow control, and the like are handled on specific classes of devices. For information on common control operations on terminal devices, see @ref{Low-Level Terminal Interface}. You can bypass the stream buffering facilities altogether by using the low-level input and output functions that operate on file descriptors instead. @xref{Low-Level I/O}. @menu * Buffering Concepts:: Terminology is defined here. * Flushing Buffers:: How to ensure that output buffers are flushed. * Controlling Buffering:: How to specify what kind of buffering to use. @end menu @node Buffering Concepts @subsection Buffering Concepts There are three different kinds of buffering strategies: @itemize @bullet @item Characters written to or read from an @dfn{unbuffered} stream are transmitted individually to or from the file as soon as possible. @cindex unbuffered stream @item Characters written to a @dfn{line buffered} stream are transmitted to the file in blocks when a newline character is encountered. @cindex line buffered stream @item Characters written to or read from a @dfn{fully buffered} stream are transmitted to or from the file in blocks of arbitrary size. @cindex fully buffered stream @end itemize Newly opened streams are normally fully buffered, with one exception: a stream connected to an interactive device such as a terminal is initially line buffered. @xref{Controlling Buffering}, for information on how to select a different kind of buffering. Usually the automatic selection gives you the most convenient kind of buffering for the file or device you open. The use of line buffering for interactive devices implies that output messages ending in a newline will appear immediately---which is usually what you want. Output that doesn't end in a newline might or might not show up immediately, so if you want them to appear immediately, you should flush buffered output explicitly with @code{fflush}, as described in @ref{Flushing Buffers}. @node Flushing Buffers @subsection Flushing Buffers @cindex flushing a stream @dfn{Flushing} output on a buffered stream means transmitting all accumulated characters to the file. There are many circumstances when buffered output on a stream is flushed automatically: @itemize @bullet @item When you try to do output and the output buffer is full. @item When the stream is closed. @xref{Closing Streams}. @item When the program terminates by calling @code{exit}. @xref{Normal Termination}. @item When a newline is written, if the stream is line buffered. @item Whenever an input operation on @emph{any} stream actually reads data from its file. @end itemize If you want to flush the buffered output at another time, call @code{fflush}, which is declared in the header file @file{stdio.h}. @pindex stdio.h @comment stdio.h @comment ISO @deftypefun int fflush (FILE *@var{stream}) This function causes any buffered output on @var{stream} to be delivered to the file. If @var{stream} is a null pointer, then @code{fflush} causes buffered output on @emph{all} open output streams to be flushed. This function returns @code{EOF} if a write error occurs, or zero otherwise. @end deftypefun @strong{Compatibility Note:} Some brain-damaged operating systems have been known to be so thoroughly fixated on line-oriented input and output that flushing a line buffered stream causes a newline to be written! Fortunately, this ``feature'' seems to be becoming less common. You do not need to worry about this in the GNU system. @node Controlling Buffering @subsection Controlling Which Kind of Buffering After opening a stream (but before any other operations have been performed on it), you can explicitly specify what kind of buffering you want it to have using the @code{setvbuf} function. @cindex buffering, controlling The facilities listed in this section are declared in the header file @file{stdio.h}. @pindex stdio.h @comment stdio.h @comment ISO @deftypefun int setvbuf (FILE *@var{stream}, char *@var{buf}, int @var{mode}, size_t @var{size}) This function is used to specify that the stream @var{stream} should have the buffering mode @var{mode}, which can be either @code{_IOFBF} (for full buffering), @code{_IOLBF} (for line buffering), or @code{_IONBF} (for unbuffered input/output). If you specify a null pointer as the @var{buf} argument, then @code{setvbuf} allocates a buffer itself using @code{malloc}. This buffer will be freed when you close the stream. Otherwise, @var{buf} should be a character array that can hold at least @var{size} characters. You should not free the space for this array as long as the stream remains open and this array remains its buffer. You should usually either allocate it statically, or @code{malloc} (@pxref{Unconstrained Allocation}) the buffer. Using an automatic array is not a good idea unless you close the file before exiting the block that declares the array. While the array remains a stream buffer, the stream I/O functions will use the buffer for their internal purposes. You shouldn't try to access the values in the array directly while the stream is using it for buffering. The @code{setvbuf} function returns zero on success, or a nonzero value if the value of @var{mode} is not valid or if the request could not be honored. @end deftypefun @comment stdio.h @comment ISO @deftypevr Macro int _IOFBF The value of this macro is an integer constant expression that can be used as the @var{mode} argument to the @code{setvbuf} function to specify that the stream should be fully buffered. @end deftypevr @comment stdio.h @comment ISO @deftypevr Macro int _IOLBF The value of this macro is an integer constant expression that can be used as the @var{mode} argument to the @code{setvbuf} function to specify that the stream should be line buffered. @end deftypevr @comment stdio.h @comment ISO @deftypevr Macro int _IONBF The value of this macro is an integer constant expression that can be used as the @var{mode} argument to the @code{setvbuf} function to specify that the stream should be unbuffered. @end deftypevr @comment stdio.h @comment ISO @deftypevr Macro int BUFSIZ The value of this macro is an integer constant expression that is good to use for the @var{size} argument to @code{setvbuf}. This value is guaranteed to be at least @code{256}. The value of @code{BUFSIZ} is chosen on each system so as to make stream I/O efficient. So it is a good idea to use @code{BUFSIZ} as the size for the buffer when you call @code{setvbuf}. Actually, you can get an even better value to use for the buffer size by means of the @code{fstat} system call: it is found in the @code{st_blksize} field of the file attributes. @xref{Attribute Meanings}. Sometimes people also use @code{BUFSIZ} as the allocation size of buffers used for related purposes, such as strings used to receive a line of input with @code{fgets} (@pxref{Character Input}). There is no particular reason to use @code{BUFSIZ} for this instead of any other integer, except that it might lead to doing I/O in chunks of an efficient size. @end deftypevr @comment stdio.h @comment ISO @deftypefun void setbuf (FILE *@var{stream}, char *@var{buf}) If @var{buf} is a null pointer, the effect of this function is equivalent to calling @code{setvbuf} with a @var{mode} argument of @code{_IONBF}. Otherwise, it is equivalent to calling @code{setvbuf} with @var{buf}, and a @var{mode} of @code{_IOFBF} and a @var{size} argument of @code{BUFSIZ}. The @code{setbuf} function is provided for compatibility with old code; use @code{setvbuf} in all new programs. @end deftypefun @comment stdio.h @comment BSD @deftypefun void setbuffer (FILE *@var{stream}, char *@var{buf}, size_t @var{size}) If @var{buf} is a null pointer, this function makes @var{stream} unbuffered. Otherwise, it makes @var{stream} fully buffered using @var{buf} as the buffer. The @var{size} argument specifies the length of @var{buf}. This function is provided for compatibility with old BSD code. Use @code{setvbuf} instead. @end deftypefun @comment stdio.h @comment BSD @deftypefun void setlinebuf (FILE *@var{stream}) This function makes @var{stream} be line buffered, and allocates the buffer for you. This function is provided for compatibility with old BSD code. Use @code{setvbuf} instead. @end deftypefun @node Other Kinds of Streams @section Other Kinds of Streams The GNU library provides ways for you to define additional kinds of streams that do not necessarily correspond to an open file. One such type of stream takes input from or writes output to a string. These kinds of streams are used internally to implement the @code{sprintf} and @code{sscanf} functions. You can also create such a stream explicitly, using the functions described in @ref{String Streams}. More generally, you can define streams that do input/output to arbitrary objects using functions supplied by your program. This protocol is discussed in @ref{Custom Streams}. @strong{Portability Note:} The facilities described in this section are specific to GNU. Other systems or C implementations might or might not provide equivalent functionality. @menu * String Streams:: Streams that get data from or put data in a string or memory buffer. * Obstack Streams:: Streams that store data in an obstack. * Custom Streams:: Defining your own streams with an arbitrary input data source and/or output data sink. @end menu @node String Streams @subsection String Streams @cindex stream, for I/O to a string @cindex string stream The @code{fmemopen} and @code{open_memstream} functions allow you to do I/O to a string or memory buffer. These facilities are declared in @file{stdio.h}. @pindex stdio.h @comment stdio.h @comment GNU @deftypefun {FILE *} fmemopen (void *@var{buf}, size_t @var{size}, const char *@var{opentype}) This function opens a stream that allows the access specified by the @var{opentype} argument, that reads from or writes to the buffer specified by the argument @var{buf}. This array must be at least @var{size} bytes long. If you specify a null pointer as the @var{buf} argument, @code{fmemopen} dynamically allocates (as with @code{malloc}; @pxref{Unconstrained Allocation}) an array @var{size} bytes long. This is really only useful if you are going to write things to the buffer and then read them back in again, because you have no way of actually getting a pointer to the buffer (for this, try @code{open_memstream}, below). The buffer is freed when the stream is open. The argument @var{opentype} is the same as in @code{fopen} (@pxref{Opening Streams}). If the @var{opentype} specifies append mode, then the initial file position is set to the first null character in the buffer. Otherwise the initial file position is at the beginning of the buffer. When a stream open for writing is flushed or closed, a null character (zero byte) is written at the end of the buffer if it fits. You should add an extra byte to the @var{size} argument to account for this. Attempts to write more than @var{size} bytes to the buffer result in an error. For a stream open for reading, null characters (zero bytes) in the buffer do not count as ``end of file''. Read operations indicate end of file only when the file position advances past @var{size} bytes. So, if you want to read characters from a null-terminated string, you should supply the length of the string as the @var{size} argument. @end deftypefun Here is an example of using @code{fmemopen} to create a stream for reading from a string: @smallexample @include memopen.c.texi @end smallexample This program produces the following output: @smallexample Got f Got o Got o Got b Got a Got r @end smallexample @comment stdio.h @comment GNU @deftypefun {FILE *} open_memstream (char **@var{ptr}, size_t *@var{sizeloc}) This function opens a stream for writing to a buffer. The buffer is allocated dynamically (as with @code{malloc}; @pxref{Unconstrained Allocation}) and grown as necessary. When the stream is closed with @code{fclose} or flushed with @code{fflush}, the locations @var{ptr} and @var{sizeloc} are updated to contain the pointer to the buffer and its size. The values thus stored remain valid only as long as no further output on the stream takes place. If you do more output, you must flush the stream again to store new values before you use them again. A null character is written at the end of the buffer. This null character is @emph{not} included in the size value stored at @var{sizeloc}. You can move the stream's file position with @code{fseek} or @code{fseeko} (@pxref{File Positioning}). Moving the file position past the end of the data already written fills the intervening space with zeroes. @end deftypefun Here is an example of using @code{open_memstream}: @smallexample @include memstrm.c.texi @end smallexample This program produces the following output: @smallexample buf = `hello', size = 5 buf = `hello, world', size = 12 @end smallexample @c @group Invalid outside @example. @node Obstack Streams @subsection Obstack Streams You can open an output stream that puts it data in an obstack. @xref{Obstacks}. @comment stdio.h @comment GNU @deftypefun {FILE *} open_obstack_stream (struct obstack *@var{obstack}) This function opens a stream for writing data into the obstack @var{obstack}. This starts an object in the obstack and makes it grow as data is written (@pxref{Growing Objects}). @c @end group Doubly invalid because not nested right. Calling @code{fflush} on this stream updates the current size of the object to match the amount of data that has been written. After a call to @code{fflush}, you can examine the object temporarily. You can move the file position of an obstack stream with @code{fseek} or @code{fseeko} (@pxref{File Positioning}). Moving the file position past the end of the data written fills the intervening space with zeros. To make the object permanent, update the obstack with @code{fflush}, and then use @code{obstack_finish} to finalize the object and get its address. The following write to the stream starts a new object in the obstack, and later writes add to that object until you do another @code{fflush} and @code{obstack_finish}. But how do you find out how long the object is? You can get the length in bytes by calling @code{obstack_object_size} (@pxref{Status of an Obstack}), or you can null-terminate the object like this: @smallexample obstack_1grow (@var{obstack}, 0); @end smallexample Whichever one you do, you must do it @emph{before} calling @code{obstack_finish}. (You can do both if you wish.) @end deftypefun Here is a sample function that uses @code{open_obstack_stream}: @smallexample char * make_message_string (const char *a, int b) @{ FILE *stream = open_obstack_stream (&message_obstack); output_task (stream); fprintf (stream, ": "); fprintf (stream, a, b); fprintf (stream, "\n"); fclose (stream); obstack_1grow (&message_obstack, 0); return obstack_finish (&message_obstack); @} @end smallexample @node Custom Streams @subsection Programming Your Own Custom Streams @cindex custom streams @cindex programming your own streams This section describes how you can make a stream that gets input from an arbitrary data source or writes output to an arbitrary data sink programmed by you. We call these @dfn{custom streams}. The functions and types described here are all GNU extensions. @c !!! this does not talk at all about the higher-level hooks @menu * Streams and Cookies:: The @dfn{cookie} records where to fetch or store data that is read or written. * Hook Functions:: How you should define the four @dfn{hook functions} that a custom stream needs. @end menu @node Streams and Cookies @subsubsection Custom Streams and Cookies @cindex cookie, for custom stream Inside every custom stream is a special object called the @dfn{cookie}. This is an object supplied by you which records where to fetch or store the data read or written. It is up to you to define a data type to use for the cookie. The stream functions in the library never refer directly to its contents, and they don't even know what the type is; they record its address with type @code{void *}. To implement a custom stream, you must specify @emph{how} to fetch or store the data in the specified place. You do this by defining @dfn{hook functions} to read, write, change ``file position'', and close the stream. All four of these functions will be passed the stream's cookie so they can tell where to fetch or store the data. The library functions don't know what's inside the cookie, but your functions will know. When you create a custom stream, you must specify the cookie pointer, and also the four hook functions stored in a structure of type @code{cookie_io_functions_t}. These facilities are declared in @file{stdio.h}. @pindex stdio.h @comment stdio.h @comment GNU @deftp {Data Type} {cookie_io_functions_t} This is a structure type that holds the functions that define the communications protocol between the stream and its cookie. It has the following members: @table @code @item cookie_read_function_t *read This is the function that reads data from the cookie. If the value is a null pointer instead of a function, then read operations on this stream always return @code{EOF}. @item cookie_write_function_t *write This is the function that writes data to the cookie. If the value is a null pointer instead of a function, then data written to the stream is discarded. @item cookie_seek_function_t *seek This is the function that performs the equivalent of file positioning on the cookie. If the value is a null pointer instead of a function, calls to @code{fseek} or @code{fseeko} on this stream can only seek to locations within the buffer; any attempt to seek outside the buffer will return an @code{ESPIPE} error. @item cookie_close_function_t *close This function performs any appropriate cleanup on the cookie when closing the stream. If the value is a null pointer instead of a function, nothing special is done to close the cookie when the stream is closed. @end table @end deftp @comment stdio.h @comment GNU @deftypefun {FILE *} fopencookie (void *@var{cookie}, const char *@var{opentype}, cookie_io_functions_t @var{io-functions}) This function actually creates the stream for communicating with the @var{cookie} using the functions in the @var{io-functions} argument. The @var{opentype} argument is interpreted as for @code{fopen}; see @ref{Opening Streams}. (But note that the ``truncate on open'' option is ignored.) The new stream is fully buffered. The @code{fopencookie} function returns the newly created stream, or a null pointer in case of an error. @end deftypefun @node Hook Functions @subsubsection Custom Stream Hook Functions @cindex hook functions (of custom streams) Here are more details on how you should define the four hook functions that a custom stream needs. You should define the function to read data from the cookie as: @smallexample ssize_t @var{reader} (void *@var{cookie}, void *@var{buffer}, size_t @var{size}) @end smallexample This is very similar to the @code{read} function; see @ref{I/O Primitives}. Your function should transfer up to @var{size} bytes into the @var{buffer}, and return the number of bytes read, or zero to indicate end-of-file. You can return a value of @code{-1} to indicate an error. You should define the function to write data to the cookie as: @smallexample ssize_t @var{writer} (void *@var{cookie}, const void *@var{buffer}, size_t @var{size}) @end smallexample This is very similar to the @code{write} function; see @ref{I/O Primitives}. Your function should transfer up to @var{size} bytes from the buffer, and return the number of bytes written. You can return a value of @code{-1} to indicate an error. You should define the function to perform seek operations on the cookie as: @smallexample int @var{seeker} (void *@var{cookie}, fpos_t *@var{position}, int @var{whence}) @end smallexample For this function, the @var{position} and @var{whence} arguments are interpreted as for @code{fgetpos}; see @ref{Portable Positioning}. In the GNU library, @code{fpos_t} is equivalent to @code{off_t} or @code{long int}, and simply represents the number of bytes from the beginning of the file. After doing the seek operation, your function should store the resulting file position relative to the beginning of the file in @var{position}. Your function should return a value of @code{0} on success and @code{-1} to indicate an error. You should define the function to do cleanup operations on the cookie appropriate for closing the stream as: @smallexample int @var{cleaner} (void *@var{cookie}) @end smallexample Your function should return @code{-1} to indicate an error, and @code{0} otherwise. @comment stdio.h @comment GNU @deftp {Data Type} cookie_read_function This is the data type that the read function for a custom stream should have. If you declare the function as shown above, this is the type it will have. @end deftp @comment stdio.h @comment GNU @deftp {Data Type} cookie_write_function The data type of the write function for a custom stream. @end deftp @comment stdio.h @comment GNU @deftp {Data Type} cookie_seek_function The data type of the seek function for a custom stream. @end deftp @comment stdio.h @comment GNU @deftp {Data Type} cookie_close_function The data type of the close function for a custom stream. @end deftp @ignore Roland says: @quotation There is another set of functions one can give a stream, the input-room and output-room functions. These functions must understand stdio internals. To describe how to use these functions, you also need to document lots of how stdio works internally (which isn't relevant for other uses of stdio). Perhaps I can write an interface spec from which you can write good documentation. But it's pretty complex and deals with lots of nitty-gritty details. I think it might be better to let this wait until the rest of the manual is more done and polished. @end quotation @end ignore @c ??? This section could use an example. @node Formatted Messages @section Formatted Messages @cindex formatted messages On systems which are based on System V messages of programs (especially the system tools) are printed in a strict form using the @code{fmtmsg} function. The uniformity sometimes helps the user to interpret messages and the strictness tests of the @code{fmtmsg} function ensure that the programmer follows some minimal requirements. @menu * Printing Formatted Messages:: The @code{fmtmsg} function. * Adding Severity Classes:: Add more severity classes. * Example:: How to use @code{fmtmsg} and @code{addseverity}. @end menu @node Printing Formatted Messages @subsection Printing Formatted Messages Messages can be printed to standard error and/or to the console. To select the destination the programmer can use the following two values, bitwise OR combined if wanted, for the @var{classification} parameter of @code{fmtmsg}: @vtable @code @item MM_PRINT Display the message in standard error. @item MM_CONSOLE Display the message on the system console. @end vtable The erroneous piece of the system can be signalled by exactly one of the following values which also is bitwise ORed with the @var{classification} parameter to @code{fmtmsg}: @vtable @code @item MM_HARD The source of the condition is some hardware. @item MM_SOFT The source of the condition is some software. @item MM_FIRM The source of the condition is some firmware. @end vtable A third component of the @var{classification} parameter to @code{fmtmsg} can describe the part of the system which detects the problem. This is done by using exactly one of the following values: @vtable @code @item MM_APPL The erroneous condition is detected by the application. @item MM_UTIL The erroneous condition is detected by a utility. @item MM_OPSYS The erroneous condition is detected by the operating system. @end vtable A last component of @var{classification} can signal the results of this message. Exactly one of the following values can be used: @vtable @code @item MM_RECOVER It is a recoverable error. @item MM_NRECOV It is a non-recoverable error. @end vtable @comment fmtmsg.h @comment XPG @deftypefun int fmtmsg (long int @var{classification}, const char *@var{label}, int @var{severity}, const char *@var{text}, const char *@var{action}, const char *@var{tag}) Display a message described by its parameters on the device(s) specified in the @var{classification} parameter. The @var{label} parameter identifies the source of the message. The string should consist of two colon separated parts where the first part has not more than 10 and the second part not more the 14 characters. The @var{text} parameter describes the condition of the error, the @var{action} parameter possible steps to recover from the error and the @var{tag} parameter is a reference to the online documentation where more information can be found. It should contain the @var{label} value and a unique identification number. Each of the parameters can be a special value which means this value is to be omitted. The symbolic names for these values are: @vtable @code @item MM_NULLLBL Ignore @var{label} parameter. @item MM_NULLSEV Ignore @var{severity} parameter. @item MM_NULLMC Ignore @var{classification} parameter. This implies that nothing is actually printed. @item MM_NULLTXT Ignore @var{text} parameter. @item MM_NULLACT Ignore @var{action} parameter. @item MM_NULLTAG Ignore @var{tag} parameter. @end vtable There is another way certain fields can be omitted from the output to standard error. This is described below in the description of environment variables influencing the behaviour. The @var{severity} parameter can have one of the values in the following table: @cindex severity class @vtable @code @item MM_NOSEV Nothing is printed, this value is the same as @code{MM_NULLSEV}. @item MM_HALT This value is printed as @code{HALT}. @item MM_ERROR This value is printed as @code{ERROR}. @item MM_WARNING This value is printed as @code{WARNING}. @item MM_INFO This value is printed as @code{INFO}. @end vtable The numeric value of these five macros are between @code{0} and @code{4}. Using the environment variable @code{SEV_LEVEL} or using the @code{addseverity} function one can add more severity levels with their corresponding string to print. This is described below (@pxref{Adding Severity Classes}). @noindent If no parameter is ignored the output looks like this: @smallexample @var{label}: @var{severity-string}: @var{text} TO FIX: @var{action} @var{tag} @end smallexample The colons, new line characters and the @code{TO FIX} string are inserted if necessary, i.e., if the corresponding parameter is not ignored. This function is specified in the X/Open Portability Guide. It is also available on all system derived from System V. The function returns the value @code{MM_OK} if no error occurred. If only the printing to standard error failed, it returns @code{MM_NOMSG}. If printing to the console fails, it returns @code{MM_NOCON}. If nothing is printed @code{MM_NOTOK} is returned. Among situations where all outputs fail this last value is also returned if a parameter value is incorrect. @end deftypefun There are two environment variables which influence the behaviour of @code{fmtmsg}. The first is @code{MSGVERB}. It is used to control the output actually happening on standard error (@emph{not} the console output). Each of the five fields can explicitely be enabled. To do this the user has to put the @code{MSGVERB} variable with a format like the following in the environment before calling the @code{fmtmsg} function the first time: @smallexample MSGVERB=@var{keyword}[:@var{keyword}[:...]] @end smallexample Valid @var{keyword}s are @code{label}, @code{severity}, @code{text}, @code{action}, and @code{tag}. If the environment variable is not given or is the empty string, a not supported keyword is given or the value is somehow else invalid, no part of the message is masked out. The second environment variable which influences the behaviour of @code{fmtmsg} is @code{SEV_LEVEL}. This variable and the change in the behaviour of @code{fmtmsg} is not specified in the X/Open Portability Guide. It is available in System V systems, though. It can be used to introduce new severity levels. By default, only the five severity levels described above are available. Any other numeric value would make @code{fmtmsg} print nothing. If the user puts @code{SEV_LEVEL} with a format like @smallexample SEV_LEVEL=[@var{description}[:@var{description}[:...]]] @end smallexample @noindent in the environment of the process before the first call to @code{fmtmsg}, where @var{description} has a value of the form @smallexample @var{severity-keyword},@var{level},@var{printstring} @end smallexample The @var{severity-keyword} part is not used by @code{fmtmsg} but it has to be present. The @var{level} part is a string representation of a number. The numeric value must be a number greater than 4. This value must be used in the @var{severity} parameter of @code{fmtmsg} to select this class. It is not possible to overwrite any of the predefined classes. The @var{printstring} is the string printed when a message of this class is processed by @code{fmtmsg} (see above, @code{fmtsmg} does not print the numeric value but instead the string representation). @node Adding Severity Classes @subsection Adding Severity Classes @cindex severity class There is another possibility to introduce severity classes beside using the environment variable @code{SEV_LEVEL}. This simplifies the task of introducing new classes in a running program. One could use the @code{setenv} or @code{putenv} function to set the environment variable, but this is toilsome. @deftypefun int addseverity (int @var{severity}, const char *@var{string}) This function allows to introduce new severity classes which can be addressed by the @var{severity} parameter of the @code{fmtmsg} function. The @var{severity} parameter of @code{addseverity} must match the value for the parameter with the same name of @code{fmtmsg} and @var{string} is the string printed in the actual messages instead of the numeric value. If @var{string} is @code{NULL} the severity class with the numeric value according to @var{severity} is removed. It is not possible to overwrite or remove one of the default severity classes. All calls to @code{addseverity} with @var{severity} set to one of the values for the default classes will fail. The return value is @code{MM_OK} if the task was successfully performed. If the return value is @code{MM_NOTOK} something went wrong. This could mean that no more memory is available or a class is not available when it has to be removed. This function is not specified in the X/Open Portability Guide although the @code{fmtsmg} function is. It is available on System V systems. @end deftypefun @node Example @subsection How to use @code{fmtmsg} and @code{addseverity} Here is a simple example program to illustrate the use of the both functions described in this section. @smallexample @include fmtmsgexpl.c.texi @end smallexample The second call to @code{fmtmsg} illustrates a use of this function how it usually happens on System V systems which heavily use this function. It might be worth a thought to follow the scheme used in System V systems so we give a short explanation here. The value of the @var{label} field (@code{UX:cat}) says that the error occured in the Unix program @code{cat}. The explanation of the error follows and the value for the @var{action} parameter is @code{"refer to manual"}. One could me more specific here, if needed. The @var{tag} field contains, as proposed above, the value of the string given for the @var{label} parameter, and additionally a unique ID (@code{001} in this case). For a GNU environment this string could contain a reference to the corresponding node in the Info page for the program. @noindent Running this program without specifying the @code{MSGVERB} and @code{SEV_LEVEL} function produces the following output: @smallexample UX:cat: NOTE2: invalid syntax TO FIX: refer to manual UX:cat:001 @end smallexample We see the different fields of the message and how the extra glue (the colons and the @code{TO FIX} string) are printed. But only one of the three calls to @code{fmtmsg} produced output. The first call does not print anything because the @var{label} parameter is not in the correct form. The string must contain two fields, separated by a colon (@pxref{Printing Formatted Messages}). The third @code{fmtmsg} call produced no output since the class with the numeric value @code{6} is not defined. Although a class with numeric value @code{5} is also not defined by default, the call the @code{addseverity} introduces it and the second call to @code{fmtmsg} produces the above output. When we change the environment of the program to contain @code{SEV_LEVEL=XXX,6,NOTE} when running it we get a different result: @smallexample UX:cat: NOTE2: invalid syntax TO FIX: refer to manual UX:cat:001 label:foo: NOTE: text TO FIX: action tag @end smallexample Now the third call the @code{fmtmsg} produced some output and we see how the string @code{NOTE} from the environment variable appears in the message. Now we can reduce the output by specifying in which fields we are interested in. If we additionally set the environment variable @code{MSGVERB} to the value @code{severity:label:action} we get the following output: @smallexample UX:cat: NOTE2 TO FIX: refer to manual label:foo: NOTE TO FIX: action @end smallexample @noindent I.e., the output produced by the @var{text} and the @var{tag} parameters to @code{fmtmsg} vanished. Please also note that now there is no colon after the @code{NOTE} and @code{NOTE2} strings in the output. This is not necessary since there is no more output on this line since the text is missing.