@c -*-texinfo-*- @c This is part of the GNU Guile Reference Manual. @c Copyright (C) 1996, 1997, 2000, 2001, 2002, 2003, 2004, 2007, 2009, @c 2010, 2011, 2013, 2016, 2019, 2021, 2023 Free Software Foundation, Inc. @c See the file guile.texi for copying conditions. @node Input and Output @section Input and Output @menu * Ports:: What's a port? * Binary I/O:: Reading and writing bytes. * Encoding:: Characters as bytes. * Textual I/O:: Reading and writing characters. * Simple Output:: Simple syntactic sugar solution. * Buffering:: Controlling when data is written to ports. * Random Access:: Moving around a random access port. * Line/Delimited:: Read and write lines or delimited text. * Default Ports:: Defaults for input, output and errors. * Port Types:: Types of port and how to make them. * Venerable Port Interfaces:: Procedures from the last millennium. * Using Ports from C:: Nice interfaces for C. * Non-Blocking I/O:: How Guile deals with EWOULDBLOCK. * BOM Handling:: Handling of Unicode byte order marks. @end menu @node Ports @subsection Ports @cindex Port Ports are the way that Guile performs input and output. Guile can read in characters or bytes from an @dfn{input port}, or write them out to an @dfn{output port}. Some ports support both interfaces. There are a number of different port types implemented in Guile. File ports provide input and output over files, as you might imagine. For example, we might display a string to a file like this: @example (let ((port (open-output-file "foo.txt"))) (display "Hello, world!\n" port) (close-port port)) @end example There are also string ports, for taking input from a string, or collecting output to a string; bytevector ports, for doing the same but using a bytevector as a source or sink of data; and custom ports, for arranging to call Scheme functions to provide input or handle output. @xref{Port Types}. Ports should be @dfn{closed} when they are not needed by calling @code{close-port} on them, as in the example above. This will make sure that any pending output is successfully written out to disk, in the case of a file port, or otherwise to whatever mutable store is backed by the port. Any error that occurs while writing out that buffered data would also be raised promptly at the @code{close-port}, and not later when the port is closed by the garbage collector. @xref{Buffering}, for more on buffered output. Closing a port also releases any precious resource the file might have. Usually in Scheme a programmer doesn't have to clean up after their data structures (@pxref{Memory Management}), but most systems have strict limits on how many files can be open, both on a per-process and a system-wide basis. A program that uses many files should take care not to hit those limits. The same applies to similar system resources such as pipes and sockets. Indeed for these reasons the above example is not the most idiomatic way to use ports. It is more common to acquire ports via procedures like @code{call-with-output-file}, which handle the @code{close-port} automatically: @example (call-with-output-file "foo.txt" (lambda (port) (display "Hello, world!\n" port))) @end example Finally, all ports have associated input and output buffers, as appropriate. Buffering is a common strategy to limit the overhead of small reads and writes: without buffering, each character fetched from a file would involve at least one call into the kernel, and maybe more depending on the character and the encoding. Instead, Guile will batch reads and writes into internal buffers. However, sometimes you want to make output on a port show up immediately. @xref{Buffering}, for more on interfaces to control port buffering. @deffn {Scheme Procedure} port? x @deffnx {C Function} scm_port_p (x) Return a boolean indicating whether @var{x} is a port. Equivalent to @code{(or (input-port? @var{x}) (output-port? @var{x}))}. @end deffn @rnindex input-port? @deffn {Scheme Procedure} input-port? x @deffnx {C Function} scm_input_port_p (x) Return @code{#t} if @var{x} is an input port, otherwise return @code{#f}. Any object satisfying this predicate also satisfies @code{port?}. @end deffn @rnindex output-port? @deffn {Scheme Procedure} output-port? x @deffnx {C Function} scm_output_port_p (x) Return @code{#t} if @var{x} is an output port, otherwise return @code{#f}. Any object satisfying this predicate also satisfies @code{port?}. @end deffn @cindex Closing ports @cindex Port, close @deffn {Scheme Procedure} close-port port @deffnx {C Function} scm_close_port (port) Close the specified port object. Return @code{#t} if it successfully closes a port or @code{#f} if it was already closed. An exception may be raised if an error occurs, for example when flushing buffered output. @xref{Buffering}, for more on buffered output. @xref{Ports and File Descriptors, close}, for a procedure which can close file descriptors. @end deffn @deffn {Scheme Procedure} port-closed? port @deffnx {C Function} scm_port_closed_p (port) Return @code{#t} if @var{port} is closed or @code{#f} if it is open. @end deffn @deffn {Scheme Procedure} call-with-port port proc Call @var{proc}, passing it @var{port} and closing @var{port} upon exit of @var{proc}. Return the return values of @var{proc}. @end deffn @node Binary I/O @subsection Binary I/O Guile's ports are fundamentally binary in nature: at the lowest level, they work on bytes. This section describes Guile's core binary I/O operations. @xref{Textual I/O}, for input and output of strings and characters. To use these routines, first include the binary I/O module: @example (use-modules (ice-9 binary-ports)) @end example Note that although this module's name suggests that binary ports are some different kind of port, that's not the case: all ports in Guile are both binary and textual ports. @cindex binary input @anchor{x-get-u8} @deffn {Scheme Procedure} get-u8 port @deffnx {C Function} scm_get_u8 (port) Return an octet read from @var{port}, an input port, blocking as necessary, or the end-of-file object. @end deffn @anchor{x-lookahead-u8} @deffn {Scheme Procedure} lookahead-u8 port @deffnx {C Function} scm_lookahead_u8 (port) Like @code{get-u8} but does not update @var{port}'s position to point past the octet. @end deffn The end-of-file object is unlike any other kind of object: it's not a pair, a symbol, or anything else. To check if a value is the end-of-file object, use the @code{eof-object?} predicate. @rnindex eof-object? @cindex End of file object @deffn {Scheme Procedure} eof-object? x @deffnx {C Function} scm_eof_object_p (x) Return @code{#t} if @var{x} is an end-of-file object, or @code{#f} otherwise. @end deffn Note that unlike other procedures in this module, @code{eof-object?} is defined in the default environment. @deffn {Scheme Procedure} get-bytevector-n port count @deffnx {C Function} scm_get_bytevector_n (port, count) Read @var{count} octets from @var{port}, blocking as necessary and return a bytevector containing the octets read. If fewer bytes are available, a bytevector smaller than @var{count} is returned. @end deffn @deffn {Scheme Procedure} get-bytevector-n! port bv start count @deffnx {C Function} scm_get_bytevector_n_x (port, bv, start, count) Read @var{count} bytes from @var{port} and store them in @var{bv} starting at index @var{start}. Return either the number of bytes actually read or the end-of-file object. @end deffn @deffn {Scheme Procedure} get-bytevector-some port @deffnx {C Function} scm_get_bytevector_some (port) Read from @var{port}, blocking as necessary, until bytes are available or an end-of-file is reached. Return either the end-of-file object or a new bytevector containing some of the available bytes (at least one), and update the port position to point just past these bytes. @end deffn @deffn {Scheme Procedure} get-bytevector-some! port bv start count @deffnx {C Function} scm_get_bytevector_some_x (port, bv, start, count) Read up to @var{count} bytes from @var{port}, blocking as necessary until at least one byte is available or an end-of-file is reached. Store them in @var{bv} starting at index @var{start}. Return the number of bytes actually read, or an end-of-file object. @end deffn @deffn {Scheme Procedure} get-bytevector-all port @deffnx {C Function} scm_get_bytevector_all (port) Read from @var{port}, blocking as necessary, until the end-of-file is reached. Return either a new bytevector containing the data read or the end-of-file object (if no data were available). @end deffn @deffn {Scheme Procedure} unget-bytevector port bv [start [count]] @deffnx {C Function} scm_unget_bytevector (port, bv, start, count) Place the contents of @var{bv} in @var{port}, optionally starting at index @var{start} and limiting to @var{count} octets, so that its bytes will be read from left-to-right as the next bytes from @var{port} during subsequent read operations. If called multiple times, the unread bytes will be read again in last-in first-out order. @end deffn @cindex binary output To perform binary output on a port, use @code{put-u8} or @code{put-bytevector}. @anchor{x-put-u8} @deffn {Scheme Procedure} put-u8 port octet @deffnx {C Function} scm_put_u8 (port, octet) Write @var{octet}, an integer in the 0--255 range, to @var{port}, a binary output port. @end deffn @deffn {Scheme Procedure} put-bytevector port bv [start [count]] @deffnx {C Function} scm_put_bytevector (port, bv, start, count) Write the contents of @var{bv} to @var{port}, optionally starting at index @var{start} and limiting to @var{count} octets. @end deffn @subsubheading Binary I/O in R7RS @ref{R7RS Standard Libraries,R7RS} defines the following binary I/O procedures. Access them with @example (use-modules (scheme base)) @end example @anchor{x-open-output-bytevector} @deffn {Scheme Procedure} open-output-bytevector Returns a binary output port that will accumulate bytes for retrieval by @ref{x-get-output-bytevector,@code{get-output-bytevector}}. @end deffn @deffn {Scheme Procedure} write-u8 byte [out] Writes @var{byte} to the given binary output port @var{out} and returns an unspecified value. @var{out} defaults to @code{(current-output-port)}. See also @ref{x-put-u8,@code{put-u8}}. @end deffn @deffn {Scheme Procedure} read-u8 [in] Returns the next byte available from the binary input port @var{in}, updating the port to point to the following byte. If no more bytes are available, an end-of-file object is returned. @var{in} defaults to @code{(current-input-port)}. See also @ref{x-get-u8,@code{get-u8}}. @end deffn @deffn {Scheme Procedure} peek-u8 [in] Returns the next byte available from the binary input port @var{in}, but without updating the port to point to the following byte. If no more bytes are available, an end-of-file object is returned. @var{in} defaults to @code{(current-input-port)}. See also @ref{x-lookahead-u8,@code{lookahead-u8}}. @end deffn @anchor{x-get-output-bytevector} @deffn {Scheme Procedure} get-output-bytevector port Returns a bytevector consisting of the bytes that have been output to @var{port} so far in the order they were output. It is an error if @var{port} was not created with @ref{x-open-output-bytevector,@code{open-output-bytevector}}. @example (define out (open-output-bytevector)) (write-u8 1 out) (write-u8 2 out) (write-u8 3 out) (get-output-bytevector out) @result{} #vu8(1 2 3) @end example @end deffn @deffn {Scheme Procedure} open-input-bytevector bv Takes a bytevector @var{bv} and returns a binary input port that delivers bytes from @var{bv}. @example (define in (open-input-bytevector #vu8(1 2 3))) (read-u8 in) @result{} 1 (peek-u8 in) @result{} 2 (read-u8 in) @result{} 2 (read-u8 in) @result{} 3 (read-u8 in) @result{} # @end example @end deffn @deffn {Scheme Procedure} read-bytevector! bv [port [start [end]]] Reads the next @var{end} - @var{start} bytes, or as many as are available before the end of file, from the binary input port into the bytevector @var{bv} in left-to-right order beginning at the @var{start} position. If @var{end} is not supplied, reads until the end of @var{bv} has been reached. If @var{start} is not supplied, reads beginning at position 0. Returns the number of bytes read. If no bytes are available, an end-of-file object is returned. @example (define in (open-input-bytevector #vu8(1 2 3))) (define bv (make-bytevector 5 0)) (read-bytevector! bv in 1 3) @result{} 2 bv @result{} #vu8(0 1 2 0 0 0) @end example @end deffn @deffn {Scheme Procedure} read-bytevector k in Reads the next @var{k} bytes, or as many as are available before the end of file if that is less than @var{k}, from the binary input port @var{in} into a newly allocated bytevector in left-to-right order, and returns the bytevector. If no bytes are available before the end of file, an end-of-file object is returned. @example (define bv #vu8(1 2 3)) (read-bytevector 2 (open-input-bytevector bv)) @result{} #vu8(1 2) (read-bytevector 10 (open-input-bytevector bv)) @result{} #vu8(1 2 3) @end example @end deffn @deffn {Scheme Procedure} write-bytevector bv [port [start [end]]] Writes the bytes of bytevector @var{bv} from @var{start} to @var{end} in left-to-right order to the binary output @var{port}. @var{start} defaults to 0 and @var{end} defaults to the length of @var{bv}. @example (define out (open-output-bytevector)) (write-bytevector #vu8(0 1 2 3 4) out 2 4) (get-output-bytevector out) @result{} #vu8(2 3) @end example @end deffn @node Encoding @subsection Encoding Textual input and output on Guile ports is layered on top of binary operations. To this end, each port has an associated character encoding that controls how bytes read from the port are converted to characters, and how characters written to the port are converted to bytes. @deffn {Scheme Procedure} port-encoding port @deffnx {C Function} scm_port_encoding (port) Returns, as a string, the character encoding that @var{port} uses to interpret its input and output. @end deffn @deffn {Scheme Procedure} set-port-encoding! port enc @deffnx {C Function} scm_set_port_encoding_x (port, enc) Sets the character encoding that will be used to interpret I/O to @var{port}. @var{enc} is a string containing the name of an encoding. Valid encoding names are those @url{http://www.iana.org/assignments/character-sets, defined by IANA}, for example @code{"UTF-8"} or @code{"ISO-8859-1"}. @end deffn When ports are created, they are assigned an encoding. The usual process to determine the initial encoding for a port is to take the value of the @code{%default-port-encoding} fluid. @defvr {Scheme Variable} %default-port-encoding A fluid containing name of the encoding to be used by default for newly created ports (@pxref{Fluids and Dynamic States}). As a special case, the value @code{#f} is equivalent to @code{"ISO-8859-1"}. @end defvr The @code{%default-port-encoding} itself defaults to the encoding appropriate for the current locale, if @code{setlocale} has been called. @xref{Locales}, for more on locales and when you might need to call @code{setlocale} explicitly. Some port types have other ways of determining their initial locales. String ports, for example, default to the UTF-8 encoding, in order to be able to represent all characters regardless of the current locale. File ports can optionally sniff their file for a @code{coding:} declaration; @xref{File Ports}. Binary ports might be initialized to the ISO-8859-1 encoding in which each codepoint between 0 and 255 corresponds to a byte with that value. Currently, the ports only work with @emph{non-modal} encodings. Most encodings are non-modal, meaning that the conversion of bytes to a string doesn't depend on its context: the same byte sequence will always return the same string. A couple of modal encodings are in common use, like ISO-2022-JP and ISO-2022-KR, and they are not yet supported. @cindex port conversion strategy @cindex conversion strategy, port @cindex decoding error @cindex encoding error Each port also has an associated conversion strategy, which determines what to do when a Guile character can't be converted to the port's encoded character representation for output. There are three possible strategies: to raise an error, to replace the character with a hex escape, or to replace the character with a substitute character. Port conversion strategies are also used when decoding characters from an input port. @deffn {Scheme Procedure} port-conversion-strategy port @deffnx {C Function} scm_port_conversion_strategy (port) Returns the behavior of the port when outputting a character that is not representable in the port's current encoding. If @var{port} is @code{#f}, then the current default behavior will be returned. New ports will have this default behavior when they are created. @end deffn @deffn {Scheme Procedure} set-port-conversion-strategy! port sym @deffnx {C Function} scm_set_port_conversion_strategy_x (port, sym) Sets the behavior of Guile when outputting a character that is not representable in the port's current encoding, or when Guile encounters a decoding error when trying to read a character. @var{sym} can be either @code{error}, @code{substitute}, or @code{escape}. If @var{port} is an open port, the conversion error behavior is set for that port. If it is @code{#f}, it is set as the default behavior for any future ports that get created in this thread. @end deffn As with port encodings, there is a fluid which determines the initial conversion strategy for a port. @deffn {Scheme Variable} %default-port-conversion-strategy The fluid that defines the conversion strategy for newly created ports, and also for other conversion routines such as @code{scm_to_stringn}, @code{scm_from_stringn}, @code{string->pointer}, and @code{pointer->string}. Its value must be one of the symbols described above, with the same semantics: @code{error}, @code{substitute}, or @code{escape}. When Guile starts, its value is @code{substitute}. Note that @code{(set-port-conversion-strategy! #f @var{sym})} is equivalent to @code{(fluid-set! %default-port-conversion-strategy @var{sym})}. @end deffn As mentioned above, for an output port there are three possible port conversion strategies. The @code{error} strategy will throw an error when a nonconvertible character is encountered. The @code{substitute} strategy will replace nonconvertible characters with a question mark (@samp{?}). Finally the @code{escape} strategy will print nonconvertible characters as a hex escape, using the escaping that is recognized by Guile's string syntax. Note that if the port's encoding is a Unicode encoding, like @code{UTF-8}, then encoding errors are impossible. For an input port, the @code{error} strategy will cause Guile to throw an error if it encounters an invalid encoding, such as might happen if you tried to read @code{ISO-8859-1} as @code{UTF-8}. The error is thrown before advancing the read position. The @code{substitute} strategy will replace the bad bytes with a U+FFFD replacement character, in accordance with Unicode recommendations. When reading from an input port, the @code{escape} strategy is treated as if it were @code{error}. @node Textual I/O @subsection Textual I/O @cindex textual input @cindex textual output This section describes Guile's core textual I/O operations on characters and strings. @xref{Binary I/O}, for input and output of bytes and bytevectors. @xref{Encoding}, for more on how characters relate to bytes. To read general S-expressions from ports, @xref{Scheme Read}. @xref{Scheme Write}, for interfaces that write generic Scheme datums. To use these routines, first include the textual I/O module: @example (use-modules (ice-9 textual-ports)) @end example Note that although this module's name suggests that textual ports are some different kind of port, that's not the case: all ports in Guile are both binary and textual ports. @deffn {Scheme Procedure} get-char input-port Reads from @var{input-port}, blocking as necessary, until a complete character is available from @var{input-port}, or until an end of file is reached. If a complete character is available before the next end of file, @code{get-char} returns that character and updates the input port to point past the character. If an end of file is reached before any character is read, @code{get-char} returns the end-of-file object. @end deffn @deffn {Scheme Procedure} lookahead-char input-port The @code{lookahead-char} procedure is like @code{get-char}, but it does not update @var{input-port} to point past the character. @end deffn In the same way that it's possible to "unget" a byte or bytes, it's possible to "unget" the bytes corresponding to an encoded character. @deffn {Scheme Procedure} unget-char port char Place character @var{char} in @var{port} so that it will be read by the next read operation. If called multiple times, the unread characters will be read again in last-in first-out order. @end deffn @deffn {Scheme Procedure} unget-string port str Place the string @var{str} in @var{port} so that its characters will be read from left-to-right as the next characters from @var{port} during subsequent read operations. If called multiple times, the unread characters will be read again in last-in first-out order. @end deffn Reading in a character at a time can be inefficient. If it's possible to perform I/O over multiple characters at a time, via strings, that might be faster. @deffn {Scheme Procedure} get-string-n input-port count The @code{get-string-n} procedure reads from @var{input-port}, blocking as necessary, until @var{count} characters are available, or until an end of file is reached. @var{count} must be an exact, non-negative integer, representing the number of characters to be read. If @var{count} characters are available before end of file, @code{get-string-n} returns a string consisting of those @var{count} characters. If fewer characters are available before an end of file, but one or more characters can be read, @code{get-string-n} returns a string containing those characters. In either case, the input port is updated to point just past the characters read. If no characters can be read before an end of file, the end-of-file object is returned. @end deffn @deffn {Scheme Procedure} get-string-n! input-port string start count The @code{get-string-n!} procedure reads from @var{input-port} in the same manner as @code{get-string-n}. @var{start} and @var{count} must be exact, non-negative integer objects, with @var{count} representing the number of characters to be read. @var{string} must be a string with at least $@var{start} + @var{count}$ characters. If @var{count} characters are available before an end of file, they are written into @var{string} starting at index @var{start}, and @var{count} is returned. If fewer characters are available before an end of file, but one or more can be read, those characters are written into @var{string} starting at index @var{start} and the number of characters actually read is returned as an exact integer object. If no characters can be read before an end of file, the end-of-file object is returned. @end deffn @deffn {Scheme Procedure} get-string-all input-port Reads from @var{input-port} until an end of file, decoding characters in the same manner as @code{get-string-n} and @code{get-string-n!}. If characters are available before the end of file, a string containing all the characters decoded from that data are returned. If no character precedes the end of file, the end-of-file object is returned. @end deffn @deffn {Scheme Procedure} get-line input-port Reads from @var{input-port} up to and including the linefeed character or end of file, decoding characters in the same manner as @code{get-string-n} and @code{get-string-n!}. If a linefeed character is read, a string containing all of the text up to (but not including) the linefeed character is returned, and the port is updated to point just past the linefeed character. If an end of file is encountered before any linefeed character is read, but some characters have been read and decoded as characters, a string containing those characters is returned. If an end of file is encountered before any characters are read, the end-of-file object is returned. @end deffn Finally, there are just two core procedures to write characters to a port. @deffn {Scheme Procedure} put-char port char Writes @var{char} to the port. The @code{put-char} procedure returns an unspecified value. @end deffn @deffn {Scheme Procedure} put-string port string @deffnx {Scheme Procedure} put-string port string start @deffnx {Scheme Procedure} put-string port string start count Write the @var{count} characters of @var{string} starting at index @var{start} to the port. @var{start} and @var{count} must be non-negative exact integer objects. @var{string} must have a length of at least @math{@var{start} + @var{count}}. @var{start} defaults to 0. @var{count} defaults to @math{@code{(string-length @var{string})} - @var{start}}$. Calling @code{put-string} is equivalent in all respects to calling @code{put-char} on the relevant sequence of characters, except that it will attempt to write multiple characters to the port at a time, even if the port is unbuffered. The @code{put-string} procedure returns an unspecified value. @end deffn Textual ports have a textual position associated with them: a line and a column. Reading in characters or writing them out advances the line and the column appropriately. @deffn {Scheme Procedure} port-column port @deffnx {Scheme Procedure} port-line port @deffnx {C Function} scm_port_column (port) @deffnx {C Function} scm_port_line (port) Return the current column number or line number of @var{port}. @end deffn Port lines and positions are represented as 0-origin integers, which is to say that the first character of the first line is line 0, column 0. However, when you display a line number, for example in an error message, we recommend you add 1 to get 1-origin integers. This is because lines numbers traditionally start with 1, and that is what non-programmers will find most natural. @deffn {Scheme Procedure} set-port-column! port column @deffnx {Scheme Procedure} set-port-line! port line @deffnx {C Function} scm_set_port_column_x (port, column) @deffnx {C Function} scm_set_port_line_x (port, line) Set the current column or line number of @var{port}. @end deffn @node Simple Output @subsection Simple Textual Output Guile exports a simple formatted output function, @code{simple-format}. For a more capable formatted output facility, @xref{Formatted Output}. @deffn {Scheme Procedure} simple-format destination message . args @deffnx {C Function} scm_simple_format (destination, message, args) Write @var{message} to @var{destination}, defaulting to the current output port. @var{message} can contain @code{~A} and @code{~S} escapes. When printed, the escapes are replaced with corresponding members of @var{args}: @code{~A} formats using @code{display} and @code{~S} formats using @code{write}. If @var{destination} is @code{#t}, then use the current output port, if @var{destination} is @code{#f}, then return a string containing the formatted text. Does not add a trailing newline. @end deffn Somewhat confusingly, Guile binds the @code{format} identifier to @code{simple-format} at startup. Once @code{(ice-9 format)} loads, it actually replaces the core @code{format} binding, so depending on whether you or a module you use has loaded @code{(ice-9 format)}, you may be using the simple or the more capable version. @node Buffering @subsection Buffering @cindex Port, buffering Every port has associated input and output buffers. You can think of ports as being backed by some mutable store, and that store might be far away. For example, ports backed by file descriptors have to go all the way to the kernel to read and write their data. To avoid this round-trip cost, Guile usually reads in data from the mutable store in chunks, and then services small requests like @code{get-char} out of that intermediate buffer. Similarly, small writes like @code{write-char} first go to a buffer, and are sent to the store when the buffer is full (or when port is flushed). Buffered ports speed up your program by reducing the number of round-trips to the mutable store, and they do so in a way that is mostly transparent to the user. There are two major ways, however, in which buffering affects program semantics. Building correct, performant programs requires understanding these situations. The first case is in random-access read/write ports (@pxref{Random Access}). These ports, usually backed by a file, logically operate over the same mutable store when both reading and writing. So, if you read a character, causing the buffer to fill, then write a character, the bytes you filled in your read buffer are now invalid. Every time you switch between reading and writing, Guile has to flush any pending buffer. If this happens frequently, the cost can be high. In that case you should reduce the amount that you buffer, in both directions. Similarly, Guile has to flush buffers before seeking. None of these considerations apply to sockets, which don't logically read from and write to the same mutable store, and are not seekable. Note also that sockets are unbuffered by default. @xref{Network Sockets and Communication}. The second case is the more pernicious one. If you write data to a buffered port, it probably doesn't go out to the mutable store directly. (This ``probably'' introduces some indeterminism in your program: what goes to the store, and when, depends on how full the buffer is. It is something that the user needs to explicitly be aware of.) The data is written to the store later -- when the buffer fills up due to another write, or when @code{force-output} is called, or when @code{close-port} is called, or when the program exits, or even when the garbage collector runs. The salient point is, @emph{the errors are signaled then too}. Buffered writes defer error detection (and defer the side effects to the mutable store), perhaps indefinitely if the port type does not need to be closed at GC. One common heuristic that works well for textual ports is to flush output when a newline (@code{\n}) is written. This @dfn{line buffering} mode is on by default for TTY ports. Most other ports are @dfn{block buffered}, meaning that once the output buffer reaches the block size, which depends on the port and its configuration, the output is flushed as a block, without regard to what is in the block. Likewise reads are read in at the block size, though if there are fewer bytes available to read, the buffer may not be entirely filled. Note that binary reads or writes that are larger than the buffer size go directly to the mutable store without passing through the buffers. If your access pattern involves many big reads or writes, buffering might not matter so much to you. To control the buffering behavior of a port, use @code{setvbuf}. @deffn {Scheme Procedure} setvbuf port mode [size] @deffnx {C Function} scm_setvbuf (port, mode, size) @cindex port buffering Set the buffering mode for @var{port}. @var{mode} can be one of the following symbols: @table @code @item none non-buffered @item line line buffered @item block block buffered, using a newly allocated buffer of @var{size} bytes. If @var{size} is omitted, a default size will be used. @end table @end deffn Another way to set the buffering, for file ports, is to open the file with @code{0} or @code{l} as part of the mode string, for unbuffered or line-buffered ports, respectively. @xref{File Ports}, for more. Any buffered output data will be written out when the port is closed. To make sure to flush it at specific points in your program, use @code{force-output}. @findex fflush @deffn {Scheme Procedure} force-output [port] @deffnx {C Function} scm_force_output (port) Flush the specified output port, or the current output port if @var{port} is omitted. The current output buffer contents, if any, are passed to the underlying port implementation. The return value is unspecified. @end deffn @deffn {Scheme Procedure} flush-all-ports @deffnx {C Function} scm_flush_all_ports () Equivalent to calling @code{force-output} on all open output ports. The return value is unspecified. @end deffn Similarly, sometimes you might want to switch from using Guile's ports to working directly on file descriptors. In that case, for input ports use @code{drain-input} to get any buffered input from that port. @deffn {Scheme Procedure} drain-input port @deffnx {C Function} scm_drain_input (port) This procedure clears a port's input buffers, similar to the way that force-output clears the output buffer. The contents of the buffers are returned as a single string, e.g., @lisp (define p (open-input-file ...)) (drain-input p) => empty string, nothing buffered yet. (unread-char (read-char p) p) (drain-input p) => initial chars from p, up to the buffer size. @end lisp @end deffn All of these considerations are very similar to those of streams in the C library, although Guile's ports are not built on top of C streams. Still, it is useful to read what other systems do. @xref{Streams,,,libc,The GNU C Library Reference Manual}, for more discussion on C streams. @node Random Access @subsection Random Access @cindex Random access, ports @cindex Port, random access @deffn {Scheme Procedure} seek fd_port offset whence @deffnx {C Function} scm_seek (fd_port, offset, whence) Sets the current position of @var{fd_port} to the integer @var{offset}. For a file port, @var{offset} is expressed as a number of bytes; for other types of ports, such as string ports, @var{offset} is an abstract representation of the position within the port's data, not necessarily expressed as a number of bytes. @var{offset} is interpreted according to the value of @var{whence}. One of the following variables should be supplied for @var{whence}: @defvar SEEK_SET Seek from the beginning of the file. @end defvar @defvar SEEK_CUR Seek from the current position. @end defvar @defvar SEEK_END Seek from the end of the file. @end defvar On systems that support it, such as GNU/Linux, the following constants can be used for @var{whence} to navigate ``holes'' in sparse files: @defvar SEEK_DATA Seek to the next location in the file greater than or equal to @var{offset} containing data. If @var{offset} points to data, then the file offset is set to @var{offset}. @end defvar @defvar SEEK_HOLE Seek to the next hole in the file greater than or equal to the @var{offset}. If @var{offset} points into the middle of a hole, then the file offset is set to @var{offset}. If there is no hole past @var{offset}, then the file offset is adjusted to the end of the file---i.e., there is an implicit hole at the end of any file. @end defvar If @var{fd_port} is a file descriptor, the underlying system call is @code{lseek} (@pxref{File Position Primitive,,, libc, The GNU C Library Reference Manual}). @var{port} may be a string port. The value returned is the new position in @var{fd_port}. This means that the current position of a port can be obtained using: @lisp (seek port 0 SEEK_CUR) @end lisp @end deffn @deffn {Scheme Procedure} ftell fd_port @deffnx {C Function} scm_ftell (fd_port) Return an integer representing the current position of @var{fd_port}, measured from the beginning. Equivalent to: @lisp (seek port 0 SEEK_CUR) @end lisp @end deffn @findex truncate @findex ftruncate @deffn {Scheme Procedure} truncate-file file [length] @deffnx {C Function} scm_truncate_file (file, length) Truncate @var{file} to @var{length} bytes. @var{file} can be a filename string, a port object, or an integer file descriptor. The return value is unspecified. For a port or file descriptor @var{length} can be omitted, in which case the file is truncated at the current position (per @code{ftell} above). On most systems a file can be extended by giving a length greater than the current size, but this is not mandatory in the POSIX standard. @end deffn @node Line/Delimited @subsection Line Oriented and Delimited Text @cindex Line input/output @cindex Port, line input/output The delimited-I/O module can be accessed with: @lisp (use-modules (ice-9 rdelim)) @end lisp It can be used to read or write lines of text, or read text delimited by a specified set of characters. @deffn {Scheme Procedure} read-line [port] [handle-delim] Return a line of text from @var{port} if specified, otherwise from the value returned by @code{(current-input-port)}. Under Unix, a line of text is terminated by the first end-of-line character or by end-of-file. If @var{handle-delim} is specified, it should be one of the following symbols: @table @code @item trim Discard the terminating delimiter. This is the default, but it will be impossible to tell whether the read terminated with a delimiter or end-of-file. @item concat Append the terminating delimiter (if any) to the returned string. @item peek Push the terminating delimiter (if any) back on to the port. @item split Return a pair containing the string read from the port and the terminating delimiter or end-of-file object. @end table @end deffn @deffn {Scheme Procedure} read-line! buf [port] Read a line of text into the supplied string @var{buf} and return the number of characters added to @var{buf}. If @var{buf} is filled, then @code{#f} is returned. Read from @var{port} if specified, otherwise from the value returned by @code{(current-input-port)}. @end deffn @deffn {Scheme Procedure} read-delimited delims [port] [handle-delim] Read text until one of the characters in the string @var{delims} is found or end-of-file is reached. Read from @var{port} if supplied, otherwise from the value returned by @code{(current-input-port)}. @var{handle-delim} takes the same values as described for @code{read-line}. @end deffn @c begin (scm-doc-string "rdelim.scm" "read-delimited!") @deffn {Scheme Procedure} read-delimited! delims buf [port] [handle-delim] [start] [end] Read text into the supplied string @var{buf}. If a delimiter was found, return the number of characters written, except if @var{handle-delim} is @code{split}, in which case the return value is a pair, as noted above. As a special case, if @var{port} was already at end-of-stream, the EOF object is returned. Also, if no characters were written because the buffer was full, @code{#f} is returned. It's something of a wacky interface, to be honest. @end deffn @deffn {Scheme Procedure} %read-delimited! delims str gobble [port [start [end]]] @deffnx {C Function} scm_read_delimited_x (delims, str, gobble, port, start, end) Read characters from @var{port} into @var{str} until one of the characters in the @var{delims} string is encountered. If @var{gobble} is true, discard the delimiter character; otherwise, leave it in the input stream for the next read. If @var{port} is not specified, use the value of @code{(current-input-port)}. If @var{start} or @var{end} are specified, store data only into the substring of @var{str} bounded by @var{start} and @var{end} (which default to the beginning and end of the string, respectively). Return a pair consisting of the delimiter that terminated the string and the number of characters read. If reading stopped at the end of file, the delimiter returned is the @var{eof-object}; if the string was filled without encountering a delimiter, this value is @code{#f}. @end deffn @deffn {Scheme Procedure} %read-line [port] @deffnx {C Function} scm_read_line (port) Read a newline-terminated line from @var{port}, allocating storage as necessary. The newline terminator (if any) is removed from the string, and a pair consisting of the line and its delimiter is returned. The delimiter may be either a newline or the @var{eof-object}; if @code{%read-line} is called at the end of file, it returns the pair @code{(# . #)}. @end deffn @deffn {Scheme Procedure} write-line obj [port] @deffnx {C Function} scm_write_line (obj, port) Display @var{obj} and a newline character to @var{port}. If @var{port} is not specified, @code{(current-output-port)} is used. This procedure is equivalent to: @lisp (display obj [port]) (newline [port]) @end lisp @end deffn @node Default Ports @subsection Default Ports for Input, Output and Errors @cindex Default ports @cindex Port, default @rnindex current-input-port @deffn {Scheme Procedure} current-input-port @deffnx {C Function} scm_current_input_port () @cindex standard input Return the current input port. This is the default port used by many input procedures. Initially this is the @dfn{standard input} in Unix and C terminology. When the standard input is a TTY the port is unbuffered, otherwise it's fully buffered. Unbuffered input is good if an application runs an interactive subprocess, since any type-ahead input won't go into Guile's buffer and be unavailable to the subprocess. Note that Guile buffering is completely separate from the TTY ``line discipline''. In the usual cooked mode on a TTY Guile only sees a line of input once the user presses @key{Return}. @end deffn @rnindex current-output-port @deffn {Scheme Procedure} current-output-port @deffnx {C Function} scm_current_output_port () @cindex standard output Return the current output port. This is the default port used by many output procedures. Initially this is the @dfn{standard output} in Unix and C terminology. When the standard output is a TTY this port is unbuffered, otherwise it's fully buffered. Unbuffered output to a TTY is good for ensuring progress output or a prompt is seen. But an application which always prints whole lines could change to line buffered, or an application with a lot of output could go fully buffered and perhaps make explicit @code{force-output} calls (@pxref{Buffering}) at selected points. @end deffn @deffn {Scheme Procedure} current-error-port @deffnx {C Function} scm_current_error_port () @cindex standard error output Return the port to which errors and warnings should be sent. Initially this is the @dfn{standard error} in Unix and C terminology. When the standard error is a TTY this port is unbuffered, otherwise it's fully buffered. @end deffn @deffn {Scheme Procedure} set-current-input-port port @deffnx {Scheme Procedure} set-current-output-port port @deffnx {Scheme Procedure} set-current-error-port port @deffnx {C Function} scm_set_current_input_port (port) @deffnx {C Function} scm_set_current_output_port (port) @deffnx {C Function} scm_set_current_error_port (port) Change the ports returned by @code{current-input-port}, @code{current-output-port} and @code{current-error-port}, respectively, so that they use the supplied @var{port} for input or output. @end deffn @deffn {Scheme Procedure} with-input-from-port port thunk @deffnx {Scheme Procedure} with-output-to-port port thunk @deffnx {Scheme Procedure} with-error-to-port port thunk Call @var{thunk} in a dynamic environment in which @code{current-input-port}, @code{current-output-port} or @code{current-error-port} is rebound to the given @var{port}. @end deffn @deftypefn {C Function} void scm_dynwind_current_input_port (SCM port) @deftypefnx {C Function} void scm_dynwind_current_output_port (SCM port) @deftypefnx {C Function} void scm_dynwind_current_error_port (SCM port) These functions must be used inside a pair of calls to @code{scm_dynwind_begin} and @code{scm_dynwind_end} (@pxref{Dynamic Wind}). During the dynwind context, the indicated port is set to @var{port}. More precisely, the current port is swapped with a `backup' value whenever the dynwind context is entered or left. The backup value is initialized with the @var{port} argument. @end deftypefn @node Port Types @subsection Types of Port @cindex Types of ports @cindex Port, types @menu * File Ports:: Ports on an operating system file. * Bytevector Ports:: Ports on a bytevector. * String Ports:: Ports on a Scheme string. * Custom Ports:: Ports whose implementation you control. * Soft Ports:: A Guile-specific version of custom ports. * Void Ports:: Ports on nothing at all. * Low-Level Custom Ports:: Implementing new kinds of port. * Low-Level Custom Ports in C:: A C counterpart to make-custom-port. @end menu @node File Ports @subsubsection File Ports @cindex File port @cindex Port, file The following procedures are used to open file ports. See also @ref{Ports and File Descriptors, open}, for an interface to the Unix @code{open} system call. All file access uses the ``LFS'' large file support functions when available, so files bigger than 2 gibibytes (@math{2^31} bytes) can be read and written on a 32-bit system. Most systems have limits on how many files can be open, so it's strongly recommended that file ports be closed explicitly when no longer required (@pxref{Ports}). @deffn {Scheme Procedure} open-file filename mode @ [#:guess-encoding=#f] [#:encoding=#f] @deffnx {C Function} scm_open_file_with_encoding @ (filename, mode, guess_encoding, encoding) @deffnx {C Function} scm_open_file (filename, mode) Open the file whose name is @var{filename}, and return a port representing that file. The attributes of the port are determined by the @var{mode} string. The way in which this is interpreted is similar to C stdio. The first character must be one of the following: @table @samp @item r Open an existing file for input. @item w Open a file for output, creating it if it doesn't already exist or removing its contents if it does. @item a Open a file for output, creating it if it doesn't already exist. All writes to the port will go to the end of the file. The "append mode" can be turned off while the port is in use @pxref{Ports and File Descriptors, fcntl} @end table The following additional characters can be appended: @table @samp @item b Open the underlying file in binary mode, if supported by the system. Also, open the file using the binary-compatible character encoding "ISO-8859-1", ignoring the default port encoding. @item + Open the port for both input and output. E.g., @code{r+}: open an existing file for both input and output. @item e Mark the underlying file descriptor as close-on-exec, as per the @code{O_CLOEXEC} flag. @item 0 Create an "unbuffered" port. In this case input and output operations are passed directly to the underlying port implementation without additional buffering. This is likely to slow down I/O operations. The buffering mode can be changed while a port is in use (@pxref{Buffering}). @item l Add line-buffering to the port. The port output buffer will be automatically flushed whenever a newline character is written. @item b Use binary mode, ensuring that each byte in the file will be read as one Scheme character. To provide this property, the file will be opened with the 8-bit character encoding "ISO-8859-1", ignoring the default port encoding. @xref{Ports}, for more information on port encodings. Note that while it is possible to read and write binary data as characters or strings, it is usually better to treat bytes as octets, and byte sequences as bytevectors. @xref{Binary I/O}, for more. This option had another historical meaning, for DOS compatibility: in the default (textual) mode, DOS reads a CR-LF sequence as one LF byte. The @code{b} flag prevents this from happening, adding @code{O_BINARY} to the underlying @code{open} call. Still, the flag is generally useful because of its port encoding ramifications. @end table Unless binary mode is requested, the character encoding of the new port is determined as follows: First, if @var{guess-encoding} is true, the @code{file-encoding} procedure is used to guess the encoding of the file (@pxref{Character Encoding of Source Files}). If @var{guess-encoding} is false or if @code{file-encoding} fails, @var{encoding} is used unless it is also false. As a last resort, the default port encoding is used. @xref{Ports}, for more information on port encodings. It is an error to pass a non-false @var{guess-encoding} or @var{encoding} if binary mode is requested. If a file cannot be opened with the access requested, @code{open-file} throws an exception. @end deffn @rnindex open-input-file @deffn {Scheme Procedure} open-input-file filename @ [#:guess-encoding=#f] [#:encoding=#f] [#:binary=#f] Open @var{filename} for input. If @var{binary} is true, open the port in binary mode, otherwise use text mode. @var{encoding} and @var{guess-encoding} determine the character encoding as described above for @code{open-file}. Equivalent to @lisp (open-file @var{filename} (if @var{binary} "rb" "r") #:guess-encoding @var{guess-encoding} #:encoding @var{encoding}) @end lisp @end deffn @rnindex open-output-file @deffn {Scheme Procedure} open-output-file filename @ [#:encoding=#f] [#:binary=#f] Open @var{filename} for output. If @var{binary} is true, open the port in binary mode, otherwise use text mode. @var{encoding} specifies the character encoding as described above for @code{open-file}. Equivalent to @lisp (open-file @var{filename} (if @var{binary} "wb" "w") #:encoding @var{encoding}) @end lisp @end deffn @deffn {Scheme Procedure} call-with-input-file filename proc @ [#:guess-encoding=#f] [#:encoding=#f] [#:binary=#f] @deffnx {Scheme Procedure} call-with-output-file filename proc @ [#:encoding=#f] [#:binary=#f] @rnindex call-with-input-file @rnindex call-with-output-file Open @var{filename} for input or output, and call @code{(@var{proc} port)} with the resulting port. Return the value returned by @var{proc}. @var{filename} is opened as per @code{open-input-file} or @code{open-output-file} respectively, and an error is signaled if it cannot be opened. When @var{proc} returns, the port is closed. If @var{proc} does not return (e.g.@: if it throws an error), then the port might not be closed automatically, though it will be garbage collected in the usual way if not otherwise referenced. @end deffn @deffn {Scheme Procedure} with-input-from-file filename thunk @ [#:guess-encoding=#f] [#:encoding=#f] [#:binary=#f] @deffnx {Scheme Procedure} with-output-to-file filename thunk @ [#:encoding=#f] [#:binary=#f] @deffnx {Scheme Procedure} with-error-to-file filename thunk @ [#:encoding=#f] [#:binary=#f] @rnindex with-input-from-file @rnindex with-output-to-file Open @var{filename} and call @code{(@var{thunk})} with the new port setup as respectively the @code{current-input-port}, @code{current-output-port}, or @code{current-error-port}. Return the value returned by @var{thunk}. @var{filename} is opened as per @code{open-input-file} or @code{open-output-file} respectively, and an error is signaled if it cannot be opened. When @var{thunk} returns, the port is closed and the previous setting of the respective current port is restored. The current port setting is managed with @code{dynamic-wind}, so the previous value is restored no matter how @var{thunk} exits (eg.@: an exception), and if @var{thunk} is re-entered (via a captured continuation) then it's set again to the @var{filename} port. The port is closed when @var{thunk} returns normally, but not when exited via an exception or new continuation. This ensures it's still ready for use if @var{thunk} is re-entered by a captured continuation. Of course the port is always garbage collected and closed in the usual way when no longer referenced anywhere. @end deffn @deffn {Scheme Procedure} port-mode port @deffnx {C Function} scm_port_mode (port) Return the port modes associated with the open port @var{port}. These will not necessarily be identical to the modes used when the port was opened, since modes such as "append" which are used only during port creation are not retained. @end deffn @deffn {Scheme Procedure} port-filename port @deffnx {C Function} scm_port_filename (port) Return the filename associated with @var{port}, or @code{#f} if no filename is associated with the port. @var{port} must be open; @code{port-filename} cannot be used once the port is closed. @end deffn @deffn {Scheme Procedure} set-port-filename! port filename @deffnx {C Function} scm_set_port_filename_x (port, filename) Change the filename associated with @var{port}, using the current input port if none is specified. Note that this does not change the port's source of data, but only the value that is returned by @code{port-filename} and reported in diagnostic output. @end deffn @deffn {Scheme Procedure} file-port? obj @deffnx {C Function} scm_file_port_p (obj) Determine whether @var{obj} is a port that is related to a file. @end deffn @node Bytevector Ports @subsubsection Bytevector Ports @deffn {Scheme Procedure} open-bytevector-input-port bv [transcoder] @deffnx {C Function} scm_open_bytevector_input_port (bv, transcoder) Return an input port whose contents are drawn from bytevector @var{bv} (@pxref{Bytevectors}). @c FIXME: Update description when implemented. The @var{transcoder} argument is currently not supported. @end deffn @deffn {Scheme Procedure} open-bytevector-output-port [transcoder] @deffnx {C Function} scm_open_bytevector_output_port (transcoder) Return two values: a binary output port and a procedure. The latter should be called with zero arguments to obtain a bytevector containing the data accumulated by the port, as illustrated below. @lisp (call-with-values (lambda () (open-bytevector-output-port)) (lambda (port get-bytevector) (display "hello" port) (get-bytevector))) @result{} #vu8(104 101 108 108 111) @end lisp @c FIXME: Update description when implemented. The @var{transcoder} argument is currently not supported. @end deffn @deffn {Scheme Procedure} call-with-output-bytevector proc Call the one-argument procedure @var{proc} with a newly created bytevector output port. When the function returns, the bytevector composed of the characters written into the port is returned. @var{proc} should not close the port. @end deffn @deffn {Scheme Procedure} call-with-input-bytevector bytevector proc Call the one-argument procedure @var{proc} with a newly created input port from which @var{bytevector}'s contents may be read. The values yielded by the @var{proc} is returned. @end deffn @node String Ports @subsubsection String Ports @cindex String port @cindex Port, string @deffn {Scheme Procedure} call-with-output-string proc @deffnx {C Function} scm_call_with_output_string (proc) Calls the one-argument procedure @var{proc} with a newly created output port. When the function returns, the string composed of the characters written into the port is returned. @var{proc} should not close the port. @end deffn @deffn {Scheme Procedure} call-with-input-string string proc @deffnx {C Function} scm_call_with_input_string (string, proc) Calls the one-argument procedure @var{proc} with a newly created input port from which @var{string}'s contents may be read. The value yielded by the @var{proc} is returned. @end deffn @deffn {Scheme Procedure} with-output-to-string thunk Calls the zero-argument procedure @var{thunk} with the current output port set temporarily to a new string port. It returns a string composed of the characters written to the current output. @end deffn @deffn {Scheme Procedure} with-input-from-string string thunk Calls the zero-argument procedure @var{thunk} with the current input port set temporarily to a string port opened on the specified @var{string}. The value yielded by @var{thunk} is returned. @end deffn @deffn {Scheme Procedure} open-input-string str @deffnx {C Function} scm_open_input_string (str) Take a string and return an input port that delivers characters from the string. The port can be closed by @code{close-input-port}, though its storage will be reclaimed by the garbage collector if it becomes inaccessible. @end deffn @deffn {Scheme Procedure} open-output-string @deffnx {C Function} scm_open_output_string () Return an output port that will accumulate characters for retrieval by @code{get-output-string}. The port can be closed by the procedure @code{close-output-port}, though its storage will be reclaimed by the garbage collector if it becomes inaccessible. @end deffn @deffn {Scheme Procedure} get-output-string port @deffnx {C Function} scm_get_output_string (port) Given an output port created by @code{open-output-string}, return a string consisting of the characters that have been output to the port so far. @code{get-output-string} must be used before closing @var{port}, once closed the string cannot be obtained. @end deffn With string ports, the port-encoding is treated differently than other types of ports. When string ports are created, they do not inherit a character encoding from the current locale. They are given a default locale that allows them to handle all valid string characters. Typically one should not modify a string port's character encoding away from its default. @xref{Encoding}. @node Custom Ports @subsubsection Custom Ports Custom ports allow the user to provide input and handle output via user-supplied procedures. The most basic of these operates on the level of bytes, calling user-supplied functions to supply bytes for input and accept bytes for output. In Guile, textual ports are built on top of binary ports, encoding and decoding their codepoint sequences from the bytes; the higher-level textual layer for custom ports allows users to deal in characters instead of bytes. Before using these procedures, import the appropriate module: @example (use-modules (ice-9 binary-ports)) (use-modules (ice-9 textual-ports)) @end example @cindex custom binary input ports @deffn {Scheme Procedure} make-custom-binary-input-port id read! get-position set-position! close Return a new custom binary input port named @var{id} (a string) whose input is drained by invoking @var{read!} and passing it a bytevector, an index where bytes should be written, and the number of bytes to read. The @code{read!} procedure must return an integer indicating the number of bytes read, or @code{0} to indicate the end-of-file. Optionally, if @var{get-position} is not @code{#f}, it must be a thunk that will be called when @code{port-position} is invoked on the custom binary port and should return an integer indicating the position within the underlying data stream; if @var{get-position} was not supplied, the returned port does not support @code{port-position}. Likewise, if @var{set-position!} is not @code{#f}, it should be a one-argument procedure. When @code{set-port-position!} is invoked on the custom binary input port, @var{set-position!} is passed an integer indicating the position of the next byte is to read. Finally, if @var{close} is not @code{#f}, it must be a thunk. It is invoked when the custom binary input port is closed. The returned port is fully buffered by default, but its buffering mode can be changed using @code{setvbuf} (@pxref{Buffering}). Using a custom binary input port, the @code{open-bytevector-input-port} procedure (@pxref{Bytevector Ports}) could be implemented as follows: @lisp (define (open-bytevector-input-port source) (define position 0) (define length (bytevector-length source)) (define (read! bv start count) (let ((count (min count (- length position)))) (bytevector-copy! source position bv start count) (set! position (+ position count)) count)) (define (get-position) position) (define (set-position! new-position) (set! position new-position)) (make-custom-binary-input-port "the port" read! get-position set-position! #f)) (read (open-bytevector-input-port (string->utf8 "hello"))) @result{} hello @end lisp @end deffn @cindex custom binary output ports @deffn {Scheme Procedure} make-custom-binary-output-port id write! get-position set-position! close Return a new custom binary output port named @var{id} (a string) whose output is sunk by invoking @var{write!} and passing it a bytevector, an index where bytes should be read from this bytevector, and the number of bytes to be ``written''. The @code{write!} procedure must return an integer indicating the number of bytes actually written; when it is passed @code{0} as the number of bytes to write, it should behave as though an end-of-file was sent to the byte sink. The other arguments are as for @code{make-custom-binary-input-port}. @end deffn @cindex custom binary input/output ports @deffn {Scheme Procedure} make-custom-binary-input/output-port id read! write! get-position set-position! close Return a new custom binary input/output port named @var{id} (a string). The various arguments are the same as for The other arguments are as for @code{make-custom-binary-input-port} and @code{make-custom-binary-output-port}. If buffering is enabled on the port, as is the case by default, input will be buffered in both directions; @xref{Buffering}. If the @var{set-position!} function is provided and not @code{#f}, then the port will also be marked as random-access, causing the buffer to be flushed between reads and writes. @end deffn @cindex custom textual ports @cindex custom textual input ports @cindex custom textual output ports @cindex custom textual input/output ports @deffn {Scheme Procedure} make-custom-textual-input-port id read! get-position set-position! close @deffnx {Scheme Procedure} make-custom-textual-output-port id write! get-position set-position! close @deffnx {Scheme Procedure} make-custom-textual-input/output-port id read! write! get-position set-position! close Like their custom binary port counterparts, but for textual ports. Concretely this means that instead of being passed a bytevector, the @var{read} function is passed a mutable string to fill, and likewise for the buffer supplied to @var{write}. Port positions are still expressed in bytes, however. If string ports were not supplied with Guile, we could implement them With custom textual ports: @example (define (open-string-input-port source) (define position 0) (define length (string-length source)) (define (read! dst start count) (let ((count (min count (- length position)))) (string-copy! dst start source position (+ position count)) (set! position (+ position count)) count)) (make-custom-textual-input-port "strport" read! #f #f #f)) (read (open-string-input-port "hello")) @end example @end deffn @node Soft Ports @subsubsection Soft Ports @cindex Soft port @cindex Port, soft Soft ports are what Guile had before it had custom binary and textual ports, and allow for customizable textual input and output. We recommend soft ports over R6RS custom textual ports because they are easier to use while also being more expressive. R6RS custom textual ports operate under the principle that a port has a mutable string buffer, and this is reflected in the @code{read} and @code{write} procedures which take a buffer, offset, and length. However in Guile as all ports have a byte buffer rather than some having a string buffer, the R6RS interface imposes overhead and complexity. Additionally, and unlike the R6RS interfaces, @code{make-soft-port} from the @code{(ice-9 soft-ports)} module accepts keyword arguments, allowing for its functionality to be extended over time. If you find yourself needing more power, notably the ability to seek, probably you want to use low-level custom ports. @xref{Low-Level Custom Ports}. @example (use-modules (ice-9 soft-ports)) @end example @deffn {Scheme Procedure} make-soft-port @ [#:id] [#:read-string] [#:write-string] [#:input-waiting?] @ [#:close] [#:close-on-gc?] Return a new port. If the @var{read-string} keyword argument is present, the port will be an input port. If @var{write-string} is present, the port will be an output port. If both are supplied, the port will be open for input and output. When the port's internal buffers are empty, @var{read-string} will be called with no arguments, and should return a string, or @code{#f} to indicate end-of-stream. Similarly when a port flushes its write buffer, the characters in that buffer will be passed to the @var{write-string} procedure as its single argument. @var{write-string} returns unspecified values. If supplied, @var{input-waiting?} should return @code{#t} if the soft port has input which would be returned directly by @var{read-string}. If supplied, @var{close} will be called when the port is closed, with no arguments. If @var{close-on-gc?} is @code{#t}, @var{close} will additionally be called when the port becomes unreachable, after flushing any pending write buffers. @end deffn With soft ports, the @code{open-string-input-port} example from the previous section is more simple: @example (define (open-string-input-port source) (define already-read? #f) (define (read-string) (cond (already-read? "") (else (set! already-read? #t) source))) (make-soft-port #:id "strport" #:read-string read-string)) @end example Note that there was an earlier form of @code{make-soft-port} which was exposed in Guile's default environment, and which is still there. Its interface is more clumsy and its users historically expect unbuffered input. This interface will be deprecated, but we document it here. @deffn {Scheme Procedure} deprecated-make-soft-port pv modes Return a port capable of receiving or delivering characters as specified by the @var{modes} string (@pxref{File Ports, open-file}). @var{pv} must be a vector of length 5 or 6. Its components are as follows: @enumerate 0 @item procedure accepting one character for output @item procedure accepting a string for output @item thunk for flushing output @item thunk for getting one character @item thunk for closing port (not by garbage collection) @item (if present and not @code{#f}) thunk for computing the number of characters that can be read from the port without blocking. @end enumerate For an output-only port only elements 0, 1, 2, and 4 need be procedures. For an input-only port only elements 3 and 4 need be procedures. Thunks 2 and 4 can instead be @code{#f} if there is no useful operation for them to perform. If thunk 3 returns @code{#f} or an @code{eof-object} (@pxref{Input, eof-object?, ,r5rs, The Revised^5 Report on Scheme}) it indicates that the port has reached end-of-file. For example: @lisp (define stdout (current-output-port)) (define p (deprecated-make-soft-port (vector (lambda (c) (write c stdout)) (lambda (s) (display s stdout)) (lambda () (display "." stdout)) (lambda () (char-upcase (read-char))) (lambda () (display "@@" stdout))) "rw")) (write p p) @result{} # @end lisp @end deffn @node Void Ports @subsubsection Void Ports @cindex Void port @cindex Port, void This kind of port causes any data to be discarded when written to, and always returns the end-of-file object when read from. @deffn {Scheme Procedure} %make-void-port mode @deffnx {C Function} scm_sys_make_void_port (mode) Create and return a new void port. A void port acts like @file{/dev/null}. The @var{mode} argument specifies the input/output modes for this port: see the documentation for @code{open-file} in @ref{File Ports}. @end deffn @node Low-Level Custom Ports @subsubsection Low-Level Custom Ports This section describes how to implement a new kind of port using Guile's lowest-level, most primitive interfaces. First, load the @code{(ice-9 custom-ports)} module: @example (use-modules (ice-9 custom-ports)) @end example Then to make a new port, call @code{make-custom-port}: @deffn {Scheme Procedure} make-custom-port @ [#:read] [#:write] @ [#:read-wait-fd] [#:write-wait-fd] [#:input-waiting?] @ [#:seek] [#:random-access?] [#:get-natural-buffer-sizes] @ [#:id] [#:print] @ [#:close] [#:close-on-gc?] @ [#:truncate] @ [#:encoding] [#:conversion-strategy] Make a new custom port. @xref{Encoding}, for more on @code{#:encoding} and @code{#:conversion-strategy}. @end deffn A port has a number of associated procedures and properties which collectively implement its behavior. Creating a new custom port mostly involves writing these procedures, which are passed as keyword arguments to @code{make-custom-port}. @deffn {Scheme Port Method} #:read port dst start count A port's @code{#:read} implementation fills read buffers. It should copy bytes to the supplied bytevector @var{dst}, starting at offset @var{start} and continuing for @var{count} bytes, and return the number of bytes that were read, or @code{#f} to indicate that reading any bytes would block. @end deffn @deffn {Scheme Port Method} #:write port src start count A port's @code{#:write} implementation flushes write buffers to the mutable store. It should write out bytes from the supplied bytevector @var{src}, starting at offset @var{start} and continuing for @var{count} bytes, and return the number of bytes that were written, or @code{#f} to indicate writing any bytes would block. @end deffn If @code{make-custom-port} is passed a @code{#:read} argument, the port will be an input port. Passing a @code{#:write} argument will make an output port, and passing both will make an input-output port. @deffn {Scheme Port Method} #:read-wait-fd port @deffnx {Scheme Port Method} #:write-wait-fd port If a port's @code{#:read} or @code{#:write} method returns @code{#f}, that indicates that reading or writing would block, and that Guile should instead @code{poll} on the file descriptor returned by the port's @code{#:read-wait-fd} or @code{#:write-wait-fd} method, respectively, until the operation can complete. @xref{Non-Blocking I/O}, for a more in-depth discussion. These methods must be implemented if the @code{#:read} or @code{#:write} method can return @code{#f}, and should return a non-negative integer file descriptor. However they may be called explicitly by a user, for example to determine if a port may eventually be readable or writable. If there is no associated file descriptor with the port, they should return @code{#f}. The default implementation returns @code{#f}. @end deffn @deffn {Scheme Port Method} #:input-waiting? port In rare cases it is useful to be able to know whether data can be read from a port. For example, if the user inputs @code{1 2 3} at the interactive console, after reading and evaluating @code{1} the console shouldn't then print another prompt before reading and evaluating @code{2} because there is input already waiting. If the port can look ahead, then it should implement the @code{#:input-waiting?} method, which returns @code{#t} if input is available, or @code{#f} reading the next byte would block. The default implementation returns @code{#t}. @end deffn @deffn {Scheme Port Method} #:seek port offset whence Set or get the current byte position of the port. Guile will flush read and/or write buffers before seeking, as appropriate. The @var{offset} and @var{whence} parameters are as for the @code{seek} procedure; @xref{Random Access}. The @code{#:seek} method returns the byte position after seeking. To query the current position, @code{#:seek} will be called with an @var{offset} of 0 and @code{SEEK_CUR} for @var{whence}. Other values of @var{offset} and/or @var{whence} will actually perform the seek. The @code{#:seek} method should throw an error if the port is not seekable, which is what the default implementation does. @end deffn @deffn {Scheme Port Method} #:truncate port Truncate the port data to be specified length. Guile will flush buffers beforehand, as appropriate. The default implementation throws an error, indicating that truncation is not supported for this port. @end deffn @deffn {Scheme Port Method} #:random-access? port Return @code{#t} if @var{port} is open for random access, or @code{#f} otherwise. @cindex random access Seeking on a random-access port with buffered input, or switching to writing after reading, will cause the buffered input to be discarded and Guile will seek the port back the buffered number of bytes. Likewise seeking on a random-access port with buffered output, or switching to reading after writing, will flush pending bytes with a call to the @code{write} procedure. @xref{Buffering}. Indicate to Guile that your port needs this behavior by returning true from your @code{#:random-access?} method. The default implementation of this function returns @code{#t} if the port has a @code{#:seek} implementation. @end deffn @deffn {Scheme Port Method} #:get-natural-buffer-sizes read-buf-size write-buf-size Guile will internally attach buffers to ports. An input port always has a read buffer, and an output port always has a write buffer. @xref{Buffering}. A port buffer consists of a bytevector, along with some cursors into that bytevector denoting where to get and put data. Port implementations generally don't have to be concerned with buffering: a port's @code{#:read} or @code{#:write} method will receive the buffer's bytevector as an argument, along with an offset and a length into that bytevector, and should then either fill or empty that bytevector. However in some cases, port implementations may be able to provide an appropriate default buffer size to Guile. For example file ports implement @code{#:get-natural-buffer-sizes} to let the operating system inform Guile about the appropriate buffer sizes for the particular file opened by the port. This method returns two values, corresponding to the natural read and write buffer sizes for the ports. The two parameters @var{read-buf-size} and @var{write-buf-size} are Guile's guesses for what sizes might be good. A custom @code{#:get-natural-buffer-sizes} method could override Guile's choices, or just pass them on, as the default implementation does. @end deffn @deffn {Scheme Port Method} #:print port out Called when the port @var{port} is written to @var{out}, e.g. via @code{(write port out)}. If @code{#:print} is not explicitly supplied, the default implementation prints something like @code{#<@var{mode}:@var{id} @var{address}>}, where @var{mode} is either @code{input}, @code{output}, or @code{input-output}, @var{id} comes from the @code{#:id} keyword argument (defaulting to @code{"custom-port"}), and @var{address} is a unique integer associated with the port. @end deffn @deffn {Scheme Port Method} #:close port Called when @var{port} is closed. It should release any explicitly-managed resources used by the port. @end deffn By default, ports that are garbage collected just go away without closing or flushing any buffered output. If your port needs to release some external resource like a file descriptor, or needs to make sure that its internal buffers are flushed even if the port is collected while it was open, then pass @code{#:close-on-gc? #t} to @code{make-custom-port}. Note that in that case, the @code{#:close} method will probably be called on a separate thread. Note that calls to all of these methods can proceed in parallel and concurrently and from any thread up until the point that the port is closed. The call to @code{close} will happen when no other method is running, and no method will be called after the @code{close} method is called. If your port implementation needs mutual exclusion to prevent concurrency, it is responsible for locking appropriately. @node Low-Level Custom Ports in C @subsubsection Low-Level Custom Ports in C The @code{make-custom-port} procedure described in the previous section has similar functionality on the C level, though it is organized a bit differently. In C, the mechanism is that one creates a new @dfn{port type object}. The methods are then associated with the port type object instead of the port itself. The port type object is an opaque pointer allocated when defining the port type, which serves as a key into the port API. Ports themselves have associated @dfn{stream} values. The stream is a pointer controlled by the user, which is set when the port is created. Given a port, the @code{SCM_STREAM} macro returns its associated stream value, as a @code{scm_t_bits}. Note that your port methods are only ever called with ports of your type, so port methods can safely cast this value to the expected type. Contrast this to Scheme, which doesn't need access to the stream because the @code{make-custom-port} methods can be closures that share port-specific data directly. A port type is created by calling @code{scm_make_port_type}. @deftypefun scm_t_port_type* scm_make_port_type (char *name, size_t (*read) (SCM port, SCM dst, size_t start, size_t count), size_t (*write) (SCM port, SCM src, size_t start, size_t count)) Define a new port type. The @var{name} parameter is like the @code{#:id} parameter to @code{make-custom-port}; and @var{read} and @var{write} are like @code{make-custom-port}'s @code{#:read} and @code{#:write}, except that they should return @code{(size_t)-1} if the read or write operation would block, instead of @code{#f}. @end deftypefun @deftypefun void scm_set_port_read_wait_fd (scm_t_port_type *type, int (*wait_fd) (SCM port)) @deftypefunx void scm_set_port_write_wait_fd (scm_t_port_type *type, int (*wait_fd) (SCM port)) @deftypefunx void scm_set_port_print (scm_t_port_type *type, int (*print) (SCM port, SCM dest_port, scm_print_state *pstate)) @deftypefunx void scm_set_port_close (scm_t_port_type *type, void (*close) (SCM port)) @deftypefunx void scm_set_port_needs_close_on_gc (scm_t_port_type *type, int needs_close_p) @deftypefunx void scm_set_port_seek (scm_t_port_type *type, scm_t_off (*seek) (SCM port, scm_t_off offset, int whence)) @deftypefunx void scm_set_port_truncate (scm_t_port_type *type, void (*truncate) (SCM port, scm_t_off length)) @deftypefunx void scm_set_port_random_access_p (scm_t_port_type *type, int (*random_access_p) (SCM port)); @deftypefunx void scm_set_port_input_waiting (scm_t_port_type *type, int (*input_waiting) (SCM port)); @deftypefunx void scm_set_port_get_natural_buffer_sizes @ (scm_t_port_type *type, void (*get_natural_buffer_sizes) (SCM, size_t *read_buf_size, size_t *write_buf_size)) Port method definitions. @xref{Low-Level Custom Ports}, for more details on each of these methods. @end deftypefun Once you have your port type, you can create ports with @code{scm_c_make_port}, or @code{scm_c_make_port_with_encoding}. @deftypefun SCM scm_c_make_port_with_encoding (scm_t_port_type *type, unsigned long mode_bits, SCM encoding, SCM conversion_strategy, scm_t_bits stream) @deftypefunx SCM scm_c_make_port (scm_t_port_type *type, unsigned long mode_bits, scm_t_bits stream) Make a port with the given @var{type}. The @var{stream} indicates the private data associated with the port, which your port implementation may later retrieve with @code{SCM_STREAM}. The mode bits should include one or more of the flags @code{SCM_RDNG} or @code{SCM_WRTNG}, indicating that the port is an input and/or an output port, respectively. The mode bits may also include @code{SCM_BUF0} or @code{SCM_BUFLINE}, indicating that the port should be unbuffered or line-buffered, respectively. The default is that the port will be block-buffered. @xref{Buffering}. As you would imagine, @var{encoding} and @var{conversion_strategy} specify the port's initial textual encoding and conversion strategy. Both are symbols. @code{scm_c_make_port} is the same as @code{scm_c_make_port_with_encoding}, except it uses the default port encoding and conversion strategy. @end deftypefun At this point you may be wondering whether to implement your custom port type in C or Scheme. The answer is that probably you want to use Scheme's @code{make-custom-port}. The speed is similar between C and Scheme, and ports implemented in C have the disadvantage of not being suspendable. @xref{Non-Blocking I/O}. @node Venerable Port Interfaces @subsection Venerable Port Interfaces Over the 25 years or so that Guile has been around, its port system has evolved, adding many useful features. At the same time there have been four major Scheme standards released in those 25 years, which also evolve the common Scheme understanding of what a port interface should be. Alas, it would be too much to ask for all of these evolutionary branches to be consistent. Some of Guile's original interfaces don't mesh with the later Scheme standards, and yet Guile can't just drop old interfaces. Sadly as well, the R6RS and R7RS standards both part from a base of R5RS, but end up in different and somewhat incompatible designs. Guile's approach is to pick a set of port primitives that make sense together. We document that set of primitives, design our internal interfaces around them, and recommend them to users. As the R6RS I/O system is the most capable standard that Scheme has yet produced in this domain, we mostly recommend that; @code{(ice-9 binary-ports)} and @code{(ice-9 textual-ports)} are wholly modeled on @code{(rnrs io ports)}. Guile does not wholly copy R6RS, however; @xref{R6RS Incompatibilities}. At the same time, we have many venerable port interfaces, lore handed down to us from our hacker ancestors. Most of these interfaces even predate the expectation that Scheme should have modules, so they are present in the default environment. In Guile we support them as well and we have no plans to remove them, but again we don't recommend them for new users. @rnindex char-ready? @deffn {Scheme Procedure} char-ready? [port] Return @code{#t} if a character is ready on input @var{port} and return @code{#f} otherwise. If @code{char-ready?} returns @code{#t} then the next @code{read-char} operation on @var{port} is guaranteed not to hang. If @var{port} is a file port at end of file then @code{char-ready?} returns @code{#t}. @code{char-ready?} exists to make it possible for a program to accept characters from interactive ports without getting stuck waiting for input. Any input editors associated with such ports must make sure that characters whose existence has been asserted by @code{char-ready?} cannot be rubbed out. If @code{char-ready?} were to return @code{#f} at end of file, a port at end of file would be indistinguishable from an interactive port that has no ready characters. Note that @code{char-ready?} only works reliably for terminals and sockets with one-byte encodings. Under the hood it will return @code{#t} if the port has any input buffered, or if the file descriptor that backs the port polls as readable, indicating that Guile can fetch more bytes from the kernel. However being able to fetch one byte doesn't mean that a full character is available; @xref{Encoding}. Also, on many systems it's possible for a file descriptor to poll as readable, but then block when it comes time to read bytes. Note also that on Linux kernels, all file ports backed by files always poll as readable. For non-file ports, this procedure always returns @code{#t}, except for soft ports, which have a @code{char-ready?} handler. @xref{Soft Ports}. In short, this is a legacy procedure whose semantics are hard to provide. However it is a useful check to see if any input is buffered. @xref{Non-Blocking I/O}. @end deffn @rnindex read-char @deffn {Scheme Procedure} read-char [port] The same as @code{get-char}, except that @var{port} defaults to the current input port. @xref{Textual I/O}. @end deffn @rnindex peek-char @deffn {Scheme Procedure} peek-char [port] The same as @code{lookahead-char}, except that @var{port} defaults to the current input port. @xref{Textual I/O}. @end deffn @deffn {Scheme Procedure} unread-char cobj [port] The same as @code{unget-char}, except that @var{port} defaults to the current input port, and the arguments are swapped. @xref{Textual I/O}. @end deffn @deffn {Scheme Procedure} unread-string str [port] @deffnx {C Function} scm_unread_string (str, port) The same as @code{unget-string}, except that @var{port} defaults to the current input port, and the arguments are swapped. @xref{Textual I/O}. @end deffn @rnindex newline @deffn {Scheme Procedure} newline [port] Send a newline to @var{port}. If @var{port} is omitted, send to the current output port. Equivalent to @code{(put-char port #\newline)}. @end deffn @rnindex write-char @deffn {Scheme Procedure} write-char chr [port] The same as @code{put-char}, except that @var{port} defaults to the current input port, and the arguments are swapped. @xref{Textual I/O}. @end deffn @node Using Ports from C @subsection Using Ports from C Guile's C interfaces provides some niceties for sending and receiving bytes and characters in a way that works better with C. @deftypefn {C Function} size_t scm_c_read (SCM port, void *buffer, size_t size) Read up to @var{size} bytes from @var{port} and store them in @var{buffer}. The return value is the number of bytes actually read, which can be less than @var{size} if end-of-file has been reached. Note that as this is a binary input procedure, this function does not update @code{port-line} and @code{port-column} (@pxref{Textual I/O}). @end deftypefn @deftypefn {C Function} void scm_c_write (SCM port, const void *buffer, size_t size) Write @var{size} bytes at @var{buffer} to @var{port}. Note that as this is a binary output procedure, this function does not update @code{port-line} and @code{port-column} (@pxref{Textual I/O}). @end deftypefn @deftypefn {C Function} size_t scm_c_read_bytes (SCM port, SCM bv, size_t start, size_t count) @deftypefnx {C Function} void scm_c_write_bytes (SCM port, SCM bv, size_t start, size_t count) Like @code{scm_c_read} and @code{scm_c_write}, but reading into or writing from the bytevector @var{bv}. @var{count} indicates the byte index at which to start in the bytevector, and the read or write will continue for @var{count} bytes. @end deftypefn @deftypefn {C Function} void scm_unget_bytes (const unsigned char *buf, size_t len, SCM port) @deftypefnx {C Function} void scm_unget_byte (int c, SCM port) @deftypefnx {C Function} void scm_ungetc (scm_t_wchar c, SCM port) Like @code{unget-bytevector}, @code{unget-byte}, and @code{unget-char}, respectively. @xref{Textual I/O}. @end deftypefn @deftypefn {C Function} void scm_c_put_latin1_chars (SCM port, const scm_t_uint8 *buf, size_t len) @deftypefnx {C Function} void scm_c_put_utf32_chars (SCM port, const scm_t_uint32 *buf, size_t len); Write a string to @var{port}. In the first case, the @code{scm_t_uint8*} buffer is a string in the latin-1 encoding. In the second, the @code{scm_t_uint32*} buffer is a string in the UTF-32 encoding. These routines will update the port's line and column. @end deftypefn @node Non-Blocking I/O @subsection Non-Blocking I/O Most ports in Guile are @dfn{blocking}: when you try to read a character from a port, Guile will block on the read until a character is ready, or end-of-stream is detected. Likewise whenever Guile goes to write (possibly buffered) data to an output port, Guile will block until all the data is written. Interacting with ports in blocking mode is very convenient: you can write straightforward, sequential algorithms whose code flow reflects the flow of data. However, blocking I/O has two main limitations. The first is that it's easy to get into a situation where code is waiting on data. Time spent waiting on data when code could be doing something else is wasteful and prevents your program from reaching its peak throughput. If you implement a web server that sequentially handles requests from clients, it's very easy for the server to end up waiting on a client to finish its HTTP request, or waiting on it to consume the response. The end result is that you are able to serve fewer requests per second than you'd like to serve. The second limitation is related: a blocking parser over user-controlled input is a denial-of-service vulnerability. Indeed the so-called ``slow loris'' attack of the early 2010s was just that: an attack on common web servers that drip-fed HTTP requests, one character at a time. All it took was a handful of slow loris connections to occupy an entire web server. In Guile we would like to preserve the ability to write straightforward blocking networking processes of all kinds, but under the hood to allow those processes to suspend their requests if they would block. To do this, the first piece is to allow Guile ports to declare themselves as being nonblocking. This is currently supported only for file ports, which also includes sockets, terminals, or any other port that is backed by a file descriptor. To do that, we use an arcane UNIX incantation: @example (let ((flags (fcntl socket F_GETFL))) (fcntl socket F_SETFL (logior O_NONBLOCK flags))) @end example Now the file descriptor is open in non-blocking mode. If Guile tries to read or write from this file and the read or write returns a result indicating that more data can only be had by doing a blocking read or write, Guile will block by polling on the socket's @code{read-wait-fd} or @code{write-wait-fd}, to preserve the illusion of a blocking read or write. @xref{Low-Level Custom Ports} for more on those internal interfaces. So far we have just reproduced the status quo: the file descriptor is non-blocking, but the operations on the port do block. To go farther, it would be nice if we could suspend the ``thread'' using delimited continuations, and only resume the thread once the file descriptor is readable or writable. (@xref{Prompts}). But here we run into a difficulty. The ports code is implemented in C, which means that although we can suspend the computation to some outer prompt, we can't resume it because Guile can't resume delimited continuations that capture the C stack. To overcome this difficulty we have created a compatible but entirely parallel implementation of port operations. To use this implementation, do the following: @example (use-modules (ice-9 suspendable-ports)) (install-suspendable-ports!) @end example This will replace the core I/O primitives like @code{get-char} and @code{put-bytevector} with new versions that are exactly the same as the ones in the standard library, but with two differences. One is that when a read or a write would block, the suspendable port operations call out the value of the @code{current-read-waiter} or @code{current-write-waiter} parameter, as appropriate. @xref{Parameters}. The default read and write waiters do the same thing that the C read and write waiters do, which is to poll. User code can parameterize the waiters, though, enabling the computation to suspend and allow the program to process other I/O operations. Because the new suspendable ports implementation is written in Scheme, that suspended computation can resume again later when it is able to make progress. Success! The other main difference is that because the new ports implementation is written in Scheme, it is slower than C, currently by a factor of 3 or 4, though it depends on many factors. For this reason we have to keep the C implementations as the default ones. One day when Guile's compiler is better, we can close this gap and have only one port operation implementation again. Note that Guile does not currently include an implementation of the facility to suspend the current thread and schedule other threads in the meantime. Before adding such a thing, we want to make sure that we're providing the right primitives that can be used to build schedulers and other user-space concurrency patterns, and that the patterns that we settle on are the right patterns. In the meantime, have a look at 8sync (@url{https://gnu.org/software/8sync}) for a prototype of an asynchronous I/O and concurrency facility. @deffn {Scheme Procedure} install-suspendable-ports! Replace the core ports implementation with suspendable ports, as described above. This will mutate the values of the bindings like @code{get-char}, @code{put-u8}, and so on in place. @end deffn @deffn {Scheme Procedure} uninstall-suspendable-ports! Restore the original core ports implementation, un-doing the effect of @code{install-suspendable-ports!}. @end deffn @deffn {Scheme Parameter} current-read-waiter @deffnx {Scheme Parameter} current-write-waiter Parameters whose values are procedures of one argument, called when a suspendable port operation would block on a port while reading or writing, respectively. The default values of these parameters do a blocking @code{poll} on the port's file descriptor. The procedures are passed the port in question as their one argument. @end deffn @node BOM Handling @subsection Handling of Unicode Byte Order Marks @cindex BOM @cindex byte order mark This section documents the finer points of Guile's handling of Unicode byte order marks (BOMs). A byte order mark (U+FEFF) is typically found at the start of a UTF-16 or UTF-32 stream, to allow readers to reliably determine the byte order. Occasionally, a BOM is found at the start of a UTF-8 stream, but this is much less common and not generally recommended. Guile attempts to handle BOMs automatically, and in accordance with the recommendations of the Unicode Standard, when the port encoding is set to @code{UTF-8}, @code{UTF-16}, or @code{UTF-32}. In brief, Guile automatically writes a BOM at the start of a UTF-16 or UTF-32 stream, and automatically consumes one from the start of a UTF-8, UTF-16, or UTF-32 stream. As specified in the Unicode Standard, a BOM is only handled specially at the start of a stream, and only if the port encoding is set to @code{UTF-8}, @code{UTF-16} or @code{UTF-32}. If the port encoding is set to @code{UTF-16BE}, @code{UTF-16LE}, @code{UTF-32BE}, or @code{UTF-32LE}, then BOMs are @emph{not} handled specially, and none of the special handling described in this section applies. @itemize @bullet @item To ensure that Guile will properly detect the byte order of a UTF-16 or UTF-32 stream, you must perform a textual read before any writes, seeks, or binary I/O. Guile will not attempt to read a BOM unless a read is explicitly requested at the start of the stream. @item If a textual write is performed before the first read, then an arbitrary byte order will be chosen. Currently, big endian is the default on all platforms, but that may change in the future. If you wish to explicitly control the byte order of an output stream, set the port encoding to @code{UTF-16BE}, @code{UTF-16LE}, @code{UTF-32BE}, or @code{UTF-32LE}, and explicitly write a BOM (@code{#\xFEFF}) if desired. @item If @code{set-port-encoding!} is called in the middle of a stream, Guile treats this as a new logical ``start of stream'' for purposes of BOM handling, and will forget about any BOMs that had previously been seen. Therefore, it may choose a different byte order than had been used previously. This is intended to support multiple logical text streams embedded within a larger binary stream. @item Binary I/O operations are not guaranteed to update Guile's notion of whether the port is at the ``start of the stream'', nor are they guaranteed to produce or consume BOMs. @item For ports that support seeking (e.g. normal files), the input and output streams are considered linked: if the user reads first, then a BOM will be consumed (if appropriate), but later writes will @emph{not} produce a BOM. Similarly, if the user writes first, then later reads will @emph{not} consume a BOM. @item For ports that are not random access (e.g. pipes, sockets, and terminals), the input and output streams are considered @emph{independent} for purposes of BOM handling: the first read will consume a BOM (if appropriate), and the first write will @emph{also} produce a BOM (if appropriate). However, the input and output streams will always use the same byte order. @item Seeks to the beginning of a file will set the ``start of stream'' flags. Therefore, a subsequent textual read or write will consume or produce a BOM. However, unlike @code{set-port-encoding!}, if a byte order had already been chosen for the port, it will remain in effect after a seek, and cannot be changed by the presence of a BOM. Seeks anywhere other than the beginning of a file clear the ``start of stream'' flags. @end itemize @c Local Variables: @c TeX-master: "guile.texi" @c End: