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	@c --texinfo--
	@c This is part of the GNU Guile Reference Manual.
	@c Copyright (C) 1996, 1997, 2000, 2001, 2002, 2003, 2004, 2005, 2006, 2009,
	@c 2010, 2011, 2012, 2013, 2014, 2020, 2021 Free Software Foundation, Inc.
	@c See the file guile.texi for copying conditions.

	@node Read/Load/Eval/Compile
	@section Reading and Evaluating Scheme Code

	This chapter describes Guile functions that are concerned with reading,
	loading, evaluating, and compiling Scheme code at run time.

	@menu
	* Scheme Syntax:: Standard and extended Scheme syntax.
	* Scheme Read:: Reading Scheme code.
	* Annotated Scheme Read:: Reading Scheme code, for the compiler.
	* Scheme Write:: Writing Scheme values to a port.
	* Fly Evaluation:: Procedures for on the fly evaluation.
	* Compilation:: How to compile Scheme files and procedures.
	* Loading:: Loading Scheme code from file.
	* Load Paths:: Where Guile looks for code.
	* Character Encoding of Source Files:: Loading non-ASCII Scheme code from file.
	* Delayed Evaluation:: Postponing evaluation until it is needed.
	* Local Evaluation:: Evaluation in a local lexical environment.
	* Local Inclusion:: Compile-time inclusion of one file in another.
	* Sandboxed Evaluation:: Evaluation with limited capabilities.
	* REPL Servers:: Serving a REPL over a socket.
	* Cooperative REPL Servers:: REPL server for single-threaded applications.
	@end menu


	@node Scheme Syntax
	@subsection Scheme Syntax: Standard and Guile Extensions

	@menu
	* Expression Syntax::
	* Comments::
	* Block Comments::
	* Case Sensitivity::
	* Keyword Syntax::
	* Reader Extensions::
	@end menu


	@node Expression Syntax
	@subsubsection Expression Syntax

	An expression to be evaluated takes one of the following forms.

	@table @nicode

	@item @var{symbol}
	A symbol is evaluated by dereferencing. A binding of that symbol is
	sought and the value there used. For example,

	@example
	(define x 123)
	x @result{} 123
	@end example

	@item (@var{proc} @var{args}@dots{})
	A parenthesized expression is a function call. @var{proc} and each
	argument are evaluated, then the function (which @var{proc} evaluated
	to) is called with those arguments.

	The order in which @var{proc} and the arguments are evaluated is
	unspecified, so be careful when using expressions with side effects.

	@example
	(max 1 2 3) @result{} 3

	(define (get-some-proc) min)
	((get-some-proc) 1 2 3) @result{} 1
	@end example

	The same sort of parenthesized form is used for a macro invocation,
	but in that case the arguments are not evaluated. See the
	descriptions of macros for more on this (@pxref{Macros}, and
	@pxref{Syntax Rules}).

	@item @var{constant}
	Number, string, character and boolean constants evaluate ``to
	themselves'', so can appear as literals.

	@example
	123 @result{} 123
	99.9 @result{} 99.9
	"hello" @result{} "hello"
	#\z @result{} #\z
	#t @result{} #t
	@end example

	Note that an application must not attempt to modify literal strings,
	since they may be in read-only memory.

	@item (quote @var{data})
	@itemx '@var{data}
	@findex quote
	@findex '
	Quoting is used to obtain a literal symbol (instead of a variable
	reference), a literal list (instead of a function call), or a literal
	vector. @nicode{'} is simply a shorthand for a @code{quote} form.
	For example,

	@example
	'x @result{} x
	'(1 2 3) @result{} (1 2 3)
	'#(1 (2 3) 4) @result{} #(1 (2 3) 4)
	(quote x) @result{} x
	(quote (1 2 3)) @result{} (1 2 3)
	(quote #(1 (2 3) 4)) @result{} #(1 (2 3) 4)
	@end example

	Note that an application must not attempt to modify literal lists or
	vectors obtained from a @code{quote} form, since they may be in
	read-only memory.

	@item (quasiquote @var{data})
	@itemx `@var{data}
	@findex quasiquote
	@findex `
	Backquote quasi-quotation is like @code{quote}, but selected
	sub-expressions are evaluated. This is a convenient way to construct
	a list or vector structure most of which is constant, but at certain
	points should have expressions substituted.

	The same effect can always be had with suitable @code{list},
	@code{cons} or @code{vector} calls, but quasi-quoting is often easier.

	@table @nicode

	@item (unquote @var{expr})
	@itemx ,@var{expr}
	@findex unquote
	@findex ,
	Within the quasiquote @var{data}, @code{unquote} or @code{,} indicates
	an expression to be evaluated and inserted. The comma syntax @code{,}
	is simply a shorthand for an @code{unquote} form. For example,

	@example
	`(1 2 (* 9 9) 3 4) @result{} (1 2 (* 9 9) 3 4)
	`(1 2 ,(* 9 9) 3 4) @result{} (1 2 81 3 4)
	`(1 (unquote (+ 1 1)) 3) @result{} (1 2 3)
	`#(1 ,(/ 12 2)) @result{} #(1 6)
	@end example

	@item (unquote-splicing @var{expr})
	@itemx ,@@@var{expr}
	@findex unquote-splicing
	@findex ,@@
	Within the quasiquote @var{data}, @code{unquote-splicing} or
	@code{,@@} indicates an expression to be evaluated and the elements of
	the returned list inserted. @var{expr} must evaluate to a list. The
	``comma-at'' syntax @code{,@@} is simply a shorthand for an
	@code{unquote-splicing} form.

	@example
	(define x '(2 3))
	`(1 ,x 4) @result{} (1 (2 3) 4)
	`(1 ,@@x 4) @result{} (1 2 3 4)
	`(1 (unquote-splicing (map 1+ x))) @result{} (1 3 4)
	`#(9 ,@@x 9) @result{} #(9 2 3 9)
	@end example

	Notice @code{,@@} differs from plain @code{,} in the way one level of
	nesting is stripped. For @code{,@@} the elements of a returned list
	are inserted, whereas with @code{,} it would be the list itself
	inserted.
	@end table

	@c
	@c FIXME: What can we say about the mutability of a quasiquote
	@c result? R5RS doesn't seem to specify anything, though where it
	@c says backquote without commas is the same as plain quote then
	@c presumably the "fixed" portions of a quasiquote expression must be
	@c treated as immutable.
	@c

	@end table


	@node Comments
	@subsubsection Comments

	@c FIXME::martin: Review me!

	Comments in Scheme source files are written by starting them with a
	semicolon character (@code{;}). The comment then reaches up to the end
	of the line. Comments can begin at any column, and the may be inserted
	on the same line as Scheme code.

	@lisp
	; Comment
	;; Comment too
	(define x 1) ; Comment after expression
	(let ((y 1))
	;; Display something.
	(display y)
	;;; Comment at left margin.
	(display (+ y 1)))
	@end lisp

	It is common to use a single semicolon for comments following
	expressions on a line, to use two semicolons for comments which are
	indented like code, and three semicolons for comments which start at
	column 0, even if they are inside an indented code block. This
	convention is used when indenting code in Emacs' Scheme mode.


	@node Block Comments
	@subsubsection Block Comments
	@cindex multiline comments
	@cindex block comments
	@cindex #!
	@cindex !#

	@c FIXME::martin: Review me!

	In addition to the standard line comments defined by R5RS, Guile has
	another comment type for multiline comments, called @dfn{block
	comments}. This type of comment begins with the character sequence
	@code{#!} and ends with the characters @code{!#}.

	These comments are compatible with the block
	comments in the Scheme Shell @file{scsh} (@pxref{The Scheme shell
	(scsh)}). The characters @code{#!} were chosen because they are the
	magic characters used in shell scripts for indicating that the name of
	the program for executing the script follows on the same line.

	Thus a Guile script often starts like this.

	@lisp
	#! /usr/local/bin/guile -s
	!#
	@end lisp

	More details on Guile scripting can be found in the scripting section
	(@pxref{Guile Scripting}).

	@cindex R6RS block comments
	@cindex SRFI-30 block comments
	Similarly, Guile (starting from version 2.0) supports nested block
	comments as specified by R6RS and
	@url{http://srfi.schemers.org/srfi-30/srfi-30.html, SRFI-30}:

	@lisp
	(+ 1 #\| this is a #\| nested \|# block comment \|# 2)
	@result{} 3
	@end lisp

	For backward compatibility, this syntax can be overridden with
	@code{read-hash-extend} (@pxref{Reader Extensions,
	@code{read-hash-extend}}).

	There is one special case where the contents of a comment can actually
	affect the interpretation of code. When a character encoding
	declaration, such as @code{coding: utf-8} appears in one of the first
	few lines of a source file, it indicates to Guile's default reader
	that this source code file is not ASCII. For details see @ref{Character
	Encoding of Source Files}.

	@node Case Sensitivity
	@subsubsection Case Sensitivity
	@cindex fold-case
	@cindex no-fold-case

	@c FIXME::martin: Review me!

	Scheme as defined in R5RS is not case sensitive when reading symbols.
	Guile, on the contrary is case sensitive by default, so the identifiers

	@lisp
	guile-whuzzy
	Guile-Whuzzy
	@end lisp

	are the same in R5RS Scheme, but are different in Guile.

	It is possible to turn off case sensitivity in Guile by setting the
	reader option @code{case-insensitive}. For more information on reader
	options, @xref{Scheme Read}.

	@lisp
	(read-enable 'case-insensitive)
	@end lisp

	It is also possible to disable (or enable) case sensitivity within a
	single file by placing the reader directives @code{#!fold-case} (or
	@code{#!no-fold-case}) within the file itself.

	@node Keyword Syntax
	@subsubsection Keyword Syntax


	@node Reader Extensions
	@subsubsection Reader Extensions

	@deffn {Scheme Procedure} read-hash-extend chr proc
	@deffnx {C Function} scm_read_hash_extend (chr, proc)
	Install the procedure @var{proc} for reading expressions
	starting with the character sequence @code{#} and @var{chr}.
	@var{proc} will be called with two arguments: the character
	@var{chr} and the port to read further data from. The object
	returned will be the return value of @code{read}.
	Passing @code{#f} for @var{proc} will remove a previous setting.

	@end deffn


	@node Scheme Read
	@subsection Reading Scheme Code

	@rnindex read
	@deffn {Scheme Procedure} read [port]
	@deffnx {C Function} scm_read (port)
	Read an s-expression from the input port @var{port}, or from
	the current input port if @var{port} is not specified.
	Any whitespace before the next token is discarded.
	@end deffn

	The behavior of Guile's Scheme reader can be modified by manipulating
	its read options.

	@cindex options - read
	@cindex read options
	@deffn {Scheme Procedure} read-options [setting]
	Display the current settings of the global read options. If
	@var{setting} is omitted, only a short form of the current read options
	is printed. Otherwise if @var{setting} is the symbol @code{help}, a
	complete options description is displayed.
	@end deffn

	The set of available options, and their default values, may be had by
	invoking @code{read-options} at the prompt.

	@smalllisp
	scheme@@(guile-user)> (read-options)
	(square-brackets keywords #f positions)
	scheme@@(guile-user)> (read-options 'help)
	positions yes Record positions of source code expressions.
	case-insensitive no Convert symbols to lower case.
	keywords #f Style of keyword recognition: #f, 'prefix or 'postfix.
	r6rs-hex-escapes no Use R6RS variable-length character and string hex escapes.
	square-brackets yes Treat `[' and `]' as parentheses, for R6RS compatibility.
	hungry-eol-escapes no In strings, consume leading whitespace after an
	escaped end-of-line.
	curly-infix no Support SRFI-105 curly infix expressions.
	r7rs-symbols no Support R7RS \|...\| symbol notation.
	@end smalllisp

	Note that Guile also includes a preliminary mechanism for setting read
	options on a per-port basis. For instance, the @code{case-insensitive}
	read option is set (or unset) on the port when the reader encounters the
	@code{#!fold-case} or @code{#!no-fold-case} reader directives.
	Similarly, the @code{#!curly-infix} reader directive sets the
	@code{curly-infix} read option on the port, and
	@code{#!curly-infix-and-bracket-lists} sets @code{curly-infix} and
	unsets @code{square-brackets} on the port (@pxref{SRFI-105}). There is
	currently no other way to access or set the per-port read options.

	The boolean options may be toggled with @code{read-enable} and
	@code{read-disable}. The non-boolean @code{keywords} option must be set
	using @code{read-set!}.

	@deffn {Scheme Procedure} read-enable option-name
	@deffnx {Scheme Procedure} read-disable option-name
	@deffnx {Scheme Syntax} read-set! option-name value
	Modify the read options. @code{read-enable} should be used with boolean
	options and switches them on, @code{read-disable} switches them off.

	@code{read-set!} can be used to set an option to a specific value. Due
	to historical oddities, it is a macro that expects an unquoted option
	name.
	@end deffn

	For example, to make @code{read} fold all symbols to their lower case
	(perhaps for compatibility with older Scheme code), you can enter:

	@lisp
	(read-enable 'case-insensitive)
	@end lisp

	For more information on the effect of the @code{r6rs-hex-escapes} and
	@code{hungry-eol-escapes} options, see (@pxref{String Syntax}).

	For more information on the @code{r7rs-symbols} option, see
	(@pxref{Symbol Read Syntax}).


	@node Annotated Scheme Read
	@subsection Reading Scheme Code, For the Compiler

	When something goes wrong with a Scheme program, the user will want to
	know how to fix it. This starts with identifying where the error
	occurred: we want to associate a source location with each component part
	of source code, and propagate that source location information through
	to the compiler or interpreter.

	For that, Guile provides @code{read-syntax}.

	@deffn {Scheme Procedure} read-syntax [port]
	Read an s-expression from the input port @var{port}, or from the current
	input port if @var{port} is not specified.

	If, after skipping white space and comments, no more bytes are available
	from @var{port}, return the end-of-file object. @xref{Binary I/O}.
	Otherwise, return an annotated datum. An annotated datum is a syntax
	object which associates a source location with a datum. For example:

	@example
	(call-with-input-string " foo" read-syntax)
	; @result{} #<syntax:unknown file:1:2 foo>
	(call-with-input-string "(foo)" read-syntax)
	; @result{}
	; #<syntax:unknown file:1:0
	; (#<syntax unknown file:1:1 foo>)>
	@end example

	As the second example shows, all fields of pairs and vectors are also
	annotated, recursively.
	@end deffn

	Most users are familiar with syntax objects in the context of macros,
	which use syntax objects to associate scope information with
	identifiers. @xref{Macros}. Here we use syntax objects to associate
	source location information with any datum, but without attaching scope
	information. The Scheme compiler (@code{compile}) and the interpreter
	(@code{eval}) can accept syntax objects directly as input, allowing them
	to associate source information with resulting code.
	@xref{Compilation}, and @xref{Fly Evaluation}.

	Note that there is a legacy interface for getting source locations into
	the Scheme compiler or interpreter, which is to use a side table that
	associates ``source properties'' with each subdatum returned by
	@code{read}, instead of wrapping the datums directly as in
	@code{read-syntax}. This has the disadvantage of not being able to
	annotate all kinds of datums. @xref{Source Properties}, for more
	information.


	@node Scheme Write
	@subsection Writing Scheme Values

	Any scheme value may be written to a port. Not all values may be read
	back in (@pxref{Scheme Read}), however.

	@rnindex write
	@rnindex print
	@deffn {Scheme Procedure} write obj [port]
	Send a representation of @var{obj} to @var{port} or to the current
	output port if not given.

	The output is designed to be machine readable, and can be read back
	with @code{read} (@pxref{Scheme Read}). Strings are printed in
	double quotes, with escapes if necessary, and characters are printed in
	@samp{#\} notation.
	@end deffn

	@rnindex display
	@deffn {Scheme Procedure} display obj [port]
	Send a representation of @var{obj} to @var{port} or to the current
	output port if not given.

	The output is designed for human readability, it differs from
	@code{write} in that strings are printed without double quotes and
	escapes, and characters are printed as per @code{write-char}, not in
	@samp{#\} form.
	@end deffn

	As was the case with the Scheme reader, there are a few options that
	affect the behavior of the Scheme printer.

	@cindex options - print
	@cindex print options
	@deffn {Scheme Procedure} print-options [setting]
	Display the current settings of the read options. If @var{setting} is
	omitted, only a short form of the current read options is
	printed. Otherwise if @var{setting} is the symbol @code{help}, a
	complete options description is displayed.
	@end deffn

	The set of available options, and their default values, may be had by
	invoking @code{print-options} at the prompt.

	@smalllisp
	scheme@@(guile-user)> (print-options)
	(quote-keywordish-symbols reader highlight-suffix "@}" highlight-prefix "@{")
	scheme@@(guile-user)> (print-options 'help)
	highlight-prefix @{ The string to print before highlighted values.
	highlight-suffix @} The string to print after highlighted values.
	quote-keywordish-symbols reader How to print symbols that have a colon
	as their first or last character. The
	value '#f' does not quote the colons;
	'#t' quotes them; 'reader' quotes them
	when the reader option 'keywords' is
	not '#f'.
	escape-newlines yes Render newlines as \n when printing
	using `write'.
	r7rs-symbols no Escape symbols using R7RS \|...\| symbol
	notation.
	@end smalllisp

	These options may be modified with the print-set! syntax.

	@deffn {Scheme Syntax} print-set! option-name value
	Modify the print options. Due to historical oddities, @code{print-set!}
	is a macro that expects an unquoted option name.
	@end deffn


	@node Fly Evaluation
	@subsection Procedures for On the Fly Evaluation

	Scheme has the lovely property that its expressions may be represented
	as data. The @code{eval} procedure takes a Scheme datum and evaluates
	it as code.

	@rnindex eval
	@c ARGFIXME environment/environment specifier
	@deffn {Scheme Procedure} eval exp module_or_state
	@deffnx {C Function} scm_eval (exp, module_or_state)
	Evaluate @var{exp}, a list representing a Scheme expression,
	in the top-level environment specified by @var{module_or_state}.
	While @var{exp} is evaluated (using @code{primitive-eval}),
	@var{module_or_state} is made the current module. The current module
	is reset to its previous value when @code{eval} returns.
	XXX - dynamic states.
	Example: (eval '(+ 1 2) (interaction-environment))
	@end deffn

	@rnindex interaction-environment
	@deffn {Scheme Procedure} interaction-environment
	@deffnx {C Function} scm_interaction_environment ()
	Return a specifier for the environment that contains
	implementation--defined bindings, typically a superset of those
	listed in the report. The intent is that this procedure will
	return the environment in which the implementation would
	evaluate expressions dynamically typed by the user.
	@end deffn

	@xref{Environments}, for other environments.

	One does not always receive code as Scheme data, of course, and this is
	especially the case for Guile's other language implementations
	(@pxref{Other Languages}). For the case in which all you have is a
	string, we have @code{eval-string}. There is a legacy version of this
	procedure in the default environment, but you really want the one from
	@code{(ice-9 eval-string)}, so load it up:

	@example
	(use-modules (ice-9 eval-string))
	@end example

	@deffn {Scheme Procedure} eval-string string [#:module=#f] [#:file=#f] @
	[#:line=#f] [#:column=#f] @
	[#:lang=(current-language)] @
	[#:compile?=#f]
	Parse @var{string} according to the current language, normally Scheme.
	Evaluate or compile the expressions it contains, in order, returning the
	last expression.

	If the @var{module} keyword argument is set, save a module excursion
	(@pxref{Module System Reflection}) and set the current module to
	@var{module} before evaluation.

	The @var{file}, @var{line}, and @var{column} keyword arguments can be
	used to indicate that the source string begins at a particular source
	location.

	Finally, @var{lang} is a language, defaulting to the current language,
	and the expression is compiled if @var{compile?} is true or there is no
	evaluator for the given language.
	@end deffn

	@deffn {C Function} scm_eval_string (string)
	@deffnx {C Function} scm_eval_string_in_module (string, module)
	These C bindings call @code{eval-string} from @code{(ice-9
	eval-string)}, evaluating within @var{module} or the current module.
	@end deffn

	@deftypefn {C Function} SCM scm_c_eval_string (const char *string)
	@code{scm_eval_string}, but taking a C string in locale encoding instead
	of an @code{SCM}.
	@end deftypefn

	@deffn {Scheme Procedure} apply proc arg @dots{} arglst
	@deffnx {C Function} scm_apply_0 (proc, arglst)
	@deffnx {C Function} scm_apply_1 (proc, arg1, arglst)
	@deffnx {C Function} scm_apply_2 (proc, arg1, arg2, arglst)
	@deffnx {C Function} scm_apply_3 (proc, arg1, arg2, arg3, arglst)
	@deffnx {C Function} scm_apply (proc, arg, rest)
	@rnindex apply
	Call @var{proc} with arguments @var{arg} @dots{} and the
	elements of the @var{arglst} list.

	@code{scm_apply} takes parameters corresponding to a Scheme level
	@code{(lambda (proc arg1 . rest) ...)}. So @var{arg1} and all but the
	last element of the @var{rest} list make up @var{arg} @dots{}, and the
	last element of @var{rest} is the @var{arglst} list. Or if @var{rest}
	is the empty list @code{SCM_EOL} then there's no @var{arg} @dots{}, and
	(@var{arg1}) is the @var{arglst}.

	@var{arglst} is not modified, but the @var{rest} list passed to
	@code{scm_apply} is modified.
	@end deffn

	@deffn {C Function} scm_call_0 (proc)
	@deffnx {C Function} scm_call_1 (proc, arg1)
	@deffnx {C Function} scm_call_2 (proc, arg1, arg2)
	@deffnx {C Function} scm_call_3 (proc, arg1, arg2, arg3)
	@deffnx {C Function} scm_call_4 (proc, arg1, arg2, arg3, arg4)
	@deffnx {C Function} scm_call_5 (proc, arg1, arg2, arg3, arg4, arg5)
	@deffnx {C Function} scm_call_6 (proc, arg1, arg2, arg3, arg4, arg5, arg6)
	@deffnx {C Function} scm_call_7 (proc, arg1, arg2, arg3, arg4, arg5, arg6, arg7)
	@deffnx {C Function} scm_call_8 (proc, arg1, arg2, arg3, arg4, arg5, arg6, arg7, arg8)
	@deffnx {C Function} scm_call_9 (proc, arg1, arg2, arg3, arg4, arg5, arg6, arg7, arg8, arg9)
	Call @var{proc} with the given arguments.
	@end deffn

	@deffn {C Function} scm_call (proc, ...)
	Call @var{proc} with any number of arguments. The argument list must be
	terminated by @code{SCM_UNDEFINED}. For example:

	@example
	scm_call (scm_c_public_ref ("guile", "+"),
	scm_from_int (1),
	scm_from_int (2),
	SCM_UNDEFINED);
	@end example
	@end deffn

	@deffn {C Function} scm_call_n (proc, argv, nargs)
	Call @var{proc} with the array of arguments @var{argv}, as a
	@code{SCM*}. The length of the arguments should be passed in
	@var{nargs}, as a @code{size_t}.
	@end deffn

	@deffn {Scheme Procedure} primitive-eval exp
	@deffnx {C Function} scm_primitive_eval (exp)
	Evaluate @var{exp} in the top-level environment specified by
	the current module.
	@end deffn


	@node Compilation
	@subsection Compiling Scheme Code

	The @code{eval} procedure directly interprets the S-expression
	representation of Scheme. An alternate strategy for evaluation is to
	determine ahead of time what computations will be necessary to
	evaluate the expression, and then use that recipe to produce the
	desired results. This is known as @dfn{compilation}.

	While it is possible to compile simple Scheme expressions such as
	@code{(+ 2 2)} or even @code{"Hello world!"}, compilation is most
	interesting in the context of procedures. Compiling a lambda expression
	produces a compiled procedure, which is just like a normal procedure
	except typically much faster, because it can bypass the generic
	interpreter.

	Functions from system modules in a Guile installation are normally
	compiled already, so they load and run quickly.

	@cindex automatic compilation
	Note that well-written Scheme programs will not typically call the
	procedures in this section, for the same reason that it is often bad
	taste to use @code{eval}. By default, Guile automatically compiles any
	files it encounters that have not been compiled yet (@pxref{Invoking
	Guile, @code{--auto-compile}}). The compiler can also be invoked
	explicitly from the shell as @code{guild compile foo.scm}.

	(Why are calls to @code{eval} and @code{compile} usually in bad taste?
	Because they are limited, in that they can only really make sense for
	top-level expressions. Also, most needs for ``compile-time''
	computation are fulfilled by macros and closures. Of course one good
	counterexample is the REPL itself, or any code that reads expressions
	from a port.)

	Automatic compilation generally works transparently, without any need
	for user intervention. However Guile does not yet do proper dependency
	tracking, so that if file @file{@var{a}.scm} uses macros from
	@file{@var{b}.scm}, and @var{@var{b}.scm} changes, @code{@var{a}.scm}
	would not be automatically recompiled. To forcibly invalidate the
	auto-compilation cache, pass the @code{--fresh-auto-compile} option to
	Guile, or set the @code{GUILE_AUTO_COMPILE} environment variable to
	@code{fresh} (instead of to @code{0} or @code{1}).

	For more information on the compiler itself, see @ref{Compiling to the
	Virtual Machine}. For information on the virtual machine, see @ref{A
	Virtual Machine for Guile}.

	The command-line interface to Guile's compiler is the @command{guild
	compile} command:

	@deffn {Command} {guild compile} [@option{option}...] @var{file}...
	Compile @var{file}, a source file, and store bytecode in the compilation cache
	or in the file specified by the @option{-o} option. The following options are
	available:

	@table @option

	@item -L @var{dir}
	@itemx --load-path=@var{dir}
	Add @var{dir} to the front of the module load path.

	@item -o @var{ofile}
	@itemx --output=@var{ofile}
	Write output bytecode to @var{ofile}. By convention, bytecode file
	names end in @code{.go}. When @option{-o} is omitted, the output file
	name is as for @code{compile-file} (see below).

	@item -x @var{extension}
	Recognize @var{extension} as a valid source file name extension.

	For example, to compile R6RS code, you might want to pass @command{-x
	.sls} so that files ending in @file{.sls} can be found.

	@item -W @var{warning}
	@itemx --warn=@var{warning}
	@cindex warnings, compiler
	Enable specific warning passes; use @code{-Whelp} for a list of
	available options. The default is @code{-W1}, which enables a number of
	common warnings. Pass @code{-W0} to disable all warnings.

	@item -O @var{opt}
	@itemx --optimize=@var{opt}
	@cindex optimizations, compiler
	Enable or disable specific compiler optimizations; use @code{-Ohelp} for
	a list of available options. The default is @code{-O2}, which enables
	most optimizations. @code{-O0} is recommended if compilation speed is
	more important than the speed of the compiled code. Pass
	@code{-Ono-@var{opt}} to disable a specific compiler pass. Any number
	of @code{-O} options can be passed to the compiler, with later ones
	taking precedence.

	@item --r6rs
	@itemx --r7rs
	Compile in an environment whose default bindings, reader options, and
	load paths are adapted for specific Scheme standards. @xref{R6RS
	Support}, and @xref{R7RS Support}.

	@item -f @var{lang}
	@itemx --from=@var{lang}
	Use @var{lang} as the source language of @var{file}. If this option is omitted,
	@code{scheme} is assumed.

	@item -t @var{lang}
	@itemx --to=@var{lang}
	Use @var{lang} as the target language of @var{file}. If this option is omitted,
	@code{rtl} is assumed.

	@item -T @var{target}
	@itemx --target=@var{target}
	Produce code for @var{target} instead of @var{%host-type} (@pxref{Build
	Config, %host-type}). Target must be a valid GNU triplet, such as
	@code{armv5tel-unknown-linux-gnueabi} (@pxref{Specifying Target
	Triplets,,, autoconf, GNU Autoconf Manual}).

	@end table

	Each @var{file} is assumed to be UTF-8-encoded, unless it contains a
	coding declaration as recognized by @code{file-encoding}
	(@pxref{Character Encoding of Source Files}).
	@end deffn

	The compiler can also be invoked directly by Scheme code. These
	interfaces are in their own module:

	@example
	(use-modules (system base compile))
	@end example

	@deffn {Scheme Procedure} compile exp [#:env=#f] @
	[#:from=(current-language)] @
	[#:to=value] [#:opts='()] @
	[#:optimization-level=(default-optimization-level)] @
	[#:warning-level=(default-warning-level)]
	Compile the expression @var{exp} in the environment @var{env}. If
	@var{exp} is a procedure, the result will be a compiled procedure;
	otherwise @code{compile} is mostly equivalent to @code{eval}.

	For a discussion of languages and compiler options, @xref{Compiling to
	the Virtual Machine}.
	@end deffn

	@deffn {Scheme Procedure} compile-file file [#:output-file=#f] @
	[#:from=(current-language)] [#:to='rtl] @
	[#:env=(default-environment from)] @
	[#:opts='()] @
	[#:optimization-level=(default-optimization-level)] @
	[#:warning-level=(default-warning-level)] @
	[#:canonicalization='relative]
	Compile the file named @var{file}.

	Output will be written to a @var{output-file}. If you do not supply an
	output file name, output is written to a file in the cache directory, as
	computed by @code{(compiled-file-name @var{file})}.

	@var{from} and @var{to} specify the source and target languages.
	@xref{Compiling to the Virtual Machine}, for more information on these
	options, and on @var{env} and @var{opts}.

	As with @command{guild compile}, @var{file} is assumed to be
	UTF-8-encoded unless it contains a coding declaration.
	@end deffn

	@deffn {Scheme Parameter} default-optimization-level
	The default optimization level, as an integer from 0 to 9. The default
	is 2.
	@end deffn
	@deffn {Scheme Parameter} default-warning-level
	The default warning level, as an integer from 0 to 9. The default is 1.
	@end deffn

	@xref{Parameters}, for more on how to set parameters.

	@deffn {Scheme Procedure} compiled-file-name file
	Compute a cached location for a compiled version of a Scheme file named
	@var{file}.

	This file will usually be below the @file{$HOME/.cache/guile/ccache}
	directory, depending on the value of the @env{XDG_CACHE_HOME}
	environment variable. The intention is that @code{compiled-file-name}
	provides a fallback location for caching auto-compiled files. If you
	want to place a compile file in the @code{%load-compiled-path}, you
	should pass the @var{output-file} option to @code{compile-file},
	explicitly.
	@end deffn

	@defvr {Scheme Variable} %auto-compilation-options
	This variable contains the options passed to the @code{compile-file}
	procedure when auto-compiling source files. By default, it enables
	useful compilation warnings. It can be customized from @file{~/.guile}.
	@end defvr

	@node Loading
	@subsection Loading Scheme Code from File

	@rnindex load
	@deffn {Scheme Procedure} load filename [reader]
	Load @var{filename} and evaluate its contents in the top-level
	environment.

	@var{reader} if provided should be either @code{#f}, or a procedure with
	the signature @code{(lambda (port) @dots{})} which reads the next
	expression from @var{port}. If @var{reader} is @code{#f} or absent,
	Guile's built-in @code{read} procedure is used (@pxref{Scheme Read}).

	The @var{reader} argument takes effect by setting the value of the
	@code{current-reader} fluid (see below) before loading the file, and
	restoring its previous value when loading is complete. The Scheme code
	inside @var{filename} can itself change the current reader procedure on
	the fly by setting @code{current-reader} fluid.

	If the variable @code{%load-hook} is defined, it should be bound to a
	procedure that will be called before any code is loaded. See
	documentation for @code{%load-hook} later in this section.
	@end deffn

	@deffn {Scheme Procedure} load-compiled filename
	Load the compiled file named @var{filename}.

	Compiling a source file (@pxref{Read/Load/Eval/Compile}) and then
	calling @code{load-compiled} on the resulting file is equivalent to
	calling @code{load} on the source file.
	@end deffn

	@deffn {Scheme Procedure} primitive-load filename
	@deffnx {C Function} scm_primitive_load (filename)
	Load the file named @var{filename} and evaluate its contents in the
	top-level environment. @var{filename} must either be a full pathname or
	be a pathname relative to the current directory. If the variable
	@code{%load-hook} is defined, it should be bound to a procedure that
	will be called before any code is loaded. See the documentation for
	@code{%load-hook} later in this section.
	@end deffn

	@deftypefn {C Function} SCM scm_c_primitive_load (const char *filename)
	@code{scm_primitive_load}, but taking a C string instead of an
	@code{SCM}.
	@end deftypefn

	@defvar current-reader
	@code{current-reader} holds the read procedure that is currently being
	used by the above loading procedures to read expressions (from the file
	that they are loading). @code{current-reader} is a fluid, so it has an
	independent value in each dynamic root and should be read and set using
	@code{fluid-ref} and @code{fluid-set!} (@pxref{Fluids and Dynamic
	States}).

	Changing @code{current-reader} is typically useful to introduce local
	syntactic changes, such that code following the @code{fluid-set!} call
	is read using the newly installed reader. The @code{current-reader}
	change should take place at evaluation time when the code is evaluated,
	or at compilation time when the code is compiled:

	@findex eval-when
	@example
	(eval-when (compile eval)
	(fluid-set! current-reader my-own-reader))
	@end example

	The @code{eval-when} form above ensures that the @code{current-reader}
	change occurs at the right time.
	@end defvar

	@defvar %load-hook
	A procedure to be called @code{(%load-hook @var{filename})} whenever a
	file is loaded, or @code{#f} for no such call. @code{%load-hook} is
	used by all of the loading functions (@code{load} and
	@code{primitive-load}, and @code{load-from-path} and
	@code{primitive-load-path} documented in the next section).

	For example an application can set this to show what's loaded,

	@example
	(set! %load-hook (lambda (filename)
	(format #t "Loading ~a ...\n" filename)))
	(load-from-path "foo.scm")
	@print{} Loading /usr/local/share/guile/site/foo.scm ...
	@end example
	@end defvar

	@deffn {Scheme Procedure} current-load-port
	@deffnx {C Function} scm_current_load_port ()
	Return the current-load-port.
	The load port is used internally by @code{primitive-load}.
	@end deffn

	@node Load Paths
	@subsection Load Paths

	The procedure in the previous section look for Scheme code in the file
	system at specific location. Guile also has some procedures to search
	the load path for code.

	@defvar %load-path
	List of directories which should be searched for Scheme modules and
	libraries. When Guile starts up, @code{%load-path} is initialized to
	the default load path @code{(list (%library-dir) (%site-dir)
	(%global-site-dir) (%package-data-dir))}. The @env{GUILE_LOAD_PATH}
	environment variable can be used to prepend or append additional
	directories (@pxref{Environment Variables}).

	@xref{Build Config}, for more on @code{%site-dir} and related
	procedures.
	@end defvar

	@deffn {Scheme Procedure} load-from-path filename
	Similar to @code{load}, but searches for @var{filename} in the load
	paths. Preferentially loads a compiled version of the file, if it is
	available and up-to-date.
	@end deffn

	A user can extend the load path by calling @code{add-to-load-path}.

	@deffn {Scheme Syntax} add-to-load-path dir
	Add @var{dir} to the load path.
	@end deffn

	For example, a script might include this form to add the directory that
	it is in to the load path:

	@example
	(add-to-load-path (dirname (current-filename)))
	@end example

	It's better to use @code{add-to-load-path} than to modify
	@code{%load-path} directly, because @code{add-to-load-path} takes care
	of modifying the path both at compile-time and at run-time.

	@deffn {Scheme Procedure} primitive-load-path filename [exception-on-not-found]
	@deffnx {C Function} scm_primitive_load_path (filename)
	Search @code{%load-path} for the file named @var{filename} and
	load it into the top-level environment. If @var{filename} is a
	relative pathname and is not found in the list of search paths,
	an error is signaled. Preferentially loads a compiled version of the
	file, if it is available and up-to-date.

	If @var{filename} is a relative pathname and is not found in the list of
	search paths, one of three things may happen, depending on the optional
	second argument, @var{exception-on-not-found}. If it is @code{#f},
	@code{#f} will be returned. If it is a procedure, it will be called
	with no arguments. (This allows a distinction to be made between
	exceptions raised by loading a file, and exceptions related to the
	loader itself.) Otherwise an error is signaled.

	For compatibility with Guile 1.8 and earlier, the C function takes only
	one argument, which can be either a string (the file name) or an
	argument list.
	@end deffn

	@deffn {Scheme Procedure} %search-load-path filename
	@deffnx {C Function} scm_sys_search_load_path (filename)
	Search @code{%load-path} for the file named @var{filename}, which must
	be readable by the current user. If @var{filename} is found in the list
	of paths to search or is an absolute pathname, return its full pathname.
	Otherwise, return @code{#f}. Filenames may have any of the optional
	extensions in the @code{%load-extensions} list; @code{%search-load-path}
	will try each extension automatically.
	@end deffn

	@defvar %load-extensions
	A list of default file extensions for files containing Scheme code.
	@code{%search-load-path} tries each of these extensions when looking for
	a file to load. By default, @code{%load-extensions} is bound to the
	list @code{("" ".scm")}.
	@end defvar

	As mentioned above, when Guile searches the @code{%load-path} for a
	source file, it will also search the @code{%load-compiled-path} for a
	corresponding compiled file. If the compiled file is as new or newer
	than the source file, it will be loaded instead of the source file,
	using @code{load-compiled}.

	@defvar %load-compiled-path
	Like @code{%load-path}, but for compiled files. By default, this path
	has two entries: one for compiled files from Guile itself, and one for
	site packages. The @env{GUILE_LOAD_COMPILED_PATH} environment variable
	can be used to prepend or append additional directories
	(@pxref{Environment Variables}).
	@end defvar

	When @code{primitive-load-path} searches the @code{%load-compiled-path}
	for a corresponding compiled file for a relative path it does so by
	appending @code{.go} to the relative path. For example, searching for
	@code{ice-9/popen} could find
	@code{/usr/lib/guile/3.0/ccache/ice-9/popen.go}, and use it instead of
	@code{/usr/share/guile/3.0/ice-9/popen.scm}.

	If @code{primitive-load-path} does not find a corresponding @code{.go}
	file in the @code{%load-compiled-path}, or the @code{.go} file is out of
	date, it will search for a corresponding auto-compiled file in the
	fallback path, possibly creating one if one does not exist.

	@xref{Installing Site Packages}, for more on how to correctly install
	site packages. @xref{Modules and the File System}, for more on the
	relationship between load paths and modules. @xref{Compilation}, for
	more on the fallback path and auto-compilation.

	Finally, there are a couple of helper procedures for general path
	manipulation.

	@deffn {Scheme Procedure} parse-path path [tail]
	@deffnx {C Function} scm_parse_path (path, tail)
	Parse @var{path}, which is expected to be a colon-separated string, into
	a list and return the resulting list with @var{tail} appended. If
	@var{path} is @code{#f}, @var{tail} is returned.
	@end deffn

	@deffn {Scheme Procedure} parse-path-with-ellipsis path base
	@deffnx {C Function} scm_parse_path_with_ellipsis (path, base)
	Parse @var{path}, which is expected to be a colon-separated string, into
	a list and return the resulting list with @var{base} (a list) spliced in
	place of the @code{...} path component, if present, or else @var{base}
	is added to the end. If @var{path} is @code{#f}, @var{base} is
	returned.
	@end deffn

	@deffn {Scheme Procedure} search-path path filename [extensions [require-exts?]]
	@deffnx {C Function} scm_search_path (path, filename, rest)
	Search @var{path} for a directory containing a file named
	@var{filename}. The file must be readable, and not a directory. If we
	find one, return its full filename; otherwise, return @code{#f}. If
	@var{filename} is absolute, return it unchanged. If given,
	@var{extensions} is a list of strings; for each directory in @var{path},
	we search for @var{filename} concatenated with each @var{extension}. If
	@var{require-exts?} is true, require that the returned file name have
	one of the given extensions; if @var{require-exts?} is not given, it
	defaults to @code{#f}.

	For compatibility with Guile 1.8 and earlier, the C function takes only
	three arguments.
	@end deffn


	@node Character Encoding of Source Files
	@subsection Character Encoding of Source Files

	@cindex source file encoding
	@cindex primitive-load
	@cindex load
	Scheme source code files are usually encoded in ASCII or UTF-8, but the
	built-in reader can interpret other character encodings as well. When
	Guile loads Scheme source code, it uses the @code{file-encoding}
	procedure (described below) to try to guess the encoding of the file.
	In the absence of any hints, UTF-8 is assumed. One way to provide a
	hint about the encoding of a source file is to place a coding
	declaration in the top 500 characters of the file.

	A coding declaration has the form @code{coding: XXXXXX}, where
	@code{XXXXXX} is the name of a character encoding in which the source
	code file has been encoded. The coding declaration must appear in a
	scheme comment. It can either be a semicolon-initiated comment, or the
	first block @code{#!} comment in the file.

	The name of the character encoding in the coding declaration is
	typically lower case and containing only letters, numbers, and hyphens,
	as recognized by @code{set-port-encoding!} (@pxref{Ports,
	@code{set-port-encoding!}}). Common examples of character encoding
	names are @code{utf-8} and @code{iso-8859-1},
	@url{http://www.iana.org/assignments/character-sets, as defined by
	IANA}. Thus, the coding declaration is mostly compatible with Emacs.

	However, there are some differences in encoding names recognized by
	Emacs and encoding names defined by IANA, the latter being essentially a
	subset of the former. For instance, @code{latin-1} is a valid encoding
	name for Emacs, but it's not according to the IANA standard, which Guile
	follows; instead, you should use @code{iso-8859-1}, which is both
	understood by Emacs and dubbed by IANA (IANA writes it uppercase but
	Emacs wants it lowercase and Guile is case insensitive.)

	For source code, only a subset of all possible character encodings can
	be interpreted by the built-in source code reader. Only those
	character encodings in which ASCII text appears unmodified can be
	used. This includes @code{UTF-8} and @code{ISO-8859-1} through
	@code{ISO-8859-15}. The multi-byte character encodings @code{UTF-16}
	and @code{UTF-32} may not be used because they are not compatible with
	ASCII.

	@cindex read
	@cindex encoding
	@cindex port encoding
	@findex set-port-encoding!
	There might be a scenario in which one would want to read non-ASCII
	code from a port, such as with the function @code{read}, instead of
	with @code{load}. If the port's character encoding is the same as the
	encoding of the code to be read by the port, not other special
	handling is necessary. The port will automatically do the character
	encoding conversion. The functions @code{setlocale} or by
	@code{set-port-encoding!} are used to set port encodings
	(@pxref{Ports}).

	If a port is used to read code of unknown character encoding, it can
	accomplish this in three steps. First, the character encoding of the
	port should be set to ISO-8859-1 using @code{set-port-encoding!}.
	Then, the procedure @code{file-encoding}, described below, is used to
	scan for a coding declaration when reading from the port. As a side
	effect, it rewinds the port after its scan is complete. After that,
	the port's character encoding should be set to the encoding returned
	by @code{file-encoding}, if any, again by using
	@code{set-port-encoding!}. Then the code can be read as normal.

	Alternatively, one can use the @code{#:guess-encoding} keyword argument
	of @code{open-file} and related procedures. @xref{File Ports}.

	@deffn {Scheme Procedure} file-encoding port
	@deffnx {C Function} scm_file_encoding (port)
	Attempt to scan the first few hundred bytes from the @var{port} for
	hints about its character encoding. Return a string containing the
	encoding name or @code{#f} if the encoding cannot be determined. The
	port is rewound.

	Currently, the only supported method is to look for an Emacs-like
	character coding declaration (@pxref{Recognize Coding, how Emacs
	recognizes file encoding,, emacs, The GNU Emacs Reference Manual}). The
	coding declaration is of the form @code{coding: XXXXX} and must appear
	in a Scheme comment. Additional heuristics may be added in the future.
	@end deffn


	@node Delayed Evaluation
	@subsection Delayed Evaluation
	@cindex delayed evaluation
	@cindex promises

	Promises are a convenient way to defer a calculation until its result
	is actually needed, and to run such a calculation only once. Also
	@pxref{SRFI-45}.

	@deffn syntax delay expr
	@rnindex delay
	Return a promise object which holds the given @var{expr} expression,
	ready to be evaluated by a later @code{force}.
	@end deffn

	@deffn {Scheme Procedure} promise? obj
	@deffnx {C Function} scm_promise_p (obj)
	Return true if @var{obj} is a promise.
	@end deffn

	@rnindex force
	@deffn {Scheme Procedure} force p
	@deffnx {C Function} scm_force (p)
	Return the value obtained from evaluating the @var{expr} in the given
	promise @var{p}. If @var{p} has previously been forced then its
	@var{expr} is not evaluated again, instead the value obtained at that
	time is simply returned.

	During a @code{force}, an @var{expr} can call @code{force} again on
	its own promise, resulting in a recursive evaluation of that
	@var{expr}. The first evaluation to return gives the value for the
	promise. Higher evaluations run to completion in the normal way, but
	their results are ignored, @code{force} always returns the first
	value.
	@end deffn


	@node Local Evaluation
	@subsection Local Evaluation

	Guile includes a facility to capture a lexical environment, and later
	evaluate a new expression within that environment. This code is
	implemented in a module.

	@example
	(use-modules (ice-9 local-eval))
	@end example

	@deffn syntax the-environment
	Captures and returns a lexical environment for use with
	@code{local-eval} or @code{local-compile}.
	@end deffn

	@deffn {Scheme Procedure} local-eval exp env
	@deffnx {C Function} scm_local_eval (exp, env)
	@deffnx {Scheme Procedure} local-compile exp env [opts=()]
	Evaluate or compile the expression @var{exp} in the lexical environment
	@var{env}.
	@end deffn

	Here is a simple example, illustrating that it is the variable
	that gets captured, not just its value at one point in time.

	@example
	(define e (let ((x 100)) (the-environment)))
	(define fetch-x (local-eval '(lambda () x) e))
	(fetch-x)
	@result{} 100
	(local-eval '(set! x 42) e)
	(fetch-x)
	@result{} 42
	@end example

	While @var{exp} is evaluated within the lexical environment of
	@code{(the-environment)}, it has the dynamic environment of the call to
	@code{local-eval}.

	@code{local-eval} and @code{local-compile} can only evaluate
	expressions, not definitions.

	@example
	(local-eval '(define foo 42)
	(let ((x 100)) (the-environment)))
	@result{} syntax error: definition in expression context
	@end example

	Note that the current implementation of @code{(the-environment)} only
	captures ``normal'' lexical bindings, and pattern variables bound by
	@code{syntax-case}. It does not currently capture local syntax
	transformers bound by @code{let-syntax}, @code{letrec-syntax} or
	non-top-level @code{define-syntax} forms. Any attempt to reference such
	captured syntactic keywords via @code{local-eval} or
	@code{local-compile} produces an error.


	@node Local Inclusion
	@subsection Local Inclusion

	This section has discussed various means of linking Scheme code
	together: fundamentally, loading up files at run-time using @code{load}
	and @code{load-compiled}. Guile provides another option to compose
	parts of programs together at expansion-time instead of at run-time.

	@deffn {Scheme Syntax} include file-name
	Open @var{file-name}, at expansion-time, and read the Scheme forms that
	it contains, splicing them into the location of the @code{include},
	within a @code{begin}.

	If @var{file-name} is a relative path, it is searched for relative to
	the path that contains the file that the @code{include} form appears in.
	@end deffn

	If you are a C programmer, if @code{load} in Scheme is like
	@code{dlopen} in C, consider @code{include} to be like the C
	preprocessor's @code{#include}. When you use @code{include}, it is as
	if the contents of the included file were typed in instead of the
	@code{include} form.

	Because the code is included at compile-time, it is available to the
	macroexpander. Syntax definitions in the included file are available to
	later code in the form in which the @code{include} appears, without the
	need for @code{eval-when}. (@xref{Eval When}.)

	For the same reason, compiling a form that uses @code{include} results
	in one compilation unit, composed of multiple files. Loading the
	compiled file is one @code{stat} operation for the compilation unit,
	instead of @code{2*@var{n}} in the case of @code{load} (once for each
	loaded source file, and once each corresponding compiled file, in the
	best case).

	Unlike @code{load}, @code{include} also works within nested lexical
	contexts. It so happens that the optimizer works best within a lexical
	context, because all of the uses of bindings in a lexical context are
	visible, so composing files by including them within a @code{(let ()
	...)} can sometimes lead to important speed improvements.

	On the other hand, @code{include} does have all the disadvantages of
	early binding: once the code with the @code{include} is compiled, no
	change to the included file is reflected in the future behavior of the
	including form.

	Also, the particular form of @code{include}, which requires an absolute
	path, or a path relative to the current directory at compile-time, is
	not very amenable to compiling the source in one place, but then
	installing the source to another place. For this reason, Guile provides
	another form, @code{include-from-path}, which looks for the source file
	to include within a load path.

	@deffn {Scheme Syntax} include-from-path file-name
	Like @code{include}, but instead of expecting @code{file-name} to be an
	absolute file name, it is expected to be a relative path to search in
	the @code{%load-path}.
	@end deffn

	@code{include-from-path} is more useful when you want to install all of
	the source files for a package (as you should!). It makes it possible
	to evaluate an installed file from source, instead of relying on the
	@code{.go} file being up to date.

	@node Sandboxed Evaluation
	@subsection Sandboxed Evaluation

	Sometimes you would like to evaluate code that comes from an untrusted
	party. The safest way to do this is to buy a new computer, evaluate the
	code on that computer, then throw the machine away. However if you are
	unwilling to take this simple approach, Guile does include a limited
	``sandbox'' facility that can allow untrusted code to be evaluated with
	some confidence.

	To use the sandboxed evaluator, load its module:

	@example
	(use-modules (ice-9 sandbox))
	@end example

	Guile's sandboxing facility starts with the ability to restrict the time
	and space used by a piece of code.

	@deffn {Scheme Procedure} call-with-time-limit limit thunk limit-reached
	Call @var{thunk}, but cancel it if @var{limit} seconds of wall-clock
	time have elapsed. If the computation is canceled, call
	@var{limit-reached} in tail position. @var{thunk} must not disable
	interrupts or prevent an abort via a @code{dynamic-wind} unwind handler.
	@end deffn

	@deffn {Scheme Procedure} call-with-allocation-limit limit thunk limit-reached
	Call @var{thunk}, but cancel it if @var{limit} bytes have been
	allocated. If the computation is canceled, call @var{limit-reached} in
	tail position. @var{thunk} must not disable interrupts or prevent an
	abort via a @code{dynamic-wind} unwind handler.

	This limit applies to both stack and heap allocation. The computation
	will not be aborted before @var{limit} bytes have been allocated, but
	for the heap allocation limit, the check may be postponed until the next garbage collection.

	Note that as a current shortcoming, the heap size limit applies to all
	threads; concurrent allocation by other unrelated threads counts towards
	the allocation limit.
	@end deffn

	@deffn {Scheme Procedure} call-with-time-and-allocation-limits time-limit allocation-limit thunk
	Invoke @var{thunk} in a dynamic extent in which its execution is limited
	to @var{time-limit} seconds of wall-clock time, and its allocation to
	@var{allocation-limit} bytes. @var{thunk} must not disable interrupts
	or prevent an abort via a @code{dynamic-wind} unwind handler.

	If successful, return all values produced by invoking @var{thunk}. Any
	uncaught exception thrown by the thunk will propagate out. If the time
	or allocation limit is exceeded, an exception will be thrown to the
	@code{limit-exceeded} key.
	@end deffn

	The time limit and stack limit are both very precise, but the heap limit
	only gets checked asynchronously, after a garbage collection. In
	particular, if the heap is already very large, the number of allocated
	bytes between garbage collections will be large, and therefore the
	precision of the check is reduced.

	Additionally, due to the mechanism used by the allocation limit (the
	@code{after-gc-hook}), large single allocations like @code{(make-vector
	#e1e7)} are only detected after the allocation completes, even if the
	allocation itself causes garbage collection. It's possible therefore
	for user code to not only exceed the allocation limit set, but also to
	exhaust all available memory, causing out-of-memory conditions at any
	allocation site. Failure to allocate memory in Guile itself should be
	safe and cause an exception to be thrown, but most systems are not
	designed to handle @code{malloc} failures. An allocation failure may
	therefore exercise unexpected code paths in your system, so it is a
	weakness of the sandbox (and therefore an interesting point of attack).

	The main sandbox interface is @code{eval-in-sandbox}.

	@deffn {Scheme Procedure} eval-in-sandbox exp [#:time-limit 0.1] @
	[#:allocation-limit #e10e6] @
	[#:bindings all-pure-bindings] @
	[#:module (make-sandbox-module bindings)] @
	[#:sever-module? #t]
	Evaluate the Scheme expression @var{exp} within an isolated
	"sandbox". Limit its execution to @var{time-limit} seconds of
	wall-clock time, and limit its allocation to @var{allocation-limit}
	bytes.

	The evaluation will occur in @var{module}, which defaults to the result
	of calling @code{make-sandbox-module} on @var{bindings}, which itself
	defaults to @code{all-pure-bindings}. This is the core of the
	sandbox: creating a scope for the expression that is @dfn{safe}.

	A safe sandbox module has two characteristics. Firstly, it will not
	allow the expression being evaluated to avoid being canceled due to
	time or allocation limits. This ensures that the expression terminates
	in a timely fashion.

	Secondly, a safe sandbox module will prevent the evaluation from
	receiving information from previous evaluations, or from affecting
	future evaluations. All combinations of binding sets exported by
	@code{(ice-9 sandbox)} form safe sandbox modules.

	The @var{bindings} should be given as a list of import sets. One import
	set is a list whose car names an interface, like @code{(ice-9 q)}, and
	whose cdr is a list of imports. An import is either a bare symbol or a
	pair of @code{(@var{out} . @var{in})}, where @var{out} and @var{in} are
	both symbols and denote the name under which a binding is exported from
	the module, and the name under which to make the binding available,
	respectively. Note that @var{bindings} is only used as an input to the
	default initializer for the @var{module} argument; if you pass
	@code{#:module}, @var{bindings} is unused. If @var{sever-module?} is
	true (the default), the module will be unlinked from the global module
	tree after the evaluation returns, to allow @var{mod} to be
	garbage-collected.

	If successful, return all values produced by @var{exp}. Any uncaught
	exception thrown by the expression will propagate out. If the time or
	allocation limit is exceeded, an exception will be thrown to the
	@code{limit-exceeded} key.
	@end deffn

	Constructing a safe sandbox module is tricky in general. Guile defines
	an easy way to construct safe modules from predefined sets of bindings.
	Before getting to that interface, here are some general notes on safety.

	@enumerate
	@item The time and allocation limits rely on the ability to interrupt
	and cancel a computation. For this reason, no binding included in a
	sandbox module should be able to indefinitely postpone interrupt
	handling, nor should a binding be able to prevent an abort. In practice
	this second consideration means that @code{dynamic-wind} should not be
	included in any binding set.
	@item The time and allocation limits apply only to the
	@code{eval-in-sandbox} call. If the call returns a procedure which is
	later called, no limit is ``automatically'' in place. Users of
	@code{eval-in-sandbox} have to be very careful to reimpose limits when
	calling procedures that escape from sandboxes.
	@item Similarly, the dynamic environment of the @code{eval-in-sandbox}
	call is not necessarily in place when any procedure that escapes from
	the sandbox is later called.

	This detail prevents us from exposing @code{primitive-eval} to the
	sandbox, for two reasons. The first is that it's possible for legacy
	code to forge references to any binding, if the
	@code{allow-legacy-syntax-objects?} parameter is true. The default for
	this parameter is true; @pxref{Syntax Transformer Helpers} for the
	details. The parameter is bound to @code{#f} for the duration of the
	@code{eval-in-sandbox} call itself, but that will not be in place during
	calls to escaped procedures.

	The second reason we don't expose @code{primitive-eval} is that
	@code{primitive-eval} implicitly works in the current module, which for
	an escaped procedure will probably be different than the module that is
	current for the @code{eval-in-sandbox} call itself.

	The common denominator here is that if an interface exposed to the
	sandbox relies on dynamic environments, it is easy to mistakenly grant
	the sandboxed procedure additional capabilities in the form of bindings
	that it should not have access to. For this reason, the default sets of
	predefined bindings do not depend on any dynamically scoped value.
	@item Mutation may allow a sandboxed evaluation to break some invariant
	in users of data supplied to it. A lot of code culturally doesn't
	expect mutation, but if you hand mutable data to a sandboxed evaluation
	and you also grant mutating capabilities to that evaluation, then the
	sandboxed code may indeed mutate that data. The default set of bindings
	to the sandbox do not include any mutating primitives.

	Relatedly, @code{set!} may allow a sandbox to mutate a primitive,
	invalidating many system-wide invariants. Guile is currently quite
	permissive when it comes to imported bindings and mutability. Although
	@code{set!} to a module-local or lexically bound variable would be fine,
	we don't currently have an easy way to disallow @code{set!} to an
	imported binding, so currently no binding set includes @code{set!}.
	@item Mutation may allow a sandboxed evaluation to keep state, or
	make a communication mechanism with other code. On the one hand this
	sounds cool, but on the other hand maybe this is part of your threat
	model. Again, the default set of bindings doesn't include mutating
	primitives, preventing sandboxed evaluations from keeping state.
	@item The sandbox should probably not be able to open a network
	connection, or write to a file, or open a file from disk. The default
	binding set includes no interaction with the operating system.
	@end enumerate

	If you, dear reader, find the above discussion interesting, you will
	enjoy Jonathan Rees' dissertation, ``A Security Kernel Based on the
	Lambda Calculus''.

	@defvr {Scheme Variable} all-pure-bindings
	All ``pure'' bindings that together form a safe subset of those bindings
	available by default to Guile user code.
	@end defvr

	@defvr {Scheme Variable} all-pure-and-impure-bindings
	Like @code{all-pure-bindings}, but additionally including mutating
	primitives like @code{vector-set!}. This set is still safe in the sense
	mentioned above, with the caveats about mutation.
	@end defvr

	The components of these composite sets are as follows:
	@defvr {Scheme Variable} alist-bindings
	@defvrx {Scheme Variable} array-bindings
	@defvrx {Scheme Variable} bit-bindings
	@defvrx {Scheme Variable} bitvector-bindings
	@defvrx {Scheme Variable} char-bindings
	@defvrx {Scheme Variable} char-set-bindings
	@defvrx {Scheme Variable} clock-bindings
	@defvrx {Scheme Variable} core-bindings
	@defvrx {Scheme Variable} error-bindings
	@defvrx {Scheme Variable} fluid-bindings
	@defvrx {Scheme Variable} hash-bindings
	@defvrx {Scheme Variable} iteration-bindings
	@defvrx {Scheme Variable} keyword-bindings
	@defvrx {Scheme Variable} list-bindings
	@defvrx {Scheme Variable} macro-bindings
	@defvrx {Scheme Variable} nil-bindings
	@defvrx {Scheme Variable} number-bindings
	@defvrx {Scheme Variable} pair-bindings
	@defvrx {Scheme Variable} predicate-bindings
	@defvrx {Scheme Variable} procedure-bindings
	@defvrx {Scheme Variable} promise-bindings
	@defvrx {Scheme Variable} prompt-bindings
	@defvrx {Scheme Variable} regexp-bindings
	@defvrx {Scheme Variable} sort-bindings
	@defvrx {Scheme Variable} srfi-4-bindings
	@defvrx {Scheme Variable} string-bindings
	@defvrx {Scheme Variable} symbol-bindings
	@defvrx {Scheme Variable} unspecified-bindings
	@defvrx {Scheme Variable} variable-bindings
	@defvrx {Scheme Variable} vector-bindings
	@defvrx {Scheme Variable} version-bindings
	The components of @code{all-pure-bindings}.
	@end defvr

	@defvr {Scheme Variable} mutating-alist-bindings
	@defvrx {Scheme Variable} mutating-array-bindings
	@defvrx {Scheme Variable} mutating-bitvector-bindings
	@defvrx {Scheme Variable} mutating-fluid-bindings
	@defvrx {Scheme Variable} mutating-hash-bindings
	@defvrx {Scheme Variable} mutating-list-bindings
	@defvrx {Scheme Variable} mutating-pair-bindings
	@defvrx {Scheme Variable} mutating-sort-bindings
	@defvrx {Scheme Variable} mutating-srfi-4-bindings
	@defvrx {Scheme Variable} mutating-string-bindings
	@defvrx {Scheme Variable} mutating-variable-bindings
	@defvrx {Scheme Variable} mutating-vector-bindings
	The additional components of @code{all-pure-and-impure-bindings}.
	@end defvr

	Finally, what do you do with a binding set? What is a binding set
	anyway? @code{make-sandbox-module} is here for you.

	@deffn {Scheme Procedure} make-sandbox-module bindings
	Return a fresh module that only contains @var{bindings}.

	The @var{bindings} should be given as a list of import sets. One import
	set is a list whose car names an interface, like @code{(ice-9 q)}, and
	whose cdr is a list of imports. An import is either a bare symbol or a
	pair of @code{(@var{out} . @var{in})}, where @var{out} and @var{in} are
	both symbols and denote the name under which a binding is exported from
	the module, and the name under which to make the binding available,
	respectively.
	@end deffn

	So you see that binding sets are just lists, and
	@code{all-pure-and-impure-bindings} is really just the result of
	appending all of the component binding sets.


	@node REPL Servers
	@subsection REPL Servers

	@cindex REPL server

	The procedures in this section are provided by
	@lisp
	(use-modules (system repl server))
	@end lisp

	When an application is written in Guile, it is often convenient to
	allow the user to be able to interact with it by evaluating Scheme
	expressions in a REPL.

	The procedures of this module allow you to spawn a @dfn{REPL server},
	which permits interaction over a local or TCP connection. Guile itself
	uses them internally to implement the @option{--listen} switch,
	@ref{Command-line Options}.

	@deffn {Scheme Procedure} make-tcp-server-socket [#:host=#f] @
	[#:addr] [#:port=37146]
	Return a stream socket bound to a given address @var{addr} and port
	number @var{port}. If the @var{host} is given, and @var{addr} is not,
	then the @var{host} string is converted to an address. If neither is
	given, we use the loopback address.
	@end deffn

	@deffn {Scheme Procedure} make-unix-domain-server-socket [#:path="/tmp/guile-socket"]
	Return a UNIX domain socket, bound to a given @var{path}.
	@end deffn

	@deffn {Scheme Procedure} run-server [server-socket]
	@deffnx {Scheme Procedure} spawn-server [server-socket]
	Create and run a REPL, making it available over the given
	@var{server-socket}. If @var{server-socket} is not provided, it
	defaults to the socket created by calling @code{make-tcp-server-socket}
	with no arguments.

	@code{run-server} runs the server in the current thread, whereas
	@code{spawn-server} runs the server in a new thread.
	@end deffn

	@deffn {Scheme Procedure} stop-server-and-clients!
	Closes the connection on all running server sockets.

	Please note that in the current implementation, the REPL threads are
	canceled without unwinding their stacks. If any of them are holding
	mutexes or are within a critical section, the results are unspecified.
	@end deffn

	@node Cooperative REPL Servers
	@subsection Cooperative REPL Servers

	@cindex Cooperative REPL server

	The procedures in this section are provided by
	@lisp
	(use-modules (system repl coop-server))
	@end lisp

	Whereas ordinary REPL servers run in their own threads (@pxref{REPL
	Servers}), sometimes it is more convenient to provide REPLs that run at
	specified times within an existing thread, for example in programs
	utilizing an event loop or in single-threaded programs. This allows for
	safe access and mutation of a program's data structures from the REPL,
	without concern for thread synchronization.

	Although the REPLs are run in the thread that calls
	@code{spawn-coop-repl-server} and @code{poll-coop-repl-server},
	dedicated threads are spawned so that the calling thread is not blocked.
	The spawned threads read input for the REPLs and to listen for new
	connections.

	Cooperative REPL servers must be polled periodically to evaluate any
	pending expressions by calling @code{poll-coop-repl-server} with the
	object returned from @code{spawn-coop-repl-server}. The thread that
	calls @code{poll-coop-repl-server} will be blocked for as long as the
	expression takes to be evaluated or if the debugger is entered.

	@deffn {Scheme Procedure} spawn-coop-repl-server [server-socket]
	Create and return a new cooperative REPL server object, and spawn a new
	thread to listen for connections on @var{server-socket}. Proper
	functioning of the REPL server requires that
	@code{poll-coop-repl-server} be called periodically on the returned
	server object.
	@end deffn

	@deffn {Scheme Procedure} poll-coop-repl-server coop-server
	Poll the cooperative REPL server @var{coop-server} and apply a pending
	operation if there is one, such as evaluating an expression typed at the
	REPL prompt. This procedure must be called from the same thread that
	called @code{spawn-coop-repl-server}.
	@end deffn

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