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functions that do not take that parameter with functions that do. The
latter can be problematic: since store operations have side effects
and/or depend on external state, they have to be properly sequenced.
@cindex monadic values
@cindex monadic functions
This is where the @code{(guix monads)} module comes in. This module
provides a framework for working with @dfn{monads}, and a particularly
useful monad for our uses, the @dfn{store monad}. Monads are a
construct that allows two things: associating ``context'' with values
(in our case, the context is the store), and building sequences of
computations (here computations include accesses to the store). Values
in a monad---values that carry this additional context---are called
@dfn{monadic values}; procedures that return such values are called
@dfn{monadic procedures}.
Consider this ``normal'' procedure:
@example
(define (sh-symlink store)
;; Return a derivation that symlinks the 'bash' executable.
(let* ((drv (package-derivation store bash))
(out (derivation->output-path drv))
(sh (string-append out "/bin/bash")))
(build-expression->derivation store "sh"
`(symlink ,sh %output))))
Using @code{(guix monads)} and @code{(guix gexp)}, it may be rewritten
as a monadic function:
(mlet %store-monad ((drv (package->derivation bash)))
(gexp->derivation "sh"
#~(symlink (string-append #$drv "/bin/bash")
#$output))))
There are several things to note in the second version: the @code{store}
parameter is now implicit and is ``threaded'' in the calls to the
@code{package->derivation} and @code{gexp->derivation} monadic
procedures, and the monadic value returned by @code{package->derivation}
is @dfn{bound} using @code{mlet} instead of plain @code{let}.
As it turns out, the call to @code{package->derivation} can even be
omitted since it will take place implicitly, as we will see later
(@pxref{G-Expressions}):
@example
(define (sh-symlink)
(gexp->derivation "sh"
#~(symlink (string-append #$bash "/bin/bash")
#$output)))
@end example
@c <https://syntaxexclamation.wordpress.com/2014/06/26/escaping-continuations/>
@c for the funny quote.
Calling the monadic @code{sh-symlink} has no effect. As someone once
said, ``you exit a monad like you exit a building on fire: by running''.
So, to exit the monad and get the desired effect, one must use
@code{run-with-store}:
(run-with-store (open-connection) (sh-symlink))
@result{} /gnu/store/...-sh-symlink
Note that the @code{(guix monad-repl)} module extends the Guile REPL with
new ``meta-commands'' to make it easier to deal with monadic procedures:
@code{run-in-store}, and @code{enter-store-monad}. The former is used
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to ``run'' a single monadic value through the store:
@example
scheme@@(guile-user)> ,run-in-store (package->derivation hello)
$1 = #<derivation /gnu/store/@dots{}-hello-2.9.drv => @dots{}>
@end example
The latter enters a recursive REPL, where all the return values are
automatically run through the store:
@example
scheme@@(guile-user)> ,enter-store-monad
store-monad@@(guile-user) [1]> (package->derivation hello)
$2 = #<derivation /gnu/store/@dots{}-hello-2.9.drv => @dots{}>
store-monad@@(guile-user) [1]> (text-file "foo" "Hello!")
$3 = "/gnu/store/@dots{}-foo"
store-monad@@(guile-user) [1]> ,q
scheme@@(guile-user)>
@end example
@noindent
Note that non-monadic values cannot be returned in the
@code{store-monad} REPL.
The main syntactic forms to deal with monads in general are provided by
the @code{(guix monads)} module and are described below.
@deffn {Scheme Syntax} with-monad @var{monad} @var{body} ...
Evaluate any @code{>>=} or @code{return} forms in @var{body} as being
in @var{monad}.
@end deffn
@deffn {Scheme Syntax} return @var{val}
Return a monadic value that encapsulates @var{val}.
@end deffn
@deffn {Scheme Syntax} >>= @var{mval} @var{mproc} ...
@dfn{Bind} monadic value @var{mval}, passing its ``contents'' to monadic
procedures @var{mproc}@dots{}@footnote{This operation is commonly
referred to as ``bind'', but that name denotes an unrelated procedure in
Guile. Thus we use this somewhat cryptic symbol inherited from the
Haskell language.}. There can be one @var{mproc} or several of them, as
in this example:
@example
(run-with-state
(with-monad %state-monad
(>>= (return 1)
(lambda (x) (return (+ 1 x)))
(lambda (x) (return (* 2 x)))))
'some-state)
@result{} 4
@result{} some-state
@end example
@end deffn
@deffn {Scheme Syntax} mlet @var{monad} ((@var{var} @var{mval}) ...) @
@var{body} ...
@deffnx {Scheme Syntax} mlet* @var{monad} ((@var{var} @var{mval}) ...) @
@var{body} ...
Bind the variables @var{var} to the monadic values @var{mval} in
@var{body}, which is a sequence of expressions. As with the bind
operator, this can be thought of as ``unpacking'' the raw, non-monadic
value ``contained'' in @var{mval} and making @var{var} refer to that
raw, non-monadic value within the scope of the @var{body}. The form
(@var{var} -> @var{val}) binds @var{var} to the ``normal'' value
@var{val}, as per @code{let}. The binding operations occur in sequence
from left to right. The last expression of @var{body} must be a monadic
expression, and its result will become the result of the @code{mlet} or
@code{mlet*} when run in the @var{monad}.
@code{mlet*} is to @code{mlet} what @code{let*} is to @code{let}
(@pxref{Local Bindings,,, guile, GNU Guile Reference Manual}).
@end deffn
@deffn {Scheme System} mbegin @var{monad} @var{mexp} ...
Bind @var{mexp} and the following monadic expressions in sequence,
returning the result of the last expression. Every expression in the
sequence must be a monadic expression.
This is akin to @code{mlet}, except that the return values of the
monadic expressions are ignored. In that sense, it is analogous to
@code{begin}, but applied to monadic expressions.
@end deffn
@deffn {Scheme System} mwhen @var{condition} @var{mexp0} @var{mexp*} ...
When @var{condition} is true, evaluate the sequence of monadic
expressions @var{mexp0}..@var{mexp*} as in an @code{mbegin}. When
@var{condition} is false, return @code{*unspecified*} in the current
monad. Every expression in the sequence must be a monadic expression.
@end deffn
@deffn {Scheme System} munless @var{condition} @var{mexp0} @var{mexp*} ...
When @var{condition} is false, evaluate the sequence of monadic
expressions @var{mexp0}..@var{mexp*} as in an @code{mbegin}. When
@var{condition} is true, return @code{*unspecified*} in the current
monad. Every expression in the sequence must be a monadic expression.
@end deffn
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@cindex state monad
The @code{(guix monads)} module provides the @dfn{state monad}, which
allows an additional value---the state---to be @emph{threaded} through
monadic procedure calls.
@defvr {Scheme Variable} %state-monad
The state monad. Procedures in the state monad can access and change
the state that is threaded.
Consider the example below. The @code{square} procedure returns a value
in the state monad. It returns the square of its argument, but also
increments the current state value:
@example
(define (square x)
(mlet %state-monad ((count (current-state)))
(mbegin %state-monad
(set-current-state (+ 1 count))
(return (* x x)))))
(run-with-state (sequence %state-monad (map square (iota 3))) 0)
@result{} (0 1 4)
@result{} 3
@end example
When ``run'' through @var{%state-monad}, we obtain that additional state
value, which is the number of @code{square} calls.
@end defvr
@deffn {Monadic Procedure} current-state
Return the current state as a monadic value.
@end deffn
@deffn {Monadic Procedure} set-current-state @var{value}
Set the current state to @var{value} and return the previous state as a
monadic value.
@end deffn
@deffn {Monadic Procedure} state-push @var{value}
Push @var{value} to the current state, which is assumed to be a list,
and return the previous state as a monadic value.
@end deffn
@deffn {Monadic Procedure} state-pop
Pop a value from the current state and return it as a monadic value.
The state is assumed to be a list.
@end deffn
@deffn {Scheme Procedure} run-with-state @var{mval} [@var{state}]
Run monadic value @var{mval} starting with @var{state} as the initial
state. Return two values: the resulting value, and the resulting state.
@end deffn
The main interface to the store monad, provided by the @code{(guix
store)} module, is as follows.
The store monad---an alias for @var{%state-monad}.
Values in the store monad encapsulate accesses to the store. When its
effect is needed, a value of the store monad must be ``evaluated'' by
passing it to the @code{run-with-store} procedure (see below.)
@end defvr
@deffn {Scheme Procedure} run-with-store @var{store} @var{mval} [#:guile-for-build] [#:system (%current-system)]
Run @var{mval}, a monadic value in the store monad, in @var{store}, an
open store connection.
@end deffn
@deffn {Monadic Procedure} text-file @var{name} @var{text} [@var{references}]
Return as a monadic value the absolute file name in the store of the file
containing @var{text}, a string. @var{references} is a list of store items that the
resulting text file refers to; it defaults to the empty list.
@deffn {Monadic Procedure} interned-file @var{file} [@var{name}] @
[#:recursive? #t] [#:select? (const #t)]
Return the name of @var{file} once interned in the store. Use
@var{name} as its store name, or the basename of @var{file} if
@var{name} is omitted.
When @var{recursive?} is true, the contents of @var{file} are added
recursively; if @var{file} designates a flat file and @var{recursive?}
is true, its contents are added, and its permission bits are kept.
When @var{recursive?} is true, call @code{(@var{select?} @var{file}
@var{stat})} for each directory entry, where @var{file} is the entry's
absolute file name and @var{stat} is the result of @code{lstat}; exclude
entries for which @var{select?} does not return true.
The example below adds a file to the store, under two different names:
@example
(run-with-store (open-connection)
(mlet %store-monad ((a (interned-file "README"))
(b (interned-file "README" "LEGU-MIN")))
(return (list a b))))
@result{} ("/gnu/store/rwm@dots{}-README" "/gnu/store/44i@dots{}-LEGU-MIN")
@end example
@end deffn
The @code{(guix packages)} module exports the following package-related
monadic procedures:
@deffn {Monadic Procedure} package-file @var{package} [@var{file}] @
[#:system (%current-system)] [#:target #f] @
value in the absolute file name of @var{file} within the @var{output}
directory of @var{package}. When @var{file} is omitted, return the name
of the @var{output} directory of @var{package}. When @var{target} is
true, use it as a cross-compilation target triplet.
@end deffn
@deffn {Monadic Procedure} package->derivation @var{package} [@var{system}]
@deffnx {Monadic Procedure} package->cross-derivation @var{package} @
@var{target} [@var{system}]
Monadic version of @code{package-derivation} and
@code{package-cross-derivation} (@pxref{Defining Packages}).
@node G-Expressions
@section G-Expressions
@cindex G-expression
@cindex build code quoting
So we have ``derivations'', which represent a sequence of build actions
to be performed to produce an item in the store (@pxref{Derivations}).
These build actions are performed when asking the daemon to actually
build the derivations; they are run by the daemon in a container
(@pxref{Invoking guix-daemon}).
@cindex strata of code
It should come as no surprise that we like to write these build actions
in Scheme. When we do that, we end up with two @dfn{strata} of Scheme
code@footnote{The term @dfn{stratum} in this context was coined by
Manuel Serrano et al.@: in the context of their work on Hop. Oleg
Kiselyov, who has written insightful
@url{http://okmij.org/ftp/meta-programming/#meta-scheme, essays and code
on this topic}, refers to this kind of code generation as
@dfn{staging}.}: the ``host code''---code that defines packages, talks
to the daemon, etc.---and the ``build code''---code that actually
performs build actions, such as making directories, invoking
@command{make}, etc.
To describe a derivation and its build actions, one typically needs to
embed build code inside host code. It boils down to manipulating build
code as data, and the homoiconicity of Scheme---code has a direct
representation as data---comes in handy for that. But we need more than
the normal @code{quasiquote} mechanism in Scheme to construct build
expressions.
The @code{(guix gexp)} module implements @dfn{G-expressions}, a form of
S-expressions adapted to build expressions. G-expressions, or
@dfn{gexps}, consist essentially of three syntactic forms: @code{gexp},
@code{ungexp}, and @code{ungexp-splicing} (or simply: @code{#~},
@code{#$}, and @code{#$@@}), which are comparable to
@code{quasiquote}, @code{unquote}, and @code{unquote-splicing},
respectively (@pxref{Expression Syntax, @code{quasiquote},, guile,
GNU Guile Reference Manual}). However, there are major differences:
@itemize
@item
Gexps are meant to be written to a file and run or manipulated by other
processes.
@item
When a high-level object such as a package or derivation is unquoted
inside a gexp, the result is as if its output file name had been
introduced.
@item
Gexps carry information about the packages or derivations they refer to,
and these dependencies are automatically added as inputs to the build
processes that use them.
@end itemize
@cindex lowering, of high-level objects in gexps
This mechanism is not limited to package and derivation
objects: @dfn{compilers} able to ``lower'' other high-level objects to
derivations or files in the store can be defined,
such that these objects can also be inserted
into gexps. For example, a useful type of high-level objects that can be
inserted in a gexp is ``file-like objects'', which make it easy to
derivations and such (see @code{local-file} and @code{plain-file}
below.)
To illustrate the idea, here is an example of a gexp:
@example
(define build-exp
#~(begin
(mkdir #$output)
(chdir #$output)
(symlink (string-append #$coreutils "/bin/ls")
"list-files")))
@end example
This gexp can be passed to @code{gexp->derivation}; we obtain a
derivation that builds a directory containing exactly one symlink to
@file{/gnu/store/@dots{}-coreutils-8.22/bin/ls}:
@example
(gexp->derivation "the-thing" build-exp)
@end example
As one would expect, the @code{"/gnu/store/@dots{}-coreutils-8.22"} string is
substituted to the reference to the @var{coreutils} package in the
actual build code, and @var{coreutils} is automatically made an input to
the derivation. Likewise, @code{#$output} (equivalent to @code{(ungexp
output)}) is replaced by a string containing the directory name of the
output of the derivation.
@cindex cross compilation
In a cross-compilation context, it is useful to distinguish between
references to the @emph{native} build of a package---that can run on the
host---versus references to cross builds of a package. To that end, the
@code{#+} plays the same role as @code{#$}, but is a reference to a
native package build:
@example
(gexp->derivation "vi"
#~(begin
(mkdir #$output)
(system* (string-append #+coreutils "/bin/ln")
"-s"
(string-append #$emacs "/bin/emacs")
(string-append #$output "/bin/vi")))
#:target "mips64el-linux-gnu")
@end example
@noindent
In the example above, the native build of @var{coreutils} is used, so
that @command{ln} can actually run on the host; but then the
cross-compiled build of @var{emacs} is referenced.
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@cindex imported modules, for gexps
@findex with-imported-modules
Another gexp feature is @dfn{imported modules}: sometimes you want to be
able to use certain Guile modules from the ``host environment'' in the
gexp, so those modules should be imported in the ``build environment''.
The @code{with-imported-modules} form allows you to express that:
@example
(let ((build (with-imported-modules '((guix build utils))
#~(begin
(use-modules (guix build utils))
(mkdir-p (string-append #$output "/bin"))))))
(gexp->derivation "empty-dir"
#~(begin
#$build
(display "success!\n")
#t)))
@end example
@noindent
In this example, the @code{(guix build utils)} module is automatically
pulled into the isolated build environment of our gexp, such that
@code{(use-modules (guix build utils))} works as expected.
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@cindex module closure
@findex source-module-closure
Usually you want the @emph{closure} of the module to be imported---i.e.,
the module itself and all the modules it depends on---rather than just
the module; failing to do that, attempts to use the module will fail
because of missing dependent modules. The @code{source-module-closure}
procedure computes the closure of a module by looking at its source file
headers, which comes in handy in this case:
@example
(use-modules (guix modules)) ;for 'source-module-closure'
(with-imported-modules (source-module-closure
'((guix build utils)
(gnu build vm)))
(gexp->derivation "something-with-vms"
#~(begin
(use-modules (guix build utils)
(gnu build vm))
@dots{})))
@end example
The syntactic form to construct gexps is summarized below.
@deffn {Scheme Syntax} #~@var{exp}
@deffnx {Scheme Syntax} (gexp @var{exp})
Return a G-expression containing @var{exp}. @var{exp} may contain one
or more of the following forms:
@table @code
@item #$@var{obj}
@itemx (ungexp @var{obj})
Introduce a reference to @var{obj}. @var{obj} may have one of the
supported types, for example a package or a
derivation, in which case the @code{ungexp} form is replaced by its
output file name---e.g., @code{"/gnu/store/@dots{}-coreutils-8.22}.
If @var{obj} is a list, it is traversed and references to supported
objects are substituted similarly.
If @var{obj} is another gexp, its contents are inserted and its
dependencies are added to those of the containing gexp.
If @var{obj} is another kind of object, it is inserted as is.
@item #$@var{obj}:@var{output}
@itemx (ungexp @var{obj} @var{output})
This is like the form above, but referring explicitly to the
@var{output} of @var{obj}---this is useful when @var{obj} produces
multiple outputs (@pxref{Packages with Multiple Outputs}).
@item #+@var{obj}
@itemx #+@var{obj}:output
@itemx (ungexp-native @var{obj})
@itemx (ungexp-native @var{obj} @var{output})
Same as @code{ungexp}, but produces a reference to the @emph{native}
build of @var{obj} when used in a cross compilation context.
@item #$output[:@var{output}]
@itemx (ungexp output [@var{output}])
Insert a reference to derivation output @var{output}, or to the main
output when @var{output} is omitted.
This only makes sense for gexps passed to @code{gexp->derivation}.
@item #$@@@var{lst}
@itemx (ungexp-splicing @var{lst})
Like the above, but splices the contents of @var{lst} inside the
containing list.
@item #+@@@var{lst}
@itemx (ungexp-native-splicing @var{lst})
Like the above, but refers to native builds of the objects listed in
@var{lst}.
@end table
G-expressions created by @code{gexp} or @code{#~} are run-time objects
of the @code{gexp?} type (see below.)
@end deffn
@deffn {Scheme Syntax} with-imported-modules @var{modules} @var{body}@dots{}
Mark the gexps defined in @var{body}@dots{} as requiring @var{modules}
in their execution environment.
Each item in @var{modules} can be the name of a module, such as
@code{(guix build utils)}, or it can be a module name, followed by an
arrow, followed by a file-like object:
@example
`((guix build utils)
(guix gcrypt)
((guix config) => ,(scheme-file "config.scm"
#~(define-module @dots{}))))
@end example
@noindent
In the example above, the first two modules are taken from the search
path, and the last one is created from the given file-like object.
This form has @emph{lexical} scope: it has an effect on the gexps
directly defined in @var{body}@dots{}, but not on those defined, say, in
procedures called from @var{body}@dots{}.
@end deffn
@deffn {Scheme Procedure} gexp? @var{obj}
Return @code{#t} if @var{obj} is a G-expression.
@end deffn
G-expressions are meant to be written to disk, either as code building
some derivation, or as plain files in the store. The monadic procedures
below allow you to do that (@pxref{The Store Monad}, for more
information about monads.)
@deffn {Monadic Procedure} gexp->derivation @var{name} @var{exp} @
[#:system (%current-system)] [#:target #f] [#:graft? #t] @
[#:hash #f] [#:hash-algo #f] @
[#:recursive? #f] [#:env-vars '()] [#:modules '()] @
[#:module-path @var{%load-path}] @
[#:references-graphs #f] [#:allowed-references #f] @
[#:leaked-env-vars #f] @
[#:script-name (string-append @var{name} "-builder")] @
[#:local-build? #f] [#:substitutable? #t] [#:guile-for-build #f]
Return a derivation @var{name} that runs @var{exp} (a gexp) with
@var{guile-for-build} (a derivation) on @var{system}; @var{exp} is
stored in a file called @var{script-name}. When @var{target} is true,
it is used as the cross-compilation target triplet for packages referred
to by @var{exp}.
@var{modules} is deprecated in favor of @code{with-imported-modules}.
Its meaning is to
make @var{modules} available in the evaluation context of @var{exp};
@var{modules} is a list of names of Guile modules searched in
@var{module-path} to be copied in the store, compiled, and made available in
the load path during the execution of @var{exp}---e.g., @code{((guix
build utils) (guix build gnu-build-system))}.
@var{graft?} determines whether packages referred to by @var{exp} should be grafted when
applicable.
When @var{references-graphs} is true, it must be a list of tuples of one of the
following forms:
@example
(@var{file-name} @var{package})
(@var{file-name} @var{package} @var{output})
(@var{file-name} @var{derivation})
(@var{file-name} @var{derivation} @var{output})
(@var{file-name} @var{store-item})
@end example
The right-hand-side of each element of @var{references-graphs} is automatically made
an input of the build process of @var{exp}. In the build environment, each
@var{file-name} contains the reference graph of the corresponding item, in a simple
text format.
@var{allowed-references} must be either @code{#f} or a list of output names and packages.
In the latter case, the list denotes store items that the result is allowed to
refer to. Any reference to another store item will lead to a build error.
Similarly for @var{disallowed-references}, which can list items that must not be
referenced by the outputs.
The other arguments are as for @code{derivation} (@pxref{Derivations}).
The @code{local-file}, @code{plain-file}, @code{computed-file},
@code{program-file}, and @code{scheme-file} procedures below return
@dfn{file-like objects}. That is, when unquoted in a G-expression,
these objects lead to a file in the store. Consider this G-expression:
#~(system* #$(file-append glibc "/sbin/nscd") "-f"
#$(local-file "/tmp/my-nscd.conf"))
@end example
The effect here is to ``intern'' @file{/tmp/my-nscd.conf} by copying it
to the store. Once expanded, for instance @i{via}
@code{gexp->derivation}, the G-expression refers to that copy under
@file{/gnu/store}; thus, modifying or removing the file in @file{/tmp}
does not have any effect on what the G-expression does.
@code{plain-file} can be used similarly; it differs in that the file
content is directly passed as a string.
@deffn {Scheme Procedure} local-file @var{file} [@var{name}] @
[#:recursive? #f] [#:select? (const #t)]
Return an object representing local file @var{file} to add to the store; this
object can be used in a gexp. If @var{file} is a relative file name, it is looked
up relative to the source file where this form appears. @var{file} will be added to
the store under @var{name}--by default the base name of @var{file}.
When @var{recursive?} is true, the contents of @var{file} are added recursively; if @var{file}
designates a flat file and @var{recursive?} is true, its contents are added, and its
permission bits are kept.
When @var{recursive?} is true, call @code{(@var{select?} @var{file}
@var{stat})} for each directory entry, where @var{file} is the entry's
absolute file name and @var{stat} is the result of @code{lstat}; exclude
entries for which @var{select?} does not return true.
This is the declarative counterpart of the @code{interned-file} monadic
procedure (@pxref{The Store Monad, @code{interned-file}}).
@end deffn
@deffn {Scheme Procedure} plain-file @var{name} @var{content}
Return an object representing a text file called @var{name} with the given
@var{content} (a string) to be added to the store.
This is the declarative counterpart of @code{text-file}.
@end deffn
@deffn {Scheme Procedure} computed-file @var{name} @var{gexp} @
[#:options '(#:local-build? #t)]
Return an object representing the store item @var{name}, a file or
directory computed by @var{gexp}. @var{options}
is a list of additional arguments to pass to @code{gexp->derivation}.
This is the declarative counterpart of @code{gexp->derivation}.
@end deffn
@deffn {Monadic Procedure} gexp->script @var{name} @var{exp}
Return an executable script @var{name} that runs @var{exp} using
@var{guile}, with @var{exp}'s imported modules in its search path.
The example below builds a script that simply invokes the @command{ls}
command:
@example
(use-modules (guix gexp) (gnu packages base))
(gexp->script "list-files"
#~(execl #$(file-append coreutils "/bin/ls")
"ls"))
@end example
When ``running'' it through the store (@pxref{The Store Monad,
@code{run-with-store}}), we obtain a derivation that produces an
executable file @file{/gnu/store/@dots{}-list-files} along these lines:
@example
#!/gnu/store/@dots{}-guile-2.0.11/bin/guile -ds
!#
(execl "/gnu/store/@dots{}-coreutils-8.22"/bin/ls" "ls")
@deffn {Scheme Procedure} program-file @var{name} @var{exp} @
[#:guile #f]
Return an object representing the executable store item @var{name} that
runs @var{gexp}. @var{guile} is the Guile package used to execute that
script.
This is the declarative counterpart of @code{gexp->script}.
@end deffn
@deffn {Monadic Procedure} gexp->file @var{name} @var{exp} @
[#:set-load-path? #t]
Return a derivation that builds a file @var{name} containing @var{exp}.
When @var{set-load-path?} is true, emit code in the resulting file to
set @code{%load-path} and @code{%load-compiled-path} to honor
@var{exp}'s imported modules.
The resulting file holds references to all the dependencies of @var{exp}
or a subset thereof.
@end deffn
@deffn {Scheme Procedure} scheme-file @var{name} @var{exp}
Return an object representing the Scheme file @var{name} that contains
@var{exp}.
This is the declarative counterpart of @code{gexp->file}.
@end deffn
@deffn {Monadic Procedure} text-file* @var{name} @var{text} @dots{}
Return as a monadic value a derivation that builds a text file
containing all of @var{text}. @var{text} may list, in addition to
strings, objects of any type that can be used in a gexp: packages,
derivations, local file objects, etc. The resulting store file holds
references to all these.
This variant should be preferred over @code{text-file} anytime the file
to create will reference items from the store. This is typically the
case when building a configuration file that embeds store file names,
like this:
@example
(define (profile.sh)
;; Return the name of a shell script in the store that
;; initializes the 'PATH' environment variable.
(text-file* "profile.sh"
"export PATH=" coreutils "/bin:"
grep "/bin:" sed "/bin\n"))
@end example
In this example, the resulting @file{/gnu/store/@dots{}-profile.sh} file
will reference @var{coreutils}, @var{grep}, and @var{sed}, thereby
preventing them from being garbage-collected during its lifetime.
@end deffn
@deffn {Scheme Procedure} mixed-text-file @var{name} @var{text} @dots{}
Return an object representing store file @var{name} containing
@var{text}. @var{text} is a sequence of strings and file-like objects,
as in:
@example
(mixed-text-file "profile"
"export PATH=" coreutils "/bin:" grep "/bin")
@end example
This is the declarative counterpart of @code{text-file*}.
@end deffn
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@deffn {Scheme Procedure} file-append @var{obj} @var{suffix} @dots{}
Return a file-like object that expands to the concatenation of @var{obj}
and @var{suffix}, where @var{obj} is a lowerable object and each
@var{suffix} is a string.
As an example, consider this gexp:
@example
(gexp->script "run-uname"
#~(system* #$(file-append coreutils
"/bin/uname")))
@end example
The same effect could be achieved with:
@example
(gexp->script "run-uname"
#~(system* (string-append #$coreutils
"/bin/uname")))
@end example
There is one difference though: in the @code{file-append} case, the
resulting script contains the absolute file name as a string, whereas in
the second case, the resulting script contains a @code{(string-append
@dots{})} expression to construct the file name @emph{at run time}.
@end deffn
Of course, in addition to gexps embedded in ``host'' code, there are
also modules containing build tools. To make it clear that they are
meant to be used in the build stratum, these modules are kept in the
@code{(guix build @dots{})} name space.
@cindex lowering, of high-level objects in gexps
Internally, high-level objects are @dfn{lowered}, using their compiler,
to either derivations or store items. For instance, lowering a package
yields a derivation, and lowering a @code{plain-file} yields a store
item. This is achieved using the @code{lower-object} monadic procedure.
@deffn {Monadic Procedure} lower-object @var{obj} [@var{system}] @
[#:target #f]
Return as a value in @var{%store-monad} the derivation or store item
corresponding to @var{obj} for @var{system}, cross-compiling for
@var{target} if @var{target} is true. @var{obj} must be an object that
has an associated gexp compiler, such as a @code{<package>}.
@end deffn
@c *********************************************************************
@node Utilities
@chapter Utilities
This section describes Guix command-line utilities. Some of them are
primarily targeted at developers and users who write new package
definitions, while others are more generally useful. They complement
the Scheme programming interface of Guix in a convenient way.
* Invoking guix build:: Building packages from the command line.
* Invoking guix download:: Downloading a file and printing its hash.
* Invoking guix hash:: Computing the cryptographic hash of a file.
* Invoking guix import:: Importing package definitions.
* Invoking guix refresh:: Updating package definitions.
* Invoking guix lint:: Finding errors in package definitions.
* Invoking guix graph:: Visualizing the graph of packages.
* Invoking guix environment:: Setting up development environments.
* Invoking guix publish:: Sharing substitutes.
* Invoking guix challenge:: Challenging substitute servers.
* Invoking guix copy:: Copying to and from a remote store.
* Invoking guix container:: Process isolation.
@node Invoking guix build
@section Invoking @command{guix build}
@cindex package building
@cindex @command{guix build}
The @command{guix build} command builds packages or derivations and
their dependencies, and prints the resulting store paths. Note that it
does not modify the user's profile---this is the job of the
@command{guix package} command (@pxref{Invoking guix package}). Thus,
it is mainly useful for distribution developers.
The general syntax is:
guix build @var{options} @var{package-or-derivation}@dots{}
As an example, the following command builds the latest versions of Emacs
and of Guile, displays their build logs, and finally displays the
resulting directories:
@example
guix build emacs guile
@end example
Similarly, the following command builds all the available packages:
@example
`guix package -A | cut -f1,2 --output-delimiter=@@`
@end example
@var{package-or-derivation} may be either the name of a package found in
the software distribution such as @code{coreutils} or
@file{/gnu/store/@dots{}-coreutils-8.19.drv}. In the former case, a
package with the corresponding name (and optionally version) is searched
for among the GNU distribution modules (@pxref{Package Modules}).
Alternatively, the @code{--expression} option may be used to specify a
Scheme expression that evaluates to a package; this is useful when
disambiguating among several same-named packages or package variants is
needed.
There may be zero or more @var{options}. The available options are
described in the subsections below.
@menu
* Common Build Options:: Build options for most commands.
* Package Transformation Options:: Creating variants of packages.
* Additional Build Options:: Options specific to 'guix build'.
* Debugging Build Failures:: Real life packaging experience.
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@end menu
@node Common Build Options
@subsection Common Build Options
A number of options that control the build process are common to
@command{guix build} and other commands that can spawn builds, such as
@command{guix package} or @command{guix archive}. These are the
following:
@table @code
@item --load-path=@var{directory}
@itemx -L @var{directory}
Add @var{directory} to the front of the package module search path
(@pxref{Package Modules}).
This allows users to define their own packages and make them visible to
the command-line tools.
@item --keep-failed
@itemx -K
Keep the build tree of failed builds. Thus, if a build fails, its build
tree is kept under @file{/tmp}, in a directory whose name is shown at
the end of the build log. This is useful when debugging build issues.
@xref{Debugging Build Failures}, for tips and tricks on how to debug
build issues.
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@item --keep-going
@itemx -k
Keep going when some of the derivations fail to build; return only once
all the builds have either completed or failed.
The default behavior is to stop as soon as one of the specified
derivations has failed.
@item --dry-run
@itemx -n
Do not build the derivations.
@item --fallback
When substituting a pre-built binary fails, fall back to building
packages locally.
@item --substitute-urls=@var{urls}
@anchor{client-substitute-urls}
Consider @var{urls} the whitespace-separated list of substitute source
URLs, overriding the default list of URLs of @command{guix-daemon}
(@pxref{daemon-substitute-urls,, @command{guix-daemon} URLs}).
This means that substitutes may be downloaded from @var{urls}, provided
they are signed by a key authorized by the system administrator
(@pxref{Substitutes}).
When @var{urls} is the empty string, substitutes are effectively
disabled.
@item --no-substitutes
Do not use substitutes for build products. That is, always build things
locally instead of allowing downloads of pre-built binaries
(@pxref{Substitutes}).
@item --no-grafts
Do not ``graft'' packages. In practice, this means that package updates
available as grafts are not applied. @xref{Security Updates}, for more
information on grafts.
@item --rounds=@var{n}
Build each derivation @var{n} times in a row, and raise an error if
consecutive build results are not bit-for-bit identical.
This is a useful way to detect non-deterministic builds processes.
Non-deterministic build processes are a problem because they make it
practically impossible for users to @emph{verify} whether third-party
binaries are genuine. @xref{Invoking guix challenge}, for more.
Note that, currently, the differing build results are not kept around,
so you will have to manually investigate in case of an error---e.g., by
stashing one of the build results with @code{guix archive --export}
(@pxref{Invoking guix archive}), then rebuilding, and finally comparing
the two results.
@item --no-build-hook
Do not attempt to offload builds @i{via} the ``build hook'' of the daemon
(@pxref{Daemon Offload Setup}). That is, always build things locally
instead of offloading builds to remote machines.
@item --max-silent-time=@var{seconds}
When the build or substitution process remains silent for more than
@var{seconds}, terminate it and report a build failure.
By default, the daemon's setting is honored (@pxref{Invoking
guix-daemon, @code{--max-silent-time}}).
@item --timeout=@var{seconds}
Likewise, when the build or substitution process lasts for more than
@var{seconds}, terminate it and report a build failure.
By default, the daemon's setting is honored (@pxref{Invoking
guix-daemon, @code{--timeout}}).
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@item --verbosity=@var{level}
Use the given verbosity level. @var{level} must be an integer between 0
and 5; higher means more verbose output. Setting a level of 4 or more
may be helpful when debugging setup issues with the build daemon.
@item --cores=@var{n}
@itemx -c @var{n}
Allow the use of up to @var{n} CPU cores for the build. The special
value @code{0} means to use as many CPU cores as available.
@item --max-jobs=@var{n}
@itemx -M @var{n}
Allow at most @var{n} build jobs in parallel. @xref{Invoking
guix-daemon, @code{--max-jobs}}, for details about this option and the
equivalent @command{guix-daemon} option.
@end table
Behind the scenes, @command{guix build} is essentially an interface to
the @code{package-derivation} procedure of the @code{(guix packages)}
module, and to the @code{build-derivations} procedure of the @code{(guix
derivations)} module.