On this page:
require
only-in
except-in
prefix-in
rename-in
combine-in
relative-in
only-meta-in
lib
file
planet
submod
local-require
provide
all-defined-out
all-from-out
rename-out
except-out
prefix-out
struct-out
combine-out
protect-out
for-meta
for-syntax
for-template
for-label
#%require
#%provide
3.2.1 Additional require Forms
matching-identifiers-in
subtract-in
filtered-in
path-up
multi-in
3.2.2 Additional provide Forms
matching-identifiers-out
filtered-out

3.2 Importing and Exporting: require and provide

+Imports: require in The Racket Guide introduces require.

syntax

(require require-spec ...)

 
require-spec = module-path
  | (only-in require-spec id-maybe-renamed ...)
  | (except-in require-spec id ...)
  | (prefix-in prefix-id require-spec)
  | (rename-in require-spec [orig-id bind-id] ...)
  | (combine-in require-spec ...)
  | (relative-in module-path require-spec ...)
  | (only-meta-in phase-level require-spec ...)
  | (for-syntax require-spec ...)
  | (for-template require-spec ...)
  | (for-label require-spec ...)
  | (for-meta phase-level require-spec ...)
  | derived-require-spec
     
module-path = root-module-path
  | (submod root-module-path submod-path-element ...)
  | (submod "." submod-path-element ...)
  | (submod ".." submod-path-element ...)
     
root-module-path = (quote id)
  | rel-string
  | (lib rel-string ...+)
  | id
  | (file string)
  | (planet id)
  | (planet string)
  | 
(planet rel-string
        (user-string pkg-string vers)
        rel-string ...)
     
submod-path-element = id
  | ".."
     
id-maybe-renamed = id
  | [orig-id bind-id]
     
phase-level = exact-integer
  | #f
     
vers = 
  | nat
  | nat minor-vers
     
minor-vers = nat
  | (nat nat)
  | (= nat)
  | (+ nat)
  | (- nat)
In a top-level context, require instantiates modules (see Modules and Module-Level Variables). In a top-level context or module context, expansion of require visits modules (see Module Expansion, Phases, and Visits). In both contexts and both evaluation and expansion, require introduces bindings into a namespace or a module (see Introducing Bindings). A require form in a expression context or internal-definition context is a syntax error.

A require-spec designates a particular set of identifiers to be bound in the importing context. Each identifier is mapped to a particular export of a particular module; the identifier to bind may be different from the symbolic name of the originally exported identifier. Each identifier also binds at a particular phase level.

No identifier can be bound multiple times in a given phase level by an import, unless all of the bindings refer to the same original definition in the same module. In a module context, an identifier can be either imported or defined for a given phase level, but not both.

The syntax of require-spec can be extended via define-require-syntax, and when multiple require-specs are specified in a require, the bindings of each require-spec are visible for expanding later require-specs. The pre-defined forms (as exported by racket/base) are as follows:

module-path

Imports all exported bindings from the named module, using the export identifiers as the local identifiers. (See below for information on module-path.) The lexical context of the module-path form determines the context of the introduced identifiers.

syntax

(only-in require-spec id-maybe-renamed ...)

Like require-spec, but constrained to those exports for which the identifiers to bind match id-maybe-renamed: as id or as orig-id in [orig-id bind-id]. If the id or orig-id of any id-maybe-renamed is not in the set that require-spec describes, a syntax error is reported.

Examples:
> (require (only-in racket/tcp
                    tcp-listen
                    [tcp-accept my-accept]))
> tcp-listen

#<procedure:tcp-listen>

> my-accept

#<procedure:tcp-accept>

> tcp-accept

tcp-accept: undefined;

 cannot reference an identifier before its definition

  in module: top-level

syntax

(except-in require-spec id ...)

Like require-spec, but omitting those imports for which ids are the identifiers to bind; if any id is not in the set that require-spec describes, a syntax error is reported.

Examples:
> (require (except-in racket/tcp
                      tcp-listen))
> tcp-accept

#<procedure:tcp-accept>

> tcp-listen

tcp-listen: undefined;

 cannot reference an identifier before its definition

  in module: top-level

syntax

(prefix-in prefix-id require-spec)

Like require-spec, but adjusting each identifier to be bound by prefixing it with prefix-id. The lexical context of the prefix-id is ignored, and instead preserved from the identifiers before prefixing.

Examples:
> (require (prefix-in tcp: racket/tcp))
> tcp:tcp-accept

#<procedure:tcp-accept>

> tcp:tcp-listen

#<procedure:tcp-listen>

syntax

(rename-in require-spec [orig-id bind-id] ...)

Like require-spec, but replacing the identifier to bind orig-id with bind-id; if any orig-id is not in the set that require-spec describes, a syntax error is reported.

Examples:
> (require (rename-in racket/tcp
                      (tcp-accept accept)
                      (tcp-listen listen)))
> accept

#<procedure:tcp-accept>

> listen

#<procedure:tcp-listen>

syntax

(combine-in require-spec ...)

The union of the require-specs. If two or more imports from the require-specs have the same identifier name but they do not refer to the same original binding, a syntax error is reported.

Examples:
> (require (combine-in (only-in racket/tcp tcp-accept)
                       (only-in racket/tcp tcp-listen)))
> tcp-accept

#<procedure:tcp-accept>

> tcp-listen

#<procedure:tcp-listen>

syntax

(relative-in module-path require-spec ...)

Like the union of the require-specs, but each relative module path in a require-spec is treated as relative to module-path instead of the enclosing context.

The require transformer that implements relative-in sets current-require-module-path to adjust module paths in the require-specs.

syntax

(only-meta-in phase-level require-spec ...)

Like the combination of require-specs, but removing any binding that is not for phase-level, where #f for phase-level corresponds to the label phase level.

The following example imports bindings only at phase level 1, the transform phase:

> (module nest racket
    (provide (for-syntax meta-eggs)
             (for-meta 1 meta-chicks)
             num-eggs)
    (define-for-syntax meta-eggs 2)
    (define-for-syntax meta-chicks 3)
    (define num-eggs 2))
> (require (only-meta-in 1 'nest))
> (define-syntax (desc stx)
    (printf "~s ~s\n" meta-eggs meta-chicks)
    #'(void))
> (desc)

2 3

> num-eggs

num-eggs: undefined;

 cannot reference an identifier before its definition

  in module: top-level

The following example imports only bindings at phase level 0, the normal phase.

> (require (only-meta-in 0 'nest))
> num-eggs

2

(for-meta phase-level require-spec ...)

Like the combination of require-specs, but the binding specified by each require-spec is shifted by phase-level. The label phase level corresponds to #f, and a shifting combination that involves #f produces #f.

Examples:
> (module nest racket
    (provide num-eggs)
    (define num-eggs 2))
> (require (for-meta 0 'nest))
> num-eggs

2

> (require (for-meta 1 'nest))
> (define-syntax (roost stx)
    (datum->syntax stx num-eggs))
> (roost)

2

(for-syntax require-spec ...)

Same as (for-meta 1 require-spec ...).

(for-template require-spec ...)

Same as (for-meta -1 require-spec ...).

(for-label require-spec ...)

Same as (for-meta #f require-spec ...). If an identifier in any of the require-specs is bound at more than one phase level, a syntax error is reported.

derived-require-spec

See define-require-syntax for information on expanding the set of require-spec forms.

+Module Paths in The Racket Guide introduces module paths.

A module-path identifies a module, either a root module or a submodule that is declared lexically within another module. A root module is identified either through a concrete name in the form of an identifier, or through an indirect name that can trigger automatic loading of the module declaration. Except for the (quote id) case below, the actual resolution of a root module path is up to the current module name resolver (see current-module-name-resolver), and the description below corresponds to the default module name resolver.

(quote id)

Refers to a submodule previously declared with the name id or a module previously declared interactively with the name id. When id refers to a submodule, (quote id) is equivalent to (submod "." id).

Examples:
; a module declared interactively as test:
> (require 'test)

rel-string

A path relative to the containing source (as determined by current-load-relative-directory or current-directory). Regardless of the current platform, rel-string is always parsed as a Unix-format relative path: / is the path delimiter (multiple adjacent /s are not allowed), .. accesses the parent directory, and . accesses the current directory. The path cannot be empty or contain a leading or trailing slash, path elements before than the last one cannot include a file suffix (i.e., a . in an element other than . or ..), and the only allowed characters are ASCII letters, ASCII digits, -, +, _, ., /, and %. Furthermore, a % is allowed only when followed by two lowercase hexadecimal digits, and the digits must form a number that is not the ASCII value of a letter, digit, -, +, or _.

The % provision is intended to support a one-to-one encoding of arbitrary strings as path elements (after UTF-8 encoding). Such encodings are not decoded to arrive at a filename, but instead preserved in the file access.

If rel-string ends with a ".ss" suffix, it is converted to a ".rkt" suffix. The compiled-load handler may reverse that conversion if a ".rkt" file does not exist and a ".ss" exists.

Examples:
; a module named "x.rkt" in the same
; directory as the enclosing module's file:
> (require "x.rkt")
; a module named "x.rkt" in the parent directory
; of the enclosing module file's directory:
> (require "../x.rkt")

syntax

(lib rel-string ...+)

A path to a module installed into a collection (see Libraries and Collections). The rel-strings in lib are constrained similar to the plain rel-string case, with the additional constraint that a rel-string cannot contain . or .. directory indicators.

The specific interpretation of the path depends on the number and shape of the rel-strings:

  • If a single rel-string is provided, and if it consists of a single element (i.e., no /) with no file suffix (i.e., no .), then rel-string names a collection, and "main.rkt" is the library file name.

    Examples:
    ; the main swindle library:
    > (require (lib "swindle"))
    ; the same:
    > (require (lib "swindle/main.rkt"))

  • If a single rel-string is provided, and if it consists of multiple /-separated elements, then each element up to the last names a collection, subcollection, etc., and the last element names a file. If the last element has no file suffix, ".rkt" is added, while a ".ss" suffix is converted to ".rkt".

    Examples:
    ; "turbo.rkt" from the "swindle" collection:
    > (require (lib "swindle/turbo"))
    ; the same:
    > (require (lib "swindle/turbo.rkt"))
    ; the same:
    > (require (lib "swindle/turbo.ss"))

  • If a single rel-string is provided, and if it consists of a single element with a file suffix (i.e, with a .), then rel-string names a file within the "mzlib" collection. A ".ss" suffix is converted to ".rkt". (This convention is for compatibility with older version of Racket.)

    Examples:
    ; "tar.rkt" module from the "mzlib" collection:
    > (require (lib "tar.ss"))

  • Otherwise, when multiple rel-strings are provided, the first rel-string is effectively moved after the others, and all rel-strings are appended with / separators. The resulting path names a collection, then subcollection, etc., ending with a file name. No suffix is added automatically, but a ".ss" suffix is converted to ".rkt". (This convention is for compatibility with older version of Racket.)

    Examples:
    ; "tar.rkt" module from the "mzlib" collection:
    > (require (lib "tar.ss" "mzlib"))

id

A shorthand for a lib form with a single rel-string whose characters are the same as in the symbolic form of id. In addition to the constraints of a lib rel-string, id must not contain ..

Example:
> (require racket/tcp)

syntax

(file string)

Similar to the plain rel-string case, but string is a path—possibly absolute—using the current platform’s path conventions and expand-user-path. A ".ss" suffix is converted to ".rkt".

Example:
> (require (file "~/tmp/x.rkt"))

syntax

(planet id)

(planet string)
(planet rel-string (user-string pkg-string vers)
        rel-string ...)
Specifies a library available via the PLaneT server.

The first form is a shorthand for the last one, where the id’s character sequence must match the following spec grammar:

 

spec

 ::= 

owner / pkg lib

 

owner

 ::= 

elem

 

pkg

 ::= 

elem  |  elem : version

 

version

 ::= 

int  |  int : minor

 

minor

 ::= 

int  |  <= int  |  >= int  |  = int

 

  |  

int - int

 

lib

 ::= 

empty  |  / path

 

path

 ::= 

elem  |  elem / path

and where an elem is a non-empty sequence of characters that are ASCII letters, ASCII digits, -, +, _, or % followed by lowercase hexadecimal digits (that do not encode one of the other allowed characters), and an int is a non-empty sequence of ASCII digits. As this shorthand is expended, a ".plt" extension is added to pkg, and a ".rkt" extension is added to path; if no path is included, "main.rkt" is used in the expansion.

A (planet string) form is like a (planet id) form with the identifier converted to a string, except that the string can optionally end with a file extension (i.e., a .) for a path. A ".ss" file extension is converted to ".rkt".

In the more general last form of a planet module path, the rel-strings are similar to the lib form, except that the (user-string pkg-string vers) names a PLaneT-based package instead of a collection. A version specification can include an optional major and minor version, where the minor version can be a specific number or a constraint: (nat nat) specifies an inclusive range, (= nat) specifies an exact match, (+ nat) specifies a minimum version and is equivalent to just nat, and (- nat) specifies a maximum version. The =, +, and - identifiers in a minor-version constraint are recognized symbolically.

Examples:
; "main.rkt" in package "farm" by "mcdonald":
> (require (planet mcdonald/farm))
; "main.rkt" in version >= 2.0 of "farm" by "mcdonald":
> (require (planet mcdonald/farm:2))
; "main.rkt" in version >= 2.5 of "farm" by "mcdonald":
> (require (planet mcdonald/farm:2:5))
; "duck.rkt" in version >= 2.5 of "farm" by "mcdonald":
> (require (planet mcdonald/farm:2:5/duck))

syntax

(submod root-module-path submod-path-element ...)

(submod "." submod-path-element ...)
(submod ".." submod-path-element ...)
Identifies a submodule within the module specified by root-module-path or relative to the current module in the case of (submod "." ....), where (submod ".." submod-path-element ...) is equivalent to (submod "." ".." submod-path-element ...). Submodules have symbolic names, and a sequence of identifiers as submod-path-elements determine a path of successively nested submodules with the given names. A ".." as a submod-path-element names the enclosing module of a submodule, and it’s intended for use in (submod "." ....) and (submod ".." ....) forms.

As require prepares to handle a sequence of require-specs, it logs a “prefetch” message to the current logger at the 'info level, using the name 'module-prefetch, and including message data that is a list of two elements: a list of module paths that appear to be imported, and a directory path to use for relative module paths. The logged list of module paths may be incomplete, but a compilation manager can use approximate prefetch information to start on compilations in parallel.

Changed in version 6.0.1.10 of package base: Added prefetch logging.

syntax

(local-require require-spec ...)

Like require, but for use in a internal-definition context to import just into the local context. Only bindings from phase level 0 are imported.

Examples:
> (let ()
    (local-require racket/control)
    fcontrol)

#<procedure:fcontrol>

> fcontrol

fcontrol: undefined;

 cannot reference an identifier before its definition

  in module: top-level

+Exports: provide in The Racket Guide introduces provide.

syntax

(provide provide-spec ...)

 
provide-spec = id
  | (all-defined-out)
  | (all-from-out module-path ...)
  | (rename-out [orig-id export-id] ...)
  | (except-out provide-spec provide-spec ...)
  | (prefix-out prefix-id provide-spec)
  | (struct-out id)
  | (combine-out provide-spec ...)
  | (protect-out provide-spec ...)
  | (for-meta phase-level provide-spec ...)
  | (for-syntax provide-spec ...)
  | (for-template provide-spec ...)
  | (for-label provide-spec ...)
  | derived-provide-spec
     
phase-level = exact-integer
  | #f
Declares exports from a module. A provide form must appear in a module context or a module-begin context.

A provide-spec indicates one or more bindings to provide. For each exported binding, the external name is a symbol that can be different from the symbolic form of the identifier that is bound within the module. Also, each export is drawn from a particular phase level and exported at the same phase level; by default, the relevant phase level is the number of begin-for-syntax forms that enclose the provide form.

The syntax of provide-spec can be extended by bindings to provide transformers or provide pre-transformers, such as via define-provide-syntax, but the pre-defined forms are as follows.

id

Exports id, which must be bound within the module (i.e., either defined or imported) at the relevant phase level. The symbolic form of id is used as the external name, and the symbolic form of the defined or imported identifier must match (otherwise, the external name could be ambiguous).

Examples:
> (module nest racket
    (provide num-eggs)
    (define num-eggs 2))
> (require 'nest)
> num-eggs

2

If id has a transformer binding to a rename transformer, then the transformer affects the exported binding. See make-rename-transformer for more information.

Exports all identifiers that are defined at the relevant phase level within the exporting module, and that have the same lexical context as the (all-defined-out) form, excluding bindings to rename transformers where the target identifier has the 'not-provide-all-defined syntax property. The external name for each identifier is the symbolic form of the identifier. Only identifiers accessible from the lexical context of the (all-defined-out) form are included; that is, macro-introduced imports are not re-exported, unless the (all-defined-out) form was introduced at the same time.

Examples:
> (module nest racket
    (provide (all-defined-out))
    (define num-eggs 2))
> (require 'nest)
> num-eggs

2

syntax

(all-from-out module-path ...)

Exports all identifiers that are imported into the exporting module using a require-spec built on each module-path (see Importing and Exporting: require and provide) with no phase-level shift. The symbolic name for export is derived from the name that is bound within the module, as opposed to the symbolic name of the export from each module-path. Only identifiers accessible from the lexical context of the module-path are included; that is, macro-introduced imports are not re-exported, unless the module-path was introduced at the same time.

Examples:
> (module nest racket
    (provide num-eggs)
    (define num-eggs 2))
> (module hen-house racket
    (require 'nest)
    (provide (all-from-out 'nest)))
> (require 'hen-house)
> num-eggs

2

syntax

(rename-out [orig-id export-id] ...)

Exports each orig-id, which must be bound within the module at the relevant phase level. The symbolic name for each export is export-id instead of orig-id.

Examples:
> (module nest racket
    (provide (rename-out [count num-eggs]))
    (define count 2))
> (require 'nest)
> num-eggs

2

> count

count: undefined;

 cannot reference an identifier before its definition

  in module: top-level

syntax

(except-out provide-spec provide-spec ...)

Like the first provide-spec, but omitting the bindings listed in each subsequent provide-spec. If one of the latter bindings is not included in the initial provide-spec, a syntax error is reported. The symbolic export name information in the latter provide-specs is ignored; only the bindings are used.

Examples:
> (module nest racket
    (provide (except-out (all-defined-out)
                         num-chicks))
    (define num-eggs 2)
    (define num-chicks 3))
> (require 'nest)
> num-eggs

2

> num-chicks

num-chicks: undefined;

 cannot reference an identifier before its definition

  in module: top-level

syntax

(prefix-out prefix-id provide-spec)

Like provide-spec, but with each symbolic export name from provide-spec prefixed with prefix-id.

Examples:
> (module nest racket
    (provide (prefix-out chicken: num-eggs))
    (define num-eggs 2))
> (require 'nest)
> chicken:num-eggs

2

syntax

(struct-out id)

Exports the bindings associated with a structure type id. Typically, id is bound with (struct id ....); more generally, id must have a transformer binding of structure-type information at the relevant phase level; see Structure Type Transformer Binding. Furthermore, for each identifier mentioned in the structure-type information, the enclosing module must define or import one identifier that is free-identifier=?. If the structure-type information includes a super-type identifier, and if the identifier has a transformer binding of structure-type information, the accessor and mutator bindings of the super-type are not included by struct-out for export.

Examples:
> (module nest racket
    (provide (struct-out egg))
    (struct egg (color wt)))
> (require 'nest)
> (egg-color (egg 'blue 10))

'blue

syntax

(combine-out provide-spec ...)

The union of the provide-specs.

Examples:
> (module nest racket
    (provide (combine-out num-eggs num-chicks))
    (define num-eggs 2)
    (define num-chicks 1))
> (require 'nest)
> num-eggs

2

> num-chicks

1

syntax

(protect-out provide-spec ...)

Like the union of the provide-specs, except that the exports are protected; requiring modules may refer to these bindings, but may not extract these bindings from macro expansions or access them via eval without access privileges. For more details, see Code Inspectors. The provide-spec must specify only bindings that are defined within the exporting module.

Examples:
> (module nest racket
    (provide num-eggs (protect-out num-chicks))
    (define num-eggs 2)
    (define num-chicks 3))
> (define weak-inspector (make-inspector (current-code-inspector)))
> (define (weak-eval x)
    (parameterize ([current-code-inspector weak-inspector])
      (define weak-ns (make-base-namespace))
      (namespace-attach-module (current-namespace)
                               ''nest
                               weak-ns)
      (parameterize ([current-namespace weak-ns])
        (namespace-require ''nest)
        (eval x))))
> (require 'nest)
> (list num-eggs num-chicks)

'(2 3)

> (weak-eval 'num-eggs)

2

> (weak-eval 'num-chicks)

?: access disallowed by code inspector to protected variable

  from module: 'nest

  at: num-chicks

See also Code Inspectors for Trusted and Untrusted Code.

(for-meta phase-level provide-spec ...)

Like the union of the provide-specs, but adjusted to apply to the phase level specified by phase-level relative to the current phase level (where #f corresponds to the label phase level). In particular, an id or rename-out form as a provide-spec refers to a binding at phase-level relative to the current level, an all-defined-out exports only definitions at phase-level relative to the current phase level, and an all-from-out exports bindings imported with a shift by phase-level.

Examples:
> (module nest racket
    (begin-for-syntax
     (define eggs 2))
    (define chickens 3)
    (provide (for-syntax eggs)
             chickens))
> (require 'nest)
> (define-syntax (test-eggs stx)
    (printf "Eggs are ~a\n" eggs)
    #'0)
> (test-eggs)

Eggs are 2

0

> chickens

3

> (module broken-nest racket
    (define eggs 2)
    (define chickens 3)
    (provide (for-syntax eggs)
             chickens))

eval:7:0: provide: provided identifier is not defined or

required

  at: eggs

  in: (#%provide (expand (provide-trampoline (for-syntax

eggs) chickens)))

> (module nest2 racket
    (begin-for-syntax
     (define eggs 2))
    (provide (for-syntax eggs)))
> (require (for-meta 2 racket/base)
           (for-syntax 'nest2))
> (define-syntax (test stx)
    (define-syntax (show-eggs stx)
      (printf "Eggs are ~a\n" eggs)
      #'0)
    (begin
      (show-eggs)
      #'0))

Eggs are 2

> (test)

0

(for-syntax provide-spec ...)

Same as (for-meta 1 provide-spec ...).

(for-template provide-spec ...)

Same as (for-meta -1 provide-spec ...).

(for-label provide-spec ...)

Same as (for-meta #f provide-spec ...).

derived-provide-spec

See define-provide-syntax for information on expanding the set of provide-spec forms.

Each export specified within a module must have a distinct symbolic export name, though the same binding can be specified with the multiple symbolic names.

syntax

(for-meta phase-level require-spec ...)

See require and provide.

syntax

(for-syntax require-spec ...)

See require and provide.

syntax

(for-template require-spec ...)

See require and provide.

syntax

(for-label require-spec ...)

See require and provide.

syntax

(#%require raw-require-spec ...)

 
raw-require-spec = phaseless-spec
  | (for-meta phase-level phaseless-spec ...)
  | (for-syntax phaseless-spec ...)
  | (for-template phaseless-spec ...)
  | (for-label phaseless-spec ...)
  | (just-meta phase-level raw-require-spec ...)
     
phase-level = exact-integer
  | #f
     
phaseless-spec = raw-module-path
  | (only raw-module-path id ...)
  | (prefix prefix-id raw-module-path)
  | (all-except raw-module-path id ...)
  | 
(prefix-all-except prefix-id
                   raw-module-path id ...)
  | (rename raw-module-path local-id exported-id)
     
raw-module-path = raw-root-module-path
  | (submod raw-root-module-path id ...+)
  | (submod "." id ...+)
     
raw-root-module-path = (quote id)
  | rel-string
  | (lib rel-string ...)
  | id
  | (file string)
  | 
(planet rel-string
        (user-string pkg-string vers ...))
  | literal-path
The primitive import form, to which require expands. A raw-require-spec is similar to a require-spec in a require form, except that the syntax is more constrained, not composable, and not extensible. Also, sub-form names like for-syntax and lib are recognized symbolically, instead of via bindings. Although not formalized in the grammar above, a just-meta form cannot appear within a just-meta form, but it can appear under for-meta, for-syntax, for-template, or for-label.

Each raw-require-spec corresponds to the obvious require-spec, but the rename sub-form has the identifiers in reverse order compared to rename-in.

For most raw-require-specs, the lexical context of the raw-require-spec determines the context of introduced identifiers. The exception is the rename sub-form, where the lexical context of the local-id is preserved.

A literal-path as a raw-root-module-path corresponds to a path in the sense of path?. Since path values are never produced by read-syntax, they appear only in programmatically constructed expressions. They also appear naturally as arguments to functions such as namespace-require, with otherwise take a quoted raw-module-spec.

syntax

(#%provide raw-provide-spec ...)

 
raw-provide-spec = phaseless-spec
  | (for-meta phase-level phaseless-spec ...)
  | (for-syntax phaseless-spec ...)
  | (for-label phaseless-spec ...)
  | (protect raw-provide-spec ...)
     
phase-level = exact-integer
  | #f
     
phaseless-spec = id
  | (rename local-id export-id)
  | (struct struct-id (field-id ...))
  | (all-from raw-module-path)
  | (all-from-except raw-module-path id ...)
  | (all-defined)
  | (all-defined-except id ...)
  | (prefix-all-defined prefix-id)
  | (prefix-all-defined-except prefix-id id ...)
  | (protect phaseless-spec ...)
  | (expand (id . datum))
The primitive export form, to which provide expands. A raw-module-path is as for #%require. A protect sub-form cannot appear within a protect sub-form.

Like #%require, the sub-form keywords for #%provide are recognized symbolically, and nearly every raw-provide-spec has an obvious equivalent provide-spec via provide, with the exception of the struct and expand sub-forms.

A (struct struct-id (field-id ...)) sub-form expands to struct-id, make-struct-id, struct:struct-id, struct-id?, struct-id-field-id for each field-id, and set-struct-id-field-id! for each field-id. The lexical context of the struct-id is used for all generated identifiers.

Unlike #%require, the #%provide form is macro-extensible via an explicit expand sub-form; the (id . datum) part is locally expanded as an expression (even though it is not actually an expression), stopping when a begin form is produced; if the expansion result is (begin raw-provide-spec ...), it is spliced in place of the expand form, otherwise a syntax error is reported. The expand sub-form is not normally used directly; it provides a hook for implementing provide and provide transformers.

The all-from and all-from-except forms re-export only identifiers that are accessible in lexical context of the all-from or all-from-except form itself. That is, macro-introduced imports are not re-exported, unless the all-from or all-from-except form was introduced at the same time. Similarly, all-defined and its variants export only definitions accessible from the lexical context of the phaseless-spec form.

3.2.1 Additional require Forms

The bindings documented in this section are provided by the racket/require library, not racket/base or racket.

The following forms support more complex selection and manipulation of sets of imported identifiers.

syntax

(matching-identifiers-in regexp require-spec)

Like require-spec, but including only imports whose names match regexp. The regexp must be a literal regular expression (see Regular Expressions).

Examples:
> (module zoo racket/base
    (provide tunafish swordfish blowfish
             monkey lizard ant)
    (define tunafish 1)
    (define swordfish 2)
    (define blowfish 3)
    (define monkey 4)
    (define lizard 5)
    (define ant 6))
> (require racket/require)
> (require (matching-identifiers-in #rx"\\w*fish" 'zoo))
> tunafish

1

> swordfish

2

> blowfish

3

> monkey

monkey: undefined;

 cannot reference an identifier before its definition

  in module: top-level

syntax

(subtract-in require-spec subtracted-spec ...)

Like require-spec, but omitting those imports that would be imported by one of the subtracted-specs.

Examples:
> (module earth racket
    (provide land sea air)
    (define land 1)
    (define sea 2)
    (define air 3))
> (module mars racket
    (provide aliens)
    (define aliens 4))
> (module solar-system racket
    (require 'earth 'mars)
    (provide (all-from-out 'earth)
             (all-from-out 'mars)))
> (require racket/require)
> (require (subtract-in 'solar-system 'earth))
> land

land: undefined;

 cannot reference an identifier before its definition

  in module: top-level

> aliens

4

syntax

(filtered-in proc-expr require-spec)

Applies an arbitrary transformation on the import names (as strings) of require-spec. The proc-expr must evaluate at expansion time to a single-argument procedure, which is applied on each of the names from require-spec. For each name, the procedure must return either a string for the import’s new name or #f to exclude the import.

For example,
(require (filtered-in
          (lambda (name)
            (and (regexp-match? #rx"^[a-z-]+$" name)
                 (regexp-replace #rx"-" (string-titlecase name) "")))
          racket/base))
imports only bindings from racket/base that match the pattern #rx"^[a-z-]+$", and it converts the names to “camel case.”

syntax

(path-up rel-string ...)

Specifies paths to modules named by the rel-strings similar to using the rel-strings directly, except that if a required module file is not found relative to the enclosing source, it is searched for in the parent directory, and then in the grand-parent directory, etc., all the way to the root directory. The discovered path relative to the enclosing source becomes part of the expanded form.

This form is useful in setting up a “project environment.” For example, using the following "config.rkt" file in the root directory of your project:
#lang racket/base
(require racket/require-syntax
         (for-syntax "utils/in-here.rkt"))
 
(provide utils-in)
(define-require-syntax utils-in in-here-transformer)
and using "utils/in-here.rkt" under the same root directory:
#lang racket/base
(require racket/runtime-path)
(provide in-here-transformer)
(define-runtime-path here ".")
(define (in-here-transformer stx)
  (syntax-case stx ()
    [(_ sym)
     (identifier? #'sym)
     (let ([path (build-path here (format "~a.rkt" (syntax-e #'sym)))])
       (datum->syntax stx `(file ,(path->string path)) stx))]))
then path-up works for any other module under the project directory to find "config.rkt":
(require racket/require
         (path-up "config.rkt")
         (utils-in foo))
Note that the order of requires in the example is important, as each of the first two bind the identifier used in the following.

An alternative in this scenario is to use path-up directly to find the utility module:
(require racket/require
         (path-up "utils/foo.rkt"))
but then sub-directories that are called "utils" override the one in the project’s root. In other words, the previous method requires only a single unique name.

syntax

(multi-in subs ...+)

 
subs = sub-path
  | (sub-path ...)
     
sub-path = rel-string
  | id
Specifies multiple files to be required from a hierarchy of directories or collections. The set of required module paths is computed as the Cartesian product of the subs groups, where each sub-path is combined with other sub-paths in order using a / separator. A sub-path as a subs is equivalent to (sub-path). All sub-paths in a given multi-in form must be either strings or identifiers.

Examples:

(require (multi-in racket (dict list)))

   is equivalent to 

(require racket/dict racket/list)

 

(require (multi-in "math" "matrix" "utils.rkt"))

   is equivalent to 

(require "math/matrix/utils.rkt")

 

(require (multi-in "utils" ("math.rkt" "matrix.rkt")))

   is equivalent to 

(require "utils/math.rkt" "utils/matrix.rkt")

 

(require (multi-in ("math" "matrix") "utils.rkt"))

   is equivalent to 

(require "math/utils.rkt" "matrix/utils.rkt")

 

(require (multi-in ("math" "matrix") ("utils.rkt" "helpers.rkt")))

   is equivalent to 

(require "math/utils.rkt" "math/helpers.rkt"
         "matrix/utils.rkt" "matrix/helpers.rkt")

3.2.2 Additional provide Forms

The bindings documented in this section are provided by the racket/provide library, not racket/base or racket.

syntax

(matching-identifiers-out regexp provide-spec)

Like provide-spec, but including only exports of bindings with an external name that matches regexp. The regexp must be a literal regular expression (see Regular Expressions).

syntax

(filtered-out proc-expr provide-spec)

Analogous to filtered-in, but for filtering and renaming exports.

For example,
(provide (filtered-out
          (lambda (name)
            (and (regexp-match? #rx"^[a-z-]+$" name)
                 (regexp-replace
                  #rx"-" (string-titlecase name) "")))
          (all-defined-out)))
exports only bindings that match the pattern #rx"^[a-z-]+$", and it converts the names to “camel case.”