New datatypes are normally created with the struct form, which is the topic of this chapter. The class-based object system, which we defer to Classes and Objects, offers an alternate mechanism for creating new datatypes, but even classes and objects are implemented in terms of structure types.
5.1 Simple Structure Types: struct
To a first approximation, the syntax of struct is
(struct struct-id (field-id ...))
(struct posn (x y))
The struct form binds struct-id and a number of identifiers that are built from struct-id and the field-ids:
> (posn 1 2)
> (posn? 3)
> (posn? (posn 1 2))
> (posn-x (posn 1 2))
> (posn-y (posn 1 2))
struct:struct-id : a structure type descriptor, which is a value that represents the structure type as a first-class value (with #:super, as discussed later in More Structure Type Options).
A struct form places no constraints on the kinds of values that can appear for fields in an instance of the structure type. For example, (posn "apple" #f) produces an instance of posn, even though "apple" and #f are not valid coordinates for the obvious uses of posn instances. Enforcing constraints on field values, such as requiring them to be numbers, is normally the job of a contract, as discussed later in Contracts.
The struct-copy form clones a structure and optionally updates specified fields in the clone. This process is sometimes called a functional update, because the result is a structure with updated field values. but the original structure is not modified.
(struct-copy struct-id struct-expr [field-id expr] ...)
The struct-id that appears after struct-copy must be a structure type name bound by struct (i.e., the name that cannot be used directly as an expression). The struct-expr must produce an instance of the structure type. The result is a new instance of the structure type that is like the old one, except that the field indicated by each field-id gets the value of the corresponding expr.
> (define p1 (posn 1 2)) > (define p2 (struct-copy posn p1 [x 3])) > (list (posn-x p2) (posn-y p2))
> (list (posn-x p1) (posn-x p2))
An extended form of struct can be used to define a structure subtype, which is a structure type that extends an existing structure type:
(struct struct-id super-id (field-id ...))
The super-id must be a structure type name bound by struct (i.e., the name that cannot be used directly as an expression).
A structure subtype inherits the fields of its supertype, and the subtype constructor accepts the values for the subtype fields after values for the supertype fields. An instance of a structure subtype can be used with the predicate and accessors of the supertype.
> (define p (3d-posn 1 2 3)) > p
> (posn? p)
> (3d-posn-z p)
; a 3d-posn has an x field, but there is no 3d-posn-x selector: > (3d-posn-x p)
cannot reference an identifier before its definition
in module: top-level
internal name: 3d-posn-x
; use the supertype's posn-x selector to access the x field: > (posn-x p)
With a structure type definition like
(struct posn (x y))
an instance of the structure type prints in a way that does not show any information about the fields’ values. That is, structure types by default are opaque. If the accessors and mutators of a structure type are kept private to a module, then no other module can rely on the representation of the type’s instances.
(struct posn (x y) #:transparent)
> (posn 1 2)
(posn 1 2)
An instance of a transparent structure type prints like a call to the constructor, so that it shows the structures field values. A transparent structure type also allows reflective operations, such as struct? and struct-info, to be used on its instances (see Reflection and Dynamic Evaluation).
Structure types are opaque by default, because opaque structure instances provide more encapsulation guarantees. That is, a library can use an opaque structure to encapsulate data, and clients of the library cannot manipulate the data in the structure except as allowed by the library.
(struct lead (width height) #:methods gen:equal+hash [(define (equal-proc a b equal?-recur) ; compare a and b (and (equal?-recur (lead-width a) (lead-width b)) (equal?-recur (lead-height a) (lead-height b)))) (define (hash-proc a hash-recur) ; compute primary hash code of a (+ (hash-recur (lead-width a)) (* 3 (hash-recur (lead-height a))))) (define (hash2-proc a hash2-recur) ; compute secondary hash code of a (+ (hash2-recur (lead-width a)) (hash2-recur (lead-height a))))])
> (equal? (lead 1 2) (lead 1 2))
The first function in the list implements the equal? test on two leads; the third argument to the function is used instead of equal? for recursive equality testing, so that data cycles can be handled correctly. The other two functions compute primary and secondary hash codes for use with hash tables:
> (define h (make-hash)) > (hash-set! h (lead 1 2) 3) > (hash-ref h (lead 1 2))
> (hash-ref h (lead 2 1))
hash-ref: no value found for key
The first function provided with gen:equal+hash is not required to recursively compare the fields of the structure. For example, a structure type representing a set might implement equality by checking that the members of the set are the same, independent of the order of elements in the internal representation. Just take care that the hash functions produce the same value for any two structure types that are supposed to be equivalent.
Each time that a struct form is evaluated, it generates a structure type that is distinct from all existing structure types, even if some other structure type has the same name and fields.
This generativity is useful for enforcing abstractions and implementing programs such as interpreters, but beware of placing a struct form in positions that are evaluated multiple times.
(define (add-bigger-fish lst) (struct fish (size) #:transparent) ; new every time (cond [(null? lst) (list (fish 1))] [else (cons (fish (* 2 (fish-size (car lst)))) lst)])) > (add-bigger-fish null)
(list (fish 1))
> (add-bigger-fish (add-bigger-fish null))
fish-size: contract violation;
given value instantiates a different structure type with
the same name
given: (fish 1)
Although a transparent structure type prints in a way that shows its content, the printed form of the structure cannot be used in an expression to get the structure back, unlike the printed form of a number, string, symbol, or list.
A prefab (“previously fabricated”) structure type is a built-in type that is known to the Racket printer and expression reader. Infinitely many such types exist, and they are indexed by name, field count, supertype, and other such details. The printed form of a prefab structure is similar to a vector, but it starts #s instead of just #, and the first element in the printed form is the prefab structure type’s name.
The following examples show instances of the sprout prefab structure type that has one field. The first instance has a field value 'bean, and the second has field value 'alfalfa:
> '#s(sprout bean)
> '#s(sprout alfalfa)
Like numbers and strings, prefab structures are “self-quoting,” so the quotes above are optional:
> #s(sprout bean)
When you use the #:prefab keyword with struct, instead of generating a new structure type, you obtain bindings that work with the existing prefab structure type:
> (define lunch '#s(sprout bean)) > (struct sprout (kind) #:prefab) > (sprout? lunch)
> (sprout-kind lunch)
> (sprout 'garlic)
The field name kind above does not matter for finding the prefab structure type; only the name sprout and the number of fields matters. At the same time, the prefab structure type sprout with three fields is a different structure type than the one with a single field:
> (sprout? #s(sprout bean #f 17))
> (struct sprout (kind yummy? count) #:prefab) ; redefine > (sprout? #s(sprout bean #f 17))
> (sprout? lunch)
A prefab structure type can have another prefab structure type as its supertype, it can have mutable fields, and it can have auto fields. Variations in any of these dimensions correspond to different prefab structure types, and the printed form of the structure type’s name encodes all of the relevant details.
> (struct building (rooms [location #:mutable]) #:prefab)
> (struct house building ([occupied #:auto]) #:prefab #:auto-value 'no) > (house 5 'factory)
'#s((house (1 no) building 2 #(1)) 5 factory no)
Every prefab structure type is transparent—
Opaque (the default) : Instances cannot be inspected or forged without access to the structure-type declaration. As discussed in the next section, constructor guards and properties can be attached to the structure type to further protect or to specialize the behavior of its instances.
Transparent : Anyone can inspect or create an instance without access to the structure-type declaration, which means that the value printer can show the content of an instance. All instance creation passes through a constructor guard, however, so that the content of an instance can be controlled, and the behavior of instances can be specialized through properties. Since the structure type is generated by its definition, instances cannot be manufactured simply through the name of the structure type, and therefore cannot be generated automatically by the expression reader.
Prefab : Anyone can inspect or create an instance at any time, without prior access to a structure-type declaration or an example instance. Consequently, the expression reader can manufacture instances directly. The instance cannot have a constructor guard or properties.
Since the expression reader can generate prefab instances, they are useful when convenient serialization is more important than abstraction. Opaque and transparent structures also can be serialized, however, if they are defined with serializable-struct as described in Datatypes and Serialization.
The full syntax of struct supports many options, both at the structure-type level and at the level of individual fields:
(struct struct-id maybe-super (field ...) struct-option ...)
| super-id field = field-id | [field-id field-option ...]
A struct-option always starts with a keyword:
Causes all fields of the structure to be mutable, and introduces for each field-id a mutator set-struct-id-field-id! that sets the value of the corresponding field in an instance of the structure type.Examples:
The #:mutable option can also be used as a field-option, in which case it makes an individual field mutable.Examples:
Controls reflective access to structure instances, as discussed in a previous section, Opaque versus Transparent Structure Types.
Generalizes #:transparent to support more controlled access to reflective operations.
Accesses a built-in structure type, as discussed in a previous section, Prefab Structure Types.
Specifies a value to be used for all automatic fields in the structure type, where an automatic field is indicated by the #:auto field option. The constructor procedure does not accept arguments for automatic fields. Automatic fields are implicitly mutable (via reflective operations), but mutator functions are bound only if #:mutable is also specified.Examples:
> (struct posn (x y [z #:auto]) #:transparent #:auto-value 0) > (posn 1 2)
(posn 1 2 0)
Specifies a constructor guard procedure to be called whenever an instance of the structure type is created. The guard takes as many arguments as non-automatic fields in the structure type, plus one more for the name of the instantiated type (in case a sub-type is instantiated, in which case it’s best to report an error using the sub-type’s name). The guard should return the same number of values as given, minus the name argument. The guard can raise an exception if one of the given arguments is unacceptable, or it can convert an argument.Examples:
The guard is called even when subtype instances are created. In that case, only the fields accepted by the constructor are provided to the guard (but the subtype’s guard gets both the original fields and fields added by the subtype).Examples:
#:methods interface-expr [body ...]
Associates method definitions for the structure type that correspond to a generic interface. For example, implementing the methods for gen:dict allows instances of a structure type to be used as dictionaries. Implementing the methods for gen:custom-write allows the customization of how an instance of a structure type is displayed.Examples:
> (struct cake (candles) #:methods gen:custom-write [(define (write-proc cake port mode) (define n (cake-candles cake)) (show " ~a ~n" n #\. port) (show " .-~a-. ~n" n #\| port) (show " | ~a | ~n" n #\space port) (show "---~a---~n" n #\- port)) (define (show fmt n ch port) (fprintf port fmt (make-string n ch)))]) > (display (cake 5))
#:property prop-expr val-expr
Associates a property and value with the structure type. For example, the prop:procedure property allows a structure instance to be used as a function; the property value determines how a call is implemented when using the structure as a function.Examples:
An alternative to supplying a super-id next to struct-id. Instead of the name of a structure type (which is not an expression), super-expr should produce a structure type descriptor value. An advantage of #:super is that structure type descriptors are values, so they can be passed to procedures.Examples:
(define (raven-constructor super-type) (struct raven () #:super super-type #:transparent #:property prop:procedure (lambda (self) 'nevermore)) raven)
> (let ([r ((raven-constructor struct:posn) 1 2)]) (list r (r)))
(list (raven 1 2) 'nevermore)
> (let ([r ((raven-constructor struct:thing) "apple")]) (list r (r)))
(list (raven "apple") 'nevermore)