8.1 Data-structure Contracts
procedure
(flat-contract-with-explanation get-explanation [ #:name name]) → flat-contract? get-explanation : (-> any/c (or/c boolean? (-> blame? any))) name : any/c = (object-name get-explanation)
If get-explanation returns a boolean, then that boolean value is treated as the predicate in a flat contract. If it returns a procedure, then it is treated similarly to returning #f, except the result procedure is called to actually signal the contract violation.
The name argument is used as the name of the contract; it defaults to the name of the get-explanation function.
(flat-contract-with-explanation (λ (val) (cond [(even? val) #t] [else (λ (blame) (define more-information ...do-some-complex-computation-here...) (raise-blame-error blame val '(expected: "an even number" given: "~e" "and, here is more help: ~s") val more-information))])))
procedure
(flat-named-contract name flat-contract [ generator]) → flat-contract? name : any/c flat-contract : flat-contract? generator : (or/c #f (-> contract (-> int? any))) = #f
(define/contract i (flat-named-contract 'odd-integer (lambda (x) (and (integer? x) (odd? x)))) 2)
The generator argument adds a generator for the flat-named-contract. See contract-random-generate for more information.
value
When using this contract as the result portion of a function contract, consider using any instead; using any leads to better memory performance, but it also allows multiple results.
value
The or/c result tests any value by applying the contracts in order, from left to right, with the exception that it always moves the non-flat contracts (if any) to the end, checking them last. Thus, a contract such as (or/c (not/c real?) positive?) is guaranteed to only invoke the positive? predicate on real numbers.
If all of the arguments are procedures or flat contracts, the result is a flat contract. If only one of the arguments is a higher-order contract, the result is a contract that just checks the flat contracts and, if they don’t pass, applies the higher-order contract.
If all of its arguments are list-contract?s, then or/c returns a list-contract?.
procedure
(first-or/c contract ...) → contract?
contract : contract?
The first-or/c result tests any value by applying the contracts in order from left to right. Thus, a contract such as (first-or/c (not/c real?) positive?) is guaranteed to only invoke the positive? predicate on real numbers.
If all of the arguments are procedures or flat contracts, the result is a flat contract and similarly if all of the arguments are chaperone contracts the result is too. Otherwise, the result is an impersonator contract.
If there are multiple higher-order contracts, first-or/c uses contract-first-order-passes? to distinguish between them. More precisely, when an first-or/c is checked, it checks the first order passes of the first contract against the value. If it succeeds, then it uses only that contract. If it fails, then it moves to the second contract, continuing until it finds one of the contracts where the first order check succeeds. If none of them do, a contract violation is signaled.
If all of its arguments are list-contract?s, then first-or/c returns a list-contract?.
If all of the arguments are procedures or flat contracts, the result is a flat contract.
The contract produced by and/c tests any value by applying the contracts in order, from left to right.
This means that and/c can be used to guard predicates that are not total in contracts. For example, this contract is well-behaved, correctly blaming the definition of whoops-not-a-number for not being a number:
> (define/contract whoops-not-a-number (and/c real? even?) "four") whoops-not-a-number: broke its own contract
promised: real?
produced: "four"
in: an and/c case of
(and/c real? even?)
contract from:
(definition whoops-not-a-number)
blaming: (definition whoops-not-a-number)
(assuming the contract is correct)
at: eval:2:0
> (define/contract whoops-not-a-number (and/c even? real?) "four") even?: contract violation
expected: integer?
given: "four"
If more than one of the contracts are not flat contracts, then the order in which the higher-order parts of the contract are tested can be counter-intuitive. As an example, consider this function that uses and/c in a higher-order manner with contracts that always succeed, but that print when they are called, in order for us to see the order in which they are called.
> (define ((show-me n) x) (printf "show-me ~a\n" n) #t)
> (define/contract identity-with-complex-printing-contract (and/c (-> (show-me 4) (show-me 5)) (-> (show-me 3) (show-me 6)) (-> (show-me 2) (show-me 7)) (-> (show-me 1) (show-me 8))) (λ (x) x)) > (identity-with-complex-printing-contract 101)
show-me 1
show-me 2
show-me 3
show-me 4
show-me 5
show-me 6
show-me 7
show-me 8
101
The checking order is just like the usual ordering when a contract is double-wrapped. The contract that is first put on has its domain checked second but its range checked first and we see a similar pattern here in this example, because and/c simply applies the contracts in order.
procedure
(not/c flat-contract) → flat-contract?
flat-contract : flat-contract?
procedure
(=/c z) → flat-contract?
z : real?
procedure
(</c n) → flat-contract?
n : real?
procedure
(>/c n) → flat-contract?
n : real?
procedure
(<=/c n) → flat-contract?
n : real?
procedure
(>=/c n) → flat-contract?
n : real?
procedure
(between/c n m) → flat-contract?
n : real? m : real?
procedure
(real-in n m) → flat-contract?
n : real? m : real?
procedure
(integer-in j k) → flat-contract?
j : (or/c exact-integer? #f) k : (or/c exact-integer? #f)
> (define/contract two-digit-number (integer-in 10 99) 23)
> (define/contract not-a-two-digit-number (integer-in 10 99) 124) not-a-two-digit-number: broke its own contract
promised: (integer-in 10 99)
produced: 124
in: (integer-in 10 99)
contract from:
(definition not-a-two-digit-number)
blaming: (definition not-a-two-digit-number)
(assuming the contract is correct)
at: eval:3:0
> (define/contract negative-number (integer-in #f -1) -4)
> (define/contract not-a-negative-number (integer-in #f -1) 4) not-a-negative-number: broke its own contract
promised: (integer-in #f -1)
produced: 4
in: (integer-in #f -1)
contract from:
(definition not-a-negative-number)
blaming: (definition not-a-negative-number)
(assuming the contract is correct)
at: eval:5:0
Changed in version 6.8.0.2 of package base: Allow j and k to be #f
procedure
(char-in a b) → flat-contract?
a : char? b : char?
value
procedure
(string-len/c len) → flat-contract?
len : real?
value
value
procedure
(one-of/c v ...+) → flat-contract?
v : any/c
This is a backwards compatibility contract constructor. If neither #<void> nor #<undefined> are arguments, it simply passes its arguments to or/c.
procedure
(symbols sym ...+) → flat-contract?
sym : symbol?
This is a backwards compatibility constructor; it merely passes its arguments to or/c.
procedure
(vectorof c [ #:immutable immutable #:flat? flat? #:eager eager]) → contract? c : contract? immutable : (or/c #t #f 'dont-care) = 'dont-care flat? : boolean? = #f eager : (or/c #t #f exact-nonnegative-integer?) = #t
If the flat? argument is #t, then the resulting contract is a flat contract, and the c argument must also be a flat contract. Such flat contracts will be unsound if applied to mutable vectors, as they will not check future operations on the vector.
If the immutable argument is #t and the c argument is a flat contract and the eager argument is #t, the result will be a flat contract. If the c argument is a chaperone contract, then the result will be a chaperone contract.
If the eager argument is #t, then immutable vectors are checked eagerly when c is a flat contract. If the eager argument is a number n, then immutable vectors are checked eagerly when c is a flat contract and the length of the vector is less than or equal to n.
When a higher-order vectorof contract is applied to a vector, the result is not eq? to the input. The result will be a copy for immutable vectors and a chaperone or impersonator of the input for mutable vectors, unless the c argument is a flat contract and the vector is immutable, in which case the result is the original vector.
Changed in version 6.3.0.5 of package base: Changed flat vector contracts to not copy
immutable vectors.
Changed in version 6.7.0.3: Added the #:eager option.
procedure
(vector-immutableof c) → contract?
c : contract?
procedure
(vector/c c ... [ #:immutable immutable #:flat? flat?]) → contract? c : contract? immutable : (or/c #t #f 'dont-care) = 'dont-care flat? : boolean? = #f
If the flat? argument is #t, then the resulting contract is a flat contract, and the c arguments must also be flat contracts. Such flat contracts will be unsound if applied to mutable vectors, as they will not check future operations on the vector.
If the immutable argument is #t and the c arguments are flat contracts, the result will be a flat contract. If the c arguments are chaperone contracts, then the result will be a chaperone contract.
When a higher-order vector/c contract is applied to a vector, the result is not eq? to the input. The result will be a copy for immutable vectors and a chaperone or impersonator of the input for mutable vectors.
procedure
(vector-immutable/c c ...) → contract?
c : contract?
procedure
(box/c in-c [ c #:immutable immutable #:flat? flat?]) → contract? in-c : contract? c : contract? = in-c immutable : (or/c #t #f 'dont-care) = 'dont-care flat? : boolean? = #f
If the flat? argument is #t, then the resulting contract is a flat contract, and the out argument must also be a flat contract. Such flat contracts will be unsound if applied to mutable boxes, as they will not check future operations on the box.
If the immutable argument is #t and the c argument is a flat contract, the result will be a flat contract. If the c argument is a chaperone contract, then the result will be a chaperone contract.
When a higher-order box/c contract is applied to a box, the result is not eq? to the input. The result will be a copy for immutable boxes and either a chaperone or impersonator of the input for mutable boxes.
procedure
(box-immutable/c c) → contract?
c : contract?
procedure
(listof c) → list-contract?
c : contract?
> (define/contract some-numbers (listof number?) (list 1 2 3))
> (define/contract just-one-number (listof number?) 11) just-one-number: broke its own contract
promised: list?
produced: 11
in: (listof number?)
contract from: (definition just-one-number)
blaming: (definition just-one-number)
(assuming the contract is correct)
at: eval:3:0
procedure
c : contract?
> (define/contract some-numbers (non-empty-listof number?) (list 1 2 3))
> (define/contract not-enough-numbers (non-empty-listof number?) (list)) not-enough-numbers: broke its own contract
promised: "(and/c list? pair?)"
produced: '()
in: (non-empty-listof number?)
contract from:
(definition not-enough-numbers)
blaming: (definition not-enough-numbers)
(assuming the contract is correct)
at: eval:3:0
> (define/contract improper-numbers (list*of number?) (cons 1 (cons 2 3)))
> (define/contract not-improper-numbers (list*of number?) (list 1 2 3)) not-improper-numbers: broke its own contract
promised: number?
produced: '()
in: an element of
(list*of number?)
contract from:
(definition not-improper-numbers)
blaming: (definition not-improper-numbers)
(assuming the contract is correct)
at: eval:3:0
Added in version 6.1.1.1 of package base.
Changed in version 6.4.0.4: Added the last-c argument.
If the cdr-c contract is a list-contract?, then cons/c returns a list-contract?.
> (define/contract a-pair-of-numbers (cons/c number? number?) (cons 1 2))
> (define/contract not-a-pair-of-numbers (cons/c number? number?) (cons #f #t)) not-a-pair-of-numbers: broke its own contract
promised: number?
produced: #f
in: the car of
(cons/c number? number?)
contract from:
(definition not-a-pair-of-numbers)
blaming: (definition not-a-pair-of-numbers)
(assuming the contract is correct)
at: eval:3:0
Changed in version 6.0.1.13 of package base: Added the list-contract? propagating behavior.
syntax
(cons/dc [car-id contract-expr] [cdr-id (car-id) contract-expr] cons/dc-option)
(cons/dc [car-id (cdr-id) contract-expr] [cdr-id contract-expr] cons/dc-option)
cons/dc-option =
| #:flat | #:chaperone | #:impersonator
In the first case, the contract on the cdr-id portion of the contract may depend on the value in the car-id portion of the pair and in the second case, the reverse is true.
> (define/contract an-ordered-pair-of-reals (cons/dc [hd real?] [tl (hd) (>=/c hd)]) (cons 1 2))
> (define/contract not-an-ordered-pair-of-reals (cons/dc [hd real?] [tl (hd) (>=/c hd)]) (cons 2 1)) not-an-ordered-pair-of-reals: broke its own contract
promised: (>=/c 2)
produced: 1
in: the cdr of
(cons/dc (hd real?) (tl (hd) (>=/c hd)))
contract from:
(definition not-an-ordered-pair-of-reals)
blaming: (definition not-an-ordered-pair-of-reals)
(assuming the contract is correct)
at: eval:3:0
Added in version 6.1.1.6 of package base.
procedure
(list/c c ...) → list-contract?
c : contract?
procedure
(*list/c prefix suffix ...) → list-contract?
prefix : contract? suffix : contract?
Beware that when this contract is applied to a value, the result is not necessarily eq? to the input.
> (define/contract a-list-of-numbers-ending-with-two-integers (*list/c number? integer? integer?) (list 1/2 4/5 0+1i -11 322))
> (define/contract not-enough-integers-at-the-end (*list/c number? integer? integer? integer?) (list 1/2 4/5 1/2 321 322)) not-enough-integers-at-the-end: broke its own contract
promised: integer?
produced: 1/2
in: the 3rd to the last element of
(*list/c number? integer? integer? integer?)
contract from:
(definition not-enough-integers-at-the-end)
blaming: (definition not-enough-integers-at-the-end)
(assuming the contract is correct)
at: eval:3:0
procedure
(syntax/c c) → flat-contract?
c : flat-contract?
syntax
(struct/c struct-id contract-expr ...)
Contracts for immutable fields must be either flat or chaperone contracts. Contracts for mutable fields may be impersonator contracts. If all fields are immutable and the contract-exprs evaluate to flat contracts, a flat contract is produced. If all the contract-exprs are chaperone contracts, a chaperone contract is produced. Otherwise, an impersonator contract is produced.
syntax
(struct/dc struct-id field-spec ... maybe-inv)
field-spec = [field-name maybe-lazy contract-expr] |
[field-name (dep-field-name ...) maybe-lazy maybe-contract-type maybe-dep-state contract-expr] field-name = field-id | (#:selector selector-id) | (field-id #:parent struct-id) maybe-lazy =
| #:lazy maybe-contract-type =
| #:flat | #:chaperone | #:impersonator maybe-dep-state =
| #:depends-on-state maybe-inv =
| #:inv (dep-field-name ...) invariant-expr
If the field-spec lists the names of other fields, then the contract depends on values in those fields, and the contract-expr expression is evaluated each time a selector is applied, building a new contract for the fields based on the values of the dep-field-name fields (the dep-field-name syntax is the same as the field-name syntax). If the field is a dependent field and no contract-type annotation appears, then it is assumed that the contract is a chaperone, but not always a flat contract (and thus the entire struct/dc contract is not a flat contract). If this is not the case, and the contract is always flat then the field must be annotated with the #:flat, or the field must be annotated with #:impersonator (in which case, it must be a mutable field).
A field-name is either an identifier naming a field in the first case, an identifier naming a selector in the second case indicated by the #:selector keyword, or a field id for a struct that is a parent of struct-id, indicated by the #:parent keyword.
If the #:lazy keyword appears, then the contract on the field is checked lazily (only when a selector is applied); #:lazy contracts cannot be put on mutable fields.
If a dependent contract depends on some mutable state, then use the #:depends-on-state keyword argument (if a field’s dependent contract depends on a mutable field, this keyword is automatically inferred). The presence of this keyword means that the contract expression is evaluated each time the corresponding field is accessed (or mutated, if it is a mutable field). Otherwise, the contract expression for a dependent field contract is evaluated when the contract is applied to a value.
If the #:inv clause appears, then the invariant expression is evaluated (and must return a non-#f value) when the contract is applied to a struct.
Contracts for immutable fields must be either flat or chaperone contracts. Contracts for mutable fields may be impersonator contracts. If all fields are immutable and the contract-exprs evaluate to flat contracts, a flat contract is produced. If all the contract-exprs are chaperone contracts, a chaperone contract is produced. Otherwise, an impersonator contract is produced.
As an example, the function bst/c below returns a contract for binary search trees whose values are all between lo and hi. The lazy annotations ensure that this contract does not change the running time of operations that do not inspect the entire tree.
> (struct bt (val left right))
> (define (bst/c lo hi) (or/c #f (struct/dc bt [val (between/c lo hi)] [left (val) #:lazy (bst/c lo val)] [right (val) #:lazy (bst/c val hi)])))
> (define/contract not-really-a-bst (bst/c -inf.0 +inf.0) (bt 5 (bt 4 (bt 2 #f #f) (bt 6 #f #f)) #f)) > (bt-right not-really-a-bst) #f
> (bt-val (bt-left (bt-left not-really-a-bst))) 2
> (bt-right (bt-left not-really-a-bst)) not-really-a-bst: broke its own contract
promised: (between/c 4 5)
produced: 6
in: the val field of
a part of the or/c of
the right field of
a part of the or/c of
the left field of
a part of the or/c of
(or/c
#f
(struct/dc
bt
(val (between/c -inf.0 +inf.0))
(left (val) #:lazy ...)
(right (val) #:lazy ...)))
contract from: (definition not-really-a-bst)
blaming: (definition not-really-a-bst)
(assuming the contract is correct)
at: eval:4:0
Changed in version 6.0.1.6 of package base: Added #:inv.
procedure
(parameter/c in [out]) → contract?
in : contract? out : contract? = in
> (define/contract current-snack (parameter/c string?) (make-parameter "potato-chip"))
> (define baked/c (flat-named-contract 'baked/c (λ (s) (regexp-match #rx"baked" s))))
> (define/contract current-dinner (parameter/c string? baked/c) (make-parameter "turkey" (λ (s) (string-append "roasted " s)))) > (current-snack 'not-a-snack) current-snack: contract violation
expected: string?
given: 'not-a-snack
in: the parameter of
(parameter/c string?)
contract from: (definition current-snack)
blaming: top-level
(assuming the contract is correct)
at: eval:2:0
> (parameterize ([current-dinner "tofurkey"]) (current-dinner)) current-dinner: broke its own contract
promised: baked/c
produced: "roasted tofurkey"
in: the parameter of
(parameter/c string? baked/c)
contract from: (definition current-dinner)
blaming: (definition current-dinner)
(assuming the contract is correct)
at: eval:4:0
procedure
n : exact-nonnegative-integer?
procedure
(hash/c key val [ #:immutable immutable #:flat? flat?]) → contract? key : chaperone-contract? val : contract? immutable : (or/c #t #f 'dont-care) = 'dont-care flat? : boolean? = #f
> (define/contract good-hash (hash/c integer? boolean?) (hash 1 #t 2 #f 3 #t))
> (define/contract bad-hash (hash/c integer? boolean?) (hash 1 "elephant" 2 "monkey" 3 "manatee")) bad-hash: broke its own contract
promised: boolean?
produced: "elephant"
in: the values of
(hash/c integer? boolean?)
contract from: (definition bad-hash)
blaming: (definition bad-hash)
(assuming the contract is correct)
at: eval:3:0
If the flat? argument is #t, then the resulting contract is a flat contract, and the key and val arguments must also be flat contracts.
Examples:> (flat-contract? (hash/c integer? boolean?)) #f
> (flat-contract? (hash/c integer? boolean? #:flat? #t)) #t
> (hash/c integer? (-> integer? integer?) #:flat? #t) hash/c: contract violation
expected: flat-contract?
given: (-> integer? integer?)
Such flat contracts will be unsound if applied to mutable hash tables, as they will not check future mutations to the hash table.
Examples:> (define original-h (make-hasheq)) > (define/contract ctc-h (hash/c integer? boolean? #:flat? #t) original-h) > (hash-set! original-h 1 "not a boolean") > (hash-ref ctc-h 1) "not a boolean"
If the immutable argument is #t and the key and val arguments are flat-contract?s, the result will be a flat-contract?.
Example:> (flat-contract? (hash/c integer? boolean? #:immutable #t)) #t
If either the domain or the range is a chaperone-contract?, then the result will be a chaperone-contract?.
Examples:- If the key argument is a chaperone-contract? but not a flat-contract?, then the resulting contract can be applied only to equal?-based hash tables.Example:
> (define/contract h (hash/c (-> integer? integer?) any/c) (make-hasheq)) h: broke its own contract;
promised equal?-based hash table due to higher-order domain
contract
produced: '#hasheq()
in: (hash/c (-> integer? integer?) any/c)
contract from: (definition h)
blaming: (definition h)
(assuming the contract is correct)
at: eval:2:0
Also, when such a hash/c contract is applied to a hash table, the result is not eq? to the input. The result of applying the contract will be a copy for immutable hash tables, and either a chaperone or impersonator of the original hash table for mutable hash tables.
syntax
(hash/dc [key-id key-contract-expr] [value-id (key-id) value-contract-expr] hash/dc-option)
hash/dc-option =
| #:immutable immutable?-expr hash/dc-option | #:kind kind-expr hash/dc-option
If immutable?-expr is #t, then only immutable? hashes are accepted. If it is #f then immutable? hashes are always rejected. It defaults to 'dont-care, in which case both mutable and immutable hashes are accepted.
If kind-expr evaluates to 'flat, then key-contract-expr and value-contract-expr are expected to evaluate to flat-contract?s. If it is 'chaperone, then they are expected to be chaperone-contract?s, and it may also be 'impersonator, in which case they may be any contract?s. The default is 'chaperone.
> (define/contract h (hash/dc [k real?] [v (k) (>=/c k)]) (hash 1 3 2 4))
> (define/contract h (hash/dc [k real?] [v (k) (>=/c k)]) (hash 3 1 4 2)) h: broke its own contract
promised: (>=/c 3)
produced: 1
in: the values of
(hash/dc (k real?) (v (k) (>=/c k)))
contract from: (definition h)
blaming: (definition h)
(assuming the contract is correct)
at: eval:3:0
If the val argument is a chaperone contract, then the resulting contract is a chaperone contract. Otherwise, the resulting contract is an impersonator contract. When a channel contract is applied to a channel, the resulting channel is not eq? to the input.
> (define/contract chan (channel/c string?) (make-channel)) > (thread (λ () (channel-get chan))) #<thread>
> (channel-put chan 'not-a-string) chan: contract violation
expected: string?
given: 'not-a-string
in: (channel/c string?)
contract from: (definition chan)
blaming: top-level
(assuming the contract is correct)
at: eval:2:0
syntax
(prompt-tag/c contract ... maybe-call/cc)
maybe-call/cc =
| #:call/cc contract | #:call/cc (values contract ...)
contract : contract?
Each contract will check the corresponding value passed to an abort-current-continuation and handled by the handler of a call to call-with-continuation-prompt.
If all of the contracts are chaperone contracts, the resulting contract will also be a chaperone contract. Otherwise, the contract is an impersonator contract.
If maybe-call/cc is provided, then the provided contracts are used to check the return values from a continuation captured with call-with-current-continuation.
> (define/contract tag (prompt-tag/c (-> number? string?)) (make-continuation-prompt-tag))
> (call-with-continuation-prompt (lambda () (number->string (call-with-composable-continuation (lambda (k) (abort-current-continuation tag k))))) tag (lambda (k) (k "not a number"))) tag: contract violation
expected: number?
given: "not a number"
in: the 1st argument of
(prompt-tag/c
(-> number? string?)
#:call/cc)
contract from: (definition tag)
blaming: top-level
(assuming the contract is correct)
at: eval:2:0
procedure
(continuation-mark-key/c contract) → contract?
contract : contract?
If the argument contract is a chaperone contract, the resulting contract will also be a chaperone contract. Otherwise, the contract is an impersonator contract.
> (define/contract mark-key (continuation-mark-key/c (-> symbol? (listof symbol?))) (make-continuation-mark-key))
> (with-continuation-mark mark-key (lambda (s) (append s '(truffle fudge ganache))) (let ([mark-value (continuation-mark-set-first (current-continuation-marks) mark-key)]) (mark-value "chocolate-bar"))) mark-key: contract violation
expected: symbol?
given: "chocolate-bar"
in: the 1st argument of
(continuation-mark-key/c
(-> symbol? (listof symbol?)))
contract from: (definition mark-key)
blaming: top-level
(assuming the contract is correct)
at: eval:2:0
procedure
(evt/c contract ...) → chaperone-contract?
contract : chaperone-contract?
The resulting contract is always a chaperone contract and its arguments must all be chaperone contracts.
> (define/contract my-evt (evt/c evt?) always-evt)
> (define/contract failing-evt (evt/c number? number?) (alarm-evt (+ (current-inexact-milliseconds) 50))) > (sync my-evt) #<always-evt>
> (sync failing-evt) failing-evt: broke its own contract
promised: event that produces 2 values
produced: event that produces 1 values
in: (evt/c number? number?)
contract from: (definition failing-evt)
blaming: (definition failing-evt)
(assuming the contract is correct)
at: eval:3:0
syntax
(flat-rec-contract id flat-contract-expr ...)
For example, the contract
(flat-rec-contract sexp (cons/c sexp sexp) number? symbol?)
is a flat contract that checks for (a limited form of) S-expressions. It says that a sexp is either two sexps combined with cons, or a number, or a symbol.
Note that if the contract is applied to a circular value, contract checking will not terminate.
syntax
(flat-murec-contract ([id flat-contract-expr ...] ...) body ...+)
syntax
procedure
(flat-contract predicate) → flat-contract?
predicate : (-> any/c any/c)
This function is a holdover from before predicates could be used directly as flat contracts. It exists today for backwards compatibility.
procedure
(flat-contract-predicate v) → (-> any/c any/c)
v : flat-contract?
Note that most flat contracts can be used directly as predicates, but not all. This function can be used to build predicates for ordinary Racket values that double as contracts, such as numbers and symbols. When building a contract combinator that needs to explicitly convert ordinary racket values to flat contracts, consider using coerce-flat-contract instead of flat-contract-predicate so that the combinator can raise errors that use the combinator’s name in the error message.
procedure
(property/c accessor ctc [#:name name]) → flat-contract?
accessor : (-> any/c any/c) ctc : flat-contract? name : any/c = (object-name accessor)
(lambda (v) (ctc (accessor v)))
except that more information is included in error messages produced by violations of the contract. The name argument is used to describe the property being checked in error messages.
> (define/contract (sum-triple lst) (-> (and/c (listof number?) (property/c length (=/c 3))) number?) (+ (first lst) (second lst) (third lst))) > (sum-triple '(1 2 3)) 6
> (sum-triple '(1 2)) sum-triple: contract violation
expected: (=/c 3)
given: 2
in: the length of
an and/c case of
the 1st argument of
(->
(and/c
(listof number?)
(property/c length (=/c 3)))
number?)
contract from: (function sum-triple)
blaming: top-level
(assuming the contract is correct)
at: eval:2:0
Added in version 7.3.0.11 of package base.
The field and message strings are added following the guidelines in Error Message Conventions.
> (define allow-calls? #f)
> (define/contract (f) (suggest/c (->* () #:pre allow-calls? any) "suggestion" "maybe you should set! allow-calls? to #t") 5) > (f) f: contract violation
#:pre condition
suggestion: maybe you should set! allow-calls? to #t
in: (->* () #:pre ... any)
contract from: (function f)
blaming: top-level
(assuming the contract is correct)
at: eval:3:0