/usr/share/guile/2.0/guile-procedures.txt is in guile-2.0-libs 2.0.5+1-3.
This file is owned by root:root, with mode 0o644.
The actual contents of the file can be viewed below.
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| This is guile-procedures.txt, produced by makeinfo version 4.13 from
guile-procedures.texi.
acons
-- Scheme Procedure: acons key value alist
Add a new key-value pair to ALIST. A new pair is created whose
car is KEY and whose cdr is VALUE, and the pair is consed onto
ALIST, and the new list is returned. This function is _not_
destructive; ALIST is not modified.
sloppy-assq
-- Scheme Procedure: sloppy-assq key alist
Behaves like `assq' but does not do any error checking.
Recommended only for use in Guile internals.
sloppy-assv
-- Scheme Procedure: sloppy-assv key alist
Behaves like `assv' but does not do any error checking.
Recommended only for use in Guile internals.
sloppy-assoc
-- Scheme Procedure: sloppy-assoc key alist
Behaves like `assoc' but does not do any error checking.
Recommended only for use in Guile internals.
assq
-- Scheme Procedure: assq key alist
-- Scheme Procedure: assv key alist
-- Scheme Procedure: assoc key alist
Fetch the entry in ALIST that is associated with KEY. To decide
whether the argument KEY matches a particular entry in ALIST,
`assq' compares keys with `eq?', `assv' uses `eqv?' and `assoc'
uses `equal?'. If KEY cannot be found in ALIST (according to
whichever equality predicate is in use), then return `#f'. These
functions return the entire alist entry found (i.e. both the key
and the value).
assv
-- Scheme Procedure: assv key alist
Behaves like `assq' but uses `eqv?' for key comparison.
assoc
-- Scheme Procedure: assoc key alist
Behaves like `assq' but uses `equal?' for key comparison.
assq-ref
-- Scheme Procedure: assq-ref alist key
-- Scheme Procedure: assv-ref alist key
-- Scheme Procedure: assoc-ref alist key
Like `assq', `assv' and `assoc', except that only the value
associated with KEY in ALIST is returned. These functions are
equivalent to
(let ((ent (ASSOCIATOR KEY ALIST)))
(and ent (cdr ent)))
where ASSOCIATOR is one of `assq', `assv' or `assoc'.
assv-ref
-- Scheme Procedure: assv-ref alist key
Behaves like `assq-ref' but uses `eqv?' for key comparison.
assoc-ref
-- Scheme Procedure: assoc-ref alist key
Behaves like `assq-ref' but uses `equal?' for key comparison.
assq-set!
-- Scheme Procedure: assq-set! alist key val
-- Scheme Procedure: assv-set! alist key value
-- Scheme Procedure: assoc-set! alist key value
Reassociate KEY in ALIST with VALUE: find any existing ALIST entry
for KEY and associate it with the new VALUE. If ALIST does not
contain an entry for KEY, add a new one. Return the (possibly
new) alist.
These functions do not attempt to verify the structure of ALIST,
and so may cause unusual results if passed an object that is not an
association list.
assv-set!
-- Scheme Procedure: assv-set! alist key val
Behaves like `assq-set!' but uses `eqv?' for key comparison.
assoc-set!
-- Scheme Procedure: assoc-set! alist key val
Behaves like `assq-set!' but uses `equal?' for key comparison.
assq-remove!
-- Scheme Procedure: assq-remove! alist key
-- Scheme Procedure: assv-remove! alist key
-- Scheme Procedure: assoc-remove! alist key
Delete the first entry in ALIST associated with KEY, and return
the resulting alist.
assv-remove!
-- Scheme Procedure: assv-remove! alist key
Behaves like `assq-remove!' but uses `eqv?' for key comparison.
assoc-remove!
-- Scheme Procedure: assoc-remove! alist key
Behaves like `assq-remove!' but uses `equal?' for key comparison.
make-arbiter
-- Scheme Procedure: make-arbiter name
Return an arbiter object, initially unlocked. Currently NAME is
only used for diagnostic output.
try-arbiter
-- Scheme Procedure: try-arbiter arb
If ARB is unlocked, then lock it and return `#t'. If ARB is
already locked, then do nothing and return `#f'.
release-arbiter
-- Scheme Procedure: release-arbiter arb
If ARB is locked, then unlock it and return `#t'. If ARB is
already unlocked, then do nothing and return `#f'.
Typical usage is for the thread which locked an arbiter to later
release it, but that's not required, any thread can release it.
array-fill!
-- Scheme Procedure: array-fill! ra fill
Store FILL in every element of ARRAY. The value returned is
unspecified.
array-copy-in-order!
-- Scheme Procedure: array-copy-in-order!
implemented by the C function "scm_array_copy_x"
array-copy!
-- Scheme Procedure: array-copy! src dst
-- Scheme Procedure: array-copy-in-order! src dst
Copy every element from vector or array SOURCE to the
corresponding element of DESTINATION. DESTINATION must have the
same rank as SOURCE, and be at least as large in each dimension.
The order is unspecified.
array-map-in-order!
-- Scheme Procedure: array-map-in-order!
implemented by the C function "scm_array_map_x"
array-map!
-- Scheme Procedure: array-map! ra0 proc . lra
-- Scheme Procedure: array-map-in-order! ra0 proc . lra
ARRAY1, ... must have the same number of dimensions as ARRAY0 and
have a range for each index which includes the range for the
corresponding index in ARRAY0. PROC is applied to each tuple of
elements of ARRAY1 ... and the result is stored as the
corresponding element in ARRAY0. The value returned is
unspecified. The order of application is unspecified.
array-for-each
-- Scheme Procedure: array-for-each proc ra0 . lra
Apply PROC to each tuple of elements of ARRAY0 ... in row-major
order. The value returned is unspecified.
array-index-map!
-- Scheme Procedure: array-index-map! ra proc
Apply PROC to the indices of each element of ARRAY in turn,
storing the result in the corresponding element. The value
returned and the order of application are unspecified.
One can implement ARRAY-INDEXES as
(define (array-indexes array)
(let ((ra (apply make-array #f (array-shape array))))
(array-index-map! ra (lambda x x))
ra))
Another example:
(define (apl:index-generator n)
(let ((v (make-uniform-vector n 1)))
(array-index-map! v (lambda (i) i))
v))
array-equal?
-- Scheme Procedure: array-equal? [ra0 [ra1 . rest]]
Return `#t' iff all arguments are arrays with the same shape, the
same type, and have corresponding elements which are either
`equal?' or `array-equal?'. This function differs from `equal?'
in that all arguments must be arrays.
shared-array-root
-- Scheme Procedure: shared-array-root ra
Return the root vector of a shared array.
shared-array-offset
-- Scheme Procedure: shared-array-offset ra
Return the root vector index of the first element in the array.
shared-array-increments
-- Scheme Procedure: shared-array-increments ra
For each dimension, return the distance between elements in the
root vector.
make-typed-array
-- Scheme Procedure: make-typed-array type fill . bounds
Create and return an array of type TYPE.
make-array
-- Scheme Procedure: make-array fill . bounds
Create and return an array.
make-shared-array
-- Scheme Procedure: make-shared-array oldra mapfunc . dims
`make-shared-array' can be used to create shared subarrays of other
arrays. The MAPPER is a function that translates coordinates in
the new array into coordinates in the old array. A MAPPER must be
linear, and its range must stay within the bounds of the old
array, but it can be otherwise arbitrary. A simple example:
(define fred (make-array #f 8 8))
(define freds-diagonal
(make-shared-array fred (lambda (i) (list i i)) 8))
(array-set! freds-diagonal 'foo 3)
(array-ref fred 3 3) => foo
(define freds-center
(make-shared-array fred (lambda (i j) (list (+ 3 i) (+ 3 j))) 2 2))
(array-ref freds-center 0 0) => foo
transpose-array
-- Scheme Procedure: transpose-array ra . args
Return an array sharing contents with ARRAY, but with dimensions
arranged in a different order. There must be one DIM argument for
each dimension of ARRAY. DIM0, DIM1, ... should be integers
between 0 and the rank of the array to be returned. Each integer
in that range must appear at least once in the argument list.
The values of DIM0, DIM1, ... correspond to dimensions in the
array to be returned, their positions in the argument list to
dimensions of ARRAY. Several DIMs may have the same value, in
which case the returned array will have smaller rank than ARRAY.
(transpose-array '#2((a b) (c d)) 1 0) => #2((a c) (b d))
(transpose-array '#2((a b) (c d)) 0 0) => #1(a d)
(transpose-array '#3(((a b c) (d e f)) ((1 2 3) (4 5 6))) 1 1 0) =>
#2((a 4) (b 5) (c 6))
array-contents
-- Scheme Procedure: array-contents ra [strict]
If ARRAY may be "unrolled" into a one dimensional shared array
without changing their order (last subscript changing fastest),
then `array-contents' returns that shared array, otherwise it
returns `#f'. All arrays made by MAKE-ARRAY and
MAKE-UNIFORM-ARRAY may be unrolled, some arrays made by
MAKE-SHARED-ARRAY may not be.
If the optional argument STRICT is provided, a shared array will
be returned only if its elements are stored internally contiguous
in memory.
list->typed-array
-- Scheme Procedure: list->typed-array type shape lst
Return an array of the type TYPE with elements the same as those
of LST.
The argument SHAPE determines the number of dimensions of the
array and their shape. It is either an exact integer, giving the
number of dimensions directly, or a list whose length specifies
the number of dimensions and each element specified the lower and
optionally the upper bound of the corresponding dimension. When
the element is list of two elements, these elements give the lower
and upper bounds. When it is an exact integer, it gives only the
lower bound.
list->array
-- Scheme Procedure: list->array ndim lst
Return an array with elements the same as those of LST.
async
-- Scheme Procedure: async thunk
Create a new async for the procedure THUNK.
async-mark
-- Scheme Procedure: async-mark a
Mark the async A for future execution.
run-asyncs
-- Scheme Procedure: run-asyncs list_of_a
Execute all thunks from the asyncs of the list LIST_OF_A.
system-async
-- Scheme Procedure: system-async thunk
This function is deprecated. You can use THUNK directly instead
of explicitly creating an async object.
system-async-mark
-- Scheme Procedure: system-async-mark proc [thread]
Mark PROC (a procedure with zero arguments) for future execution
in THREAD. If PROC has already been marked for THREAD but has not
been executed yet, this call has no effect. If THREAD is omitted,
the thread that called `system-async-mark' is used.
This procedure is not safe to be called from C signal handlers.
Use `scm_sigaction' or `scm_sigaction_for_thread' to install
signal handlers.
noop
-- Scheme Procedure: noop . args
Do nothing. When called without arguments, return `#f', otherwise
return the first argument.
unmask-signals
-- Scheme Procedure: unmask-signals
Unmask signals. The returned value is not specified.
mask-signals
-- Scheme Procedure: mask-signals
Mask signals. The returned value is not specified.
call-with-blocked-asyncs
-- Scheme Procedure: call-with-blocked-asyncs proc
Call PROC with no arguments and block the execution of system
asyncs by one level for the current thread while it is running.
Return the value returned by PROC.
call-with-unblocked-asyncs
-- Scheme Procedure: call-with-unblocked-asyncs proc
Call PROC with no arguments and unblock the execution of system
asyncs by one level for the current thread while it is running.
Return the value returned by PROC.
display-error
-- Scheme Procedure: display-error frame port subr message args rest
Display an error message to the output port PORT. FRAME is the
frame in which the error occurred, SUBR is the name of the
procedure in which the error occurred and MESSAGE is the actual
error message, which may contain formatting instructions. These
will format the arguments in the list ARGS accordingly. REST is
currently ignored.
display-application
-- Scheme Procedure: display-application frame [port [indent]]
Display a procedure application FRAME to the output port PORT.
INDENT specifies the indentation of the output.
display-backtrace
-- Scheme Procedure: display-backtrace stack port [first [depth
[highlights]]]
Display a backtrace to the output port PORT. STACK is the stack
to take the backtrace from, FIRST specifies where in the stack to
start and DEPTH how many frames to display. FIRST and DEPTH can
be `#f', which means that default values will be used. If
HIGHLIGHTS is given it should be a list; the elements of this list
will be highlighted wherever they appear in the backtrace.
backtrace
-- Scheme Procedure: backtrace [highlights]
Display a backtrace of the current stack to the current output
port. If HIGHLIGHTS is given, it should be a list; the elements
of this list will be highlighted wherever they appear in the
backtrace.
not
-- Scheme Procedure: not x
Return `#t' iff X is false, else return `#f'.
boolean?
-- Scheme Procedure: boolean? obj
Return `#t' iff OBJ is `#t' or false.
bitvector?
-- Scheme Procedure: bitvector? obj
Return `#t' when OBJ is a bitvector, else return `#f'.
make-bitvector
-- Scheme Procedure: make-bitvector len [fill]
Create a new bitvector of length LEN and optionally initialize all
elements to FILL.
bitvector
-- Scheme Procedure: bitvector . bits
Create a new bitvector with the arguments as elements.
bitvector-length
-- Scheme Procedure: bitvector-length vec
Return the length of the bitvector VEC.
bitvector-ref
-- Scheme Procedure: bitvector-ref vec idx
Return the element at index IDX of the bitvector VEC.
bitvector-set!
-- Scheme Procedure: bitvector-set! vec idx val
Set the element at index IDX of the bitvector VEC when VAL is
true, else clear it.
bitvector-fill!
-- Scheme Procedure: bitvector-fill! vec val
Set all elements of the bitvector VEC when VAL is true, else clear
them.
list->bitvector
-- Scheme Procedure: list->bitvector list
Return a new bitvector initialized with the elements of LIST.
bitvector->list
-- Scheme Procedure: bitvector->list vec
Return a new list initialized with the elements of the bitvector
VEC.
bit-count
-- Scheme Procedure: bit-count b bitvector
Return the number of occurrences of the boolean B in BITVECTOR.
bit-position
-- Scheme Procedure: bit-position item v k
Return the index of the first occurrence of ITEM in bit vector V,
starting from K. If there is no ITEM entry between K and the end
of BITVECTOR, then return `#f'. For example,
(bit-position #t #*000101 0) => 3
(bit-position #f #*0001111 3) => #f
bit-set*!
-- Scheme Procedure: bit-set*! v kv obj
Set entries of bit vector V to OBJ, with KV selecting the entries
to change. The return value is unspecified.
If KV is a bit vector, then those entries where it has `#t' are
the ones in V which are set to OBJ. V must be at least as long as
KV. When OBJ is `#t' it's like KV is OR'ed into V. Or when OBJ
is `#f' it can be seen as an ANDNOT.
(define bv #*01000010)
(bit-set*! bv #*10010001 #t)
bv
=> #*11010011
If KV is a u32vector, then its elements are indices into V which
are set to OBJ.
(define bv #*01000010)
(bit-set*! bv #u32(5 2 7) #t)
bv
=> #*01100111
bit-count*
-- Scheme Procedure: bit-count* v kv obj
Return a count of how many entries in bit vector V are equal to
OBJ, with KV selecting the entries to consider.
If KV is a bit vector, then those entries where it has `#t' are
the ones in V which are considered. KV and V must be the same
length.
If KV is a u32vector, then it contains the indexes in V to
consider.
For example,
(bit-count* #*01110111 #*11001101 #t) => 3
(bit-count* #*01110111 #u32(7 0 4) #f) => 2
bit-invert!
-- Scheme Procedure: bit-invert! v
Modify the bit vector V by replacing each element with its
negation.
native-endianness
-- Scheme Procedure: native-endianness
Return a symbol denoting the machine's native endianness.
bytevector?
-- Scheme Procedure: bytevector? obj
Return true if OBJ is a bytevector.
make-bytevector
-- Scheme Procedure: make-bytevector len [fill]
Return a newly allocated bytevector of LEN bytes, optionally
filled with FILL.
bytevector-length
-- Scheme Procedure: bytevector-length bv
Return the length (in bytes) of BV.
bytevector=?
-- Scheme Procedure: bytevector=? bv1 bv2
Return is BV1 equals to BV2--i.e., if they have the same length
and contents.
bytevector-fill!
-- Scheme Procedure: bytevector-fill! bv fill
Fill bytevector BV with FILL, a byte.
bytevector-copy!
-- Scheme Procedure: bytevector-copy! source source_start target
target_start len
Copy LEN bytes from SOURCE into TARGET, starting reading from
SOURCE_START (a positive index within SOURCE) and start writing at
TARGET_START.
bytevector-copy
-- Scheme Procedure: bytevector-copy bv
Return a newly allocated copy of BV.
uniform-array->bytevector
-- Scheme Procedure: uniform-array->bytevector array
Return a newly allocated bytevector whose contents will be copied
from the uniform array ARRAY.
bytevector-u8-ref
-- Scheme Procedure: bytevector-u8-ref bv index
Return the octet located at INDEX in BV.
bytevector-s8-ref
-- Scheme Procedure: bytevector-s8-ref bv index
Return the byte located at INDEX in BV.
bytevector-u8-set!
-- Scheme Procedure: bytevector-u8-set! bv index value
Return the octet located at INDEX in BV.
bytevector-s8-set!
-- Scheme Procedure: bytevector-s8-set! bv index value
Return the octet located at INDEX in BV.
bytevector->u8-list
-- Scheme Procedure: bytevector->u8-list bv
Return a newly allocated list of octets containing the contents of
BV.
u8-list->bytevector
-- Scheme Procedure: u8-list->bytevector lst
Turn LST, a list of octets, into a bytevector.
bytevector-uint-ref
-- Scheme Procedure: bytevector-uint-ref bv index endianness size
Return the SIZE-octet long unsigned integer at index INDEX in BV.
bytevector-sint-ref
-- Scheme Procedure: bytevector-sint-ref bv index endianness size
Return the SIZE-octet long unsigned integer at index INDEX in BV.
bytevector-uint-set!
-- Scheme Procedure: bytevector-uint-set! bv index value endianness
size
Set the SIZE-octet long unsigned integer at INDEX to VALUE.
bytevector-sint-set!
-- Scheme Procedure: bytevector-sint-set! bv index value endianness
size
Set the SIZE-octet long signed integer at INDEX to VALUE.
bytevector->sint-list
-- Scheme Procedure: bytevector->sint-list bv endianness size
Return a list of signed integers of SIZE octets representing the
contents of BV.
bytevector->uint-list
-- Scheme Procedure: bytevector->uint-list bv endianness size
Return a list of unsigned integers of SIZE octets representing the
contents of BV.
uint-list->bytevector
-- Scheme Procedure: uint-list->bytevector lst endianness size
Return a bytevector containing the unsigned integers listed in LST
and encoded on SIZE octets according to ENDIANNESS.
sint-list->bytevector
-- Scheme Procedure: sint-list->bytevector lst endianness size
Return a bytevector containing the signed integers listed in LST
and encoded on SIZE octets according to ENDIANNESS.
bytevector-u16-ref
-- Scheme Procedure: bytevector-u16-ref bv index endianness
Return the unsigned 16-bit integer from BV at INDEX.
bytevector-s16-ref
-- Scheme Procedure: bytevector-s16-ref bv index endianness
Return the signed 16-bit integer from BV at INDEX.
bytevector-u16-native-ref
-- Scheme Procedure: bytevector-u16-native-ref bv index
Return the unsigned 16-bit integer from BV at INDEX using the
native endianness.
bytevector-s16-native-ref
-- Scheme Procedure: bytevector-s16-native-ref bv index
Return the unsigned 16-bit integer from BV at INDEX using the
native endianness.
bytevector-u16-set!
-- Scheme Procedure: bytevector-u16-set! bv index value endianness
Store VALUE in BV at INDEX according to ENDIANNESS.
bytevector-s16-set!
-- Scheme Procedure: bytevector-s16-set! bv index value endianness
Store VALUE in BV at INDEX according to ENDIANNESS.
bytevector-u16-native-set!
-- Scheme Procedure: bytevector-u16-native-set! bv index value
Store the unsigned integer VALUE at index INDEX of BV using the
native endianness.
bytevector-s16-native-set!
-- Scheme Procedure: bytevector-s16-native-set! bv index value
Store the signed integer VALUE at index INDEX of BV using the
native endianness.
bytevector-u32-ref
-- Scheme Procedure: bytevector-u32-ref bv index endianness
Return the unsigned 32-bit integer from BV at INDEX.
bytevector-s32-ref
-- Scheme Procedure: bytevector-s32-ref bv index endianness
Return the signed 32-bit integer from BV at INDEX.
bytevector-u32-native-ref
-- Scheme Procedure: bytevector-u32-native-ref bv index
Return the unsigned 32-bit integer from BV at INDEX using the
native endianness.
bytevector-s32-native-ref
-- Scheme Procedure: bytevector-s32-native-ref bv index
Return the unsigned 32-bit integer from BV at INDEX using the
native endianness.
bytevector-u32-set!
-- Scheme Procedure: bytevector-u32-set! bv index value endianness
Store VALUE in BV at INDEX according to ENDIANNESS.
bytevector-s32-set!
-- Scheme Procedure: bytevector-s32-set! bv index value endianness
Store VALUE in BV at INDEX according to ENDIANNESS.
bytevector-u32-native-set!
-- Scheme Procedure: bytevector-u32-native-set! bv index value
Store the unsigned integer VALUE at index INDEX of BV using the
native endianness.
bytevector-s32-native-set!
-- Scheme Procedure: bytevector-s32-native-set! bv index value
Store the signed integer VALUE at index INDEX of BV using the
native endianness.
bytevector-u64-ref
-- Scheme Procedure: bytevector-u64-ref bv index endianness
Return the unsigned 64-bit integer from BV at INDEX.
bytevector-s64-ref
-- Scheme Procedure: bytevector-s64-ref bv index endianness
Return the signed 64-bit integer from BV at INDEX.
bytevector-u64-native-ref
-- Scheme Procedure: bytevector-u64-native-ref bv index
Return the unsigned 64-bit integer from BV at INDEX using the
native endianness.
bytevector-s64-native-ref
-- Scheme Procedure: bytevector-s64-native-ref bv index
Return the unsigned 64-bit integer from BV at INDEX using the
native endianness.
bytevector-u64-set!
-- Scheme Procedure: bytevector-u64-set! bv index value endianness
Store VALUE in BV at INDEX according to ENDIANNESS.
bytevector-s64-set!
-- Scheme Procedure: bytevector-s64-set! bv index value endianness
Store VALUE in BV at INDEX according to ENDIANNESS.
bytevector-u64-native-set!
-- Scheme Procedure: bytevector-u64-native-set! bv index value
Store the unsigned integer VALUE at index INDEX of BV using the
native endianness.
bytevector-s64-native-set!
-- Scheme Procedure: bytevector-s64-native-set! bv index value
Store the signed integer VALUE at index INDEX of BV using the
native endianness.
bytevector-ieee-single-ref
-- Scheme Procedure: bytevector-ieee-single-ref bv index endianness
Return the IEEE-754 single from BV at INDEX.
bytevector-ieee-single-native-ref
-- Scheme Procedure: bytevector-ieee-single-native-ref bv index
Return the IEEE-754 single from BV at INDEX using the native
endianness.
bytevector-ieee-single-set!
-- Scheme Procedure: bytevector-ieee-single-set! bv index value
endianness
Store real VALUE in BV at INDEX according to ENDIANNESS.
bytevector-ieee-single-native-set!
-- Scheme Procedure: bytevector-ieee-single-native-set! bv index value
Store the real VALUE at index INDEX of BV using the native
endianness.
bytevector-ieee-double-ref
-- Scheme Procedure: bytevector-ieee-double-ref bv index endianness
Return the IEEE-754 double from BV at INDEX.
bytevector-ieee-double-native-ref
-- Scheme Procedure: bytevector-ieee-double-native-ref bv index
Return the IEEE-754 double from BV at INDEX using the native
endianness.
bytevector-ieee-double-set!
-- Scheme Procedure: bytevector-ieee-double-set! bv index value
endianness
Store real VALUE in BV at INDEX according to ENDIANNESS.
bytevector-ieee-double-native-set!
-- Scheme Procedure: bytevector-ieee-double-native-set! bv index value
Store the real VALUE at index INDEX of BV using the native
endianness.
string->utf8
-- Scheme Procedure: string->utf8 str
Return a newly allocated bytevector that contains the UTF-8
encoding of STR.
string->utf16
-- Scheme Procedure: string->utf16 str [endianness]
Return a newly allocated bytevector that contains the UTF-16
encoding of STR.
string->utf32
-- Scheme Procedure: string->utf32 str [endianness]
Return a newly allocated bytevector that contains the UTF-32
encoding of STR.
utf8->string
-- Scheme Procedure: utf8->string utf
Return a newly allocate string that contains from the
UTF-8-encoded contents of bytevector UTF.
utf16->string
-- Scheme Procedure: utf16->string utf [endianness]
Return a newly allocate string that contains from the
UTF-16-encoded contents of bytevector UTF.
utf32->string
-- Scheme Procedure: utf32->string utf [endianness]
Return a newly allocate string that contains from the
UTF-32-encoded contents of bytevector UTF.
char?
-- Scheme Procedure: char? x
Return `#t' iff X is a character, else `#f'.
char=?
-- Scheme Procedure: char=? [x [y . rest]]
Return `#t' if the Unicode code point of X is equal to the code
point of Y, else `#f'.
char<?
-- Scheme Procedure: char<? [x [y . rest]]
Return `#t' iff the code point of X is less than the code point of
Y, else `#f'.
char<=?
-- Scheme Procedure: char<=? [x [y . rest]]
Return `#t' if the Unicode code point of X is less than or equal
to the code point of Y, else `#f'.
char>?
-- Scheme Procedure: char>? [x [y . rest]]
Return `#t' if the Unicode code point of X is greater than the
code point of Y, else `#f'.
char>=?
-- Scheme Procedure: char>=? [x [y . rest]]
Return `#t' if the Unicode code point of X is greater than or
equal to the code point of Y, else `#f'.
char-ci=?
-- Scheme Procedure: char-ci=? [x [y . rest]]
Return `#t' if the case-folded Unicode code point of X is the same
as the case-folded code point of Y, else `#f'.
char-ci<?
-- Scheme Procedure: char-ci<? [x [y . rest]]
Return `#t' if the case-folded Unicode code point of X is less
than the case-folded code point of Y, else `#f'.
char-ci<=?
-- Scheme Procedure: char-ci<=? [x [y . rest]]
Return `#t' iff the case-folded Unicode code point of X is less
than or equal to the case-folded code point of Y, else `#f'
char-ci>?
-- Scheme Procedure: char-ci>? [x [y . rest]]
Return `#t' iff the case-folded code point of X is greater than
the case-folded code point of Y, else `#f'.
char-ci>=?
-- Scheme Procedure: char-ci>=? [x [y . rest]]
Return `#t' iff the case-folded Unicode code point of X is greater
than or equal to the case-folded code point of Y, else `#f'.
char-alphabetic?
-- Scheme Procedure: char-alphabetic? chr
Return `#t' iff CHR is alphabetic, else `#f'.
char-numeric?
-- Scheme Procedure: char-numeric? chr
Return `#t' iff CHR is numeric, else `#f'.
char-whitespace?
-- Scheme Procedure: char-whitespace? chr
Return `#t' iff CHR is whitespace, else `#f'.
char-upper-case?
-- Scheme Procedure: char-upper-case? chr
Return `#t' iff CHR is uppercase, else `#f'.
char-lower-case?
-- Scheme Procedure: char-lower-case? chr
Return `#t' iff CHR is lowercase, else `#f'.
char-is-both?
-- Scheme Procedure: char-is-both? chr
Return `#t' iff CHR is either uppercase or lowercase, else `#f'.
char->integer
-- Scheme Procedure: char->integer chr
Return the Unicode code point of CHR.
integer->char
-- Scheme Procedure: integer->char n
Return the character that has Unicode code point N. The integer N
must be a valid code point. Valid code points are in the ranges 0
to `#xD7FF' inclusive or `#xE000' to `#x10FFFF' inclusive.
char-upcase
-- Scheme Procedure: char-upcase chr
Return the uppercase character version of CHR.
char-downcase
-- Scheme Procedure: char-downcase chr
Return the lowercase character version of CHR.
char-titlecase
-- Scheme Procedure: char-titlecase chr
Return the titlecase character version of CHR.
char-general-category
-- Scheme Procedure: char-general-category chr
Return a symbol representing the Unicode general category of CHR
or `#f' if a named category cannot be found.
@abort
-- Scheme Procedure: @abort tag args
Abort to the nearest prompt with tag TAG.
with-continuation-barrier
-- Scheme Procedure: with-continuation-barrier proc
Call PROC and return its result. Do not allow the invocation of
continuations that would leave or enter the dynamic extent of the
call to `with-continuation-barrier'. Such an attempt causes an
error to be signaled.
Throws (such as errors) that are not caught from within PROC are
caught by `with-continuation-barrier'. In that case, a short
message is printed to the current error port and `#f' is returned.
Thus, `with-continuation-barrier' returns exactly once.
debug-options-interface
-- Scheme Procedure: debug-options-interface [setting]
Option interface for the debug options. Instead of using this
procedure directly, use the procedures `debug-enable',
`debug-disable', `debug-set!' and `debug-options'.
procedure-name
-- Scheme Procedure: procedure-name proc
Return the name of the procedure PROC
procedure-source
-- Scheme Procedure: procedure-source proc
Return the source of the procedure PROC.
substring-move-left!
-- Scheme Procedure: substring-move-left!
implemented by the C function "scm_substring_move_x"
substring-move-right!
-- Scheme Procedure: substring-move-right!
implemented by the C function "scm_substring_move_x"
c-registered-modules
-- Scheme Procedure: c-registered-modules
Return a list of the object code modules that have been imported
into the current Guile process. Each element of the list is a
pair whose car is the name of the module, and whose cdr is the
function handle for that module's initializer function. The name
is the string that has been passed to scm_register_module_xxx.
c-clear-registered-modules
-- Scheme Procedure: c-clear-registered-modules
Destroy the list of modules registered with the current Guile
process. The return value is unspecified. *Warning:* this
function does not actually unlink or deallocate these modules, but
only destroys the records of which modules have been loaded. It
should therefore be used only by module bookkeeping operations.
close-all-ports-except
-- Scheme Procedure: close-all-ports-except . ports
[DEPRECATED] Close all open file ports used by the interpreter
except for those supplied as arguments. This procedure was
intended to be used before an exec call to close file descriptors
which are not needed in the new process. However it has the
undesirable side effect of flushing buffers, so it's deprecated.
Use port-for-each instead.
variable-set-name-hint!
-- Scheme Procedure: variable-set-name-hint! var hint
Do not use this function.
builtin-variable
-- Scheme Procedure: builtin-variable name
Do not use this function.
sloppy-memq
-- Scheme Procedure: sloppy-memq x lst
This procedure behaves like `memq', but does no type or error
checking. Its use is recommended only in writing Guile internals,
not for high-level Scheme programs.
sloppy-memv
-- Scheme Procedure: sloppy-memv x lst
This procedure behaves like `memv', but does no type or error
checking. Its use is recommended only in writing Guile internals,
not for high-level Scheme programs.
sloppy-member
-- Scheme Procedure: sloppy-member x lst
This procedure behaves like `member', but does no type or error
checking. Its use is recommended only in writing Guile internals,
not for high-level Scheme programs.
read-and-eval!
-- Scheme Procedure: read-and-eval! [port]
Read a form from PORT (standard input by default), and evaluate it
(memoizing it in the process) in the top-level environment. If no
data is left to be read from PORT, an `end-of-file' error is
signalled.
string->obarray-symbol
-- Scheme Procedure: string->obarray-symbol o s [softp]
Intern a new symbol in OBARRAY, a symbol table, with name STRING.
If OBARRAY is `#f', use the default system symbol table. If
OBARRAY is `#t', the symbol should not be interned in any symbol
table; merely return the pair (SYMBOL . #<UNDEFINED>).
The SOFT? argument determines whether new symbol table entries
should be created when the specified symbol is not already present
in OBARRAY. If SOFT? is specified and is a true value, then new
entries should not be added for symbols not already present in the
table; instead, simply return `#f'.
intern-symbol
-- Scheme Procedure: intern-symbol o s
Add a new symbol to OBARRAY with name STRING, bound to an
unspecified initial value. The symbol table is not modified if a
symbol with this name is already present.
unintern-symbol
-- Scheme Procedure: unintern-symbol o s
Remove the symbol with name STRING from OBARRAY. This function
returns `#t' if the symbol was present and `#f' otherwise.
symbol-binding
-- Scheme Procedure: symbol-binding o s
Look up in OBARRAY the symbol whose name is STRING, and return the
value to which it is bound. If OBARRAY is `#f', use the global
symbol table. If STRING is not interned in OBARRAY, an error is
signalled.
symbol-bound?
-- Scheme Procedure: symbol-bound? o s
Return `#t' if OBARRAY contains a symbol with name STRING bound to
a defined value. This differs from SYMBOL-INTERNED? in that the
mere mention of a symbol usually causes it to be interned;
`symbol-bound?' determines whether a symbol has been given any
meaningful value.
symbol-set!
-- Scheme Procedure: symbol-set! o s v
Find the symbol in OBARRAY whose name is STRING, and rebind it to
VALUE. An error is signalled if STRING is not present in OBARRAY.
gentemp
-- Scheme Procedure: gentemp [prefix [obarray]]
Create a new symbol with a name unique in an obarray. The name is
constructed from an optional string PREFIX and a counter value.
The default prefix is `t'. The OBARRAY is specified as a second
optional argument. Default is the system obarray where all normal
symbols are interned. The counter is increased by 1 at each call.
There is no provision for resetting the counter.
uniform-vector-read!
-- Scheme Procedure: uniform-vector-read! uvec [port_or_fd [start
[end]]]
Fill the elements of UVEC by reading raw bytes from PORT-OR-FDES,
using host byte order.
The optional arguments START (inclusive) and END (exclusive) allow
a specified region to be read, leaving the remainder of the vector
unchanged.
When PORT-OR-FDES is a port, all specified elements of UVEC are
attempted to be read, potentially blocking while waiting for more
input or end-of-file. When PORT-OR-FD is an integer, a single
call to read(2) is made.
An error is signalled when the last element has only been
partially filled before reaching end-of-file or in the single call
to read(2).
`uniform-vector-read!' returns the number of elements read.
PORT-OR-FDES may be omitted, in which case it defaults to the
value returned by `(current-input-port)'.
uniform-vector-write
-- Scheme Procedure: uniform-vector-write uvec [port_or_fd [start
[end]]]
Write the elements of UVEC as raw bytes to PORT-OR-FDES, in the
host byte order.
The optional arguments START (inclusive) and END (exclusive) allow
a specified region to be written.
When PORT-OR-FDES is a port, all specified elements of UVEC are
attempted to be written, potentially blocking while waiting for
more room. When PORT-OR-FD is an integer, a single call to
write(2) is made.
An error is signalled when the last element has only been
partially written in the single call to write(2).
The number of objects actually written is returned. PORT-OR-FDES
may be omitted, in which case it defaults to the value returned by
`(current-output-port)'.
uniform-array-read!
-- Scheme Procedure: uniform-array-read! ura [port_or_fd [start [end]]]
-- Scheme Procedure: uniform-vector-read! uve [port-or-fdes] [start]
[end]
Attempt to read all elements of URA, in lexicographic order, as
binary objects from PORT-OR-FDES. If an end of file is
encountered, the objects up to that point are put into URA
(starting at the beginning) and the remainder of the array is
unchanged.
The optional arguments START and END allow a specified region of a
vector (or linearized array) to be read, leaving the remainder of
the vector unchanged.
`uniform-array-read!' returns the number of objects read.
PORT-OR-FDES may be omitted, in which case it defaults to the value
returned by `(current-input-port)'.
uniform-array-write
-- Scheme Procedure: uniform-array-write ura [port_or_fd [start [end]]]
Writes all elements of URA as binary objects to PORT-OR-FDES.
The optional arguments START and END allow a specified region of a
vector (or linearized array) to be written.
The number of objects actually written is returned. PORT-OR-FDES
may be omitted, in which case it defaults to the value returned by
`(current-output-port)'.
inet-aton
-- Scheme Procedure: inet-aton address
Convert an IPv4 Internet address from printable string (dotted
decimal notation) to an integer. E.g.,
(inet-aton "127.0.0.1") => 2130706433
inet-ntoa
-- Scheme Procedure: inet-ntoa inetid
Convert an IPv4 Internet address to a printable (dotted decimal
notation) string. E.g.,
(inet-ntoa 2130706433) => "127.0.0.1"
guardian-destroyed?
-- Scheme Procedure: guardian-destroyed? guardian
Return `#t' if GUARDIAN has been destroyed, otherwise `#f'.
guardian-greedy?
-- Scheme Procedure: guardian-greedy? guardian
Return `#t' if GUARDIAN is a greedy guardian, otherwise `#f'.
destroy-guardian!
-- Scheme Procedure: destroy-guardian! guardian
Destroys GUARDIAN, by making it impossible to put any more objects
in it or get any objects from it. It also unguards any objects
guarded by GUARDIAN.
lazy-catch
-- Scheme Procedure: lazy-catch key thunk handler
This behaves exactly like `catch', except that it does not unwind
the stack before invoking HANDLER. If the HANDLER procedure
returns normally, Guile rethrows the same exception again to the
next innermost catch, lazy-catch or throw handler. If the HANDLER
exits non-locally, that exit determines the continuation.
dynamic-args-call
-- Scheme Procedure: dynamic-args-call func dobj args
Call the C function indicated by FUNC and DOBJ, just like
`dynamic-call', but pass it some arguments and return its return
value. The C function is expected to take two arguments and
return an `int', just like `main':
int c_func (int argc, char **argv);
The parameter ARGS must be a list of strings and is converted into
an array of `char *'. The array is passed in ARGV and its size in
ARGC. The return value is converted to a Scheme number and
returned from the call to `dynamic-args-call'.
make-keyword-from-dash-symbol
-- Scheme Procedure: make-keyword-from-dash-symbol symbol
Make a keyword object from a SYMBOL that starts with a dash.
keyword-dash-symbol
-- Scheme Procedure: keyword-dash-symbol keyword
Return the dash symbol for KEYWORD. This is the inverse of
`make-keyword-from-dash-symbol'.
cuserid
-- Scheme Procedure: cuserid
Return a string containing a user name associated with the
effective user id of the process. Return `#f' if this information
cannot be obtained.
primitive-make-property
-- Scheme Procedure: primitive-make-property not_found_proc
Create a "property token" that can be used with
`primitive-property-ref' and `primitive-property-set!'. See
`primitive-property-ref' for the significance of NOT_FOUND_PROC.
primitive-property-ref
-- Scheme Procedure: primitive-property-ref prop obj
Return the property PROP of OBJ.
When no value has yet been associated with PROP and OBJ, the
NOT-FOUND-PROC from PROP is used. A call `(NOT-FOUND-PROC PROP
OBJ)' is made and the result set as the property value. If
NOT-FOUND-PROC is `#f' then `#f' is the property value.
primitive-property-set!
-- Scheme Procedure: primitive-property-set! prop obj val
Set the property PROP of OBJ to VAL.
primitive-property-del!
-- Scheme Procedure: primitive-property-del! prop obj
Remove any value associated with PROP and OBJ.
issue-deprecation-warning
-- Scheme Procedure: issue-deprecation-warning . msgs
Output MSGS to `(current-error-port)' when this is the first call
to `issue-deprecation-warning' with this specific MSGS. Do
nothing otherwise. The argument MSGS should be a list of strings;
they are printed in turn, each one followed by a newline.
include-deprecated-features
-- Scheme Procedure: include-deprecated-features
Return `#t' iff deprecated features should be included in public
interfaces.
dynamic-link
-- Scheme Procedure: dynamic-link [filename]
Find the shared object (shared library) denoted by FILENAME and
link it into the running Guile application. The returned scheme
object is a "handle" for the library which can be passed to
`dynamic-func', `dynamic-call' etc.
Searching for object files is system dependent. Normally, if
FILENAME does have an explicit directory it will be searched for
in locations such as `/usr/lib' and `/usr/local/lib'.
When FILENAME is omitted, a "global symbol handle" is returned.
This handle provides access to the symbols available to the
program at run-time, including those exported by the program
itself and the shared libraries already loaded.
dynamic-object?
-- Scheme Procedure: dynamic-object? obj
Return `#t' if OBJ is a dynamic object handle, or `#f' otherwise.
dynamic-unlink
-- Scheme Procedure: dynamic-unlink dobj
Unlink a dynamic object from the application, if possible. The
object must have been linked by `dynamic-link', with DOBJ the
corresponding handle. After this procedure is called, the handle
can no longer be used to access the object.
dynamic-pointer
-- Scheme Procedure: dynamic-pointer name dobj
Return a "wrapped pointer" to the symbol NAME in the shared object
referred to by DOBJ. The returned pointer points to a C object.
Regardless whether your C compiler prepends an underscore `_' to
the global names in a program, you should *not* include this
underscore in NAME since it will be added automatically when
necessary.
dynamic-func
-- Scheme Procedure: dynamic-func name dobj
Return a "handle" for the function NAME in the shared object
referred to by DOBJ. The handle can be passed to `dynamic-call'
to actually call the function.
Regardless whether your C compiler prepends an underscore `_' to
the global names in a program, you should *not* include this
underscore in NAME since it will be added automatically when
necessary.
dynamic-call
-- Scheme Procedure: dynamic-call func dobj
Call a C function in a dynamic object. Two styles of invocation
are supported:
* FUNC can be a function handle returned by `dynamic-func'. In
this case DOBJ is ignored
* FUNC can be a string with the name of the function to call,
with DOBJ the handle of the dynamic object in which to find
the function. This is equivalent to
(dynamic-call (dynamic-func FUNC DOBJ) #f)
In either case, the function is passed no arguments and its return
value is ignored.
eq?
-- Scheme Procedure: eq? [x [y . rest]]
Return `#t' if X and Y are the same object, except for numbers and
characters. For example,
(define x (vector 1 2 3))
(define y (vector 1 2 3))
(eq? x x) => #t
(eq? x y) => #f
Numbers and characters are not equal to any other object, but the
problem is they're not necessarily `eq?' to themselves either.
This is even so when the number comes directly from a variable,
(let ((n (+ 2 3)))
(eq? n n)) => *unspecified*
Generally `eqv?' should be used when comparing numbers or
characters. `=' or `char=?' can be used too.
It's worth noting that end-of-list `()', `#t', `#f', a symbol of a
given name, and a keyword of a given name, are unique objects.
There's just one of each, so for instance no matter how `()'
arises in a program, it's the same object and can be compared with
`eq?',
(define x (cdr '(123)))
(define y (cdr '(456)))
(eq? x y) => #t
(define x (string->symbol "foo"))
(eq? x 'foo) => #t
eqv?
-- Scheme Procedure: eqv? [x [y . rest]]
Return `#t' if X and Y are the same object, or for characters and
numbers the same value.
On objects except characters and numbers, `eqv?' is the same as
`eq?', it's true if X and Y are the same object.
If X and Y are numbers or characters, `eqv?' compares their type
and value. An exact number is not `eqv?' to an inexact number
(even if their value is the same).
(eqv? 3 (+ 1 2)) => #t
(eqv? 1 1.0) => #f
equal?
-- Scheme Procedure: equal? [x [y . rest]]
Return `#t' if X and Y are the same type, and their contents or
value are equal.
For a pair, string, vector or array, `equal?' compares the
contents, and does so using using the same `equal?' recursively,
so a deep structure can be traversed.
(equal? (list 1 2 3) (list 1 2 3)) => #t
(equal? (list 1 2 3) (vector 1 2 3)) => #f
For other objects, `equal?' compares as per `eqv?', which means
characters and numbers are compared by type and value (and like
`eqv?', exact and inexact numbers are not `equal?', even if their
value is the same).
(equal? 3 (+ 1 2)) => #t
(equal? 1 1.0) => #f
Hash tables are currently only compared as per `eq?', so two
different tables are not `equal?', even if their contents are the
same.
`equal?' does not support circular data structures, it may go into
an infinite loop if asked to compare two circular lists or similar.
New application-defined object types (Smobs) have an `equalp'
handler which is called by `equal?'. This lets an application
traverse the contents or control what is considered `equal?' for
two such objects. If there's no handler, the default is to just
compare as per `eq?'.
scm-error
-- Scheme Procedure: scm-error key subr message args data
Raise an error with key KEY. SUBR can be a string naming the
procedure associated with the error, or `#f'. MESSAGE is the
error message string, possibly containing `~S' and `~A' escapes.
When an error is reported, these are replaced by formatting the
corresponding members of ARGS: `~A' (was `%s' in older versions of
Guile) formats using `display' and `~S' (was `%S') formats using
`write'. DATA is a list or `#f' depending on KEY: if KEY is
`system-error' then it should be a list containing the Unix
`errno' value; If KEY is `signal' then it should be a list
containing the Unix signal number; If KEY is `out-of-range' or
`wrong-type-arg', it is a list containing the bad value; otherwise
it will usually be `#f'.
strerror
-- Scheme Procedure: strerror err
Return the Unix error message corresponding to ERR, which must be
an integer value.
apply:nconc2last
-- Scheme Procedure: apply:nconc2last lst
Given a list (ARG1 ... ARGS), this function conses the ARG1 ...
arguments onto the front of ARGS, and returns the resulting list.
Note that ARGS is a list; thus, the argument to this function is a
list whose last element is a list. Note: Rather than do new
consing, `apply:nconc2last' destroys its argument, so use with
care.
eval
-- Scheme Procedure: eval exp module_or_state
Evaluate EXP, a list representing a Scheme expression, in the
top-level environment specified by MODULE_OR_STATE. While EXP is
evaluated (using `primitive-eval'), MODULE_OR_STATE is made the
current module when it is a module, or the current dynamic state
when it is a dynamic state.Example: (eval '(+ 1 2)
(interaction-environment))
defined?
-- Scheme Procedure: defined? sym [module]
Return `#t' if SYM is defined in the module MODULE or the current
module when MODULE is notspecified.
self-evaluating?
-- Scheme Procedure: self-evaluating? obj
Return #t for objects which Guile considers self-evaluating
macroexpand
-- Scheme Procedure: macroexpand exp
Expand the expression EXP.
macroexpanded?
-- Scheme Procedure: macroexpanded? exp
Return `#t' if EXP is an expanded expression.
load-extension
-- Scheme Procedure: load-extension lib init
Load and initialize the extension designated by LIB and INIT.
When there is no pre-registered function for LIB/INIT, this is
equivalent to
(dynamic-call INIT (dynamic-link LIB))
When there is a pre-registered function, that function is called
instead.
Normally, there is no pre-registered function. This option exists
only for situations where dynamic linking is unavailable or
unwanted. In that case, you would statically link your program
with the desired library, and register its init function right
after Guile has been initialized.
LIB should be a string denoting a shared library without any file
type suffix such as ".so". The suffix is provided automatically.
It should also not contain any directory components. Libraries
that implement Guile Extensions should be put into the normal
locations for shared libraries. We recommend to use the naming
convention libguile-bla-blum for a extension related to a module
`(bla blum)'.
The normal way for a extension to be used is to write a small
Scheme file that defines a module, and to load the extension into
this module. When the module is auto-loaded, the extension is
loaded as well. For example,
(define-module (bla blum))
(load-extension "libguile-bla-blum" "bla_init_blum")
program-arguments
-- Scheme Procedure: program-arguments
-- Scheme Procedure: command-line
Return the list of command line arguments passed to Guile, as a
list of strings. The list includes the invoked program name,
which is usually `"guile"', but excludes switches and parameters
for command line options like `-e' and `-l'.
set-program-arguments
-- Scheme Procedure: set-program-arguments lst
Set the command line arguments to be returned by
`program-arguments' (and `command-line'). LST should be a list of
strings, the first of which is the program name (either a script
name, or just `"guile"').
Program arguments are held in a fluid and therefore have a
separate value in each Guile thread. Neither the list nor the
strings within it are copied, so should not be modified later.
chown
-- Scheme Procedure: chown object owner group
Change the ownership and group of the file referred to by OBJECT to
the integer values OWNER and GROUP. OBJECT can be a string
containing a file name or, if the platform supports fchown, a port
or integer file descriptor which is open on the file. The return
value is unspecified.
If OBJECT is a symbolic link, either the ownership of the link or
the ownership of the referenced file will be changed depending on
the operating system (lchown is unsupported at present). If OWNER
or GROUP is specified as `-1', then that ID is not changed.
open-fdes
-- Scheme Procedure: open-fdes path flags [mode]
Similar to `open' but return a file descriptor instead of a port.
open
-- Scheme Procedure: open path flags [mode]
Open the file named by PATH for reading and/or writing. FLAGS is
an integer specifying how the file should be opened. MODE is an
integer specifying the permission bits of the file, if it needs to
be created, before the umask is applied. The default is 666 (Unix
itself has no default).
FLAGS can be constructed by combining variables using `logior'.
Basic flags are:
-- Variable: O_RDONLY
Open the file read-only.
-- Variable: O_WRONLY
Open the file write-only.
-- Variable: O_RDWR
Open the file read/write.
-- Variable: O_APPEND
Append to the file instead of truncating.
-- Variable: O_CREAT
Create the file if it does not already exist.
See the Unix documentation of the `open' system call for
additional flags.
close
-- Scheme Procedure: close fd_or_port
Similar to close-port (*note close-port: Closing.), but also works
on file descriptors. A side effect of closing a file descriptor
is that any ports using that file descriptor are moved to a
different file descriptor and have their revealed counts set to
zero.
close-fdes
-- Scheme Procedure: close-fdes fd
A simple wrapper for the `close' system call. Close file
descriptor FD, which must be an integer. Unlike close (*note
close: Ports and File Descriptors.), the file descriptor will be
closed even if a port is using it. The return value is
unspecified.
stat
-- Scheme Procedure: stat object [exception_on_error]
Return an object containing various information about the file
determined by OBJ. OBJ can be a string containing a file name or
a port or integer file descriptor which is open on a file (in
which case `fstat' is used as the underlying system call).
If the optional EXCEPTION_ON_ERROR argument is true, which is the
default, an exception will be raised if the underlying system call
returns an error, for example if the file is not found or is not
readable. Otherwise, an error will cause `stat' to return `#f'.
The object returned by a successful call to `stat' can be passed
as a single parameter to the following procedures, all of which
return integers:
`stat:dev'
The device containing the file.
`stat:ino'
The file serial number, which distinguishes this file from all
other files on the same device.
`stat:mode'
The mode of the file. This includes file type information and
the file permission bits. See `stat:type' and `stat:perms'
below.
`stat:nlink'
The number of hard links to the file.
`stat:uid'
The user ID of the file's owner.
`stat:gid'
The group ID of the file.
`stat:rdev'
Device ID; this entry is defined only for character or block
special files.
`stat:size'
The size of a regular file in bytes.
`stat:atime'
The last access time for the file.
`stat:mtime'
The last modification time for the file.
`stat:ctime'
The last modification time for the attributes of the file.
`stat:blksize'
The optimal block size for reading or writing the file, in
bytes.
`stat:blocks'
The amount of disk space that the file occupies measured in
units of 512 byte blocks.
In addition, the following procedures return the information from
stat:mode in a more convenient form:
`stat:type'
A symbol representing the type of file. Possible values are
regular, directory, symlink, block-special, char-special,
fifo, socket and unknown
`stat:perms'
An integer representing the access permission bits.
lstat
-- Scheme Procedure: lstat str
Similar to `stat', but does not follow symbolic links, i.e., it
will return information about a symbolic link itself, not the file
it points to. PATH must be a string.
link
-- Scheme Procedure: link oldpath newpath
Creates a new name NEWPATH in the file system for the file named
by OLDPATH. If OLDPATH is a symbolic link, the link may or may
not be followed depending on the system.
chdir
-- Scheme Procedure: chdir str
Change the current working directory to PATH. The return value is
unspecified.
select
-- Scheme Procedure: select reads writes excepts [secs [usecs]]
This procedure has a variety of uses: waiting for the ability to
provide input, accept output, or the existence of exceptional
conditions on a collection of ports or file descriptors, or
waiting for a timeout to occur. It also returns if interrupted by
a signal.
READS, WRITES and EXCEPTS can be lists or vectors, with each
member a port or a file descriptor. The value returned is a list
of three corresponding lists or vectors containing only the
members which meet the specified requirement. The ability of port
buffers to provide input or accept output is taken into account.
Ordering of the input lists or vectors is not preserved.
The optional arguments SECS and USECS specify the timeout. Either
SECS can be specified alone, as either an integer or a real
number, or both SECS and USECS can be specified as integers, in
which case USECS is an additional timeout expressed in
microseconds. If SECS is omitted or is `#f' then select will wait
for as long as it takes for one of the other conditions to be
satisfied.
The scsh version of `select' differs as follows: Only vectors are
accepted for the first three arguments. The USECS argument is not
supported. Multiple values are returned instead of a list.
Duplicates in the input vectors appear only once in output. An
additional `select!' interface is provided.
fcntl
-- Scheme Procedure: fcntl object cmd [value]
Apply COMMAND to the specified file descriptor or the underlying
file descriptor of the specified port. VALUE is an optional
integer argument.
Values for COMMAND are:
`F_DUPFD'
Duplicate a file descriptor
`F_GETFD'
Get flags associated with the file descriptor.
`F_SETFD'
Set flags associated with the file descriptor to VALUE.
`F_GETFL'
Get flags associated with the open file.
`F_SETFL'
Set flags associated with the open file to VALUE
`F_GETOWN'
Get the process ID of a socket's owner, for `SIGIO' signals.
`F_SETOWN'
Set the process that owns a socket to VALUE, for `SIGIO'
signals.
`FD_CLOEXEC'
The value used to indicate the "close on exec" flag with
`F_GETFL' or `F_SETFL'.
fsync
-- Scheme Procedure: fsync object
Copies any unwritten data for the specified output file descriptor
to disk. If PORT/FD is a port, its buffer is flushed before the
underlying file descriptor is fsync'd. The return value is
unspecified.
symlink
-- Scheme Procedure: symlink oldpath newpath
Create a symbolic link named PATH-TO with the value (i.e.,
pointing to) PATH-FROM. The return value is unspecified.
readlink
-- Scheme Procedure: readlink path
Return the value of the symbolic link named by PATH (a string),
i.e., the file that the link points to.
copy-file
-- Scheme Procedure: copy-file oldfile newfile
Copy the file specified by PATH-FROM to PATH-TO. The return value
is unspecified.
getcwd
-- Scheme Procedure: getcwd
Return the name of the current working directory.
mkdir
-- Scheme Procedure: mkdir path [mode]
Create a new directory named by PATH. If MODE is omitted then the
permissions of the directory file are set using the current umask.
Otherwise they are set to the decimal value specified with MODE.
The return value is unspecified.
rmdir
-- Scheme Procedure: rmdir path
Remove the existing directory named by PATH. The directory must
be empty for this to succeed. The return value is unspecified.
rename-file
-- Scheme Procedure: rename-file oldname newname
Renames the file specified by OLDNAME to NEWNAME. The return
value is unspecified.
delete-file
-- Scheme Procedure: delete-file str
Deletes (or "unlinks") the file specified by PATH.
access?
-- Scheme Procedure: access? path how
Test accessibility of a file under the real UID and GID of the
calling process. The return is `#t' if PATH exists and the
permissions requested by HOW are all allowed, or `#f' if not.
HOW is an integer which is one of the following values, or a
bitwise-OR (`logior') of multiple values.
-- Variable: R_OK
Test for read permission.
-- Variable: W_OK
Test for write permission.
-- Variable: X_OK
Test for execute permission.
-- Variable: F_OK
Test for existence of the file. This is implied by each of
the other tests, so there's no need to combine it with them.
It's important to note that `access?' does not simply indicate
what will happen on attempting to read or write a file. In normal
circumstances it does, but in a set-UID or set-GID program it
doesn't because `access?' tests the real ID, whereas an open or
execute attempt uses the effective ID.
A program which will never run set-UID/GID can ignore the
difference between real and effective IDs, but for maximum
generality, especially in library functions, it's best not to use
`access?' to predict the result of an open or execute, instead
simply attempt that and catch any exception.
The main use for `access?' is to let a set-UID/GID program
determine what the invoking user would have been allowed to do,
without the greater (or perhaps lesser) privileges afforded by the
effective ID. For more on this, see "Testing File Access" in The
GNU C Library Reference Manual.
chmod
-- Scheme Procedure: chmod object mode
Changes the permissions of the file referred to by OBJ. OBJ can
be a string containing a file name or a port or integer file
descriptor which is open on a file (in which case `fchmod' is used
as the underlying system call). MODE specifies the new
permissions as a decimal number, e.g., `(chmod "foo" #o755)'. The
return value is unspecified.
umask
-- Scheme Procedure: umask [mode]
If MODE is omitted, returns a decimal number representing the
current file creation mask. Otherwise the file creation mask is
set to MODE and the previous value is returned.
E.g., `(umask #o022)' sets the mask to octal 22, decimal 18.
mkstemp!
-- Scheme Procedure: mkstemp! tmpl
Create a new unique file in the file system and return a new
buffered port open for reading and writing to the file.
TMPL is a string specifying where the file should be created: it
must end with `XXXXXX' and those `X's will be changed in the
string to return the name of the file. (`port-filename' on the
port also gives the name.)
POSIX doesn't specify the permissions mode of the file, on GNU and
most systems it's `#o600'. An application can use `chmod' to
relax that if desired. For example `#o666' less `umask', which is
usual for ordinary file creation,
(let ((port (mkstemp! (string-copy "/tmp/myfile-XXXXXX"))))
(chmod port (logand #o666 (lognot (umask))))
...)
dirname
-- Scheme Procedure: dirname filename
Return the directory name component of the file name FILENAME. If
FILENAME does not contain a directory component, `.' is returned.
basename
-- Scheme Procedure: basename filename [suffix]
Return the base name of the file name FILENAME. The base name is
the file name without any directory components. If SUFFIX is
provided, and is equal to the end of BASENAME, it is removed also.
canonicalize-path
-- Scheme Procedure: canonicalize-path path
Return the canonical path of PATH. A canonical path has no `.' or
`..' components, nor any repeated path separators (`/') nor
symlinks.
Raises an error if any component of PATH does not exist.
directory-stream?
-- Scheme Procedure: directory-stream? obj
Return a boolean indicating whether OBJECT is a directory stream
as returned by `opendir'.
opendir
-- Scheme Procedure: opendir dirname
Open the directory specified by PATH and return a directory stream.
readdir
-- Scheme Procedure: readdir port
Return (as a string) the next directory entry from the directory
stream STREAM. If there is no remaining entry to be read then the
end of file object is returned.
rewinddir
-- Scheme Procedure: rewinddir port
Reset the directory port STREAM so that the next call to `readdir'
will return the first directory entry.
closedir
-- Scheme Procedure: closedir port
Close the directory stream STREAM. The return value is
unspecified.
make-fluid
-- Scheme Procedure: make-fluid [dflt]
Return a newly created fluid, whose initial value is DFLT, or `#f'
if DFLT is not given. Fluids are objects that can hold one value
per dynamic state. That is, modifications to this value are only
visible to code that executes with the same dynamic state as the
modifying code. When a new dynamic state is constructed, it
inherits the values from its parent. Because each thread normally
executes with its own dynamic state, you can use fluids for thread
local storage.
make-unbound-fluid
-- Scheme Procedure: make-unbound-fluid
Make a fluid that is initially unbound.
fluid?
-- Scheme Procedure: fluid? obj
Return `#t' iff OBJ is a fluid; otherwise, return `#f'.
fluid-ref
-- Scheme Procedure: fluid-ref fluid
Return the value associated with FLUID in the current dynamic
root. If FLUID has not been set, then return `#f'.
fluid-set!
-- Scheme Procedure: fluid-set! fluid value
Set the value associated with FLUID in the current dynamic root.
fluid-unset!
-- Scheme Procedure: fluid-unset! fluid
Unset the value associated with FLUID.
fluid-bound?
-- Scheme Procedure: fluid-bound? fluid
Return `#t' iff FLUID is bound to a value. Throw an error if
FLUID is not a fluid.
with-fluids*
-- Scheme Procedure: with-fluids* fluids values thunk
Set FLUIDS to VALUES temporary, and call THUNK. FLUIDS must be a
list of fluids and VALUES must be the same number of their values
to be applied. Each substitution is done one after another.
THUNK must be a procedure with no argument.
with-fluid*
-- Scheme Procedure: with-fluid* fluid value thunk
Set FLUID to VALUE temporarily, and call THUNK. THUNK must be a
procedure with no argument.
make-dynamic-state
-- Scheme Procedure: make-dynamic-state [parent]
Return a copy of the dynamic state object PARENT or of the current
dynamic state when PARENT is omitted.
dynamic-state?
-- Scheme Procedure: dynamic-state? obj
Return `#t' if OBJ is a dynamic state object; return `#f' otherwise
current-dynamic-state
-- Scheme Procedure: current-dynamic-state
Return the current dynamic state object.
set-current-dynamic-state
-- Scheme Procedure: set-current-dynamic-state state
Set the current dynamic state object to STATE and return the
previous current dynamic state object.
with-dynamic-state
-- Scheme Procedure: with-dynamic-state state proc
Call PROC while STATE is the current dynamic state object.
pointer?
-- Scheme Procedure: pointer? obj
Return `#t' if OBJ is a pointer object, `#f' otherwise.
make-pointer
-- Scheme Procedure: make-pointer address [finalizer]
Return a foreign pointer object pointing to ADDRESS. If FINALIZER
is passed, it should be a pointer to a one-argument C function
that will be called when the pointer object becomes unreachable.
pointer-address
-- Scheme Procedure: pointer-address pointer
Return the numerical value of POINTER.
pointer->scm
-- Scheme Procedure: pointer->scm pointer
Unsafely cast POINTER to a Scheme object. Cross your fingers!
scm->pointer
-- Scheme Procedure: scm->pointer scm
Return a foreign pointer object with the `object-address' of SCM.
pointer->bytevector
-- Scheme Procedure: pointer->bytevector pointer len [offset
[uvec_type]]
Return a bytevector aliasing the LEN bytes pointed to by POINTER.
The user may specify an alternate default interpretation for the
memory by passing the UVEC_TYPE argument, to indicate that the
memory is an array of elements of that type. UVEC_TYPE should be
something that `uniform-vector-element-type' would return, like
`f32' or `s16'.
When OFFSET is passed, it specifies the offset in bytes relative
to POINTER of the memory region aliased by the returned bytevector.
bytevector->pointer
-- Scheme Procedure: bytevector->pointer bv [offset]
Return a pointer pointer aliasing the memory pointed to by BV or
OFFSET bytes after BV when OFFSET is passed.
set-pointer-finalizer!
-- Scheme Procedure: set-pointer-finalizer! pointer finalizer
Arrange for the C procedure wrapped by FINALIZER to be called on
the pointer wrapped by POINTER when POINTER becomes unreachable.
Note: the C procedure should not call into Scheme. If you need a
Scheme finalizer, use guardians.
dereference-pointer
-- Scheme Procedure: dereference-pointer pointer
Assuming POINTER points to a memory region that holds a pointer,
return this pointer.
string->pointer
-- Scheme Procedure: string->pointer string [encoding]
Return a foreign pointer to a nul-terminated copy of STRING in the
given ENCODING, defaulting to the current locale encoding. The C
string is freed when the returned foreign pointer becomes
unreachable.
This is the Scheme equivalent of `scm_to_stringn'.
pointer->string
-- Scheme Procedure: pointer->string pointer [length [encoding]]
Return the string representing the C string pointed to by POINTER.
If LENGTH is omitted or `-1', the string is assumed to be
nul-terminated. Otherwise LENGTH is the number of bytes in memory
pointed to by POINTER. The C string is assumed to be in the given
ENCODING, defaulting to the current locale encoding.
This is the Scheme equivalent of `scm_from_stringn'.
alignof
-- Scheme Procedure: alignof type
Return the alignment of TYPE, in bytes.
TYPE should be a valid C type, like `int'. Alternately TYPE may
be the symbol `*', in which case the alignment of a pointer is
returned. TYPE may also be a list of types, in which case the
alignment of a `struct' with ABI-conventional packing is returned.
sizeof
-- Scheme Procedure: sizeof type
Return the size of TYPE, in bytes.
TYPE should be a valid C type, like `int'. Alternately TYPE may
be the symbol `*', in which case the size of a pointer is
returned. TYPE may also be a list of types, in which case the size
of a `struct' with ABI-conventional packing is returned.
pointer->procedure
-- Scheme Procedure: pointer->procedure return_type func_ptr arg_types
Make a foreign function.
Given the foreign void pointer FUNC_PTR, its argument and return
types ARG_TYPES and RETURN_TYPE, return a procedure that will pass
arguments to the foreign function and return appropriate values.
ARG_TYPES should be a list of foreign types. `return_type' should
be a foreign type.
procedure->pointer
-- Scheme Procedure: procedure->pointer return_type proc arg_types
Return a pointer to a C function of type RETURN-TYPE taking
arguments of types ARG-TYPES (a list) and behaving as a proxy to
procedure PROC. Thus PROC's arity, supported argument types, and
return type should match RETURN-TYPE and ARG-TYPES.
setvbuf
-- Scheme Procedure: setvbuf port mode [size]
Set the buffering mode for PORT. MODE can be:
`_IONBF'
non-buffered
`_IOLBF'
line buffered
`_IOFBF'
block buffered, using a newly allocated buffer of SIZE bytes.
If SIZE is omitted, a default size will be used.
file-port?
-- Scheme Procedure: file-port? obj
Determine whether OBJ is a port that is related to a file.
open-file
-- Scheme Procedure: open-file filename mode
Open the file whose name is FILENAME, and return a port
representing that file. The attributes of the port are determined
by the MODE string. The way in which this is interpreted is
similar to C stdio. The first character must be one of the
following:
`r'
Open an existing file for input.
`w'
Open a file for output, creating it if it doesn't already
exist or removing its contents if it does.
`a'
Open a file for output, creating it if it doesn't already
exist. All writes to the port will go to the end of the file.
The "append mode" can be turned off while the port is in use
*note fcntl: Ports and File Descriptors.
The following additional characters can be appended:
`b'
Open the underlying file in binary mode, if supported by the
system. Also, open the file using the binary-compatible
character encoding "ISO-8859-1", ignoring the port's encoding
and the coding declaration at the top of the input file, if
any.
`+'
Open the port for both input and output. E.g., `r+': open an
existing file for both input and output.
`0'
Create an "unbuffered" port. In this case input and output
operations are passed directly to the underlying port
implementation without additional buffering. This is likely
to slow down I/O operations. The buffering mode can be
changed while a port is in use *note setvbuf: Ports and File
Descriptors.
`l'
Add line-buffering to the port. The port output buffer will
be automatically flushed whenever a newline character is
written.
When the file is opened, this procedure will scan for a coding
declaration*note Character Encoding of Source Files::. If present
will use that encoding for interpreting the file. Otherwise, the
port's encoding will be used.
In theory we could create read/write ports which were buffered in
one direction only. However this isn't included in the current
interfaces. If a file cannot be opened with the access requested,
`open-file' throws an exception.
gc-live-object-stats
-- Scheme Procedure: gc-live-object-stats
Return an alist of statistics of the current live objects.
gc-stats
-- Scheme Procedure: gc-stats
Return an association list of statistics about Guile's current use
of storage.
gc-dump
-- Scheme Procedure: gc-dump
Dump information about the garbage collector's internal data
structures and memory usage to the standard output.
object-address
-- Scheme Procedure: object-address obj
Return an integer that for the lifetime of OBJ is uniquely
returned by this function for OBJ
gc-disable
-- Scheme Procedure: gc-disable
Disables the garbage collector. Nested calls are permitted. GC
is re-enabled once `gc-enable' has been called the same number of
times `gc-disable' was called.
gc-enable
-- Scheme Procedure: gc-enable
Enables the garbage collector.
gc
-- Scheme Procedure: gc
Scans all of SCM objects and reclaims for further use those that
are no longer accessible.
gettext
-- Scheme Procedure: gettext msgid [domain [category]]
Return the translation of MSGID in the message domain DOMAIN.
DOMAIN is optional and defaults to the domain set through
(textdomain). CATEGORY is optional and defaults to LC_MESSAGES.
ngettext
-- Scheme Procedure: ngettext msgid msgid_plural n [domain [category]]
Return the translation of MSGID/MSGID_PLURAL in the message domain
DOMAIN, with the plural form being chosen appropriately for the
number N. DOMAIN is optional and defaults to the domain set
through (textdomain). CATEGORY is optional and defaults to
LC_MESSAGES.
textdomain
-- Scheme Procedure: textdomain [domainname]
If optional parameter DOMAINNAME is supplied, set the textdomain.
Return the textdomain.
bindtextdomain
-- Scheme Procedure: bindtextdomain domainname [directory]
If optional parameter DIRECTORY is supplied, set message catalogs
to directory DIRECTORY. Return the directory bound to DOMAINNAME.
bind-textdomain-codeset
-- Scheme Procedure: bind-textdomain-codeset domainname [encoding]
If optional parameter ENCODING is supplied, set encoding for
message catalogs of DOMAINNAME. Return the encoding of DOMAINNAME.
array?
-- Scheme Procedure: array? obj
Return `#t' if the OBJ is an array, and `#f' if not.
typed-array?
-- Scheme Procedure: typed-array? obj type
Return `#t' if the OBJ is an array of type TYPE, and `#f' if not.
array-rank
-- Scheme Procedure: array-rank array
Return the number of dimensions of the array ARRAY.
array-dimensions
-- Scheme Procedure: array-dimensions ra
`array-dimensions' is similar to `array-shape' but replaces
elements with a `0' minimum with one greater than the maximum. So:
(array-dimensions (make-array 'foo '(-1 3) 5)) => ((-1 3) 5)
array-type
-- Scheme Procedure: array-type ra
array-in-bounds?
-- Scheme Procedure: array-in-bounds? ra . args
Return `#t' if its arguments would be acceptable to `array-ref'.
array-ref
-- Scheme Procedure: array-ref v . args
Return the element at the `(index1, index2)' element in ARRAY.
array-set!
-- Scheme Procedure: array-set! v obj . args
Set the element at the `(index1, index2)' element in ARRAY to
NEW-VALUE. The value returned by array-set! is unspecified.
array->list
-- Scheme Procedure: array->list array
Return a list representation of ARRAY.
It is easiest to specify the behavior of this function by example:
(array->list #0(a)) => 1
(array->list #1(a b)) => (a b)
(array->list #2((aa ab) (ba bb)) => ((aa ab) (ba bb))
make-generalized-vector
-- Scheme Procedure: make-generalized-vector type len [fill]
Make a generalized vector
generalized-vector?
-- Scheme Procedure: generalized-vector? obj
Return `#t' if OBJ is a vector, string, bitvector, or uniform
numeric vector.
generalized-vector-length
-- Scheme Procedure: generalized-vector-length v
Return the length of the generalized vector V.
generalized-vector-ref
-- Scheme Procedure: generalized-vector-ref v idx
Return the element at index IDX of the generalized vector V.
generalized-vector-set!
-- Scheme Procedure: generalized-vector-set! v idx val
Set the element at index IDX of the generalized vector V to VAL.
generalized-vector->list
-- Scheme Procedure: generalized-vector->list v
Return a new list whose elements are the elements of the
generalized vector V.
class-of
-- Scheme Procedure: class-of x
Return the class of X.
%compute-slots
-- Scheme Procedure: %compute-slots class
Return a list consisting of the names of all slots belonging to
class CLASS, i. e. the slots of CLASS and of all of its
superclasses.
get-keyword
-- Scheme Procedure: get-keyword key l default_value
Determine an associated value for the keyword KEY from the list L.
The list L has to consist of an even number of elements, where,
starting with the first, every second element is a keyword,
followed by its associated value. If L does not hold a value for
KEY, the value DEFAULT_VALUE is returned.
%initialize-object
-- Scheme Procedure: %initialize-object obj initargs
Initialize the object OBJ with the given arguments INITARGS.
%prep-layout!
-- Scheme Procedure: %prep-layout! class
%inherit-magic!
-- Scheme Procedure: %inherit-magic! class dsupers
instance?
-- Scheme Procedure: instance? obj
Return `#t' if OBJ is an instance.
class-name
-- Scheme Procedure: class-name obj
Return the class name of OBJ.
class-direct-supers
-- Scheme Procedure: class-direct-supers obj
Return the direct superclasses of the class OBJ.
class-direct-slots
-- Scheme Procedure: class-direct-slots obj
Return the direct slots of the class OBJ.
class-direct-subclasses
-- Scheme Procedure: class-direct-subclasses obj
Return the direct subclasses of the class OBJ.
class-direct-methods
-- Scheme Procedure: class-direct-methods obj
Return the direct methods of the class OBJ
class-precedence-list
-- Scheme Procedure: class-precedence-list obj
Return the class precedence list of the class OBJ.
class-slots
-- Scheme Procedure: class-slots obj
Return the slot list of the class OBJ.
generic-function-name
-- Scheme Procedure: generic-function-name obj
Return the name of the generic function OBJ.
generic-function-methods
-- Scheme Procedure: generic-function-methods obj
Return the methods of the generic function OBJ.
method-generic-function
-- Scheme Procedure: method-generic-function obj
Return the generic function for the method OBJ.
method-specializers
-- Scheme Procedure: method-specializers obj
Return specializers of the method OBJ.
method-procedure
-- Scheme Procedure: method-procedure obj
Return the procedure of the method OBJ.
make-unbound
-- Scheme Procedure: make-unbound
Return the unbound value.
unbound?
-- Scheme Procedure: unbound? obj
Return `#t' if OBJ is unbound.
assert-bound
-- Scheme Procedure: assert-bound value obj
Return VALUE if it is bound, and invoke the SLOT-UNBOUND method of
OBJ if it is not.
@assert-bound-ref
-- Scheme Procedure: @assert-bound-ref obj index
Like `assert-bound', but use INDEX for accessing the value from
OBJ.
%fast-slot-ref
-- Scheme Procedure: %fast-slot-ref obj index
Return the slot value with index INDEX from OBJ.
%fast-slot-set!
-- Scheme Procedure: %fast-slot-set! obj index value
Set the slot with index INDEX in OBJ to VALUE.
slot-ref-using-class
-- Scheme Procedure: slot-ref-using-class class obj slot_name
slot-set-using-class!
-- Scheme Procedure: slot-set-using-class! class obj slot_name value
slot-bound-using-class?
-- Scheme Procedure: slot-bound-using-class? class obj slot_name
slot-exists-using-class?
-- Scheme Procedure: slot-exists-using-class? class obj slot_name
slot-ref
-- Scheme Procedure: slot-ref obj slot_name
Return the value from OBJ's slot with the name SLOT_NAME.
slot-set!
-- Scheme Procedure: slot-set! obj slot_name value
Set the slot named SLOT_NAME of OBJ to VALUE.
slot-bound?
-- Scheme Procedure: slot-bound? obj slot_name
Return `#t' if the slot named SLOT_NAME of OBJ is bound.
slot-exists?
-- Scheme Procedure: slot-exists? obj slot_name
Return `#t' if OBJ has a slot named SLOT_NAME.
%allocate-instance
-- Scheme Procedure: %allocate-instance class initargs
Create a new instance of class CLASS and initialize it from the
arguments INITARGS.
%set-object-setter!
-- Scheme Procedure: %set-object-setter! obj setter
%modify-instance
-- Scheme Procedure: %modify-instance old new
%modify-class
-- Scheme Procedure: %modify-class old new
%invalidate-class
-- Scheme Procedure: %invalidate-class class
%invalidate-method-cache!
-- Scheme Procedure: %invalidate-method-cache! gf
generic-capability?
-- Scheme Procedure: generic-capability? proc
enable-primitive-generic!
-- Scheme Procedure: enable-primitive-generic! . subrs
set-primitive-generic!
-- Scheme Procedure: set-primitive-generic! subr generic
primitive-generic-generic
-- Scheme Procedure: primitive-generic-generic subr
make
-- Scheme Procedure: make . args
Make a new object. ARGS must contain the class and all necessary
initialization information.
find-method
-- Scheme Procedure: find-method . l
%method-more-specific?
-- Scheme Procedure: %method-more-specific? m1 m2 targs
Return true if method M1 is more specific than M2 given the
argument types (classes) listed in TARGS.
%goops-loaded
-- Scheme Procedure: %goops-loaded
Announce that GOOPS is loaded and perform initialization on the C
level which depends on the loaded GOOPS modules.
make-guardian
-- Scheme Procedure: make-guardian
Create a new guardian. A guardian protects a set of objects from
garbage collection, allowing a program to apply cleanup or other
actions.
`make-guardian' returns a procedure representing the guardian.
Calling the guardian procedure with an argument adds the argument
to the guardian's set of protected objects. Calling the guardian
procedure without an argument returns one of the protected objects
which are ready for garbage collection, or `#f' if no such object
is available. Objects which are returned in this way are removed
from the guardian.
You can put a single object into a guardian more than once and you
can put a single object into more than one guardian. The object
will then be returned multiple times by the guardian procedures.
An object is eligible to be returned from a guardian when it is no
longer referenced from outside any guardian.
There is no guarantee about the order in which objects are returned
from a guardian. If you want to impose an order on finalization
actions, for example, you can do that by keeping objects alive in
some global data structure until they are no longer needed for
finalizing other objects.
Being an element in a weak vector, a key in a hash table with weak
keys, or a value in a hash table with weak value does not prevent
an object from being returned by a guardian. But as long as an
object can be returned from a guardian it will not be removed from
such a weak vector or hash table. In other words, a weak link
does not prevent an object from being considered collectable, but
being inside a guardian prevents a weak link from being broken.
A key in a weak key hash table can be though of as having a strong
reference to its associated value as long as the key is accessible.
Consequently, when the key only accessible from within a guardian,
the reference from the key to the value is also considered to be
coming from within a guardian. Thus, if there is no other
reference to the value, it is eligible to be returned from a
guardian.
hashq
-- Scheme Procedure: hashq key size
Determine a hash value for KEY that is suitable for lookups in a
hashtable of size SIZE, where `eq?' is used as the equality
predicate. The function returns an integer in the range 0 to SIZE
- 1. Note that `hashq' may use internal addresses. Thus two
calls to hashq where the keys are `eq?' are not guaranteed to
deliver the same value if the key object gets garbage collected in
between. This can happen, for example with symbols: `(hashq 'foo
n) (gc) (hashq 'foo n)' may produce two different values, since
`foo' will be garbage collected.
hashv
-- Scheme Procedure: hashv key size
Determine a hash value for KEY that is suitable for lookups in a
hashtable of size SIZE, where `eqv?' is used as the equality
predicate. The function returns an integer in the range 0 to SIZE
- 1. Note that `(hashv key)' may use internal addresses. Thus
two calls to hashv where the keys are `eqv?' are not guaranteed to
deliver the same value if the key object gets garbage collected in
between. This can happen, for example with symbols: `(hashv 'foo
n) (gc) (hashv 'foo n)' may produce two different values, since
`foo' will be garbage collected.
hash
-- Scheme Procedure: hash key size
Determine a hash value for KEY that is suitable for lookups in a
hashtable of size SIZE, where `equal?' is used as the equality
predicate. The function returns an integer in the range 0 to SIZE
- 1.
make-hash-table
-- Scheme Procedure: make-hash-table [n]
Make a new abstract hash table object with minimum number of
buckets N
make-weak-key-hash-table
-- Scheme Procedure: make-weak-key-hash-table [n]
-- Scheme Procedure: make-weak-value-hash-table size
-- Scheme Procedure: make-doubly-weak-hash-table size
Return a weak hash table with SIZE buckets.
You can modify weak hash tables in exactly the same way you would
modify regular hash tables. (*note Hash Tables::)
make-weak-value-hash-table
-- Scheme Procedure: make-weak-value-hash-table [n]
Return a hash table with weak values with SIZE buckets. (*note
Hash Tables::)
make-doubly-weak-hash-table
-- Scheme Procedure: make-doubly-weak-hash-table n
Return a hash table with weak keys and values with SIZE buckets.
(*note Hash Tables::)
hash-table?
-- Scheme Procedure: hash-table? obj
Return `#t' if OBJ is an abstract hash table object.
weak-key-hash-table?
-- Scheme Procedure: weak-key-hash-table? obj
-- Scheme Procedure: weak-value-hash-table? obj
-- Scheme Procedure: doubly-weak-hash-table? obj
Return `#t' if OBJ is the specified weak hash table. Note that a
doubly weak hash table is neither a weak key nor a weak value hash
table.
weak-value-hash-table?
-- Scheme Procedure: weak-value-hash-table? obj
Return `#t' if OBJ is a weak value hash table.
doubly-weak-hash-table?
-- Scheme Procedure: doubly-weak-hash-table? obj
Return `#t' if OBJ is a doubly weak hash table.
hash-clear!
-- Scheme Procedure: hash-clear! table
Remove all items from TABLE (without triggering a resize).
hashq-get-handle
-- Scheme Procedure: hashq-get-handle table key
This procedure returns the `(key . value)' pair from the hash
table TABLE. If TABLE does not hold an associated value for KEY,
`#f' is returned. Uses `eq?' for equality testing.
hashq-create-handle!
-- Scheme Procedure: hashq-create-handle! table key init
This function looks up KEY in TABLE and returns its handle. If
KEY is not already present, a new handle is created which
associates KEY with INIT.
hashq-ref
-- Scheme Procedure: hashq-ref table key [dflt]
Look up KEY in the hash table TABLE, and return the value (if any)
associated with it. If KEY is not found, return DEFAULT (or `#f'
if no DEFAULT argument is supplied). Uses `eq?' for equality
testing.
hashq-set!
-- Scheme Procedure: hashq-set! table key val
Find the entry in TABLE associated with KEY, and store VALUE
there. Uses `eq?' for equality testing.
hashq-remove!
-- Scheme Procedure: hashq-remove! table key
Remove KEY (and any value associated with it) from TABLE. Uses
`eq?' for equality tests.
hashv-get-handle
-- Scheme Procedure: hashv-get-handle table key
This procedure returns the `(key . value)' pair from the hash
table TABLE. If TABLE does not hold an associated value for KEY,
`#f' is returned. Uses `eqv?' for equality testing.
hashv-create-handle!
-- Scheme Procedure: hashv-create-handle! table key init
This function looks up KEY in TABLE and returns its handle. If
KEY is not already present, a new handle is created which
associates KEY with INIT.
hashv-ref
-- Scheme Procedure: hashv-ref table key [dflt]
Look up KEY in the hash table TABLE, and return the value (if any)
associated with it. If KEY is not found, return DEFAULT (or `#f'
if no DEFAULT argument is supplied). Uses `eqv?' for equality
testing.
hashv-set!
-- Scheme Procedure: hashv-set! table key val
Find the entry in TABLE associated with KEY, and store VALUE
there. Uses `eqv?' for equality testing.
hashv-remove!
-- Scheme Procedure: hashv-remove! table key
Remove KEY (and any value associated with it) from TABLE. Uses
`eqv?' for equality tests.
hash-get-handle
-- Scheme Procedure: hash-get-handle table key
This procedure returns the `(key . value)' pair from the hash
table TABLE. If TABLE does not hold an associated value for KEY,
`#f' is returned. Uses `equal?' for equality testing.
hash-create-handle!
-- Scheme Procedure: hash-create-handle! table key init
This function looks up KEY in TABLE and returns its handle. If
KEY is not already present, a new handle is created which
associates KEY with INIT.
hash-ref
-- Scheme Procedure: hash-ref table key [dflt]
Look up KEY in the hash table TABLE, and return the value (if any)
associated with it. If KEY is not found, return DEFAULT (or `#f'
if no DEFAULT argument is supplied). Uses `equal?' for equality
testing.
hash-set!
-- Scheme Procedure: hash-set! table key val
Find the entry in TABLE associated with KEY, and store VALUE
there. Uses `equal?' for equality testing.
hash-remove!
-- Scheme Procedure: hash-remove! table key
Remove KEY (and any value associated with it) from TABLE. Uses
`equal?' for equality tests.
hashx-get-handle
-- Scheme Procedure: hashx-get-handle hash assoc table key
This behaves the same way as the corresponding `-get-handle'
function, but uses HASH as a hash function and ASSOC to compare
keys. `hash' must be a function that takes two arguments, a key
to be hashed and a table size. `assoc' must be an associator
function, like `assoc', `assq' or `assv'.
hashx-create-handle!
-- Scheme Procedure: hashx-create-handle! hash assoc table key init
This behaves the same way as the corresponding `-create-handle'
function, but uses HASH as a hash function and ASSOC to compare
keys. `hash' must be a function that takes two arguments, a key
to be hashed and a table size. `assoc' must be an associator
function, like `assoc', `assq' or `assv'.
hashx-ref
-- Scheme Procedure: hashx-ref hash assoc table key [dflt]
This behaves the same way as the corresponding `ref' function, but
uses HASH as a hash function and ASSOC to compare keys. `hash'
must be a function that takes two arguments, a key to be hashed
and a table size. `assoc' must be an associator function, like
`assoc', `assq' or `assv'.
By way of illustration, `hashq-ref table key' is equivalent to
`hashx-ref hashq assq table key'.
hashx-set!
-- Scheme Procedure: hashx-set! hash assoc table key val
This behaves the same way as the corresponding `set!' function,
but uses HASH as a hash function and ASSOC to compare keys.
`hash' must be a function that takes two arguments, a key to be
hashed and a table size. `assoc' must be an associator function,
like `assoc', `assq' or `assv'.
By way of illustration, `hashq-set! table key' is equivalent to
`hashx-set! hashq assq table key'.
hashx-remove!
-- Scheme Procedure: hashx-remove! hash assoc table obj
This behaves the same way as the corresponding `remove!' function,
but uses HASH as a hash function and ASSOC to compare keys.
`hash' must be a function that takes two arguments, a key to be
hashed and a table size. `assoc' must be an associator function,
like `assoc', `assq' or `assv'.
By way of illustration, `hashq-remove! table key' is equivalent to
`hashx-remove! hashq assq #f table key'.
hash-fold
-- Scheme Procedure: hash-fold proc init table
An iterator over hash-table elements. Accumulates and returns a
result by applying PROC successively. The arguments to PROC are
"(key value prior-result)" where key and value are successive
pairs from the hash table TABLE, and prior-result is either INIT
(for the first application of PROC) or the return value of the
previous application of PROC. For example, `(hash-fold acons '()
tab)' will convert a hash table into an a-list of key-value pairs.
hash-for-each
-- Scheme Procedure: hash-for-each proc table
An iterator over hash-table elements. Applies PROC successively
on all hash table items. The arguments to PROC are "(key value)"
where key and value are successive pairs from the hash table TABLE.
hash-for-each-handle
-- Scheme Procedure: hash-for-each-handle proc table
An iterator over hash-table elements. Applies PROC successively
on all hash table handles.
hash-map->list
-- Scheme Procedure: hash-map->list proc table
An iterator over hash-table elements. Accumulates and returns as
a list the results of applying PROC successively. The arguments
to PROC are "(key value)" where key and value are successive pairs
from the hash table TABLE.
make-hook
-- Scheme Procedure: make-hook [n_args]
Create a hook for storing procedure of arity N_ARGS. N_ARGS
defaults to zero. The returned value is a hook object to be used
with the other hook procedures.
hook?
-- Scheme Procedure: hook? x
Return `#t' if X is a hook, `#f' otherwise.
hook-empty?
-- Scheme Procedure: hook-empty? hook
Return `#t' if HOOK is an empty hook, `#f' otherwise.
add-hook!
-- Scheme Procedure: add-hook! hook proc [append_p]
Add the procedure PROC to the hook HOOK. The procedure is added to
the end if APPEND_P is true, otherwise it is added to the front.
The return value of this procedure is not specified.
remove-hook!
-- Scheme Procedure: remove-hook! hook proc
Remove the procedure PROC from the hook HOOK. The return value of
this procedure is not specified.
reset-hook!
-- Scheme Procedure: reset-hook! hook
Remove all procedures from the hook HOOK. The return value of
this procedure is not specified.
run-hook
-- Scheme Procedure: run-hook hook . args
Apply all procedures from the hook HOOK to the arguments ARGS.
The order of the procedure application is first to last. The
return value of this procedure is not specified.
hook->list
-- Scheme Procedure: hook->list hook
Convert the procedure list of HOOK to a list.
make-locale
-- Scheme Procedure: make-locale category_list locale_name
[base_locale]
Return a reference to a data structure representing a set of
locale datasets. CATEGORY_LIST should be either a list of locale
categories or a single category as used with `setlocale' (*note
`setlocale': Locales.) and LOCALE_NAME should be the name of the
locale considered (e.g., `"sl_SI"'). Optionally, if `base_locale'
is passed, it should be a locale object denoting settings for
categories not listed in CATEGORY_LIST.
locale?
-- Scheme Procedure: locale? obj
Return true if OBJ is a locale object.
string-locale<?
-- Scheme Procedure: string-locale<? s1 s2 [locale]
Compare strings S1 and S2 in a locale-dependent way.If LOCALE is
provided, it should be locale object (as returned by
`make-locale') and will be used to perform the comparison;
otherwise, the current system locale is used.
string-locale>?
-- Scheme Procedure: string-locale>? s1 s2 [locale]
Compare strings S1 and S2 in a locale-dependent way.If LOCALE is
provided, it should be locale object (as returned by
`make-locale') and will be used to perform the comparison;
otherwise, the current system locale is used.
string-locale-ci<?
-- Scheme Procedure: string-locale-ci<? s1 s2 [locale]
Compare strings S1 and S2 in a case-insensitive, and
locale-dependent way. If LOCALE is provided, it should be locale
object (as returned by `make-locale') and will be used to perform
the comparison; otherwise, the current system locale is used.
string-locale-ci>?
-- Scheme Procedure: string-locale-ci>? s1 s2 [locale]
Compare strings S1 and S2 in a case-insensitive, and
locale-dependent way. If LOCALE is provided, it should be locale
object (as returned by `make-locale') and will be used to perform
the comparison; otherwise, the current system locale is used.
string-locale-ci=?
-- Scheme Procedure: string-locale-ci=? s1 s2 [locale]
Compare strings S1 and S2 in a case-insensitive, and
locale-dependent way. If LOCALE is provided, it should be locale
object (as returned by `make-locale') and will be used to perform
the comparison; otherwise, the current system locale is used.
char-locale<?
-- Scheme Procedure: char-locale<? c1 c2 [locale]
Return true if character C1 is lower than C2 according to LOCALE
or to the current locale.
char-locale>?
-- Scheme Procedure: char-locale>? c1 c2 [locale]
Return true if character C1 is greater than C2 according to LOCALE
or to the current locale.
char-locale-ci<?
-- Scheme Procedure: char-locale-ci<? c1 c2 [locale]
Return true if character C1 is lower than C2, in a case
insensitive way according to LOCALE or to the current locale.
char-locale-ci>?
-- Scheme Procedure: char-locale-ci>? c1 c2 [locale]
Return true if character C1 is greater than C2, in a case
insensitive way according to LOCALE or to the current locale.
char-locale-ci=?
-- Scheme Procedure: char-locale-ci=? c1 c2 [locale]
Return true if character C1 is equal to C2, in a case insensitive
way according to LOCALE or to the current locale.
char-locale-downcase
-- Scheme Procedure: char-locale-downcase chr [locale]
Return the lowercase character that corresponds to CHR according
to either LOCALE or the current locale.
char-locale-upcase
-- Scheme Procedure: char-locale-upcase chr [locale]
Return the uppercase character that corresponds to CHR according
to either LOCALE or the current locale.
char-locale-titlecase
-- Scheme Procedure: char-locale-titlecase chr [locale]
Return the titlecase character that corresponds to CHR according
to either LOCALE or the current locale.
string-locale-upcase
-- Scheme Procedure: string-locale-upcase str [locale]
Return a new string that is the uppercase version of STR according
to either LOCALE or the current locale.
string-locale-downcase
-- Scheme Procedure: string-locale-downcase str [locale]
Return a new string that is the down-case version of STR according
to either LOCALE or the current locale.
string-locale-titlecase
-- Scheme Procedure: string-locale-titlecase str [locale]
Return a new string that is the title-case version of STR
according to either LOCALE or the current locale.
locale-string->integer
-- Scheme Procedure: locale-string->integer str [base [locale]]
Convert string STR into an integer according to either LOCALE (a
locale object as returned by `make-locale') or the current process
locale. Return two values: an integer (on success) or `#f', and
the number of characters read from STR (`0' on failure).
locale-string->inexact
-- Scheme Procedure: locale-string->inexact str [locale]
Convert string STR into an inexact number according to either
LOCALE (a locale object as returned by `make-locale') or the
current process locale. Return two values: an inexact number (on
success) or `#f', and the number of characters read from STR (`0'
on failure).
nl-langinfo
-- Scheme Procedure: nl-langinfo item [locale]
Return a string denoting locale information for ITEM in the
current locale or that specified by LOCALE. The semantics and
arguments are the same as those of the X/Open `nl_langinfo'
function (*note `nl_langinfo': (libc)The Elegant and Fast Way.).
ftell
-- Scheme Procedure: ftell fd_port
Return an integer representing the current position of FD/PORT,
measured from the beginning. Equivalent to:
(seek port 0 SEEK_CUR)
redirect-port
-- Scheme Procedure: redirect-port old new
This procedure takes two ports and duplicates the underlying file
descriptor from OLD-PORT into NEW-PORT. The current file
descriptor in NEW-PORT will be closed. After the redirection the
two ports will share a file position and file status flags.
The return value is unspecified.
Unexpected behaviour can result if both ports are subsequently used
and the original and/or duplicate ports are buffered.
This procedure does not have any side effects on other ports or
revealed counts.
dup->fdes
-- Scheme Procedure: dup->fdes fd_or_port [fd]
Return a new integer file descriptor referring to the open file
designated by FD_OR_PORT, which must be either an open file port
or a file descriptor.
dup2
-- Scheme Procedure: dup2 oldfd newfd
A simple wrapper for the `dup2' system call. Copies the file
descriptor OLDFD to descriptor number NEWFD, replacing the
previous meaning of NEWFD. Both OLDFD and NEWFD must be integers.
Unlike for dup->fdes or primitive-move->fdes, no attempt is made
to move away ports which are using NEWFD. The return value is
unspecified.
fileno
-- Scheme Procedure: fileno port
Return the integer file descriptor underlying PORT. Does not
change its revealed count.
isatty?
-- Scheme Procedure: isatty? port
Return `#t' if PORT is using a serial non-file device, otherwise
`#f'.
fdopen
-- Scheme Procedure: fdopen fdes modes
Return a new port based on the file descriptor FDES. Modes are
given by the string MODES. The revealed count of the port is
initialized to zero. The modes string is the same as that
accepted by *note open-file: File Ports.
primitive-move->fdes
-- Scheme Procedure: primitive-move->fdes port fd
Moves the underlying file descriptor for PORT to the integer value
FDES without changing the revealed count of PORT. Any other ports
already using this descriptor will be automatically shifted to new
descriptors and their revealed counts reset to zero. The return
value is `#f' if the file descriptor already had the required
value or `#t' if it was moved.
fdes->ports
-- Scheme Procedure: fdes->ports fd
Return a list of existing ports which have FDES as an underlying
file descriptor, without changing their revealed counts.
keyword?
-- Scheme Procedure: keyword? obj
Return `#t' if the argument OBJ is a keyword, else `#f'.
symbol->keyword
-- Scheme Procedure: symbol->keyword symbol
Return the keyword with the same name as SYMBOL.
keyword->symbol
-- Scheme Procedure: keyword->symbol keyword
Return the symbol with the same name as KEYWORD.
make-list
-- Scheme Procedure: make-list n [init]
Create a list containing of N elements, where each element is
initialized to INIT. INIT defaults to the empty list `()' if not
given.
cons*
-- Scheme Procedure: cons* arg . rest
Like `list', but the last arg provides the tail of the constructed
list, returning `(cons ARG1 (cons ARG2 (cons ... ARGN)))'.
Requires at least one argument. If given one argument, that
argument is returned as result. This function is called `list*'
in some other Schemes and in Common LISP.
null?
-- Scheme Procedure: null? x
Return `#t' iff X is the empty list, else `#f'.
list?
-- Scheme Procedure: list? x
Return `#t' iff X is a proper list, else `#f'.
length
-- Scheme Procedure: length lst
Return the number of elements in list LST.
append
-- Scheme Procedure: append . args
Return a list consisting of the elements the lists passed as
arguments.
(append '(x) '(y)) => (x y)
(append '(a) '(b c d)) => (a b c d)
(append '(a (b)) '((c))) => (a (b) (c))
The resulting list is always newly allocated, except that it
shares structure with the last list argument. The last argument
may actually be any object; an improper list results if the last
argument is not a proper list.
(append '(a b) '(c . d)) => (a b c . d)
(append '() 'a) => a
append!
-- Scheme Procedure: append! . lists
A destructive version of `append' (*note Pairs and Lists:
(r5rs)Pairs and Lists.). The cdr field of each list's final pair
is changed to point to the head of the next list, so no consing is
performed. Return the mutated list.
last-pair
-- Scheme Procedure: last-pair lst
Return the last pair in LST, signalling an error if LST is
circular.
reverse
-- Scheme Procedure: reverse lst
Return a new list that contains the elements of LST but in reverse
order.
reverse!
-- Scheme Procedure: reverse! lst [new_tail]
A destructive version of `reverse' (*note Pairs and Lists:
(r5rs)Pairs and Lists.). The cdr of each cell in LST is modified
to point to the previous list element. Return the reversed list.
Caveat: because the list is modified in place, the tail of the
original list now becomes its head, and the head of the original
list now becomes the tail. Therefore, the LST symbol to which the
head of the original list was bound now points to the tail. To
ensure that the head of the modified list is not lost, it is wise
to save the return value of `reverse!'
list-ref
-- Scheme Procedure: list-ref list k
Return the Kth element from LIST.
list-set!
-- Scheme Procedure: list-set! list k val
Set the Kth element of LIST to VAL.
list-cdr-ref
-- Scheme Procedure: list-cdr-ref
implemented by the C function "scm_list_tail"
list-tail
-- Scheme Procedure: list-tail lst k
-- Scheme Procedure: list-cdr-ref lst k
Return the "tail" of LST beginning with its Kth element. The
first element of the list is considered to be element 0.
`list-tail' and `list-cdr-ref' are identical. It may help to
think of `list-cdr-ref' as accessing the Kth cdr of the list, or
returning the results of cdring K times down LST.
list-cdr-set!
-- Scheme Procedure: list-cdr-set! list k val
Set the Kth cdr of LIST to VAL.
list-head
-- Scheme Procedure: list-head lst k
Copy the first K elements from LST into a new list, and return it.
list-copy
-- Scheme Procedure: list-copy lst
Return a (newly-created) copy of LST.
list
-- Scheme Procedure: list . objs
Return a list containing OBJS, the arguments to `list'.
memq
-- Scheme Procedure: memq x lst
Return the first sublist of LST whose car is `eq?' to X where the
sublists of LST are the non-empty lists returned by `(list-tail
LST K)' for K less than the length of LST. If X does not occur in
LST, then `#f' (not the empty list) is returned.
memv
-- Scheme Procedure: memv x lst
Return the first sublist of LST whose car is `eqv?' to X where the
sublists of LST are the non-empty lists returned by `(list-tail
LST K)' for K less than the length of LST. If X does not occur in
LST, then `#f' (not the empty list) is returned.
member
-- Scheme Procedure: member x lst
Return the first sublist of LST whose car is `equal?' to X where
the sublists of LST are the non-empty lists returned by
`(list-tail LST K)' for K less than the length of LST. If X does
not occur in LST, then `#f' (not the empty list) is returned.
delq!
-- Scheme Procedure: delq! item lst
-- Scheme Procedure: delv! item lst
-- Scheme Procedure: delete! item lst
These procedures are destructive versions of `delq', `delv' and
`delete': they modify the existing LST rather than creating a new
list. Caveat evaluator: Like other destructive list functions,
these functions cannot modify the binding of LST, and so cannot be
used to delete the first element of LST destructively.
delv!
-- Scheme Procedure: delv! item lst
Destructively remove all elements from LST that are `eqv?' to ITEM.
delete!
-- Scheme Procedure: delete! item lst
Destructively remove all elements from LST that are `equal?' to
ITEM.
delq
-- Scheme Procedure: delq item lst
Return a newly-created copy of LST with elements `eq?' to ITEM
removed. This procedure mirrors `memq': `delq' compares elements
of LST against ITEM with `eq?'.
delv
-- Scheme Procedure: delv item lst
Return a newly-created copy of LST with elements `eqv?' to ITEM
removed. This procedure mirrors `memv': `delv' compares elements
of LST against ITEM with `eqv?'.
delete
-- Scheme Procedure: delete item lst
Return a newly-created copy of LST with elements `equal?' to ITEM
removed. This procedure mirrors `member': `delete' compares
elements of LST against ITEM with `equal?'.
delq1!
-- Scheme Procedure: delq1! item lst
Like `delq!', but only deletes the first occurrence of ITEM from
LST. Tests for equality using `eq?'. See also `delv1!' and
`delete1!'.
delv1!
-- Scheme Procedure: delv1! item lst
Like `delv!', but only deletes the first occurrence of ITEM from
LST. Tests for equality using `eqv?'. See also `delq1!' and
`delete1!'.
delete1!
-- Scheme Procedure: delete1! item lst
Like `delete!', but only deletes the first occurrence of ITEM from
LST. Tests for equality using `equal?'. See also `delq1!' and
`delv1!'.
filter
-- Scheme Procedure: filter pred list
Return all the elements of 2nd arg LIST that satisfy predicate
PRED. The list is not disordered - elements that appear in the
result list occur in the same order as they occur in the argument
list. The returned list may share a common tail with the argument
list. The dynamic order in which the various applications of pred
are made is not specified.
(filter even? '(0 7 8 8 43 -4)) => (0 8 8 -4)
filter!
-- Scheme Procedure: filter! pred list
Linear-update variant of `filter'.
primitive-load
-- Scheme Procedure: primitive-load filename
Load the file named FILENAME and evaluate its contents in the
top-level environment. The load paths are not searched; FILENAME
must either be a full pathname or be a pathname relative to the
current directory. If the variable `%load-hook' is defined, it
should be bound to a procedure that will be called before any code
is loaded. See the documentation for `%load-hook' later in this
section.
%package-data-dir
-- Scheme Procedure: %package-data-dir
Return the name of the directory where Scheme packages, modules and
libraries are kept. On most Unix systems, this will be
`/usr/local/share/guile'.
%library-dir
-- Scheme Procedure: %library-dir
Return the directory where the Guile Scheme library files are
installed. E.g., may return "/usr/share/guile/1.3.5".
%site-dir
-- Scheme Procedure: %site-dir
Return the directory where users should install Scheme code for use
with this version of Guile.
E.g., may return "/usr/share/guile/site/2.0".
%global-site-dir
-- Scheme Procedure: %global-site-dir
Return the directory where users should install Scheme code for use
with all versions of Guile.
E.g., may return "/usr/share/guile/site".
parse-path
-- Scheme Procedure: parse-path path [tail]
Parse PATH, which is expected to be a colon-separated string, into
a list and return the resulting list with TAIL appended. If PATH
is `#f', TAIL is returned.
search-path
-- Scheme Procedure: search-path path filename . rest
Search PATH for a directory containing a file named FILENAME. The
file must be readable, and not a directory. If we find one,
return its full filename; otherwise, return `#f'. If FILENAME is
absolute, return it unchanged. If given, EXTENSIONS is a list of
strings; for each directory in PATH, we search for FILENAME
concatenated with each EXTENSION.
%search-load-path
-- Scheme Procedure: %search-load-path filename
Search %LOAD-PATH for the file named FILENAME, which must be
readable by the current user. If FILENAME is found in the list of
paths to search or is an absolute pathname, return its full
pathname. Otherwise, return `#f'. Filenames may have any of the
optional extensions in the `%load-extensions' list;
`%search-load-path' will try each extension automatically.
%warn-auto-compilation-enabled
-- Scheme Procedure: %warn-auto-compilation-enabled
primitive-load-path
-- Scheme Procedure: primitive-load-path . args
Search %LOAD-PATH for the file named FILENAME and load it into the
top-level environment. If FILENAME is a relative pathname and is
not found in the list of search paths, an error is signalled,
unless the optional argument EXCEPTION_ON_NOT_FOUND is `#f', in
which case `#f' is returned instead.
make-syntax-transformer
-- Scheme Procedure: make-syntax-transformer name type binding
Construct a "syntax transformer".
This function is part of Guile's low-level support for the psyntax
syntax expander. Users should not call this function.
macro?
-- Scheme Procedure: macro? obj
Return `#t' if OBJ is a syntax transformer (an object that
transforms Scheme expressions at expansion-time).
Macros are actually just one kind of syntax transformer; this
procedure has its name due to historical reasons.
macro-type
-- Scheme Procedure: macro-type m
Return the type of the syntax transformer M, as passed to
`make-syntax-transformer'. If M is a primitive syntax transformer,
`#f' will be returned.
macro-name
-- Scheme Procedure: macro-name m
Return the name of the syntax transformer M.
macro-transformer
-- Scheme Procedure: macro-transformer m
Return the transformer procedure of the macro M.
If M is a syntax transformer but not a macro, `#f' will be
returned. (This can happen, for example, with primitive syntax
transformers).
macro-binding
-- Scheme Procedure: macro-binding m
Return the binding of the syntax transformer M, as passed to
`make-syntax-transformer'. If M is a primitive syntax transformer,
`#f' will be returned.
memoize-expression
-- Scheme Procedure: memoize-expression exp
Memoize the expression EXP.
memoized?
-- Scheme Procedure: memoized? obj
Return `#t' if OBJ is memoized.
unmemoize-expression
-- Scheme Procedure: unmemoize-expression m
Unmemoize the memoized expression M.
memoized-expression-typecode
-- Scheme Procedure: memoized-expression-typecode m
Return the typecode from the memoized expression M.
memoized-expression-data
-- Scheme Procedure: memoized-expression-data m
Return the data from the memoized expression M.
memoized-typecode
-- Scheme Procedure: memoized-typecode sym
Return the memoized typecode corresponding to the symbol SYM.
memoize-variable-access!
-- Scheme Procedure: memoize-variable-access! m mod
Look up and cache the variable that M will access, returning the
variable.
current-module
-- Scheme Procedure: current-module
Return the current module.
set-current-module
-- Scheme Procedure: set-current-module module
Set the current module to MODULE and return the previous current
module.
interaction-environment
-- Scheme Procedure: interaction-environment
Return a specifier for the environment that contains
implementation-defined bindings, typically a superset of those
listed in the report. The intent is that this procedure will
return the environment in which the implementation would evaluate
expressions dynamically typed by the user.
module-local-variable
-- Scheme Procedure: module-local-variable module sym
Return the variable bound to SYM in MODULE. Return `#f' is SYM is
not bound locally in MODULE.
module-variable
-- Scheme Procedure: module-variable module sym
Return the variable bound to SYM in MODULE. This may be both a
local variable or an imported variable. Return `#f' is SYM is not
bound in MODULE.
standard-eval-closure
-- Scheme Procedure: standard-eval-closure module
Return an eval closure for the module MODULE.
standard-interface-eval-closure
-- Scheme Procedure: standard-interface-eval-closure module
Return a interface eval closure for the module MODULE. Such a
closure does not allow new bindings to be added.
eval-closure-module
-- Scheme Procedure: eval-closure-module eval_closure
Return the module associated with this eval closure.
module-transformer
-- Scheme Procedure: module-transformer module
Returns the syntax expander for the given module.
module-import-interface
-- Scheme Procedure: module-import-interface module sym
Return the module or interface from which SYM is imported in
MODULE. If SYM is not imported (i.e., it is not defined in MODULE
or it is a module-local binding instead of an imported one), then
`#f' is returned.
define!
-- Scheme Procedure: define! sym value
Define SYM to be VALUE in the current module.Returns the variable
itself. Note that this is a procedure, not a macro.
module-reverse-lookup
-- Scheme Procedure: module-reverse-lookup module variable
Return the symbol under which VARIABLE is bound in MODULE or #F if
VARIABLE is not visible from MODULE. If MODULE is `#f', then the
pre-module obarray is used.
%get-pre-modules-obarray
-- Scheme Procedure: %get-pre-modules-obarray
Return the obarray that is used for all new bindings before the
module system is booted. The first call to `set-current-module'
will boot the module system.
exact?
-- Scheme Procedure: exact? x
Return `#t' if X is an exact number, `#f' otherwise.
inexact?
-- Scheme Procedure: inexact? x
Return `#t' if X is an inexact number, `#f' else.
odd?
-- Scheme Procedure: odd? n
Return `#t' if N is an odd number, `#f' otherwise.
even?
-- Scheme Procedure: even? n
Return `#t' if N is an even number, `#f' otherwise.
finite?
-- Scheme Procedure: finite? x
Return `#t' if the real number X is neither infinite nor a NaN,
`#f' otherwise.
inf?
-- Scheme Procedure: inf? x
Return `#t' if the real number X is `+inf.0' or `-inf.0'.
Otherwise return `#f'.
nan?
-- Scheme Procedure: nan? x
Return `#t' if the real number X is a NaN, or `#f' otherwise.
inf
-- Scheme Procedure: inf
Return Inf.
nan
-- Scheme Procedure: nan
Return NaN.
abs
-- Scheme Procedure: abs x
Return the absolute value of X.
quotient
-- Scheme Procedure: quotient x y
Return the quotient of the numbers X and Y.
remainder
-- Scheme Procedure: remainder x y
Return the remainder of the numbers X and Y.
(remainder 13 4) => 1
(remainder -13 4) => -1
modulo
-- Scheme Procedure: modulo x y
Return the modulo of the numbers X and Y.
(modulo 13 4) => 1
(modulo -13 4) => 3
euclidean-quotient
-- Scheme Procedure: euclidean-quotient x y
Return the integer Q such that X = Q*Y + R where 0 <= R < abs(Y).
(euclidean-quotient 123 10) => 12
(euclidean-quotient 123 -10) => -12
(euclidean-quotient -123 10) => -13
(euclidean-quotient -123 -10) => 13
(euclidean-quotient -123.2 -63.5) => 2.0
(euclidean-quotient 16/3 -10/7) => -3
euclidean-remainder
-- Scheme Procedure: euclidean-remainder x y
Return the real number R such that 0 <= R < abs(Y) and X = Q*Y + R
for some integer Q.
(euclidean-remainder 123 10) => 3
(euclidean-remainder 123 -10) => 3
(euclidean-remainder -123 10) => 7
(euclidean-remainder -123 -10) => 7
(euclidean-remainder -123.2 -63.5) => 3.8
(euclidean-remainder 16/3 -10/7) => 22/21
euclidean/
-- Scheme Procedure: euclidean/ x y
Return the integer Q and the real number R such that X = Q*Y + R
and 0 <= R < abs(Y).
(euclidean/ 123 10) => 12 and 3
(euclidean/ 123 -10) => -12 and 3
(euclidean/ -123 10) => -13 and 7
(euclidean/ -123 -10) => 13 and 7
(euclidean/ -123.2 -63.5) => 2.0 and 3.8
(euclidean/ 16/3 -10/7) => -3 and 22/21
floor-quotient
-- Scheme Procedure: floor-quotient x y
Return the floor of X / Y.
(floor-quotient 123 10) => 12
(floor-quotient 123 -10) => -13
(floor-quotient -123 10) => -13
(floor-quotient -123 -10) => 12
(floor-quotient -123.2 -63.5) => 1.0
(floor-quotient 16/3 -10/7) => -4
floor-remainder
-- Scheme Procedure: floor-remainder x y
Return the real number R such that X = Q*Y + R where Q = floor(X /
Y).
(floor-remainder 123 10) => 3
(floor-remainder 123 -10) => -7
(floor-remainder -123 10) => 7
(floor-remainder -123 -10) => -3
(floor-remainder -123.2 -63.5) => -59.7
(floor-remainder 16/3 -10/7) => -8/21
floor/
-- Scheme Procedure: floor/ x y
Return the integer Q and the real number R such that X = Q*Y + R
and Q = floor(X / Y).
(floor/ 123 10) => 12 and 3
(floor/ 123 -10) => -13 and -7
(floor/ -123 10) => -13 and 7
(floor/ -123 -10) => 12 and -3
(floor/ -123.2 -63.5) => 1.0 and -59.7
(floor/ 16/3 -10/7) => -4 and -8/21
ceiling-quotient
-- Scheme Procedure: ceiling-quotient x y
Return the ceiling of X / Y.
(ceiling-quotient 123 10) => 13
(ceiling-quotient 123 -10) => -12
(ceiling-quotient -123 10) => -12
(ceiling-quotient -123 -10) => 13
(ceiling-quotient -123.2 -63.5) => 2.0
(ceiling-quotient 16/3 -10/7) => -3
ceiling-remainder
-- Scheme Procedure: ceiling-remainder x y
Return the real number R such that X = Q*Y + R where Q = ceiling(X
/ Y).
(ceiling-remainder 123 10) => -7
(ceiling-remainder 123 -10) => 3
(ceiling-remainder -123 10) => -3
(ceiling-remainder -123 -10) => 7
(ceiling-remainder -123.2 -63.5) => 3.8
(ceiling-remainder 16/3 -10/7) => 22/21
ceiling/
-- Scheme Procedure: ceiling/ x y
Return the integer Q and the real number R such that X = Q*Y + R
and Q = ceiling(X / Y).
(ceiling/ 123 10) => 13 and -7
(ceiling/ 123 -10) => -12 and 3
(ceiling/ -123 10) => -12 and -3
(ceiling/ -123 -10) => 13 and 7
(ceiling/ -123.2 -63.5) => 2.0 and 3.8
(ceiling/ 16/3 -10/7) => -3 and 22/21
truncate-quotient
-- Scheme Procedure: truncate-quotient x y
Return X / Y rounded toward zero.
(truncate-quotient 123 10) => 12
(truncate-quotient 123 -10) => -12
(truncate-quotient -123 10) => -12
(truncate-quotient -123 -10) => 12
(truncate-quotient -123.2 -63.5) => 1.0
(truncate-quotient 16/3 -10/7) => -3
truncate-remainder
-- Scheme Procedure: truncate-remainder x y
Return the real number R such that X = Q*Y + R where Q =
truncate(X / Y).
(truncate-remainder 123 10) => 3
(truncate-remainder 123 -10) => 3
(truncate-remainder -123 10) => -3
(truncate-remainder -123 -10) => -3
(truncate-remainder -123.2 -63.5) => -59.7
(truncate-remainder 16/3 -10/7) => 22/21
truncate/
-- Scheme Procedure: truncate/ x y
Return the integer Q and the real number R such that X = Q*Y + R
and Q = truncate(X / Y).
(truncate/ 123 10) => 12 and 3
(truncate/ 123 -10) => -12 and 3
(truncate/ -123 10) => -12 and -3
(truncate/ -123 -10) => 12 and -3
(truncate/ -123.2 -63.5) => 1.0 and -59.7
(truncate/ 16/3 -10/7) => -3 and 22/21
centered-quotient
-- Scheme Procedure: centered-quotient x y
Return the integer Q such that X = Q*Y + R where -abs(Y/2) <= R <
abs(Y/2).
(centered-quotient 123 10) => 12
(centered-quotient 123 -10) => -12
(centered-quotient -123 10) => -12
(centered-quotient -123 -10) => 12
(centered-quotient -123.2 -63.5) => 2.0
(centered-quotient 16/3 -10/7) => -4
centered-remainder
-- Scheme Procedure: centered-remainder x y
Return the real number R such that -abs(Y/2) <= R < abs(Y/2) and X
= Q*Y + R for some integer Q.
(centered-remainder 123 10) => 3
(centered-remainder 123 -10) => 3
(centered-remainder -123 10) => -3
(centered-remainder -123 -10) => -3
(centered-remainder -123.2 -63.5) => 3.8
(centered-remainder 16/3 -10/7) => -8/21
centered/
-- Scheme Procedure: centered/ x y
Return the integer Q and the real number R such that X = Q*Y + R
and -abs(Y/2) <= R < abs(Y/2).
(centered/ 123 10) => 12 and 3
(centered/ 123 -10) => -12 and 3
(centered/ -123 10) => -12 and -3
(centered/ -123 -10) => 12 and -3
(centered/ -123.2 -63.5) => 2.0 and 3.8
(centered/ 16/3 -10/7) => -4 and -8/21
round-quotient
-- Scheme Procedure: round-quotient x y
Return X / Y to the nearest integer, with ties going to the
nearest even integer.
(round-quotient 123 10) => 12
(round-quotient 123 -10) => -12
(round-quotient -123 10) => -12
(round-quotient -123 -10) => 12
(round-quotient 125 10) => 12
(round-quotient 127 10) => 13
(round-quotient 135 10) => 14
(round-quotient -123.2 -63.5) => 2.0
(round-quotient 16/3 -10/7) => -4
round-remainder
-- Scheme Procedure: round-remainder x y
Return the real number R such that X = Q*Y + R, where Q is X / Y
rounded to the nearest integer, with ties going to the nearest
even integer.
(round-remainder 123 10) => 3
(round-remainder 123 -10) => 3
(round-remainder -123 10) => -3
(round-remainder -123 -10) => -3
(round-remainder 125 10) => 5
(round-remainder 127 10) => -3
(round-remainder 135 10) => -5
(round-remainder -123.2 -63.5) => 3.8
(round-remainder 16/3 -10/7) => -8/21
round/
-- Scheme Procedure: round/ x y
Return the integer Q and the real number R such that X = Q*Y + R
and Q is X / Y rounded to the nearest integer, with ties going to
the nearest even integer.
(round/ 123 10) => 12 and 3
(round/ 123 -10) => -12 and 3
(round/ -123 10) => -12 and -3
(round/ -123 -10) => 12 and -3
(round/ 125 10) => 12 and 5
(round/ 127 10) => 13 and -3
(round/ 135 10) => 14 and -5
(round/ -123.2 -63.5) => 2.0 and 3.8
(round/ 16/3 -10/7) => -4 and -8/21
gcd
-- Scheme Procedure: gcd [x [y . rest]]
Return the greatest common divisor of all parameter values. If
called without arguments, 0 is returned.
lcm
-- Scheme Procedure: lcm [x [y . rest]]
Return the least common multiple of the arguments. If called
without arguments, 1 is returned.
logand
-- Scheme Procedure: logand [x [y . rest]]
Return the bitwise AND of the integer arguments.
(logand) => -1
(logand 7) => 7
(logand #b111 #b011 #b001) => 1
logior
-- Scheme Procedure: logior [x [y . rest]]
Return the bitwise OR of the integer arguments.
(logior) => 0
(logior 7) => 7
(logior #b000 #b001 #b011) => 3
logxor
-- Scheme Procedure: logxor [x [y . rest]]
Return the bitwise XOR of the integer arguments. A bit is set in
the result if it is set in an odd number of arguments.
(logxor) => 0
(logxor 7) => 7
(logxor #b000 #b001 #b011) => 2
(logxor #b000 #b001 #b011 #b011) => 1
logtest
-- Scheme Procedure: logtest j k
Test whether J and K have any 1 bits in common. This is
equivalent to `(not (zero? (logand j k)))', but without actually
calculating the `logand', just testing for non-zero.
(logtest #b0100 #b1011) => #f
(logtest #b0100 #b0111) => #t
logbit?
-- Scheme Procedure: logbit? index j
Test whether bit number INDEX in J is set. INDEX starts from 0
for the least significant bit.
(logbit? 0 #b1101) => #t
(logbit? 1 #b1101) => #f
(logbit? 2 #b1101) => #t
(logbit? 3 #b1101) => #t
(logbit? 4 #b1101) => #f
lognot
-- Scheme Procedure: lognot n
Return the integer which is the ones-complement of the integer
argument.
(number->string (lognot #b10000000) 2)
=> "-10000001"
(number->string (lognot #b0) 2)
=> "-1"
modulo-expt
-- Scheme Procedure: modulo-expt n k m
Return N raised to the integer exponent K, modulo M.
(modulo-expt 2 3 5)
=> 3
integer-expt
-- Scheme Procedure: integer-expt n k
Return N raised to the power K. K must be an exact integer, N can
be any number.
Negative K is supported, and results in 1/N^abs(K) in the usual
way. N^0 is 1, as usual, and that includes 0^0 is 1.
(integer-expt 2 5) => 32
(integer-expt -3 3) => -27
(integer-expt 5 -3) => 1/125
(integer-expt 0 0) => 1
ash
-- Scheme Procedure: ash n cnt
Return N shifted left by CNT bits, or shifted right if CNT is
negative. This is an "arithmetic" shift.
This is effectively a multiplication by 2^CNT, and when CNT is
negative it's a division, rounded towards negative infinity.
(Note that this is not the same rounding as `quotient' does.)
With N viewed as an infinite precision twos complement, `ash'
means a left shift introducing zero bits, or a right shift
dropping bits.
(number->string (ash #b1 3) 2) => "1000"
(number->string (ash #b1010 -1) 2) => "101"
;; -23 is bits ...11101001, -6 is bits ...111010
(ash -23 -2) => -6
bit-extract
-- Scheme Procedure: bit-extract n start end
Return the integer composed of the START (inclusive) through END
(exclusive) bits of N. The STARTth bit becomes the 0-th bit in
the result.
(number->string (bit-extract #b1101101010 0 4) 2)
=> "1010"
(number->string (bit-extract #b1101101010 4 9) 2)
=> "10110"
logcount
-- Scheme Procedure: logcount n
Return the number of bits in integer N. If integer is positive,
the 1-bits in its binary representation are counted. If negative,
the 0-bits in its two's-complement binary representation are
counted. If 0, 0 is returned.
(logcount #b10101010)
=> 4
(logcount 0)
=> 0
(logcount -2)
=> 1
integer-length
-- Scheme Procedure: integer-length n
Return the number of bits necessary to represent N.
(integer-length #b10101010)
=> 8
(integer-length 0)
=> 0
(integer-length #b1111)
=> 4
number->string
-- Scheme Procedure: number->string n [radix]
Return a string holding the external representation of the number
N in the given RADIX. If N is inexact, a radix of 10 will be used.
string->number
-- Scheme Procedure: string->number string [radix]
Return a number of the maximally precise representation expressed
by the given STRING. RADIX must be an exact integer, either 2, 8,
10, or 16. If supplied, RADIX is a default radix that may be
overridden by an explicit radix prefix in STRING (e.g. "#o177").
If RADIX is not supplied, then the default radix is 10. If string
is not a syntactically valid notation for a number, then
`string->number' returns `#f'.
number?
-- Scheme Procedure: number? x
Return `#t' if X is a number, `#f' otherwise.
complex?
-- Scheme Procedure: complex? x
Return `#t' if X is a complex number, `#f' otherwise. Note that
the sets of real, rational and integer values form subsets of the
set of complex numbers, i. e. the predicate will also be fulfilled
if X is a real, rational or integer number.
real?
-- Scheme Procedure: real? x
Return `#t' if X is a real number, `#f' otherwise. Note that the
set of integer values forms a subset of the set of real numbers,
i. e. the predicate will also be fulfilled if X is an integer
number.
rational?
-- Scheme Procedure: rational? x
Return `#t' if X is a rational number, `#f' otherwise. Note that
the set of integer values forms a subset of the set of rational
numbers, i. e. the predicate will also be fulfilled if X is an
integer number.
integer?
-- Scheme Procedure: integer? x
Return `#t' if X is an integer number, `#f' else.
=
-- Scheme Procedure: = [x [y . rest]]
Return `#t' if all parameters are numerically equal.
<
-- Scheme Procedure: < [x [y . rest]]
Return `#t' if the list of parameters is monotonically increasing.
>
-- Scheme Procedure: > [x [y . rest]]
Return `#t' if the list of parameters is monotonically decreasing.
<=
-- Scheme Procedure: <= [x [y . rest]]
Return `#t' if the list of parameters is monotonically
non-decreasing.
>=
-- Scheme Procedure: >= [x [y . rest]]
Return `#t' if the list of parameters is monotonically
non-increasing.
zero?
-- Scheme Procedure: zero? z
Return `#t' if Z is an exact or inexact number equal to zero.
positive?
-- Scheme Procedure: positive? x
Return `#t' if X is an exact or inexact number greater than zero.
negative?
-- Scheme Procedure: negative? x
Return `#t' if X is an exact or inexact number less than zero.
max
-- Scheme Procedure: max [x [y . rest]]
Return the maximum of all parameter values.
min
-- Scheme Procedure: min [x [y . rest]]
Return the minimum of all parameter values.
+
-- Scheme Procedure: + [x [y . rest]]
Return the sum of all parameter values. Return 0 if called without
any parameters.
1+
-- Scheme Procedure: 1+ x
Return X+1.
-
-- Scheme Procedure: - [x [y . rest]]
If called with one argument Z1, -Z1 returned. Otherwise the sum of
all but the first argument are subtracted from the first argument.
1-
-- Scheme Procedure: 1- x
Return X-1.
*
-- Scheme Procedure: * [x [y . rest]]
Return the product of all arguments. If called without arguments,
1 is returned.
/
-- Scheme Procedure: / [x [y . rest]]
Divide the first argument by the product of the remaining
arguments. If called with one argument Z1, 1/Z1 is returned.
truncate
-- Scheme Procedure: truncate x
Round the number X towards zero.
round
-- Scheme Procedure: round x
Round the number X towards the nearest integer. When it is exactly
halfway between two integers, round towards the even one.
floor
-- Scheme Procedure: floor x
Round the number X towards minus infinity.
ceiling
-- Scheme Procedure: ceiling x
Round the number X towards infinity.
expt
-- Scheme Procedure: expt x y
Return X raised to the power of Y.
sin
-- Scheme Procedure: sin z
Compute the sine of Z.
cos
-- Scheme Procedure: cos z
Compute the cosine of Z.
tan
-- Scheme Procedure: tan z
Compute the tangent of Z.
sinh
-- Scheme Procedure: sinh z
Compute the hyperbolic sine of Z.
cosh
-- Scheme Procedure: cosh z
Compute the hyperbolic cosine of Z.
tanh
-- Scheme Procedure: tanh z
Compute the hyperbolic tangent of Z.
asin
-- Scheme Procedure: asin z
Compute the arc sine of Z.
acos
-- Scheme Procedure: acos z
Compute the arc cosine of Z.
atan
-- Scheme Procedure: atan z [y]
With one argument, compute the arc tangent of Z. If Y is present,
compute the arc tangent of Z/Y, using the sign of Z and Y to
determine the quadrant.
asinh
-- Scheme Procedure: asinh z
Compute the inverse hyperbolic sine of Z.
acosh
-- Scheme Procedure: acosh z
Compute the inverse hyperbolic cosine of Z.
atanh
-- Scheme Procedure: atanh z
Compute the inverse hyperbolic tangent of Z.
make-rectangular
-- Scheme Procedure: make-rectangular real_part imaginary_part
Return a complex number constructed of the given REAL-PART and
IMAGINARY-PART parts.
make-polar
-- Scheme Procedure: make-polar mag ang
Return the complex number MAG * e^(i * ANG).
real-part
-- Scheme Procedure: real-part z
Return the real part of the number Z.
imag-part
-- Scheme Procedure: imag-part z
Return the imaginary part of the number Z.
numerator
-- Scheme Procedure: numerator z
Return the numerator of the number Z.
denominator
-- Scheme Procedure: denominator z
Return the denominator of the number Z.
magnitude
-- Scheme Procedure: magnitude z
Return the magnitude of the number Z. This is the same as `abs'
for real arguments, but also allows complex numbers.
angle
-- Scheme Procedure: angle z
Return the angle of the complex number Z.
exact->inexact
-- Scheme Procedure: exact->inexact z
Convert the number Z to its inexact representation.
inexact->exact
-- Scheme Procedure: inexact->exact z
Return an exact number that is numerically closest to Z.
rationalize
-- Scheme Procedure: rationalize x eps
Returns the _simplest_ rational number differing from X by no more
than EPS.
As required by R5RS, `rationalize' only returns an exact result
when both its arguments are exact. Thus, you might need to use
`inexact->exact' on the arguments.
(rationalize (inexact->exact 1.2) 1/100)
=> 6/5
log
-- Scheme Procedure: log z
Return the natural logarithm of Z.
log10
-- Scheme Procedure: log10 z
Return the base 10 logarithm of Z.
exp
-- Scheme Procedure: exp z
Return e to the power of Z, where e is the base of natural
logarithms (2.71828...).
exact-integer-sqrt
-- Scheme Procedure: exact-integer-sqrt k
Return two exact non-negative integers S and R such that K = S^2 +
R and S^2 <= K < (S + 1)^2. An error is raised if K is not an
exact non-negative integer.
(exact-integer-sqrt 10) => 3 and 1
sqrt
-- Scheme Procedure: sqrt z
Return the square root of Z. Of the two possible roots (positive
and negative), the one with positive real part is returned, or if
that's zero then a positive imaginary part. Thus,
(sqrt 9.0) => 3.0
(sqrt -9.0) => 0.0+3.0i
(sqrt 1.0+1.0i) => 1.09868411346781+0.455089860562227i
(sqrt -1.0-1.0i) => 0.455089860562227-1.09868411346781i
object-properties
-- Scheme Procedure: object-properties obj
Return OBJ's property list.
set-object-properties!
-- Scheme Procedure: set-object-properties! obj alist
Set OBJ's property list to ALIST.
object-property
-- Scheme Procedure: object-property obj key
Return the property of OBJ with name KEY.
set-object-property!
-- Scheme Procedure: set-object-property! obj key value
In OBJ's property list, set the property named KEY to VALUE.
cons
-- Scheme Procedure: cons x y
Return a newly allocated pair whose car is X and whose cdr is Y.
The pair is guaranteed to be different (in the sense of `eq?')
from every previously existing object.
pair?
-- Scheme Procedure: pair? x
Return `#t' if X is a pair; otherwise return `#f'.
set-car!
-- Scheme Procedure: set-car! pair value
Stores VALUE in the car field of PAIR. The value returned by
`set-car!' is unspecified.
set-cdr!
-- Scheme Procedure: set-cdr! pair value
Stores VALUE in the cdr field of PAIR. The value returned by
`set-cdr!' is unspecified.
cdr
-- Scheme Procedure: cdr x
car
-- Scheme Procedure: car x
cddr
-- Scheme Procedure: cddr x
cdar
-- Scheme Procedure: cdar x
cadr
-- Scheme Procedure: cadr x
caar
-- Scheme Procedure: caar x
cdddr
-- Scheme Procedure: cdddr x
cddar
-- Scheme Procedure: cddar x
cdadr
-- Scheme Procedure: cdadr x
cdaar
-- Scheme Procedure: cdaar x
caddr
-- Scheme Procedure: caddr x
cadar
-- Scheme Procedure: cadar x
caadr
-- Scheme Procedure: caadr x
caaar
-- Scheme Procedure: caaar x
cddddr
-- Scheme Procedure: cddddr x
cdddar
-- Scheme Procedure: cdddar x
cddadr
-- Scheme Procedure: cddadr x
cddaar
-- Scheme Procedure: cddaar x
cdaddr
-- Scheme Procedure: cdaddr x
cdadar
-- Scheme Procedure: cdadar x
cdaadr
-- Scheme Procedure: cdaadr x
cdaaar
-- Scheme Procedure: cdaaar x
cadddr
-- Scheme Procedure: cadddr x
caddar
-- Scheme Procedure: caddar x
cadadr
-- Scheme Procedure: cadadr x
cadaar
-- Scheme Procedure: cadaar x
caaddr
-- Scheme Procedure: caaddr x
caadar
-- Scheme Procedure: caadar x
caaadr
-- Scheme Procedure: caaadr x
caaaar
-- Scheme Procedure: caaaar x
char-ready?
-- Scheme Procedure: char-ready? [port]
Return `#t' if a character is ready on input PORT and return `#f'
otherwise. If `char-ready?' returns `#t' then the next
`read-char' operation on PORT is guaranteed not to hang. If PORT
is a file port at end of file then `char-ready?' returns `#t'.
`char-ready?' exists to make it possible for a program to accept
characters from interactive ports without getting stuck waiting
for input. Any input editors associated with such ports must make
sure that characters whose existence has been asserted by
`char-ready?' cannot be rubbed out. If `char-ready?' were to
return `#f' at end of file, a port at end of file would be
indistinguishable from an interactive port that has no ready
characters.
drain-input
-- Scheme Procedure: drain-input port
This procedure clears a port's input buffers, similar to the way
that force-output clears the output buffer. The contents of the
buffers are returned as a single string, e.g.,
(define p (open-input-file ...))
(drain-input p) => empty string, nothing buffered yet.
(unread-char (read-char p) p)
(drain-input p) => initial chars from p, up to the buffer size.
Draining the buffers may be useful for cleanly finishing buffered
I/O so that the file descriptor can be used directly for further
input.
current-input-port
-- Scheme Procedure: current-input-port
Return the current input port. This is the default port used by
many input procedures. Initially, `current-input-port' returns
the "standard input" in Unix and C terminology.
current-output-port
-- Scheme Procedure: current-output-port
Return the current output port. This is the default port used by
many output procedures. Initially, `current-output-port' returns
the "standard output" in Unix and C terminology.
current-error-port
-- Scheme Procedure: current-error-port
Return the port to which errors and warnings should be sent (the
"standard error" in Unix and C terminology).
current-load-port
-- Scheme Procedure: current-load-port
Return the current-load-port. The load port is used internally by
`primitive-load'.
set-current-input-port
-- Scheme Procedure: set-current-input-port port
-- Scheme Procedure: set-current-output-port port
-- Scheme Procedure: set-current-error-port port
Change the ports returned by `current-input-port',
`current-output-port' and `current-error-port', respectively, so
that they use the supplied PORT for input or output.
set-current-output-port
-- Scheme Procedure: set-current-output-port port
Set the current default output port to PORT.
set-current-error-port
-- Scheme Procedure: set-current-error-port port
Set the current default error port to PORT.
port-revealed
-- Scheme Procedure: port-revealed port
Return the revealed count for PORT.
set-port-revealed!
-- Scheme Procedure: set-port-revealed! port rcount
Sets the revealed count for a port to a given value. The return
value is unspecified.
port-mode
-- Scheme Procedure: port-mode port
Return the port modes associated with the open port PORT. These
will not necessarily be identical to the modes used when the port
was opened, since modes such as "append" which are used only
during port creation are not retained.
close-port
-- Scheme Procedure: close-port port
Close the specified port object. Return `#t' if it successfully
closes a port or `#f' if it was already closed. An exception may
be raised if an error occurs, for example when flushing buffered
output. See also *note close: Ports and File Descriptors, for a
procedure which can close file descriptors.
close-input-port
-- Scheme Procedure: close-input-port port
Close the specified input port object. The routine has no effect
if the file has already been closed. An exception may be raised
if an error occurs. The value returned is unspecified.
See also *note close: Ports and File Descriptors, for a procedure
which can close file descriptors.
close-output-port
-- Scheme Procedure: close-output-port port
Close the specified output port object. The routine has no effect
if the file has already been closed. An exception may be raised
if an error occurs. The value returned is unspecified.
See also *note close: Ports and File Descriptors, for a procedure
which can close file descriptors.
port-for-each
-- Scheme Procedure: port-for-each proc
Apply PROC to each port in the Guile port table in turn. The
return value is unspecified. More specifically, PROC is applied
exactly once to every port that exists in the system at the time
PORT-FOR-EACH is invoked. Changes to the port table while
PORT-FOR-EACH is running have no effect as far as PORT-FOR-EACH is
concerned.
input-port?
-- Scheme Procedure: input-port? x
Return `#t' if X is an input port, otherwise return `#f'. Any
object satisfying this predicate also satisfies `port?'.
output-port?
-- Scheme Procedure: output-port? x
Return `#t' if X is an output port, otherwise return `#f'. Any
object satisfying this predicate also satisfies `port?'.
port?
-- Scheme Procedure: port? x
Return a boolean indicating whether X is a port. Equivalent to
`(or (input-port? X) (output-port? X))'.
port-closed?
-- Scheme Procedure: port-closed? port
Return `#t' if PORT is closed or `#f' if it is open.
eof-object?
-- Scheme Procedure: eof-object? x
Return `#t' if X is an end-of-file object; otherwise return `#f'.
force-output
-- Scheme Procedure: force-output [port]
Flush the specified output port, or the current output port if PORT
is omitted. The current output buffer contents are passed to the
underlying port implementation (e.g., in the case of fports, the
data will be written to the file and the output buffer will be
cleared.) It has no effect on an unbuffered port.
The return value is unspecified.
flush-all-ports
-- Scheme Procedure: flush-all-ports
Equivalent to calling `force-output' on all open output ports.
The return value is unspecified.
read-char
-- Scheme Procedure: read-char [port]
Return the next character available from PORT, updating PORT to
point to the following character. If no more characters are
available, the end-of-file object is returned.
When PORT's data cannot be decoded according to its character
encoding, a `decoding-error' is raised and PORT points past the
erroneous byte sequence.
peek-char
-- Scheme Procedure: peek-char [port]
Return the next character available from PORT, _without_ updating
PORT to point to the following character. If no more characters
are available, the end-of-file object is returned.
The value returned by a call to `peek-char' is the same as the
value that would have been returned by a call to `read-char' on
the same port. The only difference is that the very next call to
`read-char' or `peek-char' on that PORT will return the value
returned by the preceding call to `peek-char'. In particular, a
call to `peek-char' on an interactive port will hang waiting for
input whenever a call to `read-char' would have hung.
As for `read-char', a `decoding-error' may be raised if such a
situation occurs. However, unlike with `read-char', PORT still
points at the beginning of the erroneous byte sequence when the
error is raised.
unread-char
-- Scheme Procedure: unread-char cobj [port]
Place CHAR in PORT so that it will be read by the next read
operation. If called multiple times, the unread characters will
be read again in last-in first-out order. If PORT is not
supplied, the current input port is used.
unread-string
-- Scheme Procedure: unread-string str port
Place the string STR in PORT so that its characters will be read
in subsequent read operations. If called multiple times, the
unread characters will be read again in last-in first-out order.
If PORT is not supplied, the current-input-port is used.
seek
-- Scheme Procedure: seek fd_port offset whence
Sets the current position of FD/PORT to the integer OFFSET, which
is interpreted according to the value of WHENCE.
One of the following variables should be supplied for WHENCE:
-- Variable: SEEK_SET
Seek from the beginning of the file.
-- Variable: SEEK_CUR
Seek from the current position.
-- Variable: SEEK_END
Seek from the end of the file.
If FD/PORT is a file descriptor, the underlying system call is
`lseek'. PORT may be a string port.
The value returned is the new position in the file. This means
that the current position of a port can be obtained using:
(seek port 0 SEEK_CUR)
truncate-file
-- Scheme Procedure: truncate-file object [length]
Truncate FILE to LENGTH bytes. FILE can be a filename string, a
port object, or an integer file descriptor. The return value is
unspecified.
For a port or file descriptor LENGTH can be omitted, in which case
the file is truncated at the current position (per `ftell' above).
On most systems a file can be extended by giving a length greater
than the current size, but this is not mandatory in the POSIX
standard.
port-line
-- Scheme Procedure: port-line port
Return the current line number for PORT.
The first line of a file is 0. But you might want to add 1 when
printing line numbers, since starting from 1 is traditional in
error messages, and likely to be more natural to non-programmers.
set-port-line!
-- Scheme Procedure: set-port-line! port line
Set the current line number for PORT to LINE. The first line of a
file is 0.
port-column
-- Scheme Procedure: port-column port
Return the current column number of PORT. If the number is
unknown, the result is #f. Otherwise, the result is a 0-origin
integer - i.e. the first character of the first line is line 0,
column 0. (However, when you display a file position, for example
in an error message, we recommend you add 1 to get 1-origin
integers. This is because lines and column numbers traditionally
start with 1, and that is what non-programmers will find most
natural.)
set-port-column!
-- Scheme Procedure: set-port-column! port column
Set the current column of PORT. Before reading the first
character on a line the column should be 0.
port-filename
-- Scheme Procedure: port-filename port
Return the filename associated with PORT, or `#f' if no filename
is associated with the port.
set-port-filename!
-- Scheme Procedure: set-port-filename! port filename
Change the filename associated with PORT, using the current input
port if none is specified. Note that this does not change the
port's source of data, but only the value that is returned by
`port-filename' and reported in diagnostic output.
port-encoding
-- Scheme Procedure: port-encoding port
Returns, as a string, the character encoding that PORT uses to
interpret its input and output.
set-port-encoding!
-- Scheme Procedure: set-port-encoding! port enc
Sets the character encoding that will be used to interpret all
port I/O. New ports are created with the encoding appropriate for
the current locale if `setlocale' has been called or ISO-8859-1
otherwise and this procedure can be used to modify that encoding.
port-conversion-strategy
-- Scheme Procedure: port-conversion-strategy port
Returns the behavior of the port when handling a character that is
not representable in the port's current encoding. It returns the
symbol `error' if unrepresentable characters should cause
exceptions, `substitute' if the port should try to replace
unrepresentable characters with question marks or approximate
characters, or `escape' if unrepresentable characters should be
converted to string escapes.
If PORT is `#f', then the current default behavior will be
returned. New ports will have this default behavior when they are
created.
set-port-conversion-strategy!
-- Scheme Procedure: set-port-conversion-strategy! port sym
Sets the behavior of the interpreter when outputting a character
that is not representable in the port's current encoding. SYM can
be either `'error', `'substitute', or `'escape'. If it is
`'error', an error will be thrown when an unconvertible character
is encountered. If it is `'substitute', then unconvertible
characters will be replaced with approximate characters, or with
question marks if no approximately correct character is available.
If it is `'escape', it will appear as a hex escape when output.
If PORT is an open port, the conversion error behavior is set for
that port. If it is `#f', it is set as the default behavior for
any future ports that get created in this thread.
%make-void-port
-- Scheme Procedure: %make-void-port mode
Create and return a new void port. A void port acts like
`/dev/null'. The MODE argument specifies the input/output modes
for this port: see the documentation for `open-file' in *note File
Ports::.
print-options-interface
-- Scheme Procedure: print-options-interface [setting]
Option interface for the print options. Instead of using this
procedure directly, use the procedures `print-enable',
`print-disable', `print-set!' and `print-options'.
simple-format
-- Scheme Procedure: simple-format destination message . args
Write MESSAGE to DESTINATION, defaulting to the current output
port. MESSAGE can contain `~A' (was `%s') and `~S' (was `%S')
escapes. When printed, the escapes are replaced with
corresponding members of ARGS: `~A' formats using `display' and
`~S' formats using `write'. If DESTINATION is `#t', then use the
current output port, if DESTINATION is `#f', then return a string
containing the formatted text. Does not add a trailing newline.
newline
-- Scheme Procedure: newline [port]
Send a newline to PORT. If PORT is omitted, send to the current
output port.
write-char
-- Scheme Procedure: write-char chr [port]
Send character CHR to PORT.
port-with-print-state
-- Scheme Procedure: port-with-print-state port [pstate]
Create a new port which behaves like PORT, but with an included
print state PSTATE. PSTATE is optional. If PSTATE isn't supplied
and PORT already has a print state, the old print state is reused.
get-print-state
-- Scheme Procedure: get-print-state port
Return the print state of the port PORT. If PORT has no associated
print state, `#f' is returned.
set-procedure-minimum-arity!
-- Scheme Procedure: set-procedure-minimum-arity! proc req opt rest
procedure-minimum-arity
-- Scheme Procedure: procedure-minimum-arity proc
Return the "minimum arity" of a procedure.
If the procedure has only one arity, that arity is returned as a
list of three values: the number of required arguments, the number
of optional arguments, and a boolean indicating whether or not the
procedure takes rest arguments.
For a case-lambda procedure, the arity returned is the one with
the lowest minimum number of arguments, and the highest maximum
number of arguments.
If it was not possible to determine the arity of the procedure,
`#f' is returned.
procedure-properties
-- Scheme Procedure: procedure-properties proc
Return OBJ's property list.
set-procedure-properties!
-- Scheme Procedure: set-procedure-properties! proc alist
Set PROC's property list to ALIST.
procedure-property
-- Scheme Procedure: procedure-property proc key
Return the property of PROC with name KEY.
set-procedure-property!
-- Scheme Procedure: set-procedure-property! proc key val
In PROC's property list, set the property named KEY to VAL.
procedure?
-- Scheme Procedure: procedure? obj
Return `#t' if OBJ is a procedure.
thunk?
-- Scheme Procedure: thunk? obj
Return `#t' if OBJ is a thunk.
procedure-documentation
-- Scheme Procedure: procedure-documentation proc
Return the documentation string associated with `proc'. By
convention, if a procedure contains more than one expression and
the first expression is a string constant, that string is assumed
to contain documentation for that procedure.
procedure-with-setter?
-- Scheme Procedure: procedure-with-setter? obj
Return `#t' if OBJ is a procedure with an associated setter
procedure.
make-procedure-with-setter
-- Scheme Procedure: make-procedure-with-setter procedure setter
Create a new procedure which behaves like PROCEDURE, but with the
associated setter SETTER.
procedure
-- Scheme Procedure: procedure proc
Return the procedure of PROC, which must be an applicable struct.
setter
-- Scheme Procedure: setter proc
Return the setter of PROC, which must be an applicable struct with
a setter.
make-promise
-- Scheme Procedure: make-promise thunk
Create a new promise object.
`make-promise' is a procedural form of `delay'. These two
expressions are equivalent:
(delay EXP)
(make-promise (lambda () EXP))
force
-- Scheme Procedure: force promise
If the promise X has not been computed yet, compute and return X,
otherwise just return the previously computed value.
promise?
-- Scheme Procedure: promise? obj
Return true if OBJ is a promise, i.e. a delayed computation (*note
Delayed evaluation: (r5rs.info)Delayed evaluation.).
eof-object
-- Scheme Procedure: eof-object
Return the end-of-file object.
open-bytevector-input-port
-- Scheme Procedure: open-bytevector-input-port bv [transcoder]
Return an input port whose contents are drawn from bytevector BV.
make-custom-binary-input-port
-- Scheme Procedure: make-custom-binary-input-port id read_proc
get_position_proc set_position_proc close_proc
Return a new custom binary input port whose input is drained by
invoking READ_PROC and passing it a bytevector, an index where
octets should be written, and an octet count.
get-u8
-- Scheme Procedure: get-u8 port
Read an octet from PORT, a binary input port, blocking as
necessary.
lookahead-u8
-- Scheme Procedure: lookahead-u8 port
Like `get-u8' but does not update PORT to point past the octet.
get-bytevector-n
-- Scheme Procedure: get-bytevector-n port count
Read COUNT octets from PORT, blocking as necessary and return a
bytevector containing the octets read. If fewer bytes are
available, a bytevector smaller than COUNT is returned.
get-bytevector-n!
-- Scheme Procedure: get-bytevector-n! port bv start count
Read COUNT bytes from PORT and store them in BV starting at index
START. Return either the number of bytes actually read or the
end-of-file object.
get-bytevector-some
-- Scheme Procedure: get-bytevector-some port
Read from PORT, blocking as necessary, until data are available or
and end-of-file is reached. Return either a new bytevector
containing the data read or the end-of-file object.
get-bytevector-all
-- Scheme Procedure: get-bytevector-all port
Read from PORT, blocking as necessary, until the end-of-file is
reached. Return either a new bytevector containing the data read
or the end-of-file object (if no data were available).
put-u8
-- Scheme Procedure: put-u8 port octet
Write OCTET to binary port PORT.
put-bytevector
-- Scheme Procedure: put-bytevector port bv [start [count]]
Write the contents of BV to PORT, optionally starting at index
START and limiting to COUNT octets.
open-bytevector-output-port
-- Scheme Procedure: open-bytevector-output-port [transcoder]
Return two values: an output port and a procedure. The latter
should be called with zero arguments to obtain a bytevector
containing the data accumulated by the port.
make-custom-binary-output-port
-- Scheme Procedure: make-custom-binary-output-port id write_proc
get_position_proc set_position_proc close_proc
Return a new custom binary output port whose output is drained by
invoking WRITE_PROC and passing it a bytevector, an index where
octets should be written, and an octet count.
%make-transcoded-port
-- Scheme Procedure: %make-transcoded-port port
Return a new port which reads and writes to PORT
get-string-n!
-- Scheme Procedure: get-string-n! port str start count
Read up to COUNT characters from PORT into STR, starting at START.
If no characters can be read before the end of file is
encountered, the end of file object is returned. Otherwise, the
number of characters read is returned.
random
-- Scheme Procedure: random n [state]
Return a number in [0, N).
Accepts a positive integer or real n and returns a number of the
same type between zero (inclusive) and N (exclusive). The values
returned have a uniform distribution.
The optional argument STATE must be of the type produced by
`seed->random-state'. It defaults to the value of the variable
*RANDOM-STATE*. This object is used to maintain the state of the
pseudo-random-number generator and is altered as a side effect of
the random operation.
copy-random-state
-- Scheme Procedure: copy-random-state [state]
Return a copy of the random state STATE.
seed->random-state
-- Scheme Procedure: seed->random-state seed
Return a new random state using SEED.
datum->random-state
-- Scheme Procedure: datum->random-state datum
Return a new random state using DATUM, which should have been
obtained from `random-state->datum'.
random-state->datum
-- Scheme Procedure: random-state->datum state
Return a datum representation of STATE that may be written out and
read back with the Scheme reader.
random:uniform
-- Scheme Procedure: random:uniform [state]
Return a uniformly distributed inexact real random number in [0,1).
random:normal
-- Scheme Procedure: random:normal [state]
Return an inexact real in a normal distribution. The distribution
used has mean 0 and standard deviation 1. For a normal
distribution with mean m and standard deviation d use `(+ m (* d
(random:normal)))'.
random:solid-sphere!
-- Scheme Procedure: random:solid-sphere! v [state]
Fills VECT with inexact real random numbers the sum of whose
squares is less than 1.0. Thinking of VECT as coordinates in
space of dimension N = `(vector-length VECT)', the coordinates are
uniformly distributed within the unit N-sphere.
random:hollow-sphere!
-- Scheme Procedure: random:hollow-sphere! v [state]
Fills vect with inexact real random numbers the sum of whose
squares is equal to 1.0. Thinking of vect as coordinates in space
of dimension n = (vector-length vect), the coordinates are
uniformly distributed over the surface of the unit n-sphere.
random:normal-vector!
-- Scheme Procedure: random:normal-vector! v [state]
Fills vect with inexact real random numbers that are independent
and standard normally distributed (i.e., with mean 0 and variance
1).
random:exp
-- Scheme Procedure: random:exp [state]
Return an inexact real in an exponential distribution with mean 1.
For an exponential distribution with mean u use (* u (random:exp)).
random-state-from-platform
-- Scheme Procedure: random-state-from-platform
Construct a new random state seeded from a platform-specific
source of entropy, appropriate for use in non-security-critical
applications.
%read-delimited!
-- Scheme Procedure: %read-delimited! delims str gobble [port [start
[end]]]
Read characters from PORT into STR until one of the characters in
the DELIMS string is encountered. If GOBBLE is true, discard the
delimiter character; otherwise, leave it in the input stream for
the next read. If PORT is not specified, use the value of
`(current-input-port)'. If START or END are specified, store data
only into the substring of STR bounded by START and END (which
default to the beginning and end of the string, respectively).
Return a pair consisting of the delimiter that terminated the
string and the number of characters read. If reading stopped at
the end of file, the delimiter returned is the EOF-OBJECT; if the
string was filled without encountering a delimiter, this value is
`#f'.
%read-line
-- Scheme Procedure: %read-line [port]
Read a newline-terminated line from PORT, allocating storage as
necessary. The newline terminator (if any) is removed from the
string, and a pair consisting of the line and its delimiter is
returned. The delimiter may be either a newline or the
EOF-OBJECT; if `%read-line' is called at the end of file, it
returns the pair `(#<eof> . #<eof>)'.
write-line
-- Scheme Procedure: write-line obj [port]
Display OBJ and a newline character to PORT. If PORT is not
specified, `(current-output-port)' is used. This function is
equivalent to:
(display obj [port])
(newline [port])
read-options-interface
-- Scheme Procedure: read-options-interface [setting]
Option interface for the read options. Instead of using this
procedure directly, use the procedures `read-enable',
`read-disable', `read-set!' and `read-options'.
read
-- Scheme Procedure: read [port]
Read an s-expression from the input port PORT, or from the current
input port if PORT is not specified. Any whitespace before the
next token is discarded.
read-hash-extend
-- Scheme Procedure: read-hash-extend chr proc
Install the procedure PROC for reading expressions starting with
the character sequence `#' and CHR. PROC will be called with two
arguments: the character CHR and the port to read further data
from. The object returned will be the return value of `read'.
Passing `#f' for PROC will remove a previous setting.
file-encoding
-- Scheme Procedure: file-encoding port
Scans the port for an Emacs-like character coding declaration near
the top of the contents of a port with random-accessible contents.
The coding declaration is of the form `coding: XXXXX' and must
appear in a scheme comment.
Returns a string containing the character encoding of the file if
a declaration was found, or `#f' otherwise.
call-with-dynamic-root
-- Scheme Procedure: call-with-dynamic-root thunk handler
Call THUNK with a new dynamic state and within a continuation
barrier. The HANDLER catches all otherwise uncaught throws and
executes within the same dynamic context as THUNK.
dynamic-root
-- Scheme Procedure: dynamic-root
Return an object representing the current dynamic root.
These objects are only useful for comparison using `eq?'.
read-string!/partial
-- Scheme Procedure: read-string!/partial str [port_or_fdes [start
[end]]]
Read characters from a port or file descriptor into a string STR.
A port must have an underlying file descriptor -- a so-called
fport. This procedure is scsh-compatible and can efficiently read
large strings. It will:
* attempt to fill the entire string, unless the START and/or
END arguments are supplied. i.e., START defaults to 0 and
END defaults to `(string-length str)'
* use the current input port if PORT_OR_FDES is not supplied.
* return fewer than the requested number of characters in some
cases, e.g., on end of file, if interrupted by a signal, or if
not all the characters are immediately available.
* wait indefinitely for some input if no characters are
currently available, unless the port is in non-blocking mode.
* read characters from the port's input buffers if available,
instead from the underlying file descriptor.
* return `#f' if end-of-file is encountered before reading any
characters, otherwise return the number of characters read.
* return 0 if the port is in non-blocking mode and no characters
are immediately available.
* return 0 if the request is for 0 bytes, with no end-of-file
check.
write-string/partial
-- Scheme Procedure: write-string/partial str [port_or_fdes [start
[end]]]
Write characters from a string STR to a port or file descriptor.
A port must have an underlying file descriptor -- a so-called
fport. This procedure is scsh-compatible and can efficiently
write large strings. It will:
* attempt to write the entire string, unless the START and/or
END arguments are supplied. i.e., START defaults to 0 and
END defaults to `(string-length str)'
* use the current output port if PORT_OF_FDES is not supplied.
* in the case of a buffered port, store the characters in the
port's output buffer, if all will fit. If they will not fit
then any existing buffered characters will be flushed before
attempting to write the new characters directly to the
underlying file descriptor. If the port is in non-blocking
mode and buffered characters can not be flushed immediately,
then an `EAGAIN' system-error exception will be raised (Note:
scsh does not support the use of non-blocking buffered ports.)
* write fewer than the requested number of characters in some
cases, e.g., if interrupted by a signal or if not all of the
output can be accepted immediately.
* wait indefinitely for at least one character from STR to be
accepted by the port, unless the port is in non-blocking mode.
* return the number of characters accepted by the port.
* return 0 if the port is in non-blocking mode and can not
accept at least one character from STR immediately
* return 0 immediately if the request size is 0 bytes.
sigaction
-- Scheme Procedure: sigaction signum [handler [flags [thread]]]
Install or report the signal handler for a specified signal.
SIGNUM is the signal number, which can be specified using the value
of variables such as `SIGINT'.
If HANDLER is omitted, `sigaction' returns a pair: the CAR is the
current signal hander, which will be either an integer with the
value `SIG_DFL' (default action) or `SIG_IGN' (ignore), or the
Scheme procedure which handles the signal, or `#f' if a non-Scheme
procedure handles the signal. The CDR contains the current
`sigaction' flags for the handler.
If HANDLER is provided, it is installed as the new handler for
SIGNUM. HANDLER can be a Scheme procedure taking one argument, or
the value of `SIG_DFL' (default action) or `SIG_IGN' (ignore), or
`#f' to restore whatever signal handler was installed before
`sigaction' was first used. When a scheme procedure has been
specified, that procedure will run in the given THREAD. When no
thread has been given, the thread that made this call to
`sigaction' is used. Flags can optionally be specified for the
new handler. The return value is a pair with information about the
old handler as described above.
This interface does not provide access to the "signal blocking"
facility. Maybe this is not needed, since the thread support may
provide solutions to the problem of consistent access to data
structures.
restore-signals
-- Scheme Procedure: restore-signals
Return all signal handlers to the values they had before any call
to `sigaction' was made. The return value is unspecified.
alarm
-- Scheme Procedure: alarm i
Set a timer to raise a `SIGALRM' signal after the specified number
of seconds (an integer). It's advisable to install a signal
handler for `SIGALRM' beforehand, since the default action is to
terminate the process.
The return value indicates the time remaining for the previous
alarm, if any. The new value replaces the previous alarm. If
there was no previous alarm, the return value is zero.
setitimer
-- Scheme Procedure: setitimer which_timer interval_seconds
interval_microseconds value_seconds value_microseconds
Set the timer specified by WHICH_TIMER according to the given
INTERVAL_SECONDS, INTERVAL_MICROSECONDS, VALUE_SECONDS, and
VALUE_MICROSECONDS values.
Return information about the timer's previous setting. Errors are
handled as described in the guile info pages under "POSIX
Interface Conventions".
The timers available are: `ITIMER_REAL', `ITIMER_VIRTUAL', and
`ITIMER_PROF'.
The return value will be a list of two cons pairs representing the
current state of the given timer. The first pair is the seconds
and microseconds of the timer `it_interval', and the second pair is
the seconds and microseconds of the timer `it_value'.
getitimer
-- Scheme Procedure: getitimer which_timer
Return information about the timer specified by WHICH_TIMER Errors
are handled as described in the guile info pages under "POSIX
Interface Conventions".
The timers available are: `ITIMER_REAL', `ITIMER_VIRTUAL', and
`ITIMER_PROF'.
The return value will be a list of two cons pairs representing the
current state of the given timer. The first pair is the seconds
and microseconds of the timer `it_interval', and the second pair is
the seconds and microseconds of the timer `it_value'.
pause
-- Scheme Procedure: pause
Pause the current process (thread?) until a signal arrives whose
action is to either terminate the current process or invoke a
handler procedure. The return value is unspecified.
sleep
-- Scheme Procedure: sleep i
Wait for the given number of seconds (an integer) or until a signal
arrives. The return value is zero if the time elapses or the
number of seconds remaining otherwise.
See also `usleep'.
usleep
-- Scheme Procedure: usleep i
Wait the given period USECS microseconds (an integer). If a
signal arrives the wait stops and the return value is the time
remaining, in microseconds. If the period elapses with no signal
the return is zero.
On most systems the process scheduler is not microsecond accurate
and the actual period slept by `usleep' may be rounded to a system
clock tick boundary. Traditionally such ticks were 10 milliseconds
apart, and that interval is often still used.
See also `sleep'.
raise
-- Scheme Procedure: raise sig
Sends a specified signal SIG to the current process, where SIG is
as described for the kill procedure.
system
-- Scheme Procedure: system [cmd]
Execute CMD using the operating system's "command processor".
Under Unix this is usually the default shell `sh'. The value
returned is CMD's exit status as returned by `waitpid', which can
be interpreted using `status:exit-val' and friends.
If `system' is called without arguments, return a boolean
indicating whether the command processor is available.
system*
-- Scheme Procedure: system* . args
Execute the command indicated by ARGS. The first element must be
a string indicating the command to be executed, and the remaining
items must be strings representing each of the arguments to that
command.
This function returns the exit status of the command as provided by
`waitpid'. This value can be handled with `status:exit-val' and
the related functions.
`system*' is similar to `system', but accepts only one string
per-argument, and performs no shell interpretation. The command
is executed using fork and execlp. Accordingly this function may
be safer than `system' in situations where shell interpretation is
not required.
Example: (system* "echo" "foo" "bar")
getenv
-- Scheme Procedure: getenv nam
Looks up the string NAME in the current environment. The return
value is `#f' unless a string of the form `NAME=VALUE' is found,
in which case the string `VALUE' is returned.
primitive-exit
-- Scheme Procedure: primitive-exit [status]
Terminate the current process without unwinding the Scheme stack.
The exit status is STATUS if supplied, otherwise zero.
primitive-_exit
-- Scheme Procedure: primitive-_exit [status]
Terminate the current process using the _exit() system call and
without unwinding the Scheme stack. The exit status is STATUS if
supplied, otherwise zero.
This function is typically useful after a fork, to ensure no
Scheme cleanups or `atexit' handlers are run (those usually
belonging in the parent rather than the child).
restricted-vector-sort!
-- Scheme Procedure: restricted-vector-sort! vec less startpos endpos
Sort the vector VEC, using LESS for comparing the vector elements.
STARTPOS (inclusively) and ENDPOS (exclusively) delimit the range
of the vector which gets sorted. The return value is not
specified.
sorted?
-- Scheme Procedure: sorted? items less
Return `#t' iff ITEMS is a list or a vector such that for all 1 <=
i <= m, the predicate LESS returns true when applied to all
elements i - 1 and i
merge
-- Scheme Procedure: merge alist blist less
Merge two already sorted lists into one. Given two lists ALIST
and BLIST, such that `(sorted? alist less?)' and `(sorted? blist
less?)', return a new list in which the elements of ALIST and
BLIST have been stably interleaved so that `(sorted? (merge alist
blist less?) less?)'. Note: this does _not_ accept vectors.
merge!
-- Scheme Procedure: merge! alist blist less
Takes two lists ALIST and BLIST such that `(sorted? alist less?)'
and `(sorted? blist less?)' and returns a new list in which the
elements of ALIST and BLIST have been stably interleaved so that
`(sorted? (merge alist blist less?) less?)'. This is the
destructive variant of `merge' Note: this does _not_ accept
vectors.
sort!
-- Scheme Procedure: sort! items less
Sort the sequence ITEMS, which may be a list or a vector. LESS is
used for comparing the sequence elements. The sorting is
destructive, that means that the input sequence is modified to
produce the sorted result. This is not a stable sort.
sort
-- Scheme Procedure: sort items less
Sort the sequence ITEMS, which may be a list or a vector. LESS is
used for comparing the sequence elements. This is not a stable
sort.
stable-sort!
-- Scheme Procedure: stable-sort! items less
Sort the sequence ITEMS, which may be a list or a vector. LESS is
used for comparing the sequence elements. The sorting is
destructive, that means that the input sequence is modified to
produce the sorted result. This is a stable sort.
stable-sort
-- Scheme Procedure: stable-sort items less
Sort the sequence ITEMS, which may be a list or a vector. LESS is
used for comparing the sequence elements. This is a stable sort.
sort-list!
-- Scheme Procedure: sort-list! items less
Sort the list ITEMS, using LESS for comparing the list elements.
The sorting is destructive, that means that the input list is
modified to produce the sorted result. This is a stable sort.
sort-list
-- Scheme Procedure: sort-list items less
Sort the list ITEMS, using LESS for comparing the list elements.
This is a stable sort.
source-properties
-- Scheme Procedure: source-properties obj
Return the source property association list of OBJ.
set-source-properties!
-- Scheme Procedure: set-source-properties! obj alist
Install the association list ALIST as the source property list for
OBJ.
source-property
-- Scheme Procedure: source-property obj key
Return the source property specified by KEY from OBJ's source
property list.
set-source-property!
-- Scheme Procedure: set-source-property! obj key datum
Set the source property of object OBJ, which is specified by KEY
to DATUM. Normally, the key will be a symbol.
cons-source
-- Scheme Procedure: cons-source xorig x y
Create and return a new pair whose car and cdr are X and Y. Any
source properties associated with XORIG are also associated with
the new pair.
append-reverse
-- Scheme Procedure: append-reverse revhead tail
Reverse REV-HEAD, append TAIL to it, and return the result. This
is equivalent to `(append (reverse REV-HEAD) TAIL)', but its
implementation is more efficient.
(append-reverse '(1 2 3) '(4 5 6)) => (3 2 1 4 5 6)
append-reverse!
-- Scheme Procedure: append-reverse! revhead tail
Reverse REV-HEAD, append TAIL to it, and return the result. This
is equivalent to `(append! (reverse! REV-HEAD) TAIL)', but its
implementation is more efficient.
(append-reverse! (list 1 2 3) '(4 5 6)) => (3 2 1 4 5 6)
REV-HEAD may be modified in order to produce the result.
concatenate
-- Scheme Procedure: concatenate lstlst
Construct a list by appending all lists in LSTLST.
`concatenate' is the same as `(apply append LSTLST)'. It exists
because some Scheme implementations have a limit on the number of
arguments a function takes, which the `apply' might exceed. In
Guile there is no such limit.
concatenate!
-- Scheme Procedure: concatenate! lstlst
Construct a list by appending all lists in LSTLST. Those lists
may be modified to produce the result.
`concatenate!' is the same as `(apply append! LSTLST)'. It
exists because some Scheme implementations have a limit on the
number of arguments a function takes, which the `apply' might
exceed. In Guile there is no such limit.
count
-- Scheme Procedure: count pred list1 . rest
Return a count of the number of times PRED returns true when
called on elements from the given lists.
PRED is called with N parameters `(PRED ELEM1 ... ELEMN)', each
element being from the corresponding LIST1 ... LSTN. The first
call is with the first element of each list, the second with the
second element from each, and so on.
Counting stops when the end of the shortest list is reached. At
least one list must be non-circular.
delete
-- Scheme Procedure: delete x lst [pred]
Return a list containing the elements of LST but with those equal
to X deleted. The returned elements will be in the same order as
they were in LST.
Equality is determined by PRED, or `equal?' if not given. An
equality call is made just once for each element, but the order in
which the calls are made on the elements is unspecified.
The equality calls are always `(pred x elem)', ie. the given X is
first. This means for instance elements greater than 5 can be
deleted with `(delete 5 lst <)'.
LST is not modified, but the returned list might share a common
tail with LST.
delete!
-- Scheme Procedure: delete! x lst [pred]
Return a list containing the elements of LST but with those equal
to X deleted. The returned elements will be in the same order as
they were in LST.
Equality is determined by PRED, or `equal?' if not given. An
equality call is made just once for each element, but the order in
which the calls are made on the elements is unspecified.
The equality calls are always `(pred x elem)', ie. the given X is
first. This means for instance elements greater than 5 can be
deleted with `(delete 5 lst <)'.
LST may be modified to construct the returned list.
delete-duplicates
-- Scheme Procedure: delete-duplicates lst [pred]
Return a list containing the elements of LST but without
duplicates.
When elements are equal, only the first in LST is retained. Equal
elements can be anywhere in LST, they don't have to be adjacent.
The returned list will have the retained elements in the same
order as they were in LST.
Equality is determined by PRED, or `equal?' if not given. Calls
`(pred x y)' are made with element X being before Y in LST. A
call is made at most once for each combination, but the sequence
of the calls across the elements is unspecified.
LST is not modified, but the return might share a common tail with
LST.
In the worst case, this is an O(N^2) algorithm because it must
check each element against all those preceding it. For long lists
it is more efficient to sort and then compare only adjacent
elements.
delete-duplicates!
-- Scheme Procedure: delete-duplicates! lst [pred]
Return a list containing the elements of LST but without
duplicates.
When elements are equal, only the first in LST is retained. Equal
elements can be anywhere in LST, they don't have to be adjacent.
The returned list will have the retained elements in the same
order as they were in LST.
Equality is determined by PRED, or `equal?' if not given. Calls
`(pred x y)' are made with element X being before Y in LST. A
call is made at most once for each combination, but the sequence
of the calls across the elements is unspecified.
LST may be modified to construct the returned list.
In the worst case, this is an O(N^2) algorithm because it must
check each element against all those preceding it. For long lists
it is more efficient to sort and then compare only adjacent
elements.
find
-- Scheme Procedure: find pred lst
Return the first element of LST which satisfies the predicate
PRED, or return `#f' if no such element is found.
find-tail
-- Scheme Procedure: find-tail pred lst
Return the first pair of LST whose CAR satisfies the predicate
PRED, or return `#f' if no such element is found.
length+
-- Scheme Procedure: length+ lst
Return the length of LST, or `#f' if LST is circular.
list-copy
-- Scheme Procedure: list-copy lst
Return a copy of the given list LST.
LST can be a proper or improper list. And if LST is not a pair
then it's treated as the final tail of an improper list and simply
returned.
lset-difference!
-- Scheme Procedure: lset-difference! equal lst . rest
Return LST with any elements in the lists in REST removed (ie.
subtracted). For only one LST argument, just that list is
returned.
The given EQUAL procedure is used for comparing elements, called
as `(EQUAL elem1 elemN)'. The first argument is from LST and the
second from one of the subsequent lists. But exactly which calls
are made and in what order is unspecified.
(lset-difference! eqv? (list 'x 'y)) => (x y)
(lset-difference! eqv? (list 1 2 3) '(3 1)) => (2)
(lset-difference! eqv? (list 1 2 3) '(3) '(2)) => (1)
`lset-difference!' may modify LST to form its result.
assoc
-- Scheme Procedure: assoc key alist [pred]
Behaves like `assq' but uses third argument PRED? for key
comparison. If PRED? is not supplied, `equal?' is used.
(Extended from R5RS.)
partition
-- Scheme Procedure: partition pred list
Partition the elements of LIST with predicate PRED. Return two
values: the list of elements satisfying PRED and the list of
elements _not_ satisfying PRED. The order of the output lists
follows the order of LIST. LIST is not mutated. One of the
output lists may share memory with LIST.
partition!
-- Scheme Procedure: partition! pred lst
Split LST into those elements which do and don't satisfy the
predicate PRED.
The return is two values (*note Multiple Values::), the first
being a list of all elements from LST which satisfy PRED, the
second a list of those which do not.
The elements in the result lists are in the same order as in LST
but the order in which the calls `(PRED elem)' are made on the
list elements is unspecified.
LST may be modified to construct the return lists.
remove
-- Scheme Procedure: remove pred list
Return a list containing all elements from LST which do not
satisfy the predicate PRED. The elements in the result list have
the same order as in LST. The order in which PRED is applied to
the list elements is not specified.
remove!
-- Scheme Procedure: remove! pred list
Return a list containing all elements from LIST which do not
satisfy the predicate PRED. The elements in the result list have
the same order as in LIST. The order in which PRED is applied to
the list elements is not specified. LIST may be modified to build
the return list.
make-srfi-4-vector
-- Scheme Procedure: make-srfi-4-vector type len [fill]
Make a srfi-4 vector
string-null?
-- Scheme Procedure: string-null? str
Return `#t' if STR's length is zero, and `#f' otherwise.
(string-null? "") => #t
y => "foo"
(string-null? y) => #f
string-any-c-code
-- Scheme Procedure: string-any-c-code char_pred s [start [end]]
Check if CHAR_PRED is true for any character in string S.
CHAR_PRED can be a character to check for any equal to that, or a
character set (*note Character Sets::) to check for any in that
set, or a predicate procedure to call.
For a procedure, calls `(CHAR_PRED c)' are made successively on
the characters from START to END. If CHAR_PRED returns true (ie.
non-`#f'), `string-any' stops and that return value is the return
from `string-any'. The call on the last character (ie. at END-1),
if that point is reached, is a tail call.
If there are no characters in S (ie. START equals END) then the
return is `#f'.
string-every-c-code
-- Scheme Procedure: string-every-c-code char_pred s [start [end]]
Check if CHAR_PRED is true for every character in string S.
CHAR_PRED can be a character to check for every character equal to
that, or a character set (*note Character Sets::) to check for
every character being in that set, or a predicate procedure to
call.
For a procedure, calls `(CHAR_PRED c)' are made successively on
the characters from START to END. If CHAR_PRED returns `#f',
`string-every' stops and returns `#f'. The call on the last
character (ie. at END-1), if that point is reached, is a tail call
and the return from that call is the return from `string-every'.
If there are no characters in S (ie. START equals END) then the
return is `#t'.
string-tabulate
-- Scheme Procedure: string-tabulate proc len
PROC is an integer->char procedure. Construct a string of size
LEN by applying PROC to each index to produce the corresponding
string element. The order in which PROC is applied to the indices
is not specified.
string->list
-- Scheme Procedure: string->list str [start [end]]
Convert the string STR into a list of characters.
reverse-list->string
-- Scheme Procedure: reverse-list->string chrs
An efficient implementation of `(compose string->list reverse)':
(reverse-list->string '(#\a #\B #\c)) => "cBa"
string-join
-- Scheme Procedure: string-join ls [delimiter [grammar]]
Append the string in the string list LS, using the string DELIM as
a delimiter between the elements of LS. GRAMMAR is a symbol which
specifies how the delimiter is placed between the strings, and
defaults to the symbol `infix'.
`infix'
Insert the separator between list elements. An empty string
will produce an empty list.
`string-infix'
Like `infix', but will raise an error if given the empty list.
`suffix'
Insert the separator after every list element.
`prefix'
Insert the separator before each list element.
string-copy
-- Scheme Procedure: string-copy str [start [end]]
Return a freshly allocated copy of the string STR. If given,
START and END delimit the portion of STR which is copied.
string-copy!
-- Scheme Procedure: string-copy! target tstart s [start [end]]
Copy the sequence of characters from index range [START, END) in
string S to string TARGET, beginning at index TSTART. The
characters are copied left-to-right or right-to-left as needed -
the copy is guaranteed to work, even if TARGET and S are the same
string. It is an error if the copy operation runs off the end of
the target string.
substring-move!
-- Scheme Procedure: substring-move! str1 start1 end1 str2 start2
Copy the substring of STR1 bounded by START1 and END1 into STR2
beginning at position START2. STR1 and STR2 can be the same
string.
string-take
-- Scheme Procedure: string-take s n
Return the N first characters of S.
string-drop
-- Scheme Procedure: string-drop s n
Return all but the first N characters of S.
string-take-right
-- Scheme Procedure: string-take-right s n
Return the N last characters of S.
string-drop-right
-- Scheme Procedure: string-drop-right s n
Return all but the last N characters of S.
string-pad
-- Scheme Procedure: string-pad s len [chr [start [end]]]
Take that characters from START to END from the string S and
return a new string, right-padded by the character CHR to length
LEN. If the resulting string is longer than LEN, it is truncated
on the right.
string-pad-right
-- Scheme Procedure: string-pad-right s len [chr [start [end]]]
Take that characters from START to END from the string S and
return a new string, left-padded by the character CHR to length
LEN. If the resulting string is longer than LEN, it is truncated
on the left.
string-trim
-- Scheme Procedure: string-trim s [char_pred [start [end]]]
Trim S by skipping over all characters on the left that satisfy
the parameter CHAR_PRED:
* if it is the character CH, characters equal to CH are trimmed,
* if it is a procedure PRED characters that satisfy PRED are
trimmed,
* if it is a character set, characters in that set are trimmed.
If called without a CHAR_PRED argument, all whitespace is trimmed.
string-trim-right
-- Scheme Procedure: string-trim-right s [char_pred [start [end]]]
Trim S by skipping over all characters on the right that satisfy
the parameter CHAR_PRED:
* if it is the character CH, characters equal to CH are trimmed,
* if it is a procedure PRED characters that satisfy PRED are
trimmed,
* if it is a character sets, all characters in that set are
trimmed.
If called without a CHAR_PRED argument, all whitespace is trimmed.
string-trim-both
-- Scheme Procedure: string-trim-both s [char_pred [start [end]]]
Trim S by skipping over all characters on both sides of the string
that satisfy the parameter CHAR_PRED:
* if it is the character CH, characters equal to CH are trimmed,
* if it is a procedure PRED characters that satisfy PRED are
trimmed,
* if it is a character set, the characters in the set are
trimmed.
If called without a CHAR_PRED argument, all whitespace is trimmed.
string-fill!
-- Scheme Procedure: string-fill! str chr [start [end]]
Stores CHR in every element of the given STR and returns an
unspecified value.
string-compare
-- Scheme Procedure: string-compare s1 s2 proc_lt proc_eq proc_gt
[start1 [end1 [start2 [end2]]]]
Apply PROC_LT, PROC_EQ, PROC_GT to the mismatch index, depending
upon whether S1 is less than, equal to, or greater than S2. The
mismatch index is the largest index I such that for every 0 <= J <
I, S1[J] = S2[J] - that is, I is the first position that does not
match.
string-compare-ci
-- Scheme Procedure: string-compare-ci s1 s2 proc_lt proc_eq proc_gt
[start1 [end1 [start2 [end2]]]]
Apply PROC_LT, PROC_EQ, PROC_GT to the mismatch index, depending
upon whether S1 is less than, equal to, or greater than S2. The
mismatch index is the largest index I such that for every 0 <= J <
I, S1[J] = S2[J] - that is, I is the first position where the
lowercased letters do not match.
string=
-- Scheme Procedure: string= s1 s2 [start1 [end1 [start2 [end2]]]]
Return `#f' if S1 and S2 are not equal, a true value otherwise.
string<>
-- Scheme Procedure: string<> s1 s2 [start1 [end1 [start2 [end2]]]]
Return `#f' if S1 and S2 are equal, a true value otherwise.
string<
-- Scheme Procedure: string< s1 s2 [start1 [end1 [start2 [end2]]]]
Return `#f' if S1 is greater or equal to S2, a true value
otherwise.
string>
-- Scheme Procedure: string> s1 s2 [start1 [end1 [start2 [end2]]]]
Return `#f' if S1 is less or equal to S2, a true value otherwise.
string<=
-- Scheme Procedure: string<= s1 s2 [start1 [end1 [start2 [end2]]]]
Return `#f' if S1 is greater to S2, a true value otherwise.
string>=
-- Scheme Procedure: string>= s1 s2 [start1 [end1 [start2 [end2]]]]
Return `#f' if S1 is less to S2, a true value otherwise.
string-ci=
-- Scheme Procedure: string-ci= s1 s2 [start1 [end1 [start2 [end2]]]]
Return `#f' if S1 and S2 are not equal, a true value otherwise.
The character comparison is done case-insensitively.
string-ci<>
-- Scheme Procedure: string-ci<> s1 s2 [start1 [end1 [start2 [end2]]]]
Return `#f' if S1 and S2 are equal, a true value otherwise. The
character comparison is done case-insensitively.
string-ci<
-- Scheme Procedure: string-ci< s1 s2 [start1 [end1 [start2 [end2]]]]
Return `#f' if S1 is greater or equal to S2, a true value
otherwise. The character comparison is done case-insensitively.
string-ci>
-- Scheme Procedure: string-ci> s1 s2 [start1 [end1 [start2 [end2]]]]
Return `#f' if S1 is less or equal to S2, a true value otherwise.
The character comparison is done case-insensitively.
string-ci<=
-- Scheme Procedure: string-ci<= s1 s2 [start1 [end1 [start2 [end2]]]]
Return `#f' if S1 is greater to S2, a true value otherwise. The
character comparison is done case-insensitively.
string-ci>=
-- Scheme Procedure: string-ci>= s1 s2 [start1 [end1 [start2 [end2]]]]
Return `#f' if S1 is less to S2, a true value otherwise. The
character comparison is done case-insensitively.
string-hash
-- Scheme Procedure: string-hash s [bound [start [end]]]
Compute a hash value for S. the optional argument BOUND is a
non-negative exact integer specifying the range of the hash
function. A positive value restricts the return value to the range
[0,bound).
string-hash-ci
-- Scheme Procedure: string-hash-ci s [bound [start [end]]]
Compute a hash value for S. the optional argument BOUND is a
non-negative exact integer specifying the range of the hash
function. A positive value restricts the return value to the range
[0,bound).
string-prefix-length
-- Scheme Procedure: string-prefix-length s1 s2 [start1 [end1 [start2
[end2]]]]
Return the length of the longest common prefix of the two strings.
string-prefix-length-ci
-- Scheme Procedure: string-prefix-length-ci s1 s2 [start1 [end1
[start2 [end2]]]]
Return the length of the longest common prefix of the two strings,
ignoring character case.
string-suffix-length
-- Scheme Procedure: string-suffix-length s1 s2 [start1 [end1 [start2
[end2]]]]
Return the length of the longest common suffix of the two strings.
string-suffix-length-ci
-- Scheme Procedure: string-suffix-length-ci s1 s2 [start1 [end1
[start2 [end2]]]]
Return the length of the longest common suffix of the two strings,
ignoring character case.
string-prefix?
-- Scheme Procedure: string-prefix? s1 s2 [start1 [end1 [start2
[end2]]]]
Is S1 a prefix of S2?
string-prefix-ci?
-- Scheme Procedure: string-prefix-ci? s1 s2 [start1 [end1 [start2
[end2]]]]
Is S1 a prefix of S2, ignoring character case?
string-suffix?
-- Scheme Procedure: string-suffix? s1 s2 [start1 [end1 [start2
[end2]]]]
Is S1 a suffix of S2?
string-suffix-ci?
-- Scheme Procedure: string-suffix-ci? s1 s2 [start1 [end1 [start2
[end2]]]]
Is S1 a suffix of S2, ignoring character case?
string-index
-- Scheme Procedure: string-index s char_pred [start [end]]
Search through the string S from left to right, returning the
index of the first occurrence of a character which
* equals CHAR_PRED, if it is character,
* satisfies the predicate CHAR_PRED, if it is a procedure,
* is in the set CHAR_PRED, if it is a character set.
Return `#f' if no match is found.
string-index-right
-- Scheme Procedure: string-index-right s char_pred [start [end]]
Search through the string S from right to left, returning the
index of the last occurrence of a character which
* equals CHAR_PRED, if it is character,
* satisfies the predicate CHAR_PRED, if it is a procedure,
* is in the set if CHAR_PRED is a character set.
Return `#f' if no match is found.
string-rindex
-- Scheme Procedure: string-rindex s char_pred [start [end]]
Search through the string S from right to left, returning the
index of the last occurrence of a character which
* equals CHAR_PRED, if it is character,
* satisfies the predicate CHAR_PRED, if it is a procedure,
* is in the set if CHAR_PRED is a character set.
Return `#f' if no match is found.
string-skip
-- Scheme Procedure: string-skip s char_pred [start [end]]
Search through the string S from left to right, returning the
index of the first occurrence of a character which
* does not equal CHAR_PRED, if it is character,
* does not satisfy the predicate CHAR_PRED, if it is a
procedure,
* is not in the set if CHAR_PRED is a character set.
string-skip-right
-- Scheme Procedure: string-skip-right s char_pred [start [end]]
Search through the string S from right to left, returning the
index of the last occurrence of a character which
* does not equal CHAR_PRED, if it is character,
* does not satisfy the predicate CHAR_PRED, if it is a
procedure,
* is not in the set if CHAR_PRED is a character set.
string-count
-- Scheme Procedure: string-count s char_pred [start [end]]
Return the count of the number of characters in the string S which
* equals CHAR_PRED, if it is character,
* satisfies the predicate CHAR_PRED, if it is a procedure.
* is in the set CHAR_PRED, if it is a character set.
string-contains
-- Scheme Procedure: string-contains s1 s2 [start1 [end1 [start2
[end2]]]]
Does string S1 contain string S2? Return the index in S1 where S2
occurs as a substring, or false. The optional start/end indices
restrict the operation to the indicated substrings.
string-contains-ci
-- Scheme Procedure: string-contains-ci s1 s2 [start1 [end1 [start2
[end2]]]]
Does string S1 contain string S2? Return the index in S1 where S2
occurs as a substring, or false. The optional start/end indices
restrict the operation to the indicated substrings. Character
comparison is done case-insensitively.
string-upcase!
-- Scheme Procedure: string-upcase! str [start [end]]
Destructively upcase every character in `str'.
(string-upcase! y)
=> "ARRDEFG"
y
=> "ARRDEFG"
string-upcase
-- Scheme Procedure: string-upcase str [start [end]]
Upcase every character in `str'.
string-downcase!
-- Scheme Procedure: string-downcase! str [start [end]]
Destructively downcase every character in STR.
y
=> "ARRDEFG"
(string-downcase! y)
=> "arrdefg"
y
=> "arrdefg"
string-downcase
-- Scheme Procedure: string-downcase str [start [end]]
Downcase every character in STR.
string-titlecase!
-- Scheme Procedure: string-titlecase! str [start [end]]
Destructively titlecase every first character in a word in STR.
string-titlecase
-- Scheme Procedure: string-titlecase str [start [end]]
Titlecase every first character in a word in STR.
string-capitalize!
-- Scheme Procedure: string-capitalize! str
Upcase the first character of every word in STR destructively and
return STR.
y => "hello world"
(string-capitalize! y) => "Hello World"
y => "Hello World"
string-capitalize
-- Scheme Procedure: string-capitalize str
Return a freshly allocated string with the characters in STR,
where the first character of every word is capitalized.
string-reverse
-- Scheme Procedure: string-reverse str [start [end]]
Reverse the string STR. The optional arguments START and END
delimit the region of STR to operate on.
string-reverse!
-- Scheme Procedure: string-reverse! str [start [end]]
Reverse the string STR in-place. The optional arguments START and
END delimit the region of STR to operate on. The return value is
unspecified.
string-append/shared
-- Scheme Procedure: string-append/shared . rest
Like `string-append', but the result may share memory with the
argument strings.
string-concatenate
-- Scheme Procedure: string-concatenate ls
Append the elements of LS (which must be strings) together into a
single string. Guaranteed to return a freshly allocated string.
string-concatenate-reverse
-- Scheme Procedure: string-concatenate-reverse ls [final_string [end]]
Without optional arguments, this procedure is equivalent to
(string-concatenate (reverse ls))
If the optional argument FINAL_STRING is specified, it is consed
onto the beginning to LS before performing the list-reverse and
string-concatenate operations. If END is given, only the
characters of FINAL_STRING up to index END are used.
Guaranteed to return a freshly allocated string.
string-concatenate/shared
-- Scheme Procedure: string-concatenate/shared ls
Like `string-concatenate', but the result may share memory with
the strings in the list LS.
string-concatenate-reverse/shared
-- Scheme Procedure: string-concatenate-reverse/shared ls
[final_string [end]]
Like `string-concatenate-reverse', but the result may share memory
with the strings in the LS arguments.
string-map
-- Scheme Procedure: string-map proc s [start [end]]
PROC is a char->char procedure, it is mapped over S. The order in
which the procedure is applied to the string elements is not
specified.
string-map!
-- Scheme Procedure: string-map! proc s [start [end]]
PROC is a char->char procedure, it is mapped over S. The order in
which the procedure is applied to the string elements is not
specified. The string S is modified in-place, the return value is
not specified.
string-fold
-- Scheme Procedure: string-fold kons knil s [start [end]]
Fold KONS over the characters of S, with KNIL as the terminating
element, from left to right. KONS must expect two arguments: The
actual character and the last result of KONS' application.
string-fold-right
-- Scheme Procedure: string-fold-right kons knil s [start [end]]
Fold KONS over the characters of S, with KNIL as the terminating
element, from right to left. KONS must expect two arguments: The
actual character and the last result of KONS' application.
string-unfold
-- Scheme Procedure: string-unfold p f g seed [base [make_final]]
* G is used to generate a series of _seed_ values from the
initial SEED: SEED, (G SEED), (G^2 SEED), (G^3 SEED), ...
* P tells us when to stop - when it returns true when applied
to one of these seed values.
* F maps each seed value to the corresponding character in the
result string. These chars are assembled into the string in
a left-to-right order.
* BASE is the optional initial/leftmost portion of the
constructed string; it default to the empty string.
* MAKE_FINAL is applied to the terminal seed value (on which P
returns true) to produce the final/rightmost portion of the
constructed string. It defaults to `(lambda (x) )'.
string-unfold-right
-- Scheme Procedure: string-unfold-right p f g seed [base [make_final]]
* G is used to generate a series of _seed_ values from the
initial SEED: SEED, (G SEED), (G^2 SEED), (G^3 SEED), ...
* P tells us when to stop - when it returns true when applied
to one of these seed values.
* F maps each seed value to the corresponding character in the
result string. These chars are assembled into the string in
a right-to-left order.
* BASE is the optional initial/rightmost portion of the
constructed string; it default to the empty string.
* MAKE_FINAL is applied to the terminal seed value (on which P
returns true) to produce the final/leftmost portion of the
constructed string. It defaults to `(lambda (x) )'.
string-for-each
-- Scheme Procedure: string-for-each proc s [start [end]]
PROC is mapped over S in left-to-right order. The return value is
not specified.
string-for-each-index
-- Scheme Procedure: string-for-each-index proc s [start [end]]
Call `(PROC i)' for each index i in S, from left to right.
For example, to change characters to alternately upper and lower
case,
(define str (string-copy "studly"))
(string-for-each-index
(lambda (i)
(string-set! str i
((if (even? i) char-upcase char-downcase)
(string-ref str i))))
str)
str => "StUdLy"
xsubstring
-- Scheme Procedure: xsubstring s from [to [start [end]]]
This is the _extended substring_ procedure that implements
replicated copying of a substring of some string.
S is a string, START and END are optional arguments that demarcate
a substring of S, defaulting to 0 and the length of S. Replicate
this substring up and down index space, in both the positive and
negative directions. `xsubstring' returns the substring of this
string beginning at index FROM, and ending at TO, which defaults
to FROM + (END - START).
string-xcopy!
-- Scheme Procedure: string-xcopy! target tstart s sfrom [sto [start
[end]]]
Exactly the same as `xsubstring', but the extracted text is
written into the string TARGET starting at index TSTART. The
operation is not defined if `(eq? TARGET S)' or these arguments
share storage - you cannot copy a string on top of itself.
string-replace
-- Scheme Procedure: string-replace s1 s2 [start1 [end1 [start2
[end2]]]]
Return the string S1, but with the characters START1 ... END1
replaced by the characters START2 ... END2 from S2.
string-tokenize
-- Scheme Procedure: string-tokenize s [token_set [start [end]]]
Split the string S into a list of substrings, where each substring
is a maximal non-empty contiguous sequence of characters from the
character set TOKEN_SET, which defaults to `char-set:graphic'. If
START or END indices are provided, they restrict `string-tokenize'
to operating on the indicated substring of S.
string-split
-- Scheme Procedure: string-split str chr
Split the string STR into a list of the substrings delimited by
appearances of the character CHR. Note that an empty substring
between separator characters will result in an empty string in the
result list.
(string-split "root:x:0:0:root:/root:/bin/bash" #\:)
=>
("root" "x" "0" "0" "root" "/root" "/bin/bash")
(string-split "::" #\:)
=>
("" "" "")
(string-split "" #\:)
=>
("")
string-filter
-- Scheme Procedure: string-filter char_pred s [start [end]]
Filter the string S, retaining only those characters which satisfy
CHAR_PRED.
If CHAR_PRED is a procedure, it is applied to each character as a
predicate, if it is a character, it is tested for equality and if
it is a character set, it is tested for membership.
string-delete
-- Scheme Procedure: string-delete char_pred s [start [end]]
Delete characters satisfying CHAR_PRED from S.
If CHAR_PRED is a procedure, it is applied to each character as a
predicate, if it is a character, it is tested for equality and if
it is a character set, it is tested for membership.
char-set?
-- Scheme Procedure: char-set? obj
Return `#t' if OBJ is a character set, `#f' otherwise.
char-set=
-- Scheme Procedure: char-set= . char_sets
Return `#t' if all given character sets are equal.
char-set<=
-- Scheme Procedure: char-set<= . char_sets
Return `#t' if every character set CSi is a subset of character
set CSi+1.
char-set-hash
-- Scheme Procedure: char-set-hash cs [bound]
Compute a hash value for the character set CS. If BOUND is given
and non-zero, it restricts the returned value to the range 0 ...
BOUND - 1.
char-set-cursor
-- Scheme Procedure: char-set-cursor cs
Return a cursor into the character set CS.
char-set-ref
-- Scheme Procedure: char-set-ref cs cursor
Return the character at the current cursor position CURSOR in the
character set CS. It is an error to pass a cursor for which
`end-of-char-set?' returns true.
char-set-cursor-next
-- Scheme Procedure: char-set-cursor-next cs cursor
Advance the character set cursor CURSOR to the next character in
the character set CS. It is an error if the cursor given
satisfies `end-of-char-set?'.
end-of-char-set?
-- Scheme Procedure: end-of-char-set? cursor
Return `#t' if CURSOR has reached the end of a character set, `#f'
otherwise.
char-set-fold
-- Scheme Procedure: char-set-fold kons knil cs
Fold the procedure KONS over the character set CS, initializing it
with KNIL.
char-set-unfold
-- Scheme Procedure: char-set-unfold p f g seed [base_cs]
This is a fundamental constructor for character sets.
* G is used to generate a series of "seed" values from the
initial seed: SEED, (G SEED), (G^2 SEED), (G^3 SEED), ...
* P tells us when to stop - when it returns true when applied
to one of the seed values.
* F maps each seed value to a character. These characters are
added to the base character set BASE_CS to form the result;
BASE_CS defaults to the empty set.
char-set-unfold!
-- Scheme Procedure: char-set-unfold! p f g seed base_cs
This is a fundamental constructor for character sets.
* G is used to generate a series of "seed" values from the
initial seed: SEED, (G SEED), (G^2 SEED), (G^3 SEED), ...
* P tells us when to stop - when it returns true when applied
to one of the seed values.
* F maps each seed value to a character. These characters are
added to the base character set BASE_CS to form the result;
BASE_CS defaults to the empty set.
char-set-for-each
-- Scheme Procedure: char-set-for-each proc cs
Apply PROC to every character in the character set CS. The return
value is not specified.
char-set-map
-- Scheme Procedure: char-set-map proc cs
Map the procedure PROC over every character in CS. PROC must be a
character -> character procedure.
char-set-copy
-- Scheme Procedure: char-set-copy cs
Return a newly allocated character set containing all characters
in CS.
char-set
-- Scheme Procedure: char-set . rest
Return a character set containing all given characters.
list->char-set
-- Scheme Procedure: list->char-set list [base_cs]
Convert the character list LIST to a character set. If the
character set BASE_CS is given, the character in this set are also
included in the result.
list->char-set!
-- Scheme Procedure: list->char-set! list base_cs
Convert the character list LIST to a character set. The
characters are added to BASE_CS and BASE_CS is returned.
string->char-set
-- Scheme Procedure: string->char-set str [base_cs]
Convert the string STR to a character set. If the character set
BASE_CS is given, the characters in this set are also included in
the result.
string->char-set!
-- Scheme Procedure: string->char-set! str base_cs
Convert the string STR to a character set. The characters from
the string are added to BASE_CS, and BASE_CS is returned.
char-set-filter
-- Scheme Procedure: char-set-filter pred cs [base_cs]
Return a character set containing every character from CS so that
it satisfies PRED. If provided, the characters from BASE_CS are
added to the result.
char-set-filter!
-- Scheme Procedure: char-set-filter! pred cs base_cs
Return a character set containing every character from CS so that
it satisfies PRED. The characters are added to BASE_CS and
BASE_CS is returned.
ucs-range->char-set
-- Scheme Procedure: ucs-range->char-set lower upper [error [base_cs]]
Return a character set containing all characters whose character
codes lie in the half-open range [LOWER,UPPER).
If ERROR is a true value, an error is signalled if the specified
range contains characters which are not valid Unicode code points.
If ERROR is `#f', these characters are silently left out of the
resulting character set.
The characters in BASE_CS are added to the result, if given.
ucs-range->char-set!
-- Scheme Procedure: ucs-range->char-set! lower upper error base_cs
Return a character set containing all characters whose character
codes lie in the half-open range [LOWER,UPPER).
If ERROR is a true value, an error is signalled if the specified
range contains characters which are not contained in the
implemented character range. If ERROR is `#f', these characters
are silently left out of the resulting character set.
The characters are added to BASE_CS and BASE_CS is returned.
->char-set
-- Scheme Procedure: ->char-set x
Coerces x into a char-set. X may be a string, character or
char-set. A string is converted to the set of its constituent
characters; a character is converted to a singleton set; a
char-set is returned as-is.
char-set-size
-- Scheme Procedure: char-set-size cs
Return the number of elements in character set CS.
char-set-count
-- Scheme Procedure: char-set-count pred cs
Return the number of the elements int the character set CS which
satisfy the predicate PRED.
char-set->list
-- Scheme Procedure: char-set->list cs
Return a list containing the elements of the character set CS.
char-set->string
-- Scheme Procedure: char-set->string cs
Return a string containing the elements of the character set CS.
The order in which the characters are placed in the string is not
defined.
char-set-contains?
-- Scheme Procedure: char-set-contains? cs ch
Return `#t' iff the character CH is contained in the character set
CS.
char-set-every
-- Scheme Procedure: char-set-every pred cs
Return a true value if every character in the character set CS
satisfies the predicate PRED.
char-set-any
-- Scheme Procedure: char-set-any pred cs
Return a true value if any character in the character set CS
satisfies the predicate PRED.
char-set-adjoin
-- Scheme Procedure: char-set-adjoin cs . rest
Add all character arguments to the first argument, which must be a
character set.
char-set-delete
-- Scheme Procedure: char-set-delete cs . rest
Delete all character arguments from the first argument, which must
be a character set.
char-set-adjoin!
-- Scheme Procedure: char-set-adjoin! cs . rest
Add all character arguments to the first argument, which must be a
character set.
char-set-delete!
-- Scheme Procedure: char-set-delete! cs . rest
Delete all character arguments from the first argument, which must
be a character set.
char-set-complement
-- Scheme Procedure: char-set-complement cs
Return the complement of the character set CS.
char-set-union
-- Scheme Procedure: char-set-union . rest
Return the union of all argument character sets.
char-set-intersection
-- Scheme Procedure: char-set-intersection . rest
Return the intersection of all argument character sets.
char-set-difference
-- Scheme Procedure: char-set-difference cs1 . rest
Return the difference of all argument character sets.
char-set-xor
-- Scheme Procedure: char-set-xor . rest
Return the exclusive-or of all argument character sets.
char-set-diff+intersection
-- Scheme Procedure: char-set-diff+intersection cs1 . rest
Return the difference and the intersection of all argument
character sets.
char-set-complement!
-- Scheme Procedure: char-set-complement! cs
Return the complement of the character set CS.
char-set-union!
-- Scheme Procedure: char-set-union! cs1 . rest
Return the union of all argument character sets.
char-set-intersection!
-- Scheme Procedure: char-set-intersection! cs1 . rest
Return the intersection of all argument character sets.
char-set-difference!
-- Scheme Procedure: char-set-difference! cs1 . rest
Return the difference of all argument character sets.
char-set-xor!
-- Scheme Procedure: char-set-xor! cs1 . rest
Return the exclusive-or of all argument character sets.
char-set-diff+intersection!
-- Scheme Procedure: char-set-diff+intersection! cs1 cs2 . rest
Return the difference and the intersection of all argument
character sets.
%char-set-dump
-- Scheme Procedure: %char-set-dump charset
Returns an association list containing debugging information for
CHARSET. The association list has the following entries.
`char-set'
The char-set itself.
`len'
The number of character ranges the char-set contains
`ranges'
A list of lists where each sublist a range of code points and
their associated characters
log2-binary-factors
-- Scheme Procedure: log2-binary-factors n
Return a count of how many factors of 2 are present in N. This is
also the bit index of the lowest 1 bit in N. If N is 0, the
return is -1.
(log2-binary-factors 6) => 1
(log2-binary-factors -8) => 3
copy-bit
-- Scheme Procedure: copy-bit index n newbit
Return N with the bit at INDEX set according to NEWBIT. NEWBIT
should be `#t' to set the bit to 1, or `#f' to set it to 0. Bits
other than at INDEX are unchanged in the return.
(copy-bit 1 #b0101 #t) => 7
rotate-bit-field
-- Scheme Procedure: rotate-bit-field n count start end
Return N with the bit field from START (inclusive) to END
(exclusive) rotated upwards by COUNT bits.
COUNT can be positive or negative, and it can be more than the
field width (it'll be reduced modulo the width).
(rotate-bit-field #b0110 2 1 4) => #b1010
reverse-bit-field
-- Scheme Procedure: reverse-bit-field n start end
Return N with the bits between START (inclusive) to END
(exclusive) reversed.
(reverse-bit-field #b101001 2 4) => #b100101
integer->list
-- Scheme Procedure: integer->list n [len]
Return bits from N in the form of a list of `#t' for 1 and `#f'
for 0. The least significant LEN bits are returned, and the first
list element is the most significant of those bits. If LEN is not
given, the default is `(integer-length N)' (*note Bitwise
Operations::).
(integer->list 6) => (#t #t #f)
(integer->list 1 4) => (#f #f #f #t)
list->integer
-- Scheme Procedure: list->integer lst
Return an integer formed bitwise from the given LST list of
booleans. Each boolean is `#t' for a 1 and `#f' for a 0. The
first element becomes the most significant bit in the return.
(list->integer '(#t #f #t #f)) => 10
booleans->integer
-- Scheme Procedure: booleans->integer
implemented by the C function "scm_srfi60_list_to_integer"
%get-stack-size
-- Scheme Procedure: %get-stack-size
Return the current thread's C stack size (in Scheme objects).
stack?
-- Scheme Procedure: stack? obj
Return `#t' if OBJ is a calling stack.
make-stack
-- Scheme Procedure: make-stack obj . args
Create a new stack. If OBJ is `#t', the current evaluation stack
is used for creating the stack frames, otherwise the frames are
taken from OBJ (which must be a continuation or a frame object).
ARGS should be a list containing any combination of integer,
procedure, prompt tag and `#t' values.
These values specify various ways of cutting away uninteresting
stack frames from the top and bottom of the stack that
`make-stack' returns. They come in pairs like this: `(INNER_CUT_1
OUTER_CUT_1 INNER_CUT_2 OUTER_CUT_2 ...)'.
Each INNER_CUT_N can be `#t', an integer, a prompt tag, or a
procedure. `#t' means to cut away all frames up to but excluding
the first user module frame. An integer means to cut away exactly
that number of frames. A prompt tag means to cut away all frames
that are inside a prompt with the given tag. A procedure means to
cut away all frames up to but excluding the application frame
whose procedure matches the specified one.
Each OUTER_CUT_N can be an integer, a prompt tag, or a procedure.
An integer means to cut away that number of frames. A prompt tag
means to cut away all frames that are outside a prompt with the
given tag. A procedure means to cut away frames down to but
excluding the application frame whose procedure matches the
specified one.
If the OUTER_CUT_N of the last pair is missing, it is taken as 0.
stack-id
-- Scheme Procedure: stack-id stack
Return the identifier given to STACK by `start-stack'.
stack-ref
-- Scheme Procedure: stack-ref stack index
Return the INDEX'th frame from STACK.
stack-length
-- Scheme Procedure: stack-length stack
Return the length of STACK.
get-internal-real-time
-- Scheme Procedure: get-internal-real-time
Return the number of time units since the interpreter was started.
times
-- Scheme Procedure: times
Return an object with information about real and processor time.
The following procedures accept such an object as an argument and
return a selected component:
`tms:clock'
The current real time, expressed as time units relative to an
arbitrary base.
`tms:utime'
The CPU time units used by the calling process.
`tms:stime'
The CPU time units used by the system on behalf of the calling
process.
`tms:cutime'
The CPU time units used by terminated child processes of the
calling process, whose status has been collected (e.g., using
`waitpid').
`tms:cstime'
Similarly, the CPU times units used by the system on behalf of
terminated child processes.
get-internal-run-time
-- Scheme Procedure: get-internal-run-time
Return the number of time units of processor time used by the
interpreter. Both _system_ and _user_ time are included but
subprocesses are not.
current-time
-- Scheme Procedure: current-time
Return the number of seconds since 1970-01-01 00:00:00 UTC,
excluding leap seconds.
gettimeofday
-- Scheme Procedure: gettimeofday
Return a pair containing the number of seconds and microseconds
since 1970-01-01 00:00:00 UTC, excluding leap seconds. Note:
whether true microsecond resolution is available depends on the
operating system.
localtime
-- Scheme Procedure: localtime time [zone]
Return an object representing the broken down components of TIME,
an integer like the one returned by `current-time'. The time zone
for the calculation is optionally specified by ZONE (a string),
otherwise the `TZ' environment variable or the system default is
used.
gmtime
-- Scheme Procedure: gmtime time
Return an object representing the broken down components of TIME,
an integer like the one returned by `current-time'. The values
are calculated for UTC.
mktime
-- Scheme Procedure: mktime sbd_time [zone]
BD-TIME is an object representing broken down time and `zone' is
an optional time zone specifier (otherwise the TZ environment
variable or the system default is used).
Returns a pair: the car is a corresponding integer time value like
that returned by `current-time'; the cdr is a broken down time
object, similar to as BD-TIME but with normalized values.
tzset
-- Scheme Procedure: tzset
Initialize the timezone from the TZ environment variable or the
system default. It's not usually necessary to call this procedure
since it's done automatically by other procedures that depend on
the timezone.
strftime
-- Scheme Procedure: strftime format stime
Return a string which is broken-down time structure STIME
formatted according to the given FORMAT string.
FORMAT contains field specifications introduced by a `%'
character. See *note Formatting Calendar Time: (libc)Formatting
Calendar Time, or `man 3 strftime', for the available formatting.
(strftime "%c" (localtime (current-time)))
=> "Mon Mar 11 20:17:43 2002"
If `setlocale' has been called (*note Locales::), month and day
names are from the current locale and in the locale character set.
strptime
-- Scheme Procedure: strptime format string
Performs the reverse action to `strftime', parsing STRING
according to the specification supplied in TEMPLATE. The
interpretation of month and day names is dependent on the current
locale. The value returned is a pair. The car has an object with
time components in the form returned by `localtime' or `gmtime',
but the time zone components are not usefully set. The cdr
reports the number of characters from STRING which were used for
the conversion.
%string-dump
-- Scheme Procedure: %string-dump str
Returns an association list containing debugging information for
STR. The association list has the following entries.
`string'
The string itself.
`start'
The start index of the string into its stringbuf
`length'
The length of the string
`shared'
If this string is a substring, it returns its parent string.
Otherwise, it returns `#f'
`read-only'
`#t' if the string is read-only
`stringbuf-chars'
A new string containing this string's stringbuf's characters
`stringbuf-length'
The number of characters in this stringbuf
`stringbuf-shared'
`#t' if this stringbuf is shared
`stringbuf-wide'
`#t' if this stringbuf's characters are stored in a 32-bit
buffer, or `#f' if they are stored in an 8-bit buffer
%symbol-dump
-- Scheme Procedure: %symbol-dump sym
Returns an association list containing debugging information for
SYM. The association list has the following entries.
`symbol'
The symbol itself
`hash'
Its hash value
`interned'
`#t' if it is an interned symbol
`stringbuf-chars'
A new string containing this symbols's stringbuf's characters
`stringbuf-length'
The number of characters in this stringbuf
`stringbuf-shared'
`#t' if this stringbuf is shared
`stringbuf-wide'
`#t' if this stringbuf's characters are stored in a 32-bit
buffer, or `#f' if they are stored in an 8-bit buffer
string?
-- Scheme Procedure: string? obj
Return `#t' if OBJ is a string, else `#f'.
list->string
-- Scheme Procedure: list->string
implemented by the C function "scm_string"
string
-- Scheme Procedure: string . chrs
-- Scheme Procedure: list->string chrs
Return a newly allocated string composed of the arguments, CHRS.
make-string
-- Scheme Procedure: make-string k [chr]
Return a newly allocated string of length K. If CHR is given,
then all elements of the string are initialized to CHR, otherwise
the contents of the STRING are all set to # UL.
string-length
-- Scheme Procedure: string-length string
Return the number of characters in STRING.
string-bytes-per-char
-- Scheme Procedure: string-bytes-per-char string
Return the bytes used to represent a character in STRING.This will
return 1 or 4.
string-ref
-- Scheme Procedure: string-ref str k
Return character K of STR using zero-origin indexing. K must be a
valid index of STR.
string-set!
-- Scheme Procedure: string-set! str k chr
Store CHR in element K of STR and return an unspecified value. K
must be a valid index of STR.
substring
-- Scheme Procedure: substring str start [end]
Return a newly allocated string formed from the characters of STR
beginning with index START (inclusive) and ending with index END
(exclusive). STR must be a string, START and END must be exact
integers satisfying:
0 <= START <= END <= (string-length STR).
substring/read-only
-- Scheme Procedure: substring/read-only str start [end]
Return a newly allocated string formed from the characters of STR
beginning with index START (inclusive) and ending with index END
(exclusive). STR must be a string, START and END must be exact
integers satisfying:
0 <= START <= END <= (string-length STR).
The returned string is read-only.
substring/copy
-- Scheme Procedure: substring/copy str start [end]
Return a newly allocated string formed from the characters of STR
beginning with index START (inclusive) and ending with index END
(exclusive). STR must be a string, START and END must be exact
integers satisfying:
0 <= START <= END <= (string-length STR).
substring/shared
-- Scheme Procedure: substring/shared str start [end]
Return string that indirectly refers to the characters of STR
beginning with index START (inclusive) and ending with index END
(exclusive). STR must be a string, START and END must be exact
integers satisfying:
0 <= START <= END <= (string-length STR).
string-append
-- Scheme Procedure: string-append . args
Return a newly allocated string whose characters form the
concatenation of the given strings, ARGS.
string-normalize-nfc
-- Scheme Procedure: string-normalize-nfc string
Returns the NFC normalized form of STRING.
string-normalize-nfd
-- Scheme Procedure: string-normalize-nfd string
Returns the NFD normalized form of STRING.
string-normalize-nfkc
-- Scheme Procedure: string-normalize-nfkc string
Returns the NFKC normalized form of STRING.
string-normalize-nfkd
-- Scheme Procedure: string-normalize-nfkd string
Returns the NFKD normalized form of STRING.
string=?
-- Scheme Procedure: string=? [s1 [s2 . rest]]
Lexicographic equality predicate; return `#t' if the two strings
are the same length and contain the same characters in the same
positions, otherwise return `#f'.
The procedure `string-ci=?' treats upper and lower case letters as
though they were the same character, but `string=?' treats upper
and lower case as distinct characters.
string-ci=?
-- Scheme Procedure: string-ci=? [s1 [s2 . rest]]
Case-insensitive string equality predicate; return `#t' if the two
strings are the same length and their component characters match
(ignoring case) at each position; otherwise return `#f'.
string<?
-- Scheme Procedure: string<? [s1 [s2 . rest]]
Lexicographic ordering predicate; return `#t' if S1 is
lexicographically less than S2.
string<=?
-- Scheme Procedure: string<=? [s1 [s2 . rest]]
Lexicographic ordering predicate; return `#t' if S1 is
lexicographically less than or equal to S2.
string>?
-- Scheme Procedure: string>? [s1 [s2 . rest]]
Lexicographic ordering predicate; return `#t' if S1 is
lexicographically greater than S2.
string>=?
-- Scheme Procedure: string>=? [s1 [s2 . rest]]
Lexicographic ordering predicate; return `#t' if S1 is
lexicographically greater than or equal to S2.
string-ci<?
-- Scheme Procedure: string-ci<? [s1 [s2 . rest]]
Case insensitive lexicographic ordering predicate; return `#t' if
S1 is lexicographically less than S2 regardless of case.
string-ci<=?
-- Scheme Procedure: string-ci<=? [s1 [s2 . rest]]
Case insensitive lexicographic ordering predicate; return `#t' if
S1 is lexicographically less than or equal to S2 regardless of
case.
string-ci>?
-- Scheme Procedure: string-ci>? [s1 [s2 . rest]]
Case insensitive lexicographic ordering predicate; return `#t' if
S1 is lexicographically greater than S2 regardless of case.
string-ci>=?
-- Scheme Procedure: string-ci>=? [s1 [s2 . rest]]
Case insensitive lexicographic ordering predicate; return `#t' if
S1 is lexicographically greater than or equal to S2 regardless of
case.
object->string
-- Scheme Procedure: object->string obj [printer]
Return a Scheme string obtained by printing OBJ. Printing
function can be specified by the optional second argument PRINTER
(default: `write').
call-with-output-string
-- Scheme Procedure: call-with-output-string proc
Calls the one-argument procedure PROC with a newly created output
port. When the function returns, the string composed of the
characters written into the port is returned.
call-with-input-string
-- Scheme Procedure: call-with-input-string string proc
Calls the one-argument procedure PROC with a newly created input
port from which STRING's contents may be read. The value yielded
by the PROC is returned.
open-input-string
-- Scheme Procedure: open-input-string str
Take a string and return an input port that delivers characters
from the string. The port can be closed by `close-input-port',
though its storage will be reclaimed by the garbage collector if
it becomes inaccessible.
open-output-string
-- Scheme Procedure: open-output-string
Return an output port that will accumulate characters for
retrieval by `get-output-string'. The port can be closed by the
procedure `close-output-port', though its storage will be
reclaimed by the garbage collector if it becomes inaccessible.
get-output-string
-- Scheme Procedure: get-output-string port
Given an output port created by `open-output-string', return a
string consisting of the characters that have been output to the
port so far.
eval-string
-- Scheme Procedure: eval-string string [module]
Evaluate STRING as the text representation of a Scheme form or
forms, and return whatever value they produce. Evaluation takes
place in the given module, or the current module when no module is
given. While the code is evaluated, the given module is made the
current one. The current module is restored when this procedure
returns.
make-struct-layout
-- Scheme Procedure: make-struct-layout fields
Return a new structure layout object.
FIELDS must be a string made up of pairs of characters strung
together. The first character of each pair describes a field
type, the second a field protection. Allowed types are 'p' for
GC-protected Scheme data, 'u' for unprotected binary data, and 's'
for a field that points to the structure itself. Allowed
protections are 'w' for mutable fields, 'h' for hidden fields, 'r'
for read-only fields, and 'o' for opaque fields.
Hidden fields are writable, but they will not consume an
initializer arg passed to `make-struct'. They are useful to add
slots to a struct in a way that preserves backward-compatibility
with existing calls to `make-struct', especially for derived
vtables.
The last field protection specification may be capitalized to
indicate that the field is a tail-array.
struct?
-- Scheme Procedure: struct? x
Return `#t' iff X is a structure object, else `#f'.
struct-vtable?
-- Scheme Procedure: struct-vtable? x
Return `#t' iff X is a vtable structure.
make-struct
-- Scheme Procedure: make-struct vtable tail_array_size . init
Create a new structure.
TYPE must be a vtable structure (*note Vtables::).
TAIL-ELTS must be a non-negative integer. If the layout
specification indicated by TYPE includes a tail-array, this is the
number of elements allocated to that array.
The INIT1, ... are optional arguments describing how successive
fields of the structure should be initialized. Only fields with
protection 'r' or 'w' can be initialized, except for fields of
type 's', which are automatically initialized to point to the new
structure itself. Fields with protection 'o' can not be
initialized by Scheme programs.
If fewer optional arguments than initializable fields are supplied,
fields of type 'p' get default value #f while fields of type 'u'
are initialized to 0.
For more information, see the documentation for
`make-vtable-vtable'.
make-vtable-vtable
-- Scheme Procedure: make-vtable-vtable user_fields tail_array_size .
init
Return a new, self-describing vtable structure.
USER-FIELDS is a string describing user defined fields of the
vtable beginning at index `vtable-offset-user' (see
`make-struct-layout').
TAIL-SIZE specifies the size of the tail-array (if any) of this
vtable.
INIT1, ... are the optional initializers for the fields of the
vtable.
Vtables have one initializable system field--the struct printer.
This field comes before the user fields in the initializers passed
to `make-vtable-vtable' and `make-struct', and thus works as a
third optional argument to `make-vtable-vtable' and a fourth to
`make-struct' when creating vtables:
If the value is a procedure, it will be called instead of the
standard printer whenever a struct described by this vtable is
printed. The procedure will be called with arguments STRUCT and
PORT.
The structure of a struct is described by a vtable, so the vtable
is in essence the type of the struct. The vtable is itself a
struct with a vtable. This could go on forever if it weren't for
the vtable-vtables which are self-describing vtables, and thus
terminate the chain.
There are several potential ways of using structs, but the standard
one is to use three kinds of structs, together building up a type
sub-system: one vtable-vtable working as the root and one or
several "types", each with a set of "instances". (The
vtable-vtable should be compared to the class <class> which is the
class of itself.)
(define ball-root (make-vtable-vtable "pr" 0))
(define (make-ball-type ball-color)
(make-struct ball-root 0
(make-struct-layout "pw")
(lambda (ball port)
(format port "#<a ~A ball owned by ~A>"
(color ball)
(owner ball)))
ball-color))
(define (color ball) (struct-ref (struct-vtable ball) vtable-offset-user))
(define (owner ball) (struct-ref ball 0))
(define red (make-ball-type 'red))
(define green (make-ball-type 'green))
(define (make-ball type owner) (make-struct type 0 owner))
(define ball (make-ball green 'Nisse))
ball => #<a green ball owned by Nisse>
make-vtable
-- Scheme Procedure: make-vtable fields [printer]
Create a vtable, for creating structures with the given FIELDS.
The optional PRINTER argument is a function to be called `(PRINTER
struct port)' on the structures created. It should look at STRUCT
and write to PORT.
struct-ref
-- Scheme Procedure: struct-ref handle pos
Access the Nth field of STRUCT.
If the field is of type 'p', then it can be set to an arbitrary
value.
If the field is of type 'u', then it can only be set to a
non-negative integer value small enough to fit in one machine word.
struct-set!
-- Scheme Procedure: struct-set! handle pos val
Set the slot of the structure HANDLE with index POS to VAL.
Signal an error if the slot can not be written to.
struct-vtable
-- Scheme Procedure: struct-vtable handle
Return the vtable structure that describes the type of STRUCT.
struct-vtable-tag
-- Scheme Procedure: struct-vtable-tag handle
Return the vtable tag of the structure HANDLE.
struct-vtable-name
-- Scheme Procedure: struct-vtable-name vtable
Return the name of the vtable VTABLE.
set-struct-vtable-name!
-- Scheme Procedure: set-struct-vtable-name! vtable name
Set the name of the vtable VTABLE to NAME.
symbol?
-- Scheme Procedure: symbol? obj
Return `#t' if OBJ is a symbol, otherwise return `#f'.
symbol-interned?
-- Scheme Procedure: symbol-interned? symbol
Return `#t' if SYMBOL is interned, otherwise return `#f'.
make-symbol
-- Scheme Procedure: make-symbol name
Return a new uninterned symbol with the name NAME. The returned
symbol is guaranteed to be unique and future calls to
`string->symbol' will not return it.
symbol->string
-- Scheme Procedure: symbol->string s
Return the name of SYMBOL as a string. If the symbol was part of
an object returned as the value of a literal expression (section
*note Literal expressions: (r5rs)Literal expressions.) or by a
call to the `read' procedure, and its name contains alphabetic
characters, then the string returned will contain characters in
the implementation's preferred standard case--some implementations
will prefer upper case, others lower case. If the symbol was
returned by `string->symbol', the case of characters in the string
returned will be the same as the case in the string that was
passed to `string->symbol'. It is an error to apply mutation
procedures like `string-set!' to strings returned by this
procedure.
The following examples assume that the implementation's standard
case is lower case:
(symbol->string 'flying-fish) => "flying-fish"
(symbol->string 'Martin) => "martin"
(symbol->string
(string->symbol "Malvina")) => "Malvina"
string->symbol
-- Scheme Procedure: string->symbol string
Return the symbol whose name is STRING. This procedure can create
symbols with names containing special characters or letters in the
non-standard case, but it is usually a bad idea to create such
symbols because in some implementations of Scheme they cannot be
read as themselves. See `symbol->string'.
The following examples assume that the implementation's standard
case is lower case:
(eq? 'mISSISSIppi 'mississippi) => #t
(string->symbol "mISSISSIppi") => the symbol with name "mISSISSIppi"
(eq? 'bitBlt (string->symbol "bitBlt")) => #f
(eq? 'JollyWog
(string->symbol (symbol->string 'JollyWog))) => #t
(string=? "K. Harper, M.D."
(symbol->string
(string->symbol "K. Harper, M.D."))) =>#t
string-ci->symbol
-- Scheme Procedure: string-ci->symbol str
Return the symbol whose name is STR. STR is converted to
lowercase before the conversion is done, if Guile is currently
reading symbols case-insensitively.
gensym
-- Scheme Procedure: gensym [prefix]
Create a new symbol with a name constructed from a prefix and a
counter value. The string PREFIX can be specified as an optional
argument. Default prefix is ` g'. The counter is increased by 1
at each call. There is no provision for resetting the counter.
symbol-hash
-- Scheme Procedure: symbol-hash symbol
Return a hash value for SYMBOL.
symbol-fref
-- Scheme Procedure: symbol-fref s
Return the contents of SYMBOL's "function slot".
symbol-pref
-- Scheme Procedure: symbol-pref s
Return the "property list" currently associated with SYMBOL.
symbol-fset!
-- Scheme Procedure: symbol-fset! s val
Change the binding of SYMBOL's function slot.
symbol-pset!
-- Scheme Procedure: symbol-pset! s val
Change the binding of SYMBOL's property slot.
call-with-new-thread
-- Scheme Procedure: call-with-new-thread thunk [handler]
Call `thunk' in a new thread and with a new dynamic state,
returning a new thread object representing the thread. The
procedure THUNK is called via `with-continuation-barrier'.
When HANDLER is specified, then THUNK is called from within a
`catch' with tag `#t' that has HANDLER as its handler. This catch
is established inside the continuation barrier.
Once THUNK or HANDLER returns, the return value is made the _exit
value_ of the thread and the thread is terminated.
yield
-- Scheme Procedure: yield
Move the calling thread to the end of the scheduling queue.
cancel-thread
-- Scheme Procedure: cancel-thread thread
Asynchronously force the target THREAD to terminate. THREAD cannot
be the current thread, and if THREAD has already terminated or
been signaled to terminate, this function is a no-op.
set-thread-cleanup!
-- Scheme Procedure: set-thread-cleanup! thread proc
Set the thunk PROC as the cleanup handler for the thread THREAD.
This handler will be called when the thread exits.
thread-cleanup
-- Scheme Procedure: thread-cleanup thread
Return the cleanup handler installed for the thread THREAD.
join-thread
-- Scheme Procedure: join-thread thread [timeout [timeoutval]]
Suspend execution of the calling thread until the target THREAD
terminates, unless the target THREAD has already terminated.
thread?
-- Scheme Procedure: thread? obj
Return `#t' if OBJ is a thread.
make-mutex
-- Scheme Procedure: make-mutex . flags
Create a new mutex.
make-recursive-mutex
-- Scheme Procedure: make-recursive-mutex
Create a new recursive mutex.
lock-mutex
-- Scheme Procedure: lock-mutex m [timeout [owner]]
Lock MUTEX. If the mutex is already locked, the calling thread
blocks until the mutex becomes available. The function returns
when the calling thread owns the lock on MUTEX. Locking a mutex
that a thread already owns will succeed right away and will not
block the thread. That is, Guile's mutexes are _recursive_.
try-mutex
-- Scheme Procedure: try-mutex mutex
Try to lock MUTEX. If the mutex is already locked by someone else,
return `#f'. Else lock the mutex and return `#t'.
unlock-mutex
-- Scheme Procedure: unlock-mutex mx [cond [timeout]]
Unlocks MUTEX if the calling thread owns the lock on MUTEX.
Calling unlock-mutex on a mutex not owned by the current thread
results in undefined behaviour. Once a mutex has been unlocked,
one thread blocked on MUTEX is awakened and grabs the mutex lock.
Every call to `lock-mutex' by this thread must be matched with a
call to `unlock-mutex'. Only the last call to `unlock-mutex' will
actually unlock the mutex.
mutex?
-- Scheme Procedure: mutex? obj
Return `#t' if OBJ is a mutex.
mutex-owner
-- Scheme Procedure: mutex-owner mx
Return the thread owning MX, or `#f'.
mutex-level
-- Scheme Procedure: mutex-level mx
Return the lock level of mutex MX.
mutex-locked?
-- Scheme Procedure: mutex-locked? mx
Returns `#t' if the mutex MX is locked.
make-condition-variable
-- Scheme Procedure: make-condition-variable
Make a new condition variable.
wait-condition-variable
-- Scheme Procedure: wait-condition-variable cv mx [t]
Wait until COND-VAR has been signalled. While waiting, MUTEX is
atomically unlocked (as with `unlock-mutex') and is locked again
when this function returns. When TIME is given, it specifies a
point in time where the waiting should be aborted. It can be
either a integer as returned by `current-time' or a pair as
returned by `gettimeofday'. When the waiting is aborted the mutex
is locked and `#f' is returned. When the condition variable is in
fact signalled, the mutex is also locked and `#t' is returned.
signal-condition-variable
-- Scheme Procedure: signal-condition-variable cv
Wake up one thread that is waiting for CV
broadcast-condition-variable
-- Scheme Procedure: broadcast-condition-variable cv
Wake up all threads that are waiting for CV.
condition-variable?
-- Scheme Procedure: condition-variable? obj
Return `#t' if OBJ is a condition variable.
current-thread
-- Scheme Procedure: current-thread
Return the thread that called this function.
all-threads
-- Scheme Procedure: all-threads
Return a list of all threads.
thread-exited?
-- Scheme Procedure: thread-exited? thread
Return `#t' iff THREAD has exited.
total-processor-count
-- Scheme Procedure: total-processor-count
Return the total number of processors of the machine, which is
guaranteed to be at least 1. A "processor" here is a thread
execution unit, which can be either:
* an execution core in a (possibly multi-core) chip, in a
(possibly multi- chip) module, in a single computer, or
* a thread execution unit inside a core in the case of
"hyper-threaded" CPUs.
Which of the two definitions is used, is unspecified.
current-processor-count
-- Scheme Procedure: current-processor-count
Like `total-processor-count', but return the number of processors
available to the current process. See `setaffinity' and
`getaffinity' for more information.
copy-tree
-- Scheme Procedure: copy-tree obj
Recursively copy the data tree that is bound to OBJ, and return a
the new data structure. `copy-tree' recurses down the contents of
both pairs and vectors (since both cons cells and vector cells may
point to arbitrary objects), and stops recursing when it hits any
other object.
uniform-vector?
-- Scheme Procedure: uniform-vector? obj
Return `#t' if OBJ is a uniform vector.
uniform-vector-element-type
-- Scheme Procedure: uniform-vector-element-type v
Return the type of the elements in the uniform vector, V.
uniform-vector-element-size
-- Scheme Procedure: uniform-vector-element-size v
Return the number of bytes allocated to each element in the
uniform vector, V.
uniform-vector-ref
-- Scheme Procedure: uniform-vector-ref v idx
Return the element at index IDX of the homogeneous numeric vector
V.
uniform-vector-set!
-- Scheme Procedure: uniform-vector-set! v idx val
Set the element at index IDX of the homogeneous numeric vector V
to VAL.
uniform-vector->list
-- Scheme Procedure: uniform-vector->list uvec
Convert the uniform numeric vector UVEC to a list.
uniform-vector-length
-- Scheme Procedure: uniform-vector-length v
Return the number of elements in the uniform vector V.
values
-- Scheme Procedure: values . args
Delivers all of its arguments to its continuation. Except for
continuations created by the `call-with-values' procedure, all
continuations take exactly one value. The effect of passing no
value or more than one value to continuations that were not
created by `call-with-values' is unspecified.
make-variable
-- Scheme Procedure: make-variable init
Return a variable initialized to value INIT.
make-undefined-variable
-- Scheme Procedure: make-undefined-variable
Return a variable that is initially unbound.
variable?
-- Scheme Procedure: variable? obj
Return `#t' iff OBJ is a variable object, else return `#f'.
variable-ref
-- Scheme Procedure: variable-ref var
Dereference VAR and return its value. VAR must be a variable
object; see `make-variable' and `make-undefined-variable'.
variable-set!
-- Scheme Procedure: variable-set! var val
Set the value of the variable VAR to VAL. VAR must be a variable
object, VAL can be any value. Return an unspecified value.
variable-unset!
-- Scheme Procedure: variable-unset! var
Ensure that VAR is not bound to a value. VAR must be a variable
object.
variable-bound?
-- Scheme Procedure: variable-bound? var
Return `#t' iff VAR is bound to a value. Throws an error if VAR
is not a variable object.
vector?
-- Scheme Procedure: vector? obj
Return `#t' if OBJ is a vector, otherwise return `#f'.
list->vector
-- Scheme Procedure: list->vector
implemented by the C function "scm_vector"
vector
-- Scheme Procedure: vector . l
-- Scheme Procedure: list->vector l
Return a newly allocated vector composed of the given arguments.
Analogous to `list'.
(vector 'a 'b 'c) => #(a b c)
make-vector
-- Scheme Procedure: make-vector k [fill]
Return a newly allocated vector of K elements. If a second
argument is given, then each position is initialized to FILL.
Otherwise the initial contents of each position is unspecified.
vector-copy
-- Scheme Procedure: vector-copy vec
Return a copy of VEC.
vector->list
-- Scheme Procedure: vector->list v
Return a newly allocated list composed of the elements of V.
(vector->list '#(dah dah didah)) => (dah dah didah)
(list->vector '(dididit dah)) => #(dididit dah)
vector-fill!
-- Scheme Procedure: vector-fill! v fill
Store FILL in every position of VECTOR. The value returned by
`vector-fill!' is unspecified.
vector-move-left!
-- Scheme Procedure: vector-move-left! vec1 start1 end1 vec2 start2
Copy elements from VEC1, positions START1 to END1, to VEC2
starting at position START2. START1 and START2 are inclusive
indices; END1 is exclusive.
`vector-move-left!' copies elements in leftmost order. Therefore,
in the case where VEC1 and VEC2 refer to the same vector,
`vector-move-left!' is usually appropriate when START1 is greater
than START2.
vector-move-right!
-- Scheme Procedure: vector-move-right! vec1 start1 end1 vec2 start2
Copy elements from VEC1, positions START1 to END1, to VEC2
starting at position START2. START1 and START2 are inclusive
indices; END1 is exclusive.
`vector-move-right!' copies elements in rightmost order.
Therefore, in the case where VEC1 and VEC2 refer to the same
vector, `vector-move-right!' is usually appropriate when START1 is
less than START2.
major-version
-- Scheme Procedure: major-version
Return a string containing Guile's major version number. E.g.,
the 1 in "1.6.5".
minor-version
-- Scheme Procedure: minor-version
Return a string containing Guile's minor version number. E.g.,
the 6 in "1.6.5".
micro-version
-- Scheme Procedure: micro-version
Return a string containing Guile's micro version number. E.g.,
the 5 in "1.6.5".
version
-- Scheme Procedure: version
-- Scheme Procedure: major-version
-- Scheme Procedure: minor-version
-- Scheme Procedure: micro-version
Return a string describing Guile's version number, or its major,
minor or micro version number, respectively.
(version) => "1.6.0"
(major-version) => "1"
(minor-version) => "6"
(micro-version) => "0"
effective-version
-- Scheme Procedure: effective-version
Return a string describing Guile's effective version number.
(version) => "1.6.0"
(effective-version) => "1.6"
(major-version) => "1"
(minor-version) => "6"
(micro-version) => "0"
make-soft-port
-- Scheme Procedure: make-soft-port pv modes
Return a port capable of receiving or delivering characters as
specified by the MODES string (*note open-file: File Ports.). PV
must be a vector of length 5 or 6. Its components are as follows:
0. procedure accepting one character for output
1. procedure accepting a string for output
2. thunk for flushing output
3. thunk for getting one character
4. thunk for closing port (not by garbage collection)
5. (if present and not `#f') thunk for computing the number of
characters that can be read from the port without blocking.
For an output-only port only elements 0, 1, 2, and 4 need be
procedures. For an input-only port only elements 3 and 4 need be
procedures. Thunks 2 and 4 can instead be `#f' if there is no
useful operation for them to perform.
If thunk 3 returns `#f' or an `eof-object' (*note eof-object?:
(r5rs)Input.) it indicates that the port has reached end-of-file.
For example:
(define stdout (current-output-port))
(define p (make-soft-port
(vector
(lambda (c) (write c stdout))
(lambda (s) (display s stdout))
(lambda () (display "." stdout))
(lambda () (char-upcase (read-char)))
(lambda () (display "@" stdout)))
"rw"))
(write p p) => #<input-output: soft 8081e20>
make-weak-vector
-- Scheme Procedure: make-weak-vector size [fill]
Return a weak vector with SIZE elements. If the optional argument
FILL is given, all entries in the vector will be set to FILL. The
default value for FILL is the empty list.
list->weak-vector
-- Scheme Procedure: list->weak-vector
implemented by the C function "scm_weak_vector"
weak-vector
-- Scheme Procedure: weak-vector . l
-- Scheme Procedure: list->weak-vector l
Construct a weak vector from a list: `weak-vector' uses the list
of its arguments while `list->weak-vector' uses its only argument
L (a list) to construct a weak vector the same way `list->vector'
would.
weak-vector?
-- Scheme Procedure: weak-vector? obj
Return `#t' if OBJ is a weak vector. Note that all weak hashes are
also weak vectors.
make-weak-key-alist-vector
-- Scheme Procedure: make-weak-key-alist-vector [size]
-- Scheme Procedure: make-weak-value-alist-vector size
-- Scheme Procedure: make-doubly-weak-alist-vector size
Return a weak hash table with SIZE buckets. As with any hash
table, choosing a good size for the table requires some caution.
You can modify weak hash tables in exactly the same way you would
modify regular hash tables. (*note Hash Tables::)
make-weak-value-alist-vector
-- Scheme Procedure: make-weak-value-alist-vector [size]
Return a hash table with weak values with SIZE buckets. (*note
Hash Tables::)
make-doubly-weak-alist-vector
-- Scheme Procedure: make-doubly-weak-alist-vector size
Return a hash table with weak keys and values with SIZE buckets.
(*note Hash Tables::)
weak-key-alist-vector?
-- Scheme Procedure: weak-key-alist-vector? obj
-- Scheme Procedure: weak-value-alist-vector? obj
-- Scheme Procedure: doubly-weak-alist-vector? obj
Return `#t' if OBJ is the specified weak hash table. Note that a
doubly weak hash table is neither a weak key nor a weak value hash
table.
weak-value-alist-vector?
-- Scheme Procedure: weak-value-alist-vector? obj
Return `#t' if OBJ is a weak value hash table.
doubly-weak-alist-vector?
-- Scheme Procedure: doubly-weak-alist-vector? obj
Return `#t' if OBJ is a doubly weak hash table.
dynamic-link
-- Scheme Procedure: dynamic-link [filename]
Find the shared object (shared library) denoted by FILENAME and
link it into the running Guile application. The returned scheme
object is a "handle" for the library which can be passed to
`dynamic-func', `dynamic-call' etc.
Searching for object files is system dependent. Normally, if
FILENAME does have an explicit directory it will be searched for
in locations such as `/usr/lib' and `/usr/local/lib'.
When FILENAME is omitted, a "global symbol handle" is returned.
This handle provides access to the symbols available to the
program at run-time, including those exported by the program
itself and the shared libraries already loaded.
dynamic-object?
-- Scheme Procedure: dynamic-object? obj
Return `#t' if OBJ is a dynamic object handle, or `#f' otherwise.
dynamic-unlink
-- Scheme Procedure: dynamic-unlink dobj
Unlink a dynamic object from the application, if possible. The
object must have been linked by `dynamic-link', with DOBJ the
corresponding handle. After this procedure is called, the handle
can no longer be used to access the object.
dynamic-pointer
-- Scheme Procedure: dynamic-pointer name dobj
Return a "wrapped pointer" to the symbol NAME in the shared object
referred to by DOBJ. The returned pointer points to a C object.
Regardless whether your C compiler prepends an underscore `_' to
the global names in a program, you should *not* include this
underscore in NAME since it will be added automatically when
necessary.
dynamic-func
-- Scheme Procedure: dynamic-func name dobj
Return a "handle" for the function NAME in the shared object
referred to by DOBJ. The handle can be passed to `dynamic-call'
to actually call the function.
Regardless whether your C compiler prepends an underscore `_' to
the global names in a program, you should *not* include this
underscore in NAME since it will be added automatically when
necessary.
dynamic-call
-- Scheme Procedure: dynamic-call func dobj
Call a C function in a dynamic object. Two styles of invocation
are supported:
* FUNC can be a function handle returned by `dynamic-func'. In
this case DOBJ is ignored
* FUNC can be a string with the name of the function to call,
with DOBJ the handle of the dynamic object in which to find
the function. This is equivalent to
(dynamic-call (dynamic-func FUNC DOBJ) #f)
In either case, the function is passed no arguments and its return
value is ignored.
pipe
-- Scheme Procedure: pipe
Return a newly created pipe: a pair of ports which are linked
together on the local machine. The _car_ is the input port and
the _cdr_ is the output port. Data written (and flushed) to the
output port can be read from the input port. Pipes are commonly
used for communication with a newly forked child process. The
need to flush the output port can be avoided by making it
unbuffered using `setvbuf'.
Writes occur atomically provided the size of the data in bytes is
not greater than the value of `PIPE_BUF'. Note that the output
port is likely to block if too much data (typically equal to
`PIPE_BUF') has been written but not yet read from the input port.
getgroups
-- Scheme Procedure: getgroups
Return a vector of integers representing the current supplementary
group IDs.
setgroups
-- Scheme Procedure: setgroups group_vec
Set the current set of supplementary group IDs to the integers in
the given vector VEC. The return value is unspecified.
Generally only the superuser can set the process group IDs.
getpw
-- Scheme Procedure: getpw [user]
Look up an entry in the user database. OBJ can be an integer, a
string, or omitted, giving the behaviour of getpwuid, getpwnam or
getpwent respectively.
setpw
-- Scheme Procedure: setpw [arg]
If called with a true argument, initialize or reset the password
data stream. Otherwise, close the stream. The `setpwent' and
`endpwent' procedures are implemented on top of this.
getgr
-- Scheme Procedure: getgr [name]
Look up an entry in the group database. OBJ can be an integer, a
string, or omitted, giving the behaviour of getgrgid, getgrnam or
getgrent respectively.
setgr
-- Scheme Procedure: setgr [arg]
If called with a true argument, initialize or reset the group data
stream. Otherwise, close the stream. The `setgrent' and
`endgrent' procedures are implemented on top of this.
getrlimit
-- Scheme Procedure: getrlimit resource
Get a resource limit for this process. RESOURCE identifies the
resource, either as an integer or as a symbol. For example,
`(getrlimit 'stack)' gets the limits associated with
`RLIMIT_STACK'.
`getrlimit' returns two values, the soft and the hard limit. If no
limit is set for the resource in question, the returned limit will
be `#f'.
setrlimit
-- Scheme Procedure: setrlimit resource soft hard
Set a resource limit for this process. RESOURCE identifies the
resource, either as an integer or as a symbol. SOFT and HARD
should be integers, or `#f' to indicate no limit (i.e.,
`RLIM_INFINITY').
For example, `(setrlimit 'stack 150000 300000)' sets the
`RLIMIT_STACK' limit to 150 kilobytes, with a hard limit of 300 kB.
kill
-- Scheme Procedure: kill pid sig
Sends a signal to the specified process or group of processes.
PID specifies the processes to which the signal is sent:
PID greater than 0
The process whose identifier is PID.
PID equal to 0
All processes in the current process group.
PID less than -1
The process group whose identifier is -PID
PID equal to -1
If the process is privileged, all processes except for some
special system processes. Otherwise, all processes with the
current effective user ID.
SIG should be specified using a variable corresponding to the Unix
symbolic name, e.g.,
-- Variable: SIGHUP
Hang-up signal.
-- Variable: SIGINT
Interrupt signal.
waitpid
-- Scheme Procedure: waitpid pid [options]
This procedure collects status information from a child process
which has terminated or (optionally) stopped. Normally it will
suspend the calling process until this can be done. If more than
one child process is eligible then one will be chosen by the
operating system.
The value of PID determines the behaviour:
PID greater than 0
Request status information from the specified child process.
PID equal to -1 or WAIT_ANY
Request status information for any child process.
PID equal to 0 or WAIT_MYPGRP
Request status information for any child process in the
current process group.
PID less than -1
Request status information for any child process whose
process group ID is -PID.
The OPTIONS argument, if supplied, should be the bitwise OR of the
values of zero or more of the following variables:
-- Variable: WNOHANG
Return immediately even if there are no child processes to be
collected.
-- Variable: WUNTRACED
Report status information for stopped processes as well as
terminated processes.
The return value is a pair containing:
1. The process ID of the child process, or 0 if `WNOHANG' was
specified and no process was collected.
2. The integer status value.
status:exit-val
-- Scheme Procedure: status:exit-val status
Return the exit status value, as would be set if a process ended
normally through a call to `exit' or `_exit', if any, otherwise
`#f'.
status:term-sig
-- Scheme Procedure: status:term-sig status
Return the signal number which terminated the process, if any,
otherwise `#f'.
status:stop-sig
-- Scheme Procedure: status:stop-sig status
Return the signal number which stopped the process, if any,
otherwise `#f'.
getppid
-- Scheme Procedure: getppid
Return an integer representing the process ID of the parent
process.
getuid
-- Scheme Procedure: getuid
Return an integer representing the current real user ID.
getgid
-- Scheme Procedure: getgid
Return an integer representing the current real group ID.
geteuid
-- Scheme Procedure: geteuid
Return an integer representing the current effective user ID. If
the system does not support effective IDs, then the real ID is
returned. `(provided? 'EIDs)' reports whether the system supports
effective IDs.
getegid
-- Scheme Procedure: getegid
Return an integer representing the current effective group ID. If
the system does not support effective IDs, then the real ID is
returned. `(provided? 'EIDs)' reports whether the system supports
effective IDs.
setuid
-- Scheme Procedure: setuid id
Sets both the real and effective user IDs to the integer ID,
provided the process has appropriate privileges. The return value
is unspecified.
setgid
-- Scheme Procedure: setgid id
Sets both the real and effective group IDs to the integer ID,
provided the process has appropriate privileges. The return value
is unspecified.
seteuid
-- Scheme Procedure: seteuid id
Sets the effective user ID to the integer ID, provided the process
has appropriate privileges. If effective IDs are not supported,
the real ID is set instead - `(provided? 'EIDs)' reports whether
the system supports effective IDs. The return value is
unspecified.
setegid
-- Scheme Procedure: setegid id
Sets the effective group ID to the integer ID, provided the process
has appropriate privileges. If effective IDs are not supported,
the real ID is set instead - `(provided? 'EIDs)' reports whether
the system supports effective IDs. The return value is
unspecified.
getpgrp
-- Scheme Procedure: getpgrp
Return an integer representing the current process group ID. This
is the POSIX definition, not BSD.
setpgid
-- Scheme Procedure: setpgid pid pgid
Move the process PID into the process group PGID. PID or PGID
must be integers: they can be zero to indicate the ID of the
current process. Fails on systems that do not support job control.
The return value is unspecified.
setsid
-- Scheme Procedure: setsid
Creates a new session. The current process becomes the session
leader and is put in a new process group. The process will be
detached from its controlling terminal if it has one. The return
value is an integer representing the new process group ID.
getsid
-- Scheme Procedure: getsid pid
Returns the session ID of process PID. (The session ID of a
process is the process group ID of its session leader.)
ttyname
-- Scheme Procedure: ttyname port
Return a string with the name of the serial terminal device
underlying PORT.
ctermid
-- Scheme Procedure: ctermid
Return a string containing the file name of the controlling
terminal for the current process.
tcgetpgrp
-- Scheme Procedure: tcgetpgrp port
Return the process group ID of the foreground process group
associated with the terminal open on the file descriptor
underlying PORT.
If there is no foreground process group, the return value is a
number greater than 1 that does not match the process group ID of
any existing process group. This can happen if all of the
processes in the job that was formerly the foreground job have
terminated, and no other job has yet been moved into the
foreground.
tcsetpgrp
-- Scheme Procedure: tcsetpgrp port pgid
Set the foreground process group ID for the terminal used by the
file descriptor underlying PORT to the integer PGID. The calling
process must be a member of the same session as PGID and must have
the same controlling terminal. The return value is unspecified.
execl
-- Scheme Procedure: execl filename . args
Executes the file named by PATH as a new process image. The
remaining arguments are supplied to the process; from a C program
they are accessible as the `argv' argument to `main'.
Conventionally the first ARG is the same as PATH. All arguments
must be strings.
If ARG is missing, PATH is executed with a null argument list,
which may have system-dependent side-effects.
This procedure is currently implemented using the `execv' system
call, but we call it `execl' because of its Scheme calling
interface.
execlp
-- Scheme Procedure: execlp filename . args
Similar to `execl', however if FILENAME does not contain a slash
then the file to execute will be located by searching the
directories listed in the `PATH' environment variable.
This procedure is currently implemented using the `execvp' system
call, but we call it `execlp' because of its Scheme calling
interface.
execle
-- Scheme Procedure: execle filename env . args
Similar to `execl', but the environment of the new process is
specified by ENV, which must be a list of strings as returned by
the `environ' procedure.
This procedure is currently implemented using the `execve' system
call, but we call it `execle' because of its Scheme calling
interface.
primitive-fork
-- Scheme Procedure: primitive-fork
Creates a new "child" process by duplicating the current "parent"
process. In the child the return value is 0. In the parent the
return value is the integer process ID of the child.
This procedure has been renamed from `fork' to avoid a naming
conflict with the scsh fork.
uname
-- Scheme Procedure: uname
Return an object with some information about the computer system
the program is running on.
environ
-- Scheme Procedure: environ [env]
If ENV is omitted, return the current environment (in the Unix
sense) as a list of strings. Otherwise set the current
environment, which is also the default environment for child
processes, to the supplied list of strings. Each member of ENV
should be of the form `NAME=VALUE' and values of `NAME' should not
be duplicated. If ENV is supplied then the return value is
unspecified.
tmpnam
-- Scheme Procedure: tmpnam
Return a name in the file system that does not match any existing
file. However there is no guarantee that another process will not
create the file after `tmpnam' is called. Care should be taken if
opening the file, e.g., use the `O_EXCL' open flag or use
`mkstemp!' instead.
tmpfile
-- Scheme Procedure: tmpfile
Return an input/output port to a unique temporary file named using
the path prefix `P_tmpdir' defined in `stdio.h'. The file is
automatically deleted when the port is closed or the program
terminates.
utime
-- Scheme Procedure: utime pathname [actime [modtime [actimens
[modtimens [flags]]]]]
`utime' sets the access and modification times for the file named
by PATH. If ACTIME or MODTIME is not supplied, then the current
time is used. ACTIME and MODTIME must be integer time values as
returned by the `current-time' procedure.
The optional ACTIMENS and MODTIMENS are nanoseconds to add ACTIME
and MODTIME. Nanosecond precision is only supported on some
combinations of file systems and operating systems.
(utime "foo" (- (current-time) 3600))
will set the access time to one hour in the past and the
modification time to the current time.
getpid
-- Scheme Procedure: getpid
Return an integer representing the current process ID.
putenv
-- Scheme Procedure: putenv str
Modifies the environment of the current process, which is also the
default environment inherited by child processes.
If STRING is of the form `NAME=VALUE' then it will be written
directly into the environment, replacing any existing environment
string with name matching `NAME'. If STRING does not contain an
equal sign, then any existing string with name matching STRING will
be removed.
The return value is unspecified.
setlocale
-- Scheme Procedure: setlocale category [locale]
If LOCALE is omitted, return the current value of the specified
locale category as a system-dependent string. CATEGORY should be
specified using the values `LC_COLLATE', `LC_ALL' etc.
Otherwise the specified locale category is set to the string
LOCALE and the new value is returned as a system-dependent string.
If LOCALE is an empty string, the locale will be set using
environment variables.
When the locale is changed, the character encoding of the new
locale (UTF-8, ISO-8859-1, etc.) is used for the current input,
output, and error ports
mknod
-- Scheme Procedure: mknod path type perms dev
Creates a new special file, such as a file corresponding to a
device. PATH specifies the name of the file. TYPE should be one
of the following symbols: regular, directory, symlink,
block-special, char-special, fifo, or socket. PERMS (an integer)
specifies the file permissions. DEV (an integer) specifies which
device the special file refers to. Its exact interpretation
depends on the kind of special file being created.
E.g.,
(mknod "/dev/fd0" 'block-special #o660 (+ (* 2 256) 2))
The return value is unspecified.
nice
-- Scheme Procedure: nice incr
Increment the priority of the current process by INCR. A higher
priority value means that the process runs less often. The return
value is unspecified.
sync
-- Scheme Procedure: sync
Flush the operating system disk buffers. The return value is
unspecified.
crypt
-- Scheme Procedure: crypt key salt
Encrypt KEY using SALT as the salt value to the crypt(3) library
call.
chroot
-- Scheme Procedure: chroot path
Change the root directory to that specified in PATH. This
directory will be used for path names beginning with `/'. The
root directory is inherited by all children of the current
process. Only the superuser may change the root directory.
getlogin
-- Scheme Procedure: getlogin
Return a string containing the name of the user logged in on the
controlling terminal of the process, or `#f' if this information
cannot be obtained.
getpriority
-- Scheme Procedure: getpriority which who
Return the scheduling priority of the process, process group or
user, as indicated by WHICH and WHO. WHICH is one of the variables
`PRIO_PROCESS', `PRIO_PGRP' or `PRIO_USER', and WHO is interpreted
relative to WHICH (a process identifier for `PRIO_PROCESS',
process group identifier for `PRIO_PGRP', and a user identifier
for `PRIO_USER'. A zero value of WHO denotes the current process,
process group, or user. Return the highest priority (lowest
numerical value) of any of the specified processes.
setpriority
-- Scheme Procedure: setpriority which who prio
Set the scheduling priority of the process, process group or user,
as indicated by WHICH and WHO. WHICH is one of the variables
`PRIO_PROCESS', `PRIO_PGRP' or `PRIO_USER', and WHO is interpreted
relative to WHICH (a process identifier for `PRIO_PROCESS',
process group identifier for `PRIO_PGRP', and a user identifier
for `PRIO_USER'. A zero value of WHO denotes the current process,
process group, or user. PRIO is a value in the range -20 and 20,
the default priority is 0; lower priorities cause more favorable
scheduling. Sets the priority of all of the specified processes.
Only the super-user may lower priorities. The return value is not
specified.
getaffinity
-- Scheme Procedure: getaffinity pid
Return a bitvector representing the CPU affinity mask for process
PID. Each CPU the process has affinity with has its corresponding
bit set in the returned bitvector. The number of bits set is a
good estimate of how many CPUs Guile can use without stepping on
other processes' toes.
Currently this procedure is only defined on GNU variants (*note
`sched_getaffinity': (libc)CPU Affinity.).
setaffinity
-- Scheme Procedure: setaffinity pid mask
Install the CPU affinity mask MASK, a bitvector, for the process
or thread with ID PID. The return value is unspecified.
Currently this procedure is only defined on GNU variants (*note
`sched_setaffinity': (libc)CPU Affinity.).
getpass
-- Scheme Procedure: getpass prompt
Display PROMPT to the standard error output and read a password
from `/dev/tty'. If this file is not accessible, it reads from
standard input. The password may be up to 127 characters in
length. Additional characters and the terminating newline
character are discarded. While reading the password, echoing and
the generation of signals by special characters is disabled.
flock
-- Scheme Procedure: flock file operation
Apply or remove an advisory lock on an open file. OPERATION
specifies the action to be done:
-- Variable: LOCK_SH
Shared lock. More than one process may hold a shared lock
for a given file at a given time.
-- Variable: LOCK_EX
Exclusive lock. Only one process may hold an exclusive lock
for a given file at a given time.
-- Variable: LOCK_UN
Unlock the file.
-- Variable: LOCK_NB
Don't block when locking. This is combined with one of the
other operations using `logior'. If `flock' would block an
`EWOULDBLOCK' error is thrown.
The return value is not specified. FILE may be an open file
descriptor or an open file descriptor port.
Note that `flock' does not lock files across NFS.
sethostname
-- Scheme Procedure: sethostname name
Set the host name of the current processor to NAME. May only be
used by the superuser. The return value is not specified.
gethostname
-- Scheme Procedure: gethostname
Return the host name of the current processor.
gethost
-- Scheme Procedure: gethost [host]
-- Scheme Procedure: gethostbyname hostname
-- Scheme Procedure: gethostbyaddr address
Look up a host by name or address, returning a host object. The
`gethost' procedure will accept either a string name or an integer
address; if given no arguments, it behaves like `gethostent' (see
below). If a name or address is supplied but the address can not
be found, an error will be thrown to one of the keys:
`host-not-found', `try-again', `no-recovery' or `no-data',
corresponding to the equivalent `h_error' values. Unusual
conditions may result in errors thrown to the `system-error' or
`misc_error' keys.
getnet
-- Scheme Procedure: getnet [net]
-- Scheme Procedure: getnetbyname net-name
-- Scheme Procedure: getnetbyaddr net-number
Look up a network by name or net number in the network database.
The NET-NAME argument must be a string, and the NET-NUMBER
argument must be an integer. `getnet' will accept either type of
argument, behaving like `getnetent' (see below) if no arguments are
given.
getproto
-- Scheme Procedure: getproto [protocol]
-- Scheme Procedure: getprotobyname name
-- Scheme Procedure: getprotobynumber number
Look up a network protocol by name or by number. `getprotobyname'
takes a string argument, and `getprotobynumber' takes an integer
argument. `getproto' will accept either type, behaving like
`getprotoent' (see below) if no arguments are supplied.
getserv
-- Scheme Procedure: getserv [name [protocol]]
-- Scheme Procedure: getservbyname name protocol
-- Scheme Procedure: getservbyport port protocol
Look up a network service by name or by service number, and return
a network service object. The PROTOCOL argument specifies the name
of the desired protocol; if the protocol found in the network
service database does not match this name, a system error is
signalled.
The `getserv' procedure will take either a service name or number
as its first argument; if given no arguments, it behaves like
`getservent' (see below).
sethost
-- Scheme Procedure: sethost [stayopen]
If STAYOPEN is omitted, this is equivalent to `endhostent'.
Otherwise it is equivalent to `sethostent stayopen'.
setnet
-- Scheme Procedure: setnet [stayopen]
If STAYOPEN is omitted, this is equivalent to `endnetent'.
Otherwise it is equivalent to `setnetent stayopen'.
setproto
-- Scheme Procedure: setproto [stayopen]
If STAYOPEN is omitted, this is equivalent to `endprotoent'.
Otherwise it is equivalent to `setprotoent stayopen'.
setserv
-- Scheme Procedure: setserv [stayopen]
If STAYOPEN is omitted, this is equivalent to `endservent'.
Otherwise it is equivalent to `setservent stayopen'.
getaddrinfo
-- Scheme Procedure: getaddrinfo name [service [hint_flags
[hint_family [hint_socktype [hint_protocol]]]]]
Return a list of `addrinfo' structures containing a socket address
and associated information for host NAME and/or SERVICE to be used
in creating a socket with which to address the specified service.
(let* ((ai (car (getaddrinfo "www.gnu.org" "http")))
(s (socket (addrinfo:fam ai) (addrinfo:socktype ai)
(addrinfo:protocol ai))))
(connect s (addrinfo:addr ai))
s)
When SERVICE is omitted or is `#f', return network-level addresses
for NAME. When NAME is `#f' SERVICE must be provided and service
locations local to the caller are returned.
Additional hints can be provided. When specified, HINT_FLAGS
should be a bitwise-or of zero or more constants among the
following:
`AI_PASSIVE'
Socket address is intended for `bind'.
`AI_CANONNAME'
Request for canonical host name, available via
`addrinfo:canonname'. This makes sense mainly when DNS
lookups are involved.
`AI_NUMERICHOST'
Specifies that NAME is a numeric host address string (e.g.,
`"127.0.0.1"'), meaning that name resolution will not be used.
`AI_NUMERICSERV'
Likewise, specifies that SERVICE is a numeric port string
(e.g., `"80"').
`AI_ADDRCONFIG'
Return only addresses configured on the local system. It is
highly recommended to provide this flag when the returned
socket addresses are to be used to make connections;
otherwise, some of the returned addresses could be
unreachable or use a protocol that is not supported.
`AI_V4MAPPED'
When looking up IPv6 addresses, return mapped IPv4 addresses
if there is no IPv6 address available at all.
`AI_ALL'
If this flag is set along with `AI_V4MAPPED' when looking up
IPv6 addresses, return all IPv6 addresses as well as all IPv4
addresses, the latter mapped to IPv6 format.
When given, HINT_FAMILY should specify the requested address
family, e.g., `AF_INET6'. Similarly, HINT_SOCKTYPE should specify
the requested socket type (e.g., `SOCK_DGRAM'), and HINT_PROTOCOL
should specify the requested protocol (its value is interpretered
as in calls to `socket').
On error, an exception with key `getaddrinfo-error' is thrown,
with an error code (an integer) as its argument:
(catch 'getaddrinfo-error
(lambda ()
(getaddrinfo "www.gnu.org" "gopher"))
(lambda (key errcode)
(cond ((= errcode EAI_SERVICE)
(display "doesn't know about Gopher!\n"))
((= errcode EAI_NONAME)
(display "www.gnu.org not found\n"))
(else
(format #t "something wrong: ~a\n"
(gai-strerror errcode))))))
Error codes are:
`EAI_AGAIN'
The name or service could not be resolved at this time.
Future attempts may succeed.
`EAI_BADFLAGS'
HINT_FLAGS contains an invalid value.
`EAI_FAIL'
A non-recoverable error occurred when attempting to resolve
the name.
`EAI_FAMILY'
HINT_FAMILY was not recognized.
`EAI_NONAME'
Either NAME does not resolve for the supplied parameters, or
neither NAME nor SERVICE were supplied.
`EAI_NODATA'
This non-POSIX error code can be returned on GNU systems when
a request was actually made but returned no data, meaning
that no address is associated with NAME. Error handling code
should be prepared to handle it when it is defined.
`EAI_SERVICE'
SERVICE was not recognized for the specified socket type.
`EAI_SOCKTYPE'
HINT_SOCKTYPE was not recognized.
`EAI_SYSTEM'
A system error occurred; the error code can be found in
`errno'.
Users are encouraged to read the POSIX specification
(http://www.opengroup.org/onlinepubs/9699919799/functions/getaddrinfo.html)
for more details.
gai-strerror
-- Scheme Procedure: gai-strerror error
Return a string describing ERROR, an integer error code returned
by `getaddrinfo'.
htons
-- Scheme Procedure: htons value
Convert a 16 bit quantity from host to network byte ordering.
VALUE is packed into 2 bytes, which are then converted and
returned as a new integer.
ntohs
-- Scheme Procedure: ntohs value
Convert a 16 bit quantity from network to host byte ordering.
VALUE is packed into 2 bytes, which are then converted and
returned as a new integer.
htonl
-- Scheme Procedure: htonl value
Convert a 32 bit quantity from host to network byte ordering.
VALUE is packed into 4 bytes, which are then converted and
returned as a new integer.
ntohl
-- Scheme Procedure: ntohl value
Convert a 32 bit quantity from network to host byte ordering.
VALUE is packed into 4 bytes, which are then converted and
returned as a new integer.
inet-netof
-- Scheme Procedure: inet-netof address
Return the network number part of the given IPv4 Internet address.
E.g.,
(inet-netof 2130706433) => 127
inet-lnaof
-- Scheme Procedure: inet-lnaof address
Return the local-address-with-network part of the given IPv4
Internet address, using the obsolete class A/B/C system. E.g.,
(inet-lnaof 2130706433) => 1
inet-makeaddr
-- Scheme Procedure: inet-makeaddr net lna
Make an IPv4 Internet address by combining the network number NET
with the local-address-within-network number LNA. E.g.,
(inet-makeaddr 127 1) => 2130706433
inet-ntop
-- Scheme Procedure: inet-ntop family address
Convert a network address into a printable string. Note that
unlike the C version of this function, the input is an integer
with normal host byte ordering. FAMILY can be `AF_INET' or
`AF_INET6'. E.g.,
(inet-ntop AF_INET 2130706433) => "127.0.0.1"
(inet-ntop AF_INET6 (- (expt 2 128) 1))
=> "ffff:ffff:ffff:ffff:ffff:ffff:ffff:ffff"
inet-pton
-- Scheme Procedure: inet-pton family address
Convert a string containing a printable network address to an
integer address. Note that unlike the C version of this function,
the result is an integer with normal host byte ordering. FAMILY
can be `AF_INET' or `AF_INET6'. E.g.,
(inet-pton AF_INET "127.0.0.1") => 2130706433
(inet-pton AF_INET6 "::1") => 1
socket
-- Scheme Procedure: socket family style proto
Return a new socket port of the type specified by FAMILY, STYLE
and PROTO. All three parameters are integers. Supported values
for FAMILY are `AF_UNIX', `AF_INET' and `AF_INET6'. Typical
values for STYLE are `SOCK_STREAM', `SOCK_DGRAM' and `SOCK_RAW'.
PROTO can be obtained from a protocol name using `getprotobyname'.
A value of zero specifies the default protocol, which is usually
right.
A single socket port cannot by used for communication until it has
been connected to another socket.
socketpair
-- Scheme Procedure: socketpair family style proto
Return a pair of connected (but unnamed) socket ports of the type
specified by FAMILY, STYLE and PROTO. Many systems support only
socket pairs of the `AF_UNIX' family. Zero is likely to be the
only meaningful value for PROTO.
getsockopt
-- Scheme Procedure: getsockopt sock level optname
Return an option value from socket port SOCK.
LEVEL is an integer specifying a protocol layer, either
`SOL_SOCKET' for socket level options, or a protocol number from
the `IPPROTO' constants or `getprotoent' (*note Network
Databases::).
-- Variable: SOL_SOCKET
-- Variable: IPPROTO_IP
-- Variable: IPPROTO_TCP
-- Variable: IPPROTO_UDP
OPTNAME is an integer specifying an option within the protocol
layer.
For `SOL_SOCKET' level the following OPTNAMEs are defined (when
provided by the system). For their meaning see *note Socket-Level
Options: (libc)Socket-Level Options, or `man 7 socket'.
-- Variable: SO_DEBUG
-- Variable: SO_REUSEADDR
-- Variable: SO_STYLE
-- Variable: SO_TYPE
-- Variable: SO_ERROR
-- Variable: SO_DONTROUTE
-- Variable: SO_BROADCAST
-- Variable: SO_SNDBUF
-- Variable: SO_RCVBUF
-- Variable: SO_KEEPALIVE
-- Variable: SO_OOBINLINE
-- Variable: SO_NO_CHECK
-- Variable: SO_PRIORITY
The value returned is an integer.
-- Variable: SO_LINGER
The VALUE returned is a pair of integers `(ENABLE .
TIMEOUT)'. On old systems without timeout support (ie.
without `struct linger'), only ENABLE has an effect but the
value in Guile is always a pair.
setsockopt
-- Scheme Procedure: setsockopt sock level optname value
Set an option on socket port SOCK. The return value is
unspecified.
LEVEL is an integer specifying a protocol layer, either
`SOL_SOCKET' for socket level options, or a protocol number from
the `IPPROTO' constants or `getprotoent' (*note Network
Databases::).
-- Variable: SOL_SOCKET
-- Variable: IPPROTO_IP
-- Variable: IPPROTO_TCP
-- Variable: IPPROTO_UDP
OPTNAME is an integer specifying an option within the protocol
layer.
For `SOL_SOCKET' level the following OPTNAMEs are defined (when
provided by the system). For their meaning see *note Socket-Level
Options: (libc)Socket-Level Options, or `man 7 socket'.
-- Variable: SO_DEBUG
-- Variable: SO_REUSEADDR
-- Variable: SO_STYLE
-- Variable: SO_TYPE
-- Variable: SO_ERROR
-- Variable: SO_DONTROUTE
-- Variable: SO_BROADCAST
-- Variable: SO_SNDBUF
-- Variable: SO_RCVBUF
-- Variable: SO_KEEPALIVE
-- Variable: SO_OOBINLINE
-- Variable: SO_NO_CHECK
-- Variable: SO_PRIORITY
VALUE is an integer.
-- Variable: SO_LINGER
VALUE is a pair of integers `(ENABLE . TIMEOUT)'. On old
systems without timeout support (ie. without `struct
linger'), only ENABLE has an effect but the value in Guile is
always a pair.
For IP level (`IPPROTO_IP') the following OPTNAMEs are defined
(when provided by the system). See `man ip' for what they mean.
-- Variable: IP_MULTICAST_IF
This sets the source interface used by multicast traffic.
-- Variable: IP_MULTICAST_TTL
This sets the default TTL for multicast traffic. This defaults
to 1 and should be increased to allow traffic to pass beyond
the local network.
-- Variable: IP_ADD_MEMBERSHIP
-- Variable: IP_DROP_MEMBERSHIP
These can be used only with `setsockopt', not `getsockopt'.
VALUE is a pair `(MULTIADDR . INTERFACEADDR)' of IPv4
addresses (*note Network Address Conversion::). MULTIADDR is
a multicast address to be added to or dropped from the
interface INTERFACEADDR. INTERFACEADDR can be `INADDR_ANY'
to have the system select the interface. INTERFACEADDR can
also be an interface index number, on systems supporting that.
shutdown
-- Scheme Procedure: shutdown sock how
Sockets can be closed simply by using `close-port'. The `shutdown'
procedure allows reception or transmission on a connection to be
shut down individually, according to the parameter HOW:
0
Stop receiving data for this socket. If further data
arrives, reject it.
1
Stop trying to transmit data from this socket. Discard any
data waiting to be sent. Stop looking for acknowledgement of
data already sent; don't retransmit it if it is lost.
2
Stop both reception and transmission.
The return value is unspecified.
connect
-- Scheme Procedure: connect sock fam_or_sockaddr [address . args]
Initiate a connection from a socket using a specified address
family to the address specified by ADDRESS and possibly ARGS. The
format required for ADDRESS and ARGS depends on the family of the
socket.
For a socket of family `AF_UNIX', only ADDRESS is specified and
must be a string with the filename where the socket is to be
created.
For a socket of family `AF_INET', ADDRESS must be an integer IPv4
host address and ARGS must be a single integer port number.
For a socket of family `AF_INET6', ADDRESS must be an integer IPv6
host address and ARGS may be up to three integers: port [flowinfo]
[scope_id], where flowinfo and scope_id default to zero.
Alternatively, the second argument can be a socket address object
as returned by `make-socket-address', in which case the no
additional arguments should be passed.
The return value is unspecified.
bind
-- Scheme Procedure: bind sock fam_or_sockaddr [address . args]
Assign an address to the socket port SOCK. Generally this only
needs to be done for server sockets, so they know where to look
for incoming connections. A socket without an address will be
assigned one automatically when it starts communicating.
The format of ADDRESS and ARGS depends on the family of the socket.
For a socket of family `AF_UNIX', only ADDRESS is specified and
must be a string with the filename where the socket is to be
created.
For a socket of family `AF_INET', ADDRESS must be an integer IPv4
address and ARGS must be a single integer port number.
The values of the following variables can also be used for ADDRESS:
-- Variable: INADDR_ANY
Allow connections from any address.
-- Variable: INADDR_LOOPBACK
The address of the local host using the loopback device.
-- Variable: INADDR_BROADCAST
The broadcast address on the local network.
-- Variable: INADDR_NONE
No address.
For a socket of family `AF_INET6', ADDRESS must be an integer IPv6
address and ARGS may be up to three integers: port [flowinfo]
[scope_id], where flowinfo and scope_id default to zero.
Alternatively, the second argument can be a socket address object
as returned by `make-socket-address', in which case the no
additional arguments should be passed.
The return value is unspecified.
listen
-- Scheme Procedure: listen sock backlog
Enable SOCK to accept connection requests. BACKLOG is an integer
specifying the maximum length of the queue for pending connections.
If the queue fills, new clients will fail to connect until the
server calls `accept' to accept a connection from the queue.
The return value is unspecified.
make-socket-address
-- Scheme Procedure: make-socket-address family address . args
Return a Scheme address object that reflects ADDRESS, being an
address of family FAMILY, with the family-specific parameters ARGS
(see the description of `connect' for details).
accept
-- Scheme Procedure: accept sock
Accept a connection on a bound, listening socket. If there are no
pending connections in the queue, wait until one is available
unless the non-blocking option has been set on the socket.
The return value is a pair in which the _car_ is a new socket port
for the connection and the _cdr_ is an object with address
information about the client which initiated the connection.
SOCK does not become part of the connection and will continue to
accept new requests.
getsockname
-- Scheme Procedure: getsockname sock
Return the address of SOCK, in the same form as the object
returned by `accept'. On many systems the address of a socket in
the `AF_FILE' namespace cannot be read.
getpeername
-- Scheme Procedure: getpeername sock
Return the address that SOCK is connected to, in the same form as
the object returned by `accept'. On many systems the address of a
socket in the `AF_FILE' namespace cannot be read.
recv!
-- Scheme Procedure: recv! sock buf [flags]
Receive data from a socket port. SOCK must already be bound to
the address from which data is to be received. BUF is a
bytevector into which the data will be written. The size of BUF
limits the amount of data which can be received: in the case of
packet protocols, if a packet larger than this limit is encountered
then some data will be irrevocably lost.
The optional FLAGS argument is a value or bitwise OR of MSG_OOB,
MSG_PEEK, MSG_DONTROUTE etc.
The value returned is the number of bytes read from the socket.
Note that the data is read directly from the socket file
descriptor: any unread buffered port data is ignored.
send
-- Scheme Procedure: send sock message [flags]
Transmit bytevector MESSAGE on socket port SOCK. SOCK must
already be bound to a destination address. The value returned is
the number of bytes transmitted - it's possible for this to be
less than the length of MESSAGE if the socket is set to be
non-blocking. The optional FLAGS argument is a value or bitwise
OR of MSG_OOB, MSG_PEEK, MSG_DONTROUTE etc.
Note that the data is written directly to the socket file
descriptor: any unflushed buffered port data is ignored.
This operation is defined only for strings containing codepoints
zero to 255.
recvfrom!
-- Scheme Procedure: recvfrom! sock buf [flags [start [end]]]
Receive data from socket port SOCK (which must be already bound),
returning the originating address as well as the data. This is
usually for use on datagram sockets, but can be used on
stream-oriented sockets too.
The data received is stored in bytevector BUF, using either the
whole bytevector or just the region between the optional START and
END positions. The size of BUF limits the amount of data that can
be received. For datagram protocols, if a packet larger than this
is received then excess bytes are irrevocably lost.
The return value is a pair. The `car' is the number of bytes
read. The `cdr' is a socket address object which is where the
data came from, or `#f' if the origin is unknown.
The optional FLAGS argument is a or bitwise OR (`logior') of
`MSG_OOB', `MSG_PEEK', `MSG_DONTROUTE' etc.
Data is read directly from the socket file descriptor, any
buffered port data is ignored.
On a GNU/Linux system `recvfrom!' is not multi-threading, all
threads stop while a `recvfrom!' call is in progress. An
application may need to use `select', `O_NONBLOCK' or
`MSG_DONTWAIT' to avoid this.
sendto
-- Scheme Procedure: sendto sock message fam_or_sockaddr [address .
args_and_flags]
Transmit bytevector MESSAGE on socket port SOCK. The destination
address is specified using the FAM, ADDRESS and ARGS_AND_FLAGS
arguments, or just a socket address object returned by
`make-socket-address', in a similar way to the `connect'
procedure. ARGS_AND_FLAGS contains the usual connection arguments
optionally followed by a flags argument, which is a value or
bitwise OR of MSG_OOB, MSG_PEEK, MSG_DONTROUTE etc.
The value returned is the number of bytes transmitted - it's
possible for this to be less than the length of MESSAGE if the
socket is set to be non-blocking. Note that the data is written
directly to the socket file descriptor: any unflushed buffered
port data is ignored. This operation is defined only for strings
containing codepoints zero to 255.
regexp?
-- Scheme Procedure: regexp? obj
Return `#t' if OBJ is a compiled regular expression, or `#f'
otherwise.
make-regexp
-- Scheme Procedure: make-regexp pat . flags
Compile the regular expression described by PAT, and return the
compiled regexp structure. If PAT does not describe a legal
regular expression, `make-regexp' throws a
`regular-expression-syntax' error.
The FLAGS arguments change the behavior of the compiled regular
expression. The following flags may be supplied:
`regexp/icase'
Consider uppercase and lowercase letters to be the same when
matching.
`regexp/newline'
If a newline appears in the target string, then permit the
`^' and `$' operators to match immediately after or
immediately before the newline, respectively. Also, the `.'
and `[^...]' operators will never match a newline character.
The intent of this flag is to treat the target string as a
buffer containing many lines of text, and the regular
expression as a pattern that may match a single one of those
lines.
`regexp/basic'
Compile a basic ("obsolete") regexp instead of the extended
("modern") regexps that are the default. Basic regexps do
not consider `|', `+' or `?' to be special characters, and
require the `{...}' and `(...)' metacharacters to be
backslash-escaped (*note Backslash Escapes::). There are
several other differences between basic and extended regular
expressions, but these are the most significant.
`regexp/extended'
Compile an extended regular expression rather than a basic
regexp. This is the default behavior; this flag will not
usually be needed. If a call to `make-regexp' includes both
`regexp/basic' and `regexp/extended' flags, the one which
comes last will override the earlier one.
regexp-exec
-- Scheme Procedure: regexp-exec rx str [start [flags]]
Match the compiled regular expression RX against `str'. If the
optional integer START argument is provided, begin matching from
that position in the string. Return a match structure describing
the results of the match, or `#f' if no match could be found.
The FLAGS arguments change the matching behavior. The following
flags may be supplied:
`regexp/notbol'
Operator `^' always fails (unless `regexp/newline' is used).
Use this when the beginning of the string should not be
considered the beginning of a line.
`regexp/noteol'
Operator `$' always fails (unless `regexp/newline' is used).
Use this when the end of the string should not be considered
the end of a line.
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