Stream SΒΆ

stream.spad line 534 [edit on github]

A stream is an implementation of a possibly infinite sequence using a list of terms that have been computed and a function closure to compute additional terms when needed.

<=: (%, %) -> Boolean if S has OrderedSet and % has finiteAggregate

from PartialOrder

<: (%, %) -> Boolean if S has OrderedSet and % has finiteAggregate

from PartialOrder

=: (%, %) -> Boolean if S has BasicType and % has finiteAggregate or S has Hashable and % has finiteAggregate or S has SetCategory

from BasicType

>=: (%, %) -> Boolean if S has OrderedSet and % has finiteAggregate

from PartialOrder

>: (%, %) -> Boolean if S has OrderedSet and % has finiteAggregate

from PartialOrder

~=: (%, %) -> Boolean if S has BasicType and % has finiteAggregate or S has Hashable and % has finiteAggregate or S has SetCategory

from BasicType

child?: (%, %) -> Boolean if S has BasicType

from RecursiveAggregate S

children: % -> List %

from RecursiveAggregate S

coerce: % -> OutputForm if S has CoercibleTo OutputForm

from CoercibleTo OutputForm

coerce: List S -> %

coerce(l) converts a list l to a stream.

complete: % -> %

from LazyStreamAggregate S

concat!: (%, %) -> %

from UnaryRecursiveAggregate S

concat!: (%, S) -> %

from UnaryRecursiveAggregate S

concat!: List % -> %

from UnaryRecursiveAggregate S

concat: (%, %) -> %

from LinearAggregate S

concat: (%, S) -> %

from LinearAggregate S

concat: (S, %) -> %

from LinearAggregate S

concat: List % -> %

from LinearAggregate S

cons: (S, %) -> %

cons(a, s) returns a stream whose first is a and whose rest is s. Note: cons(a, s) = concat(a, s).

construct: List S -> %

from Collection S

convert: % -> InputForm if S has ConvertibleTo InputForm

from ConvertibleTo InputForm

copy: % -> %

from Aggregate

count: (S, %) -> NonNegativeInteger if S has BasicType and % has finiteAggregate

from HomogeneousAggregate S

cycleEntry: % -> %

from UnaryRecursiveAggregate S

cycleLength: % -> NonNegativeInteger

from UnaryRecursiveAggregate S

cycleSplit!: % -> %

from UnaryRecursiveAggregate S

cycleTail: % -> %

from UnaryRecursiveAggregate S

cyclic?: % -> Boolean

from RecursiveAggregate S

delay: (() -> %) -> %

delay(f) creates a stream with a lazy evaluation defined by function f. Caution: This function can only be called in compiled code.

delete: (%, Integer) -> %

from LinearAggregate S

delete: (%, UniversalSegment Integer) -> %

from LinearAggregate S

distance: (%, %) -> Integer

from RecursiveAggregate S

elt: (%, first) -> S

from UnaryRecursiveAggregate S

elt: (%, Integer) -> S

from Eltable(Integer, S)

elt: (%, Integer, S) -> S

from EltableAggregate(Integer, S)

elt: (%, last) -> S

from UnaryRecursiveAggregate S

elt: (%, rest) -> %

from UnaryRecursiveAggregate S

elt: (%, UniversalSegment Integer) -> %

from Eltable(UniversalSegment Integer, %)

elt: (%, value) -> S

from RecursiveAggregate S

empty?: % -> Boolean

from Aggregate

empty: () -> %

from Aggregate

entries: % -> List S

from IndexedAggregate(Integer, S)

entry?: (S, %) -> Boolean if S has BasicType and % has finiteAggregate

from IndexedAggregate(Integer, S)

eq?: (%, %) -> Boolean

from Aggregate

eval: (%, Equation S) -> % if S has Evalable S and S has SetCategory

from Evalable S

eval: (%, List Equation S) -> % if S has Evalable S and S has SetCategory

from Evalable S

eval: (%, List S, List S) -> % if S has Evalable S and S has SetCategory

from InnerEvalable(S, S)

eval: (%, S, S) -> % if S has Evalable S and S has SetCategory

from InnerEvalable(S, S)

explicitEntries?: % -> Boolean

from LazyStreamAggregate S

explicitlyEmpty?: % -> Boolean

from LazyStreamAggregate S

explicitlyFinite?: % -> Boolean

from StreamAggregate S

extend: (%, Integer) -> %

from LazyStreamAggregate S

fill!: (%, S) -> %

from IndexedAggregate(Integer, S)

filterUntil: (S -> Boolean, %) -> %

filterUntil(p, s) returns [x0, x1, ..., x(n)] where s = [x0, x1, x2, ..] and n is the smallest index such that p(xn) = true.

filterWhile: (S -> Boolean, %) -> %

filterWhile(p, s) returns [x0, x1, ..., x(n-1)] where s = [x0, x1, x2, ..] and n is the smallest index such that p(xn) = false.

find: (S -> Boolean, %) -> Union(S, failed)

from Collection S

findCycle: (NonNegativeInteger, %) -> Record(cycle?: Boolean, prefix: NonNegativeInteger, period: NonNegativeInteger)

findCycle(n, st) determines if st is periodic within n.

first: % -> S

from IndexedAggregate(Integer, S)

first: (%, NonNegativeInteger) -> %

from LinearAggregate S

frst: % -> S

from LazyStreamAggregate S

hash: % -> SingleInteger if S has Hashable and % has finiteAggregate

from Hashable

hashUpdate!: (HashState, %) -> HashState if S has Hashable and % has finiteAggregate

from Hashable

index?: (Integer, %) -> Boolean

from IndexedAggregate(Integer, S)

indices: % -> List Integer

from IndexedAggregate(Integer, S)

insert: (%, %, Integer) -> %

from LinearAggregate S

insert: (S, %, Integer) -> %

from LinearAggregate S

last: % -> S

from UnaryRecursiveAggregate S

last: (%, NonNegativeInteger) -> %

from UnaryRecursiveAggregate S

latex: % -> String if S has SetCategory

from SetCategory

lazy?: % -> Boolean

from LazyStreamAggregate S

lazyEvaluate: % -> %

from LazyStreamAggregate S

leaf?: % -> Boolean

from RecursiveAggregate S

leaves: % -> List S

from RecursiveAggregate S

leftTrim: (%, S) -> % if S has BasicType and % has finiteAggregate

from LinearAggregate S

less?: (%, NonNegativeInteger) -> Boolean

from Aggregate

map!: (S -> S, %) -> %

from HomogeneousAggregate S

map: ((S, S) -> S, %, %) -> %

from LinearAggregate S

map: (S -> S, %) -> %

from HomogeneousAggregate S

max: % -> S if S has OrderedSet and % has finiteAggregate

from HomogeneousAggregate S

max: (%, %) -> % if S has OrderedSet and % has finiteAggregate

from OrderedSet

maxIndex: % -> Integer

from IndexedAggregate(Integer, S)

member?: (S, %) -> Boolean if S has BasicType and % has finiteAggregate

from HomogeneousAggregate S

merge: (%, %) -> % if S has OrderedSet and % has finiteAggregate

from LinearAggregate S

min: % -> S if S has OrderedSet and % has finiteAggregate

from HomogeneousAggregate S

min: (%, %) -> % if S has OrderedSet and % has finiteAggregate

from OrderedSet

minIndex: % -> Integer

from IndexedAggregate(Integer, S)

more?: (%, NonNegativeInteger) -> Boolean

from Aggregate

new: (NonNegativeInteger, S) -> %

from LinearAggregate S

node?: (%, %) -> Boolean if S has BasicType

from RecursiveAggregate S

nodes: % -> List %

from RecursiveAggregate S

numberOfComputedEntries: % -> NonNegativeInteger

from LazyStreamAggregate S

position: (S, %) -> Integer if S has BasicType and % has finiteAggregate

from LinearAggregate S

position: (S, %, Integer) -> Integer if S has BasicType and % has finiteAggregate

from LinearAggregate S

possiblyInfinite?: % -> Boolean

from StreamAggregate S

qelt: (%, Integer) -> S

from EltableAggregate(Integer, S)

qsetelt!: (%, Integer, S) -> S

from EltableAggregate(Integer, S)

qsetfirst!: (%, S) -> S

from UnaryRecursiveAggregate S

qsetrest!: (%, %) -> %

from UnaryRecursiveAggregate S

reduce: ((S, S) -> S, %, S, S) -> S if S has BasicType and % has finiteAggregate

from Collection S

remove: (S -> Boolean, %) -> %

from LazyStreamAggregate S

remove: (S, %) -> % if S has BasicType and % has finiteAggregate

from Collection S

removeDuplicates: % -> % if S has BasicType and % has finiteAggregate

from Collection S

repeating?: (List S, %) -> Boolean if S has SetCategory

repeating?(l, s) returns true if a stream s is periodic with period l, and false otherwise.

repeating: List S -> %

repeating(l) is a repeating stream whose period is the list l.

rest: % -> %

from UnaryRecursiveAggregate S

rest: (%, NonNegativeInteger) -> %

from UnaryRecursiveAggregate S

rightTrim: (%, S) -> % if S has BasicType and % has finiteAggregate

from LinearAggregate S

rst: % -> %

from LazyStreamAggregate S

sample: %

from Aggregate

second: % -> S

from UnaryRecursiveAggregate S

select: (S -> Boolean, %) -> %

from LazyStreamAggregate S

setchildren!: (%, List %) -> %

from RecursiveAggregate S

setelt!: (%, first, S) -> S

from UnaryRecursiveAggregate S

setelt!: (%, Integer, S) -> S

from EltableAggregate(Integer, S)

setelt!: (%, last, S) -> S

from UnaryRecursiveAggregate S

setelt!: (%, rest, %) -> %

from UnaryRecursiveAggregate S

setelt!: (%, UniversalSegment Integer, S) -> S

from LinearAggregate S

setelt!: (%, value, S) -> S

from RecursiveAggregate S

setfirst!: (%, S) -> S

from UnaryRecursiveAggregate S

setlast!: (%, S) -> S

from UnaryRecursiveAggregate S

setrest!: (%, %) -> %

from UnaryRecursiveAggregate S

setrest!: (%, Integer, %) -> %

setrest!(x, n, y) sets rest(x, n) to y. The function will expand cycles if necessary.

setvalue!: (%, S) -> S

from RecursiveAggregate S

showAll?: () -> Boolean if S has SetCategory

showAll?() returns true if all computed entries of streams will be displayed.

showAllElements: % -> OutputForm if S has SetCategory

showAllElements(s) creates an output form which displays all computed elements.

showElements: (NonNegativeInteger, %) -> OutputForm if S has SetCategory

showElements(n, st) computes and creates and output form of the first n entries of st.

size?: (%, NonNegativeInteger) -> Boolean

from Aggregate

smaller?: (%, %) -> Boolean if % has finiteAggregate and S has Comparable or S has OrderedSet and % has finiteAggregate

from Comparable

sort!: % -> % if S has OrderedSet and % has finiteAggregate

from LinearAggregate S

sort: % -> % if S has OrderedSet and % has finiteAggregate

from LinearAggregate S

sorted?: % -> Boolean if S has OrderedSet and % has finiteAggregate

from LinearAggregate S

split!: (%, NonNegativeInteger) -> %

from UnaryRecursiveAggregate S

stream: (() -> S) -> %

stream(f) creates an infinite stream all of whose elements are equal to f(). Note: stream(f) = [f(), f(), f(), ...].

stream: (S -> S, S) -> %

stream(f, x) creates an infinite stream whose first element is x and whose nth element (n > 1) is f applied to the previous element. Note: stream(f, x) = [x, f(x), f(f(x)), ...].

swap!: (%, Integer, Integer) -> Void

from IndexedAggregate(Integer, S)

tail: % -> %

from UnaryRecursiveAggregate S

third: % -> S

from UnaryRecursiveAggregate S

trim: (%, S) -> % if S has BasicType and % has finiteAggregate

from LinearAggregate S

value: % -> S

from RecursiveAggregate S

Aggregate

BasicType if S has BasicType and % has finiteAggregate or S has Hashable and % has finiteAggregate or S has SetCategory

CoercibleTo OutputForm if S has CoercibleTo OutputForm

Collection S

Comparable if % has finiteAggregate and S has Comparable or S has OrderedSet and % has finiteAggregate

ConvertibleTo InputForm if S has ConvertibleTo InputForm

Eltable(Integer, S)

Eltable(UniversalSegment Integer, %)

EltableAggregate(Integer, S)

Evalable S if S has Evalable S and S has SetCategory

Hashable if S has Hashable and % has finiteAggregate

HomogeneousAggregate S

IndexedAggregate(Integer, S)

InnerEvalable(S, S) if S has Evalable S and S has SetCategory

LazyStreamAggregate S

LinearAggregate S

OrderedSet if S has OrderedSet and % has finiteAggregate

PartialOrder if S has OrderedSet and % has finiteAggregate

RecursiveAggregate S

SetCategory if S has SetCategory

shallowlyMutable

StreamAggregate S

UnaryRecursiveAggregate S