struct Slice(T)
Overview
A Slice
is a Pointer
with an associated size.
While a pointer is unsafe because no bound checks are performed when reading from and writing to it,
reading from and writing to a slice involve bound checks.
In this way, a slice is a safe alternative to Pointer
.
A Slice can be created as read-only: trying to write to it
will raise. For example the slice of bytes returned by
String#to_slice
is read-only.
Included Modules
Defined in:
primitives.crslice.cr
slice/sort.cr
yaml/from_yaml.cr
yaml/to_yaml.cr
Constructors
-
.additive_identity : self
Returns the additive identity of this type.
-
.empty : self
Creates an empty slice.
-
.join(slices : Indexable(Slice)) : Slice
Returns a new slice that has the elements from slices joined together.
- .new(ctx : YAML::ParseContext, node : YAML::Nodes::Node)
-
.new(pointer : Pointer(T), size : Int, *, read_only : Bool = false)
Creates a slice to the given pointer, bounded by the given size.
-
.new(size : Int, value : T, *, read_only = false)
Allocates
size * sizeof(T)
bytes of heap memory initialized to value and returns a slice pointing to that memory. -
.new(size : Int, *, read_only = false)
Allocates
size * sizeof(T)
bytes of heap memory initialized to zero and returns a slice pointing to that memory. -
.new(size : Int, *, read_only = false, &)
Allocates
size * sizeof(T)
bytes of heap memory initialized to the value returned by the block (which is invoked once with each index in the range0...size
) and returns a slice pointing to that memory.
Class Method Summary
Macro Summary
-
[](*args, read_only = false)
Creates a new
Slice
with the given args.
Instance Method Summary
-
#+(offset : Int) : Slice(T)
Returns a new slice that is offset elements apart from this slice.
-
#+(other : Slice) : Slice
Returns a new slice that has
self
's elements followed by other's elements. -
#<=>(other : Slice(U)) forall U
Combined comparison operator.
-
#==(other : Slice(U)) : Bool forall U
Returns
true
ifself
and other have the same size and all their elements are equal,false
otherwise. -
#[](start : Int, count : Int) : Slice(T)
Returns a new slice that starts at start elements from this slice's start, and of count size.
-
#[](range : Range) : Slice(T)
Returns a new slice with the elements in the given range.
-
#[]=(index : Int, value : T) : T
Sets the given value at the given index.
-
#[]?(start : Int, count : Int) : Slice(T) | Nil
Returns a new slice that starts at start elements from this slice's start, and of count size.
-
#[]?(range : Range)
Returns a new slice with the elements in the given range.
- #bytesize : Int32
-
#clone
Returns a deep copy of this slice.
- #copy_from(source : Pointer(T), count) : Nil
-
#copy_from(source : self) : Nil
Copies the contents of source into this slice.
- #copy_to(target : Pointer(T), count) : Nil
-
#copy_to(target : self) : Nil
Copies the contents of this slice into target.
-
#dup
Returns a shallow copy of this slice.
-
#fill(value : T, start : Int, count : Int) : self
Replaces count or less (if there aren't enough) elements starting at the given start index with value.
-
#fill(value : T, range : Range) : self
Replaces the elements within the given range with value.
-
#fill(value : T) : self
Replaces every element in
self
with the given value. -
#fill(start : Int, count : Int, & : Int32 -> T) : self
Yields each index of
self
, starting at start and for count times (or less if there aren't enough elements), to the given block and then assigns the block's value in that position. -
#fill(range : Range, & : Int32 -> T) : self
Yields each index of
self
, in the given range, to the given block and then assigns the block's value in that position. -
#fill(*, offset : Int = 0, & : Int32 -> T) : self
Yields each index of
self
to the given block and then assigns the block's value in that position. - #hash(hasher)
-
#hexdump(io : IO)
Writes a hexdump of this slice to the given io.
-
#hexdump : String
Returns a hexdump of this slice.
-
#hexstring : String
Returns a hexstring representation of this slice.
-
#index(object, offset : Int = 0)
Returns the index of the first appearance of object in
self
starting from the given offset, ornil
if object is not inself
. -
#inspect(io : IO) : Nil
Appends this struct's name and instance variables names and values to the given IO.
-
#map(*, read_only = false, & : T -> _)
Returns a new slice where elements are mapped by the given block.
-
#map!(& : T -> _) : self
Invokes the given block for each element of
self
, replacing the element with the value returned by the block. -
#map_with_index(offset = 0, *, read_only = false, & : T, Int32 -> _)
Like
#map
, but the block gets passed both the element and its index. -
#map_with_index!(offset = 0, & : T, Int32 -> _) : self
Like
#map!
, but the block gets passed both the element and its index. - #move_from(source : Pointer(T), count) : Nil
-
#move_from(source : self) : Nil
Moves the contents of source into this slice.
- #move_to(target : Pointer(T), count) : Nil
-
#move_to(target : self) : Nil
Moves the contents of this slice into target.
- #pretty_print(pp) : Nil
-
#read_only? : Bool
Returns
true
if this slice cannot be written to. -
#reverse! : self
Reverses in-place all the elements of
self
. -
#rotate!(n : Int = 1) : self
Shifts all elements of
self
to the left n times. -
#shuffle!(random : Random = Random::DEFAULT) : self
Modifies
self
by randomizing the order of elements in the collection using the given random number generator. -
#size : Int32
Returns the size of this slice.
-
#sort : self
Returns a new instance with all elements sorted based on the return value of their comparison method
T#<=>
(seeComparable#<=>
), using a stable sort algorithm. -
#sort(&block : T, T -> U) : self forall U
Returns a new instance with all elements sorted based on the comparator in the given block, using a stable sort algorithm.
-
#sort! : self
Sorts all elements in
self
based on the return value of the comparison methodT#<=>
(seeComparable#<=>
), using a stable sort algorithm. -
#sort!(&block : T, T -> U) : self forall U
Sorts all elements in
self
based on the comparator in the given block, using a stable sort algorithm. -
#sort_by(&block : T -> _) : self
Returns a new instance with all elements sorted by the output value of the block.
-
#sort_by!(&block : T -> _) : Slice(T)
Modifies
self
by sorting all elements. -
#swap(index0 : Int, index1 : Int) : self
Swaps the elements at index0 and index1.
-
#to_a
Returns an
Array
with all the elements in the collection. -
#to_s(io : IO) : Nil
Same as
#inspect(io)
. - #to_slice : self
-
#to_unsafe : Pointer(T)
Returns this slice's pointer.
-
#to_unsafe_bytes : Bytes
Returns a new
Bytes
pointing at the same contents asself
. - #to_yaml(yaml : YAML::Nodes::Builder) : Nil
-
#unsafe_fetch(index : Int) : T
Returns the element at the given index, without doing any bounds check.
-
#unsafe_put(index : Int, value : T)
Sets the element at the given index to value, without doing any bounds check.
-
#unsafe_slice_of(type : U.class) : Slice(U) forall U
Returns a new
Slice
pointing at the same contents asself
, but reinterpreted as elements of the given type. -
#unstable_sort : self
Returns a new instance with all elements sorted based on the return value of their comparison method
T#<=>
(seeComparable#<=>
), using an unstable sort algorithm. -
#unstable_sort(&block : T, T -> U) : self forall U
Returns a new instance with all elements sorted based on the comparator in the given block, using an unstable sort algorithm.
-
#unstable_sort! : self
Sorts all elements in
self
based on the return value of the comparison methodT#<=>
(seeComparable#<=>
), using an unstable sort algorithm.. -
#unstable_sort!(&block : T, T -> U) : self forall U
Sorts all elements in
self
based on the comparator in the given block, using an unstable sort algorithm. -
#unstable_sort_by(&block : T -> _) : self
Returns a new instance with all elements sorted by the output value of the block.
-
#unstable_sort_by!(&block : T -> _) : Slice(T)
Modifies
self
by sorting all elements. -
#update(index : Int, & : T -> _) : T
Yields the current element at the given index and updates the value at that index with the block's value.
Instance methods inherited from module Comparable(Slice(T))
<(other : T) : Bool
<,
<=(other : T)
<=,
<=>(other : T)
<=>,
==(other : T)
==,
>(other : T) : Bool
>,
>=(other : T)
>=,
clamp(min, max)clamp(range : Range) clamp
Instance methods inherited from module Indexable::Mutable(T)
[]=(index : Int, value : T) : T
[]=,
fill(value : T, start : Int, count : Int) : selffill(value : T, range : Range) : self
fill(value : T) : self
fill(start : Int, count : Int, & : Int32 -> T) : self
fill(range : Range, & : Int32 -> T) : self
fill(*, offset : Int = 0, & : Int32 -> T) : self fill, map!(& : T -> _) : self map!, map_with_index!(offset = 0, & : T, Int32 -> _) : self map_with_index!, reverse! : self reverse!, rotate!(n : Int = 1) : self rotate!, shuffle!(random : Random = Random::DEFAULT) : self shuffle!, sort! : self
sort!(&block : T, T -> U) : self forall U sort!, sort_by!(&block : T -> _) : self sort_by!, swap(index0 : Int, index1 : Int) : self swap, unsafe_put(index : Int, value : T) unsafe_put, unstable_sort! : self
unstable_sort!(&block : T, T -> U) : self forall U unstable_sort!, unstable_sort_by!(&block : T -> _) : self unstable_sort_by!, update(index : Int, & : T -> _) : T update
Instance methods inherited from module Indexable(T)
[](index : Int)
[],
[]?(index : Int)
[]?,
bsearch(& : T -> _)
bsearch,
bsearch_index(& : T, Int32 -> _)
bsearch_index,
cartesian_product(*others : Indexable)
cartesian_product,
combinations(size : Int = self.size)
combinations,
dig(index : Int, *subindexes)
dig,
dig?(index : Int, *subindexes)
dig?,
each(& : T -> )each
each(*, start : Int, count : Int, & : T -> )
each(*, within range : Range, & : T -> ) each, each_cartesian(*others : Indexable, &)
each_cartesian(*others : Indexable) each_cartesian, each_combination(size : Int = self.size, reuse = false, &) : Nil
each_combination(size : Int = self.size, reuse = false) each_combination, each_index(& : Int32 -> ) : Nil
each_index
each_index(*, start : Int, count : Int, &) each_index, each_permutation(size : Int = self.size, reuse = false, &) : Nil
each_permutation(size : Int = self.size, reuse = false) each_permutation, each_repeated_combination(size : Int = self.size, reuse = false, &) : Nil
each_repeated_combination(size : Int = self.size, reuse = false) each_repeated_combination, empty? : Bool empty?, equals?(other : Indexable, &) : Bool
equals?(other, &) equals?, fetch(index : Int, &)
fetch(index, default) fetch, first(&) first, hash(hasher) hash, index(object, offset : Int = 0)
index(offset : Int = 0, & : T -> ) index, index!(obj, offset : Int = 0)
index!(offset : Int = 0, & : T -> ) index!, join(separator : String | Char | Number = "") : String join, last : T
last(&) last, last? : T | Nil last?, permutations(size : Int = self.size) : Array(Array(T)) permutations, repeated_combinations(size : Int = self.size) : Array(Array(T)) repeated_combinations, reverse_each(& : T -> ) : Nil
reverse_each reverse_each, rindex(value, offset = size - 1)
rindex(offset = size - 1, & : T -> ) rindex, rindex!(value, offset = size - 1)
rindex!(offset = size - 1, & : T -> ) rindex!, sample(n : Int, random : Random = Random::DEFAULT) : Array(T)
sample(random : Random = Random::DEFAULT) sample, size size, to_a : Array(T)
to_a(& : T -> U) : Array(U) forall U to_a, unsafe_fetch(index : Int) unsafe_fetch, values_at(*indexes : Int) values_at
Class methods inherited from module Indexable(T)
cartesian_product(indexables : Indexable(Indexable))
cartesian_product,
each_cartesian(indexables : Indexable(Indexable), reuse = false, &)each_cartesian(indexables : Indexable(Indexable), reuse = false) each_cartesian
Instance methods inherited from module Enumerable(T)
accumulate(initial : U) : Array(U) forall Uaccumulate : Array(T)
accumulate(initial : U, &block : U, T -> U) : Array(U) forall U
accumulate(&block : T, T -> T) : Array(T) accumulate, all?(& : T -> ) : Bool
all?(pattern) : Bool
all? : Bool all?, any?(& : T -> ) : Bool
any?(pattern) : Bool
any? : Bool any?, chunks(&block : T -> U) forall U chunks, compact_map(& : T -> _) compact_map, count(& : T -> ) : Int32
count(item) : Int32 count, cycle(n, & : T -> ) : Nil
cycle(& : T -> ) : Nil cycle, each(& : T -> ) each, each_cons(count : Int, reuse = false, &) each_cons, each_cons_pair(& : T, T -> ) : Nil each_cons_pair, each_slice(count : Int, reuse = false, &) each_slice, each_step(n : Int, *, offset : Int = 0, & : T -> ) : Nil each_step, each_with_index(offset = 0, &) each_with_index, each_with_object(obj : U, & : T, U -> ) : U forall U each_with_object, empty? : Bool empty?, find(if_none = nil, & : T -> ) find, find!(& : T -> ) : T find!, first(&)
first(count : Int) : Array(T)
first : T first, first? : T | Nil first?, flat_map(& : T -> _) flat_map, group_by(& : T -> U) forall U group_by, in_groups_of(size : Int, filled_up_with : U = nil) forall U
in_groups_of(size : Int, filled_up_with : U = nil, reuse = false, &) forall U in_groups_of, in_slices_of(size : Int) : Array(Array(T)) in_slices_of, includes?(obj) : Bool includes?, index(& : T -> ) : Int32 | Nil
index(obj) : Int32 | Nil index, index!(& : T -> ) : Int32
index!(obj) : Int32 index!, index_by(& : T -> U) : Hash(U, T) forall U index_by, join(io : IO, separator = "") : Nil
join(separator, io : IO) : Nil
join(separator = "") : String
join(io : IO, separator = "", & : T, IO -> )
join(separator, io : IO, &)
join(separator = "", & : T -> ) join, map(& : T -> U) : Array(U) forall U map, map_with_index(offset = 0, & : T, Int32 -> U) : Array(U) forall U map_with_index, max(count : Int) : Array(T)
max : T max, max? : T | Nil max?, max_by(& : T -> U) : T forall U max_by, max_by?(& : T -> U) : T | Nil forall U max_by?, max_of(& : T -> U) : U forall U max_of, max_of?(& : T -> U) : U | Nil forall U max_of?, min(count : Int) : Array(T)
min : T min, min? : T | Nil min?, min_by(& : T -> U) : T forall U min_by, min_by?(& : T -> U) : T | Nil forall U min_by?, min_of(& : T -> U) : U forall U min_of, min_of?(& : T -> U) : U | Nil forall U min_of?, minmax : Tuple(T, T) minmax, minmax? : Tuple(T | Nil, T | Nil) minmax?, minmax_by(& : T -> U) : Tuple(T, T) forall U minmax_by, minmax_by?(& : T -> U) : Tuple(T, T) | Tuple(Nil, Nil) forall U minmax_by?, minmax_of(& : T -> U) : Tuple(U, U) forall U minmax_of, minmax_of?(& : T -> U) : Tuple(U, U) | Tuple(Nil, Nil) forall U minmax_of?, none?(& : T -> ) : Bool
none?(pattern) : Bool
none? : Bool none?, one?(& : T -> ) : Bool
one?(pattern) : Bool
one? : Bool one?, partition(& : T -> ) : Tuple(Array(T), Array(T))
partition(type : U.class) forall U partition, present? : Bool present?, product(initial : Number)
product
product(initial : Number, & : T -> )
product(& : T -> _) product, reduce(memo, &)
reduce(&) reduce, reduce?(&) reduce?, reject(& : T -> )
reject(type : U.class) forall U
reject(pattern) : Array(T) reject, sample(n : Int, random : Random = Random::DEFAULT) : Array(T)
sample(random : Random = Random::DEFAULT) : T sample, select(& : T -> )
select(type : U.class) : Array(U) forall U
select(pattern) : Array(T) select, size : Int32 size, skip(count : Int) skip, skip_while(& : T -> ) : Array(T) skip_while, sum(initial)
sum
sum(initial, & : T -> )
sum(& : T -> ) sum, take_while(& : T -> ) : Array(T) take_while, tally(hash)
tally : Hash(T, Int32) tally, tally_by(hash, &)
tally_by(&block : T -> U) : Hash(U, Int32) forall U tally_by, to_a : Array(T)
to_a(& : T -> U) : Array(U) forall U to_a, to_h
to_h(& : T -> Tuple(K, V)) forall K, V to_h, to_set : Set(T)
to_set(&block : T -> U) : Set(U) forall U to_set, zip(*others : Indexable | Iterable | Iterator, &)
zip(*others : Indexable | Iterable | Iterator) zip, zip?(*others : Indexable | Iterable | Iterator, &)
zip?(*others : Indexable | Iterable | Iterator) zip?
Class methods inherited from module Enumerable(T)
element_type(x)
element_type
Instance methods inherited from module Iterable(T)
chunk(reuse = false, &block : T -> U) forall U
chunk,
chunk_while(reuse : Bool | Array(T) = false, &block : T, T -> B) forall B
chunk_while,
cycle(n)cycle cycle, each each, each_cons(count : Int, reuse = false) each_cons, each_cons_pair each_cons_pair, each_slice(count : Int, reuse = false) each_slice, each_step(n : Int)
each_step(n : Int, *, offset : Int) each_step, each_with_index(offset = 0) each_with_index, each_with_object(obj) each_with_object, slice_after(reuse : Bool | Array(T) = false, &block : T -> B) forall B
slice_after(pattern, reuse : Bool | Array(T) = false) slice_after, slice_before(reuse : Bool | Array(T) = false, &block : T -> B) forall B
slice_before(pattern, reuse : Bool | Array(T) = false) slice_before, slice_when(reuse : Bool | Array(T) = false, &block : T, T -> B) forall B slice_when
Instance methods inherited from struct Struct
==(other) : Bool
==,
hash(hasher)
hash,
inspect(io : IO) : Nil
inspect,
pretty_print(pp) : Nil
pretty_print,
to_s(io : IO) : Nil
to_s
Instance methods inherited from struct Value
==(other : JSON::Any)==(other : YAML::Any)
==(other) ==, dup dup
Instance methods inherited from class Object
! : Bool
!,
!=(other)
!=,
!~(other)
!~,
==(other)
==,
===(other : JSON::Any)===(other : YAML::Any)
===(other) ===, =~(other) =~, as(type : Class) as, as?(type : Class) as?, class class, dup dup, hash(hasher)
hash hash, in?(collection : Object) : Bool
in?(*values : Object) : Bool in?, inspect(io : IO) : Nil
inspect : String inspect, is_a?(type : Class) : Bool is_a?, itself itself, nil? : Bool nil?, not_nil!(message)
not_nil! not_nil!, pretty_inspect(width = 79, newline = "\n", indent = 0) : String pretty_inspect, pretty_print(pp : PrettyPrint) : Nil pretty_print, responds_to?(name : Symbol) : Bool responds_to?, tap(&) tap, to_json(io : IO) : Nil
to_json : String to_json, to_pretty_json(indent : String = " ") : String
to_pretty_json(io : IO, indent : String = " ") : Nil to_pretty_json, to_s(io : IO) : Nil
to_s : String to_s, to_yaml(io : IO) : Nil
to_yaml : String to_yaml, try(&) try, unsafe_as(type : T.class) forall T unsafe_as
Class methods inherited from class Object
from_json(string_or_io, root : String)from_json(string_or_io) from_json, from_yaml(string_or_io : String | IO) from_yaml
Macros inherited from class Object
class_getter(*names, &block)
class_getter,
class_getter!(*names)
class_getter!,
class_getter?(*names, &block)
class_getter?,
class_property(*names, &block)
class_property,
class_property!(*names)
class_property!,
class_property?(*names, &block)
class_property?,
class_setter(*names)
class_setter,
def_clone
def_clone,
def_equals(*fields)
def_equals,
def_equals_and_hash(*fields)
def_equals_and_hash,
def_hash(*fields)
def_hash,
delegate(*methods, to object)
delegate,
forward_missing_to(delegate)
forward_missing_to,
getter(*names, &block)
getter,
getter!(*names)
getter!,
getter?(*names, &block)
getter?,
property(*names, &block)
property,
property!(*names)
property!,
property?(*names, &block)
property?,
setter(*names)
setter
Constructor Detail
Returns the additive identity of this type.
This is an empty slice.
Returns a new slice that has the elements from slices joined together.
Slice.join([Slice[1, 2], Slice[3, 4, 5]]) # => Slice[1, 2, 3, 4, 5]
Slice.join({Slice[1], Slice['a'], Slice["xyz"]}) # => Slice[1, 'a', "xyz"]
See also: #+(other : Slice)
.
Creates a slice to the given pointer, bounded by the given size. This method does not allocate heap memory.
ptr = Pointer.malloc(9) { |i| ('a'.ord + i).to_u8 }
slice = Slice.new(ptr, 3)
slice.size # => 3
slice # => Bytes[97, 98, 99]
String.new(slice) # => "abc"
Allocates size * sizeof(T)
bytes of heap memory initialized to value
and returns a slice pointing to that memory.
The memory is allocated by the GC
, so when there are
no pointers to this memory, it will be automatically freed.
slice = Slice.new(3, 10)
slice # => Slice[10, 10, 10]
Allocates size * sizeof(T)
bytes of heap memory initialized to zero
and returns a slice pointing to that memory.
The memory is allocated by the GC
, so when there are
no pointers to this memory, it will be automatically freed.
Only works for primitive integers and floats (UInt8
, Int32
, Float64
, etc.)
slice = Slice(UInt8).new(3)
slice # => Bytes[0, 0, 0]
Allocates size * sizeof(T)
bytes of heap memory initialized to the value
returned by the block (which is invoked once with each index in the range 0...size
)
and returns a slice pointing to that memory.
The memory is allocated by the GC
, so when there are
no pointers to this memory, it will be automatically freed.
slice = Slice.new(3) { |i| i + 10 }
slice # => Slice[10, 11, 12]
Class Method Detail
Constructs a read-only Slice
constant from the given args. The slice
contents are stored in the program's read-only data section.
T
must be one of the Number::Primitive
types and cannot be a union. It
also cannot be inferred. The args must all be number literals that fit
into T
's range, as if they are autocasted into T
.
x = Slice(UInt8).literal(0, 1, 4, 9, 16, 25)
x # => Slice[0, 1, 4, 9, 16, 25]
x.read_only? # => true
EXPERIMENTAL Slice literals are still under development. Join the discussion at #2886.
Macro Detail
Creates a new Slice
with the given args. The type of the
slice will be the union of the type of the given args.
The slice is allocated on the heap.
slice = Slice[1, 'a']
slice[0] # => 1
slice[1] # => 'a'
slice.class # => Slice(Char | Int32)
If T
is a Number
then this is equivalent to
Number.slice
(numbers will be coerced to the type T
)
Number.slice
is a convenient alternative for designating a specific numerical item type.
Instance Method Detail
Returns a new slice that is offset elements apart from this slice.
slice = Slice.new(5) { |i| i + 10 }
slice # => Slice[10, 11, 12, 13, 14]
slice2 = slice + 2
slice2 # => Slice[12, 13, 14]
Returns a new slice that has self
's elements followed by other's
elements.
Slice[1, 2] + Slice[3, 4, 5] # => Slice[1, 2, 3, 4, 5]
Slice[1, 2, 3] + Slice['a', 'b', 'c'] # => Slice[1, 2, 3, 'a', 'b', 'c']
See also: Slice.join
to join multiple slices at once without creating
intermediate results.
Combined comparison operator.
Returns a negative number, 0
, or a positive number depending on
whether self
is less than other, equals other.
It compares the elements of both slices in the same position using the
<=>
operator. As soon as one of such comparisons returns a non-zero
value, that result is the return value of the comparison.
If all elements are equal, the comparison is based on the size of the arrays.
Bytes[8] <=> Bytes[1, 2, 3] # => 7
Bytes[2] <=> Bytes[4, 2, 3] # => -2
Bytes[1, 2] <=> Bytes[1, 2] # => 0
Returns true
if self
and other have the same size and all their
elements are equal, false
otherwise.
Bytes[1, 2] == Bytes[1, 2] # => true
Bytes[1, 3] == Bytes[1, 2] # => false
Bytes[1, 2] == Bytes[1, 2, 3] # => false
Returns a new slice that starts at start elements from this slice's start, and of count size.
Raises IndexError
if the new slice falls outside this slice.
slice = Slice.new(5) { |i| i + 10 }
slice # => Slice[10, 11, 12, 13, 14]
slice[1, 3] # => Slice[11, 12, 13]
slice[1, 33] # raises IndexError
Returns a new slice with the elements in the given range.
The first element in the returned slice is self[range.begin]
followed
by the next elements up to index range.end
(or self[range.end - 1]
if
the range is exclusive).
If there are fewer elements in self
, the returned slice is shorter than
range.size
.
a = Slice["a", "b", "c", "d", "e"]
a[1..3] # => Slice["b", "c", "d"]
Negative indices count backward from the end of the slice (-1
is the last
element). Additionally, an empty slice is returned when the starting index
for an element range is at the end of the slice.
Raises IndexError
if the new slice falls outside this slice.
slice = Slice.new(5) { |i| i + 10 }
slice # => Slice[10, 11, 12, 13, 14]
slice[1..3] # => Slice[11, 12, 13]
slice[1..33] # raises IndexError
Sets the given value at the given index. Returns value.
Negative indices can be used to start counting from the end of the
container. Raises IndexError
if trying to set an element outside the
container's range.
ary = [1, 2, 3]
ary[0] = 5
ary # => [5, 2, 3]
ary[3] = 5 # raises IndexError
Raises if this slice is read-only.
Returns a new slice that starts at start elements from this slice's start, and of count size.
Returns nil
if the new slice falls outside this slice.
slice = Slice.new(5) { |i| i + 10 }
slice # => Slice[10, 11, 12, 13, 14]
slice[1, 3]? # => Slice[11, 12, 13]
slice[1, 33]? # => nil
Returns a new slice with the elements in the given range.
Negative indices count backward from the end of the slice (-1
is the last
element). Additionally, an empty slice is returned when the starting index
for an element range is at the end of the slice.
Returns nil
if the new slice falls outside this slice.
slice = Slice.new(5) { |i| i + 10 }
slice # => Slice[10, 11, 12, 13, 14]
slice[1..3]? # => Slice[11, 12, 13]
slice[1..33]? # => nil
Returns a deep copy of this slice.
This method allocates memory for the slice copy and stores the return values
from calling #clone
on each item.
Copies the contents of source into this slice.
Raises IndexError
if the destination slice cannot fit the data being transferred.
Copies the contents of this slice into target.
Raises IndexError
if the destination slice cannot fit the data being transferred
e.g. dest.size < self.size
.
src = Slice['a', 'a', 'a']
dst = Slice['b', 'b', 'b', 'b', 'b']
src.copy_to dst
dst # => Slice['a', 'a', 'a', 'b', 'b']
dst.copy_to src # raises IndexError
Returns a shallow copy of this slice.
This method allocates memory for the slice copy and duplicates the values.
Replaces count or less (if there aren't enough) elements starting at the
given start index with value. Returns self
.
Negative values of start count from the end of the container.
Raises IndexError
if the start index is out of range.
Raises ArgumentError
if count is negative.
array = [1, 2, 3, 4, 5]
array.fill(9, 2, 2) # => [1, 2, 9, 9, 5]
array # => [1, 2, 9, 9, 5]
Raises if this slice is read-only.
Replaces the elements within the given range with value. Returns self
.
Negative indices count backward from the end of the container.
Raises IndexError
if the starting index is out of range.
array = [1, 2, 3, 4, 5]
array.fill(9, 2..3) # => [1, 2, 9, 9, 5]
array # => [1, 2, 9, 9, 5]
Raises if this slice is read-only.
Replaces every element in self
with the given value. Returns self
.
array = [1, 2, 3, 4]
array.fill(2) # => [2, 2, 2, 2]
array # => [2, 2, 2, 2]
Raises if this slice is read-only.
Yields each index of self
, starting at start and for count times (or
less if there aren't enough elements), to the given block and then assigns
the block's value in that position. Returns self
.
Negative values of start count from the end of the container.
Has no effect if count is zero or negative.
Raises IndexError
if start is outside the array range.
a = [1, 2, 3, 4, 5, 6]
a.fill(2, 3) { |i| i * i * i } # => [1, 2, 8, 27, 64, 6]
Raises if this slice is read-only.
Yields each index of self
, in the given range, to the given block and
then assigns the block's value in that position. Returns self
.
Negative indices count backward from the end of the container.
Raises IndexError
if the starting index is out of range.
a = [1, 2, 3, 4, 5, 6]
a.fill(2..4) { |i| i * i * i } # => [1, 2, 8, 27, 64, 6]
Raises if this slice is read-only.
Yields each index of self
to the given block and then assigns
the block's value in that position. Returns self
.
Accepts an optional offset parameter, which tells the block to start counting from there.
array = [2, 1, 1, 1]
array.fill { |i| i * i } # => [0, 1, 4, 9]
array # => [0, 1, 4, 9]
array.fill(offset: 3) { |i| i * i } # => [9, 16, 25, 36]
array # => [9, 16, 25, 36]
Raises if this slice is read-only.
Writes a hexdump of this slice to the given io.
self
must be a Slice(UInt8)
. To call this method on other Slice
s,
#to_unsafe_bytes
should be used first.
This method is specially useful for debugging binary data and incoming/outgoing data in protocols.
Returns the number of bytes written to io.
slice = UInt8.slice(97, 62, 63, 8, 255)
slice.hexdump(STDOUT)
Prints:
00000000 61 3e 3f 08 ff a>?..
Returns a hexdump of this slice.
self
must be a Slice(UInt8)
. To call this method on other Slice
s,
#to_unsafe_bytes
should be used first.
This method is specially useful for debugging binary data and incoming/outgoing data in protocols.
slice = UInt8.slice(97, 62, 63, 8, 255)
slice.hexdump # => "00000000 61 3e 3f 08 ff a>?..\n"
# assume little-endian system
slice = Int16.slice(97, 62, 1000, -2)
slice.to_unsafe_bytes.hexdump # => "00000000 61 00 3e 00 e8 03 fe ff a.>.....\n"
Returns a hexstring representation of this slice.
self
must be a Slice(UInt8)
. To call this method on other Slice
s,
#to_unsafe_bytes
should be used first.
UInt8.slice(97, 62, 63, 8, 255).hexstring # => "613e3f08ff"
# assume little-endian system
Int16.slice(97, 62, 1000, -2).to_unsafe_bytes.hexstring # => "61003e00e803feff"
Returns the index of the first appearance of object in self
starting from the given offset, or nil
if object is not in self
.
[1, 2, 3, 1, 2, 3].index(2, offset: 2) # => 4
Appends this struct's name and instance variables names and values to the given IO.
struct Point
def initialize(@x : Int32, @y : Int32)
end
end
p1 = Point.new 1, 2
p1.to_s # "Point(@x=1, @y=2)"
p1.inspect # "Point(@x=1, @y=2)"
Returns a new slice where elements are mapped by the given block.
slice = Slice[1, 2.5, "a"]
slice.map &.to_s # => Slice["1", "2.5", "a"]
Invokes the given block for each element of self
, replacing the element
with the value returned by the block. Returns self
.
a = [1, 2, 3]
a.map! { |x| x * x }
a # => [1, 4, 9]
Raises if this slice is read-only.
Like #map
, but the block gets passed both the element and its index.
Accepts an optional offset parameter, which tells it to start counting from there.
Like #map!
, but the block gets passed both the element and its index.
Accepts an optional offset parameter, which tells it to start counting from there.
gems = ["crystal", "pearl", "diamond"]
gems.map_with_index! { |gem, i| "#{i}: #{gem}" }
gems # => ["0: crystal", "1: pearl", "2: diamond"]
Raises if this slice is read-only.
Moves the contents of source into this slice. source and self
may
overlap; the copy is always done in a non-destructive manner.
Raises IndexError
if the destination slice cannot fit the data being transferred.
Moves the contents of this slice into target. target and self
may
overlap; the copy is always done in a non-destructive manner.
Raises IndexError
if the destination slice cannot fit the data being transferred
e.g. dest.size < self.size
.
src = Slice['a', 'a', 'a']
dst = Slice['b', 'b', 'b', 'b', 'b']
src.move_to dst
dst # => Slice['a', 'a', 'a', 'b', 'b']
dst.move_to src # raises IndexError
See also: Pointer#move_to
.
Reverses in-place all the elements of self
. Returns self
.
Raises if this slice is read-only.
Shifts all elements of self
to the left n times. Returns self
.
a1 = [0, 1, 2, 3, 4, 5, 6, 7, 8, 9]
a2 = [0, 1, 2, 3, 4, 5, 6, 7, 8, 9]
a3 = [0, 1, 2, 3, 4, 5, 6, 7, 8, 9]
a1.rotate!
a2.rotate!(1)
a3.rotate!(3)
a1 # => [1, 2, 3, 4, 5, 6, 7, 8, 9, 0]
a2 # => [1, 2, 3, 4, 5, 6, 7, 8, 9, 0]
a3 # => [3, 4, 5, 6, 7, 8, 9, 0, 1, 2]
Raises if this slice is read-only.
Modifies self
by randomizing the order of elements in the collection
using the given random number generator. Returns self
.
a = [1, 2, 3, 4, 5]
a.shuffle!(Random.new(42)) # => [3, 2, 4, 5, 1]
a # => [3, 2, 4, 5, 1]
Raises if this slice is read-only.
Returns a new instance with all elements sorted based on the return value of
their comparison method T#<=>
(see Comparable#<=>
), using a stable sort algorithm.
a = Slice[3, 1, 2]
a.sort # => Slice[1, 2, 3]
a # => Slice[3, 1, 2]
See #sort!
for details on the sorting mechanism.
Raises ArgumentError
if the comparison between any two elements returns nil
.
Returns a new instance with all elements sorted based on the comparator in the given block, using a stable sort algorithm.
a = Slice[3, 1, 2]
b = a.sort { |a, b| b <=> a }
b # => Slice[3, 2, 1]
a # => Slice[3, 1, 2]
See Indexable::Mutable#sort!(&block : T, T -> U)
for details on the sorting mechanism.
Raises ArgumentError
if for any two elements the block returns nil
.
Sorts all elements in self
based on the return value of the comparison
method T#<=>
(see Comparable#<=>
), using a stable sort algorithm.
slice = Slice[3, 1, 2]
slice.sort!
slice # => Slice[1, 2, 3]
This sort operation modifies self
. See #sort
for a non-modifying option
that allocates a new instance.
The sort mechanism is implemented as merge sort. It is stable, which is typically a good default.
Stability means that two elements which compare equal (i.e. a <=> b == 0
)
keep their original relation. Stable sort guarantees that [a, b].sort!
always results in [a, b]
(given they compare equal). With unstable sort,
the result could also be [b, a]
.
If stability is expendable, #unstable_sort!
provides a performance
advantage over stable sort.
Raises ArgumentError
if the comparison between any two elements returns nil
.
Sorts all elements in self
based on the comparator in the given block, using
a stable sort algorithm.
slice = Slice[3, 1, 2]
# This is a reverse sort (forward sort would be `a <=> b`)
slice.sort! { |a, b| b <=> a }
slice # => Slice[3, 2, 1]
The block must implement a comparison between two elements a and b,
where a < b
outputs a negative value, a == b
outputs 0
, and a > b
outputs a positive value.
The comparison operator (Comparable#<=>
) can be used for this.
The block's output type must be <= Int32?
, but returning an actual nil
value is an error.
This sort operation modifies self
. See #sort(&block : T, T -> U)
for a
non-modifying option that allocates a new instance.
The sort mechanism is implemented as merge sort. It is stable, which is typically a good default.
Stability means that two elements which compare equal (i.e. a <=> b == 0
)
keep their original relation. Stable sort guarantees that [a, b].sort!
always results in [a, b]
(given they compare equal). With unstable sort,
the result could also be [b, a]
.
If stability is expendable, #unstable_sort!(&block : T, T -> U)
provides a
performance advantage over stable sort.
Raises ArgumentError
if for any two elements the block returns nil
.
Returns a new instance with all elements sorted by the output value of the
block. The output values are compared via the comparison method T#<=>
(see Comparable#<=>
), using a stable sort algorithm.
a = Slice["apple", "pear", "fig"]
b = a.sort_by { |word| word.size }
b # => Slice["fig", "pear", "apple"]
a # => Slice["apple", "pear", "fig"]
If stability is expendable, #unstable_sort_by(&block : T -> _)
provides a
performance advantage over stable sort.
See Indexable::Mutable#sort_by!(&block : T -> _)
for details on the sorting mechanism.
Raises ArgumentError
if the comparison between any two comparison values returns nil
.
Modifies self
by sorting all elements. The given block is called for
each element, then the comparison method <=>
is called on the object
returned from the block to determine sort order.
a = Slice["apple", "pear", "fig"]
a.sort_by! { |word| word.size }
a # => Slice["fig", "pear", "apple"]
Swaps the elements at index0 and index1. Returns self
.
Negative indices can be used to start counting from the end of the
container. Raises IndexError
if either index is out of bounds.
a = ["first", "second", "third"]
a.swap(1, 2) # => ["first", "third", "second"]
a # => ["first", "third", "second"]
a.swap(0, -1) # => ["second", "third", "first"]
a # => ["second", "third", "first"]
a.swap(2, 3) # raises IndexError
Raises if this slice is read-only.
Returns an Array
with all the elements in the collection.
{1, 2, 3}.to_a # => [1, 2, 3]
Returns this slice's pointer.
slice = Slice.new(3, 10)
slice.to_unsafe[0] # => 10
Returns a new Bytes
pointing at the same contents as self
.
WARNING This method is unsafe: the returned slice is writable if self
is also writable, and modifications through the returned slice may violate
the binary representations of Crystal objects. Additionally, the same
elements may produce different results depending on the system endianness.
# assume little-endian system
ints = Slice[0x01020304, 0x05060708]
bytes = ints.to_unsafe_bytes # => Bytes[0x04, 0x03, 0x02, 0x01, 0x08, 0x07, 0x06, 0x05]
bytes[2] = 0xAD
ints # => Slice[0x01AD0304, 0x05060708]
Returns the element at the given index, without doing any bounds check.
Indexable
makes sure to invoke this method with index in 0...size
,
so converting negative indices to positive ones is not needed here.
Clients never invoke this method directly. Instead, they access
elements with #[](index)
and #[]?(index)
.
This method should only be directly invoked if you are absolutely sure the index is in bounds, to avoid a bounds check for a small boost of performance.
Sets the element at the given index to value, without doing any bounds check.
Indexable::Mutable
makes sure to invoke this method with index in
0...size
, so converting negative indices to positive ones is not needed
here.
Clients never invoke this method directly. Instead, they modify elements
with #[]=(index, value)
.
This method should only be directly invoked if you are absolutely sure the index is in bounds, to avoid a bounds check for a small boost of performance.
Returns a new Slice
pointing at the same contents as self
, but
reinterpreted as elements of the given type.
The returned slice never refers to more memory than self
; if the last
bytes of self
do not fit into a U
, they are excluded from the returned
slice.
WARNING This method is unsafe: elements are reinterpreted using
#unsafe_as
, and the resulting slice may not be properly aligned.
Additionally, the same elements may produce different results depending on
the system endianness.
# assume little-endian system
bytes = Bytes[0x01, 0x02, 0x03, 0x04, 0xFF, 0xFE]
bytes.unsafe_slice_of(Int8) # => Slice[1_i8, 2_i8, 3_i8, 4_i8, -1_i8, -2_i8]
bytes.unsafe_slice_of(Int16) # => Slice[513_i16, 1027_i16, -257_i16]
bytes.unsafe_slice_of(Int32) # => Slice[0x04030201]
Returns a new instance with all elements sorted based on the return value of
their comparison method T#<=>
(see Comparable#<=>
), using an unstable sort algorithm.
a = Slice[3, 1, 2]
a.unstable_sort # => Slice[1, 2, 3]
a # => Slice[3, 1, 2]
See Indexable::Mutable#unstable_sort!
for details on the sorting mechanism.
Raises ArgumentError
if the comparison between any two elements returns nil
.
Returns a new instance with all elements sorted based on the comparator in the given block, using an unstable sort algorithm.
a = Slice[3, 1, 2]
b = a.unstable_sort { |a, b| b <=> a }
b # => Slice[3, 2, 1]
a # => Slice[3, 1, 2]
See Indexable::Mutable#unstable_sort!(&block : T, T -> U)
for details on the sorting mechanism.
Raises ArgumentError
if for any two elements the block returns nil
.
Sorts all elements in self
based on the return value of the comparison
method T#<=>
(see Comparable#<=>
), using an unstable sort algorithm..
slice = Slice[3, 1, 2]
slice.unstable_sort!
slice # => Slice[1, 2, 3]
This sort operation modifies self
. See #unstable_sort
for a non-modifying
option that allocates a new instance.
The sort mechanism is implemented as introsort. It does not guarantee stability between equally comparing elements. This offers higher performance but may be unexpected in some situations.
Stability means that two elements which compare equal (i.e. a <=> b == 0
)
keep their original relation. Stable sort guarantees that [a, b].sort!
always results in [a, b]
(given they compare equal). With unstable sort,
the result could also be [b, a]
.
If stability is necessary, use #sort!
instead.
Raises ArgumentError
if the comparison between any two elements returns nil
.
Sorts all elements in self
based on the comparator in the given block,
using an unstable sort algorithm.
slice = Slice[3, 1, 2]
# This is a reverse sort (forward sort would be `a <=> b`)
slice.unstable_sort! { |a, b| b <=> a }
slice # => Slice[3, 2, 1]
The block must implement a comparison between two elements a and b,
where a < b
outputs a negative value, a == b
outputs 0
, and a > b
outputs a positive value.
The comparison operator (Comparable#<=>
) can be used for this.
The block's output type must be <= Int32?
, but returning an actual nil
value is an error.
This sort operation modifies self
. See #unstable_sort(&block : T, T -> U)
for a non-modifying option that allocates a new instance.
The sort mechanism is implemented as introsort. It does not guarantee stability between equally comparing elements. This offers higher performance but may be unexpected in some situations.
Stability means that two elements which compare equal (i.e. a <=> b == 0
)
keep their original relation. Stable sort guarantees that [a, b].sort!
always results in [a, b]
(given they compare equal). With unstable sort,
the result could also be [b, a]
.
If stability is necessary, use #sort!(&block : T, T -> U)
instead.
Raises ArgumentError
if for any two elements the block returns nil
.
Returns a new instance with all elements sorted by the output value of the
block. The output values are compared via the comparison method #<=>
(see Comparable#<=>
), using an unstable sort algorithm.
a = Slice["apple", "pear", "fig"]
b = a.unstable_sort_by { |word| word.size }
b # => Slice["fig", "pear", "apple"]
a # => Slice["apple", "pear", "fig"]
If stability is necessary, use #sort_by(&block : T -> _)
instead.
See Indexable::Mutable#unstable_sort!(&block : T -> _)
for details on the sorting mechanism.
Raises ArgumentError
if the comparison between any two comparison values returns nil
.
Modifies self
by sorting all elements. The given block is called for
each element, then the comparison method <=>
is called on the object
returned from the block to determine sort order.
a = Slice["apple", "pear", "fig"]
a.sort_by! { |word| word.size }
a # => Slice["fig", "pear", "apple"]
This method does not guarantee stability between equally sorting elements. Which results in a performance advantage over stable sort.
Yields the current element at the given index and updates the value at that index with the block's value. Returns the new value.
Raises IndexError
if trying to set an element outside the container's
range.
array = [1, 2, 3]
array.update(1) { |x| x * 2 } # => 4
array # => [1, 4, 3]
array.update(5) { |x| x * 2 } # raises IndexError
Raises if this slice is read-only.