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#
#
# Nim's Runtime Library
# (c) Copyright 2012 Andreas Rumpf
#
# See the file "copying.txt", included in this
# distribution, for details about the copyright.
#
## Implementation of a `deque`:idx: (double-ended queue).
## The underlying implementation uses a ``seq``.
##
## None of the procs that get an individual value from the deque can be used
## on an empty deque.
## If compiled with `boundChecks` option, those procs will raise an `IndexDefect`
## on such access. This should not be relied upon, as `-d:danger` or `--checks:off` will
## disable those checks and may return garbage or crash the program.
##
## As such, a check to see if the deque is empty is needed before any
## access, unless your program logic guarantees it indirectly.
runnableExamples:
var a = initDeque[int]()
doAssertRaises(IndexDefect, echo a[0])
for i in 1 .. 5:
a.addLast(10*i)
assert $a == "[10, 20, 30, 40, 50]"
assert a.peekFirst == 10
assert a.peekLast == 50
assert len(a) == 5
assert a.popFirst == 10
assert a.popLast == 50
assert len(a) == 3
a.addFirst(11)
a.addFirst(22)
a.addFirst(33)
assert $a == "[33, 22, 11, 20, 30, 40]"
a.shrink(fromFirst = 1, fromLast = 2)
assert $a == "[22, 11, 20]"
## **See also:**
## * `lists module <lists.html>`_ for singly and doubly linked lists and rings
## * `channels module <channels.html>`_ for inter-thread communication
import std/private/since
import math
type
Deque*[T] = object
## A double-ended queue backed with a ringed seq buffer.
##
## To initialize an empty deque use `initDeque proc <#initDeque,int>`_.
data: seq[T]
head, tail, count, mask: int
const
defaultInitialSize* = 4
template initImpl(result: typed, initialSize: int) =
let correctSize = nextPowerOfTwo(initialSize)
result.mask = correctSize-1
newSeq(result.data, correctSize)
template checkIfInitialized(deq: typed) =
when compiles(defaultInitialSize):
if deq.mask == 0:
initImpl(deq, defaultInitialSize)
proc initDeque*[T](initialSize: int = 4): Deque[T] =
## Creates a new empty deque.
##
## Optionally, the initial capacity can be reserved via `initialSize`
## as a performance optimization.
## The length of a newly created deque will still be 0.
##
## See also:
## * `toDeque proc <#toDeque,openArray[T]>`_
result.initImpl(initialSize)
proc toDeque*[T](x: openArray[T]): Deque[T] {.since: (1, 3).} =
## Creates a new deque that contains the elements of `x` (in the same order).
##
## See also:
## * `initDeque proc <#initDeque,int>`_
runnableExamples:
var a = toDeque([7, 8, 9])
assert len(a) == 3
assert a.popFirst == 7
assert len(a) == 2
result.initImpl(x.len)
for item in items(x):
result.addLast(item)
proc len*[T](deq: Deque[T]): int {.inline.} =
## Returns the number of elements of `deq`.
result = deq.count
template emptyCheck(deq) =
# Bounds check for the regular deque access.
when compileOption("boundChecks"):
if unlikely(deq.count < 1):
raise newException(IndexDefect, "Empty deque.")
template xBoundsCheck(deq, i) =
# Bounds check for the array like accesses.
when compileOption("boundChecks"): # `-d:danger` or `--checks:off` should disable this.
if unlikely(i >= deq.count): # x < deq.low is taken care by the Natural parameter
raise newException(IndexDefect,
"Out of bounds: " & $i & " > " & $(deq.count - 1))
if unlikely(i < 0): # when used with BackwardsIndex
raise newException(IndexDefect,
"Out of bounds: " & $i & " < 0")
proc `[]`*[T](deq: Deque[T], i: Natural): T {.inline.} =
## Accesses the i-th element of `deq`.
runnableExamples:
var a = initDeque[int]()
for i in 1 .. 5:
a.addLast(10*i)
assert a[0] == 10
assert a[3] == 40
doAssertRaises(IndexDefect, echo a[8])
xBoundsCheck(deq, i)
return deq.data[(deq.head + i) and deq.mask]
proc `[]`*[T](deq: var Deque[T], i: Natural): var T {.inline.} =
## Accesses the i-th element of `deq` and return a mutable
## reference to it.
runnableExamples:
var a = initDeque[int]()
for i in 1 .. 5:
a.addLast(10*i)
assert a[0] == 10
assert a[3] == 40
doAssertRaises(IndexDefect, echo a[8])
xBoundsCheck(deq, i)
return deq.data[(deq.head + i) and deq.mask]
proc `[]=`*[T](deq: var Deque[T], i: Natural, val: T) {.inline.} =
## Changes the i-th element of `deq`.
runnableExamples:
var a = initDeque[int]()
for i in 1 .. 5:
a.addLast(10*i)
a[0] = 99
a[3] = 66
assert $a == "[99, 20, 30, 66, 50]"
checkIfInitialized(deq)
xBoundsCheck(deq, i)
deq.data[(deq.head + i) and deq.mask] = val
proc `[]`*[T](deq: Deque[T], i: BackwardsIndex): T {.inline.} =
## Accesses the backwards indexed i-th element.
##
## `deq[^1]` is the last element.
runnableExamples:
var a = initDeque[int]()
for i in 1 .. 5:
a.addLast(10*i)
assert a[^1] == 50
assert a[^4] == 20
doAssertRaises(IndexDefect, echo a[^9])
xBoundsCheck(deq, deq.len - int(i))
return deq[deq.len - int(i)]
proc `[]`*[T](deq: var Deque[T], i: BackwardsIndex): var T {.inline.} =
## Accesses the backwards indexed i-th element.
##
## `deq[^1]` is the last element.
runnableExamples:
var a = initDeque[int]()
for i in 1 .. 5:
a.addLast(10*i)
assert a[^1] == 50
assert a[^4] == 20
doAssertRaises(IndexDefect, echo a[^9])
xBoundsCheck(deq, deq.len - int(i))
return deq[deq.len - int(i)]
proc `[]=`*[T](deq: var Deque[T], i: BackwardsIndex, x: T) {.inline.} =
## Changes the backwards indexed i-th element.
##
## `deq[^1]` is the last element.
runnableExamples:
var a = initDeque[int]()
for i in 1 .. 5:
a.addLast(10*i)
a[^1] = 99
a[^3] = 77
assert $a == "[10, 20, 77, 40, 99]"
checkIfInitialized(deq)
xBoundsCheck(deq, deq.len - int(i))
deq[deq.len - int(i)] = x
iterator items*[T](deq: Deque[T]): T =
## Yields every element of `deq`.
runnableExamples:
var a = initDeque[int]()
for i in 1 .. 3:
a.addLast(10*i)
from sugar import collect
doAssert collect(for x in a: x) == [10, 20, 30]
# same as above:
doAssert collect(for x in items(a): x) == [10, 20, 30]
var i = deq.head
for c in 0 ..< deq.count:
yield deq.data[i]
i = (i + 1) and deq.mask
iterator mitems*[T](deq: var Deque[T]): var T =
## Yields every element of `deq`, which can be modified.
runnableExamples:
var a = initDeque[int]()
for i in 1 .. 5:
a.addLast(10*i)
assert $a == "[10, 20, 30, 40, 50]"
for x in mitems(a):
x = 5*x - 1
assert $a == "[49, 99, 149, 199, 249]"
var i = deq.head
for c in 0 ..< deq.count:
yield deq.data[i]
i = (i + 1) and deq.mask
iterator pairs*[T](deq: Deque[T]): tuple[key: int, val: T] =
## Yields every (position, value) of `deq`.
runnableExamples:
var a = initDeque[int]()
for i in 1 .. 3:
a.addLast(10*i)
from sugar import collect
doAssert collect(for k, v in pairs(a): (k, v)) == @[(0, 10), (1, 20), (2, 30)]
var i = deq.head
for c in 0 ..< deq.count:
yield (c, deq.data[i])
i = (i + 1) and deq.mask
proc contains*[T](deq: Deque[T], item: T): bool {.inline.} =
## Returns true if `item` is in `deq` or false if not found.
##
## Usually used via the ``in`` operator.
## It is the equivalent of ``deq.find(item) >= 0``.
runnableExamples:
var q = [7, 9].toDeque
assert 7 in q
assert q.contains 7
assert 8 notin q
for e in deq:
if e == item: return true
return false
proc expandIfNeeded[T](deq: var Deque[T]) =
checkIfInitialized(deq)
var cap = deq.mask + 1
if unlikely(deq.count >= cap):
var n = newSeq[T](cap * 2)
var i = 0
for x in mitems(deq):
when nimVM: n[i] = x # workaround for VM bug
else: n[i] = move(x)
inc i
deq.data = move(n)
deq.mask = cap * 2 - 1
deq.tail = deq.count
deq.head = 0
proc addFirst*[T](deq: var Deque[T], item: T) =
## Adds an `item` to the beginning of the `deq`.
##
## See also:
## * `addLast proc <#addLast,Deque[T],T>`_
## * `peekFirst proc <#peekFirst,Deque[T]>`_
## * `peekLast proc <#peekLast,Deque[T]>`_
## * `popFirst proc <#popFirst,Deque[T]>`_
## * `popLast proc <#popLast,Deque[T]>`_
runnableExamples:
var a = initDeque[int]()
for i in 1 .. 5:
a.addFirst(10*i)
assert $a == "[50, 40, 30, 20, 10]"
expandIfNeeded(deq)
inc deq.count
deq.head = (deq.head - 1) and deq.mask
deq.data[deq.head] = item
proc addLast*[T](deq: var Deque[T], item: T) =
## Adds an `item` to the end of the `deq`.
##
## See also:
## * `addFirst proc <#addFirst,Deque[T],T>`_
## * `peekFirst proc <#peekFirst,Deque[T]>`_
## * `peekLast proc <#peekLast,Deque[T]>`_
## * `popFirst proc <#popFirst,Deque[T]>`_
## * `popLast proc <#popLast,Deque[T]>`_
runnableExamples:
var a = initDeque[int]()
for i in 1 .. 5:
a.addLast(10*i)
assert $a == "[10, 20, 30, 40, 50]"
expandIfNeeded(deq)
inc deq.count
deq.data[deq.tail] = item
deq.tail = (deq.tail + 1) and deq.mask
proc peekFirst*[T](deq: Deque[T]): T {.inline.} =
## Returns the first element of `deq`, but does not remove it from the deque.
##
## See also:
## * `addFirst proc <#addFirst,Deque[T],T>`_
## * `addLast proc <#addLast,Deque[T],T>`_
## * `peekLast proc <#peekLast,Deque[T]>`_
## * `popFirst proc <#popFirst,Deque[T]>`_
## * `popLast proc <#popLast,Deque[T]>`_
runnableExamples:
var a = initDeque[int]()
for i in 1 .. 5:
a.addLast(10*i)
assert $a == "[10, 20, 30, 40, 50]"
assert a.peekFirst == 10
assert len(a) == 5
emptyCheck(deq)
result = deq.data[deq.head]
proc peekLast*[T](deq: Deque[T]): T {.inline.} =
## Returns the last element of `deq`, but does not remove it from the deque.
##
## See also:
## * `addFirst proc <#addFirst,Deque[T],T>`_
## * `addLast proc <#addLast,Deque[T],T>`_
## * `peekFirst proc <#peekFirst,Deque[T]>`_
## * `popFirst proc <#popFirst,Deque[T]>`_
## * `popLast proc <#popLast,Deque[T]>`_
runnableExamples:
var a = initDeque[int]()
for i in 1 .. 5:
a.addLast(10*i)
assert $a == "[10, 20, 30, 40, 50]"
assert a.peekLast == 50
assert len(a) == 5
emptyCheck(deq)
result = deq.data[(deq.tail - 1) and deq.mask]
proc peekFirst*[T](deq: var Deque[T]): var T {.inline, since: (1, 3).} =
## Returns the first element of `deq`, but does not remove it from the deque.
##
## See also:
## * `addFirst proc <#addFirst,Deque[T],T>`_
## * `addLast proc <#addLast,Deque[T],T>`_
## * `peekLast proc <#peekLast,Deque[T]>`_
## * `popFirst proc <#popFirst,Deque[T]>`_
## * `popLast proc <#popLast,Deque[T]>`_
runnableExamples:
var a = initDeque[int]()
for i in 1 .. 5:
a.addLast(10*i)
assert $a == "[10, 20, 30, 40, 50]"
assert a.peekFirst == 10
assert len(a) == 5
emptyCheck(deq)
result = deq.data[deq.head]
proc peekLast*[T](deq: var Deque[T]): var T {.inline, since: (1, 3).} =
## Returns the last element of `deq`, but does not remove it from the deque.
##
## See also:
## * `addFirst proc <#addFirst,Deque[T],T>`_
## * `addLast proc <#addLast,Deque[T],T>`_
## * `peekFirst proc <#peekFirst,Deque[T]>`_
## * `popFirst proc <#popFirst,Deque[T]>`_
## * `popLast proc <#popLast,Deque[T]>`_
runnableExamples:
var a = initDeque[int]()
for i in 1 .. 5:
a.addLast(10*i)
assert $a == "[10, 20, 30, 40, 50]"
assert a.peekLast == 50
assert len(a) == 5
emptyCheck(deq)
result = deq.data[(deq.tail - 1) and deq.mask]
template destroy(x: untyped) =
reset(x)
proc popFirst*[T](deq: var Deque[T]): T {.inline, discardable.} =
## Removes and returns the first element of the `deq`.
##
## See also:
## * `addFirst proc <#addFirst,Deque[T],T>`_
## * `addLast proc <#addLast,Deque[T],T>`_
## * `peekFirst proc <#peekFirst,Deque[T]>`_
## * `peekLast proc <#peekLast,Deque[T]>`_
## * `popLast proc <#popLast,Deque[T]>`_
## * `clear proc <#clear,Deque[T]>`_
## * `shrink proc <#shrink,Deque[T],int,int>`_
runnableExamples:
var a = initDeque[int]()
for i in 1 .. 5:
a.addLast(10*i)
assert $a == "[10, 20, 30, 40, 50]"
assert a.popFirst == 10
assert $a == "[20, 30, 40, 50]"
emptyCheck(deq)
dec deq.count
result = deq.data[deq.head]
destroy(deq.data[deq.head])
deq.head = (deq.head + 1) and deq.mask
proc popLast*[T](deq: var Deque[T]): T {.inline, discardable.} =
## Removes and returns the last element of the `deq`.
##
## See also:
## * `addFirst proc <#addFirst,Deque[T],T>`_
## * `addLast proc <#addLast,Deque[T],T>`_
## * `peekFirst proc <#peekFirst,Deque[T]>`_
## * `peekLast proc <#peekLast,Deque[T]>`_
## * `popFirst proc <#popFirst,Deque[T]>`_
## * `clear proc <#clear,Deque[T]>`_
## * `shrink proc <#shrink,Deque[T],int,int>`_
runnableExamples:
var a = initDeque[int]()
for i in 1 .. 5:
a.addLast(10*i)
assert $a == "[10, 20, 30, 40, 50]"
assert a.popLast == 50
assert $a == "[10, 20, 30, 40]"
emptyCheck(deq)
dec deq.count
deq.tail = (deq.tail - 1) and deq.mask
result = deq.data[deq.tail]
destroy(deq.data[deq.tail])
proc clear*[T](deq: var Deque[T]) {.inline.} =
## Resets the deque so that it is empty.
##
## See also:
## * `clear proc <#clear,Deque[T]>`_
## * `shrink proc <#shrink,Deque[T],int,int>`_
runnableExamples:
var a = initDeque[int]()
for i in 1 .. 5:
a.addFirst(10*i)
assert $a == "[50, 40, 30, 20, 10]"
clear(a)
assert len(a) == 0
for el in mitems(deq): destroy(el)
deq.count = 0
deq.tail = deq.head
proc shrink*[T](deq: var Deque[T], fromFirst = 0, fromLast = 0) =
## Removes `fromFirst` elements from the front of the deque and
## `fromLast` elements from the back.
##
## If the supplied number of elements exceeds the total number of elements
## in the deque, the deque will remain empty.
##
## See also:
## * `clear proc <#clear,Deque[T]>`_
runnableExamples:
var a = initDeque[int]()
for i in 1 .. 5:
a.addFirst(10*i)
assert $a == "[50, 40, 30, 20, 10]"
a.shrink(fromFirst = 2, fromLast = 1)
assert $a == "[30, 20]"
if fromFirst + fromLast > deq.count:
clear(deq)
return
for i in 0 ..< fromFirst:
destroy(deq.data[deq.head])
deq.head = (deq.head + 1) and deq.mask
for i in 0 ..< fromLast:
destroy(deq.data[deq.tail])
deq.tail = (deq.tail - 1) and deq.mask
dec deq.count, fromFirst + fromLast
proc `$`*[T](deq: Deque[T]): string =
## Turns a deque into its string representation.
result = "["
for x in deq:
if result.len > 1: result.add(", ")
result.addQuoted(x)
result.add("]")
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