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/* __ *\
** ________ ___ / / ___ Scala API **
** / __/ __// _ | / / / _ | (c) 2006-2013, LAMP/EPFL **
** __\ \/ /__/ __ |/ /__/ __ | http://scala-lang.org/ **
** /____/\___/_/ |_/____/_/ | | **
** |/ **
\* */
package scala
package collection.immutable
import scala.collection.parallel.immutable.ParRange
/** The `Range` class represents integer values in range
* ''[start;end)'' with non-zero step value `step`.
* It's a special case of an indexed sequence.
* For example:
*
* {{{
* val r1 = 0 until 10
* val r2 = r1.start until r1.end by r1.step + 1
* println(r2.length) // = 5
* }}}
*
* Ranges that contain more than `Int.MaxValue` elements can be created, but
* these overfull ranges have only limited capabilities. Any method that
* could require a collection of over `Int.MaxValue` length to be created, or
* could be asked to index beyond `Int.MaxValue` elements will throw an
* exception. Overfull ranges can safely be reduced in size by changing
* the step size (e.g. `by 3`) or taking/dropping elements. `contains`,
* `equals`, and access to the ends of the range (`head`, `last`, `tail`,
* `init`) are also permitted on overfull ranges.
*
* @param start the start of this range.
* @param end the exclusive end of the range.
* @param step the step for the range.
*
* @author Martin Odersky
* @author Paul Phillips
* @version 2.8
* @since 2.5
* @see [[http://docs.scala-lang.org/overviews/collections/concrete-immutable-collection-classes.html#ranges "Scala's Collection Library overview"]]
* section on `Ranges` for more information.
*
* @define coll range
* @define mayNotTerminateInf
* @define willNotTerminateInf
* @define doesNotUseBuilders
* '''Note:''' this method does not use builders to construct a new range,
* and its complexity is O(1).
*/
@SerialVersionUID(7618862778670199309L)
@deprecatedInheritance("The implementation details of Range makes inheriting from it unwise.", "2.11.0")
class Range(val start: Int, val end: Int, val step: Int)
extends scala.collection.AbstractSeq[Int]
with IndexedSeq[Int]
with scala.collection.CustomParallelizable[Int, ParRange]
with Serializable
{
override def par = new ParRange(this)
private def gap = end.toLong - start.toLong
private def isExact = gap % step == 0
private def hasStub = isInclusive || !isExact
private def longLength = gap / step + ( if (hasStub) 1 else 0 )
// Check cannot be evaluated eagerly because we have a pattern where
// ranges are constructed like: "x to y by z" The "x to y" piece
// should not trigger an exception. So the calculation is delayed,
// which means it will not fail fast for those cases where failing was
// correct.
override final val isEmpty = (
(start > end && step > 0)
|| (start < end && step < 0)
|| (start == end && !isInclusive)
)
@deprecated("This method will be made private, use `length` instead.", "2.11")
final val numRangeElements: Int = {
if (step == 0) throw new IllegalArgumentException("step cannot be 0.")
else if (isEmpty) 0
else {
val len = longLength
if (len > scala.Int.MaxValue) -1
else len.toInt
}
}
@deprecated("This method will be made private, use `last` instead.", "2.11")
final val lastElement =
if (isEmpty) start - step
else step match {
case 1 => if (isInclusive) end else end-1
case -1 => if (isInclusive) end else end+1
case _ =>
val remainder = (gap % step).toInt
if (remainder != 0) end - remainder
else if (isInclusive) end
else end - step
}
@deprecated("This method will be made private.", "2.11")
final val terminalElement = lastElement + step
/** The last element of this range. This method will return the correct value
* even if there are too many elements to iterate over.
*/
override def last = if (isEmpty) Nil.last else lastElement
override def head = if (isEmpty) Nil.head else start
override def min[A1 >: Int](implicit ord: Ordering[A1]): Int =
if (ord eq Ordering.Int) {
if (step > 0) head
else last
} else super.min(ord)
override def max[A1 >: Int](implicit ord: Ordering[A1]): Int =
if (ord eq Ordering.Int) {
if (step > 0) last
else head
} else super.max(ord)
protected def copy(start: Int, end: Int, step: Int): Range = new Range(start, end, step)
/** Create a new range with the `start` and `end` values of this range and
* a new `step`.
*
* @return a new range with a different step
*/
def by(step: Int): Range = copy(start, end, step)
def isInclusive = false
override def size = length
override def length = if (numRangeElements < 0) fail() else numRangeElements
private def description = "%d %s %d by %s".format(start, if (isInclusive) "to" else "until", end, step)
private def fail() = throw new IllegalArgumentException(description + ": seqs cannot contain more than Int.MaxValue elements.")
private def validateMaxLength() {
if (numRangeElements < 0)
fail()
}
final def apply(idx: Int): Int = {
validateMaxLength()
if (idx < 0 || idx >= numRangeElements) throw new IndexOutOfBoundsException(idx.toString)
else start + (step * idx)
}
@inline final override def foreach[@specialized(Unit) U](f: Int => U) {
validateMaxLength()
val isCommonCase = (start != Int.MinValue || end != Int.MinValue)
var i = start
var count = 0
val terminal = terminalElement
val step = this.step
while(
if(isCommonCase) { i != terminal }
else { count < numRangeElements }
) {
f(i)
count += 1
i += step
}
}
/** Creates a new range containing the first `n` elements of this range.
*
* $doesNotUseBuilders
*
* @param n the number of elements to take.
* @return a new range consisting of `n` first elements.
*/
final override def take(n: Int): Range = (
if (n <= 0 || isEmpty) newEmptyRange(start)
else if (n >= numRangeElements && numRangeElements >= 0) this
else {
// May have more than Int.MaxValue elements in range (numRangeElements < 0)
// but the logic is the same either way: take the first n
new Range.Inclusive(start, locationAfterN(n - 1), step)
}
)
/** Creates a new range containing all the elements of this range except the first `n` elements.
*
* $doesNotUseBuilders
*
* @param n the number of elements to drop.
* @return a new range consisting of all the elements of this range except `n` first elements.
*/
final override def drop(n: Int): Range = (
if (n <= 0 || isEmpty) this
else if (n >= numRangeElements && numRangeElements >= 0) newEmptyRange(end)
else {
// May have more than Int.MaxValue elements (numRangeElements < 0)
// but the logic is the same either way: go forwards n steps, keep the rest
copy(locationAfterN(n), end, step)
}
)
/** Creates a new range containing all the elements of this range except the last one.
*
* $doesNotUseBuilders
*
* @return a new range consisting of all the elements of this range except the last one.
*/
final override def init: Range = {
if (isEmpty)
Nil.init
dropRight(1)
}
/** Creates a new range containing all the elements of this range except the first one.
*
* $doesNotUseBuilders
*
* @return a new range consisting of all the elements of this range except the first one.
*/
final override def tail: Range = {
if (isEmpty)
Nil.tail
drop(1)
}
// Advance from the start while we meet the given test
private def argTakeWhile(p: Int => Boolean): Long = {
if (isEmpty) start
else {
var current = start
val stop = last
while (current != stop && p(current)) current += step
if (current != stop || !p(current)) current
else current.toLong + step
}
}
// Methods like apply throw exceptions on invalid n, but methods like take/drop
// are forgiving: therefore the checks are with the methods.
private def locationAfterN(n: Int) = start + (step * n)
// When one drops everything. Can't ever have unchecked operations
// like "end + 1" or "end - 1" because ranges involving Int.{ MinValue, MaxValue }
// will overflow. This creates an exclusive range where start == end
// based on the given value.
private def newEmptyRange(value: Int) = new Range(value, value, step)
final override def takeWhile(p: Int => Boolean): Range = {
val stop = argTakeWhile(p)
if (stop==start) newEmptyRange(start)
else {
val x = (stop - step).toInt
if (x == last) this
else new Range.Inclusive(start, x, step)
}
}
final override def dropWhile(p: Int => Boolean): Range = {
val stop = argTakeWhile(p)
if (stop == start) this
else {
val x = (stop - step).toInt
if (x == last) newEmptyRange(last)
else new Range.Inclusive(x + step, last, step)
}
}
final override def span(p: Int => Boolean): (Range, Range) = {
val border = argTakeWhile(p)
if (border == start) (newEmptyRange(start), this)
else {
val x = (border - step).toInt
if (x == last) (this, newEmptyRange(last))
else (new Range.Inclusive(start, x, step), new Range.Inclusive(x+step, last, step))
}
}
/** Creates a pair of new ranges, first consisting of elements before `n`, and the second
* of elements after `n`.
*
* $doesNotUseBuilders
*/
final override def splitAt(n: Int) = (take(n), drop(n))
/** Creates a new range consisting of the `length - n` last elements of the range.
*
* $doesNotUseBuilders
*/
final override def takeRight(n: Int): Range = {
if (n <= 0) newEmptyRange(start)
else if (numRangeElements >= 0) drop(numRangeElements - n)
else {
// Need to handle over-full range separately
val y = last
val x = y - step.toLong*(n-1)
if ((step > 0 && x < start) || (step < 0 && x > start)) this
else new Range.Inclusive(x.toInt, y, step)
}
}
/** Creates a new range consisting of the initial `length - n` elements of the range.
*
* $doesNotUseBuilders
*/
final override def dropRight(n: Int): Range = {
if (n <= 0) this
else if (numRangeElements >= 0) take(numRangeElements - n)
else {
// Need to handle over-full range separately
val y = last - step.toInt*n
if ((step > 0 && y < start) || (step < 0 && y > start)) newEmptyRange(start)
else new Range.Inclusive(start, y.toInt, step)
}
}
/** Returns the reverse of this range.
*
* $doesNotUseBuilders
*/
final override def reverse: Range =
if (isEmpty) this
else new Range.Inclusive(last, start, -step)
/** Make range inclusive.
*/
def inclusive =
if (isInclusive) this
else new Range.Inclusive(start, end, step)
final def contains(x: Int) = {
if (x==end && !isInclusive) false
else if (step > 0) {
if (x < start || x > end) false
else (step == 1) || (((x - start) % step) == 0)
}
else {
if (x < end || x > start) false
else (step == -1) || (((x - start) % step) == 0)
}
}
final override def sum[B >: Int](implicit num: Numeric[B]): Int = {
if (num eq scala.math.Numeric.IntIsIntegral) {
// this is normal integer range with usual addition. arithmetic series formula can be used
if (isEmpty) 0
else if (numRangeElements == 1) head
else (numRangeElements.toLong * (head + last) / 2).toInt
} else {
// user provided custom Numeric, we cannot rely on arithmetic series formula
if (isEmpty) num.toInt(num.zero)
else {
var acc = num.zero
var i = head
while(i != terminalElement) {
acc = num.plus(acc, i)
i = i + step
}
num.toInt(acc)
}
}
}
override def toIterable = this
override def toSeq = this
override def equals(other: Any) = other match {
case x: Range =>
// Note: this must succeed for overfull ranges (length > Int.MaxValue)
(x canEqual this) && {
if (isEmpty) x.isEmpty // empty sequences are equal
else // this is non-empty...
x.nonEmpty && start == x.start && { // ...so other must contain something and have same start
val l0 = last
(l0 == x.last && ( // And same end
start == l0 || step == x.step // And either the same step, or not take any steps
))
}
}
case _ =>
super.equals(other)
}
/** Note: hashCode can't be overridden without breaking Seq's
* equals contract.
*/
override def toString() = {
val endStr =
if (numRangeElements > Range.MAX_PRINT || (!isEmpty && numRangeElements < 0)) ", ... )" else ")"
take(Range.MAX_PRINT).mkString("Range(", ", ", endStr)
}
}
/** A companion object for the `Range` class.
*/
object Range {
private[immutable] val MAX_PRINT = 512 // some arbitrary value
/** Counts the number of range elements.
* @pre step != 0
* If the size of the range exceeds Int.MaxValue, the
* result will be negative.
*/
def count(start: Int, end: Int, step: Int, isInclusive: Boolean): Int = {
if (step == 0)
throw new IllegalArgumentException("step cannot be 0.")
val isEmpty = (
if (start == end) !isInclusive
else if (start < end) step < 0
else step > 0
)
if (isEmpty) 0
else {
// Counts with Longs so we can recognize too-large ranges.
val gap: Long = end.toLong - start.toLong
val jumps: Long = gap / step
// Whether the size of this range is one larger than the
// number of full-sized jumps.
val hasStub = isInclusive || (gap % step != 0)
val result: Long = jumps + ( if (hasStub) 1 else 0 )
if (result > scala.Int.MaxValue) -1
else result.toInt
}
}
def count(start: Int, end: Int, step: Int): Int =
count(start, end, step, isInclusive = false)
class Inclusive(start: Int, end: Int, step: Int) extends Range(start, end, step) {
// override def par = new ParRange(this)
override def isInclusive = true
override protected def copy(start: Int, end: Int, step: Int): Range = new Inclusive(start, end, step)
}
/** Make a range from `start` until `end` (exclusive) with given step value.
* @note step != 0
*/
def apply(start: Int, end: Int, step: Int): Range = new Range(start, end, step)
/** Make a range from `start` until `end` (exclusive) with step value 1.
*/
def apply(start: Int, end: Int): Range = new Range(start, end, 1)
/** Make an inclusive range from `start` to `end` with given step value.
* @note step != 0
*/
def inclusive(start: Int, end: Int, step: Int): Range.Inclusive = new Inclusive(start, end, step)
/** Make an inclusive range from `start` to `end` with step value 1.
*/
def inclusive(start: Int, end: Int): Range.Inclusive = new Inclusive(start, end, 1)
// BigInt and Long are straightforward generic ranges.
object BigInt {
def apply(start: BigInt, end: BigInt, step: BigInt) = NumericRange(start, end, step)
def inclusive(start: BigInt, end: BigInt, step: BigInt) = NumericRange.inclusive(start, end, step)
}
object Long {
def apply(start: Long, end: Long, step: Long) = NumericRange(start, end, step)
def inclusive(start: Long, end: Long, step: Long) = NumericRange.inclusive(start, end, step)
}
// BigDecimal uses an alternative implementation of Numeric in which
// it pretends to be Integral[T] instead of Fractional[T]. See Numeric for
// details. The intention is for it to throw an exception anytime
// imprecision or surprises might result from anything, although this may
// not yet be fully implemented.
object BigDecimal {
implicit val bigDecAsIntegral = scala.math.Numeric.BigDecimalAsIfIntegral
def apply(start: BigDecimal, end: BigDecimal, step: BigDecimal) =
NumericRange(start, end, step)
def inclusive(start: BigDecimal, end: BigDecimal, step: BigDecimal) =
NumericRange.inclusive(start, end, step)
}
// Double works by using a BigDecimal under the hood for precise
// stepping, but mapping the sequence values back to doubles with
// .doubleValue. This constructs the BigDecimals by way of the
// String constructor (valueOf) instead of the Double one, which
// is necessary to keep 0.3d at 0.3 as opposed to
// 0.299999999999999988897769753748434595763683319091796875 or so.
object Double {
implicit val bigDecAsIntegral = scala.math.Numeric.BigDecimalAsIfIntegral
implicit val doubleAsIntegral = scala.math.Numeric.DoubleAsIfIntegral
def toBD(x: Double): BigDecimal = scala.math.BigDecimal valueOf x
def apply(start: Double, end: Double, step: Double) =
BigDecimal(toBD(start), toBD(end), toBD(step)) mapRange (_.doubleValue)
def inclusive(start: Double, end: Double, step: Double) =
BigDecimal.inclusive(toBD(start), toBD(end), toBD(step)) mapRange (_.doubleValue)
}
// As there is no appealing default step size for not-really-integral ranges,
// we offer a partially constructed object.
class Partial[T, U](f: T => U) {
def by(x: T): U = f(x)
}
// Illustrating genericity with Int Range, which should have the same behavior
// as the original Range class. However we leave the original Range
// indefinitely, for performance and because the compiler seems to bootstrap
// off it and won't do so with our parameterized version without modifications.
object Int {
def apply(start: Int, end: Int, step: Int) = NumericRange(start, end, step)
def inclusive(start: Int, end: Int, step: Int) = NumericRange.inclusive(start, end, step)
}
}
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