scala.math.Ordering.scala Maven / Gradle / Ivy
Go to download
Show more of this group Show more artifacts with this name
Show all versions of scala-library Show documentation
Show all versions of scala-library Show documentation
Standard library for the Scala Programming Language
The newest version!
/* __ *\
** ________ ___ / / ___ Scala API **
** / __/ __// _ | / / / _ | (c) 2003-2013, LAMP/EPFL **
** __\ \/ /__/ __ |/ /__/ __ | http://scala-lang.org/ **
** /____/\___/_/ |_/____/_/ | | **
** |/ **
\* */
package scala
package math
import java.util.Comparator
import scala.language.{implicitConversions, higherKinds}
/** Ordering is a trait whose instances each represent a strategy for sorting
* instances of a type.
*
* Ordering's companion object defines many implicit objects to deal with
* subtypes of AnyVal (e.g. Int, Double), String, and others.
*
* To sort instances by one or more member variables, you can take advantage
* of these built-in orderings using Ordering.by and Ordering.on:
*
* {{{
* import scala.util.Sorting
* val pairs = Array(("a", 5, 2), ("c", 3, 1), ("b", 1, 3))
*
* // sort by 2nd element
* Sorting.quickSort(pairs)(Ordering.by[(String, Int, Int), Int](_._2)
*
* // sort by the 3rd element, then 1st
* Sorting.quickSort(pairs)(Ordering[(Int, String)].on(x => (x._3, x._1)))
* }}}
*
* An Ordering[T] is implemented by specifying compare(a:T, b:T), which
* decides how to order two instances a and b. Instances of Ordering[T] can be
* used by things like scala.util.Sorting to sort collections like Array[T].
*
* For example:
*
* {{{
* import scala.util.Sorting
*
* case class Person(name:String, age:Int)
* val people = Array(Person("bob", 30), Person("ann", 32), Person("carl", 19))
*
* // sort by age
* object AgeOrdering extends Ordering[Person] {
* def compare(a:Person, b:Person) = a.age compare b.age
* }
* Sorting.quickSort(people)(AgeOrdering)
* }}}
*
* This trait and scala.math.Ordered both provide this same functionality, but
* in different ways. A type T can be given a single way to order itself by
* extending Ordered. Using Ordering, this same type may be sorted in many
* other ways. Ordered and Ordering both provide implicits allowing them to be
* used interchangeably.
*
* You can import scala.math.Ordering.Implicits to gain access to other
* implicit orderings.
*
* @author Geoffrey Washburn
* @version 0.9.5, 2008-04-15
* @since 2.7
* @see [[scala.math.Ordered]], [[scala.util.Sorting]]
*/
@annotation.implicitNotFound(msg = "No implicit Ordering defined for ${T}.")
trait Ordering[T] extends Comparator[T] with PartialOrdering[T] with Serializable {
outer =>
/** Returns whether a comparison between `x` and `y` is defined, and if so
* the result of `compare(x, y)`.
*/
def tryCompare(x: T, y: T) = Some(compare(x, y))
/** Returns an integer whose sign communicates how x compares to y.
*
* The result sign has the following meaning:
*
* - negative if x < y
* - positive if x > y
* - zero otherwise (if x == y)
*/
def compare(x: T, y: T): Int
/** Return true if `x` <= `y` in the ordering. */
override def lteq(x: T, y: T): Boolean = compare(x, y) <= 0
/** Return true if `x` >= `y` in the ordering. */
override def gteq(x: T, y: T): Boolean = compare(x, y) >= 0
/** Return true if `x` < `y` in the ordering. */
override def lt(x: T, y: T): Boolean = compare(x, y) < 0
/** Return true if `x` > `y` in the ordering. */
override def gt(x: T, y: T): Boolean = compare(x, y) > 0
/** Return true if `x` == `y` in the ordering. */
override def equiv(x: T, y: T): Boolean = compare(x, y) == 0
/** Return `x` if `x` >= `y`, otherwise `y`. */
def max(x: T, y: T): T = if (gteq(x, y)) x else y
/** Return `x` if `x` <= `y`, otherwise `y`. */
def min(x: T, y: T): T = if (lteq(x, y)) x else y
/** Return the opposite ordering of this one. */
override def reverse: Ordering[T] = new Ordering[T] {
override def reverse = outer
def compare(x: T, y: T) = outer.compare(y, x)
}
/** Given f, a function from U into T, creates an Ordering[U] whose compare
* function is equivalent to:
*
* {{{
* def compare(x:U, y:U) = Ordering[T].compare(f(x), f(y))
* }}}
*/
def on[U](f: U => T): Ordering[U] = new Ordering[U] {
def compare(x: U, y: U) = outer.compare(f(x), f(y))
}
/** This inner class defines comparison operators available for `T`. */
class Ops(lhs: T) {
def <(rhs: T) = lt(lhs, rhs)
def <=(rhs: T) = lteq(lhs, rhs)
def >(rhs: T) = gt(lhs, rhs)
def >=(rhs: T) = gteq(lhs, rhs)
def equiv(rhs: T) = Ordering.this.equiv(lhs, rhs)
def max(rhs: T): T = Ordering.this.max(lhs, rhs)
def min(rhs: T): T = Ordering.this.min(lhs, rhs)
}
/** This implicit method augments `T` with the comparison operators defined
* in `scala.math.Ordering.Ops`.
*/
implicit def mkOrderingOps(lhs: T): Ops = new Ops(lhs)
}
trait LowPriorityOrderingImplicits {
/** This would conflict with all the nice implicit Orderings
* available, but thanks to the magic of prioritized implicits
* via subclassing we can make `Ordered[A] => Ordering[A]` only
* turn up if nothing else works. Since `Ordered[A]` extends
* `Comparable[A]` anyway, we can throw in some Java interop too.
*/
implicit def ordered[A <% Comparable[A]]: Ordering[A] = new Ordering[A] {
def compare(x: A, y: A): Int = x compareTo y
}
implicit def comparatorToOrdering[A](implicit cmp: Comparator[A]): Ordering[A] = new Ordering[A] {
def compare(x: A, y: A) = cmp.compare(x, y)
}
}
/** This is the companion object for the [[scala.math.Ordering]] trait.
*
* It contains many implicit orderings as well as well as methods to construct
* new orderings.
*/
object Ordering extends LowPriorityOrderingImplicits {
def apply[T](implicit ord: Ordering[T]) = ord
trait ExtraImplicits {
/** Not in the standard scope due to the potential for divergence:
* For instance `implicitly[Ordering[Any]]` diverges in its presence.
*/
implicit def seqDerivedOrdering[CC[X] <: scala.collection.Seq[X], T](implicit ord: Ordering[T]): Ordering[CC[T]] =
new Ordering[CC[T]] {
def compare(x: CC[T], y: CC[T]): Int = {
val xe = x.iterator
val ye = y.iterator
while (xe.hasNext && ye.hasNext) {
val res = ord.compare(xe.next(), ye.next())
if (res != 0) return res
}
Ordering.Boolean.compare(xe.hasNext, ye.hasNext)
}
}
/** This implicit creates a conversion from any value for which an
* implicit `Ordering` exists to the class which creates infix operations.
* With it imported, you can write methods as follows:
*
* {{{
* def lessThan[T: Ordering](x: T, y: T) = x < y
* }}}
*/
implicit def infixOrderingOps[T](x: T)(implicit ord: Ordering[T]): Ordering[T]#Ops = new ord.Ops(x)
}
/** An object containing implicits which are not in the default scope. */
object Implicits extends ExtraImplicits { }
/** Construct an Ordering[T] given a function `lt`. */
def fromLessThan[T](cmp: (T, T) => Boolean): Ordering[T] = new Ordering[T] {
def compare(x: T, y: T) = if (cmp(x, y)) -1 else if (cmp(y, x)) 1 else 0
// overrides to avoid multiple comparisons
override def lt(x: T, y: T): Boolean = cmp(x, y)
override def gt(x: T, y: T): Boolean = cmp(y, x)
override def gteq(x: T, y: T): Boolean = !cmp(x, y)
override def lteq(x: T, y: T): Boolean = !cmp(y, x)
}
/** Given f, a function from T into S, creates an Ordering[T] whose compare
* function is equivalent to:
*
* {{{
* def compare(x:T, y:T) = Ordering[S].compare(f(x), f(y))
* }}}
*
* This function is an analogue to Ordering.on where the Ordering[S]
* parameter is passed implicitly.
*/
def by[T, S](f: T => S)(implicit ord: Ordering[S]): Ordering[T] =
fromLessThan((x, y) => ord.lt(f(x), f(y)))
trait UnitOrdering extends Ordering[Unit] {
def compare(x: Unit, y: Unit) = 0
}
implicit object Unit extends UnitOrdering
trait BooleanOrdering extends Ordering[Boolean] {
def compare(x: Boolean, y: Boolean) = (x, y) match {
case (false, true) => -1
case (true, false) => 1
case _ => 0
}
}
implicit object Boolean extends BooleanOrdering
trait ByteOrdering extends Ordering[Byte] {
def compare(x: Byte, y: Byte) = x.toInt - y.toInt
}
implicit object Byte extends ByteOrdering
trait CharOrdering extends Ordering[Char] {
def compare(x: Char, y: Char) = x.toInt - y.toInt
}
implicit object Char extends CharOrdering
trait ShortOrdering extends Ordering[Short] {
def compare(x: Short, y: Short) = x.toInt - y.toInt
}
implicit object Short extends ShortOrdering
trait IntOrdering extends Ordering[Int] {
def compare(x: Int, y: Int) =
if (x < y) -1
else if (x == y) 0
else 1
}
implicit object Int extends IntOrdering
trait LongOrdering extends Ordering[Long] {
def compare(x: Long, y: Long) =
if (x < y) -1
else if (x == y) 0
else 1
}
implicit object Long extends LongOrdering
trait FloatOrdering extends Ordering[Float] {
outer =>
def compare(x: Float, y: Float) = java.lang.Float.compare(x, y)
override def lteq(x: Float, y: Float): Boolean = x <= y
override def gteq(x: Float, y: Float): Boolean = x >= y
override def lt(x: Float, y: Float): Boolean = x < y
override def gt(x: Float, y: Float): Boolean = x > y
override def equiv(x: Float, y: Float): Boolean = x == y
override def max(x: Float, y: Float): Float = math.max(x, y)
override def min(x: Float, y: Float): Float = math.min(x, y)
override def reverse: Ordering[Float] = new FloatOrdering {
override def reverse = outer
override def compare(x: Float, y: Float) = outer.compare(y, x)
override def lteq(x: Float, y: Float): Boolean = outer.lteq(y, x)
override def gteq(x: Float, y: Float): Boolean = outer.gteq(y, x)
override def lt(x: Float, y: Float): Boolean = outer.lt(y, x)
override def gt(x: Float, y: Float): Boolean = outer.gt(y, x)
}
}
implicit object Float extends FloatOrdering
trait DoubleOrdering extends Ordering[Double] {
outer =>
def compare(x: Double, y: Double) = java.lang.Double.compare(x, y)
override def lteq(x: Double, y: Double): Boolean = x <= y
override def gteq(x: Double, y: Double): Boolean = x >= y
override def lt(x: Double, y: Double): Boolean = x < y
override def gt(x: Double, y: Double): Boolean = x > y
override def equiv(x: Double, y: Double): Boolean = x == y
override def max(x: Double, y: Double): Double = math.max(x, y)
override def min(x: Double, y: Double): Double = math.min(x, y)
override def reverse: Ordering[Double] = new DoubleOrdering {
override def reverse = outer
override def compare(x: Double, y: Double) = outer.compare(y, x)
override def lteq(x: Double, y: Double): Boolean = outer.lteq(y, x)
override def gteq(x: Double, y: Double): Boolean = outer.gteq(y, x)
override def lt(x: Double, y: Double): Boolean = outer.lt(y, x)
override def gt(x: Double, y: Double): Boolean = outer.gt(y, x)
}
}
implicit object Double extends DoubleOrdering
trait BigIntOrdering extends Ordering[BigInt] {
def compare(x: BigInt, y: BigInt) = x.compare(y)
}
implicit object BigInt extends BigIntOrdering
trait BigDecimalOrdering extends Ordering[BigDecimal] {
def compare(x: BigDecimal, y: BigDecimal) = x.compare(y)
}
implicit object BigDecimal extends BigDecimalOrdering
trait StringOrdering extends Ordering[String] {
def compare(x: String, y: String) = x.compareTo(y)
}
implicit object String extends StringOrdering
trait OptionOrdering[T] extends Ordering[Option[T]] {
def optionOrdering: Ordering[T]
def compare(x: Option[T], y: Option[T]) = (x, y) match {
case (None, None) => 0
case (None, _) => -1
case (_, None) => 1
case (Some(x), Some(y)) => optionOrdering.compare(x, y)
}
}
implicit def Option[T](implicit ord: Ordering[T]): Ordering[Option[T]] =
new OptionOrdering[T] { val optionOrdering = ord }
implicit def Iterable[T](implicit ord: Ordering[T]): Ordering[Iterable[T]] =
new Ordering[Iterable[T]] {
def compare(x: Iterable[T], y: Iterable[T]): Int = {
val xe = x.iterator
val ye = y.iterator
while (xe.hasNext && ye.hasNext) {
val res = ord.compare(xe.next(), ye.next())
if (res != 0) return res
}
Boolean.compare(xe.hasNext, ye.hasNext)
}
}
implicit def Tuple2[T1, T2](implicit ord1: Ordering[T1], ord2: Ordering[T2]): Ordering[(T1, T2)] =
new Ordering[(T1, T2)]{
def compare(x: (T1, T2), y: (T1, T2)): Int = {
val compare1 = ord1.compare(x._1, y._1)
if (compare1 != 0) return compare1
val compare2 = ord2.compare(x._2, y._2)
if (compare2 != 0) return compare2
0
}
}
implicit def Tuple3[T1, T2, T3](implicit ord1: Ordering[T1], ord2: Ordering[T2], ord3: Ordering[T3]) : Ordering[(T1, T2, T3)] =
new Ordering[(T1, T2, T3)]{
def compare(x: (T1, T2, T3), y: (T1, T2, T3)): Int = {
val compare1 = ord1.compare(x._1, y._1)
if (compare1 != 0) return compare1
val compare2 = ord2.compare(x._2, y._2)
if (compare2 != 0) return compare2
val compare3 = ord3.compare(x._3, y._3)
if (compare3 != 0) return compare3
0
}
}
implicit def Tuple4[T1, T2, T3, T4](implicit ord1: Ordering[T1], ord2: Ordering[T2], ord3: Ordering[T3], ord4: Ordering[T4]) : Ordering[(T1, T2, T3, T4)] =
new Ordering[(T1, T2, T3, T4)]{
def compare(x: (T1, T2, T3, T4), y: (T1, T2, T3, T4)): Int = {
val compare1 = ord1.compare(x._1, y._1)
if (compare1 != 0) return compare1
val compare2 = ord2.compare(x._2, y._2)
if (compare2 != 0) return compare2
val compare3 = ord3.compare(x._3, y._3)
if (compare3 != 0) return compare3
val compare4 = ord4.compare(x._4, y._4)
if (compare4 != 0) return compare4
0
}
}
implicit def Tuple5[T1, T2, T3, T4, T5](implicit ord1: Ordering[T1], ord2: Ordering[T2], ord3: Ordering[T3], ord4: Ordering[T4], ord5: Ordering[T5]): Ordering[(T1, T2, T3, T4, T5)] =
new Ordering[(T1, T2, T3, T4, T5)]{
def compare(x: (T1, T2, T3, T4, T5), y: Tuple5[T1, T2, T3, T4, T5]): Int = {
val compare1 = ord1.compare(x._1, y._1)
if (compare1 != 0) return compare1
val compare2 = ord2.compare(x._2, y._2)
if (compare2 != 0) return compare2
val compare3 = ord3.compare(x._3, y._3)
if (compare3 != 0) return compare3
val compare4 = ord4.compare(x._4, y._4)
if (compare4 != 0) return compare4
val compare5 = ord5.compare(x._5, y._5)
if (compare5 != 0) return compare5
0
}
}
implicit def Tuple6[T1, T2, T3, T4, T5, T6](implicit ord1: Ordering[T1], ord2: Ordering[T2], ord3: Ordering[T3], ord4: Ordering[T4], ord5: Ordering[T5], ord6: Ordering[T6]): Ordering[(T1, T2, T3, T4, T5, T6)] =
new Ordering[(T1, T2, T3, T4, T5, T6)]{
def compare(x: (T1, T2, T3, T4, T5, T6), y: (T1, T2, T3, T4, T5, T6)): Int = {
val compare1 = ord1.compare(x._1, y._1)
if (compare1 != 0) return compare1
val compare2 = ord2.compare(x._2, y._2)
if (compare2 != 0) return compare2
val compare3 = ord3.compare(x._3, y._3)
if (compare3 != 0) return compare3
val compare4 = ord4.compare(x._4, y._4)
if (compare4 != 0) return compare4
val compare5 = ord5.compare(x._5, y._5)
if (compare5 != 0) return compare5
val compare6 = ord6.compare(x._6, y._6)
if (compare6 != 0) return compare6
0
}
}
implicit def Tuple7[T1, T2, T3, T4, T5, T6, T7](implicit ord1: Ordering[T1], ord2: Ordering[T2], ord3: Ordering[T3], ord4: Ordering[T4], ord5: Ordering[T5], ord6: Ordering[T6], ord7: Ordering[T7]): Ordering[(T1, T2, T3, T4, T5, T6, T7)] =
new Ordering[(T1, T2, T3, T4, T5, T6, T7)]{
def compare(x: (T1, T2, T3, T4, T5, T6, T7), y: (T1, T2, T3, T4, T5, T6, T7)): Int = {
val compare1 = ord1.compare(x._1, y._1)
if (compare1 != 0) return compare1
val compare2 = ord2.compare(x._2, y._2)
if (compare2 != 0) return compare2
val compare3 = ord3.compare(x._3, y._3)
if (compare3 != 0) return compare3
val compare4 = ord4.compare(x._4, y._4)
if (compare4 != 0) return compare4
val compare5 = ord5.compare(x._5, y._5)
if (compare5 != 0) return compare5
val compare6 = ord6.compare(x._6, y._6)
if (compare6 != 0) return compare6
val compare7 = ord7.compare(x._7, y._7)
if (compare7 != 0) return compare7
0
}
}
implicit def Tuple8[T1, T2, T3, T4, T5, T6, T7, T8](implicit ord1: Ordering[T1], ord2: Ordering[T2], ord3: Ordering[T3], ord4: Ordering[T4], ord5: Ordering[T5], ord6: Ordering[T6], ord7: Ordering[T7], ord8: Ordering[T8]): Ordering[(T1, T2, T3, T4, T5, T6, T7, T8)] =
new Ordering[(T1, T2, T3, T4, T5, T6, T7, T8)]{
def compare(x: (T1, T2, T3, T4, T5, T6, T7, T8), y: (T1, T2, T3, T4, T5, T6, T7, T8)): Int = {
val compare1 = ord1.compare(x._1, y._1)
if (compare1 != 0) return compare1
val compare2 = ord2.compare(x._2, y._2)
if (compare2 != 0) return compare2
val compare3 = ord3.compare(x._3, y._3)
if (compare3 != 0) return compare3
val compare4 = ord4.compare(x._4, y._4)
if (compare4 != 0) return compare4
val compare5 = ord5.compare(x._5, y._5)
if (compare5 != 0) return compare5
val compare6 = ord6.compare(x._6, y._6)
if (compare6 != 0) return compare6
val compare7 = ord7.compare(x._7, y._7)
if (compare7 != 0) return compare7
val compare8 = ord8.compare(x._8, y._8)
if (compare8 != 0) return compare8
0
}
}
implicit def Tuple9[T1, T2, T3, T4, T5, T6, T7, T8, T9](implicit ord1: Ordering[T1], ord2: Ordering[T2], ord3: Ordering[T3], ord4: Ordering[T4], ord5: Ordering[T5], ord6: Ordering[T6], ord7: Ordering[T7], ord8 : Ordering[T8], ord9: Ordering[T9]): Ordering[(T1, T2, T3, T4, T5, T6, T7, T8, T9)] =
new Ordering[(T1, T2, T3, T4, T5, T6, T7, T8, T9)]{
def compare(x: (T1, T2, T3, T4, T5, T6, T7, T8, T9), y: (T1, T2, T3, T4, T5, T6, T7, T8, T9)): Int = {
val compare1 = ord1.compare(x._1, y._1)
if (compare1 != 0) return compare1
val compare2 = ord2.compare(x._2, y._2)
if (compare2 != 0) return compare2
val compare3 = ord3.compare(x._3, y._3)
if (compare3 != 0) return compare3
val compare4 = ord4.compare(x._4, y._4)
if (compare4 != 0) return compare4
val compare5 = ord5.compare(x._5, y._5)
if (compare5 != 0) return compare5
val compare6 = ord6.compare(x._6, y._6)
if (compare6 != 0) return compare6
val compare7 = ord7.compare(x._7, y._7)
if (compare7 != 0) return compare7
val compare8 = ord8.compare(x._8, y._8)
if (compare8 != 0) return compare8
val compare9 = ord9.compare(x._9, y._9)
if (compare9 != 0) return compare9
0
}
}
}
© 2015 - 2024 Weber Informatics LLC | Privacy Policy