Scalaz(23)- 泛函数据结构: Zipper-游标定位

时间:2022-10-27 04:25:52

外面沙尘滚滚一直向北去了,意识到年关到了,码农们都回乡过年去了,而我却留在这里玩弄“拉链”。不要想歪了,我说的不是裤裆拉链而是scalaz Zipper,一种泛函数据结构游标(cursor)。在函数式编程模式里的集合通常是不可变的(immutable collection),我们会发现在FP编程过程中处理不可变集合(immutable collection)数据的方式好像总是缺些什么,比如在集合里左右逐步游动像moveNext,movePrev等等,在一个集合的中间进行添加、更新、删除的功能更是欠奉了,这主要是因为操作效率问题。不可变集合只有对前置操作(prepend operation)才能获得可靠的效率,即对集合首位元素的操作,能得到相当于O(1)的速度,其它操作基本上都是O(n)速度,n是集合的长度,也就是随着集合的长度增加,操作效率会以倍数下降。还有一个原因就是编程时会很不方便,因为大多数程序都会对各种集合进行大量的操作,最终也会导致程序的复杂臃肿,不符合函数式编程要求的精简优雅表达形式。我想可能就是因为以上各种原因,scalaz提供了Zipper typeclass帮助对不可变集合操作的编程。Zipper的定义如下:scalaz/Zipper.scala

final case class Zipper[+A](lefts: Stream[A], focus: A, rights: Stream[A])

它以Stream为基础,A可以是任何类型,无论基础类型或高阶类型。Zipper的结构如上:当前焦点窗口、左边一串数据元素、右边一串,形似拉链,因而命名Zipper。或者这样看会更形象一点:

final case class Zipper[+A](
lefts: Stream[A],
focus: A,
rights: Stream[A])

scalaz提供了Zipper构建函数可以直接用Stream生成一个Zipper:

trait StreamFunctions {
...
final def toZipper[A](as: Stream[A]): Option[Zipper[A]] = as match {
case Empty => None
case h #:: t => Some(Zipper.zipper(empty, h, t))
} final def zipperEnd[A](as: Stream[A]): Option[Zipper[A]] = as match {
case Empty => None
case _ =>
val x = as.reverse
Some(Zipper.zipper(x.tail, x.head, empty))
}
...

zipperEnd生成倒排序的Zipper:

   Stream(,,).toZipper                          //> res2: Option[scalaz.Zipper[Int]] = Some(Zipper(<lefts>, 1, <rights>))
Stream("A","B","C").toZipper //> res3: Option[scalaz.Zipper[String]] = Some(Zipper(<lefts>, A, <rights>))
Stream(Stream(,),Stream(,)).toZipper //> res4: Option[scalaz.Zipper[scala.collection.immutable.Stream[Int]]] = Some(Z
//| ipper(<lefts>, Stream(1, ?), <rights>))
Stream(,,).zipperEnd //> res5: Option[scalaz.Zipper[Int]] = Some(Zipper(<lefts>, 3, <rights>))

scalaz也为List,NonEmptyList提供了Zipper构建函数:

trait ListFunctions {
...
final def toZipper[A](as: List[A]): Option[Zipper[A]] =
stream.toZipper(as.toStream) final def zipperEnd[A](as: List[A]): Option[Zipper[A]] =
stream.zipperEnd(as.toStream)
... final class NonEmptyList[+A] private[scalaz](val head: A, val tail: List[A]) {
...
def toZipper: Zipper[A] = zipper(Stream.Empty, head, tail.toStream) def zipperEnd: Zipper[A] = {
import Stream._
tail.reverse match {
case Nil => zipper(empty, head, empty)
case t :: ts => zipper(ts.toStream :+ head, t, empty)
}
}
...

都是先转换成Stream再生成Zipper的。Zipper本身的构建函数是zipper,在NonEmptyList的Zipper生成中调用过:

trait ZipperFunctions {
def zipper[A](ls: Stream[A], a: A, rs: Stream[A]): Zipper[A] =
Zipper(ls, a, rs)
}

用这些串形结构的构建函数产生Zipper同样很简单:

 List(,,,).toZipper                          //> res0: Option[scalaz.Zipper[Int]] = Some(Zipper(<lefts>, 1, <rights>))
List(List(,),List(,)).toZipper //> res1: Option[scalaz.Zipper[List[Int]]] = Some(Zipper(<lefts>, List(1, 2), <r
//| ights>))
NonEmptyList("A","C","E").toZipper //> res2: scalaz.Zipper[String] = Zipper(<lefts>, A, <rights>)
NonEmptyList(,,).zipperEnd //> res3: scalaz.Zipper[Int] = Zipper(<lefts>, 3, <rights>)

有了串形集合的Zipper构建方法后我们再看看一下Zipper的左右游动函数:

final case class Zipper[+A](lefts: Stream[A], focus: A, rights: Stream[A]) {
...
/**
* Possibly moves to next element to the right of focus.
*/
def next: Option[Zipper[A]] = rights match {
case Stream.Empty => None
case r #:: rs => Some(zipper(Stream.cons(focus, lefts), r, rs))
} /**
* Possibly moves to next element to the right of focus.
*/
def nextOr[AA >: A](z: => Zipper[AA]): Zipper[AA] =
next getOrElse z
/**
* Possibly moves to the previous element to the left of focus.
*/
def previous: Option[Zipper[A]] = lefts match {
case Stream.Empty => None
case l #:: ls => Some(zipper(ls, l, Stream.cons(focus, rights)))
} /**
* Possibly moves to previous element to the left of focus.
*/
def previousOr[AA >: A](z: => Zipper[AA]): Zipper[AA] =
previous getOrElse z
/**
* Moves focus n elements in the zipper, or None if there is no such element.
*
* @param n number of elements to move (positive is forward, negative is backwards)
*/
def move(n: Int): Option[Zipper[A]] = {
@tailrec
def move0(z: Option[Zipper[A]], n: Int): Option[Zipper[A]] =
if (n > && rights.isEmpty || n < && lefts.isEmpty) None
else {
if (n == ) z
else if (n > ) move0(z flatMap ((_: Zipper[A]).next), n - )
else move0(z flatMap ((_: Zipper[A]).previous), n + )
}
move0(Some(this), n)
} /**
* Moves focus to the start of the zipper.
*/
def start: Zipper[A] = {
val rights = this.lefts.reverse ++ focus #:: this.rights
this.copy(Stream.Empty, rights.head, rights.tail)
} /**
* Moves focus to the end of the zipper.
*/
def end: Zipper[A] = {
val lefts = this.rights.reverse ++ focus #:: this.lefts
this.copy(lefts.tail, lefts.head, Stream.empty)
} /**
* Moves focus to the nth element of the zipper, or the default if there is no such element.
*/
def moveOr[AA >: A](n: Int, z: => Zipper[AA]): Zipper[AA] =
move(n) getOrElse z
...

start,end,move,next,previous移动方式都齐了。还有定位函数:

...
/**
* Moves focus to the nearest element matching the given predicate, preferring the left,
* or None if no element matches.
*/
def findZ(p: A => Boolean): Option[Zipper[A]] =
if (p(focus)) Some(this)
else {
val c = this.positions
std.stream.interleave(c.lefts, c.rights).find((x => p(x.focus)))
} /**
* Moves focus to the nearest element matching the given predicate, preferring the left,
* or the default if no element matches.
*/
def findZor[AA >: A](p: A => Boolean, z: => Zipper[AA]): Zipper[AA] =
findZ(p) getOrElse z /**
* Given a traversal function, find the first element along the traversal that matches a given predicate.
*/
def findBy[AA >: A](f: Zipper[AA] => Option[Zipper[AA]])(p: AA => Boolean): Option[Zipper[AA]] = {
@tailrec
def go(zopt: Option[Zipper[AA]]): Option[Zipper[AA]] = {
zopt match {
case Some(z) => if (p(z.focus)) Some(z) else go(f(z))
case None => None
}
}
go(f(this))
} /**
* Moves focus to the nearest element on the right that matches the given predicate,
* or None if there is no such element.
*/
def findNext(p: A => Boolean): Option[Zipper[A]] = findBy((z: Zipper[A]) => z.next)(p) /**
* Moves focus to the previous element on the left that matches the given predicate,
* or None if there is no such element.
*/
def findPrevious(p: A => Boolean): Option[Zipper[A]] = findBy((z: Zipper[A]) => z.previous)(p)
...

操作函数如下:

...
/**
* An alias for insertRight
*/
def insert[AA >: A]: (AA => Zipper[AA]) = insertRight(_: AA) /**
* Inserts an element to the left of focus and focuses on the new element.
*/
def insertLeft[AA >: A](y: AA): Zipper[AA] = zipper(lefts, y, focus #:: rights) /**
* Inserts an element to the right of focus and focuses on the new element.
*/
def insertRight[AA >: A](y: AA): Zipper[AA] = zipper(focus #:: lefts, y, rights) /**
* An alias for `deleteRight`
*/
def delete: Option[Zipper[A]] = deleteRight /**
* Deletes the element at focus and moves the focus to the left. If there is no element on the left,
* focus is moved to the right.
*/
def deleteLeft: Option[Zipper[A]] = lefts match {
case l #:: ls => Some(zipper(ls, l, rights))
case Stream.Empty => rights match {
case r #:: rs => Some(zipper(Stream.empty, r, rs))
case Stream.Empty => None
}
} /**
* Deletes the element at focus and moves the focus to the left. If there is no element on the left,
* focus is moved to the right.
*/
def deleteLeftOr[AA >: A](z: => Zipper[AA]): Zipper[AA] =
deleteLeft getOrElse z /**
* Deletes the element at focus and moves the focus to the right. If there is no element on the right,
* focus is moved to the left.
*/
def deleteRight: Option[Zipper[A]] = rights match {
case r #:: rs => Some(zipper(lefts, r, rs))
case Stream.Empty => lefts match {
case l #:: ls => Some(zipper(ls, l, Stream.empty))
case Stream.Empty => None
}
} /**
* Deletes the element at focus and moves the focus to the right. If there is no element on the right,
* focus is moved to the left.
*/
def deleteRightOr[AA >: A](z: => Zipper[AA]): Zipper[AA] =
deleteRight getOrElse z /**
* Deletes all elements except the focused element.
*/
def deleteOthers: Zipper[A] = zipper(Stream.Empty, focus, Stream.Empty)
...
/**
* Update the focus in this zipper.
*/
def update[AA >: A](focus: AA) = {
this.copy(this.lefts, focus, this.rights)
} /**
* Apply f to the focus and update with the result.
*/
def modify[AA >: A](f: A => AA) = this.update(f(this.focus))
...

insert,modify,delete也很齐备。值得注意的是多数Zipper的移动函数和操作函数都返回Option[Zipper[A]]类型,如此我们可以用flatMap把这些动作都连接起来。换句话说就是我们可以用for-comprehension在Option的context内实现行令编程(imperative programming)。我们可以通过一些例子来示范Zipper用法:

 val zv = for {
z <- List(,,,,,).toZipper
s1 <- z.next
s2 <- s1.modify{_ + }.some
} yield s2 //> zv : Option[scalaz.Zipper[Int]] = Some(Zipper(<lefts>, 10, <rights>)) zv.get.show //> res8: scalaz.Cord = Zipper(Stream(2), 10, Stream(1,5,4,11))
zv.get.toList //> res9: List[Int] = List(2, 10, 1, 5, 4, 11)
...
val zv = for {
z <- List(,,,,,).toZipper
s1 <- z.next
s2 <- s1.modify{_ + }.some
s3 <- s2.move()
s4 <- s3.delete
} yield s4 //> zv : Option[scalaz.Zipper[Int]] = Some(Zipper(<lefts>, 5, <rights>)) zv.get.show //> res8: scalaz.Cord = Zipper(Stream(10,2), 5, Stream(4,11))
zv.get.toList //> res9: List[Int] = List(2, 10, 5, 4, 11)
...
val zv = for {
z <- List(,,,,,).toZipper
s1 <- z.next
s2 <- s1.modify{_ + }.some
s3 <- s2.move()
s4 <- s3.delete
s5 <- s4.findZ {_ === }
s6 <- if (s5.focus === ) s5.delete else s2.insert().some
} yield s6 //> zv : Option[scalaz.Zipper[Int]] = Some(Zipper(<lefts>, 12, <rights>)) zv.get.show //> res8: scalaz.Cord = Zipper(Stream(10,2), 12, Stream(1,5,4,11))
zv.get.toList //> res9: List[Int] = List(2, 10, 12, 1, 5, 4, 11)
...
val zv = for {
z <- List(,,,,,).toZipper
s1 <- z.next
s2 <- s1.modify{_ + }.some
s3 <- s2.move()
s4 <- s3.delete
s5 <- s4.findZ {_ === }
s6 <- if (s5.focus === ) s5.delete else s2.insert().some
s7 <- s6.end.delete
s8 <- s7.start.some
} yield s8 //> zv : Option[scalaz.Zipper[Int]] = Some(Zipper(<lefts>, 2, <rights>)) zv.get.show //> res8: scalaz.Cord = Zipper(Stream(), 2, Stream(10,12,1,5,4))
zv.get.toList //> res9: List[Int] = List(2, 10, 12, 1, 5, 4)

我在上面的程序里在for{...}yield里面逐条添加指令从而示范游标当前焦点和集合元素跟随着的变化。这段程序可以说就是一段行令程序。
回到上面提到的效率和代码质量讨论。我们提过scalaz提供Zipper就是为了使集合操作编程更简明优雅,实际情况是怎样的呢?

举个例子:有一串数字,比如:List(1,4,7,9,5,6,10), 我想找出第一个高点元素,它的左边低,右边高,在我们的例子里是元素9。如果我们尝试用习惯的行令方式用索引去编写这个函数:

def peak(list: List[Int]): Option[Int] = {
list.indices.find { index =>
val x = list(index)
index > && index < list.size - &&
x > list(index - ) && x > list(index + )
}.map(list(_))
}

哇!这东西不但极其复杂难懂而且效率低下,重复用find索引导致速度降到O(n * n)。如果用Array会把效率提高到O(n),不过我们希望用immutable方式。那么用函数式编程方式呢?

def peak_fp(list: List[Int]): Option[Int] = list match {
case x :: y :: z :: tl if y > x && y > z => Some(y)
case x :: tl => peak(tl)
case Nil => None
}

用模式匹配(pattern matching)和递归算法(recursion),这段程序好看多了,而且效率也可以提高到O(n)。

但我们再把情况搞得复杂一点:把高点值增高一点(+1)。还是用FP方式编写:

def raisePeak(list: List[Int]): Option[List[Int]] = {
def rec(head: List[Int], tail: List[Int]): Option[List[Int]] = tail match {
case x :: y :: z :: tl if y > x && y > z =>
Some((x :: head).reverse ::: ((y +) :: z :: tl))
case x :: tl => rec(x :: head, tl) case Nil => None
}
rec(List.empty, list)
}

代码又变得臃肿复杂起来。看来仅仅用FP编程方式还不足够,还需要用一些新的数据结构什么的来帮助。scalaz的Zipper可以在这个场景里派上用场了:

def raisePeak_z(list: List[Int]): Option[List[Int]] = {
for {
zipper <- list.toZipper
peak <- zipper.positions.findNext( z =>
(z.previous, z.next) match {
case (Some(p), Some(n)) => p.focus < z.focus && n.focus < z.focus
case _ => false
})
} yield (peak.focus.modify(_ + ).toStream.toList)
}

用Zipper来写程序表达清楚许多。这里用上了Zipper.positions:

/**
* A zipper of all positions of the zipper, with focus on the current position.
*/
def positions: Zipper[Zipper[A]] = {
val left = std.stream.unfold(this)(_.previous.map(x => (x, x)))
val right = std.stream.unfold(this)(_.next.map(x => (x, x))) zipper(left, this, right)
}

positions函数返回类型是Zipper[Zipper[A]]符合findNext使用。我们前面已经提到:使用Zipper的成本约为O(n)。