When should I use reduceLeft
, reduceRight
, foldLeft
, foldRight
, scanLeft
or scanRight
?
I want an intuition/overview of their differences - possibly with some simple examples.
In general, all 6 fold functions apply a binary operator to each element of a collection. The result of each step is passed on to the next step (as input to one of the binary operator's two arguments). This way we can cumulate a result.
reduceLeft
and reduceRight
cumulate a single result.
foldLeft
and foldRight
cumulate a single result using a start value.
scanLeft
and scanRight
cumulate a collection of intermediate cumulative results using a start value.
From LEFT and forwards...
With a collection of elements abc
and a binary operator add
we can explore what the different fold functions do when going forwards from the LEFT element of the collection (from A to C):
val abc = List("A", "B", "C")
def add(res: String, x: String) = {
println(s"op: $res + $x = ${res + x}")
res + x
}
abc.reduceLeft(add)
// op: A + B = AB
// op: AB + C = ABC // accumulates value AB in *first* operator arg `res`
// res: String = ABC
abc.foldLeft("z")(add) // with start value "z"
// op: z + A = zA // initial extra operation
// op: zA + B = zAB
// op: zAB + C = zABC
// res: String = zABC
abc.scanLeft("z")(add)
// op: z + A = zA // same operations as foldLeft above...
// op: zA + B = zAB
// op: zAB + C = zABC
// res: List[String] = List(z, zA, zAB, zABC) // maps intermediate results
From RIGHT and backwards...
If we start with the RIGHT element and go backwards (from C to A) we'll notice that now the second argument to our binary operator accumulates the result (the operator is the same, we just switched the argument names to make their roles clear):
def add(x: String, res: String) = {
println(s"op: $x + $res = ${x + res}")
x + res
}
abc.reduceRight(add)
// op: B + C = BC
// op: A + BC = ABC // accumulates value BC in *second* operator arg `res`
// res: String = ABC
abc.foldRight("z")(add)
// op: C + z = Cz
// op: B + Cz = BCz
// op: A + BCz = ABCz
// res: String = ABCz
abc.scanRight("z")(add)
// op: C + z = Cz
// op: B + Cz = BCz
// op: A + BCz = ABCz
// res: List[String] = List(ABCz, BCz, Cz, z)
.
From LEFT and forwards...
If instead we were to de-cumulate some result by subtraction starting from the LEFT element of a collection, we would cumulate the result through the first argument res
of our binary operator minus
:
val xs = List(1, 2, 3, 4)
def minus(res: Int, x: Int) = {
println(s"op: $res - $x = ${res - x}")
res - x
}
xs.reduceLeft(minus)
// op: 1 - 2 = -1
// op: -1 - 3 = -4 // de-cumulates value -1 in *first* operator arg `res`
// op: -4 - 4 = -8
// res: Int = -8
xs.foldLeft(0)(minus)
// op: 0 - 1 = -1
// op: -1 - 2 = -3
// op: -3 - 3 = -6
// op: -6 - 4 = -10
// res: Int = -10
xs.scanLeft(0)(minus)
// op: 0 - 1 = -1
// op: -1 - 2 = -3
// op: -3 - 3 = -6
// op: -6 - 4 = -10
// res: List[Int] = List(0, -1, -3, -6, -10)
From RIGHT and backwards...
But look out for the xRight variations now! Remember that the (de-)cumulated value in the xRight variations is passed to the second parameter res
of our binary operator minus
:
def minus(x: Int, res: Int) = {
println(s"op: $x - $res = ${x - res}")
x - res
}
xs.reduceRight(minus)
// op: 3 - 4 = -1
// op: 2 - -1 = 3 // de-cumulates value -1 in *second* operator arg `res`
// op: 1 - 3 = -2
// res: Int = -2
xs.foldRight(0)(minus)
// op: 4 - 0 = 4
// op: 3 - 4 = -1
// op: 2 - -1 = 3
// op: 1 - 3 = -2
// res: Int = -2
xs.scanRight(0)(minus)
// op: 4 - 0 = 4
// op: 3 - 4 = -1
// op: 2 - -1 = 3
// op: 1 - 3 = -2
// res: List[Int] = List(-2, 3, -1, 4, 0)
The last List(-2, 3, -1, 4, 0) is maybe not what you would intuitively expect!
As you see, you can check what your foldX is doing by simply running a scanX instead and debug the cumulated result at each step.
reduceLeft
or reduceRight
.foldLeft
or foldRight
if you have a start value.Cumulate a collection of intermediate results with scanLeft
or scanRight
.
Use a xLeft variation if you want to go forwards through the collection.
List
to then apply foldLeft
. Other collections may implement different strategies. In general, if foldLeft
and foldRight
can be used interchangeably (associative property of the applied operator), then foldLeft
is more efficient and preferable.
xLeft
and xRight
have the same asymptotic complexity and can be implemented in a tail-recursive way. The actual implementation in the Scala standard library however is impure (for efficiency).
Oct 16, 2021 at 8:27
Normally REDUCE,FOLD,SCAN method works by accumulating data on LEFT and keep on changing the RIGHT variable. Main difference between them is REDUCE,FOLD is:-
Fold will always start with a seed
value i.e. user defined starting value.
Reduce will throw a exception if collection is empty where as fold gives back the seed value. Will always result a single value.
Scan is used for some processing order of items from left or right hand side, then we can make use of previous result in subsequent calculation. That means we can scan items. Will always result a collection.
RIGHT_REDUCE is opposite to reduceLeft one i.e. it accumulates values in RIGHT and keep on changing the left variable.
reduceLeftOption and reduceRightOption are similar to left_reduce and right_reduce only difference is they return results in OPTION object.
A part of output for below mentioned code would be :-
using scan
operation over a list of numbers (using seed
value 0
) List(-2,-1,0,1,2)
{0,-2}=>-2 {-2,-1}=>-3 {-3,0}=>-3 {-3,1}=>-2 {-2,2}=>0 scan List(0, -2, -3, -3, -2, 0)
{0,-2}=>-2 {-2,-1}=>-3 {-3,0}=>-3 {-3,1}=>-2 {-2,2}=>0 scanLeft (a+b) List(0, -2, -3, -3, -2, 0)
{0,-2}=>-2 {-2,-1}=>-3 {-3,0}=>-3 {-3,1}=>-2 {-2,2}=>0 scanLeft (b+a) List(0, -2, -3, -3, -2, 0)
{2,0}=>2 {1,2}=>3 {0,3}=>3 {-1,3}=>2 {-2,2}=>0 scanRight (a+b) List(0, 2, 3, 3, 2, 0)
{2,0}=>2 {1,2}=>3 {0,3}=>3 {-1,3}=>2 {-2,2}=>0 scanRight (b+a) List(0, 2, 3, 3, 2, 0)
using reduce
,fold
operations over a list of Strings List("A","B","C","D","E")
Code :
object ScanFoldReduce extends App {
val list = List("A","B","C","D","E")
println("reduce (a+b) "+list.reduce((a,b)=>{
print("{"+a+","+b+"}=>"+ (a+b)+" ")
a+b
}))
println("reduceLeft (a+b) "+list.reduceLeft((a,b)=>{
print("{"+a+","+b+"}=>"+ (a+b)+" ")
a+b
}))
println("reduceLeft (b+a) "+list.reduceLeft((a,b)=>{
print("{"+a+","+b+"}=>"+ (b+a)+" " )
b+a
}))
println("reduceRight (a+b) "+list.reduceRight((a,b)=>{
print("{"+a+","+b+"}=>"+ (a+b)+" " )
a+b
}))
println("reduceRight (b+a) "+list.reduceRight((a,b)=>{
print("{"+a+","+b+"}=>"+ (b+a)+" ")
b+a
}))
println("scan "+list.scan("[")((a,b)=>{
print("{"+a+","+b+"}=>"+ (a+b)+" " )
a+b
}))
println("scanLeft (a+b) "+list.scanLeft("[")((a,b)=>{
print("{"+a+","+b+"}=>"+ (a+b)+" " )
a+b
}))
println("scanLeft (b+a) "+list.scanLeft("[")((a,b)=>{
print("{"+a+","+b+"}=>"+ (b+a)+" " )
b+a
}))
println("scanRight (a+b) "+list.scanRight("[")((a,b)=>{
print("{"+a+","+b+"}=>"+ (a+b)+" " )
a+b
}))
println("scanRight (b+a) "+list.scanRight("[")((a,b)=>{
print("{"+a+","+b+"}=>"+ (b+a)+" " )
b+a
}))
//Using numbers
val list1 = List(-2,-1,0,1,2)
println("reduce (a+b) "+list1.reduce((a,b)=>{
print("{"+a+","+b+"}=>"+ (a+b)+" ")
a+b
}))
println("reduceLeft (a+b) "+list1.reduceLeft((a,b)=>{
print("{"+a+","+b+"}=>"+ (a+b)+" ")
a+b
}))
println("reduceLeft (b+a) "+list1.reduceLeft((a,b)=>{
print("{"+a+","+b+"}=>"+ (b+a)+" " )
b+a
}))
println(" reduceRight (a+b) "+list1.reduceRight((a,b)=>{
print("{"+a+","+b+"}=>"+ (a+b)+" " )
a+b
}))
println(" reduceRight (b+a) "+list1.reduceRight((a,b)=>{
print("{"+a+","+b+"}=>"+ (b+a)+" ")
b+a
}))
println("scan "+list1.scan(0)((a,b)=>{
print("{"+a+","+b+"}=>"+ (a+b)+" " )
a+b
}))
println("scanLeft (a+b) "+list1.scanLeft(0)((a,b)=>{
print("{"+a+","+b+"}=>"+ (a+b)+" " )
a+b
}))
println("scanLeft (b+a) "+list1.scanLeft(0)((a,b)=>{
print("{"+a+","+b+"}=>"+ (b+a)+" " )
b+a
}))
println("scanRight (a+b) "+list1.scanRight(0)((a,b)=>{
print("{"+a+","+b+"}=>"+ (a+b)+" " )
a+b}))
println("scanRight (b+a) "+list1.scanRight(0)((a,b)=>{
print("{"+a+","+b+"}=>"+ (a+b)+" " )
b+a}))
}
For the collection x with elements x0, x1, x2, x3 and an arbitrary function f you have the following:
1. x.reduceLeft (f) is f(f(f(x0,x1),x2),x3) - notice 3 function calls
2. x.reduceRight (f) is f(f(f(x3,x2),x1),x0) - notice 3 function calls
3. x.foldLeft (init,f) is f(f(f(f(init,x0),x1),x2),x3) - notice 4 function calls
4. x.foldRight(init,f) is f(f(f(f(init,x3),x2),x1),x0) - notice 4 function calls
5. x.scanLeft (init,f) is f(init,x0)=g0
f(f(init,x0),x1) = f(g0,x1) = g1
f(f(f(init,x0),x1),x2) = f(g1,x2) = g2
f(f(f(f(init,x0),x1),x2),x3) = f(g2,x3) = g3
- notice 4 function calls but also 4 emitted values
- last element is identical with foldLeft
6. x.scanRight (init,f) is f(init,x3)=h0
f(f(init,x3),x2) = f(h0,x2) = h1
f(f(f(init,x3),x2),x1) = f(h1,x1) = h2
f(f(f(f(init,x3),x2),x1),x0) = f(h2,x0) = h3
- notice 4 function calls but also 4 emitted values
- last element is identical with foldRight
scan
is like fold
but also emits all intermediate valuesreduce
doesn't need an initial value which sometimes is a little harder to findfold
needs an initial value that is a little harder to find:
x.reduceLeft(f) === x.drop(1).foldLeft(x.head,f)
x.foldRight(init,f) === x.reverse.foldLeft(init,f)
x.foldLeft(init,f) === x.scanLeft(init,f).last
reduce
andfold
is NOT the existence of a start value - rather that is a consequence of a more deep underlying mathematical reason.