# Reduce, fold or scan (Left/Right)?

When should I use `reduceLeft`, `reduceRight`, `foldLeft`, `foldRight`, `scanLeft` or `scanRight`?

I want an intuition/overview of their differences - possibly with some simple examples.

• Recommend you see stackoverflow.com/questions/25158780/… Aug 6, 2014 at 11:08
• Thanks for the pointer. It's a bit above my technical knowledge :) Is there something in my answer that you think should be clarified/changed? Aug 6, 2014 at 15:20
• No, just pointing out a bit of history and the relevance to MPP. Aug 6, 2014 at 16:03
• Well, strictly speaking the distinction between `reduce` and `fold` is NOT the existence of a start value - rather that is a consequence of a more deep underlying mathematical reason. Aug 6, 2014 at 16:16

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.

## Accumulate

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
}

// 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

// 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
}

// op: B + C = BC
// op: A + BC = ABC  // accumulates value BC in *second* operator arg `res`
// res: String = ABC

// op: C + z = Cz
// op: B + Cz = BCz
// op: A + BCz = ABCz
// res: String = ABCz

// op: C + z = Cz
// op: B + Cz = BCz
// op: A + BCz = ABCz
// res: List[String] = List(ABCz, BCz, Cz, z)
``````

.

## De-cumulate

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.

## Bottom line

• Cumulate a result with `reduceLeft` or `reduceRight`.
• Cumulate a result with `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.

• Use a xRight variation if you want to go backwards through the collection.
• If I'm not mistaken, the left version can use tail call optimization, which means it is much more efficient. Aug 11, 2014 at 11:27
• @Marc, I like the examples with letters, it made things very clear Jul 18, 2015 at 21:13
• @Trylks foldRight can also be implemented with tailrec Apr 20, 2016 at 18:51
• @TimothyKim it can, with non-straightforward implementations optimised to do so. E.g. In the particular case of Scala lists, that way consists on reversing the `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. Apr 21, 2016 at 18:57
• @Trylks Both `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.

• LEFT_REDUCE method works similar to REDUCE Method.
• 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")`

• {A,B}=>AB {AB,C}=>ABC {ABC,D}=>ABCD {ABCD,E}=>ABCDE reduce (a+b) ABCDE
• {A,B}=>AB {AB,C}=>ABC {ABC,D}=>ABCD {ABCD,E}=>ABCDE reduceLeft (a+b) ABCDE
• {A,B}=>BA {BA,C}=>CBA {CBA,D}=>DCBA {DCBA,E}=>EDCBA reduceLeft (b+a) EDCB
• {D,E}=>DE {C,DE}=>CDE {B,CDE}=>BCDE {A,BCDE}=>ABCDE reduceRight (a+b) ABCDE
• {D,E}=>ED {C,ED}=>EDC {B,EDC}=>EDCB {A,EDCB}=>EDCBA reduceRight (b+a) EDCBA

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}))
}
``````
• This post is barely readable. Please shorten sentences, use real keywords (e.g. reduceLeft instead of LEFT_REDUCE). Use real mathematical arrows, code tags when you are dealing with the code. Prefer input/output examples rather than explaining everything. Intermediate calculations make it hard to read. Jan 11, 2016 at 18:28

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
``````

# In conclusion

• `scan` is like `fold` but also emits all intermediate values
• `reduce` doesn't need an initial value which sometimes is a little harder to find
• `fold` needs an initial value that is a little harder to find:
• 0 for sums
• 1 for products
• first element for min (some might suggest Integer.MAX_VALUE)
• not 100% sure but it looks like there are these equivalent implementations:
• `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`