Difference between revisions of "Foldr Foldl Foldl'"
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To ''foldr'', ''foldl'' or ''foldl''' that's the question! This article demonstrates the differences between these different folds by a simple example. |
To ''foldr'', ''foldl'' or ''foldl''' that's the question! This article demonstrates the differences between these different folds by a simple example. |
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| − | If you want you can copy/paste this article into your |
+ | If you want you can copy/paste this article into your favorite editor and run it. |
We are going to define our own folds so we hide the ones from the Prelude: |
We are going to define our own folds so we hide the ones from the Prelude: |
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| Line 58: | Line 58: | ||
500000500000 |
500000500000 |
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</haskell> |
</haskell> |
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| − | |||
| − | For a nice interactive animation of the above behavior see: http://foldr.com |
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The problem is that (+) is strict in both of its arguments. This means that both arguments must be fully evaluated before (+) can return a result. So to evaluate: |
The problem is that (+) is strict in both of its arguments. This means that both arguments must be fully evaluated before (+) can return a result. So to evaluate: |
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| Line 85: | Line 83: | ||
==Foldl== |
==Foldl== |
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| − | One problem with the chain of (+)'s is that |
+ | One problem with the chain of (+)'s is that it can't be made smaller (reduced) until the very last moment, when it's already too late. |
| − | smaller (reduce it) until at the very last moment when it's already |
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| − | too late. |
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| − | The reason we can't reduce it |
+ | The reason we can't reduce it is that the chain doesn't contain an |
| − | expression which can be reduced (a |
+ | expression which can be reduced (a ''redex'', for '''red'''ucible |
'''ex'''pression.) If it did we could reduce that expression before going |
'''ex'''pression.) If it did we could reduce that expression before going |
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to the next element. |
to the next element. |
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| − | + | We can introduce a redex by forming the chain in another way. If |
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instead of the chain <tt>1 + (2 + (3 + (...)))</tt> we could form the chain |
instead of the chain <tt>1 + (2 + (3 + (...)))</tt> we could form the chain |
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| − | <tt>(((0 + 1) + 2) + 3) + ...</tt> then there would always be a redex. |
+ | <tt>(((0 + 1) + 2) + 3) + ...</tt>, then there would always be a redex. |
| − | We can form |
+ | We can form such a chain by using a function called ''foldl'': |
<haskell> |
<haskell> |
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| Line 276: | Line 272: | ||
</haskell> |
</haskell> |
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| ⚫ | |||
| − | For a nice interactive animation of the above behavior see: http://foldl.com (actually this animation is not quite the same :-( ) |
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| − | |||
| ⚫ | |||
<haskell> |
<haskell> |
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| Line 297: | Line 291: | ||
The problem starts when we finally evaluate z1000000: |
The problem starts when we finally evaluate z1000000: |
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| + | We must evaluate <tt>z1000000 = z999999 + 1000000</tt>, so <tt>1000000</tt> is pushed on the stack. Then <tt>z999999</tt> is evaluated; <tt>z999999 = z999998 + 999999</tt>, so <tt>999999</tt> is pushed on the stack. Then <tt>z999998</tt> is evaluated; <tt>z999998 = z999997 + 999998</tt>, so <tt>999998</tt> is pushed on the stack. Then <tt>z999997</tt> is evaluated... |
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| − | Note that <tt>z1000000 = z999999 + 1000000</tt>. |
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| − | So <tt>1000000</tt> is pushed on the stack. |
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| − | Then <tt>z999999</tt> is evaluated. |
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| ⚫ | |||
| − | Note that <tt>z999999 = z999998 + 999999</tt>. |
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| − | So <tt>999999</tt> is pushed on the stack. |
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| − | Then <tt>z999998</tt> is evaluated: |
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| ⚫ | |||
| − | Note that <tt>z999998 = z999997 + 999998</tt>. |
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| − | So <tt>999998</tt> is pushed on the stack. |
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| − | Then <tt>z999997</tt> is evaluated: |
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| − | So ... |
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| − | |||
| ⚫ | |||
| − | |||
| ⚫ | |||
So why doesn't the chain reduce sooner than |
So why doesn't the chain reduce sooner than |
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before? |
before? |
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| + | It's because of GHC's lazy reduction strategy: expressions are reduced only when they are actually needed. In this case, the outer-left-most redexes are reduced first. In this case it's the outer <tt>foldl (+) ... [1..10000]</tt> |
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| − | The answer is that GHC uses a lazy reduction strategy. This means |
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| ⚫ | |||
| − | that GHC only reduces an expression when its value is actually |
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| − | needed. |
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| − | |||
| − | The reduction strategy works by reducing the outer-left-most redex |
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| − | first. In this case it are the outer <tt>foldl (+) ... [1..10000]</tt> |
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| − | redexen which are repeatedly reduced. |
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| ⚫ | |||
| − | the foldl is completely gone. |
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==Foldl'== |
==Foldl'== |
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| Line 414: | Line 390: | ||
foldl' (?) 6 [undefined,5,0] --> |
foldl' (?) 6 [undefined,5,0] --> |
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6 ? undefined --> |
6 ? undefined --> |
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| − | + | *** Exception: Prelude.undefined |
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</haskell> |
</haskell> |
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| + | Note that even <hask>foldl'</hask> may not do what you expect. |
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| − | For another explanation about folds see the [http://haskell.org/haskellwiki/Fold Fold] article. |
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| + | The involved <hask>seq</hask> function does only evaluate the ''top-most constructor''. |
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| + | |||
| + | If the accumulator is a more complex object, then <hask>fold'</hask> will still build up unevaluated thunks. You can introduce a function or a strict data type which forces the values as far as you need. Failing that, the "brute force" solution is to use {{HackagePackage|id=deepseq}}. For a worked example of this issue, see [http://book.realworldhaskell.org/read/profiling-and-optimization.html#id678431 ''Real World Haskell'' chapter 25]. |
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| + | |||
| + | == See also == |
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| + | |||
| + | * [[Fold]] |
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| + | * [[Foldl as foldr]] |
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[[Category:FAQ]] |
[[Category:FAQ]] |
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Revision as of 08:59, 7 December 2012
To foldr, foldl or foldl' that's the question! This article demonstrates the differences between these different folds by a simple example.
If you want you can copy/paste this article into your favorite editor and run it.
We are going to define our own folds so we hide the ones from the Prelude:
> import Prelude hiding (foldr, foldl)
Foldr
Say we want to calculate the sum of a very big list:
> veryBigList = [1..1000000]
Lets start with the following:
> foldr f z [] = z
> foldr f z (x:xs) = x `f` foldr f z xs
> sum1 = foldr (+) 0
> try1 = sum1 veryBigList
If we evaluate try1 we get:
*** Exception: stack overflow
Too bad... So what happened:
try1 -->
sum1 veryBigList -->
foldr (+) 0 veryBigList -->
foldr (+) 0 [1..1000000] -->
1 + (foldr (+) 0 [2..1000000]) -->
1 + (2 + (foldr (+) 0 [3..1000000])) -->
1 + (2 + (3 + (foldr (+) 0 [4..1000000]))) -->
1 + (2 + (3 + (4 + (foldr (+) 0 [5..1000000])))) -->
-- ...
-- ... My stack overflows when there's a chain of around 500000 (+)'s !!!
-- ... But the following would happen if you got a large enough stack:
-- ...
1 + (2 + (3 + (4 + (... + (999999 + (foldr (+) 0 [1000000]))...)))) -->
1 + (2 + (3 + (4 + (... + (999999 + (1000000 + ((foldr (+) 0 []))))...)))) -->
1 + (2 + (3 + (4 + (... + (999999 + (1000000 + 0))...)))) -->
1 + (2 + (3 + (4 + (... + (999999 + 1000000)...)))) -->
1 + (2 + (3 + (4 + (... + 1999999 ...)))) -->
1 + (2 + (3 + (4 + 500000499990))) -->
1 + (2 + (3 + 500000499994)) -->
1 + (2 + 500000499997) -->
1 + 500000499999 -->
500000500000
The problem is that (+) is strict in both of its arguments. This means that both arguments must be fully evaluated before (+) can return a result. So to evaluate:
1 + (2 + (3 + (4 + (...))))
1 is pushed on the stack. Then:
2 + (3 + (4 + (...)))
is evaluated. So 2 is pushed on the stack. Then:
3 + (4 + (...))
is evaluated. So 3 is pushed on the stack. Then:
4 + (...)
is evaluated. So 4 is pushed on the stack. Then: ...
... your limited stack will eventually run full when you evaluate a large enough chain of (+)s. This then triggers the stack overflow exception.
Lets think about how to solve it...
Foldl
One problem with the chain of (+)'s is that it can't be made smaller (reduced) until the very last moment, when it's already too late.
The reason we can't reduce it is that the chain doesn't contain an expression which can be reduced (a redex, for reducible expression.) If it did we could reduce that expression before going to the next element.
We can introduce a redex by forming the chain in another way. If instead of the chain 1 + (2 + (3 + (...))) we could form the chain (((0 + 1) + 2) + 3) + ..., then there would always be a redex.
We can form such a chain by using a function called foldl:
> foldl f z [] = z
> foldl f z (x:xs) = let z' = z `f` x
> in foldl f z' xs
> sum2 = foldl (+) 0
> try2 = sum2 veryBigList
Lets evaluate try2:
*** Exception: stack overflow
Good Lord! Again a stack overflow! Lets see what happens:
try2 -->
sum2 veryBigList -->
foldl (+) 0 veryBigList -->
foldl (+) 0 [1..1000000] -->
let z1 = 0 + 1
in foldl (+) z1 [2..1000000] -->
let z1 = 0 + 1
z2 = z1 + 2
in foldl (+) z2 [3..1000000] -->
let z1 = 0 + 1
z2 = z1 + 2
z3 = z2 + 3
in foldl (+) z3 [4..1000000] -->
let z1 = 0 + 1
z2 = z1 + 2
z3 = z2 + 3
z4 = z3 + 4
in foldl (+) z4 [5..1000000] -->
-- ... after many foldl steps ...
let z1 = 0 + 1
z2 = z1 + 2
z3 = z2 + 3
z4 = z3 + 4
...
z999997 = z999996 + 999997
in foldl (+) z999997 [999998..1000000] -->
let z1 = 0 + 1
z2 = z1 + 2
z3 = z2 + 3
z4 = z3 + 4
...
z999997 = z999996 + 999997
z999998 = z999997 + 999998
in foldl (+) z999998 [999999..1000000] -->
let z1 = 0 + 1
z2 = z1 + 2
z3 = z2 + 3
z4 = z3 + 4
...
z999997 = z999996 + 999997
z999998 = z999997 + 999998
z999999 = z999998 + 999999
in foldl (+) z999999 [1000000] -->
let z1 = 0 + 1
z2 = z1 + 2
z3 = z2 + 3
z4 = z3 + 4
...
z999997 = z999996 + 999997
z999998 = z999997 + 999998
z999999 = z999998 + 999999
z100000 = z999999 + 1000000
in foldl (+) z1000000 [] -->
let z1 = 0 + 1
z2 = z1 + 2
z3 = z2 + 3
z4 = z3 + 4
...
z999997 = z999996 + 999997
z999998 = z999997 + 999998
z999999 = z999998 + 999999
z100000 = z999999 + 1000000
in z1000000 -->
-- Now a large chain of +'s will be created:
let z1 = 0 + 1
z2 = z1 + 2
z3 = z2 + 3
z4 = z3 + 4
...
z999997 = z999996 + 999997
z999998 = z999997 + 999998
z999999 = z999998 + 999999
in z999999 + 1000000 -->
let z1 = 0 + 1
z2 = z1 + 2
z3 = z2 + 3
z4 = z3 + 4
...
z999997 = z999996 + 999997
z999998 = z999997 + 999998
in (z999998 + 999999) + 1000000 -->
let z1 = 0 + 1
z2 = z1 + 2
z3 = z2 + 3
z4 = z3 + 4
...
z999997 = z999996 + 999997
in ((z999997 + 999998) + 999999) + 1000000 -->
let z1 = 0 + 1
z2 = z1 + 2
z3 = z2 + 3
z4 = z3 + 4
...
in (((z999996 + 999997) + 999998) + 999999) + 1000000 -->
-- ...
-- ... My stack overflows when there's a chain of around 500000 (+)'s !!!
-- ... But the following would happen if you got a large enough stack:
-- ...
let z1 = 0 + 1
z2 = z1 + 2
z3 = z2 + 3
z4 = z3 + 4
in (((((z4 + 5) + ...) + 999997) + 999998) + 999999) + 1000000 -->
let z1 = 0 + 1
z2 = z1 + 2
z3 = z2 + 3
in ((((((z3 + 4) + 5) + ...) + 999997) + 999998) + 999999) + 1000000 -->
let z1 = 0 + 1
z2 = z1 + 2
in (((((((z2 + 3) + 4) + 5) + ...) + 999997) + 999998) + 999999) + 1000000 -->
let z1 = 0 + 1
in ((((((((z1 + 2) + 3) + 4) + 5) + ...) + 999997) + 999998) + 999999) + 1000000 -->
(((((((((0 + 1) + 2) + 3) + 4) + 5) + ...) + 999997) + 999998) + 999999) + 1000000 -->
-- Now we can actually start reducing:
((((((((1 + 2) + 3) + 4) + 5) + ...) + 999997) + 999998) + 999999) + 1000000 -->
(((((((3 + 3) + 4) + 5) + ...) + 999997) + 999998) + 999999) + 1000000 -->
((((((6 + 4) + 5) + ...) + 999997) + 999998) + 999999) + 1000000 -->
(((((10 + 5) + ...) + 999997) + 999998) + 999999) + 1000000 -->
((((15 + ...) + 999997) + 999998) + 999999) + 1000000 -->
(((499996500006 + 999997) + 999998) + 999999) + 1000000 -->
((499997500003 + 999998) + 999999) + 1000000 -->
(499998500001 + 999999) + 1000000 -->
499999500000 + 1000000 -->
500000500000 -->
Well, you clearly see that the redexes are created. But instead of being directly reduced, they are allocated on the heap:
let z1 = 0 + 1
z2 = z1 + 2
z3 = z2 + 3
z4 = z3 + 4
...
z999997 = z999996 + 999997
z999998 = z999997 + 999998
z999999 = z999998 + 999999
z100000 = z999999 + 1000000
in z1000000
Note that your heap is only limited by the amount of memory in your system (RAM and swap). So the only thing this does is filling up a large part of your memory.
The problem starts when we finally evaluate z1000000:
We must evaluate z1000000 = z999999 + 1000000, so 1000000 is pushed on the stack. Then z999999 is evaluated; z999999 = z999998 + 999999, so 999999 is pushed on the stack. Then z999998 is evaluated; z999998 = z999997 + 999998, so 999998 is pushed on the stack. Then z999997 is evaluated...
...your stack will eventually fill when you evaluate a large enough chain of (+)'s. This then triggers the stack overflow exception.
But this is exactly the problem we had in the foldr case — only now the chain of (+)'s is going to the left instead of the right.
So why doesn't the chain reduce sooner than before?
It's because of GHC's lazy reduction strategy: expressions are reduced only when they are actually needed. In this case, the outer-left-most redexes are reduced first. In this case it's the outer foldl (+) ... [1..10000] redexes which are repeatedly reduced. So the inner z1, z2, z3, ... redexes only get reduced when the foldl is completely gone.
Foldl'
We somehow have to tell the system that the inner redex should be reduced before the outer. Fortunately this is possible with the seq function:
seq :: a -> b -> b
seq is a primitive system function that when applied to x and y will first reduce x then return y. The idea is that y references x so that when y is reduced x will not be a big unreduced chain anymore.
Now lets fill in the pieces:
> foldl' f z [] = z
> foldl' f z (x:xs) = let z' = z `f` x
> in seq z' $ foldl' f z' xs
> sum3 = foldl' (+) 0
> try3 = sum3 veryBigList
If we now evaluate try3 we get the correct answer and we get it very quickly:
500000500000
Lets see what happens:
try3 -->
sum3 veryBigList -->
foldl' (+) 0 veryBigList -->
foldl' (+) 0 [1..1000000] -->
foldl' (+) 1 [2..1000000] -->
foldl' (+) 3 [3..1000000] -->
foldl' (+) 6 [4..1000000] -->
foldl' (+) 10 [5..1000000] -->
-- ...
-- ... You see that the stack doesn't overflow
-- ...
foldl' (+) 499999500000 [1000000] -->
foldl' (+) 500000500000 [] -->
500000500000
You can clearly see that the inner redex is repeatedly reduced first.
Conclusion
Usually the choice is between foldr and foldl', since foldl and foldl' are the same except for their strictness properties, so if both return a result, it must be the same. foldl' is the more efficient way to arrive at that result because it doesn't build a huge thunk. However, if the combining function is lazy in its first argument, foldl may happily return a result where foldl' hits an exception:
> (?) :: Int -> Int -> Int
> _ ? 0 = 0
> x ? y = x*y
>
> list :: [Int]
> list = [2,3,undefined,5,0]
>
> okey = foldl (?) 1 list
>
> boom = foldl' (?) 1 list
Let's see what happens:
okey -->
foldl (?) 1 [2,3,undefined,5,0] -->
foldl (?) (1 ? 2) [3,undefined,5,0] -->
foldl (?) ((1 ? 2) ? 3) [undefined,5,0] -->
foldl (?) (((1 ? 2) ? 3) ? undefined) [5,0] -->
foldl (?) ((((1 ? 2) ? 3) ? undefined) ? 5) [0] -->
foldl (?) (((((1 ? 2) ? 3) ? undefined) ? 5) ? 0) [] -->
((((1 ? 2) ? 3) ? undefined) ? 5) ? 0 -->
0
boom -->
foldl' (?) 1 [2,3,undefined,5,0] -->
1 ? 2 --> 2
foldl' (?) 2 [3,undefined,5,0] -->
2 ? 3 --> 6
foldl' (?) 6 [undefined,5,0] -->
6 ? undefined -->
*** Exception: Prelude.undefined
Note that even foldl' may not do what you expect.
The involved seq function does only evaluate the top-most constructor.
If the accumulator is a more complex object, then fold' will still build up unevaluated thunks. You can introduce a function or a strict data type which forces the values as far as you need. Failing that, the "brute force" solution is to use deepseq. For a worked example of this issue, see Real World Haskell chapter 25.