When we take the sum of a list, we designate an accumulator (`memo`

) and then walk through the list, applying the binary function "x+y" to each element and the accumulator. Procedurally, this looks like:

```
def mySum(list):
memo = 0
for e in list:
memo = memo + e
return memo
```

This is a common pattern, and useful for things other than taking sums — we can generalize it to any binary function, which we'll supply as a parameter, and also let the caller specify an initial value. This gives us a function known as `reduce`

, `foldl`

, or `inject`

^{[1]}:

```
def myReduce(function, list, initial):
memo = initial
for e in list:
memo = function(memo, e)
return memo
def mySum(list):
return myReduce(lambda memo, e: memo + e, list, 0)
```

In Python 2, `reduce`

was a built-in function, but in Python 3 it's been moved to the `functools`

module:

```
from functools import reduce
```

We can do all kinds of cool stuff with `reduce`

depending on the function we supply as its the first argument. If we replace "sum" with "list concatenation", and "zero" with "empty list", we get the (shallow) `copy`

function:

```
def myCopy(list):
return reduce(lambda memo, e: memo + [e], list, [])
myCopy(range(10))
> [0, 1, 2, 3, 4, 5, 6, 7, 8, 9]
```

If we add a `transform`

function as another parameter to `copy`

, and apply it before concatenating, we get `map`

:

```
def myMap(transform, list):
return reduce(lambda memo, e: memo + [transform(e)], list, [])
myMap(lambda x: x*2, range(10))
> [0, 2, 4, 6, 8, 10, 12, 14, 16, 18]
```

If we add a `predicate`

function that takes `e`

as a parameter and returns a boolean, and use it to decide whether or not to concatenate, we get `filter`

:

```
def myFilter(predicate, list):
return reduce(lambda memo, e: memo + [e] if predicate(e) else memo, list, [])
myFilter(lambda x: x%2==0, range(10))
> [0, 2, 4, 6, 8]
```

`map`

and `filter`

are sort of unfancy ways of writing list comprehensions — we could also have said `[x*2 for x in range(10)]`

or `[x for x in range(10) if x%2==0]`

. There's no corresponding list comprehension syntax for `reduce`

, because `reduce`

isn't required to return a list at all (as we saw with `sum`

, earlier, which Python also happens to offer as a built-in function).

It turns out that for computing a running sum, the list-building abilities of `reduce`

are exactly what we want, and probably the most elegant way to solve this problem, despite its reputation (along with `lambda`

) as something of an un-pythonic shibboleth. The version of `reduce`

that leaves behind copies of its old values as it runs is called `reductions`

or `scanl`

^{[1]}, and it looks like this:

```
def reductions(function, list, initial):
return reduce(lambda memo, e: memo + [function(memo[-1], e)], list, [initial])
```

So equipped, we can now define:

```
def running_sum(list):
first, rest = list[0], list[1:]
return reductions(lambda memo, e: memo + e, rest, first)
running_sum(range(10))
> [0, 1, 3, 6, 10, 15, 21, 28, 36, 45]
```

While conceptually elegant, this precise approach fares poorly in practice with Python. Because Python's `list.append()`

mutates a list in place but doesn't return it, we can't use it effectively in a lambda, and have to use the `+`

operator instead. This constructs a whole new list, which takes time proportional to the length of the accumulated list so far (that is, an O(n) operation). Since we're already inside the O(n) `for`

loop of `reduce`

when we do this, the overall time complexity compounds to O(n^{2}).

In a language like Ruby^{[2]}, where `array.push e`

returns the mutated `array`

, the equivalent runs in O(n) time:

```
class Array
def reductions(initial, &proc)
self.reduce [initial] do |memo, e|
memo.push proc.call(memo.last, e)
end
end
end
def running_sum(enumerable)
first, rest = enumerable.first, enumerable.drop(1)
rest.reductions(first, &:+)
end
running_sum (0...10)
> [0, 1, 3, 6, 10, 15, 21, 28, 36, 45]
```

same in JavaScript^{[2]}, whose `array.push(e)`

returns `e`

(not `array`

), but whose anonymous functions allow us to include multiple statements, which we can use to separately specify a return value:

```
function reductions(array, callback, initial) {
return array.reduce(function(memo, e) {
memo.push(callback(memo[memo.length - 1], e));
return memo;
}, [initial]);
}
function runningSum(array) {
var first = array[0], rest = array.slice(1);
return reductions(rest, function(memo, e) {
return x + y;
}, first);
}
function range(start, end) {
return(Array.apply(null, Array(end-start)).map(function(e, i) {
return start + i;
}
}
runningSum(range(0, 10));
> [0, 1, 3, 6, 10, 15, 21, 28, 36, 45]
```

So, how can we solve this while retaining the conceptual simplicity of a `reductions`

function that we just pass `lambda x, y: x + y`

to in order to create the running sum function? Let's rewrite `reductions`

procedurally. We can fix the accidentally quadratic problem, and while we're at it, pre-allocate the result list to avoid heap thrashing^{[3]}:

```
def reductions(function, list, initial):
result = [None] * len(list)
result[0] = initial
for i in range(len(list)):
result[i] = function(result[i-1], list[i])
return result
def running_sum(list):
first, rest = list[0], list[1:]
return reductions(lambda memo, e: memo + e, rest, first)
running_sum(range(0,10))
> [0, 1, 3, 6, 10, 15, 21, 28, 36, 45]
```

This is the sweet spot for me: O(n) performance, and the optimized procedural code is tucked away under a meaningful name where it can be re-used the next time you need to write a function that accumulates intermediate values into a list.

- The names
`reduce`

/`reductions`

come from the LISP tradition, `foldl`

/`scanl`

from the ML tradition, and `inject`

from the Smalltalk tradition.
- Python's
`List`

and Ruby's `Array`

are both implementations of an automatically resizing data structure known as a "dynamic array" (or `std::vector`

in C++). JavaScript's `Array`

is a little more baroque, but behaves identically provided you don't assign to out of bounds indices or mutate `Array.length`

.
- The dynamic array that forms the backing store of the list in the Python runtime will resize itself every time the list's length crosses a power of two. Resizing a list means allocating a new list on the heap of twice the size of the old one, copying the contents of the old list into the new one, and returning the old list's memory to the system. This is an O(n) operation, but because it happens less and less frequently as the list grows larger and larger, the time complexity of appending to a list works out to O(1) in the average case. However, the "hole" left by the old list can sometimes be difficult to recycle, depending on its position in the heap. Even with garbage collection and a robust memory allocator, pre-allocating an array of known size can save the underlying systems some work. In an embedded environment without the benefit of an OS, this kind of micro-management becomes very important.