Understanding the map function

``````map(function, iterable, ...)
``````

Apply function to every item of iterable and return a list of the results. If additional iterable arguments are passed, function must take that many arguments and is applied to the items from all iterables in parallel.

If one iterable is shorter than another it is assumed to be extended with None items.

If function is `None`, the identity function is assumed; if there are multiple arguments, `map()` returns a list consisting of tuples containing the corresponding items from all iterables (a kind of transpose operation).

The iterable arguments may be a sequence or any iterable object; the result is always a list.

What role does this play in making a Cartesian product?

``````content = map(tuple, array)
``````

What effect does putting a tuple anywhere in there have? I also noticed that without the map function the output is `abc` and with it, it's `a, b, c`.

I want to fully understand this function. The reference definitions is also hard to understand. Too much fancy fluff.

• What do you actually want to achieve and why specifically do you want to use `map`? – Kris Harper Jun 11 '12 at 1:42
• @WebMaster yes, per the first sentence in the documentation that you pasted - "Apply function to every item of iterable". The rest of the paragraph is about more complex cases - like `map(None, a, b, c)` turns out to do `zip(a, b, c)`. But you very rarely see that in practice, precisely because the `zip` call is equivalent. – lvc Jun 11 '12 at 2:11
• I'm trying hard to learn python and whenever I open up a definition in python.org. after the first sentence, i don't understand anything. Alright. thank you. – Web Master Jun 11 '12 at 2:18
• `tuple` is a function (well, its more nuanced than that, but it behaves like a function) that takes an iterable, and gives you a tuple with the same elements - so `tuple([1, 2, 3])` is equivalent to `(1, 2, 3)`. For `map(tuple, array)`, `array` would be an iterable of iterables (think a list of lists), and it gives you back each inner list turned into a tuple. – lvc Jun 11 '12 at 2:26
• In general, it is the first sentence of the documentation of any function that matters the most. If you understand that, you get the gist of it. The rest of it specifies the behaviour in great detail, and some of that will be a bit opaque to start with, and you may need to come across an odd idiom based on it before you see "oh, that's what that means!". But once you get that lightbulb moment for a few builtins, you should start being able to understand the docs a bit more easily. – lvc Jun 11 '12 at 2:32

`map` isn't particularly pythonic. I would recommend using list comprehensions instead:

``````map(f, iterable)
``````

is basically equivalent to:

``````[f(x) for x in iterable]
``````

`map` on its own can't do a Cartesian product, because the length of its output list is always the same as its input list. You can trivially do a Cartesian product with a list comprehension though:

``````[(a, b) for a in iterable_a for b in iterable_b]
``````

The syntax is a little confusing -- that's basically equivalent to:

``````result = []
for a in iterable_a:
for b in iterable_b:
result.append((a, b))
``````
• I find using `map` much less verbose than list comprehensions, at least for the case you are demonstrating. – marbel Dec 14 '16 at 16:40
• How do I use map for properties? What is the `map`-equivalent of `[v.__name__ for v in (object, str)]`? – A Sz Jul 19 '17 at 10:53
• @ASz How about `map(lambda v: v.__name__, list)`? – Kilian Koeltzsch Oct 13 '17 at 7:55
• map is faster since it doesn't call functions based on length of iterators .. calling functions has overhead .. Watch 6:00 youtube.com/watch?v=SiXyyOA6RZg&t=813s – anati Nov 22 '17 at 10:47
• @anati I thought `map` was sometimes faster than comprehensions, sometimes not, precisely because of function call overhead? In particular, the heuristic I learned is that when using `map` requires you to introduce an extra function call, comprehensions are faster? E.g. I was led to believe that `map(lambda foo: foo.bar, my_list)` is slower than `foo.bar for foo in my_list`, and that even `map(operator.add, my_list_of_pairs)` is slower than `x + y for x, y in my_list_of_pairs`, precisely because of the additional function call. – mtraceur Feb 20 '18 at 22:21

`map` doesn't relate to a Cartesian product at all, although I imagine someone well versed in functional programming could come up with some impossible to understand way of generating a one using `map`.

`map` in Python 3 is equivalent to this:

``````def map(func, iterable):
for i in iterable:
yield func(i)
``````

and the only difference in Python 2 is that it will build up a full list of results to return all at once instead of `yield`ing.

Although Python convention usually prefers list comprehensions (or generator expressions) to achieve the same result as a call to `map`, particularly if you're using a lambda expression as the first argument:

``````[func(i) for i in iterable]
``````

As an example of what you asked for in the comments on the question - "turn a string into an array", by 'array' you probably want either a tuple or a list (both of them behave a little like arrays from other languages) -

`````` >>> a = "hello, world"
>>> list(a)
['h', 'e', 'l', 'l', 'o', ',', ' ', 'w', 'o', 'r', 'l', 'd']
>>> tuple(a)
('h', 'e', 'l', 'l', 'o', ',', ' ', 'w', 'o', 'r', 'l', 'd')
``````

A use of `map` here would be if you start with a list of strings instead of a single string - `map` can listify all of them individually:

``````>>> a = ["foo", "bar", "baz"]
>>> list(map(list, a))
[['f', 'o', 'o'], ['b', 'a', 'r'], ['b', 'a', 'z']]
``````

Note that `map(list, a)` is equivalent in Python 2, but in Python 3 you need the `list` call if you want to do anything other than feed it into a `for` loop (or a processing function such as `sum` that only needs an iterable, and not a sequence). But also note again that a list comprehension is usually preferred:

``````>>> [list(b) for b in a]
[['f', 'o', 'o'], ['b', 'a', 'r'], ['b', 'a', 'z']]
``````
• map (fun x -> (x,x)) doesn't seem hard to understand... (though getting a true cartesian product out of map would be impossible, anything map produces is always some form of a list) – Kristopher Micinski Jun 11 '12 at 2:04

`map` creates a new list by applying a function to every element of the source:

``````xs = [1, 2, 3]

# all of those are equivalent — the output is [2, 4, 6]
# 1. map
ys = map(lambda x: x * 2, xs)
# 2. list comprehension
ys = [x * 2 for x in xs]
# 3. explicit loop
ys = []
for x in xs:
ys.append(x * 2)
``````

n-ary `map` is equivalent to zipping input iterables together and then applying the transformation function on every element of that intermediate zipped list. It's not a Cartesian product:

``````xs = [1, 2, 3]
ys = [2, 4, 6]

def f(x, y):
return (x * 2, y // 2)

# output: [(2, 1), (4, 2), (6, 3)]
# 1. map
zs = map(f, xs, ys)
# 2. list comp
zs = [f(x, y) for x, y in zip(xs, ys)]
# 3. explicit loop
zs = []
for x, y in zip(xs, ys):
zs.append(f(x, y))
``````

I've used `zip` here, but `map` behaviour actually differs slightly when iterables aren't the same size — as noted in its documentation, it extends iterables to contain `None`.

• complicated, trying to digest this post – Web Master Jun 11 '12 at 2:25
• @WebMaster What's complicated about it? – Jossie Calderon Jul 12 '16 at 16:09
• Best answer in my opinion. Using the lambda in the example as a function makes it very clear. – sheldonzy Feb 24 '18 at 11:49

Simplifying a bit, you can imagine `map()` doing something like this:

``````def mymap(func, lst):
result = []
for e in lst:
result.append(func(e))
return result
``````

As you can see, it takes a function and a list, and returns a new list with the result of applying the function to each of the elements in the input list. I said "simplifying a bit" because in reality `map()` can process more than one iterable:

If additional iterable arguments are passed, function must take that many arguments and is applied to the items from all iterables in parallel. If one iterable is shorter than another it is assumed to be extended with None items.

For the second part in the question: What role does this play in making a Cartesian product? well, `map()` could be used for generating the cartesian product of a list like this:

``````lst = [1, 2, 3, 4, 5]

reduce(add, map(lambda i: map(lambda j: (i, j), lst), lst))
``````

... But to tell the truth, using `product()` is a much simpler and natural way to solve the problem:

``````from itertools import product
list(product(lst, lst))
``````

Either way, the result is the cartesian product of `lst` as defined above:

``````[(1, 1), (1, 2), (1, 3), (1, 4), (1, 5),
(2, 1), (2, 2), (2, 3), (2, 4), (2, 5),
(3, 1), (3, 2), (3, 3), (3, 4), (3, 5),
(4, 1), (4, 2), (4, 3), (4, 4), (4, 5),
(5, 1), (5, 2), (5, 3), (5, 4), (5, 5)]
``````

The `map()` function is there to apply the same procedure to every item in an iterable data structure, like lists, generators, strings, and other stuff.

Let's look at an example: `map()` can iterate over every item in a list and apply a function to each item, than it will return (give you back) the new list.

Imagine you have a function that takes a number, adds 1 to that number and returns it:

``````def add_one(num):
new_num = num + 1
return new_num
``````

You also have a list of numbers:

``````my_list = [1, 3, 6, 7, 8, 10]
``````

if you want to increment every number in the list, you can do the following:

``````>>> map(add_one, my_list)
[2, 4, 7, 8, 9, 11]
``````

Note: At minimum `map()` needs two arguments. First a function name and second something like a list.

Let's see some other cool things `map()` can do. `map()` can take multiple iterables (lists, strings, etc.) and pass an element from each iterable to a function as an argument.

We have three lists:

``````list_one = [1, 2, 3, 4, 5]
list_two = [11, 12, 13, 14, 15]
list_three = [21, 22, 23, 24, 25]
``````

`map()` can make you a new list that holds the addition of elements at a specific index.

Now remember `map()`, needs a function. This time we'll use the builtin `sum()` function. Running `map()` gives the following result:

``````>>> map(sum, list_one, list_two, list_three)
[33, 36, 39, 42, 45]
``````

REMEMBER:
In Python 2 `map()`, will iterate (go through the elements of the lists) according to the longest list, and pass `None` to the function for the shorter lists, so your function should look for `None` and handle them, otherwise you will get errors. In Python 3 `map()` will stop after finishing with the shortest list. Also, in Python 3, `map()` returns an iterator, not a list.

Python3 - map(func, iterable)

One thing that wasn't mentioned completely (although @BlooB kinda mentioned it) is that map returns a map object NOT a list. This is a big difference when it comes to time performance on initialization and iteration. Consider these two tests.

``````import time
def test1(iterable):
a = time.clock()
map(str, iterable)
a = time.clock() - a

b = time.clock()
[ str(x) for x in iterable ]
b = time.clock() - b

print(a,b)

def test2(iterable):
a = time.clock()
[ x for x in map(str, iterable)]
a = time.clock() - a

b = time.clock()
[ str(x) for x in iterable ]
b = time.clock() - b

print(a,b)

test1(range(2000000))  # Prints ~1.7e-5s   ~8s
test2(range(2000000))  # Prints ~9s        ~8s
``````

As you can see initializing the map function takes almost no time at all. However iterating through the map object takes longer than simply iterating through the iterable. This means that the function passed to map() is not applied to each element until the element is reached in the iteration. If you want a list use list comprehension. If you plan to iterate through in a for loop and will break at some point, then use map.