What's the easiest way to use a linked list in python? In scheme, a linked list is defined simply by '(1 2 3 4 5). Python's lists, [1, 2, 3, 4, 5], and tuples, (1, 2, 3, 4, 5), are not, in fact, linked lists, and linked lists have some nice properties such as constant-time concatenation, and being able to reference separate parts of them. Make them immutable and they are really easy to work with!

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So you have profiled you working code and determined list operations to be a significant bottleneck that you need to replace them? –  ironfroggy Nov 12 '08 at 1:52
This might help you visualize it.. pythontutor.com/… –  user1889082 Dec 9 '12 at 7:41

Here is some list functions based on Martin v. Löwis's representation:

cons   = lambda el, lst: (el, lst)
mklist = lambda *args: reduce(lambda lst, el: cons(el, lst), reversed(args), None)
car = lambda lst: lst[0] if lst else lst
cdr = lambda lst: lst[1] if lst else lst
nth = lambda n, lst: nth(n-1, cdr(lst)) if n > 0 else car(lst)
length  = lambda lst, count=0: length(cdr(lst), count+1) if lst else count
begin   = lambda *args: args[-1]
display = lambda lst: begin(w("%s " % car(lst)), display(cdr(lst))) if lst else w("nil\n")


where w = sys.stdout.write

Linked lists have no practical value in Python. I've never used a linked list in Python for any problem except educational.

Thomas Watnedal suggested a good educational resource How to Think Like a Computer Scientist, Chapter 17: Linked lists:

• the empty list, represented by None, or
• a node that contains a cargo object and a reference to a linked list.

class Node:
def __init__(self, cargo=None, next=None):
self.car = cargo
self.cdr = next
def __str__(self):
return str(self.car)

def display(lst):
if lst:
w("%s " % lst)
display(lst.cdr)
else:
w("nil\n")

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You are right about (not) using LLs in Python. They are simply too low level. –  Ber Nov 12 '08 at 19:01
It's not like LLs have no use. Here is an OrderedSet recipe by Raymond Hettinger, code.activestate.com/recipes/576696 –  u0b34a0f6ae Oct 14 '09 at 10:35
It depends on how algorithmically involved your code is. It is naive to claim something has no practical value just because you yourself have never had to use it –  Casebash Oct 26 '09 at 1:03
Representing cons and car through lambdas is indeed beautiful, but not the fastest way to implement a linked list. –  pmr May 19 '10 at 12:20
Linked lists are great if your code needs to reference the previous/next item based on the current one. With python lists you'll have to keep passing indexes around, or use the index method - which will not work when the list contains duplicate values. –  lkraider Aug 23 '10 at 22:37

For some needs, a deque may also be useful. You can add and remove items on both ends of a deque at O(1) cost.

from collections import deque
d = deque([1,2,3,4])

print d
for x in d:
print x
print d.pop(), d

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This is clearly the best answer. Here's the correct link to the deque docs: docs.python.org/library/collections.html#collections.deque –  Emil Stenström May 20 '12 at 14:04
@EmilStenström: while deque is a useful data type, it is not a linked list (though it is implemented using doubly linked list at C level). So it answers the question "what would you use instead of linked lists in Python?" and in that case the first answer should be (for some needs) an ordinary Python list (it is also not a linked list). –  J.F. Sebastian Oct 19 at 20:26
@J.F.Sebastian: I almost agree with you :) I think the question this answers is rather: "What's the pythonic way to solve a problem that uses a linked list in other languages". It's not that linked lists aren't useful, it's just that problems where a deque doesn't work is very rare. –  Emil Stenström Oct 20 at 20:46

I wrote this up the other day

#! /usr/bin/env python

class node:
def __init__(self):
self.data = None # contains the data
self.next = None # contains the reference to the next node

def __init__(self):
self.cur_node = None

new_node = node() # create a new node
new_node.data = data
new_node.next = self.cur_node # link the new node to the 'previous' node.
self.cur_node = new_node #  set the current node to the new one.

def list_print(self):
node = self.cur_node # cant point to ll!
while node:
print node.data
node = node.next

ll.list_print()

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how would you be able to go through the list and search for a specific node with specific data? –  locoboy Aug 25 '11 at 17:17
@locoboy the code to do that would be similar in logic to the code in list_print(). –  Dennis Dec 11 at 19:28

Here's a slightly more complex version of a linked list class, with a similar interface to python's sequence types (ie. supports indexing, slicing, concatenation with arbitrary sequences etc). It should have O(1) prepend, doesn't copy data unless it needs to and can be used pretty interchangably with tuples.

It won't be as space or time efficient as lisp cons cells, as python classes are obviously a bit more heavyweight (You could improve things slightly with "__slots__ = '_head','_tail'" to reduce memory usage). It will have the desired big O performance characteristics however.

Example of usage:

>>> l = LinkedList([1,2,3,4])
>>> l

# Prepending is O(1) and can be done with:
# Or prepending arbitrary sequences (Still no copy of l performed):
[-1,0] + l
LinkedList([-1, 0, 1, 2, 3, 4])

# Normal list indexing and slice operations can be performed.
# Again, no copy is made unless needed.
>>> l[1], l[-1], l[2:]
>>> assert l[2:] is l.next.next

# For cases where the slice stops before the end, or uses a
# non-contiguous range, we do need to create a copy.  However
# this should be transparent to the user.


Implementation:

import itertools

def __new__(cls, l=[]):
if isinstance(l, LinkedList): return l # Immutable, so no copy needed.
i = iter(l)
try:
except StopIteration:
return cls.EmptyList   # Return empty list singleton.

obj._tail = tail
return obj

@classmethod
if not isinstance(tail, cls):
tail = cls(tail)
ll._tail = tail
return ll

# head and tail are not modifiable
@property

@property
def tail(self): return self._tail

def __nonzero__(self): return True

def __len__(self):
return sum(1 for _ in self)

if not self: return other   # () + l = l
start=l = LinkedList(iter(self))  # Create copy, as we'll mutate

while l:
if not l._tail: # Last element?
l._tail = other
break
l = l._tail
return start

def __iter__(self):
x=self
while x:
x=x.tail

def __getitem__(self, idx):
"""Get item at specified index"""
if isinstance(idx, slice):
# Special case: Avoid constructing a new list, or performing O(n) length
# calculation for slices like l[3:].  Since we're immutable, just return
# the appropriate node. This becomes O(start) rather than O(n).
# We can't do this for  more complicated slices however (eg [l:4]
start = idx.start or 0
if (start >= 0) and (idx.stop is None) and (idx.step is None or idx.step == 1):
no_copy_needed=True
else:
length = len(self)  # Need to calc length.
start, stop, step = idx.indices(length)
no_copy_needed = (stop == length) and (step == 1)

if no_copy_needed:
l = self
for i in range(start):
if not l: break # End of list.
l=l.tail
return l
else:
# We need to construct a new list.
if step < 1:  # Need to instantiate list to deal with -ve step
else:
else:
# Non-slice index.
if idx < 0: idx = len(self)+idx
if not self: raise IndexError("list index out of range")
if idx == 0: return self.head
return self.tail[idx-1]

def __mul__(self, n):
if n <= 0: return Nil
l=self
for i in range(n-1): l += self
return l
def __rmul__(self, n): return self * n

# Ideally we should compute the has ourselves rather than construct
# a temporary tuple as below.  I haven't impemented this here
def __hash__(self): return hash(tuple(self))

def __eq__(self, other): return self._cmp(other) == 0
def __ne__(self, other): return not self == other
def __lt__(self, other): return self._cmp(other) < 0
def __gt__(self, other): return self._cmp(other) > 0
def __le__(self, other): return self._cmp(other) <= 0
def __ge__(self, other): return self._cmp(other) >= 0

def _cmp(self, other):
"""Acts as cmp(): -1 for self<other, 0 for equal, 1 for greater"""

A, B = iter(self), iter(other)
for a,b in itertools.izip(A,B):
if a<b: return -1
elif a > b: return 1

try:
A.next()
return 1  # a has more items.
except StopIteration: pass

try:
B.next()
return -1  # b has more items.
except StopIteration: pass

return 0  # Lists are equal

def __repr__(self):

"""A singleton representing an empty list."""
def __new__(cls):
return object.__new__(cls)

def __iter__(self): return iter([])
def __nonzero__(self): return False

@property
def head(self): raise IndexError("End of list")

@property
def tail(self): raise IndexError("End of list")

# Create EmptyList singleton
del EmptyList

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Immutable lists are best represented through two-tuples, with None representing NIL. To allow simple formulation of such lists, you can use this function:

def mklist(*args):
result = None
for element in reversed(args):
result = (element, result)
return result


To work with such lists, I'd rather provide the whole collection of LISP functions (i.e. first, second, nth, etc), than introducing methods.

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Here is a simple LinkedList class based on the straightforward C++ design and Chapter 17: Linked lists, as recommended by Thomas Watnedal.

class Node:
def __init__(self, value = None, next = None):
self.value = value
self.next = next

def __str__(self):
return 'Node ['+str(self.value)+']'

def __init__(self):
self.first = None
self.last = None

def insert(self, x):
if self.first == None:
self.first = Node(x, None)
self.last = self.first
elif self.last == self.first:
self.last = Node(x, None)
self.first.next = self.last
else:
current = Node(x, None)
self.last.next = current
self.last = current

def __str__(self):
if self.first != None:
current = self.first
out = 'LinkedList [\n' +str(current.value) +'\n'
while current.next != None:
current = current.next
out += str(current.value) + '\n'
return out + ']'

def clear(self):
self.__init__()

L.insert(1)
L.insert(1)
L.insert(2)
L.insert(4)
print L
L.clear()
print L

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I based this additional function on Nick Stinemates

def add_node_at_end(self, data):
new_node = Node()
node = self.curr_node
while node:
if node.next == None:
node.next = new_node
new_node.next = None
new_node.data = data
node = node.next


The method he has adds the new node at the beginning while I have seen a lot of implementations which usually add a new node at the end but whatever, it is fun to do.

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I just did this as a fun toy. It should be immutable as long as you don't touch the underscore-prefixed methods, and it implements a bunch of Python magic like indexing and len.

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Here's a rather Scheme way to do it:

class cons:
def __init__(self, f, r):
self.__f = f
self.__r = r
def __str__(self):
return "(%s, %s)" % (str(self.__f), str(self.__r))
__repr__ = __str__
class empty:
def __init__(self): pass
__repr__ = lambda self: "empty"
__str__ = __repr__
empty = empty()
def first(self): return self.__f
def rest(self): return self.__r


I'm looking for a more python way, though, and ideally one that has easier to work with syntax than this:

>>> cons(12, cons(4, cons.empty))
(12, (4, empty))
>>> cons(12, cons(4, cons.empty)).first()
12
>>> cons(12, cons(4, cons.empty)).rest()
(4, empty)

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When using immutable linked lists, consider using Python's tuple directly.

ls = (1, 2, 3, 4, 5)

def first(ls): return ls[0]
def rest(ls): return ls[1:]


Its really that ease, and you get to keep the additional funcitons like len(ls), x in ls, etc.

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Tuples don't have the performance characteristics he asked for. Your rest() is O(n) as opposed to O(1) for a linked list, as is consing a new head. –  Brian Nov 11 '08 at 13:10
Right. My point is: Do not ask for linked lists to implement your algorithm, rather use the python features to optimally implement it. E.g. iterating over a linked list is O(n), as is iterating over a python tuple using "for x in t:" –  Ber Nov 11 '08 at 19:29
i think the right way to use tuples to implement linked lists is the accepted answer here. your way uses immutable array-like-objects –  Claudiu Nov 11 '08 at 21:56

I think the implementation below fill the bill quite gracefully.

'''singly linked lists, by Yingjie Lan, December 1st, 2011'''

'''Singly linked list, with pythonic features.
The list has pointers to both the first and the last node.'''
__slots__ = ['data', 'next'] #memory efficient
def __init__(self, iterable=(), data=None, next=None):
'''Provide an iterable to make a singly linked list.
Set iterable to None to make a data node for internal use.'''
if iterable is not None:
self.data, self.next = self, None
self.extend(iterable)
else: #a common node
self.data, self.next = data, next

def empty(self):
'''test if the list is empty'''
return self.next is None

def append(self, data):
'''append to the end of list.'''
last = self.data
self.data = last.next = linkst(None, data)
#self.data = last.next

def insert(self, data, index=0):
'''insert data before index.
Raise IndexError if index is out of range'''
curr, cat = self, 0
while cat < index and curr:
curr, cat = curr.next, cat+1
if index<0 or not curr:
raise IndexError(index)
if curr.next is None: self.data = new
curr.next = new

def reverse(self):
'''reverse the order of list in place'''
current, prev = self.next, None
while current: #what if list is empty?
next = current.next
current.next = prev
prev, current = current, next
if self.next: self.data = self.next
self.next = prev

def delete(self, index=0):
'''remvoe the item at index from the list'''
curr, cat = self, 0
while cat < index and curr.next:
curr, cat = curr.next, cat+1
if index<0 or not curr.next:
raise IndexError(index)
curr.next = curr.next.next
if curr.next is None: #tail
self.data = curr #current == self?

def remove(self, data):
'''remove first occurrence of data.
Raises ValueError if the data is not present.'''
current = self
while current.next: #node to be examined
if data == current.next.data: break
current = current.next #move on
else: raise ValueError(data)
current.next = current.next.next
if current.next is None: #tail
self.data = current #current == self?

def __contains__(self, data):
'''membership test using keyword 'in'.'''
current = self.next
while current:
if data == current.data:
return True
current = current.next
return False

def __iter__(self):
'''iterate through list by for-statements.
return an iterator that must define the __next__ method.'''
itr.next = self.next
return itr #invariance: itr.data == itr

def __next__(self):
'''the for-statement depends on this method
to provide items one by one in the list.
return the next data, and move on.'''
#the invariance is checked so that a linked list
#will not be mistakenly iterated over
if self.data is not self or self.next is None:
raise StopIteration()
next = self.next
self.next = next.next
return next.data

def __repr__(self):
'''string representation of the list'''

def __str__(self):
'''converting the list to a string'''
return '->'.join(str(i) for i in self)

#note: this is NOT the class lab! see file linked.py.
def extend(self, iterable):
'''takes an iterable, and append all items in the iterable
to the end of the list self.'''
last = self.data
for i in iterable:
last = last.next
self.data = last

def index(self, data):
'''TODO: return first index of data in the list self.
Raises ValueError if the value is not present.'''
#must not convert self to a tuple or any other containers
current, idx = self.next, 0
while current:
if current.data == data: return idx
current, idx = current.next, idx+1
raise ValueError(data)

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The following is what I came up with. It's similer to Riccardo C.'s, in this thread, except it prints the numbers in order instead of in reverse. I also made the LinkedList object a Python Iterator in order to print the list out like you would a normal Python list.

class Node:

def __init__(self, data=None):
self.data = data
self.next = None

def __str__(self):
return str(self.data)

def __init__(self):
self.curr = None
self.tail = None

def __iter__(self):
return self

def next(self):
return self.curr
elif self.curr.next:
self.curr = self.curr.next
return self.curr
else:
raise StopIteration

def append(self, data):
n = Node(data)
self.tail = n
else:
self.tail.next = n
self.tail = self.tail.next

for i in range(1, 6):
ll.append(i)

# print out the list
for n in ll:
print n

"""
Example output:
1
2
3
4
5
"""

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class LinkedList:
def __init__(self, value):
self.value = value
self.next = None

def insert(self, node):
if not self.next:
self.next = node
else:
self.next.insert(node)

def __str__(self):
if self.next:
return '%s -> %s' % (self.value, str(self.next))
else:
return ' %s ' % self.value

if __name__ == "__main__":
items = ['a', 'b', 'c', 'd', 'e']
ll = None
for item in items:
if ll:
ll.insert(next_ll)
else:
print('[ %s ]' % ll)

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First of all, I assume you want linked lists. In practice, you can use collections.deque, whose current CPython implementation is a doubly linked list of blocks (each block contains an array of 62 cargo objects). It subsumes linked list's functionality. You can also search for a C extension called llist on pypi. If you want a pure-Python and easy-to-follow implementation of the linked list ADT, you can take a look at my following minimal implementation.

class Node (object):
""" Node for a linked list. """
def __init__ (self, value, next=None):
self.value = value
self.next = next

that references either None, or a node that contains
a reference to a linked list.
"""
def __init__ (self, iterable=()):
for x in iterable:

def __iter__ (self):
while p is not None:
yield p.value
p = p.next

def prepend (self, x):  # 'appendleft'

def reverse (self):
""" In-place reversal. """
while p is not None:
p0, p = p, p.next

if __name__ == '__main__':
ll.prepend(3); ll.prepend(2)
print list(ll)
ll.reverse()
print list(ll)

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