# Python - How to check list monotonicity

What would be an efficient and pythonic way to check list monotonicity?
i.e. that it has monotonically increasing or decreasing values?

Examples:

``````[0, 1, 2, 3, 3, 4]   # This is a monotonically increasing list
[4.3, 4.2, 4.2, -2]  # This is a monotonically decreasing list
[2, 3, 1]            # This is neither
``````
• It's better to use the terms "strictly increasing" or "non decreasing" to leave any ambiguity out (and in a similar way it's better to avoid "positive" and use instead either "non negative" or "strictly positive") – 6502 Feb 13 '11 at 10:26
• @6502 the term monotonic is defined as either a non-increasing or non-decreasing set of ordered values, so there was no ambiguity in the question. – Autoplectic Feb 13 '11 at 18:33

``````def strictly_increasing(L):
return all(x<y for x, y in zip(L, L[1:]))

def strictly_decreasing(L):
return all(x>y for x, y in zip(L, L[1:]))

def non_increasing(L):
return all(x>=y for x, y in zip(L, L[1:]))

def non_decreasing(L):
return all(x<=y for x, y in zip(L, L[1:]))

def monotonic(L):
return non_increasing(L) or non_decreasing(L)
``````
• This is clear, idiomatic Python code, and its complexity is O(n) where the sorting answers are all O(n log n). An ideal answer would iterate over the list only once so it works on any iterator, but this is usually good enough and it's by far the best answer among the ones so far. (I'd offer a single-pass solution, but the OP prematurely accepting an answer curbs any urge I might have to do so...) – Glenn Maynard Feb 13 '11 at 9:20
• just out of curiosity tested your implementation against using sorted. Yours is clearly a lot slower [ I used L = range(10000000) ]. It seems complexity of all is O(n), and I could not find implementation of zip. – Asterisk Feb 13 '11 at 9:56
• Sort is specialized if the list is already sorted. Did you try the speed with a randomly shuffled list? Also note that with sort you cannot distinguish between strictly increasing and non decreasing. Also consider that with Python 2.x using `itertools.izip` instead of `zip` you can get an early exit (in python 3 `zip` already works like an iterator) – 6502 Feb 13 '11 at 10:17
• @6502: just one function needed: import operator; def monotone(L, op): return all(op(x,y) for x, y in zip(L, L[1:])) and then just feed in what you want: operator.le or .ge or whatever – akira Feb 13 '11 at 10:55
• zip and the slice operator both return entire lists, obviating the shortcut abilities of all(); this could be greatly improved by using itertools.izip and itertools.islice, as either strictly_increasing or strictly_decreasing should shortcut-fail very early. – Hugh Bothwell Feb 13 '11 at 15:05

If you have large lists of numbers it might be best to use numpy, and if you are:

``````import numpy as np

def monotonic(x):
dx = np.diff(x)
return np.all(dx <= 0) or np.all(dx >= 0)
``````

should do the trick.

• Note that dx is np.nan. You might want to use: dx = np.diff(x)[1:] to skip past it. Otherwise, at least for me, the np.all() calls always return False. – Ryan Aug 19 '15 at 18:51
• @Ryan, why would `dx` be `NaN`? What is your input array? – DilithiumMatrix Nov 16 '15 at 1:06
• N/m, I was thinking that `np.diff()` made the first element `NaN` so the shape of the output matched the input, but that was actually a different piece of code that did that that bit me. :) – Ryan Dec 4 '15 at 0:00
``````import itertools
import operator

def monotone_increasing(lst):
pairs = zip(lst, lst[1:])
return all(itertools.starmap(operator.le, pairs))

def monotone_decreasing(lst):
pairs = zip(lst, lst[1:])
return all(itertools.starmap(operator.ge, pairs))

def monotone(lst):
return monotone_increasing(lst) or monotone_decreasing(lst)
``````

This approach is `O(N)` in the length of the list.

• The Correct(TM) solution IMO. Functional paradigm for the win! – unperson325680 Feb 13 '11 at 9:00
• why using itertools instead of plain generators? – 6502 Feb 13 '11 at 9:14
• Functional paradigms are usually not "the win" in Python. – Glenn Maynard Feb 13 '11 at 9:15
• @6502 Habit, mostly. On the other hand, `map` is exactly the abstraction needed, here, so why recreate it with a generator expression? – Michael J. Barber Feb 13 '11 at 9:29
• Calculating pairs is `O(N)` as well. You could make `pairs = itertools.izip(lst, itertools.islice(lst, 1, None))`. – Tomasz Elendt Feb 13 '11 at 9:36

@6502 has the perfect code for lists, I just want to add a general version that works for all sequences:

``````def pairwise(seq):
items = iter(seq)
last = next(items)
for item in items:
yield last, item
last = item

def strictly_increasing(L):
return all(x<y for x, y in pairwise(L))

def strictly_decreasing(L):
return all(x>y for x, y in pairwise(L))

def non_increasing(L):
return all(x>=y for x, y in pairwise(L))

def non_decreasing(L):
return all(x<=y for x, y in pairwise(L))
``````
``````import operator, itertools

def is_monotone(lst):
op = operator.le            # pick 'op' based upon trend between
if not op(lst, lst[-1]): # first and last element in the 'lst'
op = operator.ge
return all(op(x,y) for x, y in itertools.izip(lst, lst[1:]))
``````
• I was thinking about a solution like this - but it fails if the list is monotonically increasing and the first two elements are equal. – Hugh Bothwell Feb 13 '11 at 15:02
• @Hugh Bothwell: i check now the first and the last to get the trend: if they are equal then all other elements should be equal as well which then works for both operator.le and operator.ge – akira Feb 14 '11 at 8:02

Here is a functional solution using `reduce` of complexity `O(n)`:

``````is_increasing = lambda L: reduce(lambda a,b: b if a < b else 9999 , L)!=9999

is_decreasing = lambda L: reduce(lambda a,b: b if a > b else -9999 , L)!=-9999
``````

Replace `9999` with the top limit of your values, and `-9999` with the bottom limit. For example, if you are testing a list of digits, you can use `10` and `-1`.

I tested its performance against @6502's answer and its faster.

Case True: `[1,2,3,4,5,6,7,8,9]`

``````# my solution ..
\$ python -m timeit "inc = lambda L: reduce(lambda a,b: b if a < b else 9999 , L)!=9999; inc([1,2,3,4,5,6,7,8,9])"
1000000 loops, best of 3: 1.9 usec per loop

# while the other solution:
\$ python -m timeit "inc = lambda L: all(x<y for x, y in zip(L, L[1:]));inc([1,2,3,4,5,6,7,8,9])"
100000 loops, best of 3: 2.77 usec per loop
``````

Case False from the 2nd element: `[4,2,3,4,5,6,7,8,7]`:

``````# my solution ..
\$ python -m timeit "inc = lambda L: reduce(lambda a,b: b if a < b else 9999 , L)!=9999; inc([4,2,3,4,5,6,7,8,7])"
1000000 loops, best of 3: 1.87 usec per loop

# while the other solution:
\$ python -m timeit "inc = lambda L: all(x<y for x, y in zip(L, L[1:]));inc([4,2,3,4,5,6,7,8,7])"
100000 loops, best of 3: 2.15 usec per loop
``````
``````L = [1,2,3]
L == sorted(L)

L == sorted(L, reverse=True)
``````
• I'd have gone for `sorted()` if it didn't actually sort anything, just check. Badly named -- sounds like a predicate when it isn't. – unperson325680 Feb 13 '11 at 9:07
• What's next? Using `sorted(L)` instead of `min`? – 6502 Feb 13 '11 at 9:12
• This is algorithmically poor; this solution is O(n log n), when this problem can be done trivially in O(n). – Glenn Maynard Feb 13 '11 at 9:14
• @all agree with all of you, thanks for constructive criticism. – Asterisk Feb 13 '11 at 9:21
• I tested all the solutions in this thread here, and found that the sorted method actually is the best... if the list is actually monotonically increasing. If the list has any items out of order, it becomes the slowest. – Matthew Moisen Nov 14 '16 at 4:25

I timed all of the answers in this question under different conditions, and found that:

• Sorting was the fastest by a long shot IF the list was already monotonically increasing
• Sorting was the slowest by a long shot IF the list was shuffled/random or if the number of elements out of order was greater than ~1. The more out of order the list of course corresponds to a slower result.
• Michael J. Barbers method was the fastest IF the list was mostly monotonically increasing, or completely random.

Here is the code to try it out:

``````import timeit

setup = '''
import random
from itertools import izip, starmap, islice
import operator

def is_increasing_normal(lst):
for i in range(0, len(lst) - 1):
if lst[i] >= lst[i + 1]:
return False
return True

def is_increasing_zip(lst):
return all(x < y for x, y in izip(lst, islice(lst, 1, None)))

def is_increasing_sorted(lst):
return lst == sorted(lst)

def is_increasing_starmap(lst):
pairs = izip(lst, islice(lst, 1, None))
return all(starmap(operator.le, pairs))

if {list_method} in (1, 2):
lst = list(range({n}))
if {list_method} == 2:
for _ in range(int({n} * 0.0001)):
lst.insert(random.randrange(0, len(lst)), -random.randrange(1,100))
if {list_method} == 3:
lst = [int(1000*random.random()) for i in xrange({n})]
'''

n = 100000
iterations = 10000
list_method = 1

timeit.timeit('is_increasing_normal(lst)', setup=setup.format(n=n, list_method=list_method), number=iterations)

timeit.timeit('is_increasing_zip(lst)', setup=setup.format(n=n, list_method=list_method), number=iterations)

timeit.timeit('is_increasing_sorted(lst)', setup=setup.format(n=n, list_method=list_method), number=iterations)

timeit.timeit('is_increasing_starmap(lst)', setup=setup.format(n=n, list_method=list_method), number=iterations)
``````

If the list was already monotonically increasing (`list_method == 1`), the fastest to slowest was:

1. sorted
2. starmap
3. normal
4. zip

If the list was mostly monotonically increasing (`list_method == 2`), the fastest to slowest was:

1. starmap
2. zip
3. normal
4. sorted

(Whether or not the starmap or zip was fastest depended on the execution and I couldn't identify a pattern. Starmap appeared to be usually faster)

If the list was completely random (`list_method == 3`), the fastest to slowest was:

1. starmap
2. zip
3. normal
• I did not try @Assem Chelli's method as it required knowledge of the max item in the list – Matthew Moisen Nov 14 '16 at 4:22

This is possible using Pandas which you can install via `pip install pandas`.

``````import pandas as pd
``````

The following commands work with a list of integers or floats.

### Monotonically increasing (≥):

``````pd.Series(mylist).is_monotonic_increasing
``````

### Strictly monotonically increasing (>):

``````myseries = pd.Series(mylist)
myseries.is_unique and myseries.is_monotonic_increasing
``````

Alternative using an undocumented private method:

``````pd.Index(mylist)._is_strictly_monotonic_increasing
``````

### Monotonically decreasing (≤):

``````pd.Series(mylist).is_monotonic_decreasing
``````

### Strictly monotonically decreasing (<):

``````myseries = pd.Series(mylist)
myseries.is_unique and myseries.is_monotonic_decreasing
``````

Alternative using an undocumented private method:

``````pd.Index(mylist)._is_strictly_monotonic_decreasing
``````

Here's a variant that accepts both materialized and non-materialized sequences. It automatically determines whether or not it's `monotonic`, and if so, its direction (i.e. `increasing` or `decreasing`) and `strict`ness. Inline comments are provided to help the reader. Similarly for test-cases provided at the end.

``````    def isMonotonic(seq):
"""
seq.............: - A Python sequence, materialized or not.
Returns.........:
(True,0,True):   - Mono Const, Strict: Seq empty or 1-item.
(True,0,False):  - Mono Const, Not-Strict: All 2+ Seq items same.
(True,+1,True):  - Mono Incr, Strict.
(True,+1,False): - Mono Incr, Not-Strict.
(True,-1,True):  - Mono Decr, Strict.
(True,-1,False): - Mono Decr, Not-Strict.
(False,None,None) - Not Monotonic.
"""
items = iter(seq) # Ensure iterator (i.e. that next(...) works).
prev_value = next(items, None) # Fetch 1st item, or None if empty.
if prev_value == None: return (True,0,True) # seq was empty.

# ============================================================
# The next for/loop scans until it finds first value-change.
# ============================================================
# Ex: [3,3,3,78,...] --or- [-5,-5,-5,-102,...]
# ============================================================
# -- If that 'change-value' represents an Increase or Decrease,
#    then we know to look for Monotonically Increasing or
#    Decreasing, respectively.
# -- If no value-change is found end-to-end (e.g. [3,3,3,...3]),
#    then it's Monotonically Constant, Non-Strict.
# -- Finally, if the sequence was exhausted above, which means
#    it had exactly one-element, then it Monotonically Constant,
#    Strict.
# ============================================================
isSequenceExhausted = True
curr_value = prev_value
for item in items:
isSequenceExhausted = False # Tiny inefficiency.
if item == prev_value: continue
curr_value = item
break
else:
return (True,0,True) if isSequenceExhausted else (True,0,False)
# ============================================================

# ============================================================
# If we tricked down to here, then none of the above
# checked-cases applied (i.e. didn't short-circuit and
# 'return'); so we continue with the final step of
# iterating through the remaining sequence items to
# determine Monotonicity, direction and strictness.
# ============================================================
strict = True
if curr_value > prev_value: # Scan for Increasing Monotonicity.
for item in items:
if item < curr_value: return (False,None,None)
if item == curr_value: strict = False # Tiny inefficiency.
curr_value = item
return (True,+1,strict)
else:                       # Scan for Decreasing Monotonicity.
for item in items:
if item > curr_value: return (False,None,None)
if item == curr_value: strict = False # Tiny inefficiency.
curr_value = item
return (True,-1,strict)
# ============================================================

# Test cases ...
assert isMonotonic([1,2,3,4])     == (True,+1,True)
assert isMonotonic([4,3,2,1])     == (True,-1,True)
assert isMonotonic([-1,-2,-3,-4]) == (True,-1,True)
assert isMonotonic([])            == (True,0,True)
assert isMonotonic()          == (True,0,True)
assert isMonotonic([-20])         == (True,0,True)
assert isMonotonic([1,1])         == (True,0,False)
assert isMonotonic([1,-1])        == (True,-1,True)
assert isMonotonic([1,-1,-1])     == (True,-1,False)
assert isMonotonic([1,3,3])       == (True,+1,False)
assert isMonotonic([1,2,1])       == (False,None,None)
assert isMonotonic([0,0,0,0])     == (True,0,False)
``````

I suppose this could be more `Pythonic`, but it's tricky because it avoids creating intermediate collections (e.g. `list`, `genexps`, etc); as well as employs a `fall/trickle-through` and `short-circuit` approach to filter through the various cases: E.g. Edge-sequences (like empty or one-item sequences; or sequences with all identical items); Identifying increasing or decreasing monotonicity, strictness, and so on. I hope it helps.

``````>>> l = [0,1,2,3,3,4]
>>> l == sorted(l) or l == sorted(l, reverse=True)
``````