Develop Reference

How to find the highest value element in a list with reference to a dictionary on python

How do I code a function in python which can:
iterate through a list of word strings which may contain duplicate words and referencing to a dictionary,
find the word with the highest absolute sum, and
output it along with the corresponding absolute value.
The function also has to ignore words which are not in the dictionary.
For example,
Assume the function is called H_abs_W().
Given the following list and dict:
list_1 = ['apples','oranges','pears','apples']
Dict_1 = {'apples':5.23,'pears':-7.62}
Then calling the function as:
H_abs_W(list_1,Dict_1)
Should give the output:
'apples',10.46
EDIT:
I managed to do it in the end with the code below. Looking over the answers, turns out I could have done it in a shorter fashion, lol.
def H_abs_W(list_1,Dict_1):
freqW = {}
for char in list_1:
if char in freqW:
freqW[char] += 1
else:
freqW[char] = 1
ASum_W = 0
i_word = ''
for a,b in freqW.items():
x = 0
d = Dict_1.get(a,0)
x = abs(float(b)*float(d))
if x > ASum_W:
ASum_W = x
i_word = a
return(i_word,ASum_W)

list_1 = ['apples','oranges','pears','apples']
Dict_1 = {'apples':5.23,'pears':-7.62}
d = {k:0 for k in list_1}
for x in list_1:
if x in Dict_1.keys():
d[x]+=Dict_1[x]
m = max(Dict_1, key=Dict_1.get)
print(m,Dict_1[m])

try this,
key, value = sorted(Dict_1.items(), key = lambda x : x[1], reverse=True)[0]
print(f"{key}, {list_1.count(key) * value}")
# apples, 10.46

you can use Counter to calculate the frequency(number of occurrences) of each item in the list.
max(counter.values()) will give us the count of maximum occurring element
max(counter, key=counter.get) will give the which item in the list is
associated with that highest count.
========================================================================
from collections import Counter
def H_abs_W(list_1, Dict_1):
counter = Counter(list_1)
count = max(counter.values())
item = max(counter, key=counter.get)
return item, abs(count * Dict_1.get(item))

PySpark: difficulty implementing KMeans with mapreduce functions

I am currently tasekd in a Distributed DataBase class to create an implementation of kmeans with map reduce based approach (yes i know that there is a premade function for it but the task is specifically to do your own approach), and while i have figured out the approach itself, i am struggling with implementing it with the appropriate use of the map and reduce functions.
def Find_dist(x,y):
sum = 0
vec1= list(x)
vec2 = list(y)
for i in range(len(vec1)):
sum = sum +(vec1[i]-vec2[i])*(vec1[i]-vec2[i])
return sum
def mapper(cent, datapoint):
min = Find_dist(datapoint,cent[0])
closest = cent[0]
for i in range(1,len(cent)):
curr = Find_dist(datapoint,cent[i])
if curr < min:
min = curr
closest = cent[i]
yield closest,datapoint
def combine(x):
Key = x[0]
Values = x[1]
sum = [0]*len(Key)
counter = 0
for datapoint in Values:
vec = list(datapoint[0])
counter = counter+1
sum = sum+vec
point = Row(vec)
result = (counter,point)
yield Key, result
def Reducer(x):
Key = x[0]
Values = x[1]
sum = [0]*len(Key)
counter = 0
for datapoint in Values:
vec = list(datapoint[0])
counter = counter+1
sum = sum+vec
avg = [0]*len(Key)
for i in range(len(Key)):
avg[i] = sum[i]/counter
centroid = Row(avg)
yield Key, centroid
def kmeans_fit(data,k,max_iter):
centers = data.rdd.takeSample(False,k,seed=42)
for i in range(max_iter):
mapped = data.rdd.map(lambda x: mapper(centers,x))
combined = mapped.reduceByKeyLocally(lambda x: combiner(x))
reduced = combined.reduceByKey(lambda x: Reducer(x)).collect()
flag = True
for i in range(k):
if(reduced[i][1] != reduced[i][0] ):
for j in range(k):
centers[i] = reduced[i][1]
flag = False
break
if (flag):
break
return centers
data = spark.read.parquet("/mnt/ddscoursedatabricksstg/ddscoursedatabricksdata/random_data.parquet")
kmeans_fit(data,5,10)
My main issue for the most part is I encounter difficulty in the usage of dataframes and the map, reducebykeylocally and reducebykey fucntions.
Currently the run fails at calling reduceByKeyLocally(lambda x: combiner(x)) because "ValueError: not enough values to unpack (expected 2, got 1)", and i really need to get this all working properly soon, so please, anyone i would love assistance on this, and thank you in advance, I will be very grateful for any help!

Pythonic way to assign range of number to bucket

I'm developing an ABtest framework using django. I want to assign variant number based on bucket_id from cookies' request.
bucket_id is set by the front end with a range integer from 0-99.
So far, I have created the function name get_bucket_name:
def get_bucket_range(data):
range_bucket = []
first_val = 0
next_val = 0
for i, v in enumerate(data.split(",")):
v = int(v)
if i == 0:
first_val = v
range_bucket.append([0, first_val])
elif i == 1:
range_bucket.append([first_val, first_val + v])
next_val = first_val + v
else:
range_bucket.append([next_val, next_val + v])
next_val = next_val + v
return range_bucket
Data input for get_bucket_range is a comma delineated string which means we have 3 variants where each variant has its own weight e.g. data = "25,25,50" with first variant's weight being 25 etc.
I then created a function to assign the variant named,
def assign_variant(range_bucket, num):
for i in range(len(range_bucket)):
if num in range(range_bucket[i][0], range_bucket[i][1]):
return i
This function should have 2 parameters, range_bucket -> from get_bucket_range function, and num -> bucket_id from cookies.
With this function I can return which bucket_id belongs to the variant id.
For example, we have 25 as bucket_id, with data = "25,25,50". This means our bucket_id should belong to variant id 1. Or in the case that we have 25 as bucket_id, with data = "10,10,10,70". This should mean that our bucket_id will belong to variant id 2.
However, it feels like neither of my functions are pythonic or optimised. Does anyone here have any suggestions as to how I could improve my code?

Your functions could look like this for example:
def get_bucket_range(data):
last = 0
range_bucket = []
for v in map(int, data.split(',')):
range_bucket.append([last, last+v])
last += v
return range_bucket
def assign_variant(range_bucket, num):
for i, (low, high) in enumerate(range_bucket):
if low <= num < high:
return i

You can greatly reduce the lengths of your functions with the itertools.accumulate and bisect.bisect functions. The first function accumulates all the weights into sums (10,10,10,70 becomes 10,20,30,100), and the second function gives you the index of where that element would belong, which in your case is equivalent to the index of the group it belongs to.
from itertools import accumulate
from bisect import bisect
def get_bucket_range(data):
return list(accumulate(map(int, data.split(',')))
def assign_variant(range_bucket, num):
return bisect(range_bucket, num)

Python: Concatenate similiar objects in List

I have a list containing strings as ['Country-Points'].
For example:
lst = ['Albania-10', 'Albania-5', 'Andorra-0', 'Andorra-4', 'Andorra-8', ...other countries...]
I want to calculate the average for each country without creating a new list. So the output would be (in the case above):
lst = ['Albania-7.5', 'Andorra-4.25', ...other countries...]
Would realy appreciate if anyone can help me with this.
EDIT:
this is what I've got so far. So, "data" is actually a dictionary, where the keys are countries and the values are list of other countries points' to this country (the one as Key). Again, I'm new at Python so I don't realy know all the built-in functions.
for key in self.data:
lst = []
index = 0
score = 0
cnt = 0
s = str(self.data[key][0]).split("-")[0]
for i in range(len(self.data[key])):
if s in self.data[key][i]:
a = str(self.data[key][i]).split("-")
score += int(float(a[1]))
cnt+=1
index+=1
if i+1 != len(self.data[key]) and not s in self.data[key][i+1]:
lst.append(s + "-" + str(float(score/cnt)))
s = str(self.data[key][index]).split("-")[0]
score = 0
self.data[key] = lst

itertools.groupby with a suitable key function can help:
import itertools
def get_country_name(item):
return item.split('-', 1)[0]
def get_country_value(item):
return float(item.split('-', 1)[1])
def country_avg_grouper(lst) :
for ctry, group in itertools.groupby(lst, key=get_country_name):
values = list(get_country_value(c) for c in group)
avg = sum(values)/len(values)
yield '{country}-{avg}'.format(country=ctry, avg=avg)
lst[:] = country_avg_grouper(lst)
The key here is that I wrote a function to do the change out of place and then I can easily make the substitution happen in place by using slice assignment.

I would probabkly do this with an intermediate dictionary.
def country(s):
return s.split('-')[0]
def value(s):
return float(s.split('-')[1])
def country_average(lst):
country_map = {}|
for point in lst:
c = country(pair)
v = value(pair)
old = country_map.get(c, (0, 0))
country_map[c] = (old[0]+v, old[1]+1)
return ['%s-%f' % (country, sum/count)
for (country, (sum, count)) in country_map.items()]
It tries hard to only traverse the original list only once, at the expense of quite a few tuple allocations.

Find the most common element in a list

What is an efficient way to find the most common element in a Python list?
My list items may not be hashable so can't use a dictionary.
Also in case of draws the item with the lowest index should be returned. Example:
>>> most_common(['duck', 'duck', 'goose'])
'duck'
>>> most_common(['goose', 'duck', 'duck', 'goose'])
'goose'

A simpler one-liner:
def most_common(lst):
return max(set(lst), key=lst.count)

Borrowing from here, this can be used with Python 2.7:
from collections import Counter
def Most_Common(lst):
data = Counter(lst)
return data.most_common(1)[0][0]
Works around 4-6 times faster than Alex's solutions, and is 50 times faster than the one-liner proposed by newacct.
On CPython 3.6+ (any Python 3.7+) the above will select the first seen element in case of ties. If you're running on older Python, to retrieve the element that occurs first in the list in case of ties you need to do two passes to preserve order:
# Only needed pre-3.6!
def most_common(lst):
data = Counter(lst)
return max(lst, key=data.get)

With so many solutions proposed, I'm amazed nobody's proposed what I'd consider an obvious one (for non-hashable but comparable elements) -- [itertools.groupby][1]. itertools offers fast, reusable functionality, and lets you delegate some tricky logic to well-tested standard library components. Consider for example:
import itertools
import operator
def most_common(L):
# get an iterable of (item, iterable) pairs
SL = sorted((x, i) for i, x in enumerate(L))
# print 'SL:', SL
groups = itertools.groupby(SL, key=operator.itemgetter(0))
# auxiliary function to get "quality" for an item
def _auxfun(g):
item, iterable = g
count = 0
min_index = len(L)
for _, where in iterable:
count += 1
min_index = min(min_index, where)
# print 'item %r, count %r, minind %r' % (item, count, min_index)
return count, -min_index
# pick the highest-count/earliest item
return max(groups, key=_auxfun)[0]
This could be written more concisely, of course, but I'm aiming for maximal clarity. The two print statements can be uncommented to better see the machinery in action; for example, with prints uncommented:
print most_common(['goose', 'duck', 'duck', 'goose'])
emits:
SL: [('duck', 1), ('duck', 2), ('goose', 0), ('goose', 3)]
item 'duck', count 2, minind 1
item 'goose', count 2, minind 0
goose
As you see, SL is a list of pairs, each pair an item followed by the item's index in the original list (to implement the key condition that, if the "most common" items with the same highest count are > 1, the result must be the earliest-occurring one).
groupby groups by the item only (via operator.itemgetter). The auxiliary function, called once per grouping during the max computation, receives and internally unpacks a group - a tuple with two items (item, iterable) where the iterable's items are also two-item tuples, (item, original index) [[the items of SL]].
Then the auxiliary function uses a loop to determine both the count of entries in the group's iterable, and the minimum original index; it returns those as combined "quality key", with the min index sign-changed so the max operation will consider "better" those items that occurred earlier in the original list.
This code could be much simpler if it worried a little less about big-O issues in time and space, e.g....:
def most_common(L):
groups = itertools.groupby(sorted(L))
def _auxfun((item, iterable)):
return len(list(iterable)), -L.index(item)
return max(groups, key=_auxfun)[0]
same basic idea, just expressed more simply and compactly... but, alas, an extra O(N) auxiliary space (to embody the groups' iterables to lists) and O(N squared) time (to get the L.index of every item). While premature optimization is the root of all evil in programming, deliberately picking an O(N squared) approach when an O(N log N) one is available just goes too much against the grain of scalability!-)
Finally, for those who prefer "oneliners" to clarity and performance, a bonus 1-liner version with suitably mangled names:-).
from itertools import groupby as g
def most_common_oneliner(L):
return max(g(sorted(L)), key=lambda(x, v):(len(list(v)),-L.index(x)))[0]

What you want is known in statistics as mode, and Python of course has a built-in function to do exactly that for you:
>>> from statistics import mode
>>> mode([1, 2, 2, 3, 3, 3, 3, 3, 4, 5, 6, 6, 6])
3
Note that if there is no "most common element" such as cases where the top two are tied, this will raise StatisticsError on Python
<=3.7, and on 3.8 onwards it will return the first one encountered.

Without the requirement about the lowest index, you can use collections.Counter for this:
from collections import Counter
a = [1936, 2401, 2916, 4761, 9216, 9216, 9604, 9801]
c = Counter(a)
print(c.most_common(1)) # the one most common element... 2 would mean the 2 most common
[(9216, 2)] # a set containing the element, and it's count in 'a'

If they are not hashable, you can sort them and do a single loop over the result counting the items (identical items will be next to each other). But it might be faster to make them hashable and use a dict.
def most_common(lst):
cur_length = 0
max_length = 0
cur_i = 0
max_i = 0
cur_item = None
max_item = None
for i, item in sorted(enumerate(lst), key=lambda x: x[1]):
if cur_item is None or cur_item != item:
if cur_length > max_length or (cur_length == max_length and cur_i < max_i):
max_length = cur_length
max_i = cur_i
max_item = cur_item
cur_length = 1
cur_i = i
cur_item = item
else:
cur_length += 1
if cur_length > max_length or (cur_length == max_length and cur_i < max_i):
return cur_item
return max_item

This is an O(n) solution.
mydict = {}
cnt, itm = 0, ''
for item in reversed(lst):
mydict[item] = mydict.get(item, 0) + 1
if mydict[item] >= cnt :
cnt, itm = mydict[item], item
print itm
(reversed is used to make sure that it returns the lowest index item)

Sort a copy of the list and find the longest run. You can decorate the list before sorting it with the index of each element, and then choose the run that starts with the lowest index in the case of a tie.

A one-liner:
def most_common (lst):
return max(((item, lst.count(item)) for item in set(lst)), key=lambda a: a[1])[0]

I am doing this using scipy stat module and lambda:
import scipy.stats
lst = [1,2,3,4,5,6,7,5]
most_freq_val = lambda x: scipy.stats.mode(x)[0][0]
print(most_freq_val(lst))
Result:
most_freq_val = 5

# use Decorate, Sort, Undecorate to solve the problem
def most_common(iterable):
# Make a list with tuples: (item, index)
# The index will be used later to break ties for most common item.
lst = [(x, i) for i, x in enumerate(iterable)]
lst.sort()
# lst_final will also be a list of tuples: (count, index, item)
# Sorting on this list will find us the most common item, and the index
# will break ties so the one listed first wins. Count is negative so
# largest count will have lowest value and sort first.
lst_final = []
# Get an iterator for our new list...
itr = iter(lst)
# ...and pop the first tuple off. Setup current state vars for loop.
count = 1
tup = next(itr)
x_cur, i_cur = tup
# Loop over sorted list of tuples, counting occurrences of item.
for tup in itr:
# Same item again?
if x_cur == tup[0]:
# Yes, same item; increment count
count += 1
else:
# No, new item, so write previous current item to lst_final...
t = (-count, i_cur, x_cur)
lst_final.append(t)
# ...and reset current state vars for loop.
x_cur, i_cur = tup
count = 1
# Write final item after loop ends
t = (-count, i_cur, x_cur)
lst_final.append(t)
lst_final.sort()
answer = lst_final[0][2]
return answer
print most_common(['x', 'e', 'a', 'e', 'a', 'e', 'e']) # prints 'e'
print most_common(['goose', 'duck', 'duck', 'goose']) # prints 'goose'

Building on Luiz's answer, but satisfying the "in case of draws the item with the lowest index should be returned" condition:
from statistics import mode, StatisticsError
def most_common(l):
try:
return mode(l)
except StatisticsError as e:
# will only return the first element if no unique mode found
if 'no unique mode' in e.args[0]:
return l[0]
# this is for "StatisticsError: no mode for empty data"
# after calling mode([])
raise
Example:
>>> most_common(['a', 'b', 'b'])
'b'
>>> most_common([1, 2])
1
>>> most_common([])
StatisticsError: no mode for empty data

Simple one line solution
moc= max([(lst.count(chr),chr) for chr in set(lst)])
It will return most frequent element with its frequency.

You probably don't need this anymore, but this is what I did for a similar problem. (It looks longer than it is because of the comments.)
itemList = ['hi', 'hi', 'hello', 'bye']
counter = {}
maxItemCount = 0
for item in itemList:
try:
# Referencing this will cause a KeyError exception
# if it doesn't already exist
counter[item]
# ... meaning if we get this far it didn't happen so
# we'll increment
counter[item] += 1
except KeyError:
# If we got a KeyError we need to create the
# dictionary key
counter[item] = 1
# Keep overwriting maxItemCount with the latest number,
# if it's higher than the existing itemCount
if counter[item] > maxItemCount:
maxItemCount = counter[item]
mostPopularItem = item
print mostPopularItem

ans = [1, 1, 0, 0, 1, 1]
all_ans = {ans.count(ans[i]): ans[i] for i in range(len(ans))}
print(all_ans)
all_ans={4: 1, 2: 0}
max_key = max(all_ans.keys())
4
print(all_ans[max_key])
1

#This will return the list sorted by frequency:
def orderByFrequency(list):
listUniqueValues = np.unique(list)
listQty = []
listOrderedByFrequency = []
for i in range(len(listUniqueValues)):
listQty.append(list.count(listUniqueValues[i]))
for i in range(len(listQty)):
index_bigger = np.argmax(listQty)
for j in range(listQty[index_bigger]):
listOrderedByFrequency.append(listUniqueValues[index_bigger])
listQty[index_bigger] = -1
return listOrderedByFrequency
#And this will return a list with the most frequent values in a list:
def getMostFrequentValues(list):
if (len(list) <= 1):
return list
list_most_frequent = []
list_ordered_by_frequency = orderByFrequency(list)
list_most_frequent.append(list_ordered_by_frequency[0])
frequency = list_ordered_by_frequency.count(list_ordered_by_frequency[0])
index = 0
while(index < len(list_ordered_by_frequency)):
index = index + frequency
if(index < len(list_ordered_by_frequency)):
testValue = list_ordered_by_frequency[index]
testValueFrequency = list_ordered_by_frequency.count(testValue)
if (testValueFrequency == frequency):
list_most_frequent.append(testValue)
else:
break
return list_most_frequent
#tests:
print(getMostFrequentValues([]))
print(getMostFrequentValues([1]))
print(getMostFrequentValues([1,1]))
print(getMostFrequentValues([2,1]))
print(getMostFrequentValues([2,2,1]))
print(getMostFrequentValues([1,2,1,2]))
print(getMostFrequentValues([1,2,1,2,2]))
print(getMostFrequentValues([3,2,3,5,6,3,2,2]))
print(getMostFrequentValues([1,2,2,60,50,3,3,50,3,4,50,4,4,60,60]))
Results:
[]
[1]
[1]
[1, 2]
[2]
[1, 2]
[2]
[2, 3]
[3, 4, 50, 60]

Here:
def most_common(l):
max = 0
maxitem = None
for x in set(l):
count = l.count(x)
if count > max:
max = count
maxitem = x
return maxitem
I have a vague feeling there is a method somewhere in the standard library that will give you the count of each element, but I can't find it.

This is the obvious slow solution (O(n^2)) if neither sorting nor hashing is feasible, but equality comparison (==) is available:
def most_common(items):
if not items:
raise ValueError
fitems = []
best_idx = 0
for item in items:
item_missing = True
i = 0
for fitem in fitems:
if fitem[0] == item:
fitem[1] += 1
d = fitem[1] - fitems[best_idx][1]
if d > 0 or (d == 0 and fitems[best_idx][2] > fitem[2]):
best_idx = i
item_missing = False
break
i += 1
if item_missing:
fitems.append([item, 1, i])
return items[best_idx]
But making your items hashable or sortable (as recommended by other answers) would almost always make finding the most common element faster if the length of your list (n) is large. O(n) on average with hashing, and O(n*log(n)) at worst for sorting.

>>> li = ['goose', 'duck', 'duck']
>>> def foo(li):
st = set(li)
mx = -1
for each in st:
temp = li.count(each):
if mx < temp:
mx = temp
h = each
return h
>>> foo(li)
'duck'

I needed to do this in a recent program. I'll admit it, I couldn't understand Alex's answer, so this is what I ended up with.
def mostPopular(l):
mpEl=None
mpIndex=0
mpCount=0
curEl=None
curCount=0
for i, el in sorted(enumerate(l), key=lambda x: (x[1], x[0]), reverse=True):
curCount=curCount+1 if el==curEl else 1
curEl=el
if curCount>mpCount \
or (curCount==mpCount and i<mpIndex):
mpEl=curEl
mpIndex=i
mpCount=curCount
return mpEl, mpCount, mpIndex
I timed it against Alex's solution and it's about 10-15% faster for short lists, but once you go over 100 elements or more (tested up to 200000) it's about 20% slower.

def most_frequent(List):
counter = 0
num = List[0]
for i in List:
curr_frequency = List.count(i)
if(curr_frequency> counter):
counter = curr_frequency
num = i
return num
List = [2, 1, 2, 2, 1, 3]
print(most_frequent(List))

Hi this is a very simple solution, with linear time complexity
L = ['goose', 'duck', 'duck']
def most_common(L):
current_winner = 0
max_repeated = None
for i in L:
amount_times = L.count(i)
if amount_times > current_winner:
current_winner = amount_times
max_repeated = i
return max_repeated
print(most_common(L))
"duck"
Where number, is the element in the list that repeats most of the time

numbers = [1, 3, 7, 4, 3, 0, 3, 6, 3]
max_repeat_num = max(numbers, key=numbers.count) *# which number most* frequently
max_repeat = numbers.count(max_repeat_num) *#how many times*
print(f" the number {max_repeat_num} is repeated{max_repeat} times")

def mostCommonElement(list):
count = {} // dict holder
max = 0 // keep track of the count by key
result = None // holder when count is greater than max
for i in list:
if i not in count:
count[i] = 1
else:
count[i] += 1
if count[i] > max:
max = count[i]
result = i
return result
mostCommonElement(["a","b","a","c"]) -> "a"

The most common element should be the one which is appearing more than N/2 times in the array where N being the len(array). The below technique will do it in O(n) time complexity, with just consuming O(1) auxiliary space.
from collections import Counter
def majorityElement(arr):
majority_elem = Counter(arr)
size = len(arr)
for key, val in majority_elem.items():
if val > size/2:
return key
return -1

def most_common(lst):
if max([lst.count(i)for i in lst]) == 1:
return False
else:
return max(set(lst), key=lst.count)

def popular(L):
C={}
for a in L:
C[a]=L.count(a)
for b in C.keys():
if C[b]==max(C.values()):
return b
L=[2,3,5,3,6,3,6,3,6,3,7,467,4,7,4]
print popular(L)