# Print series of prime numbers in python

I was having issues in printing a series of prime numbers from one to hundred. I can't figure our what's wrong with my code.

Here's what I wrote; it prints all the odd numbers instead of primes:

``````for num in range(1, 101):
for i in range(2, num):
if num % i == 0:
break
else:
print(num)
break
``````

You need to check all numbers from 2 to n-1 (to sqrt(n) actually, but ok, let it be n). If `n` is divisible by any of the numbers, it is not prime. If a number is prime, print it.

``````for num in range(2,101):
prime = True
for i in range(2,num):
if (num%i==0):
prime = False
if prime:
print (num)
``````

You can write the same much shorter and more pythonic:

``````for num in range(2,101):
if all(num%i!=0 for i in range(2,num)):
print (num)
``````

As I've said already, it would be better to check divisors not from 2 to n-1, but from 2 to sqrt(n):

``````import math
for num in range(2,101):
if all(num%i!=0 for i in range(2,int(math.sqrt(num))+1)):
print (num)
``````

For small numbers like 101 it doesn't matter, but for 10**8 the difference will be really big.

You can improve it a little more by incrementing the range you check by 2, and thereby only checking odd numbers. Like so:

``````import math
print 2
for num in range(3,101,2):
if all(num%i!=0 for i in range(2,int(math.sqrt(num))+1)):
print (num)
``````

Edited:

As in the first loop odd numbers are selected, in the second loop no need to check with even numbers, so 'i' value can be start with 3 and skipped by 2.

``````import math
print 2
for num in range(3,101,2):
if all(num%i!=0 for i in range(3,int(math.sqrt(num))+1, 2)):
print (num)
``````
• Great job, but why do you ignore the number 1 ? One is not considered a prime number. Kindly see this article primes.utm.edu/notes/faq/one.html Jul 4, 2015 at 18:38
• Change your `range(1,101)` to `range(2,101)` and the code will be perfect. Let's not forget 1 is not a prime. Nov 1, 2017 at 13:24
• No need to `import math`. Just use `**.5`
– Zaz
Nov 7, 2018 at 0:15
• Additionally, computing the square root is expensive. It would be better to compare squares. Apr 24, 2021 at 9:55
• You can make this faster by not computing all factors for each "num". If we look at the "non pythonic" code and put `break` right after `prime = False`, that loop will discontinue as soon as a single factor is found. In my experiments makes the code twice as fast. Jul 3, 2022 at 21:17

I'm a proponent of not assuming the best solution and testing it. Below are some modifications I did to create simple classes of examples by both @igor-chubin and @user448810. First off let me say it's all great information, thank you guys. But I have to acknowledge @user448810 for his clever solution, which turns out to be the fastest by far (of those I tested). So kudos to you, sir! In all examples I use a values of 1 million (1,000,000) as n.

Please feel free to try the code out.

Good luck!

Method 1 as described by Igor Chubin:

``````def primes_method1(n):
out = list()
for num in range(1, n+1):
prime = True
for i in range(2, num):
if (num % i == 0):
prime = False
if prime:
out.append(num)
return out
``````

Benchmark: Over 272+ seconds

Method 2 as described by Igor Chubin:

``````def primes_method2(n):
out = list()
for num in range(1, n+1):
if all(num % i != 0 for i in range(2, num)):
out.append(num)
return out
``````

Benchmark: 73.3420000076 seconds

Method 3 as described by Igor Chubin:

``````def primes_method3(n):
out = list()
for num in range(1, n+1):
if all(num % i != 0 for i in range(2, int(num**.5 ) + 1)):
out.append(num)
return out
``````

Benchmark: 11.3580000401 seconds

Method 4 as described by Igor Chubin:

``````def primes_method4(n):
out = list()
out.append(2)
for num in range(3, n+1, 2):
if all(num % i != 0 for i in range(2, int(num**.5 ) + 1)):
out.append(num)
return out
``````

Benchmark: 8.7009999752 seconds

Method 5 as described by user448810 (which I thought was quite clever):

``````def primes_method5(n):
out = list()
sieve = [True] * (n+1)
for p in range(2, n+1):
if (sieve[p]):
out.append(p)
for i in range(p, n+1, p):
sieve[i] = False
return out
``````

Benchmark: 1.12000012398 seconds

Notes: Solution 5 listed above (as proposed by user448810) turned out to be the fastest and honestly quiet creative and clever. I love it. Thanks guys!!

EDIT: Oh, and by the way, I didn't feel there was any need to import the math library for the square root of a value as the equivalent is just (n**.5). Otherwise I didn't edit much other then make the values get stored in and output array to be returned by the class. Also, it would probably be a bit more efficient to store the results to a file than verbose and could save a lot on memory if it was just one at a time but would cost a little bit more time due to disk writes. I think there is always room for improvement though. So hopefully the code makes sense guys.

2021 EDIT: I know it's been a really long time but I was going back through my Stackoverflow after linking it to my Codewars account and saw my recently accumulated points, which which was linked to this post. Something I read in the original poster caught my eye for @user448810, so I decided to do a slight modification mentioned in the original post by filtering out odd values before appending the output array. The results was much better performance for both the optimization as well as latest version of Python 3.8 with a result of 0.723 seconds (prior code) vs 0.504 seconds using 1,000,000 for n.

``````def primes_method5(n):
out = list()
sieve = [True] * (n+1)
for p in range(2, n+1):
if (sieve[p] and sieve[p]%2==1):
out.append(p)
for i in range(p, n+1, p):
sieve[i] = False
return out
``````

Nearly five years later, I might know a bit more but I still just love Python, and it's kind of crazy to think it's been that long. The post honestly feels like it was made a short time ago and at the time I had only been using python about a year I think. And it still seems relevant. Crazy. Good times.

• I'm curious about the two expressions in the if statement; don't they do the same thing? True % 2 is always equal to 1, so isn't that checking for the bool twice? Feb 12, 2023 at 9:20
• My mistake. You are correct, I believe I thought I was checking if the value existed, not returning the value which in both cases would be the bool. For posterity sake though, I'm not sure it's worth updating the incorrect code but good catch, and the line could then just be be "if sieve[p]:" as above (so the real optimization is then just Python itself but also obviously dependent on the system itself). May 2, 2023 at 19:30
• As it is known beforehand that every second iteration should be skipped and checking the condition every iteration is not very fast I was able to improve runtime further by initializing `out = list([2])` and changing the loop to `for p in range(3, n+1, 2):`. For n=10^6 and 1000 iterations i got a mean runtime of 0.087s when checking every iteration compared to 0.066s using increments of 2. So around 24% faster. I got a result of ~25% improvement for n=10**8 in a single iteration so this seems like a meaningful improvement.
– xtr
Jul 14, 2023 at 10:42

Instead of trial division, a better approach, invented by the Greek mathematician Eratosthenes over two thousand years ago, is to sieve by repeatedly casting out multiples of primes.

Begin by making a list of all numbers from 2 to the maximum desired prime n. Then repeatedly take the smallest uncrossed number and cross out all of its multiples; the numbers that remain uncrossed are prime.

For example, consider the numbers less than 30. Initially, 2 is identified as prime, then 4, 6, 8, 10, 12, 14, 16, 18, 20, 22, 24, 26, 28 and 30 are crossed out. Next 3 is identified as prime, then 6, 9, 12, 15, 18, 21, 24, 27 and 30 are crossed out. The next prime is 5, so 10, 15, 20, 25 and 30 are crossed out. And so on. The numbers that remain are prime: 2, 3, 5, 7, 11, 13, 17, 19, 23, and 29.

``````def primes(n):
sieve = [True] * (n+1)
for p in range(2, n+1):
if (sieve[p]):
print p
for i in range(p, n+1, p):
sieve[i] = False
``````

An optimized version of the sieve handles 2 separately and sieves only odd numbers. Also, since all composites less than the square of the current prime are crossed out by smaller primes, the inner loop can start at p^2 instead of p and the outer loop can stop at the square root of n. I'll leave the optimized version for you to work on.

• the sieve has pretty bad performance, I doubt it would be faster than trying a division, especially if you only try until the square root. Jun 19, 2015 at 10:51
• @hochl you're mistaken; see primesieve.org for the counterexample. Jun 24, 2015 at 22:31
• Wow, didn't know that -- but's its incredibly complex and uses multiple cores ... O.o but interesting -- thanks! :) Jun 25, 2015 at 0:53
• @hochl: It doesn't have to be complex. Using the optimized version of the sieve that I discussed above, it takes a third of a second to compute the primes to a million. Using the corresponding trial division takes over twenty times longer. Code at ideone.com/5U2Wns. The code at primesieve.org is more complicated, but much faster still. Jun 25, 2015 at 18:05
• Nice! The memory requirement is huge, but if you start computing primes that is maybe not an issue. My prime generator below performs way better than the simple trial division, but still is approx. 6 times slower (times for 2.000.000: sieve 0.5, simple iterative 13.2, generator 3.76). Jun 25, 2015 at 21:32

`break` ends the loop that it is currently in. So, you are only ever checking if it divisible by 2, giving you all odd numbers.

``````for num in range(2,101):
for i in range(2,num):
if (num%i==0):
break
else:
print(num)
``````

that being said, there are much better ways to find primes in python than this.

``````for num in range(2,101):
if is_prime(num):
print(num)

def is_prime(n):
for i in range(2, int(math.sqrt(n)) + 1):
if n % i == 0:
return False
return True
``````
• here is a page from the python doc describing `break`/`continue`, with an example of printing primes! docs.python.org/tutorial/controlflow.html (section 4.4) Jul 23, 2012 at 20:26
• No, you are wrong, of course. `continue` will not help here. Please write the solution wit `continue` if you think you are right Jul 23, 2012 at 20:32

Igor Chubin's answer can be improved. When testing if X is prime, the algorithm doesn't have to check every number up to the square root of X, it only has to check the prime numbers up to the sqrt(X). Thus, it can be more efficient if it refers to the list of prime numbers as it is creating it. The function below outputs a list of all primes under b, which is convenient as a list for several reasons (e.g. when you want to know the number of primes < b). By only checking the primes, it saves time at higher numbers (compare at around 10,000; the difference is stark).

``````from math import sqrt
def lp(b)
primes = [2]
for c in range(3,b):
e = round(sqrt(c)) + 1
for d in primes:
if d <= e and c%d == 0:
break
else:
primes.extend([c])
return primes
``````
• that's inefficient: for a candidate that is prime this will visit all the previous primes (and test them for `d <= e`). The loop should be broken from always, after the sqrt has been reached. Aug 4, 2013 at 18:11
• or remove the sqrt completely since it is an expensive operation and compare the squares, i.e. `for d in primes: if d*d > c: ...` Jun 19, 2015 at 10:34

The best way to solve the above problem would be to use the "Miller Rabin Primality Test" algorithm. It uses a probabilistic approach to find if a number is prime or not. And it is by-far the most efficient algorithm I've come across for the same.

The python implementation of the same is demonstrated below:

``````def miller_rabin(n, k):

# Implementation uses the Miller-Rabin Primality Test
# The optimal number of rounds for this test is 40
# See http://stackoverflow.com/questions/6325576/how-many-iterations-of-rabin-miller-should-i-use-for-cryptographic-safe-primes
# for justification

# If number is even, it's a composite number

if n == 2:
return True

if n % 2 == 0:
return False

r, s = 0, n - 1
while s % 2 == 0:
r += 1
s //= 2
for _ in xrange(k):
a = random.randrange(2, n - 1)
x = pow(a, s, n)
if x == 1 or x == n - 1:
continue
for _ in xrange(r - 1):
x = pow(x, 2, n)
if x == n - 1:
break
else:
return False
return True
``````

A Python Program function module that returns the 1'st N prime numbers:

``````def get_primes(count):
"""
Return the 1st count prime integers.
"""
result = []
x=2
while len(result) in range(count):
i=2
flag=0
for i in range(2,x):
if x%i == 0:
flag+=1
break
i=i+1
if flag == 0:
result.append(x)
x+=1
pass
return result
``````

A simpler and more efficient way of solving this is storing all prime numbers found previously and checking if the next number is a multiple of any of the smaller primes.

``````n = 1000
primes = [2]

for i in range(3, n, 2):
if not any(i % prime == 0 for prime in primes):
primes.append(i)

print(primes)
``````

Note that `any` is a short circuit function, in other words, it will break the loop as soon as a truthy value is found.

• I'm not sure why but I tested the runtime of this implementation and it gave me runtimes hundreds of times slower than the solution posted by jacktrader. While it is possible that I made a mistake somewhere in my testing I would recommend to tread lighlty when using this implementation.
– xtr
Jul 14, 2023 at 11:21

we can make a list of prime numbers using sympy library

``````import sympy
lower=int(input("lower value:"))          #let it be 30
upper=int(input("upper value:"))          #let it be 60
l=list(sympy.primerange(lower,upper+1))   #[31,37,41,43,47,53,59]
print(l)
``````

My way of listing primes to an entry number without too much hassle is using the property that you can get any number that is not a prime with the product of primes.

Therefore, if you divide the entry number with all primes below it, and it is not evenly divisible by any of them, you know that you have a prime.

Of course there are still faster ways of getting the primes, but this one already performs quite well, especially because you are not dividing the entry number by any number, but quite only the primes all the way to that number.

With this code I managed on my computer to list all primes up to 100 000 in less than 4 seconds.

``````import time as t

start = t.clock()

primes = [2,3,5,7]

for num in xrange(3,100000,2):
if all(num%x != 0 for x in primes):
primes.append(num)

print primes
print t.clock() - start
print sum(primes)
``````

Here's a simple and intuitive version of checking whether it's a prime in a RECURSIVE function! :) (I did it as a homework assignment for an MIT class) In python it runs very fast until 1900. IF you try more than 1900, you'll get an interesting error :) (Would u like to check how many numbers your computer can manage?)

``````def is_prime(n, div=2):

if div> n/2.0: return True

if n% div == 0:
return False
else:
div+=1
return is_prime(n,div)

#The program:
until = 1000
for i in range(until):
if is_prime(i):
print i
``````

Of course... if you like recursive functions, this small code can be upgraded with a dictionary to seriously increase its performance, and avoid that funny error. Here's a simple Level 1 upgrade with a MEMORY integration:

``````import datetime
def is_prime(n, div=2):
global primelist
if div> n/2.0: return True
if div < primelist[0]:
div = primelist[0]
for x in primelist:
if x ==0 or x==1: continue
if n % x == 0:
return False
if n% div == 0:
return False
else:
div+=1
return is_prime(n,div)

now = datetime.datetime.now()
print 'time and date:',now
until = 100000
primelist=[]
for i in range(until):
if is_prime(i):
primelist.insert(0,i)
print "There are", len(primelist),"prime numbers, until", until
print primelist[0:100], "..."

finish = datetime.datetime.now()
print "It took your computer", finish - now , " to calculate it"
``````

Here are the resuls, where I printed the last 100 prime numbers found.

time and date: 2013-10-15 13:32:11.674448

There are 9594 prime numbers, until 100000

[99991, 99989, 99971, 99961, 99929, 99923, 99907, 99901, 99881, 99877, 99871, 99859, 99839, 99833, 99829, 99823, 99817, 99809, 99793, 99787, 99767, 99761, 99733, 99721, 99719, 99713, 99709, 99707, 99689, 99679, 99667, 99661, 99643, 99623, 99611, 99607, 99581, 99577, 99571, 99563, 99559, 99551, 99529, 99527, 99523, 99497, 99487, 99469, 99439, 99431, 99409, 99401, 99397, 99391, 99377, 99371, 99367, 99349, 99347, 99317, 99289, 99277, 99259, 99257, 99251, 99241, 99233, 99223, 99191, 99181, 99173, 99149, 99139, 99137, 99133, 99131, 99119, 99109, 99103, 99089, 99083, 99079, 99053, 99041, 99023, 99017, 99013, 98999, 98993, 98981, 98963, 98953, 98947, 98939, 98929, 98927, 98911, 98909, 98899, 98897] ...

It took your computer 0:00:40.871083 to calculate it

So It took 40 seconds for my i7 laptop to calculate it. :)

• there are 9592 primes below 100000 and it took my old slow laptop 0.01 seconds to calculate it. without looking into it, maybe your algorithm isn't optimal. Sep 8, 2014 at 7:19
• @WillNess of course not! If you want a more efficient algorithm check: PG7.8 from en.wikibooks.org/wiki/… My algorithm is Fun cause anyone can GET it why it works! :) Sep 10, 2014 at 19:29
• I've seen that page, and it is... not good. its algorithm is not efficient. It does reinvent the wheel optimization, but uses it with trial division, instead of the sieve of Eratosthenes, which is much, much, much faster. -- about your first code: with one small correction it runs in 1.3 sec on Ideone (which is about 3x slower than your i7 - so, a 100x speedup!), and converted to loop instead of recursion - 0.77 sec. You just need to overwrite three characters in your code. :) Sep 10, 2014 at 22:51
• Recursive functions are fun though... :) i will think how to improve it a lil bit Sep 11, 2014 at 11:35
• I'll give you another hint: all three characters are together, one next to the other. Just type something new over them, replacing them with three new characters. Sep 11, 2014 at 12:03
``````# computes first n prime numbers
def primes(n=1):
from math import sqrt
count = 1
plist = [2]
c = 3
if n <= 0 :
return "Error : integer n not >= 0"
while (count <= n - 1):    # n - 1 since 2 is already in plist
pivot = int(sqrt(c))
for i in plist:
if i > pivot :    # check for primae factors 'till sqrt c
count+= 1
plist.append(c)
break
elif c % i == 0 :
break    # not prime, no need to iterate anymore
else :
continue
c += 2    # skipping even numbers
return plist
``````

You are terminating the loop too early. After you have tested all possibilities in the body of the for loop, and not breaking, then the number is prime. As one is not prime you have to start at 2:

``````for num in xrange(2, 101):
for i in range(2,num):
if not num % i:
break
else:
print num
``````

In a faster solution you only try to divide by primes that are smaller or equal to the root of the number you are testing. This can be achieved by remembering all primes you have already found. Additionally, you only have to test odd numbers (except 2). You can put the resulting algorithm into a generator so you can use it for storing primes in a container or simply printing them out:

``````def primes(limit):
if limit > 1:
primes_found = [(2, 4)]
yield 2
for n in xrange(3, limit + 1, 2):
for p, ps in primes_found:
if ps > n:
primes_found.append((n, n * n))
yield n
break
else:
if not n % p:
break

for i in primes(101):
print i
``````

As you can see there is no need to calculate the square root, it is faster to store the square for each prime number and compare each divisor with this number.

``````prime=[2]+[num for num in xrange(3,m+1,2) if all(num%i!=0 for i in range(2,int(math.sqrt(num))+1))]
``````

Prime numbers up to 1000000

``````root@nfs:/pywork# time python prime.py
``````

78498

real 0m6.600s

user 0m6.532s

sys 0m0.036s

Adding to the accepted answer, further optimization can be achieved by using a list to store primes and printing them after generation.

``````import math
Primes_Upto = 101
Primes = [2]
for num in range(3,Primes_Upto,2):
if all(num%i!=0 for i in Primes):
Primes.append(num)
for i in Primes:
print i
``````

Here is the simplest logic for beginners to get prime numbers:

``````p=[]
for n in range(2,50):
for k in range(2,50):
if n%k ==0 and n !=k:
break
else:
for t in p:
if  n%t ==0:
break
else:
p.append(n)

print p
``````
``````n = int(input())
is_prime = lambda n: all( n%i != 0 for i in range(2, int(n**.5)+1) )
def Prime_series(n):
for i in range(2,n):
if is_prime(i) == True:
print(i,end = " ")
else:
pass
Prime_series(n)
``````

Here is a simplified answer using lambda function.

``````def function(number):
for j in range(2, number+1):
if all(j % i != 0 for i in range(2, j)):
print(j)

function(13)
``````
• While this code may provide a solution to the question, it's better to add context as to why/how it works. This can help future users learn and eventually apply that knowledge to their own code. You are also likely to have positive feedback/upvotes from users, when the code is explained. Feb 27, 2021 at 12:01
``````for i in range(1, 100):
for j in range(2, i):
if i % j == 0:
break
else:
print(i)
``````
• Can you please edit your code with an explanation of how it works? Jul 13, 2021 at 8:17

Print n prime numbers using python:

``````num = input('get the value:')
for i in range(2,num+1):
count = 0
for j in range(2,i):
if i%j != 0:
count += 1
if count == i-2:
print i,
``````
``````def prime_number(a):
yes=[]
for i in range (2,100):
if (i==2 or i==3 or i==5 or i==7) or (i%2!=0 and i%3!=0 and i%5!=0 and i%7!=0 and i%(i**(float(0.5)))!=0):
yes=yes+[i]
print (yes)
``````
• `yes=[2,3,5,7]; for i in range (8,100): if (i%2!=0 and ... and i%7!=0): yes+=[i]`. Sep 8, 2014 at 7:05
``````min=int(input("min:"))
max=int(input("max:"))
for num in range(min,max):
for x in range(2,num):
if(num%x==0 and num!=1):
break
else:
print(num,"is prime")
break
``````

This is a sample program I wrote to check if a number is prime or not.

``````def is_prime(x):
y=0
if x<=1:
return False
elif x == 2:
return True
elif x%2==0:
return False
else:
root = int(x**.5)+2
for i in xrange (2,root):
if x%i==0:
return False
y=1
if y==0:
return True
``````
``````n = int(raw_input('Enter the integer range to find prime no :'))
p = 2
while p<n:
i = p
cnt = 0
while i>1:
if p%i == 0:
cnt+=1
i-=1
if cnt == 1:
print "%s is Prime Number"%p
else:
print "%s is Not Prime Number"%p
p+=1
``````

Using filter function.

``````l=range(1,101)
for i in range(2,10): # for i in range(x,y), here y should be around or <= sqrt(101)
l = filter(lambda x: x==i or x%i, l)

print l
``````
``````for num in range(1,101):
prime = True
for i in range(2,num/2):
if (num%i==0):
prime = False
if prime:
print num
``````
``````f=0
sum=0
for i in range(1,101):
for j in range(1,i+1):
if(i%j==0):
f=f+1
if(f==2):
sum=sum+i
print i
f=0
print sum
``````

The fastest & best implementation of omitting primes:

``````def PrimeRanges2(a, b):
arr = range(a, b+1)
up = int(math.sqrt(b)) + 1
for d in range(2, up):
arr = omit_multi(arr, d)
``````

Here is a different approach that trades space for faster search time. This may be fastest so.

``````import math

def primes(n):
if n < 2:
return []
numbers = [0]*(n+1)
primes = [2]
# Mark all odd numbers as maybe prime, leave evens marked composite.
for i in xrange(3, n+1, 2):
numbers[i] = 1

sqn = int(math.sqrt(n))
# Starting with 3, look at each odd number.
for i in xrange(3, len(numbers), 2):
# Skip if composite.
if numbers[i] == 0:
continue
# Number is prime.  Would have been marked as composite if there were
# any smaller prime factors already examined.
primes.append(i)
if i > sqn:
# All remaining odd numbers not marked composite must be prime.
primes.extend([i for i in xrange(i+2, len(numbers), 2)
if numbers[i]])
break
# Mark all multiples of the prime as composite.  Check odd multiples.
for r in xrange(i*i, len(numbers), i*2):
numbers[r] = 0

return primes

n = 1000000
p = primes(n)
print "Found", len(p), "primes <=", n
``````

Adding my own version, just to show some itertools tricks v2.7:

``````import itertools

def Primes():
primes = []
a = 2
while True:
if all(itertools.imap(lambda p : a % p, primes)):
yield a
primes.append(a)
a += 1

# Print the first 100 primes
for _, p in itertools.izip(xrange(100), Primes()):
print p
``````