# Print Prime Numbers with SQL query

I am new to StackOverflow and have got stuck with a query to print prime numbers from 2 to 1000. I have used the below query need input if this is the most efficient way to code it.

``````WITH NUM AS (
SELECT LEVEL N
FROM DUAL CONNECT BY LEVEL <= 1000
)
SELECT LISTAGG(B.N,'-') WITHIN GROUP(ORDER BY B.N) AS PRIMES
FROM (
SELECT  N,
CASE WHEN EXISTS (
SELECT NULL
FROM NUM N_INNER
WHERE N_INNER .N > 1
AND N_INNER.N < NUM.N
AND MOD(NUM.N, N_INNER.N)=0
) THEN
'NO PRIME'
ELSE
'PRIME'
END IS_PRIME
FROM NUM
) B
WHERE B.IS_PRIME='PRIME'
AND B.N!=1;
``````

I know this question has been asked multiple times and I am requesting better solution if any. More over need input on how this works with MySQL/MS SQL/PostgreSQL.

Any help will make my understanding better.

• Could you elaborate what you want to achieve? The query that you presented is `Oracle` specific. Do you need equivalents in other RDBMS or better algorithm to get primes? May 15, 2016 at 5:44
• Yes, I need better algorithm if available. I am able to get the details for writing the query in other platforms. Dec 27, 2016 at 7:20

In PostgreSQL probably the most fastest query that prints prime numbers up to 1000 is:

``````SELECT regexp_split_to_table('2,3,5,7,11,13,17,19,23,29,31,37,41,43,47,53,59,61,67,71,73,79,83,89,97,101,103,107,109,113,127,131,137,139,149,151,157,163,167,173,179,181,191,193,197,199,211,223,227,229,233,239,241,251,257,263,269,271,277,281,283,293,307,311,313,317,331,337,347,349,353,359,367,373,379,383,389,397,401,409,419,421,431,433,439,443,449,457,461,463,467,479,487,491,499,503,509,521,523,541,547,557,563,569,571,577,587,593,599,601,607,613,617,619,631,641,643,647,653,659,661,673,677,683,691,701,709,719,727,733,739,743,751,757,761,769,773,787,797,809,811,821,823,827,829,839,853,857,859,863,877,881,883,887,907,911,919,929,937,941,947,953,967,971,977,983,991,997',E',')::int
AS x
;
``````

It took only 16 ms on my computer.

If you prefer SQL, then this works

``````WITH x AS (
SELECT * FROM generate_series( 2, 1000 ) x
)
SELECT x.x
FROM x
WHERE NOT EXISTS (
SELECT 1 FROM x y
WHERE x.x > y.x AND x.x % y.x = 0
)
;
``````

It's two times slower - 31 ms.

Ans an equivalent version for Oracle:

``````WITH x AS(
SELECT level+1 x
FROM dual
CONNECT BY LEVEL <= 999
)
SELECT x.x
FROM x
WHERE NOT EXISTS (
SELECT 1 FROM x y
WHERE x.x > y.x AND remainder( x.x, y.x) = 0
)
;
``````
• You can halve the time using only 2 and odds: `SELECT 2 x UNION ALL SELECT * FROM generate_series(3, 1000, 2) x` May 15, 2016 at 17:37

The most obvious improvement is that instead of checking from 1 to n you can check from 1 to the square root of n.

A second major optimization would be to use a temporary table to store the results and check them first. This way you can iterate incrementally from 1 to n, and only check the known primes from 1 to square root of n (recursively doing that until you have a list). If you go about things this way you would probably want to set up the prime detection in a function and then do the same with your number series generator.

That second one though means extending SQL and so I don't know if that fits your requirements.

For postgresql I would use `generate_series` go generate the list of numbers. I would then create functions which would then either store the list of primes in a temporary table or pass them back in and out in an ordered array and then couple them like that

Similar to kordirkos algorithm:

``````select 2 as p union all
select n.seq
from seq_3_to_1000_step_2 n
where not exists (
select 1
from seq_3_to_32_step_2 q
where q.seq < n.seq
and n.seq mod q.seq = 0
);
``````

Using LEFT JOIN:

``````select 2 as p union all
select n.seq
from seq_3_to_1000_step_2 n
left join seq_3_to_32_step_2 q
on  q.seq < n.seq
and n.seq mod q.seq = 0
where q.seq is null;
``````

MySQL

There are no sequence generating helpers in MySQL. So the sequence tables have to be created first:

``````drop temporary table if exists n;
create temporary table if not exists n engine=memory
select t2.c*100 + t1.c*10 + t0.c + 1 as seq from
(select 0 c union all select 1 c union all select 2 c union all select 3 c union all select 4 c union all select 5 c union all select 6 c union all select 7 c union all select 8 c union all select 9 c) t0,
(select 0 c union all select 1 c union all select 2 c union all select 3 c union all select 4 c union all select 5 c union all select 6 c union all select 7 c union all select 8 c union all select 9 c) t1,
(select 0 c union all select 1 c union all select 2 c union all select 3 c union all select 4 c union all select 5 c union all select 6 c union all select 7 c union all select 8 c union all select 9 c) t2
having seq > 2 and seq % 2 != 0;

drop temporary table if exists q;
create temporary table if not exists q engine=memory
select *
from n
where seq <= 32;
alter table q add primary key seq (seq);
``````

Now similar queries can be used:

``````select 2 as p union all
select n.seq
from n
where not exists (
select 1
from q
where q.seq < n.seq
and n.seq mod q.seq = 0
);

select 2 as p union all
select n.seq
from n
left join q
on  q.seq < n.seq
and n.seq mod q.seq = 0
where q.seq is null;
``````

sqlfiddle

Oracle and without inner select in getting part:

`````` with tmp(id)
as (
select level  id from dual connect by level <= 100
) select t1.id from tmp t1
JOIN tmp t2
on MOD(t1.id, t2.id) = 0
group by t1.ID
having count(t1.id) = 2
order by t1.ID
;
``````
``````/* Below is my solution */

/* Step 1: Get all the numbers till 1000 */
with tempa as
(
select level as Num
from dual
connect by level<=1000
),

/* Step 2: Get the Numbers for finding out the factors */

tempb as
(
select a.NUm,b.Num as Num_1
from tempa a , tempa b
where b.Num<=a.Num
),

/*Step 3:If a number has exactly 2 factors, then it is a prime number */

tempc as
(
select Num, sum(case when mod(num,num_1)=0 then 1 end) as Factor_COunt
from tempb
group by Num
)
select listagg(Num,'&') within group (order by Num)
from tempc
where Factor_COunt=2
;
``````

Tested on sqlite3

``````WITH nums(n) AS
(
SELECT 1
UNION ALL
SELECT n + 1 FROM nums WHERE n < 100
)

SELECT n
FROM (
SELECT n FROM nums
)
WHERE n NOT IN (
SELECT n
FROM nums
JOIN ( SELECT n AS n2 FROM nums )
WHERE n  <> 1
AND n2 <> 1
AND n  <> n2
AND n2 <  n
AND n % n2 = 0
ORDER BY n
)
AND n <> 1
``````

Tested on Vertica 8

``````WITH seq AS (
SELECT ROW_NUMBER() OVER() AS n
FROM (
SELECT 1
FROM (
SELECT date(0) + INTERVAL '1 second' AS i
UNION ALL
SELECT date(0) + INTERVAL '100 seconds' AS i
) _
TIMESERIES tm AS '1 second' OVER(ORDER BY i)
) _
)
SELECT n
FROM (SELECT n FROM seq) _
WHERE n NOT IN (
SELECT n FROM (
SELECT s1.n AS n, s2.n AS n2
FROM seq AS s1
CROSS JOIN seq AS s2
ORDER BY n, n2
) _
WHERE n  <> 1
AND n2 <> 1
AND n  <> n2
AND n2 <  n
AND n % n2 = 0
)
AND n <> 1
ORDER BY n
``````

This is what worked for me in the SQL server. I tried to reduce the order of my nested loops.

``````declare @var int
declare @i int
declare @result varchar (max)
set @var = 1
select @result = '2&3&5' --first few obvious prime numbers
while @var < 1000  --the first loop
begin
set @i = 3;
while @i <= @var/2  --the second loop which I attempted to reduce the order
begin
if @var%@i = 0
break;
if @i=@var/2
begin
set @result = @result + '&' + CAST(@var AS VARCHAR)
break;
end
else
set @i = @i + 1
end
set @var = @var + 1;
end
print @result
``````
``````SELECT LISTAGG(PRIME_NUMBER,'&') WITHIN GROUP (ORDER BY PRIME_NUMBER)
FROM
(
SELECT L PRIME_NUMBER FROM
(
SELECT LEVEL L FROM DUAL CONNECT BY LEVEL <= 1000 ),
(
SELECT LEVEL M FROM DUAL CONNECT BY LEVEL <= 1000
) WHERE M <= L
GROUP BY L
HAVING COUNT(CASE WHEN L/M = TRUNC(L/M) THEN 'Y' END
) = 2
ORDER BY L
);
``````

MySQL Code :

``````DECLARE
@i INT,
@a INT,
@count INT,
@p nvarchar(max)
SET @i = 1
WHILE (@i <= 1000)
BEGIN SET @count = 0
SET @a = 1
WHILE (@a <= @i)
BEGIN IF (@i % @a = 0) SET @count = @count + 1 SET @a = @a + 1
END IF (@count = 2) SET @P = CONCAT(@P,CONCAT(@i,'&')) SET @i = @i + 1
END
PRINT LEFT(@P, LEN(@P) - 1)
``````
• The OP is looking for a solution which is more efficient than the code they currently have in their question. Can you explain a bit more about what exactly your code is doing and where its improvements come from? Jun 27, 2017 at 15:02

The below code works to find prime numbers in SQL

Tested on SampleDB of local server

``````CREATE procedure sp_PrimeNumber(@number int)
as
begin
declare @i int
declare @j int
declare @isPrime int
set @isPrime=1
set @i=2
set @j=2
while(@i<=@number)
begin
while(@j<=@number)
begin
if((@i<>@j) and (@i%@j=0))
begin
set @isPrime=0
break
end
else
begin
set @j=@j+1
end
end
if(@isPrime=1)
begin
SELECT @i
end
set @isPrime=1
set @i=@i+1
set @j=2
end
end
``````

I have created the stored procedure which has a parameter @number to find the prime numbers up to that given number

In order to get the prime numbers we can execute the below stored procedure

``````EXECUTE sp_PrimeNumber 100  -- gives prime numbers up to 100
``````

If you are new to stored procedures and want to find the prime numbers in SQL we can use the below code

Tested on master DB

``````declare @i int
declare @j int
declare @isPrime int
set @isPrime=1
set @i=2
set @j=2
while(@i<=100)
begin
while(@j<=100)
begin
if((@i<>@j) and (@i%@j=0))
begin
set @isPrime=0
break
end
else
begin
set @j=@j+1
end
end
if(@isPrime=1)
begin
SELECT @i
end
set @isPrime=1
set @i=@i+1
set @j=2
end
``````

This code can give the prime numbers between 1 to 100. If we want to find more prime numbers edit the @i and @j arguments in the while loop and execute

• In SSMS we can execute the stored procedure and then execute it with the arguments required to get the required result Jul 20, 2018 at 12:31

# Simple query in PostgreSQL:

``````SELECT serA.el AS prime
FROM generate_series(2, 100) serA(el)
LEFT JOIN generate_series(2, 100) serB(el) ON serA.el >= POWER(serB.el, 2)
AND serA.el % serB.el = 0
WHERE serB.el IS NULL
``````

Enjoy! :)

``````For SQL Server We can use below CTE

SET NOCOUNT ON

;WITH Prim AS
(
SELECT 2 AS Value
UNION ALL
SELECT t.Value+1 AS VAlue
FROM Prim t
WHERE t.Value < 1000
)SELECT *
FROM Prim t
WHERE NOT EXISTS(   SELECT 1 FROM prim t2
WHERE t.Value % t2.Value = 0
AND t.Value != t2. Value)
OPTION (MAXRECURSION 0)
``````

One simple one can be like this

``````select level id1 from dual connect by level < 2001
minus
select distinct id1 from (select level id1 from dual connect by level < 46) t1 inner join (select level id2 from dual connect by level < 11) t2
on 1=1 where t1.id1> t2.id2 and mod(id1,id2)=0 and id2<>1
``````

Simplest method For SQL Server

``````DECLARE @range int = 1000, @x INT = 2, @y INT = 2

While (@y <= @range)
BEGIN
while (@x <= @y)
begin
IF ((@y%@x) =0)
BEGIN
IF (@x = @y)
PRINT @y
break
END
IF ((@y%@x)<>0)
set @x = @x+1
end
set @x = 2
set @y = @y+1
end
``````

# MySQL QUERY SOLUTION

I have solved this problem in mysql which is following:

``````SET @range = 1000;

SELECT GROUP_CONCAT(R2.n SEPARATOR '&')
FROM (
SELECT @ctr2:=@ctr2+1 "n"
FROM information_schema.tables R2IS1,
information_schema.tables R2IS2,
(SELECT @ctr2:=1) TI
WHERE @ctr2<@range
) R2
WHERE NOT EXISTS (
SELECT R1.n
FROM (
SELECT @ctr1:=@ctr1+1 "n"
FROM information_schema.tables R1IS1,
information_schema.tables R1IS2,
(SELECT @ctr1:=1) I1
WHERE @ctr1<@range
) R1
WHERE R2.n%R1.n=0 AND R2.n>R1.n
)
``````

Note: No. of information_schema.tables should be increased for more range e.g. if range is 100000 so set the info tables by checking yourself.

--Create Table prime_number_t create table prime_number_t ( integervalue_c integer not null primary key );

--Insert Data into table prime_number_t INSERT ALL into prime_number_t(integervalue_c) values (1) into prime_number_t(integervalue_c) values (2) into prime_number_t(integervalue_c) values (3) into prime_number_t(integervalue_c) values (4) into prime_number_t(integervalue_c) values (5) into prime_number_t(integervalue_c) values (6) into prime_number_t(integervalue_c) values (7) into prime_number_t(integervalue_c) values (8) into prime_number_t(integervalue_c) values (9) into prime_number_t(integervalue_c) values (10)
SELECT 1 FROM DUAL;

COMMIT;

--Write an SQL statement to determine which of the below numbers are prime numbers --same query works for REMAINDER function also instead of MOD function WITH cte_prime_number_t AS ( select integervalue_c from prime_number_t order by integervalue_c ), cte_maxval AS ( select max(integervalue_c) AS maxval FROM cte_prime_number_t ), cte_level AS ( select LEVEL+1 as lvl from dual, cte_maxval CONNECT BY LEVEL <= cte_maxval.maxval ) SELECT DISTINCT cpnt.integervalue_c as PrimeNumbers FROM cte_prime_number_t cpnt inner join cte_level cl on lvl <= (SELECT maxval FROM cte_maxval) WHERE NOT EXISTS ( SELECT 1 FROM cte_level cpn WHERE cpnt.integervalue_c > cpn.lvl AND mod(cpnt.integervalue_c,cpn.lvl) = 0 ) order by PrimeNumbers;

For MySQL 8 or above

``````/* create a table with one row and that starts with  2 ends at 1000*/

SET cte_max_recursion_depth = 1001; /* works for MySQL 8.0*/
;WITH RECURSIVE sequence AS (
SELECT 1 AS l
UNION ALL
SELECT l + 1 AS value
FROM sequence
WHERE sequence.l < 1000
),

/* create a caretesian product of a number to other numbers uptil this very number
so for example if there is a value 5 in a row then it creates these rows using the table below
(5,2), (5,3), (5,4), (5,5) */

J as (
SELECT (a.l) as m  , (b.l) as n
FROM sequence a, sequence b
WHERE b.l <= a.l)
,

/*take a row from column 1 then divide it with other column values but group by column 1 first,
note the completely divisible count*/
f as
( SELECT m , SUM(CASE WHEN mod(m,n) = 0 THEN 1  END) as fact
FROM  J
GROUP BY m
HAVING fact = 2
ORDER BY m ASC /*this view return numbers in descending order so had to use order by*/
)

/* this is for string formatting, converting a column to a string with separator &*/
SELECT group_concat(m SEPARATOR '&') FROM f;
``````

This worked for me in MySql:

``````select '2&3&5&7&11&13&17&19&23&29&31&37&41&43&47&53&59&61&67&71&73&79&83&89&97&101&103&107&109&113&127&131&137&139&149&151&157&163&167&173&179&181&191&193&197&199&211&223&227&229&233&239&241&251&257&263&269&271&277&281&283&293&307&311&313&317&331&337&347&349&353&359&367&373&379&383&389&397&401&409&419&421&431&433&439&443&449&457&461&463&467&479&487&491&499&503&509&521&523&541&547&557&563&569&571&577&587&593&599&601&607&613&617&619&631&641&643&647&653&659&661&673&677&683&691&701&709&719&727&733&739&743&751&757&761&769&773&787&797&809&811&821&823&827&829&839&853&857&859&863&877&881&883&887&907&911&919&929&937&941&947&953&967&971&977&983&991&997';
``````

Well, I know the above one is just hardcoded and you will be able to run the problem but it's not what we should go for as a programmer so here is my solution for oracle:

``````SELECT LISTAGG(L1,'&') WITHIN GROUP (ORDER BY L1) FROM (Select L1 FROM (SELECT LEVEL L1 FROM DUAL CONNECT BY LEVEL<=1000) Where L1 <> 1 MINUS select L1 from (SELECT LEVEL L1 FROM DUAL CONNECT BY LEVEL<=1000) A , (SELECT LEVEL L2 FROM DUAL CONNECT BY LEVEL<=1000) B Where L2<=L1 and MOD(L1,L2)=0 AND L1<>L2 AND L2<>1);
``````
• This doesn't exactly solve the problem as OP wants to create this using SQL code computationally and not by hard coding in a print statement. Feb 12, 2021 at 14:05

Worked in Oracle:

``````SELECT LISTAGG(a,'&')
WITHIN GROUP (ORDER BY a)
FROM(WITH x AS(
SELECT level+1 x
FROM dual
CONNECT BY LEVEL <= 999
)

SELECT x.x as a
FROM x
WHERE NOT EXISTS (
SELECT 1 FROM x y
WHERE x.x > y.x AND remainder( x.x, y.x) = 0
));
``````
``````SELECT  GROUP_CONCAT(distinct PRIME_NUMBER SEPARATOR '&')
FROM (SELECT @prime:=@prime + 1 AS PRIME_NUMBER
FROM information_schema.tables
CROSS JOIN (SELECT @prime:=1) r
WHERE @num <1000
) p
WHERE NOT EXISTS (
SELECT * FROM
(SELECT @divisor := @divisor + 1 AS DIVISOR FROM
information_schema.tables
CROSS JOIN (SELECT @divisor:=1) r1
WHERE @divisor <=1000
) d
WHERE MOD(PRIME_NUMBER, DIVISOR) = 0 AND PRIME_NUMBER != DIVISOR) ;
enter code here
``````

Explanation:

1. The two inner SELECTs (SELECT @prime and SELECT @divisor) create two lists. Both of them contain numbers from 1 to 1000. The first list is the "list of potential primes" and the second is the "list of divisors"

2. Then, we iterate over the list of the potential primes (the outer SELECT), and for each number from this list we look for divisors (SELECT * FROM clause) that can divide the number without a reminder and are not equal to the number (WHERE MOD... clause). If at least one such divisor exists, the number is not prime and is not selected (WHERE NOT EXISTS... clause).