# How does this print “hello world”?

I discovered this oddity:

``````for (long l = 4946144450195624l; l > 0; l >>= 5)
System.out.print((char) (((l & 31 | 64) % 95) + 32));
``````

Output:

``````hello world
``````

How does this work?

-
I mean you can figure this out yourself. – Sotirios Delimanolis Dec 21 '13 at 14:43
Yes. I admit... I'm fishing for hats :) – Bohemian Dec 21 '13 at 14:44
I think I've seen this question asked here before.. – Zavior Dec 21 '13 at 14:44
@Oli There should be a hat for that. – Sotirios Delimanolis Dec 21 '13 at 15:00
Questions like this, that don't improve the database but exist solely as clickbait, are a sure-fire way to get the Hat game cancelled in the future. Please don't ruin the game by whoring for it. – Blazemonger Dec 25 '13 at 2:11

The number `4946144450195624` fits 64 bits, its binary representation is:

`````` 10001100100100111110111111110111101100011000010101000
``````

The program decodes a character for every 5-bits group, from right to left

`````` 00100|01100|10010|01111|10111|11111|01111|01100|01100|00101|01000
d  |  l  |  r  |  o  |  w  |     |  o  |  l  |  l  |  e  |  h
``````

# 5-bit codification

For 5 bits, it is posible to represent 2⁵ = 32 characters. English alphabet contains 26 letters, this leaves room for 32 - 26 = 6 symbols apart from letters. With this codification scheme you can have all 26 (one case) english letters and 6 symbols (being space among them).

# Algorithm description

The `>>= 5` in the for-loop jumps from group to group, then the 5-bits group gets isolated ANDing the number with the mask `31₁₀ = 11111₂` in the sentence `l & 31`

Now the code maps the 5-bit value to its corresponding 7-bit ascii character. This is the tricky part, check the binary representations for the lowercase alphabet letters in the following table:

``````  ascii   |     ascii     |    ascii     |    algorithm
character | decimal value | binary value | 5-bit codification
--------------------------------------------------------------
space   |       32      |   0100000    |      11111
a     |       97      |   1100001    |      00001
b     |       98      |   1100010    |      00010
c     |       99      |   1100011    |      00011
d     |      100      |   1100100    |      00100
e     |      101      |   1100101    |      00101
f     |      102      |   1100110    |      00110
g     |      103      |   1100111    |      00111
h     |      104      |   1101000    |      01000
i     |      105      |   1101001    |      01001
j     |      106      |   1101010    |      01010
k     |      107      |   1101011    |      01011
l     |      108      |   1101100    |      01100
m     |      109      |   1101101    |      01101
n     |      110      |   1101110    |      01110
o     |      111      |   1101111    |      01111
p     |      112      |   1110000    |      10000
q     |      113      |   1110001    |      10001
r     |      114      |   1110010    |      10010
s     |      115      |   1110011    |      10011
t     |      116      |   1110100    |      10100
u     |      117      |   1110101    |      10101
v     |      118      |   1110110    |      10110
w     |      119      |   1110111    |      10111
x     |      120      |   1111000    |      11000
y     |      121      |   1111001    |      11001
z     |      122      |   1111010    |      11010
``````

Here you can see that the ascii characters we want to map begin with the 7th and 6th bit set (`11xxxxx₂`) (except for space, which only has the 6th bit on), you could `OR` the 5-bit codification with `96` (`96₁₀ = 1100000₂`) and that should be enough to do the mapping, but that wouldn't work for space (darn space!)

Now we know that special care has to be taken to process space at the same time as the other characters. To achieve this, the code turns the 7th bit on (but not the 6th) on the extracted 5-bit group with an OR 64 `64₁₀ = 1000000₂` (`l & 31 | 64`).

So far the 5-bit group is of the form: `10xxxxx₂` (space would be `1011111₂ = 95₁₀`). If we can map space to `0` unaffecting other values, then we can turn the 6th bit on and that should be all. Here is what the `mod 95` part comes to play, space is `1011111₂ = 95₁₀`, using the mod operation `(l & 31 | 64) % 95)` only space goes back to `0`, and after this, the code turns the 6th bit on by adding `32₁₀ = 100000₂` to the previous result, `((l & 31 | 64) % 95) + 32)` transforming the 5-bit value into a valid ascii character

``````isolates 5 bits --+          +---- takes 'space' (and only 'space') back to 0
|          |
v          v
(l & 31 | 64) % 95) + 32
^           ^
turns the       |           |
7th bit on ------+           +--- turns the 6th bit on
``````

The following code does the inverse process, given a lowercase string (max 12 chars), returns the 64 bit long value that could be used with the OP's code:

``````public class D {
public static void main(String... args) {
String v = "hello test";
int len = Math.min(12, v.length());
long res = 0L;
for (int i = 0; i < len; i++) {
long c = (long) v.charAt(i) & 31;
res |= ((((31 - c) / 31) * 31) | c) << 5 * i;
}
System.out.println(res);
}
}
``````
-
I encoded it into an int, 3 bits per char. – גלעד ברקן Dec 24 '13 at 21:44
This answer leaves no mystery. Rather, it does your thinking for you. – user978923 Dec 25 '13 at 10:29
the answer is even harder than the question :D – Yazan Dec 31 '14 at 10:13
Explanation is much cleaner :) – Prashant Jan 9 '15 at 6:28

Adding some value to above answers. Following groovy script prints intermediate values.

``````String getBits(long l) {
}

for (long l = 4946144450195624l; l > 0; l >>= 5){
println ''
print '|'+ getBits((l & 31 ))
print '|'+ getBits(((l & 31 | 64)))
print '|'+ getBits(((l & 31 | 64)  % 95))
print '|'+ getBits(((l & 31 | 64)  % 95 + 32))

print '|';
System.out.print((char) (((l & 31 | 64) % 95) + 32));
}
``````

Here it is

``````4946144450195624|00001000|01001000|01001000|01101000|h
0154567014068613|00000101|01000101|01000101|01100101|e
0004830219189644|00001100|01001100|01001100|01101100|l
0000150944349676|00001100|01001100|01001100|01101100|l
0000004717010927|00001111|01001111|01001111|01101111|o
0000000147406591|00011111|01011111|00000000|00100000|
0000000004606455|00010111|01010111|01010111|01110111|w
0000000000143951|00001111|01001111|01001111|01101111|o
0000000000004498|00010010|01010010|01010010|01110010|r
0000000000000140|00001100|01001100|01001100|01101100|l
0000000000000004|00000100|01000100|01000100|01100100|d
``````
-

Interesting!

Standard ASCII characters which are visible are in range of 32 to 127.

That's why you see 32, and 95 (127 - 32) there.

In fact each character is mapped to 5 bits here, (you can find what is 5 bit combination for each character), and then all bits are concatenated to form a large number.

Positive longs are 63 bit numbers, large enough to hold encrypted form of 12 characters. So it is large enough to hold `Hello word`, but for larger texts you shall use larger numbers, or even a BigInteger.

In an application we wanted to transfer visible English Characters, Persian Characters and Symbols via SMS. As you see there are `32 (number of Persian chars) + 95 (number of English characters and standard visible symbols) = 127` possible values, which can be represented with 7 bits.

We converted each UTF-8 (16 bit) character to 7 bits, and gain more than 56% compression ratio. So we could send texts with twice length in the same number of SMSs. (It is somehow the same thing happened here).

-
There's a lot more going on in OP's code. For instance, this doesn't really explain what the `| 64` is doing. – Ted Hopp Dec 24 '13 at 21:43
@Amir: actually 95 is there because you need to get a space character. – Bhathiya Dec 29 '13 at 21:10

You are getting a result which happens to be `char` representation of below values

``````104 -> h
101 -> e
108 -> l
108 -> l
111 -> o
32  -> (space)
119 -> w
111 -> o
114 -> r
108 -> l
100 -> d
``````
-

You've encoded characters as 5-bit values and packed 11 of them into a 64 bit long.

`(packedValues >> 5*i) & 31` is the i-th encoded value with a range 0-31.

The hard part, as you say, is encoding the space. The lower case english letters occupy the contiguous range 97-122 in Unicode (and ascii, and most other encodings), but the space is 32.

To overcome this, you used some arithmetic. `((x+64)%95)+32` is almost the same as `x + 96` (note how bitwise OR is equivalent to addition, in this case), but when x=31, we get `32`.

-

It prints "hello world" for a similar reason this does:

``````for (int k=1587463874; k>0; k>>=3)
System.out.print((char) (100 + Math.pow(2,2*(((k&7^1)-1)>>3 + 1) + (k&7&3)) + 10*((k&7)>>2) + (((k&7)-7)>>3) + 1 - ((-(k&7^5)>>3) + 1)*80));
``````

but for a somewhat different reason than this:

``````for (int k=2011378; k>0; k>>=2)
System.out.print((char) (110 + Math.pow(2,2*(((k^1)-1)>>21 + 1) + (k&3)) - ((k&8192)/8192 + 7.9*(-(k^1964)>>21) - .1*(-((k&35)^35)>>21) + .3*(-((k&120)^120)>>21) + (-((k|7)^7)>>21) + 9.1)*10));
``````
-
You should explain what you're doing, instead of posting another riddle – Aleksandr Dubinsky Dec 25 '13 at 20:30
I suggest that you invest some effort in finding a site (perhaps some Beta StackExchange?) where contributing fun riddles is welcome. Stack Overflow is a Q&A site with a strictly enforced focus. – Marko Topolnik Apr 30 '14 at 12:33
I would, too, but SO is such a world to an unusually great extent. Sure there are exceptions even here, but they are not welcome. – Marko Topolnik May 1 '14 at 5:53
Another 15 shared Alexandr's sentiment. And you are right in pointing out that the question itself is inappropriate for SO, as commented below it. – Marko Topolnik May 3 '14 at 10:46
@MarkoTopolnik I don't think a critical comment means "opposing" the answer. I think it means hoping the answer were different in some way. And I disagree about there being "no context." I think there is. – גלעד ברקן May 5 '14 at 15:49

Without an `Oracle` tag, it was difficult to see this question. Active bounty brought me here. I wish the question had other relevant technology tags too :-(

I mostly work with `Oracle database`, so I would use some `Oracle` knowledge to interpret and explain :-)

Let's convert the number `4946144450195624` into `binary`. For that I use a small `function` called dec2bin i.e. decimal-to-binary.

``````SQL> CREATE OR REPLACE FUNCTION dec2bin (N in number) RETURN varchar2 IS
2    binval varchar2(64);
3    N2     number := N;
4  BEGIN
5    while ( N2 > 0 ) loop
6       binval := mod(N2, 2) || binval;
7       N2 := trunc( N2 / 2 );
8    end loop;
9    return binval;
10  END dec2bin;
11  /

Function created.

SQL> show errors
No errors.
SQL>
``````

Let's use the function to get the binary value -

``````SQL> SELECT dec2bin(4946144450195624) FROM dual;

DEC2BIN(4946144450195624)
--------------------------------------------------------------------------------
10001100100100111110111111110111101100011000010101000

SQL>
``````

Now the catch is the `5-bit` conversion. Start grouping from right to left with 5 digits in each group. We get :-

``````100|01100|10010|01111|10111|11111|01111|01100|01100|00101|01000
``````

We would be finally left with just 3 digits int he end at the right. Because, we had total 53 digits in the binary conversion.

``````SQL> SELECT LENGTH(dec2bin(4946144450195624)) FROM dual;

LENGTH(DEC2BIN(4946144450195624))
---------------------------------
53

SQL>
``````

`hello world` total has 11 characters(including space), so we need to add 2 bits to the last group where we were left with just 3 bits after grouping.

So, now we have :-

``````00100|01100|10010|01111|10111|11111|01111|01100|01100|00101|01000
``````

Now, we need to convert it to 7-bit ascii value. For the characters it is easy, we need to just set the 6th and 7th bit. Add `11` to each 5-bit group above to the left.

That gives :-

``````1100100|1101100|1110010|1101111|1110111|1111111|1101111|1101100|1101100|1100101|1101000
``````

Let's interpret the binary values, I will use `binary to decimal conversion function`.

``````SQL> CREATE OR REPLACE FUNCTION bin2dec (binval in char) RETURN number IS
2    i                 number;
3    digits            number;
4    result            number := 0;
5    current_digit     char(1);
6    current_digit_dec number;
7  BEGIN
8    digits := length(binval);
9    for i in 1..digits loop
10       current_digit := SUBSTR(binval, i, 1);
11       current_digit_dec := to_number(current_digit);
12       result := (result * 2) + current_digit_dec;
13    end loop;
14    return result;
15  END bin2dec;
16  /

Function created.

SQL> show errors;
No errors.
SQL>
``````

Let's look at each binary value -

``````SQL> set linesize 1000
SQL>
SQL> SELECT bin2dec('1100100') val,
2    bin2dec('1101100') val,
3    bin2dec('1110010') val,
4    bin2dec('1101111') val,
5    bin2dec('1110111') val,
6    bin2dec('1111111') val,
7    bin2dec('1101111') val,
8    bin2dec('1101100') val,
9    bin2dec('1101100') val,
10    bin2dec('1100101') val,
11    bin2dec('1101000') val
12  FROM dual;

VAL        VAL        VAL        VAL        VAL        VAL        VAL        VAL        VAL     VAL           VAL
---------- ---------- ---------- ---------- ---------- ---------- ---------- ---------- ---------- ---------- ----------
100        108        114        111        119        127        111        108        108     101           104

SQL>
``````

Let's look at what characters they are :-

``````SQL> SELECT chr(bin2dec('1100100')) character,
2    chr(bin2dec('1101100')) character,
3    chr(bin2dec('1110010')) character,
4    chr(bin2dec('1101111')) character,
5    chr(bin2dec('1110111')) character,
6    chr(bin2dec('1111111')) character,
7    chr(bin2dec('1101111')) character,
8    chr(bin2dec('1101100')) character,
9    chr(bin2dec('1101100')) character,
10    chr(bin2dec('1100101')) character,
11    chr(bin2dec('1101000')) character
12  FROM dual;

CHARACTER CHARACTER CHARACTER CHARACTER CHARACTER CHARACTER CHARACTER CHARACTER CHARACTER CHARACTER CHARACTER
--------- --------- --------- --------- --------- --------- --------- --------- --------- --------- ---------
d         l         r         o         w         ⌂         o         l         l         e         h

SQL>
``````

So, what do we get in the output?

d l r o w ⌂ o l l e h

That is hello⌂world in reverse. The only issue is the space. And the reason is well explained by @higuaro in his answer. I honestly couldn't interpret the space issue myself at first attempt, until I saw the explanation given in his answer.

-

I found the code slightly easier to understand when translated into PHP, as follows:

``````<?php

\$result=0;
\$bignum = 4946144450195624;
for (; \$bignum > 0; \$bignum >>= 5){
\$result = (( \$bignum & 31 | 64) % 95) + 32;
echo chr(\$result);
}
``````

See live code

-

out.println((char) (((l & 31 | 64) % 95) + 32 / 1002439 * 1002439));

To make it caps :3

-
consider adding some explanation about what are you doing and why. – fedorqui Dec 5 '14 at 19:14