I discovered this oddity:
for (long l = 4946144450195624l; l > 0; l >>= 5) System.out.print((char) (((l & 31 | 64) % 95) + 32));
How does this work?
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The program decodes a character for every 5-bits group, from right to left
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).
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:
Here you can see that the ascii characters we want to map begin with the 7th and 6th bit set (
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
So far the 5-bit group is of the form:
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:
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Adding some value to above answers. Following groovy script prints intermediate values.
Here it is
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
In an application we wanted to transfer visible English Characters, Persian Characters and Symbols via SMS. As you see there are
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).
You are getting a result which happens to be
You've encoded characters as 5-bit values and packed 11 of them into a 64 bit long.
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.
It prints "hello world" for a similar reason this does:
but for a somewhat different reason than this: