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I am making a program where one of the problems is that I need to do some analysis of the bit pattern in some integers.

Because of this I would like to be able to do something like this:

#Does **NOT** work:
num.each_bit do |i|
   #do something with i

I was able to make something that works, by doing:

num.to_s(2).each_char do |c|
   #do something with c as a char

This however does not have the performance I would like.

I have found that you can do this:

0.upto(num/2) do |i|
   #do something with n[i]

This have even worse performance than the each_char method

This loop is going to be executed millions of times, or more, so I would like it to be as fast as possible.

For reference, here is the entirety of the function

@@aHashMap =

#The method finds the length of the longes continuous chain of ones, minus one 
#(101110 = 2, 11 = 1, 101010101 = 0, 10111110 = 4)

def afunc(n) 
if @@aHashMap[n] != -1
    return @@aHashMap[n]

num = 0
tempnum = 0
prev = false

(n.to_s(2)).each_char do |i|
    if i
        if prev
            tempnum += 1
            if tempnum > num
                num = tempnum
            prev = true
        prev = false
        tempnum = 0

@@aHashMap[n] = num
return num
share|improve this question
If you are going for performance, building a lookup table would probably be the right optimization in this case – 32bitkid Jun 6 '12 at 10:50
Declaring an @@-type variable is highly unusual. Do you have a good reason for doing it? – tadman Jun 6 '12 at 16:05
@tadman No, I do not have a very good reason for this. It's just something that stuck when I was making some static varables, and I have not bothered to do any refactoring yet. – Cort3z Jun 7 '12 at 17:34
In most cases you should use standard @ variables inside an instance of a class to keep things organized. @@ are class variables. – tadman Jun 7 '12 at 17:36
I see. Did not know that. Thanks. – Cort3z Jun 7 '12 at 17:38
up vote 9 down vote accepted

To determine the length of the longest sequence of consecutive 1's, this is more efficient:

def longest_one_chain(n)
  c = 0
  while n != 0
    n &= n >> 1
    c += 1

The method simply counts how many times you can "bitwise AND" the number with itself shifted 1 bit to the right until it is zero.


                 ______ <-- longest chain
    01011011100001111110011110101010 c=0
AND  0101101110000111111001111010101
        1001100000111110001110000000 c=1, 1’s deleted
AND      100110000011111000111000000
            100000011110000110000000 c=2, 11’s deleted
AND          10000001111000011000000
                    1110000010000000 c=3, 111’s deleted
AND                  111000001000000
                     110000000000000 c=4, 1111’s deleted
AND                   11000000000000
                      10000000000000 c=5, 11111’s deleted
AND                    1000000000000
                                   0 c=6, 111111’s deleted
share|improve this answer
Brilliant! :D I found some other way of doing this as well, essentially doing recursive bit-shifting and counting. This is better though! – Cort3z Jun 7 '12 at 17:23

Be aware that o and "0" all have a boolean value of true in ruby, so "if i" will not give the result you intended.

Converting each number to a string is of course something one should avoid.

Fixnum has a method [] to access bits of the number, so this has the chance to be faster.

If you have tried this with

0.upto(num/2) do |i|
   #do something with n[i]

then num/2 is probably much too big, so you loop much too often.

For 32 bit integers you should use

0.upto(31) do |i|
   if n[i] == 1
share|improve this answer
documenation reference – 32bitkid Jun 6 '12 at 10:24
0.size*8 gives the number of bits. – steenslag Jun 6 '12 at 10:43
@steenslag This seem to work very vell. – Cort3z Jun 6 '12 at 11:48

Ruby might not be a good choice for your project. The strength of ruby is not it's performance but that it lets you do things like:

n.to_s(2).scan(/1+/).sort.last.length - 1

instead of writing mountains of code. Really just about any other language is likely to perform better if you don't mind writing complex code (which you don't seem to).

share|improve this answer
This will blow up on 0. – tadman Jun 6 '12 at 16:13

In Ruby, Integers (i.e. both Bignums and Fixnums) can already be indexed as if they were bit arrays. They are, however, not Enumerable.

But you can fix that, of course:

class Integer
  include Enumerable

  def each
    return to_enum unless block_given?      
    (size*8).times {|i| yield self[i] }

A slightly less intrusive way might be to represent the Integer as an array:

class Integer
  def to_a*8, &method(:[]))

Then you can use Ruby's nifty Enumerable methods:

0b10111110.chunk {|b| true if b == 1 }.map(&:last).max_by(&:size).size - 1

(Or 0b10111110.to_a.chunk … if you prefer the less intrusive method.)

If you are worried about performance, the execution engine you choose makes a big difference. Rubinius's or JRuby's optimizing compiler may be able to inline and optimize away many method calls that YARV's rather simple compiler can't, for example. YARV's special treatment of Fixnum may give it an advantage over MRI.

As you can see from the examples, I am a big fan of point-free style and functional programming. If you can prove via profiling that you have a bottleneck at a specific point in the code, you may need to replace it with a slightly less elegant or impure version, or you may want to hand-fuse the map and max_by.

class Integer
  def to_a*8) {|i| self[i] }

0b10111110.chunk {|b| true if 1 == b }.map {|key, chunk| chunk.size }.max - 1


0b10111110.chunk {|b| true if 1 == b }.max_by {|key, chunk| chunk.size }.last.size - 1
share|improve this answer

If you are looking for performance, then building a look-up table will probably be the most performant way. Especially if you are doing these in a tight loop:

class BitCounter
    def initialize
        @lookup_table = (0..65535).map { |d| count_bits(d) }

    def count(val)
        a,b,c = @lookup_table[val & 65535]
        d,e,f = @lookup_table[val >> 16]


    def count_bits(val)
        lsb = lsb_bits(val)
        msb = msb_bits(val)
        [lsb, inner_bits(val, lsb, msb), msb]

    def lsb_bits(val)
        len = 0
        while (val & 1 == 1) do
            val >>= 1
            len += 1

    def msb_bits(val)
        len = 0
        while (val & (1<<15) == (1<<15)) do
            val <<= 1
            len += 1

    def inner_bits(val, lsb, msb)
        lens = []
        ndx = lsb

        len = 0
        (lsb+1..(15-msb)).each do |x|
            if ((val & (1<<x)) == 0)
                if(len > 0)
                    lens << len
                    len = 0
                len += 1
        lens.max || 0

And then an example:

counter =
p counter.count 0b01011011100001111110011110101010  // 6

This basically creates a loopup table for all 16 bit values, and then calculates the largest result from those cached values.

You could even combine the more expressive form of n.to_s(2).scan(/1+/).sort.last.length - 1 rather than doing bitwise logic in your table initialization, since it is no longer the bottleneck point -- although I would stick with bitwise math just for clarity of expression rather than string parsing. Each look up only costs 2 table look ups, one addition and a max

share|improve this answer
This looks like a good, but complex solution. Will try it out when I get back to this. However, I have found that my problem needs to be spead up by a factor of 1000 or more, potentially millions of times, so I think I need to leave ruby for this project. But this ruby code is very good to have. – Cort3z Jun 7 '12 at 17:37

Sometimes using strings is the most obvious method, and the performance is tolerable:

def oneseq(n)
share|improve this answer
Performance is critical in this small app, so I actually need to go over to c++ and some openCL or cuda solution. The problem at hand, I found, is way too large for ruby. – Cort3z Jun 7 '12 at 17:22
If you need gigabytes per second levels of performance then you'll need a more C-based solution, but even more importantly, an algorithm that's good at teasing out sequences of 1s. Don't forget it's not too hard to embed C inside Ruby for performance-critical sections. For example: rubyinline – tadman Jun 7 '12 at 17:39
I know this is possible with ruby, but this particular problem requires multi threading. Heavy duty MT at that. Basicly figured that this needs GPU processing, or if I am very unlucky, supercomputer processing. In that case, I am in trouble. – Cort3z Jun 7 '12 at 17:42
How many numbers are you testing here? Is it a one-shot deal or something you'll be doing constantly? Ripping through even a terabyte-sized pile of integers shouldn't require OpenCL, but should be fine in C if you partition your data-set and launch several processes independently. Threads are often nothing but trouble unless you are a veteran multi-threader. Don't forget there are SIMD instructions you can use that make ordinary C code stupidly fast if you can vectorize it. – tadman Jun 7 '12 at 17:46
This is sort of off-topic related to the actual question, but: I am essentially doing an algorithm to find a sum of a range. Only problem is that the range produces numbers so vastly great that I have problems comprehending the size of the problem. Not only are the numbers themselves great, but I got to do calculations on all the numbers preceeding it to figure out the output of this current number. Then I got to find the N-t occurance of this number, where N is in the same order of magnitude as the first. So, I have a problem is what I am saying. :p – Cort3z Jun 7 '12 at 17:52

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