I have a computer with 1 MB of RAM and no other local storage. I must use it to accept 1 million 8-digit decimal numbers over a TCP connection, sort them, and then send the sorted list out over another TCP connection.

The list of numbers may contain duplicates, which I must not discard. The code will be placed in ROM, so I need not subtract the size of my code from the 1 MB. I already have code to drive the Ethernet port and handle TCP/IP connections, and it requires 2 KB for its state data, including a 1 KB buffer via which the code will read and write data. Is there a solution to this problem?

Sources Of Question And Answer:



  • 41
    Ehm, a million times 8-digit decimal number (min. 27-bit integer binary) > 1MB ram – Mr47 Oct 5 '12 at 14:19
  • 12
    1M of RAM means 2^20 bytes? And how many bits are in a byte on this architecture? And is the "million" in "1 million 8 digit decimal numbers" a SI million (10^6)? What is a 8 digit decimal number, a natural number < 10^8, a rational number whose decimal representation takes 8 digits excluding the decimal point, or something else? – user395760 Oct 5 '12 at 14:20
  • 13
    1 million 8 decimal digit numbers or 1 million 8 bit numbers? – Patrick White Oct 5 '12 at 14:20
  • 11
    it reminds me of an article in "Dr Dobb's Journal" (somewhere between 1998-2001), where the author used an insertion sort to sort phone numbers as he was reading them: that was the first time i realized that, sometimes, a slower algorithm may be faster... – Adrien Plisson Oct 21 '12 at 21:29
  • 81
    There's another solution nobody has mentioned yet: buy hardware with 2MB RAM. It shouldn't be much more expensive, and it will make the problem much, much easier to solve. – Daniel Wagner Oct 21 '12 at 23:48

36 Answers 36


Sort of like sleepsort:

for i = 1 to 1000000
    input N
        Send a message on the network with delay of (N * some constant)


How do you do this, you ask? Well:


PingFS is a set of python [sic] scripts which, in Linux, provide virtual disk storage on the network. Each file is broken up into 64-1024 byte blocks, sent over the wire in an ICMP echo request, and promptly erased from memory. Each time the server sends back your bundle of joy, PingFS recognizes its data and sends another gift [the data]. Download at the bottom of the page.

  • How are you remembering those delays/storing the numbers to be sent? – Aaron Dufour Oct 21 '12 at 17:05
  • shysecurity.com/posts/PingFS "PingFS is a set of python scripts which, in Linux, provide virtual disk storage on the network. Each file is broken up into 64-1024 byte blocks, sent over the wire in an ICMP echo request, and promptly erased from memory. Each time the server sends back your bundle of joy, PingFS recognizes its data and sends another gift [the data]. Download at the bottom of the page." – gecko Oct 21 '12 at 17:11
  • 3
    This is just a way of getting extra storage via a network, which is clearly outside the spirit of the question. – Aaron Dufour Oct 21 '12 at 17:15
  • This is similar to Joe's answer: stackoverflow.com/a/13000176/1129194 – Alex L Oct 21 '12 at 19:28
  • 1
    @AaronDufour, there is no spirit of the question, the question is broken to boot. ICMP is a valid answer. – bestsss Oct 22 '12 at 12:35

If the range of the numbers is limited (there can be only mod 2 8 digit numbers, or only 10 different 8 digit numbers for example), then you could write an optimized sorting algorithm. But if you want to sort all possible 8 digit numbers, this is not possible with that low amount of memory.

  • Instead of downvoting you could deliver some useful information so that I can help you solving your problem... – Alexander Nassian Oct 22 '12 at 14:12
  • What's your justification that "you could write an optimized sorting algorithm" under certain constraints or that "this is not possible with that low amount of memory"? – Dan Oct 22 '12 at 15:41
  • If the thread starter provides information if it would be possible to add some constraints to the incoming numbers, we may build an algorithm that is able to do the sorting. – Alexander Nassian Oct 23 '12 at 9:45

If it is possible to read the input file more than once (your problem statement doesn't say it can't), the following should work. It is described in Benchley's book "Programming Perls." If we store each number in 8 bytes we can store 250,000 numbers in one megabyte. Use a program that makes 40 passes over the input file. On the first pass it reads into memory any integer between 0 and 249,999, sorts the (at most) 250,000 integers and writes them to the output file. The second pass sorts the integers from 250,000 to 499,999 and so on to the 40th pass, which sorts 9,750,000 to 9,999,999.

  • You only need 4 bytes, not 8, to store an 8-digit decimal value. You shouldn't need 40 passes, 4 should be sufficient. You don't want to take only numbers less than 250,000 on the first pass; that could be all of them. What you want to do is take the lowest 250,000 numbers. Easy enough with an insertion sort that pushes high values off the cliff. Once you've completed the first pass you output the 250,000 lowest numbers and remember the largest of those (prev_max). On the next pass you insertion-sort numbers greater than prev_max, high values fall off the cliff, etc. Otherwise, good answer. – Dan Oct 22 '12 at 15:37

You have to count up to at most 99,999,999 and indicate 1,000,000 stops along the way. So a bitstream can be used that is interpreted such that at 1 indicates in increment a counter and a 0 indicates to output a number. If the first 8 bits in the stream are 00110010, we would have 0, 0, 2, 2, 3 so far.

log(99,999,999 + 1,000,000) / log(2) = 26.59. You have 2^28 bits in your memory. You only need to use half!

  • If all the numbers are 99,999,999 you will need the same amount of 1 bits just to get to the first 0 bit. That's well over the allotted 1 MB of memory. – StapleGun Oct 22 '12 at 2:51
  • Yes, I had a brainfart and took 1MB as 2^28 bits instead of 2^23. – mjfrazer Oct 22 '12 at 3:03
  • Ok, so here is my second attempt. – mjfrazer Oct 22 '12 at 3:21
  • Ok, so here is my second attempt. You encode the gaps as delta from the previous gap in a variable length field. The average delta is 100, and assuming a normal distribution of the 1M numbers, some % of them will have a gap width between 100-32 and 100+31, which we can encode in a 6 bit signed int. We would encode this gap as 0xxxxxx, where x is the 2s complement gap offset from 100. This uses 7 bits per number. For the rare case where we want a different gap, we encode is as a stream of ones indicating one less than the # of bits, a zero, and the gap, eg. 1110bbbbbbbb. – mjfrazer Oct 22 '12 at 3:41
  • If there are lots of large and small gaps causing pathological behaviour in this, you would indicate a 2nd encoding scheme which would use 0xxxx to encode gaps of 0-15, 10xxxxx (7 bits) to encode gaps of 16-47, 110xxxxxx (9 bits) to encode gaps of 48-111, and so on. Since your average gap must be 100, you will need different encoding modes to describe your gaps depending on their distribution around 100. – mjfrazer Oct 22 '12 at 4:08

Have you tried converting to hex?

I can see a big reduction on filesize after and before; then, work by part with the free space. Maybe, converting to dec again, order, hex, another chunk,convert to dec, order...

Sorry.. I don't know if could work

# for i in {1..10000};do echo $(od -N1 -An -i /dev/urandom) ; done > 10000numbers
# for i in $(cat 10000numbers ); do printf '%x\n' $i; done > 10000numbers_hex
# ls -lah total 100K
drwxr-xr-x  2 diego diego 4,0K oct 22 22:32 .
drwx------ 39 diego diego  12K oct 22 22:31 ..
-rw-r--r--  1 diego diego  29K oct 22 22:33 10000numbers_hex
-rw-r--r--  1 diego diego  35K oct 22 22:31 10000numbers
  • There is an extra overhead of converting the numbers to hex. – Rahul Kadukar Apr 3 '15 at 16:49

If the numbers are evenly distributed we can use Counting sort. We should keep the number of times that each number is repeated in an array. Available space is: 1 MB - 3 KB = 1045504 B or 8364032 bits Number of bits per number= 8364032/1000000 = 8 Therefore, we can store the number of times each number is repeated to the maximum of 2^8-1=255. Using this approach we have an extra 364032 bits unused that can be used to handle cases where a number is repeated more than 255 times. For example we can say a number 255 indicates a repetition greater than or equal to 255. In this case we should store a sequence of numbers+repetitions. We can handle 7745 special cases as shown bellow:

364032/ (bits need to represent each number + bits needed to represent 1 million)= 364032 / (27+20)=7745

protected by Community Oct 22 '12 at 2:21

Thank you for your interest in this question. Because it has attracted low-quality or spam answers that had to be removed, posting an answer now requires 10 reputation on this site (the association bonus does not count).

Would you like to answer one of these unanswered questions instead?

Not the answer you're looking for? Browse other questions tagged or ask your own question.