# Sorting 1 million 8-digit numbers in 1MB of RAM

I have a computer with 1M 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 1M. I already have code to drive the ethernet port and handle TCP/IP connections, and it requires 2k for its state data, including a 1k buffer via which the code will read and write data. Is there a solution to this problem?

Sources Of Question And Answer:
http://nick.cleaton.net/ramsort.html

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Ehm, a million times 8-digit decimal number (min. 27-bit integer binary) > 1MB ram –  Mr47 Oct 5 '12 at 14:19
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? –  delnan Oct 5 '12 at 14:20
1 million 8 decimal digit numbers or 1 million 8 bit numbers? –  PWhite Oct 5 '12 at 14:20
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
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
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This is assuming base 10 and as an example, your memory is using 8 bit words: Memory map the entire range of numbers using 3 bit increments. The First 3 bits would correspond to the number 0. The second set of 3 bit would map to number 1. Three hundred thousandth set of 3-bit would map to the number 300k. Repeat this until you have mapped out all the 8 digit numbers. This would total 375k bytes in total if memory range was continuous.

The 1st bit out of the 3 would mark the presence of the number. The next 2 bits would indicate the amount of duplicates that could be represented in bytes(1..3) if none, the duplicates field would be 00. There will be a second list that uses a counter that increments each time a 3 bit field is marked as having a duplicate. If it marked with 1 it will have a single bit range to count the amount of duplicates it has. 8 bits can represent a range 255.

As I'm losing track of thoughts. The second list will keep track of how many duplicates for each number. if the 255th number has a duplicate and is the first number to have a duplicate it's index in the list will be 0. If 23,543 is the second number to have a duplicate it's index will be 1. Wash,rise and repeat.

Worst case scenario is you have 500k numbers with duplicates. This can be represented by a single byte(since 1 fits in easy). So 375kB(ideally) + 500kB bytes is close to .875MB. Depending on your processor this should leave enough room left over for pointers,indexing and all of the other fun stuff.

If you have a single number that has 1M duplicates. all you need is 3 bytes, since your limited to 1M numbers, that's all you have to worry about. So on your second list it will be just be 3 byes with the total amount.

Now for the fun part. The second list will need to be sorted for each new number that comes in. In the 3 bit field the last 2 are the number of bytes that contains the number of duplicates. Since the second list is expected to be in order it will need to be sorted. Since the amount of bytes can vary. Think insertion sort!

This would keep the amount of pointers and things you need to increment to a minimum so you should have a little bit of flexibility with the maybe 250k bytes left.

GoodLuck! This sounds so much more elegant in my mind...

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There are 1e8 eight-digit numbers; 1e8/8/1024 > 12,207 kilobytes. Try it in your favorite calculator. –  Daniel Wagner Oct 22 '12 at 7:27
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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
``````
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As ROM size does not count one does not need any additional RAM besides the TCP buffers. Just implement a big finite-state machine. Each state represents a multi-set of numbers read in. After reading a million numbers one has just to print the numbers corresponding to the reached state.

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But it doesn't solve anything. It boils down to using program state instead of RAM. But unless you find a good encoding, your program state is not going to fit in any kind of register. And describing that encoding is precisely what all other answers are striving to achieve. –  JB. Oct 21 '12 at 22:57
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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.

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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!

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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.

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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

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