# 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?

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

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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A solution is possible only because of the difference between 1 megabyte and 1 million bytes. There are about 2 to the power 8093729.5 different ways to choose 1 million 8-digit numbers with duplicates allowed and order unimportant, so a machine with only 1 million bytes of RAM doesn't have enough states to represent all the possibilities. But 1M (less 2k for TCP/IP) is 1022*1024*8 = 8372224 bits, so a solution is possible.

Part 1, initial solution

This approach needs a little more than 1M, I'll refine it to fit into 1M later.

I'll store a compact sorted list of numbers in the range 0 to 99999999 as a sequence of sublists of 7-bit numbers. The first sublist holds numbers from 0 to 127, the second sublist holds numbers from 128 to 255, etc. 100000000/128 is exactly 781250, so 781250 such sublists will be needed.

Each sublist consists of a 2-bit sublist header followed by a sublist body. The sublist body takes up 7 bits per sublist entry. The sublists are all concatenated together, and the format makes it possible to tell where one sublist ends and the next begins. The total storage required for a fully populated list is 2*781250 + 7*1000000 = 8562500 bits, which is about 1.021 M-bytes.

The 4 possible sublist header values are:

00 Empty sublist, nothing follows.

01 Singleton, there is only one entry in the sublist and and next 7 bits hold it.

10 The sublist holds at least 2 distinct numbers. The entries are stored in non-decreasing order, except that the last entry is less than or equal to the first. This allows the end of the sublist to be identified. For example, the numbers 2,4,6 would be stored as (4,6,2). The numbers 2,2,3,4,4 would be stored as (2,3,4,4,2).

11 The sublist holds 2 or more repetitions of a single number. The next 7 bits give the number. Then come zero or more 7-bit entries with the value 1, followed by a 7-bit entry with the value 0. The length of the sublist body dictates the number of repetitions. For example, the numbers 12,12 would be stored as (12,0), the numbers 12,12,12 would be stored as (12,1,0), 12,12,12,12 would be (12,1,1,0) and so on.

I start off with an empty list, read a bunch of numbers in and store them as 32 bit integers, sort the new numbers in place (using heapsort, probably) and then merge them into a new compact sorted list. Repeat until there are no more numbers to read, then walk the compact list once more to generate the output.

The line below represents memory just before the start of the list merge operation. The "O"s are the region that hold the sorted 32-bit integers. The "X"s are the region that hold the old compact list. The "=" signs are the expansion room for the compact list, 7 bits for each integer in the "O"s. The "Z"s are other random overhead.

``````ZZZOOOOOOOOOOOOOOOOOOOOOOOOOO==========XXXXXXXXXXXXXXXXXXXXXXXXXX
``````

The merge routine starts reading at the leftmost "O" and at the leftmost "X", and starts writing at the leftmost "=". The write pointer doesn't catch the compact list read pointer until all of the new integers are merged, because both pointers advance 2 bits for each sublist and 7 bits for each entry in the old compact list, and there is enough extra room for the 7-bit entries for the new numbers.

Part 2, cramming it into 1M

To Squeeze the solution above into 1M, I need to make the compact list format a bit more compact. I'll get rid of one of the sublist types, so that there will be just 3 different possible sublist header values. Then I can use "00", "01" and "1" as the sublist header values and save a few bits. The sublist types are:

A Empty sublist, nothing follows.

B Singleton, there is only one entry in the sublist and and next 7 bits hold it.

C The sublist holds at least 2 distinct numbers. The entries are stored in non-decreasing order, except that the last entry is less than or equal to the first. This allows the end of the sublist to be identified. For example, the numbers 2,4,6 would be stored as (4,6,2). The numbers 2,2,3,4,4 would be stored as (2,3,4,4,2).

D The sublist consists of 2 or more repetitions of a single number.

My 3 sublist header values will be "A", "B" and "C", so I need a way to represent D-type sublists.

Suppose I have the C-type sublist header followed by 3 entries, such as "C[17][101][58]". This can't be part of a valid C-type sublist as described above, since the third entry is less than the second but more than the first. I can use this type of construct to represent a D-type sublist. In bit terms, anywhere I have "C{00?????}{1??????}{01?????}" is an impossible C-type sublist. I'll use this to represent a sublist consisting of 3 or more repetitions of a single number. The first two 7-bit words encode the number (the "N" bits below) and are followed by zero or more {0100001} words followed by a {0100000} word.

``````For example, 3 repetitions: "C{00NNNNN}{1NN0000}{0100000}", 4 repetitions: "C{00NNNNN}{1NN0000}{0100001}{0100000}", and so on.
``````

That just leaves lists that hold exactly 2 repetitions of a single number. I'll represent those with another impossible C-type sublist pattern: "C{0??????}{11?????}{10?????}". There's plenty of room for the 7 bits of the number in the first 2 words, but this pattern is longer than the sublist that it represents, which makes things a bit more complex. The five question-marks at the end can be considered not part of the pattern, so I have: "C{0NNNNNN}{11N????}10" as my pattern, with the number to be repeated stored in the "N"s. That's 2 bits too long.

I'll have to borrow 2 bits and pay them back from the 4 unused bits in this pattern. When reading, on encountering "C{0NNNNNN}{11N00AB}10", output 2 instances of the number in the "N"s, overwrite the "10" at the end with bits A and B, and rewind the read pointer by 2 bits. Destructive reads are ok for this algorithm, since each compact list gets walked only once.

When writing a sublist of 2 repetitions of a single number, write "C{0NNNNNN}11N00" and set the borrowed bits counter to 2. At every write where the borrowed bits counter is non-zero, it is decremented for each bit written and "10" is written when the counter hits zero. So the next 2 bits written will go into slots A and B, and then the "10" will get dropped onto the end.

With 3 sublist header values represented by "00", "01" and "1", I can assign "1" to the most popular sublist type. I'll need a small table to map sublist header values to sublist types, and I'll need an occurrence counter for each sublist type so that I know what the best sublist header mapping is.

The worst case minimal representation of a fully populated compact list occurs when all the sublist types are equally popular. In that case I save 1 bit for every 3 sublist headers, so the list size is 2*781250 + 7*1000000 - 781250/3 = 8302083.3 bits. Rounding up to a 32 bit word boundary, thats 8302112 bits, or 1037764 bytes.

1M minus the 2k for TCP/IP state and buffers is 1022*1024 = 1046528 bytes, leaving me 8764 bytes to play with.

But what about the process of changing the sublist header mapping ? In the memory map below, "Z" is random overhead, "=" is free space, "X" is the compact list.

``````ZZZ=====XXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXX
``````

Start reading at the leftmost "X" and start writing at the leftmost "=" and work right. When it's done the compact list will be a little shorter and it will be at the wrong end of memory:

``````ZZZXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXX=======
``````

So then I'll need to shunt it to the right:

``````ZZZ=======XXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXX
``````

In the header mapping change process, up to 1/3 of the sublist headers will be changing from 1-bit to 2-bit. In the worst case these will all be at the head of the list, so I'll need at least 781250/3 bits of free storage before I start, which takes me back to the memory requirements of the previous version of the compact list :(

To get around that, I'll split the 781250 sublists into 10 sublist groups of 78125 sublists each. Each group has its own independent sublist header mapping. Using the letters A to J for the groups:

``````ZZZ=====AAAAAABBCCCCDDDDDEEEFFFGGGGGGGGGGGHHIJJJJJJJJJJJJJJJJJJJJ
``````

Each sublist group shrinks or stays the same during a sublist header mapping change:

``````ZZZ=====AAAAAABBCCCCDDDDDEEEFFFGGGGGGGGGGGHHIJJJJJJJJJJJJJJJJJJJJ
ZZZAAAAAA=====BBCCCCDDDDDEEEFFFGGGGGGGGGGGHHIJJJJJJJJJJJJJJJJJJJJ
ZZZAAAAAABB=====CCCCDDDDDEEEFFFGGGGGGGGGGGHHIJJJJJJJJJJJJJJJJJJJJ
ZZZAAAAAABBCCC======DDDDDEEEFFFGGGGGGGGGGGHHIJJJJJJJJJJJJJJJJJJJJ
ZZZAAAAAABBCCCDDDDD======EEEFFFGGGGGGGGGGGHHIJJJJJJJJJJJJJJJJJJJJ
ZZZAAAAAABBCCCDDDDDEEE======FFFGGGGGGGGGGGHHIJJJJJJJJJJJJJJJJJJJJ
ZZZAAAAAABBCCCDDDDDEEEFFF======GGGGGGGGGGGHHIJJJJJJJJJJJJJJJJJJJJ
ZZZAAAAAABBCCCDDDDDEEEFFFGGGGGGGGGG=======HHIJJJJJJJJJJJJJJJJJJJJ
ZZZAAAAAABBCCCDDDDDEEEFFFGGGGGGGGGGHH=======IJJJJJJJJJJJJJJJJJJJJ
ZZZAAAAAABBCCCDDDDDEEEFFFGGGGGGGGGGHHI=======JJJJJJJJJJJJJJJJJJJJ
ZZZAAAAAABBCCCDDDDDEEEFFFGGGGGGGGGGHHIJJJJJJJJJJJJJJJJJJJJ=======
ZZZ=======AAAAAABBCCCDDDDDEEEFFFGGGGGGGGGGHHIJJJJJJJJJJJJJJJJJJJJ
``````

The worst case temporary expansion of a sublist group during a mapping change is 78125/3 = 26042 bits, under 4k. If I allow 4k plus the 1037764 bytes for a fully populated compact list, that leaves me 8764 - 4096 = 4668 bytes for the "Z"s in the memory map.

That should be plenty for the 10 sublist header mapping tables, 30 sublist header occurrence counts and the other few counters, pointers and small buffers I'll need, and space I've used without noticing, like stack space for function call return addresses and local variables.

Part 3, how long would it take to run ?

With an empty compact list the 1-bit list header will be used for an empty sublist, and the starting size of the list will be 781250 bits. In the worst case the list grows 8 bits for each number added, so 32 + 8 = 40 bits of free space are needed for each of the 32-bit numbers to be placed at the top of the list buffer and then sorted and merged. In the worst case, changing the sublist header mapping results in a space usage of 2*781250 + 7*entries - 781250/3 bits.

With a policy of changing the sublist header mapping after every fifth merge once there are at least 800000 numbers in the list, a worst case run would involve a total of about 30M of compact list reading and writing activity.

Source:

http://nick.cleaton.net/ramsortsol.html

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I don't think any better solution is possible (in case we need to work with any incompressible values). But this one may be a little improved. It's not necessary to change sublist headers between 1-bit and 2-bit representations. Instead you can use arithmetic coding, which simplifies the algorithm and also decreases worst-case number of bits per header from 1.67 to 1.58. And you don't need to move compact list in memory; instead use circular buffer and change only pointers. –  Evgeny Kluev Oct 21 '12 at 15:48
So, finally, was that an interview question? –  mlvljr Oct 21 '12 at 20:59
Other possible improvement is to use 100-element sublists instead of 128-element sublists (because we get most compact representation when number of sublists is equal to the number of elements in data set). Each value of the sublist to be encoded with arithmetic coding (with equal frequency of 1/100 for each value). This can save about 10000 bits, much less than compression of sublist headers. –  Evgeny Kluev Oct 22 '12 at 11:30

Please see the first correct answer or the later answer with arithmetic encoding. Below you may find some fun, but not a 100% bullet-proof solution.

This is quite an interesting task and here is an another solution. I hope somebody would find the result useful (or at least interesting).

Stage 1: Initial data structure, rough compression approach, basic results

Let's do some simple math: we have 1M (1048576 bytes) of RAM initially available to store 10^6 8 digit decimal numbers. [0;99999999]. So to store one number 27 bits are needed (taking the assumption that unsigned numbers will be used). Thus, to store a raw stream ~3.5M of RAM will be needed. Somebody already said it doesn't seem to be feasible, but I would say the task can be solved if the input is "good enough". Basically, the idea is to compress the input data with compression factor 0.29 or higher and do sorting in a proper manner.

Let's solve the compression issue first. There are some relevant tests already available:

"I ran a test to compress one million consecutive integers using various forms of compression. The results are as follows:"

``````None     4000027
Deflate  2006803
Filtered 1391833
BZip2    427067
Lzma     255040
``````

It looks like LZMA (Lempel–Ziv–Markov chain algorithm) is a good choice to continue with. I've prepared a simple PoC, but there are still some details to be highlighted:

1. Memory is limited so the idea is to presort numbers and use compressed buckets (dynamic size) as temporary storage
2. It is easier to achieve a better compression factor with presorted data, so there is a static buffer for each bucket (numbers from the buffer are to be sorted before LZMA)
3. Each bucket holds a specific range, so the final sort can be done for each bucket separately
4. Bucket's size can be properly set, so there will be enough memory to decompress stored data and do the final sort for each bucket separately

Please note, attached code is a POC, it can't be used as a final solution, it just demonstrates the idea of using several smaller buffers to store presorted numbers in some optimal way (possibly compressed). LZMA is not proposed as a final solution. It is used as a fastest possible way to introduce a compression to this PoC.

See the PoC code below (please note it just a demo, to compile it LZMA-Java will be needed):

``````public class MemorySortDemo {

static final int NUM_COUNT = 1000000;
static final int NUM_MAX   = 100000000;

static final int BUCKETS      = 5;
static final int DICT_SIZE    = 16 * 1024; // LZMA dictionary size
static final int BUCKET_SIZE  = 1024;
static final int BUFFER_SIZE  = 10 * 1024;
static final int BUCKET_RANGE = NUM_MAX / BUCKETS;

static class Producer {
private Random random = new Random();
public int produce() { return random.nextInt(NUM_MAX); }
}

static class Bucket {
public int size, pointer;
public int[] buffer = new int[BUFFER_SIZE];

public ByteArrayOutputStream tempOut = new ByteArrayOutputStream();
public DataOutputStream tempDataOut = new DataOutputStream(tempOut);
public ByteArrayOutputStream compressedOut = new ByteArrayOutputStream();

public void submitBuffer() throws IOException {
Arrays.sort(buffer, 0, pointer);

for (int j = 0; j < pointer; j++) {
tempDataOut.writeInt(buffer[j]);
size++;
}
pointer = 0;
}

public void write(int value) throws IOException {
if (isBufferFull()) {
submitBuffer();
}
buffer[pointer++] = value;
}

public boolean isBufferFull() {
return pointer == BUFFER_SIZE;
}

public byte[] compressData() throws IOException {
tempDataOut.close();
return compress(tempOut.toByteArray());
}

private byte[] compress(byte[] input) throws IOException {
final BufferedInputStream in = new BufferedInputStream(new ByteArrayInputStream(input));
final DataOutputStream out = new DataOutputStream(new BufferedOutputStream(compressedOut));

final Encoder encoder = new Encoder();
encoder.setEndMarkerMode(true);
encoder.setNumFastBytes(0x20);
encoder.setDictionarySize(DICT_SIZE);
encoder.setMatchFinder(Encoder.EMatchFinderTypeBT4);

ByteArrayOutputStream encoderPrperties = new ByteArrayOutputStream();
encoder.writeCoderProperties(encoderPrperties);
encoderPrperties.flush();
encoderPrperties.close();

encoder.code(in, out, -1, -1, null);
out.flush();
out.close();
in.close();

return encoderPrperties.toByteArray();
}

public int[] decompress(byte[] properties) throws IOException {
InputStream in = new ByteArrayInputStream(compressedOut.toByteArray());
ByteArrayOutputStream data = new ByteArrayOutputStream(10 * 1024);
BufferedOutputStream out = new BufferedOutputStream(data);

Decoder decoder = new Decoder();
decoder.setDecoderProperties(properties);
decoder.code(in, out, 4 * size);

out.flush();
out.close();
in.close();

DataInputStream input = new DataInputStream(new ByteArrayInputStream(data.toByteArray()));
int[] array = new int[size];
for (int k = 0; k < size; k++) {
}

return array;
}
}

static class Sorter {
private Bucket[] bucket = new Bucket[BUCKETS];

public void doSort(Producer p, Consumer c) throws IOException {

for (int i = 0; i < bucket.length; i++) {  // allocate buckets
bucket[i] = new Bucket();
}

for(int i=0; i< NUM_COUNT; i++) {         // produce some data
int value = p.produce();
int bucketId = value/BUCKET_RANGE;
bucket[bucketId].write(value);
c.register(value);
}

for (int i = 0; i < bucket.length; i++) { // submit non-empty buffers
bucket[i].submitBuffer();
}

byte[] compressProperties = null;
for (int i = 0; i < bucket.length; i++) { // compress the data
compressProperties = bucket[i].compressData();
}

printStatistics();

for (int i = 0; i < bucket.length; i++) { // decode & sort buckets one by one
int[] array = bucket[i].decompress(compressProperties);
Arrays.sort(array);

for(int v : array) {
c.consume(v);
}
}
c.finalCheck();
}

public void printStatistics() {
int size = 0;
int sizeCompressed = 0;

for (int i = 0; i < BUCKETS; i++) {
int bucketSize = 4*bucket[i].size;
size += bucketSize;
sizeCompressed += bucket[i].compressedOut.size();

System.out.println("  bucket[" + i
+ "] contains: " + bucket[i].size
+ " numbers, compressed size: " + bucket[i].compressedOut.size()
+ String.format(" compression factor: %.2f", ((double)bucket[i].compressedOut.size())/bucketSize));
}

System.out.println(String.format("Data size: %.2fM",(double)size/(1014*1024))
+ String.format(" compressed %.2fM",(double)sizeCompressed/(1014*1024))
+ String.format(" compression factor %.2f",(double)sizeCompressed/size));
}
}

static class Consumer {
private Set<Integer> values = new HashSet<>();

int v = -1;
public void consume(int value) {
if(v < 0) v = value;

if(v > value) {
throw new IllegalArgumentException("Current value is greater than previous: " + v + " > " + value);
}else{
v = value;
values.remove(value);
}
}

public void register(int value) {
}

public void finalCheck() {
System.out.println(values.size() > 0 ? "NOT OK: " + values.size() : "OK!");
}
}

public static void main(String[] args) throws IOException {
Producer p = new Producer();
Consumer c = new Consumer();
Sorter sorter = new Sorter();

sorter.doSort(p, c);
}
}
``````

With random numbers it produces the following:

``````bucket[0] contains: 200357 numbers, compressed size: 353679 compression factor: 0.44
bucket[1] contains: 199465 numbers, compressed size: 352127 compression factor: 0.44
bucket[2] contains: 199682 numbers, compressed size: 352464 compression factor: 0.44
bucket[3] contains: 199949 numbers, compressed size: 352947 compression factor: 0.44
bucket[4] contains: 200547 numbers, compressed size: 353914 compression factor: 0.44
Data size: 3.85M compressed 1.70M compression factor 0.44
``````

For a simple ascending sequence (one bucket is used) it produces:

``````bucket[0] contains: 1000000 numbers, compressed size: 256700 compression factor: 0.06
Data size: 3.85M compressed 0.25M compression factor 0.06
``````

EDIT

Conclusion:

1. Don't try to fool the Nature
2. Use simpler compression with lower memory footprint
3. Some additional clues are really needed. Common bullet-proof solution does not seem to be feasible.

Stage 2: Enhanced compression, final conclusion

As was already mentioned in the previous section, any suitable compression technique can be used. So let's get rid of LZMA in favor of simpler and better (if possible) approach. There are a lot of good solutions including Arithmetic coding, Radix tree etc.

Anyway, simple but useful encoding scheme will be more illustrative than yet another external library, providing some nifty algorithm. The actual solution is pretty straightforward: since there are buckets with partially sorted data, deltas can be used instead of numbers.

Random input test shows slightly better results:

``````bucket[0] contains: 10103 numbers, compressed size: 13683 compression factor: 0.34
bucket[1] contains: 9885 numbers, compressed size: 13479 compression factor: 0.34
...
bucket[98] contains: 10026 numbers, compressed size: 13612 compression factor: 0.34
bucket[99] contains: 10058 numbers, compressed size: 13701 compression factor: 0.34
Data size: 3.85M compressed 1.31M compression factor 0.34
``````

Sample code

``````  public static void encode(int[] buffer, int length, BinaryOut output) {
short size = (short)(length & 0x7FFF);

output.write(size);
output.write(buffer[0]);

for(int i=1; i< size; i++) {
int next = buffer[i] - buffer[i-1];
int bits = getBinarySize(next);

int len = bits;

if(bits > 24) {
output.write(3, 2);
len = bits - 24;
}else if(bits > 16) {
output.write(2, 2);
len = bits-16;
}else if(bits > 8) {
output.write(1, 2);
len = bits - 8;
}else{
output.write(0, 2);
}

if (len > 0) {
if ((len % 2) > 0) {
len = len / 2;
output.write(len, 2);
output.write(false);
} else {
len = len / 2 - 1;
output.write(len, 2);
}

output.write(next, bits);
}
}
}

public static short decode(BinaryIn input, int[] buffer, int offset) {
buffer[offset] = value;

for (int i = 1; i < length; i++) {

int bits;
int next = 0;
switch (flag) {
case 0:
bits = 2 * input.readInt(2) + 2;
break;
case 1:
bits = 8 + 2 * input.readInt(2) +2;
break;
case 2:
bits = 16 + 2 * input.readInt(2) +2;
break;
case 3:
bits = 24 + 2 * input.readInt(2) +2;
break;
}

buffer[offset + i] = buffer[offset + i - 1] + next;
}

return length;
}
``````

1. does not consume a lot of memory
2. works with streams
3. provides not so bad results

Full code can be found here, BinaryInput and BinaryOutput implementations can be found here

Final conclusion

No final conclusion :) Sometimes it is really good idea to move one level up and review the task from a meta-level point of view.

It was fun to spend some time with this task. BTW, there are a lot of interesting answers below. Thank you for your attention and happy codding.

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The drawing is impressive :) +1 for the solution –  Serge Oct 21 '12 at 5:04
I used Inkscape. Great tool by the way. You can use this diagram source as an example. –  Renat Gilmanov Oct 21 '12 at 10:44
Surely LZMA requires too much memory to be useful in this case? As an algorithm it's meant to minimise the amount of data that has to be stored or transmitted, rather than be efficient in memory. –  Mjiig Oct 21 '12 at 14:11
This is nonsense... Get 1 million random 27 bit integers, sort them, compress with 7zip, xz, whatever LZMA you want. Result is over 1MB. The premise on top is compression of sequential numbers. Delta encoding of that with 0bit would be just the number, e.g. 1000000 (say in 4 bytes). With sequential and duplicates (no gaps) , the number 1000000 and 1000000 bits = 128KB, with 0 for duplicate number and 1 to mark next. When you have random gaps, even small, LZMA is ridiculous. It's not designed for this. –  alecco Oct 21 '12 at 21:15
This won't actually work. I ran a simulation and while the compressed data is more than 1MB (about 1.5MB), it still uses over 100MB of RAM to compress the data. So even the compressed integers don't fit the problem not to mention run time RAM usage. Awarding you the bounty is my biggest error on stackoverflow. –  Favourite Chigozie Onwuemene Oct 22 '12 at 9:59

If the input stream could be received few times this would be much easier (no info about that, idea and time-performance problem). Then, we could count the decimal values. With counted values it would be easy to make the output stream. Compress by counting the values. It depends what would be in the input stream.

-

Knuth Volume 3 chapter 5.4 goes into extensive detail about external sorting. No need to re-invent the wheel.

-
There is no external storage available; that's a stipulation of the problem. –  Jonathan Leffler Oct 21 '12 at 13:35
+1 for mentioning Knuth, aka looking for existing solutions. –  jim Oct 21 '12 at 16:17

A radix tree representation would come close to handling this problem, since the radix tree takes advantage of "prefix compression". But it's hard to conceive of a radix tree representation that could represent a single node in one byte -- two is probably about the limit.

But, regardless of how the data is represented, once it is sorted it can be stored in prefix-compressed form, where the numbers 10, 11, and 12 would be represented by, say 001b, 001b, 001b, indicating an increment of 1 from the previous number. Perhaps, then, 10101b would represent an increment of 5, 1101001b an increment of 9, etc.

-

(My original answer was wrong, sorry for the bad math, see below the break.)

The first 27 bits store the lowest number you have seen, then the difference to the next number seen, encoded as follows: 5 bits to store the number of bits used in storing the difference, then the difference. Use 00000 to indicate that you saw that number again.

This works because as more numbers are inserted, the average difference between numbers goes down, so you use less bits to store the difference as you add more numbers. I believe this is called a delta list.

The worst case I can think of is all numbers evenly spaced (by 100), e.g. Assuming 0 is the first number:

``````000000000000000000000000000 00111 1100100
^^^^^^^^^^^^^
a million times

27 + 1,000,000 * (5+7) bits = ~ 427k
``````

Reddit to the rescue!

If all you had to do was sort them, this problem would be easy. It takes 122k (1 million bits) to store which numbers you have seen (0th bit on if 0 was seen, 2300th bit on if 2300 was seen, etc.

You read the numbers, store them in the bit field, and then shift the bits out while keeping a count.

BUT, you have to remember how many you have seen. I was inspired by the sublist answer above to come up with this scheme:

Instead of using one bit, use either 2 or 27 bits:

• 00 means you did not see the number.
• 01 means you saw it once
• 1 means you saw it, and the next 26 bits are the count of how many times.

I think this works: if there are no duplicates, you have a 244k list. In the worst case you see each number twice (if you see one number three times, it shortens the rest of the list for you), that means you have seen 50,000 more than once, and you have seen 950,000 items 0 or 1 times.

50,000 * 27 + 950,000 * 2 = 396.7k.

You can make further improvements if you use the following encoding:

0 means you did not see the number 10 means you saw it once 11 is how you keep count

Which will, on average, result in 280.7k of storage.

EDIT: my Sunday morning math was wrong.

The worst case is we see 500,000 numbers twice, so the math becomes:

500,000 *27 + 500,000 *2 = 1.77M

The alternate encoding results in an average storage of

500,000 * 27 + 500,000 = 1.70M

: (

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Well, no, since the second number would be 500000. –  jfernand Oct 21 '12 at 14:55
Where did you get the "1 million bits" number? You said the 2300th bit represents whether 2300 was seen. (I think you actually meant 2301st.) Which bit represents whether 99,999,999 was seen (the largest 8-digit number)? Presumably, it would be the 100-millionth bit. –  smarx Oct 21 '12 at 15:24

I would try a Radix Tree. If you could store the data in a tree, you could then do an in-order traverse to transmit the data.

I'm not sure you could fit this into 1MB, but I think it's worth a try.

-

sort of like sleepsort

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

qed

edit:

How do you do this, you ask? well:

http://www.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.

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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

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

-

There is one rather sneaky trick not mentioned here so far. We assume that you have no extra way to store data, but that is not strictly true.

One way around your problem is to do the following horrible thing, which should not be attempted by anyone under any circumstances: Use the network traffic to store data. And no, I don't mean NAS.

You can sort the numbers with only a few bytes of RAM in the following way:

• First take 2 variables: COUNTER and VALUE.
• First set all registers to 0;
• Every time you receive an integer I, increment COUNTER and set VALUE to max(VALUE, I);
• Then send an ICMP echo request packet with data set to I to the router. Erase I and repeat.
• Every time you receive the returned ICMP packet, you simply extract the integer and send it back out again in another echo request. This produces a huge number of ICMP requests scuttling backward and forward containing the integers.

Once COUNTER reaches 1000000, you have all of the values stored in the incessant stream of ICMP requests, and VALUE now contains the maximum integer. Pick some threshold T >> 1000000. Set COUNTER to zero. Every time you receive an ICMP packet, increment COUNTER and send the contained integer I back out in another echo request, unless I=VALUE, in which case transmit it to the destination for the sorted integers. Once COUNTER=T, decrement VALUE by 1, reset COUNTER to zero and repeat. Once VALUE reaches zero you should have transmitted all integers in order from largest to smallest to the destination, and have only used about 47 bits of RAM for the two persistent variables (and whatever small amount you need for the temporary values).

I know this is horrible, and I know there can be all sorts of practical issues, but I thought it might give some of you a laugh or at least horrify you.

-
So you're basically leveraging network latency and turning your router into a sort of que? –  Eric R. Oct 21 '12 at 17:39
Of course, you do send around 100 trillion pings ... –  Joe Fitzsimons Oct 21 '12 at 18:26
This solution isn't just outside the box; it seems to have forgotten its box at home :D –  Vladislav Zorov Oct 21 '12 at 18:33
Great answer... I love these answers because they really expose how varied a solution can be to a problem –  StackOverflowed Oct 21 '12 at 19:48
ICMP is not reliable. –  sleeplessnerd Oct 21 '12 at 23:07

There is one solution to this problem across all possible inputs. Cheat.

1. Read m values over TCP, where m is near the max that can be sorted in memory, maybe n/4.
2. Sort the 250,000 (or so) numbers and output them.
3. Repeat for the other 3 quarters.
4. Let the receiver merge the 4 lists of numbers it has received as it processes them. (It's not much slower than using a single list.)
-

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

I have a computer with 1M of RAM and no other local storage

Another way to cheat: you could use non-local (networked) storage instead (your question does not preclude this) and call a networked service that could use straightforward disk-based mergesort (or just enough RAM to sort in-memory, since you only need to accept 1M numbers), without needing the (admittedly extremely ingenious) solutions already given.

This might be cheating, but it's not clear whether you are looking for a solution to a real-world problem, or a puzzle that invites bending of the rules... if the latter, then a simple cheat may get better results than a complex but "genuine" solution (which as others have pointed out, can only work for compressible inputs).

-

What kind of computer are you using? It may not have any other "normal" local storage, but does it have video RAM, for example? 1 megapixel x 32 bits per pixel (say) is pretty close to your required data input size.

(I largely ask in memory of the old Acorn RISC PC, which could 'borrow' VRAM to expand the available system RAM, if you chose a low resolution or low colour-depth screen mode!). This was rather useful on a machine with only a few MB of normal RAM.

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Care to comment, downvoter? - I'm just trying to stretch the apparent contraints of the question (i.e. cheat creatively ;-) –  DNA Oct 21 '12 at 20:18
Yes - I answered before the question was edited to indicate that it's an interview question! –  DNA Oct 28 '12 at 8:51

Suppose this task is possible. Just prior to output, there will be an in-memory representation of the million sorted numbers. How many different such representations are there? Since there may be repeated numbers we can't use nCr (choose), but there is an operation called multichoose that works on multisets.

• There are 2.2e2436455 ways to choose a million numbers in range 0..99,999,999.
• That requires 8,093,730 bits to represent every possible combination, or 1,011,717 bytes.

So theoretically it may be possible, if you can come up with a sane (enough) representation of the sorted list of numbers. For example, an insane representation might require a 10MB lookup table or thousands of lines of code.

However, if "1M RAM" means one million bytes, then clearly there is not enough space. The fact that 5% more memory makes it theoretically possible suggests to me that the representation will have to be VERY efficient and probably not sane.

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There are 10^6 values in a range of 10^8, so there's one value per hundred code points on average. Store the distance from the Nth point to the (N+1)th. Duplicate values have a skip of 0. This means that the skip needs an average of just under 7 bits to store, so a million of them will happily fit into our 8 million bits of storage.

These skips need to be encoded into a bitstream, say by Huffman encoding. Insertion is by iterating through the bitstream and rewriting after the new value. Output by iterating through and writing out the implied values. For practicality, it probably wants to be done as, say, 10^4 lists covering 10^4 code points (and an average of 100 values) each.

A good Huffman tree for random data can be built a priori by assuming a Poisson distribution (mean=variance=100) on the length of the skips, but real statistics can be kept on the input and used to generate an optimal tree to deal with pathological cases.

-

We could play with the networking stack to send the numbers in sorted order before we have all the numbers. If you send 1M of data, TCP/IP will break it into 1500 byte packets and stream them in order to the target. Each packet will be given a sequence number.

We can do this by hand. Just before we fill our RAM we can sort what we have and send the list to our target but leave holes in our sequence around each number. Then process the 2nd 1/2 of the numbers the same way using those holes in the sequence.

The networking stack on the far end will assemble the resulting data stream in order of sequence before handing it up to the application.

It's using the network to perform a merge sort. This is a total hack, but I was inspired by the other networking hack listed previously.

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Sorting is a secondary problem here. As other said, just storing the integers is hard, and cannot work on all inputs, since 27 bits per number would be necessary.

My take on this is: store only the differences between the consecutive (sorted) integers, as they will be most likely small. Then use a compression scheme, e.g. with 2 additional bits per input number, to encode how many bits the number is stored on. Something like:

``````00 -> 5 bits
01 -> 11 bits
10 -> 19 bits
11 -> 27 bits
``````

It should be possible to store a fair number of possible input lists within the given memory constraint. The maths of how to pick the compression scheme to have it work on the maximum number of inputs, are beyond me.

I hope you may be able to exploit domain-specific knowledge of your input to find a good enough integer compression scheme based on this.

Oh and then, you do an insertion sort on that sorted list as you receive data.

-

Gilmanov answer is very wrong in it assumptions. It starts speculating based in a pointless measure of a million consecutive integers. That means no gaps. Those random gaps, however small, really make it a poor idea.

Try yourself, get 1 million random 27 bit integers, sort them, compress with 7zip, xz, whatever LZMA you want. Result is over 1.5MB. The premise on top is compression of sequential numbers. Even delta encoding of that is over 1.1MB. And never mind this is using over 100MB of RAM for compression. So even the compressed integers don't fit the problem and never mind run time RAM usage.

It's saddens me how people just upvote pretty graphics and rationalization.

``````#include <stdint.h>
#include <stdlib.h>
#include <time.h>

int32_t ints[1000000]; // random 27bit integers

int cmpi32(const void *a, const void *b) {
return ( *(int32_t *)a - *(int32_t *)b );
}

int main() {
int32_t *pi = ints; // Pointer to input ints (REPLACE W/ read from net)

// Fill pseudo random integers of 27 bits
srand(time(NULL));
for (int i = 0; i < 1000000; i++)
ints[i] = rand() & ((1<<27) - 1); // random 32bit masked to 27 bits

qsort(ints, 1000000, sizeof (ints[0]), cmpi32); // Sort 1000000 int32s

// Now delta encode, optional, store differences to previous int
for (int i = 1, prev = ints[0]; i < 1000000; i++) {
ints[i] -= prev;
prev    += ints[i];
}

FILE *f = fopen("ints.bin", "w");
fwrite(ints, 4, 1000000, f);
fclose(f);
exit(0);

}
``````

Now compress ints.bin with LZMA...

``````\$ xz -f --keep ints.bin       # 100MB RAM
\$ 7z a ints.bin.7z ints.bin   # 130MB RAM
\$ ls -lh ints.bin*
3.8M ints.bin
1.1M ints.bin.7z
1.2M ints.bin.xz
``````
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+1 for the "people upvote pretty graphics" –  robermorales Oct 21 '12 at 22:40
any algorithm involving dictionary based compression is just beyond retarded, i have coded a few custom ones and all they take quite a bit of memory just to place their own hash tables (and no HashMap in java as it's extra hungry on resources). The closest solution would be delta encoding w/ variable bit length and bouncing back the TCP packets you don't like. The peer will retransmit, still whacky at best. –  bestsss Oct 21 '12 at 23:04
finally someone posts code! –  mlvljr Oct 22 '12 at 2:59
I'd upvote this answer if it had some pretty graphics… –  Donal Fellows Oct 22 '12 at 9:23

Your initial data structure is '99999999:0' (all zeros, haven't seen any numbers) and then lets say you see the number 3,866,344 so your data structure becomes '3866343:0,1:1,96133654:0' as you can see the numbers will always alternate between number of zero bits and number of '1' bits so you can just assume the odd numbers represent 0 bits and the even numbers 1 bits. This becomes (3866343,1,96133654)

Their problem doesn't seem to cover duplicates, but let's say they use "0:1" for duplicates.

Big problem #1: insertions for 1M integers would take ages.

Big problem #2: like all plain delta encoding solutions, some distributions can't be covered this way. For example, 1m integers with distances 0:99 (e.g. +99 each one). Now think the same but with random distance in the range of 0:99. (Note: 99999999/1000000 = 99.99)

Google's approach is both unworthy (slow) and incorrect. But to their defense, their problem might have been slightly different.

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My suggestions here owe a lot to Dan's solution

First off I assume the solution must handle all possible input lists. I think the popular answers do not make this assumption (which IMO is a huge mistake).

It is known that no form of lossless compression will reduce the size of all inputs.

All the popular answers assume they will be able to apply compression effective enough to allow them extra space. In fact, a chunk of extra space large enough to hold some portion of their partially completed list in an uncompressed form and allow them to perform their sorting operations. This is just a bad assumption.

For such a solution, anyone with knowledge of how they do their compression will be able to design some input data that does not compress well for this scheme, and the "solution" will most likely then break due to running out of space.

Instead I take a mathematical approach. Our possible outputs are all the lists of length LEN consisting of elements in the range 0..MAX. Here the LEN is 1,000,000 and our MAX is 100,000,000.

For arbitrary LEN and MAX, the amount of bits needed to encode this state is:

Log2(MAX Multichoose LEN)

So for our numbers, once we have completed recieving and sorting, we will need at least Log2(100,000,000 MC 1,000,000) bits to store our result in a way that can uniquely distinguish all possible outputs.

This is ~= 988kb. So we actually have enough space to hold our result. From this point of view, it is possible.

[Deleted pointless rambling now that better examples exist...]

Another good answer is here and basically uses insertion sort as the function to expand the list by one element (buffers a few elements and pre-sorts, to allow insertion of more than one at a time, saves a bit of time). uses a nice compact state encoding too, buckets of seven bit deltas

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I would exploit the retransmission behaviour of TCP.

1. Make the TCP component create a large receive window.
2. receive some amount of packets without sending an ACK for them. 2.1 process those in passes creating some (prefix) compressed data structure 2.2 send duplicate ack for last packet that is not needed anymore/wait for retransmission timeout 2.3 goto 2
3. all packets were accepted

this assumes some kind of benefit of buckets or multiple passes.

probably by sorting the batches/buckets and merging them. -> radix trees

EDIT: Use this technique to accept and sort the first 80% then read the last 20%, verify that the last 20% does not contain numbers that would land in the first 20% of the lowest numbers. Then send the 20% lowest numbers, remove from memory, accept the remaining 20% of new numbers and merge.

-

I think one way to think about this is from a combinatorics viewpoint: how many possible combinations of sorted number orderings are there? If we give the combination 0,0,0,....,0 the code 0, and 0,0,0,...,1 the code 1, and 99999999, 99999999, ... 99999999 the code N, what is N? In other words, how big is the result space?

Well, one way to think about this is noticing that this is a bijection of the problem of finding the number of monotonic paths in an N x M grid, where N = 1,000,000 and M = 100,000,000. In other words, if you have a grid that is 1,000,000 wide and 100,000,000 tall, how many shortest paths from the bottom left to the top right are there? Shortest paths of course require you only ever either move right or up (if you were to move down or left you would be undoing previously accomplished progress). To see how this is a bijection of our number sorting problem, observe the following:

You can imagine any horizontal leg in our path as a number in our ordering, where the Y location of the leg represents the value.

So if the path simply moves to the right all the way to the end, then jumps all the way to the top, that is equivalent to the ordering 0,0,0,...,0. if it instead begins by jumping all the way to the top and then moves to the right 1,000,000 times, that is equivalent to 99999999,99999999,..., 99999999. A path where it moves right once, then up once, then right one, then up once, etc to the very end (then necessarily jumps all the way to the top), is equivalent to 0,1,2,3,...,999999.

Luckily for us this problem has already been solved, such a grid has (N + M) Choose (M) paths:

(1,000,000 + 100,000,000) Choose (100,000,000) ~= 2.27 * 10^2436455

N thus equals 2.27 * 10^2436455, and so the code 0 represents 0,0,0,...,0 and the code 2.27 * 10^2436455 and some change represents 99999999,99999999,..., 99999999.

In order to store all the numbers from 0 to 2.27 * 10^2436455 you need lg2 (2.27 * 10^2436455) = 8.0937 * 10^6 bits.

1 megabyte = 8388608 bits > 8093700 bits

So it appears that we at least actually have enough room to store the result! Now of course the interesting bit is doing the sorting as the numbers stream in. Not sure the best approach to this is given we have 294908 bits remaining. I imagine an interesting technique would be to at each point assume that that is is the entire ordering, finding the code for that ordering, and then as you receive a new number going back and updating the previous code. Hand wave hand wave.

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I think the other answers are just more subtle about their hand waving. Given that we now know the size of the result space, we know how much space we absolutely need. No other answer will be able to store every possible answer in anything smaller than 8093700 bits, since thats how many final states there can be. Doing compress(final-state) can at best sometimes reduce the space, but there will always be some answer that requires the full space (no compression algorithm can compress every input). –  Francisco Ryan Tolmasky I Oct 22 '12 at 1:22

Now aiming to an actual solution, covering all possible cases of input in the 8 digit range with only 1MB of RAM. NOTE: work in progress, tomorrow will continue. Using arithmetic coding of deltas of the sorted ints, worst case for 1M sorted ints would cost about 7bits per entry (since 99999999/1000000 is 99, and log2(99) is almost 7 bits).

But you need the 1m integers sorted to get to 7 or 8 bits! Shorter series would have bigger deltas, therefore more bits per element.

I'm working on taking as many as possible and compressing (almost) in-place. First batch of close to 250K ints would need about 9 bits each at best. So result would take about 275KB. Repeat with remaining free memory a few times. Then decompress-merge-in-place-compress those compressed chunks. This is quite hard, but possible. I think.

The merged lists would get closer and closer to the 7bit per integer target. But I don't know how many iterations it would take of the merge loop. Perhaps 3.

But the imprecision of the arithmetic coding implementation might make it impossible. If this problem is possible at all, it would be extremely tight.

Any volunteers?

-

We have 1Mb - 3Kb ram = 2^23 - 3*2^13 bits = 8388608 - 24576 = 8364032 bits available.

We are given 10^6 numbers in a 10^8 range. This gives an average gap of ~100 < 2^7 = 128

Let's first consider the simpler problem of fairly evenly spaced numbers when all gaps are < 128. This is easy. Just store the first number and the 7-bit gaps:

(27 bits) + 10^6 7-bit gap numbers = 7000027 bits required

Note repeated numbers have gaps of 0.

But what if we have gaps larger than 127?

OK, lets say a gap size < 127 is represented directly, but a gap size of 127 is followed by a continuous 8-bit encoding for the actual gap length:

`````` 10xxxxxx xxxxxxxx                       = 127 .. 16,383
110xxxxx xxxxxxxx xxxxxxxx              = 16384 .. 2,097,151
``````

etc

Note this number representation describes it's own length so we know when the next gap number starts.

With just small gaps < 127, this still requires 7000027 bits

There can be up to (10^8)/(2^7) = 781250 23-bit gap number, requiring an extra 16*781,250 = 12,500,000 bits which is too much. We need a more compact and slowly increasing representation of gaps.

The average gap size is 100 so if we reorder them as [100,99,101,98,102,...,2,198,1,199,0,200,201,202,...] and index this with a dense binary Fibonacci base encoding with no pairs of zeros (eg: 11011=8+5+2+1=16) with numbers delimited by '00' then I think we can keep the gap representation short enough, but it needs more analysis.

-

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 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.

-

To represent the sorted array one can just store the first element and the difference between adjacent elements. In this way we are concerned with encoding 10^6 elements that can sum up to at most 10^8. Let's call this D. To encode the elements of D one can use a Huffman code. The dictionary for the Huffman code can be created on the go and the array updated every time a new item is inserted in the sorted array (insertion sort). Note that when the dictionary changes because of a new item the whole array should be updated to match the new encoding.

The average number of bits for encoding each element of D is maximized if we have equal number of each unique element. Say elements d1, d2, ..., dN in D each appear F times. In that case (in worst case we have both 0 and 10^8 in input sequence) we have

sum(1<=i<=N) F. di = 10^8

where

sum(1<=i<=N) F = 10^6, or F=10^6/N and the normalized frequency will be p= F/10^=1/N

The average number of bits will be -log2(1/P) = log2(N). Under these circumstances we should find a case that maximizes N. This happens if we have consecutive numbers for di starting from 0, or, di= i-1, therefore

10^8=sum(1<=i<=N) F. di = sum(1<=i<=N) (10^6/N) (i-1) = (10^6/N) N (N-1)/2

i.e.

N <= 201. And for this case average number of bits is log2(201)=7.6511 which means we will need around 1 byte per input element for saving the sorted array. Note that this doesn't mean D in general cannot have more than 201 elements. It just sows that if elements of D are uniformly distributed, it cannot have more than 201 unique values.

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I think you have forgotten that number can be duplicate. –  bestsss Oct 23 '12 at 9:32

You just need to store the differences between the numbers in sequence, and use an encoding to compress these sequence numbers. We have 2^23 bits. We shall divide it into 6bit chunks, and let the last bit indicate whether the number extends to another 6 bits (5bits plus extending chunk).

Thus, 000010 is 1, and 000100 is 2. 000001100000 is 128. Now, we consider the worst cast in representing differences in sequence of a numbers up to 10,000,000. There can be 10,000,000/2^5 differences greater than 2^5, 10,000,000/2^10 differences greater than 2^10, and 10,000,000/2^15 differences greater than 2^15, etc.

So, we add how many bits it will take to represent our the sequence. We have 1,000,000*6 + roundup(10,000,000/2^5)*6+roundup(10,000,000/2^10)*6+roundup(10,000,000/2^15)*6+roundup(10,000,000/2^20)*4=7935479.

2^24 = 8388608. Since 8388608 > 7935479, we should easily have enough memory. We will probably need another little bit of memory to store the sum of where are when we insert new numbers. We then go through the sequence, and find where to insert our new number, decrease the next difference if necessary, and shift everything after it right.

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