Reason for the number 5381 in the DJB hash function? - algorithm

Can anyone tell me why the number 5381 is used in the DJB hash function?
The DJB hash function is defined as:
h 0 = 5381
h i = 33h i - 1 + s i
Here's a C implementation:
unsigned int DJBHash(char* str, unsigned int len)
{
unsigned int hash = 5381;
unsigned int i = 0;
for(i = 0; i < len; str++, i++)
{
hash = ((hash << 5) + hash) + (*str);
}
return hash;
}

I stumbled across a comment that sheds some light on what DJB is up to:
/*
* DJBX33A (Daniel J. Bernstein, Times 33 with Addition)
*
* This is Daniel J. Bernstein's popular `times 33' hash function as
* posted by him years ago on comp.lang.c. It basically uses a function
* like ``hash(i) = hash(i-1) * 33 + str[i]''. This is one of the best
* known hash functions for strings. Because it is both computed very
* fast and distributes very well.
*
* The magic of number 33, i.e. why it works better than many other
* constants, prime or not, has never been adequately explained by
* anyone. So I try an explanation: if one experimentally tests all
* multipliers between 1 and 256 (as RSE did now) one detects that even
* numbers are not useable at all. The remaining 128 odd numbers
* (except for the number 1) work more or less all equally well. They
* all distribute in an acceptable way and this way fill a hash table
* with an average percent of approx. 86%.
*
* If one compares the Chi^2 values of the variants, the number 33 not
* even has the best value. But the number 33 and a few other equally
* good numbers like 17, 31, 63, 127 and 129 have nevertheless a great
* advantage to the remaining numbers in the large set of possible
* multipliers: their multiply operation can be replaced by a faster
* operation based on just one shift plus either a single addition
* or subtraction operation. And because a hash function has to both
* distribute good _and_ has to be very fast to compute, those few
* numbers should be preferred and seems to be the reason why Daniel J.
* Bernstein also preferred it.
*
*
* -- Ralf S. Engelschall <rse#engelschall.com>
*/
That's a slightly different hash function than the one you're looking at, though it does use the 5381 magic number. The code below that comment at the link target has been unrolled.
Then I found this:
Magic Constant 5381:
1. odd number
2. prime number
3. deficient number
4. 001/010/100/000/101 b
There is also this answer to Can anybody explain the logic behind djb2 hash function? It references a post by DJB himself to a mailing list that mentions 5381 (excerpt from that answer excerpted here):
[...] practically any good multiplier works. I think you're worrying
about the fact that 31c + d doesn't cover any reasonable range of hash
values if c and d are between 0 and 255. That's why, when I discovered
the 33 hash function and started using it in my compressors, I started
with a hash value of 5381. I think you'll find that this does just as
well as a 261 multiplier.

5381 is just a number that, in testing, resulted in fewer collisions and better avalanching. You'll find "magic constants" in just about every hash algo.

I found a very interesting property of this number may be that can be a reason for that.
5381 is 709th prime.
709 is 127th prime.
127 is 31st prime.
31 is 11th prime.
11 is 5th prime.
5 is 3rd prime.
3 is 2nd prime.
2 is 1st prime.
5381 is the first number for which this happens for 8 times. 5381st prime may exceed the limit of signed int so it is a good point to stop the chain.

Related

Minimize integer round-off error in PLL frequency calculation

On a particular STM32 microcontroller, the system clock is driven by a PLL whose frequency F is given by the following formula:
F := (S/M * (N + K/8192)) / P
S is the PLL input source frequency (1 - 64000000, or 64 MHz).
The other factors M, N, K, and P are the parameters the user can modify to calibrate the frequency. Judging by the bitmasks in the SDK I'm using, the value of each can be limited to a maximum of M < 64, N < 512, K < 8192, and P < 128.
Unfortunately, my target firmware does not have FPU support, so floating-point arithmetic is out. Instead, I need to compute F using integer-only arithmetic.
I have tried to rearrange the given formula with 3 goals in mind:
Expand and distribute all multiplication factors
Minimize the number of factors in each denominator
Minimize the total number of divisions performed
If two expressions have the same number of divisions, choose the one whose denominators have the least maximum (identified in earlier paragraph)
However, each of my attempts to expand and rearrange the expression all produce errors greater than the original formula as it was first expressed verbatim.
To test out different arrangements of the formula and compare error, I've written a small Go program you can run online here.
Is it possible to improve this formula so that error is minimized when using integer arithmetic? Also are any of my goals listed above incorrect or useless?
I took your program (your first parentheses is redundant, so I removed):
S K
--- * ( N + ------ )
M 8192
--------------------
P
and ran through QuickMath [1], and I got this:
S * (8192 * N + K)
------------------
8192 * M * P
or in Go code:
S * (8192 * N + K) / (8192 * M * P)
So it does reduce the amount of divisions. You could improve it further by
pulling out the lower constant:
S * (8192 * N + K) / (M * P) >> 13
https://quickmath.com
Looking at the answer by #StevenPerry, I realized the majority of error is introduced by the limited precision we have to represent K/8192. This error then gets propagated into the other factors and dividends.
Postponing that division, however, often results in integer overflow before its ever reached. Thus, the solution I've found unfortunately depends on widening these operands to 64-bit.
The result is of the same form as the other answer, but it must be emphasized that widening the operands to 64-bit is essential. In Go source code, this looks like:
var S, N, M, P, K uint32
...
F := uint32(uint64(S) * uint64(8192*N+K) / uint64(8192*M*P))
To see the accuracy of all three of these expressions, run the code yourself on the Go Playground.

Representing a multiset as a sequence of bits

We can use a bitmask to represent set presence in a finite (or at least indexed) domain efficiently, for instance to represent the letters in car we could represent this in a 26-bit set like so:
abcdefghijklmnopqrstuvwxyz
10100000000000000100000000
However of course this can only represent presence, not duplicates - carry for instance actually has two rs, but a set cannot represent that.
A multiset represents a count, not just existence, so we can count duplicates, however it's not clear to me if this can be represented logically in a single number.
One idea, suggested by a coworker, would be to use primes as our indices, and represent a multiset by it's prime factorization. So our cases above would become:
car = 2^1 * 3^0 * 5^1 * ... * 61^1 * ....
carry = 2^1 * 3^0 * 5^1 * ... * 61^2 * ... 97^1 * 101^0
Is this a sound way to represent multisets? Are there better binary representations of such a concept?
Trivial: Use k bits instead of 1 bit for each element of the universe. Concatenate them to get a single number, if you care about that, but you can equivalently consider it an array of numbers (the bitset equivalent, an array of booleans, is also valid and useful).
This probably takes more space than the prime factor approach, but on the bright side, it's still very space efficient and you can test presence (and extract the count) with an array lookup and some bit fiddling, as opposed to looking up/computing the relevant prime and performing integer division.

"interval is empty", Lua math.random isn't working for large numbers?

I didn't know if this is a bug in Lua itself or if I was doing something wrong. I couldn't find anything about it anywhere. I am using Lua for Windows (Lua 5.1.4):
>return math.random(0, 1000000000)
1251258
This returns a random integer between 0 and 10000000000, as expected. This seems to work for all other values. But if I add a single 0:
>return math.random(0, 10000000000)
stdin:1: bad argument #2 to 'random' (interval is empty)
Any number higher than that does the same thing.
I tried to figure out exactly how high a number has to be to cause this and found something even weirder:
>return math.random(0, 2147483647)
-75617745
If the value is 2147483647 then it gives me negative numbers. Any higher than that and it throws an error. Any lower than that and it works fine.
That's 0b1111111111111111111111111111111 in binary, 31 binary digits exactly. I am not sure what that means though.
This unexpected behavior (bug?) is due to how math.random treats the input arguments passed in Lua 5.1. From lmathlib.c:
case 2: { /* lower and upper limits */
int l = luaL_checkint(L, 1);
int u = luaL_checkint(L, 2);
luaL_argcheck(L, l<=u, 2, "interval is empty");
lua_pushnumber(L, floor(r*(u-l+1))+l); /* int between `l' and `u' */
break;
}
As you may know in C, a standard int can represent values -2,147,483,648 to 2,147,483,647. Adding +1 to 2,147,483,647, like in your use-case, will overflow and wrap around the value giving -2,147,483,648. The end result is negative since you're multiplying a positive with a negative number.
Furthermore, anything above 2,147,483,647 will fail the luaL_argcheck due to overflow wraparound.
There are a few ways to address this problem:
Upgrade to Lua 5.2. That one has since fixed this issue by treating the input arguments as lua_Number instead.
Switch to LuaJIT which does not have this integer overflow issue.
Patch the Lua 5.1 source yourself with the fix and recompile.
Modify your random range so it does not overflow.
If you need a range that is larger than what the random function supports (32 bit signed integers or 2^31 due to sign bit, because math.random is at C level), but smaller than the range of Lua "number" type (based on What is the maximum value of a number in Lua?, 2^52, or maybe even 2^53), you could try generating two random numbers: scale the first to the range desired; add the second to "fill the gap". For example, say you want a range of 0 to 2^36. The largest from math.random is 2^31. So you could do:
-- 2^36 = 2^31 * 2^5 so
scale = 2^5
baseRand = scale * math.random(0, 2^31)
-- baseRand is now between 0 and 2^36 but there are gaps of 2^5 in the set
-- of possible values; fill the gaps with second random number:
fillGap = math.random(0, 2^5)
randNum = baseRand + fillGap
This will work as long as the desired range is less than the Lua interpreter's maximum for Lua numbers, which is a configurable compile time parameter but if you use stock build it is 2^52, a very large number (although not as large as largest long integer, 2^63).
Note also that largest positive N-bit integer is 2^N-1 (not 2^N), but the above technique can be applied to any range, you could have for instance scale = 10^6 then randNum = 10^6 * math.random(0, 10^8) + math.random(0, 10^6).

Calculating unique value from given numbers

Let's say I have some 6 random numbers and I want to calculate some unique value from these numbers.
Edit:
Allowed operations are +, -, *, and /. Every number could be used only once. You dont have to use all numbers.
Example:
Given numbers: 3, 6, 100, 50, 25, 75
Requested result: 953
3 + 6 = 9
9 * 100 = 900
900 + 50 = 950
75 / 25 = 3
3 + 950 = 953
What could be easiest algorithmic approach to write a program that solves this problem?
The easiest approach is to try them all: you have six numbers, meaning that there are up to five spots where you can place an operator, and up to 6! permutations. Given that there are only four operators, you need to go through 6!*4^5, or 737280 possibilities. This can be easily done with a recursive function, or even with nested loops. Depending on the language, you could use a library function to deal with permutations.
A language-agnostic recursive approach would have you define three functions:
int calc(int nums[6], int ops[5], int countNums) {
// Calculate the results for a given sequence of numbers
// with the specified operators.
// nums are your numbers; only countNums need to be used
// ops are your operators; only countNums-1 need to be used
// countNums is the number of items to use; it must be from 1 to 6
}
void permutations(int nums[6], int perm[6], int pos) {
// Produces all permutations of the original numbers
// nums are the original numbers
// perm, 0 through pos, is the indexes of nums used in the permutation so far
// pos, is the number of perm items filled so far
}
void solveRecursive(int numPerm[6], int permLen, int ops[5], int pos) {
// Tries all combinations of operations on the given permutation.
// numPermis the permutation of the original numbers
// permLen is the number of items used in the permutation
// ops 0 through pos are operators to be placed between elements
// of the permutation
// pos is the number of operators provided so far.
}
The easiest algorithmic approach would, I think, be backtracking. It's fairly easy to implement and will always find a solution if one exists. The basic idea is recursive: make an arbitrary choice at each step of building a solution and proceed from there. If it doesn't work out, try a different choice. When you run out of choices, report failure to the previous choice point (or report failure to find a solution if there is no previous choice point).
Your choices are: how many numbers will be involved, what each number is (a choice each number position), and how they are connected by operators (a choice for each operator position).
When you mention "unique numbers", assuming that you mean a result in the possible universe of results generated using all the numbers at hand.
If so, why not try a permutation of all operators and available numbers for a start?
If you want to guarantee that you generate a unique number from those numbers, with no chance of getting the same number from a different set of numbers, then you should use radix arithmetic, similar to decimal, hex, etc.
But you need to know the max values of the numbers.
Basically, it would be A + B * MAX_A + C * MAX_A * MAX_B + D * MAX_A * MAX_B * MAX_C + E * MAX_A * MAX_B * MAX_C * MAX_D + F * MAX_A * ... * MAX_E
use recursion to permutate the numbers and operators. it's O(6!*4^5)

Generate an integer that is not among four billion given ones

I have been given this interview question:
Given an input file with four billion integers, provide an algorithm to generate an integer which is not contained in the file. Assume you have 1 GB memory. Follow up with what you would do if you have only 10 MB of memory.
My analysis:
The size of the file is 4×109×4 bytes = 16 GB.
We can do external sorting, thus letting us know the range of the integers.
My question is what is the best way to detect the missing integer in the sorted big integer sets?
My understanding (after reading all the answers):
Assuming we are talking about 32-bit integers, there are 232 = 4*109 distinct integers.
Case 1: we have 1 GB = 1 * 109 * 8 bits = 8 billion bits memory.
Solution:
If we use one bit representing one distinct integer, it is enough. we don't need sort.
Implementation:
int radix = 8;
byte[] bitfield = new byte[0xffffffff/radix];
void F() throws FileNotFoundException{
Scanner in = new Scanner(new FileReader("a.txt"));
while(in.hasNextInt()){
int n = in.nextInt();
bitfield[n/radix] |= (1 << (n%radix));
}
for(int i = 0; i< bitfield.lenght; i++){
for(int j =0; j<radix; j++){
if( (bitfield[i] & (1<<j)) == 0) System.out.print(i*radix+j);
}
}
}
Case 2: 10 MB memory = 10 * 106 * 8 bits = 80 million bits
Solution:
For all possible 16-bit prefixes, there are 216 number of
integers = 65536, we need 216 * 4 * 8 = 2 million bits. We need build 65536 buckets. For each bucket, we need 4 bytes holding all possibilities because the worst case is all the 4 billion integers belong to the same bucket.
Build the counter of each bucket through the first pass through the file.
Scan the buckets, find the first one who has less than 65536 hit.
Build new buckets whose high 16-bit prefixes are we found in step2
through second pass of the file
Scan the buckets built in step3, find the first bucket which doesnt
have a hit.
The code is very similar to above one.
Conclusion:
We decrease memory through increasing file pass.
A clarification for those arriving late: The question, as asked, does not say that there is exactly one integer that is not contained in the file—at least that's not how most people interpret it. Many comments in the comment thread are about that variation of the task, though. Unfortunately the comment that introduced it to the comment thread was later deleted by its author, so now it looks like the orphaned replies to it just misunderstood everything. It's very confusing, sorry.
Assuming that "integer" means 32 bits: 10 MB of space is more than enough for you to count how many numbers there are in the input file with any given 16-bit prefix, for all possible 16-bit prefixes in one pass through the input file. At least one of the buckets will have be hit less than 216 times. Do a second pass to find of which of the possible numbers in that bucket are used already.
If it means more than 32 bits, but still of bounded size: Do as above, ignoring all input numbers that happen to fall outside the (signed or unsigned; your choice) 32-bit range.
If "integer" means mathematical integer: Read through the input once and keep track of the largest number length of the longest number you've ever seen. When you're done, output the maximum plus one a random number that has one more digit. (One of the numbers in the file may be a bignum that takes more than 10 MB to represent exactly, but if the input is a file, then you can at least represent the length of anything that fits in it).
Statistically informed algorithms solve this problem using fewer passes than deterministic approaches.
If very large integers are allowed then one can generate a number that is likely to be unique in O(1) time. A pseudo-random 128-bit integer like a GUID will only collide with one of the existing four billion integers in the set in less than one out of every 64 billion billion billion cases.
If integers are limited to 32 bits then one can generate a number that is likely to be unique in a single pass using much less than 10 MB. The odds that a pseudo-random 32-bit integer will collide with one of the 4 billion existing integers is about 93% (4e9 / 2^32). The odds that 1000 pseudo-random integers will all collide is less than one in 12,000 billion billion billion (odds-of-one-collision ^ 1000). So if a program maintains a data structure containing 1000 pseudo-random candidates and iterates through the known integers, eliminating matches from the candidates, it is all but certain to find at least one integer that is not in the file.
A detailed discussion on this problem has been discussed in Jon Bentley "Column 1. Cracking the Oyster" Programming Pearls Addison-Wesley pp.3-10
Bentley discusses several approaches, including external sort, Merge Sort using several external files etc., But the best method Bentley suggests is a single pass algorithm using bit fields, which he humorously calls "Wonder Sort" :)
Coming to the problem, 4 billion numbers can be represented in :
4 billion bits = (4000000000 / 8) bytes = about 0.466 GB
The code to implement the bitset is simple: (taken from solutions page )
#define BITSPERWORD 32
#define SHIFT 5
#define MASK 0x1F
#define N 10000000
int a[1 + N/BITSPERWORD];
void set(int i) { a[i>>SHIFT] |= (1<<(i & MASK)); }
void clr(int i) { a[i>>SHIFT] &= ~(1<<(i & MASK)); }
int test(int i){ return a[i>>SHIFT] & (1<<(i & MASK)); }
Bentley's algorithm makes a single pass over the file, setting the appropriate bit in the array and then examines this array using test macro above to find the missing number.
If the available memory is less than 0.466 GB, Bentley suggests a k-pass algorithm, which divides the input into ranges depending on available memory. To take a very simple example, if only 1 byte (i.e memory to handle 8 numbers ) was available and the range was from 0 to 31, we divide this into ranges of 0 to 7, 8-15, 16-22 and so on and handle this range in each of 32/8 = 4 passes.
HTH.
Since the problem does not specify that we have to find the smallest possible number that is not in the file we could just generate a number that is longer than the input file itself. :)
For the 1 GB RAM variant you can use a bit vector. You need to allocate 4 billion bits == 500 MB byte array. For each number you read from the input, set the corresponding bit to '1'. Once you done, iterate over the bits, find the first one that is still '0'. Its index is the answer.
If they are 32-bit integers (likely from the choice of ~4 billion numbers close to 232), your list of 4 billion numbers will take up at most 93% of the possible integers (4 * 109 / (232) ). So if you create a bit-array of 232 bits with each bit initialized to zero (which will take up 229 bytes ~ 500 MB of RAM; remember a byte = 23 bits = 8 bits), read through your integer list and for each int set the corresponding bit-array element from 0 to 1; and then read through your bit-array and return the first bit that's still 0.
In the case where you have less RAM (~10 MB), this solution needs to be slightly modified. 10 MB ~ 83886080 bits is still enough to do a bit-array for all numbers between 0 and 83886079. So you could read through your list of ints; and only record #s that are between 0 and 83886079 in your bit array. If the numbers are randomly distributed; with overwhelming probability (it differs by 100% by about 10-2592069) you will find a missing int). In fact, if you only choose numbers 1 to 2048 (with only 256 bytes of RAM) you'd still find a missing number an overwhelming percentage (99.99999999999999999999999999999999999999999999999999999999999995%) of the time.
But let's say instead of having about 4 billion numbers; you had something like 232 - 1 numbers and less than 10 MB of RAM; so any small range of ints only has a small possibility of not containing the number.
If you were guaranteed that each int in the list was unique, you could sum the numbers and subtract the sum with one # missing to the full sum (½)(232)(232 - 1) = 9223372034707292160 to find the missing int. However, if an int occurred twice this method will fail.
However, you can always divide and conquer. A naive method, would be to read through the array and count the number of numbers that are in the first half (0 to 231-1) and second half (231, 232). Then pick the range with fewer numbers and repeat dividing that range in half. (Say if there were two less number in (231, 232) then your next search would count the numbers in the range (231, 3*230-1), (3*230, 232). Keep repeating until you find a range with zero numbers and you have your answer. Should take O(lg N) ~ 32 reads through the array.
That method was inefficient. We are only using two integers in each step (or about 8 bytes of RAM with a 4 byte (32-bit) integer). A better method would be to divide into sqrt(232) = 216 = 65536 bins, each with 65536 numbers in a bin. Each bin requires 4 bytes to store its count, so you need 218 bytes = 256 kB. So bin 0 is (0 to 65535=216-1), bin 1 is (216=65536 to 2*216-1=131071), bin 2 is (2*216=131072 to 3*216-1=196607). In python you'd have something like:
import numpy as np
nums_in_bin = np.zeros(65536, dtype=np.uint32)
for N in four_billion_int_array:
nums_in_bin[N // 65536] += 1
for bin_num, bin_count in enumerate(nums_in_bin):
if bin_count < 65536:
break # we have found an incomplete bin with missing ints (bin_num)
Read through the ~4 billion integer list; and count how many ints fall in each of the 216 bins and find an incomplete_bin that doesn't have all 65536 numbers. Then you read through the 4 billion integer list again; but this time only notice when integers are in that range; flipping a bit when you find them.
del nums_in_bin # allow gc to free old 256kB array
from bitarray import bitarray
my_bit_array = bitarray(65536) # 32 kB
my_bit_array.setall(0)
for N in four_billion_int_array:
if N // 65536 == bin_num:
my_bit_array[N % 65536] = 1
for i, bit in enumerate(my_bit_array):
if not bit:
print bin_num*65536 + i
break
Why make it so complicated? You ask for an integer not present in the file?
According to the rules specified, the only thing you need to store is the largest integer that you encountered so far in the file. Once the entire file has been read, return a number 1 greater than that.
There is no risk of hitting maxint or anything, because according to the rules, there is no restriction to the size of the integer or the number returned by the algorithm.
This can be solved in very little space using a variant of binary search.
Start off with the allowed range of numbers, 0 to 4294967295.
Calculate the midpoint.
Loop through the file, counting how many numbers were equal, less than or higher than the midpoint value.
If no numbers were equal, you're done. The midpoint number is the answer.
Otherwise, choose the range that had the fewest numbers and repeat from step 2 with this new range.
This will require up to 32 linear scans through the file, but it will only use a few bytes of memory for storing the range and the counts.
This is essentially the same as Henning's solution, except it uses two bins instead of 16k.
EDIT Ok, this wasn't quite thought through as it assumes the integers in the file follow some static distribution. Apparently they don't need to, but even then one should try this:
There are ≈4.3 billion 32-bit integers. We don't know how they are distributed in the file, but the worst case is the one with the highest Shannon entropy: an equal distribution. In this case, the probablity for any one integer to not occur in the file is
( (2³²-1)/2³² )⁴ ⁰⁰⁰ ⁰⁰⁰ ⁰⁰⁰ ≈ .4
The lower the Shannon entropy, the higher this probability gets on the average, but even for this worst case we have a chance of 90% to find a nonoccurring number after 5 guesses with random integers. Just create such numbers with a pseudorandom generator, store them in a list. Then read int after int and compare it to all of your guesses. When there's a match, remove this list entry. After having been through all of the file, chances are you will have more than one guess left. Use any of them. In the rare (10% even at worst case) event of no guess remaining, get a new set of random integers, perhaps more this time (10->99%).
Memory consumption: a few dozen bytes, complexity: O(n), overhead: neclectable as most of the time will be spent in the unavoidable hard disk accesses rather than comparing ints anyway.
The actual worst case, when we do not assume a static distribution, is that every integer occurs max. once, because then only
1 - 4000000000/2³² ≈ 6%
of all integers don't occur in the file. So you'll need some more guesses, but that still won't cost hurtful amounts of memory.
If you have one integer missing from the range [0, 2^x - 1] then just xor them all together. For example:
>>> 0 ^ 1 ^ 3
2
>>> 0 ^ 1 ^ 2 ^ 3 ^ 4 ^ 6 ^ 7
5
(I know this doesn't answer the question exactly, but it's a good answer to a very similar question.)
They may be looking to see if you have heard of a probabilistic Bloom Filter which can very efficiently determine absolutely if a value is not part of a large set, (but can only determine with high probability it is a member of the set.)
Based on the current wording in the original question, the simplest solution is:
Find the maximum value in the file, then add 1 to it.
Use a BitSet. 4 billion integers (assuming up to 2^32 integers) packed into a BitSet at 8 per byte is 2^32 / 2^3 = 2^29 = approx 0.5 Gb.
To add a bit more detail - every time you read a number, set the corresponding bit in the BitSet. Then, do a pass over the BitSet to find the first number that's not present. In fact, you could do this just as effectively by repeatedly picking a random number and testing if it's present.
Actually BitSet.nextClearBit(0) will tell you the first non-set bit.
Looking at the BitSet API, it appears to only support 0..MAX_INT, so you may need 2 BitSets - one for +'ve numbers and one for -'ve numbers - but the memory requirements don't change.
If there is no size limit, the quickest way is to take the length of the file, and generate the length of the file+1 number of random digits (or just "11111..." s). Advantage: you don't even need to read the file, and you can minimize memory use nearly to zero. Disadvantage: You will print billions of digits.
However, if the only factor was minimizing memory usage, and nothing else is important, this would be the optimal solution. It might even get you a "worst abuse of the rules" award.
If we assume that the range of numbers will always be 2^n (an even power of 2), then exclusive-or will work (as shown by another poster). As far as why, let's prove it:
The Theory
Given any 0 based range of integers that has 2^n elements with one element missing, you can find that missing element by simply xor-ing the known values together to yield the missing number.
The Proof
Let's look at n = 2. For n=2, we can represent 4 unique integers: 0, 1, 2, 3. They have a bit pattern of:
0 - 00
1 - 01
2 - 10
3 - 11
Now, if we look, each and every bit is set exactly twice. Therefore, since it is set an even number of times, and exclusive-or of the numbers will yield 0. If a single number is missing, the exclusive-or will yield a number that when exclusive-ored with the missing number will result in 0. Therefore, the missing number, and the resulting exclusive-ored number are exactly the same. If we remove 2, the resulting xor will be 10 (or 2).
Now, let's look at n+1. Let's call the number of times each bit is set in n, x and the number of times each bit is set in n+1 y. The value of y will be equal to y = x * 2 because there are x elements with the n+1 bit set to 0, and x elements with the n+1 bit set to 1. And since 2x will always be even, n+1 will always have each bit set an even number of times.
Therefore, since n=2 works, and n+1 works, the xor method will work for all values of n>=2.
The Algorithm For 0 Based Ranges
This is quite simple. It uses 2*n bits of memory, so for any range <= 32, 2 32 bit integers will work (ignoring any memory consumed by the file descriptor). And it makes a single pass of the file.
long supplied = 0;
long result = 0;
while (supplied = read_int_from_file()) {
result = result ^ supplied;
}
return result;
The Algorithm For Arbitrary Based Ranges
This algorithm will work for ranges of any starting number to any ending number, as long as the total range is equal to 2^n... This basically re-bases the range to have the minimum at 0. But it does require 2 passes through the file (the first to grab the minimum, the second to compute the missing int).
long supplied = 0;
long result = 0;
long offset = INT_MAX;
while (supplied = read_int_from_file()) {
if (supplied < offset) {
offset = supplied;
}
}
reset_file_pointer();
while (supplied = read_int_from_file()) {
result = result ^ (supplied - offset);
}
return result + offset;
Arbitrary Ranges
We can apply this modified method to a set of arbitrary ranges, since all ranges will cross a power of 2^n at least once. This works only if there is a single missing bit. It takes 2 passes of an unsorted file, but it will find the single missing number every time:
long supplied = 0;
long result = 0;
long offset = INT_MAX;
long n = 0;
double temp;
while (supplied = read_int_from_file()) {
if (supplied < offset) {
offset = supplied;
}
}
reset_file_pointer();
while (supplied = read_int_from_file()) {
n++;
result = result ^ (supplied - offset);
}
// We need to increment n one value so that we take care of the missing
// int value
n++
while (n == 1 || 0 != (n & (n - 1))) {
result = result ^ (n++);
}
return result + offset;
Basically, re-bases the range around 0. Then, it counts the number of unsorted values to append as it computes the exclusive-or. Then, it adds 1 to the count of unsorted values to take care of the missing value (count the missing one). Then, keep xoring the n value, incremented by 1 each time until n is a power of 2. The result is then re-based back to the original base. Done.
Here's the algorithm I tested in PHP (using an array instead of a file, but same concept):
function find($array) {
$offset = min($array);
$n = 0;
$result = 0;
foreach ($array as $value) {
$result = $result ^ ($value - $offset);
$n++;
}
$n++; // This takes care of the missing value
while ($n == 1 || 0 != ($n & ($n - 1))) {
$result = $result ^ ($n++);
}
return $result + $offset;
}
Fed in an array with any range of values (I tested including negatives) with one inside that range which is missing, it found the correct value each time.
Another Approach
Since we can use external sorting, why not just check for a gap? If we assume the file is sorted prior to the running of this algorithm:
long supplied = 0;
long last = read_int_from_file();
while (supplied = read_int_from_file()) {
if (supplied != last + 1) {
return last + 1;
}
last = supplied;
}
// The range is contiguous, so what do we do here? Let's return last + 1:
return last + 1;
Trick question, unless it's been quoted improperly. Just read through the file once to get the maximum integer n, and return n+1.
Of course you'd need a backup plan in case n+1 causes an integer overflow.
Check the size of the input file, then output any number which is too large to be represented by a file that size. This may seem like a cheap trick, but it's a creative solution to an interview problem, it neatly sidesteps the memory issue, and it's technically O(n).
void maxNum(ulong filesize)
{
ulong bitcount = filesize * 8; //number of bits in file
for (ulong i = 0; i < bitcount; i++)
{
Console.Write(9);
}
}
Should print 10 bitcount - 1, which will always be greater than 2 bitcount. Technically, the number you have to beat is 2 bitcount - (4 * 109 - 1), since you know there are (4 billion - 1) other integers in the file, and even with perfect compression they'll take up at least one bit each.
The simplest approach is to find the minimum number in the file, and return 1 less than that. This uses O(1) storage, and O(n) time for a file of n numbers. However, it will fail if number range is limited, which could make min-1 not-a-number.
The simple and straightforward method of using a bitmap has already been mentioned. That method uses O(n) time and storage.
A 2-pass method with 2^16 counting-buckets has also been mentioned. It reads 2*n integers, so uses O(n) time and O(1) storage, but it cannot handle datasets with more than 2^16 numbers. However, it's easily extended to (eg) 2^60 64-bit integers by running 4 passes instead of 2, and easily adapted to using tiny memory by using only as many bins as fit in memory and increasing the number of passes correspondingly, in which case run time is no longer O(n) but instead is O(n*log n).
The method of XOR'ing all the numbers together, mentioned so far by rfrankel and at length by ircmaxell answers the question asked in stackoverflow#35185, as ltn100 pointed out. It uses O(1) storage and O(n) run time. If for the moment we assume 32-bit integers, XOR has a 7% probability of producing a distinct number. Rationale: given ~ 4G distinct numbers XOR'd together, and ca. 300M not in file, the number of set bits in each bit position has equal chance of being odd or even. Thus, 2^32 numbers have equal likelihood of arising as the XOR result, of which 93% are already in file. Note that if the numbers in file aren't all distinct, the XOR method's probability of success rises.
Strip the white space and non numeric characters from the file and append 1. Your file now contains a single number not listed in the original file.
From Reddit by Carbonetc.
For some reason, as soon as I read this problem I thought of diagonalization. I'm assuming arbitrarily large integers.
Read the first number. Left-pad it with zero bits until you have 4 billion bits. If the first (high-order) bit is 0, output 1; else output 0. (You don't really have to left-pad: you just output a 1 if there are not enough bits in the number.) Do the same with the second number, except use its second bit. Continue through the file in this way. You will output a 4-billion bit number one bit at a time, and that number will not be the same as any in the file. Proof: it were the same as the nth number, then they would agree on the nth bit, but they don't by construction.
You can use bit flags to mark whether an integer is present or not.
After traversing the entire file, scan each bit to determine if the number exists or not.
Assuming each integer is 32 bit, they will conveniently fit in 1 GB of RAM if bit flagging is done.
Just for the sake of completeness, here is another very simple solution, which will most likely take a very long time to run, but uses very little memory.
Let all possible integers be the range from int_min to int_max, and
bool isNotInFile(integer) a function which returns true if the file does not contain a certain integer and false else (by comparing that certain integer with each integer in the file)
for (integer i = int_min; i <= int_max; ++i)
{
if (isNotInFile(i)) {
return i;
}
}
For the 10 MB memory constraint:
Convert the number to its binary representation.
Create a binary tree where left = 0 and right = 1.
Insert each number in the tree using its binary representation.
If a number has already been inserted, the leafs will already have been created.
When finished, just take a path that has not been created before to create the requested number.
4 billion number = 2^32, meaning 10 MB might not be sufficient.
EDIT
An optimization is possible, if two ends leafs have been created and have a common parent, then they can be removed and the parent flagged as not a solution. This cuts branches and reduces the need for memory.
EDIT II
There is no need to build the tree completely too. You only need to build deep branches if numbers are similar. If we cut branches too, then this solution might work in fact.
I will answer the 1 GB version:
There is not enough information in the question, so I will state some assumptions first:
The integer is 32 bits with range -2,147,483,648 to 2,147,483,647.
Pseudo-code:
var bitArray = new bit[4294967296]; // 0.5 GB, initialized to all 0s.
foreach (var number in file) {
bitArray[number + 2147483648] = 1; // Shift all numbers so they start at 0.
}
for (var i = 0; i < 4294967296; i++) {
if (bitArray[i] == 0) {
return i - 2147483648;
}
}
As long as we're doing creative answers, here is another one.
Use the external sort program to sort the input file numerically. This will work for any amount of memory you may have (it will use file storage if needed).
Read through the sorted file and output the first number that is missing.
Bit Elimination
One way is to eliminate bits, however this might not actually yield a result (chances are it won't). Psuedocode:
long val = 0xFFFFFFFFFFFFFFFF; // (all bits set)
foreach long fileVal in file
{
val = val & ~fileVal;
if (val == 0) error;
}
Bit Counts
Keep track of the bit counts; and use the bits with the least amounts to generate a value. Again this has no guarantee of generating a correct value.
Range Logic
Keep track of a list ordered ranges (ordered by start). A range is defined by the structure:
struct Range
{
long Start, End; // Inclusive.
}
Range startRange = new Range { Start = 0x0, End = 0xFFFFFFFFFFFFFFFF };
Go through each value in the file and try and remove it from the current range. This method has no memory guarantees, but it should do pretty well.
2128*1018 + 1 ( which is (28)16*1018 + 1 ) - cannot it be a universal answer for today? This represents a number that cannot be held in 16 EB file, which is the maximum file size in any current file system.
I think this is a solved problem (see above), but there's an interesting side case to keep in mind because it might get asked:
If there are exactly 4,294,967,295 (2^32 - 1) 32-bit integers with no repeats, and therefore only one is missing, there is a simple solution.
Start a running total at zero, and for each integer in the file, add that integer with 32-bit overflow (effectively, runningTotal = (runningTotal + nextInteger) % 4294967296). Once complete, add 4294967296/2 to the running total, again with 32-bit overflow. Subtract this from 4294967296, and the result is the missing integer.
The "only one missing integer" problem is solvable with only one run, and only 64 bits of RAM dedicated to the data (32 for the running total, 32 to read in the next integer).
Corollary: The more general specification is extremely simple to match if we aren't concerned with how many bits the integer result must have. We just generate a big enough integer that it cannot be contained in the file we're given. Again, this takes up absolutely minimal RAM. See the pseudocode.
# Grab the file size
fseek(fp, 0L, SEEK_END);
sz = ftell(fp);
# Print a '2' for every bit of the file.
for (c=0; c<sz; c++) {
for (b=0; b<4; b++) {
print "2";
}
}
As Ryan said it basically, sort the file and then go over the integers and when a value is skipped there you have it :)
EDIT at downvoters: the OP mentioned that the file could be sorted so this is a valid method.
If you don't assume the 32-bit constraint, just return a randomly generated 64-bit number (or 128-bit if you're a pessimist). The chance of collision is 1 in 2^64/(4*10^9) = 4611686018.4 (roughly 1 in 4 billion). You'd be right most of the time!
(Joking... kind of.)

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