I'd like to generate unique random numbers between 0 and 1000 that never repeat (i.e. 6 doesn't show up twice), but that doesn't resort to something like an O(N) search of previous values to do it. Is this possible?
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Initialize an array of 1001 integers with the values 01000 and set a variable, max, to the current max index of the array (starting with 1000). Pick a random number, r, between 0 and max, swap the number at the position r with the number at position max and return the number now at position max. Decrement max by 1 and continue. When max is 0, set max back to the size of the array  1 and start again without the need to reinitialize the array. Update: Although I came up with this method on my own when I answered the question, after some research I realize this is a modified version of FisherYates known as DurstenfeldFisherYates or KnuthFisherYates. Since the description may be a little difficult to follow, I have provided an example below (using 11 elements instead of 1001): Array starts off with 11 elements initialized to array[n] = n, max starts off at 10:
At each iteration, a random number r is selected between 0 and max, array[r] and array[max] are swapped, the new array[max] is returned, and max is decremented:
After 11 iterations, all numbers in the array have been selected, max == 0, and the array elements are shuffled:
At this point, max can be reset to 10 and the process can continue. 


You can do this:
So this doesn't require a search of old values each time, but it still requires O(N) for the initial shuffle. But as Nils pointed out in comments, this is amortised O(1). 


Use a Maximal Linear Feedback Shift Register. It's implementable in a few lines of C and at runtime does little more than a couple test/branches, a little addition and bit shifting. It's not random, but it fools most people. 


You could use A Linear Congruential Generator. Where 


You don't even need an array to solve this one. You need a bitmask and a counter. Initialize the counter to zero and increment it on successive calls. XOR the counter with the bitmask (randomly selected at startup, or fixed) to generate a psuedorandom number. If you can't have numbers that exceed 1000, don't use a bitmask wider than 9 bits. (In other words, the bitmask is an integer not above 511.) Make sure that when the counter passes 1000, you reset it to zero. At this time you can select another random bitmask — if you like — to produce the same set of numbers in a different order. 


For low numbers like 0...1000, creating a list that contains all the numbers and shuffling it is straight forward. But if the set of numbers to draw from is very large there's another elegant way: You can build a pseudorandom permutation using a key and a cryptographic hash function. See the following C++ish example pseudo code:
Here, 


You may use my Xincrol algorithm described here: http://openpatent.blogspot.co.il/2013/04/xincroluniqueandrandomnumber.html This is a pure algorithmic method of generating random but unique numbers without arrays, lists, permutations or heavy CPU load. Latest version allows also to set the range of numbers, For example, if I want unique random numbers in range of 01073741821. I've practically used it for
It is open, free. Give it a try... 


You could use FormatPreserving Encryption to encrypt a counter. Your counter just goes from 0 upwards, and the encryption uses a key of your choice to turn it into a seemingly random value of whatever radix and width you want. E.g. for the example in this question: radix 10, width 3. Block ciphers normally have a fixed block size of e.g. 64 or 128 bits. But FormatPreserving Encryption allows you to take a standard cipher like AES and make a smallerwidth cipher, of whatever radix and width you want, with an algorithm which is still cryptographically robust. It is guaranteed to never have collisions (because cryptographic algorithms create a 1:1 mapping). It is also reversible (a 2way mapping), so you can take the resulting number and get back to the counter value you started with. AESFFX is one proposed standard method to achieve this. I've experimented with some basic Python code which is based on the AESFFX idea, although not fully conformantsee Python code here. It can e.g. encrypt a counter to a randomlooking 7digit decimal number, or a 16bit number. 


Another posibility: You can use an array of flags. And take the next one when it;s already chosen. But, beware after 1000 calls, the function will never end so you must make a safeguard. 


This method results appropiate when the limit is high and you only want to generate a few random numbers.
Note that the numbers are generated in ascending order, but you can shuffle then afterwards. 


Here's some code I typed up that uses the logic of the first solution. I know this is "language agnostic" but just wanted to present this as an example in C# in case anyone is looking for a quick practical solution.



N Non Repeating random numbers will be of O(n) complexity, as required. 


Here is some sample COBOL code you can play around with.



You could use a good pseudorandom number generator with 10 bits and throw away 1001 to 1023 leaving 0 to 1000. From here we get the design for a 10 bit PRNG..



Most of the answers here fail to guarantee that they won't return the same number twice. Here's a correct solution:
I'm not sure that the constraint is well specified. One assumes that after 1000 other outputs a value is allowed to repeat, but that naively allows 0 to follow immediately after 0 so long as they both appear at the end and start of sets of 1000. Conversely, while it's possible to keep a distance of 1000 other values between repetitions, doing so forces a situation where the sequence replays itself in exactly the same way every time because there's no other value that has occurred outside of that limit. Here's a method that always guarantees at least 500 other values before a value can be repeated:



Let's say you want to go over shuffled lists over and over, without having the
Preprocess
Draw



O(n)
in time or memory), then many of the answer below are wrong, including the accepted answer. – jww Aug 29 '14 at 3:26