Take the 2-minute tour ×
Stack Overflow is a question and answer site for professional and enthusiast programmers. It's 100% free, no registration required.

Looking through interview questions on the Internet I encountered the following one.

Describe a data structure for which getValue(int index), setValue(int index, int value), and setAllValues(int value) are all O(1).

Though array is good enough for the first and second operations to be performed in O(1), what can be proposed for the third (setAllValues)?

share|improve this question
1  
I highly doubt this possible. –  leppie Apr 4 '12 at 5:53
1  
@leppie I disagree - see my answer :) –  Timothy Jones Apr 4 '12 at 6:05
1  
@TimothyJones: OK, I understand your answer, but it is 'cheating'. You are only setting 1 value, not all values. –  leppie Apr 4 '12 at 6:08
2  
@leppie The data structure would work as specified, so I'm not sure what's cheating about it ;) –  Timothy Jones Apr 4 '12 at 7:27

7 Answers 7

up vote 18 down vote accepted

How about an array of tuples {timestamp, value}, with an additional {timestamp, value} called all. Since you only care about the relative time of insertions, you can use a monotonically increasing id for the values of timestamp. Initialise all fields to 0.

Then the following should work for you:

  • setValue(index i, value v):

    array[i] = {id++, value}
    
  • getValue(index i, value v):

    if(all.timestamp > array[i].timestamp) return all.value
    else return array[i].value
    
  • setAll(value v)

    all = {id++, value}
    

A problem with this approach is that eventually you'll run out of ids for timestamp, and might wrap around. If you chose a 64 bit value to store timestamps, then this gives you 18,446,744,073,709,551,616 insertions or setAlls before this happens. Depending on the expected use of the datastructure, an O(n) cleanup phase might be appropriate, or you could just throw an exception.

Another issue that might need to be considered is multi-threading. Three obvious problems:

  • if id++ isn't atomic and two threads obtained a new id at the same time then you could get two entries with the same id.
  • if the incrementation of id and the assignment of the created tuple aren't atomic together (they're probably not) and there were two simultaneous inserts, then you could get a race condition where the older id wins.
  • if the assignment of the tuple isn't atomic, and there's an insert() at the same time as a get() then you might end up in a position where you've got say {new_id, old_value} in the array, causing the wrong value to be returned.

If any of these are problems, the absolute easiest solution to this is to put "not thread safe" in the documentation (cheating). Alternatively, if you can't implement the methods atomically in your language of choice, you'd need to put some sort of synchronisation locks around them.

share|improve this answer
    
But we can;t be sure that how it works internally. This single statement can be O(n). –  ganessh Apr 4 '12 at 6:05
1  
This relies on every call to current_time() returning a different value though (otherwise, two timestamps may be equal) –  Damien_The_Unbeliever Apr 4 '12 at 6:07
    
@Damien_The_Unbeliever that's true. You may also have to deal with wrap-around cases too, if the program was around for a while. –  Timothy Jones Apr 4 '12 at 6:15
    
Thanks Timothy. Perfect! –  Alec Apr 4 '12 at 6:42
    
@Damien_The_Unbeliever So, I was writing up an edit that suggested using a tuple of {system_timestamp,id} in place of timestamps to get around this, when I realised that there's no need to involve system timestamps at all. See edit :) –  Timothy Jones Apr 4 '12 at 6:43

How about an array of pointers to a single common value? Set the value, and all references will point to the single changed value in O(1)..

share|improve this answer
    
Answers the question though! ;) lol. –  WOPR Apr 4 '12 at 6:07
    
This works until you want to change one of the elements to point to something other than the common value. –  Timothy Jones Apr 4 '12 at 6:09
    
That wasn't a requirement specified in the question. –  WOPR Apr 4 '12 at 6:10
1  
I think it is - if you call setAll(), and then setValue(), you'd have to change one of the elements. –  Timothy Jones Apr 4 '12 at 6:16
3  
I would say that specs clearly imply that it should be possible to set values individually without affecting the other values. Otherwise the index parameter to the setValue method is superfluous. And if you do not want to interpret method signatures as specifications, then it would be possible to simply implement all of the methods as NoOps... –  Alderath Apr 4 '12 at 8:57

We can have a variable V which stores an int and an array of containing Tuple as {Value, id}..

And a global int variable G (which will act like identity in SQL and whenever any set or setAll operation is done its value get increment by 1)

initial all Ids and V value will be default say null..

so V = null All Tuple = {null, null}
set(index i, val v) -> G = G+1, arr[i].Val = v, arr[i].Id = G

get(index i) -> if V.Id > arr[i].Id return V.Val else return arr[i]



set-all(val v) -> G= G+1, V.Id= G, V.Val = v
share|improve this answer

I was just asked this question very recently in an Interview. I came up with a hashtable implementation. It would solve the problem of running out of the timestamp values but the thread safety feature needs to be implemented (probably using lazy initialization techniques)

Let's say in side our class we have a private variable d to hold a default value and we also have a private hashtable h. SetAll could just set d equal to the value passed and h initialized/set to a new hashtable and discard any reference to old hashtable. Set should should add new value into the hastable h or update the value if the key(index) is already present in the hashtable h. Get should check whether the key(index) is present in hashtable, then return it, else return the value stored in d.

This is my first answer on stackoverflow. I am a little lazy in writing up the code. Will probably edit the answer soon.

The interviewer nodded yes to this solution but insisted to implement it without using a hashtable. I guess, he was asking me to give a similar approach as Timothy's answer. And I wasn't able to get it at that moment :(. Anyways, Cheers!

share|improve this answer

Python example

class d:
    def __init__(self, l):
        self.len = l
        self.g_p = [i for i in range(self.len)]
        self.g_v = [0 for i in range(self.len)]
        self.g_s = self.len - 1
        self.g_c = 0  

    def getVal(self, i):
        if (i < 0 or i >= self.len):
            return

        if (self.g_p[i] <= self.g_s):
            return self.g_v[self.g_p[i]]

        return self.g_c

    def setVal(self, i, v):
        if (i < 0 or i >= self.len):
            return

        if (self.g_p[i] > self.g_s):
            self.g_s += 1

            self.g_p[self.g_s], self.g_p[i] = self.g_p[i], self.g_p[self.g_s]

        self.g_v[self.g_p[i]] = v

    def setAll(self, v):
        self.g_c = v
        self.g_s = -1
share|improve this answer

Regarding Timothy Jone's answer:

A problem with this approach is that eventually you'll run out of ids for timestamp, and might wrap around. If you chose a 64 bit value to store timestamps, then this gives you 18,446,744,073,709,551,616 insertions or setAlls before this happens. Depending on the expected use of the datastructure, an O(n) cleanup phase might be appropriate, or you could just throw an exception.

This is exactly the worst case scenario which make this solution O(n) too, and not O(1). This stucture, although saves a lot of potential O(n) insert operation, is still in O(n) effeciency.

share|improve this answer
    
See my answer for a way to maintain constant time updates in the face of overflow. –  dfeuer Mar 6 at 1:51
    
@dfeuer can you please specify in words how you unbox the Int and Word values? This question is being asked around the world in interviews, and the expected answer by interviewers (as descibed by Timothy) is definitly incorrect, or at least incomplete. In any case, it is obvious that the answer above should be refined. Thanks in advance. –  Emliti Mar 6 at 13:31
    
That sounds like a pretty good reason to delete my answer altogether. –  dfeuer Mar 6 at 13:59
    
This does not provide an answer to the question. To critique or request clarification from an author, leave a comment below their post - you can always comment on your own posts, and once you have sufficient reputation you will be able to comment on any post. –  Bluehound Mar 6 at 14:20
    
@Bluehound Because I ususally don't write here I cannot leave a comment under Timothy's answer. I know I have made an important remark so please don't delete it. If pereferable move this answer under Timothy's answer so anyone can see and comment. Thank you –  Emliti Mar 6 at 19:20

All existing answers use a timestamp that is incremented on every setVal operation. This is not necessary. In fact, it is necessary only to increment the timestamp on setAll. Another issue some raised was arithmetic overflow. This can be handled without breaking the constant time bounds by updating a single cell on each setAll and performing the time comparison carefully.

How it works

The basic concept is essentially similar to that of the other answers, but with a twist.

What they do: Store the value used for the last setAll operation separately, and keep track of the time that operation was performed. Each time they perform a setVal, they store the current time along with the given value in the array. Each time they perform a getVal, they compare the time in the given location to the time the last setAll occurred, and then choose either the value at the location or the setAll value depending on which is greater.

Why this can be a problem: Suppose the current time overflows and a setAll operation occurs soon afterward. It will appear as though most of the stored array values are newer than the setAll value, when they are actually older.

The solution: Stop imagining that we're keeping track of the total amount of time that has passed since data structure initialization. Imagine a giant clock with a "second hand" that ticks not 60 times around the circle but rather 2^n times around the circle. The position of the second hand represents the time of the most recent setAll operation. Each setVal operation stores this time along with a value. So if we perform a setAll when the "clock" is at 45, and then perform six setVal operations on different elements, the setAll time and the times at all six locations will be the same. We wish to maintain the following invariant:

The time at a given element location equals the setAll time if and only if that element was set with setVal more recently than the last setAll operation.

Clearly, the procedure described above automatically ensures that if the element was set recently, then its time will equal the setAll time. The challenge is to make the reverse implication hold as well.

To be continued ....

The code

I've written this in Haskell because that is the language I know best, but it is not exactly the most natural language for the job.

{-# LANGUAGE BangPatterns #-}
module RepArr where

import Control.Monad.Primitive
import Data.Primitive.MutVar
import qualified Data.Vector.Mutable as V
import Data.Vector.Mutable (MVector)
import Control.Applicative
import Prelude hiding (replicate)
import Control.Monad.ST
import Data.Word

-- The Int in the MutVar is the refresh pointer
data RepArr s a = RepArr (MutVar s (Word, a, Int)) (MVector s (Word,a))

-- Create a fancy array of a given length, initially filled with a given value
replicate :: (PrimMonad m, Applicative m) => Int -> a -> m (RepArr (PrimState m) a)
replicate n a = RepArr <$> newMutVar (0,a,0) <*> V.replicate n (0,a)

getVal :: PrimMonad m => RepArr (PrimState m) a -> Int -> m a
getVal (RepArr allv vec) n = do
  (vectime, vecval) <- V.read vec n
  (alltime, allval, _) <- readMutVar allv
  if (fromIntegral (alltime - vectime) :: Int) > 0
    then return allval
    else return vecval

setVal :: PrimMonad m => RepArr (PrimState m) a -> Int -> a -> m ()
setVal (RepArr allv vec) i v = do
  (!alltime, _, _) <- readMutVar allv
  V.write vec i (alltime, v)

setAll :: PrimMonad m => RepArr (PrimState m) a -> a -> m ()
setAll r@(RepArr allv vec) v = do
  (oldt, _, oldc) <- readMutVar allv
  getVal r oldc >>= setVal r oldc
  let !newc = case oldc+1 of
        op1 | op1 == V.length vec -> 0
            | otherwise -> op1
  let !newt = oldt+1
  writeMutVar allv (newt, v, newc)

To avoid potential (rare) garbage collection pauses, it's actually necessary to unbox the Int and Word values, as well as using unboxed vectors instead of polymorphic ones, but I'm not really in the mood and this is a fairly mechanical task.

Here's a version in C (completely untested):

#include <malloc.h>

struct Pair {
  unsigned long time;
  void* val;
};

struct RepArr {
  unsigned long allT;
  void* allV;
  long count;
  long length;
  struct Pair vec[];
};

struct RepArr *replicate (long n, void* val) {
  struct RepArr *q = malloc (sizeof (struct RepArr)+n*sizeof (struct Pair));
  q->allT = 1;
  q->allV = val;
  q->count = 0;
  q->length = n;

  int i;
  for (i=0; i<n; i++) {
    struct Pair foo = {0,val};
    q->vec[i] = foo;
  }
  return q;
}


void* getVal (struct RepArr *q, long i) {
  if ((long)(q->vec[i].time - q->allT) < 0)
    return q->allV;
  else
    return q->vec[i].val;
}

void setVal (struct RepArr *q, long i, void* val) {
  q->vec[i].time = q->allT;
  q->vec[i].val = val;
}

void setAll (struct RepArr *q, void* val) {
  setVal (q, q->count, getVal (q, q->count));
  q->allV = val;
  q->allT++;
  q->count++;
  if (q->count == q->length)
    q->count = 0;
}
share|improve this answer

Your Answer

 
discard

By posting your answer, you agree to the privacy policy and terms of service.

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