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OK, here's my situation :

  • I have a function - let's say U64 calc (U64 x) - which takes a 64-bit integer parameter, performs some CPU-intensive operation, and returns a 64-bit value
  • Now, given that I know ALL possible inputs (the xs) of that function beforehand (there are some 16000 though), I thought it might be better to pre-calculate them and then fetch them on demand (from an array-like structure).
  • The ideal situation would be to store them all in some array U64 CALC[] and retrieve them by index (the x again)
  • And here's the issue : I may know what the possible inputs for my calc function are, but they are most definitely NOT consecutive (e.g. not from 1 to 16000, but values that may go as low as 0 and as high as some trillions - always withing a 64-bit range)

E.G.

  X        CALC[X]
-----------------------
  123123   123123123
  12312    12312312
  897523   986123

  etc.

And here comes my question :

  • How would you store them?
  • What workaround would you prefer?
  • Now, given that these values (from CALC) will have to be accessed some thousands-to-millions of times, per sec, which would be the best solution performance-wise?

Note : I'm no mentioning anything I've thought of or tried so as not to turn the answers into some debate of A vs B type-of-thing, and mostly not influence anyone...

share|improve this question
4  
Profile using map, set, and unordered_map, then make an informed decision. –  Retired Ninja Dec 16 '12 at 4:48
    
Showing what you've tried might help. There are also some answers here that might help, including one that implies using a map has pretty good performance. Also consider a hashmap. –  Rob I Dec 16 '12 at 4:48
    
you could also try to use a trie. –  didierc Dec 16 '12 at 4:50
    
if you know the access patterns of your data structures, you could also implement some caching techniques (LRU, MRU comes to mind). –  didierc Dec 16 '12 at 5:13
1  
You could consider using a minimal perfect hash. Most of the literature for this concentrates on strings, but I see no reason the technique could not be used on integers. –  md5i Dec 16 '12 at 5:24

6 Answers 6

I would use some sort of hash function that creates an index to a u64 pair where one is the value the key was created from and the other the replacement value. Technically the index could be three bytes long if you need to conserve space but I'd use u32s. If the stored value does not match the value computed on (hash collision) you'd enter an overflow handler.

  • You need to determine a custom hashing algorithm to fit your data
  • Since you know the size of the data you don't need algorithms that allow the data to grow.
  • I'd be wary of using some standard algorithm because they seldom fit specific data
  • I'd be wary of using a C++ method unless you are sure the code is WYSIWYG (doesn't generate a lot of calls)
  • Your index should be 25% larger than the number of pairs

Run through all possible inputs and determine min, max, average and standard deviation for the number of collisions and use these to determine the acceptable performance level. Then profile to achieve the best possible code.

The required memory space (using a u32 index) comes out to (4*1.25)+8+8 = 21 bytes per pair or 336 MeB, no problem on a typical PC.

____ EDIT______

I have been challenged by "RocketRoy" to put my money where my mouth is. Here goes:

The problem has to do with collision handling in a (fixed size) hash table. To set the stage:

  • I have a list of n entries where a field in the entry contains the value v that the hash is computed from
  • I have a vector of n*1.25 (approximately) indeces such that the number of indeces x is a prime number
  • A prime number y is computed which is a fraction of x
  • The vector is initialized to say -1 to denote unoccupied

Pretty standard stuff I think you'll agree.

The entries in the list are processed and the hash value h computed and modulo'd and used as an index into the vector and the index to the entry is placed there.

Eventually I encounter the situation where the vector entry pointed to by the index is occupied (doesn't contain -1) - voilà, a collision.

So what do I do? I keep the original h as ho, add y to h and take modulo x and get a new index into the vector. If the entry is unoccupied I use it, otherwise I continue with add y modulo x until I reach ho. In theory, this will happen because both x and y are prime numbers. In practice x is larger than n so it won't.

So the "re-hash" that RocketRoy claims is very costly is no such thing.

The tricky part with this method - as with all hashing methods - is to:

  • Determine a suitable value for x (becomes less tricky the larger x finally used)
  • Determine the algorithm a for h=a(v)%x such that a the h's index reasonably evenly ("randomly") into the index vector with as few collisions as possible
  • Determine a suitable value for y such that collisions index reasonably evenly ("randomly") into the index vector

____ EDIT______

I'm sorry I've taken so long to produce this code ... other things have had higher priorities.

Anyway, here is the code which proves that hashing has better prospects for quick lookups than a binary tree. It runs through a bunch of hashing index sizes and algorithms to aid in finding the most suitable combo for the specific data. For every algorithm the code will print the first index size such that no lookup takes longer than fourteen searches (worst case for binary searching) and an average lookup takes less than 1.5 searches.

I have a fondness for prime numbers in these types of applications, in case you haven't noticed.

There are many ways of creating a hashing algorithm with its mandatory overflow handling. I opted for simplicity assuming it will translate into speed ... and it does. On my laptop with an i5 M 480 @ 2.67 GHz an average lookup requires between 55 and 60 clock cycles (comes out to around 45 million lookups per second). I implemented a special get operation with a constant number of indeces and ditto rehash value and the cycle count dropped to 40 (65 million lookups per second). If you look at the line calling getOpSpec the index i is xor'ed with 0x444 to exercise the caches to achieve more "real worldults.

I must again point out that the program suggests suitable combinations for the specific data. Other data may require a different combo.

The source code contains both the code for generating the 16000 unsigned long long pairs and for testing different constants (index sizes and rehash values):

#include <windows.h>

#define i8    signed char
#define i16          short
#define i32          long
#define i64          long long
#define id  i64
#define u8           char
#define u16 unsigned short
#define u32 unsigned long
#define u64 unsigned long long
#define ud  u64

#include <string.h>
#include <stdio.h>

u64 prime_find_next     (const u64 value);
u64 prime_find_previous (const u64 value);

static inline volatile unsigned long long rdtsc_to_rax (void)
{
  unsigned long long lower,upper;

  asm volatile( "rdtsc\n"
                : "=a"(lower), "=d"(upper));
  return lower|(upper<<32);
}

//#define PAIRS16000

#ifndef PAIRS16000
static u16 index[65536];

static u64 nindeces,rehshFactor;

static struct PAIRS {u64 oval,rval;} pairs[16000] = {
#include "pairs.h"
};

struct HASH_STATS
{
  u64 ninvocs,nrhshs,nworst;
} getOpStats,putOpStats;

i8 putOp (u16 index[], const struct PAIRS data[], const u64 oval, const u64 ci)
{
  u64 nworst=1,ho,h,i;
  i8 success=1;

  ++putOpStats.ninvocs;
  ho=oval%nindeces;
  h=ho;
  do
  {
    i=index[h];
    if (i==0xffff)    /* unused position */
    {
      index[h]=(u16)ci;
      goto added;
    }
    if (oval==data[i].oval) goto duplicate;

    ++putOpStats.nrhshs;
    ++nworst;

    h+=rehshFactor;
    if (h>=nindeces) h-=nindeces;
  } while (h!=ho);

  exhausted:    /* should not happen */
  duplicate:
    success=0;

  added:
  if (nworst>putOpStats.nworst) putOpStats.nworst=nworst;

  return success;
}

i8 getOp (u16 index[], const struct PAIRS data[], const u64 oval, u64 *rval)
{
  u64 ho,h,i;
  i8 success=1;

  ho=oval%nindeces;
  h=ho;
  do
  {
    i=index[h];
    if (i==0xffffu) goto not_found;    /* unused position */

    if (oval==data[i].oval)
    {
      *rval=data[i].rval;    /* fetch the replacement value */
      goto found;
    }

    h+=rehshFactor;
    if (h>=nindeces) h-=nindeces;
  } while (h!=ho);

  exhausted:
  not_found:    /* should not happen */
    success=0;

  found:

  return success;
}
i8 getOpSpec (u16 index[], const struct PAIRS data[], const u64 oval, u64 *rval)
{
  u64 ho,h,i;
  i8 success=1;

  ho=oval%31253u;
  h=ho;
  do
  {
    i=index[h];
    if (i==0xffffu) goto not_found;    /* unused position */

    if (oval==data[i].oval)
    {
      *rval=data[i].rval;    /* fetch the replacement value */
      goto found;
    }

    h+=28591u;
    if (h>=31253u) h-=31253u;
  } while (h!=ho);

  exhausted:
  not_found:    /* should not happen */
    success=0;

  found:

  return success;
}
#endif

volatile i8 stop = 0;
int main (int argc, char *argv[])
{
  u64 i,rval,mulup,divdown,start;
  double ave;
#ifdef PAIRS16000
  u64 oval,rval,tval0=0,tval1=0;
  i=0;
  while (i<16000)
  {
    oval=rdtsc_to_rax ();
    Sleep (20);
    rval=rdtsc_to_rax ();
    Sleep (20);

    j=0;while (j<64) {tval0<<=1;if ((rval>>j)&1) tval0|=1;++j;}tval0^=oval;
    j=0;while (j<64) {tval1<<=1;if ((oval>>j)&1) tval1|=1;++j;}tval1^=rval;

    printf ("{0x%08x%08xull,0x%08x%08xull},\n", (u32)(tval0>>32),(u32)tval1, (u32)(tval1>>32),(u32)tval1);

    ++i;
  }
  #else

  SetThreadAffinityMask (GetCurrentThread(), 0x00000004ull);

  divdown=5;   //5
  while (divdown<=100)
  {
    mulup=3;  // 3
    while (mulup<divdown)
    {



  nindeces=16000;
  while (nindeces<65500)
  {
    nindeces=   prime_find_next     (nindeces);
    rehshFactor=nindeces*mulup/divdown;
    rehshFactor=prime_find_previous (rehshFactor);

    memset (index, 0xff, sizeof(index));
    memset (&putOpStats, 0, sizeof(struct HASH_STATS));

    i=0;
    while (i<16000)
    {
      if (!putOp (index, pairs, pairs[i].oval, (u16) i)) stop=1;

      ++i;
    }

    ave=(double)(putOpStats.ninvocs+putOpStats.nrhshs)/(double)putOpStats.ninvocs;
    if (ave<1.5 && putOpStats.nworst<15)
    {
      start=rdtsc_to_rax ();
      i=0;
      while (i<16000)
      {
        if (!getOp (index, pairs, pairs[i^0x0444]. oval, &rval)) stop=1;
        ++i;
      }
      start=rdtsc_to_rax ()-start+8000;   /* 8000 is half of 16000 (pairs), for rounding */

      printf ("%u;%u;%u;%u;%1.3f;%u;%u\n", (u32)mulup, (u32)divdown, (u32)nindeces, (u32)rehshFactor, ave, (u32) putOpStats.nworst, (u32) (start/16000ull));

      if (mulup==43 && divdown==47 && nindeces==31253 && rehshFactor==28591)
      {
        start=rdtsc_to_rax ();
        i=0;
        while (i<16000)
        {
          if (!getOpSpec (index, pairs, pairs[i^0x0444]. oval, &rval)) stop=1;
          ++i;
        }
        start=rdtsc_to_rax ()-start+8000ull;   /* 8000 is half of 16000 (pairs), for rounding */

        printf ("%u\n", (u32)(start/16000ull));
      }
      goto found;
    }

    nindeces+=2;
  }
  printf ("%u;%u\n", (u32)mulup, (u32)divdown);

  found:

      mulup=prime_find_next (mulup);
    }
    divdown=prime_find_next (divdown);
  }

  SetThreadAffinityMask (GetCurrentThread(), 0x0000000fu);

#endif
  return 0;
}

It was not possible to include the generated pairs file (an answer is apparently limited to 30000 characters).

And these are the results:

3;5;35569;21323;1,390;14;60
3;7;33577;14389;1,435;14;62
5;7;32069;22901;1,474;14;63
3;11;35107;9551;1,412;14;61
5;11;33967;15427;1,446;14;63
7;11;34583;22003;1,422;14;61
3;13;34253;7901;1,439;14;63
5;13;34039;13063;1,443;14;62
7;13;32801;17659;1,456;14;63
11;13;33791;28591;1,436;14;62
3;17;34337;6053;1,413;14;61
5;17;32341;9511;1,470;14;62
7;17;32507;13381;1,474;14;63
11;17;33301;21529;1,454;14;81
13;17;34981;26737;1,403;13;61
3;19;33791;5333;1,437;14;62
5;19;35149;9241;1,403;14;60
7;19;33377;12289;1,439;14;62
11;19;34337;19867;1,417;14;61
13;19;34403;23537;1,430;14;61
17;19;33923;30347;1,467;14;63
3;23;33857;4409;1,425;14;61
5;23;34729;7547;1,429;14;61
7;23;32801;9973;1,456;14;63
11;23;33911;16127;1,445;14;62
13;23;33637;19009;1,435;13;62
17;23;34439;25453;1,426;13;62
19;23;33329;27529;1,468;14;63
3;29;32939;3391;1,474;14;64
5;29;34543;5953;1,437;13;62
7;29;34259;8263;1,414;13;66
11;29;34367;13033;1,409;14;62
13;29;33049;14813;1,444;14;62
17;29;34511;20219;1,422;14;61
19;29;33893;22193;1,445;13;62
23;29;34693;27509;1,412;13;61
3;31;34019;3271;1,441;14;62
5;31;33923;5449;1,460;14;63
7;31;33049;7459;1,442;14;62
11;31;35897;12721;1,389;14;60
13;31;35393;14831;1,397;14;62
17;31;33773;18517;1,425;14;61
19;31;33997;20809;1,442;14;62
23;31;34841;25847;1,417;14;61
29;31;33857;31667;1,426;14;61
3;37;32569;2633;1,476;14;63
5;37;34729;4691;1,419;14;61
7;37;34141;6451;1,439;14;62
11;37;34549;10267;1,410;13;61
13;37;35117;12329;1,423;14;61
17;37;34631;15907;1,429;14;61
19;37;34253;17581;1,435;14;62
23;37;32909;20443;1,453;14;62
29;37;33403;26177;1,445;14;62
31;37;34361;28771;1,413;14;61
3;41;34297;2503;1,424;14;61
5;41;33587;4093;1,430;14;61
7;41;34583;5903;1,404;13;60
11;41;32687;8761;1,440;14;62
13;41;34457;10909;1,439;14;62
17;41;34337;14221;1,425;14;61
19;41;32843;15217;1,476;14;64
23;41;35339;19819;1,423;14;62
29;41;34273;24239;1,436;14;62
31;41;34703;26237;1,414;14;61
37;41;33343;30089;1,456;14;63
3;43;34807;2423;1,417;14;61
5;43;35527;4129;1,413;14;61
7;43;33287;5417;1,467;14;63
11;43;33863;8647;1,436;14;62
13;43;34499;10427;1,418;14;61
17;43;34549;13649;1,431;14;65
19;43;33749;14897;1,429;13;62
23;43;34361;18371;1,409;14;61
29;43;33149;22349;1,452;14;63
31;43;34457;24821;1,428;14;61
37;43;32377;27851;1,482;14;63
41;43;33623;32057;1,424;13;61
3;47;33757;2153;1,459;14;64
5;47;33353;3547;1,445;14;62
7;47;34687;5153;1,414;13;61
11;47;34519;8069;1,417;14;62
13;47;34549;9551;1,412;13;61
17;47;33613;12149;1,461;14;63
19;47;33863;13687;1,443;14;62
23;47;35393;17317;1,402;14;60
29;47;34747;21433;1,432;13;61
31;47;34871;22993;1,409;14;61
37;47;34729;27337;1,425;14;61
41;47;33773;29453;1,438;14;62
43;47;31253;28591;1,487;14;64
3;53;33623;1901;1,430;14;61
5;53;34469;3229;1,430;13;62
7;53;34883;4603;1,408;14;61
11;53;34511;7159;1,412;13;61
13;53;32587;7963;1,453;14;62
17;53;34297;10993;1,432;13;62
19;53;33599;12043;1,443;14;62
23;53;34337;14897;1,415;14;61
29;53;34877;19081;1,424;14;62
31;53;34913;20411;1,406;13;62
37;53;34429;24029;1,417;13;62
41;53;34499;26683;1,418;14;61
43;53;32261;26171;1,488;14;64
47;53;34253;30367;1,437;14;62
3;59;33503;1699;1,432;14;65
5;59;34781;2939;1,424;14;61
7;59;35531;4211;1,403;14;60
11;59;34487;6427;1,420;14;61
13;59;33563;7393;1,453;14;63
17;59;34019;9791;1,440;14;62
19;59;33967;10937;1,447;14;62
23;59;33637;13109;1,438;14;62
29;59;34487;16943;1,424;14;61
31;59;32687;17167;1,480;14;63
37;59;35353;22159;1,404;14;60
41;59;34499;23971;1,431;14;61
43;59;34039;24799;1,445;14;62
47;59;32027;25471;1,499;14;63
53;59;34019;30557;1,449;14;62
3;61;35059;1723;1,418;14;63
5;61;34351;2803;1,416;13;61
7;61;35099;4021;1,412;14;86
11;61;34019;6133;1,442;14;62
13;61;35023;7459;1,406;14;61
17;61;35201;9803;1,414;14;61
19;61;34679;10799;1,425;14;61
23;61;34039;12829;1,441;13;62
29;61;33871;16097;1,446;14;62
31;61;34147;17351;1,427;14;62
37;61;34583;20963;1,412;14;61
41;61;32999;22171;1,452;14;64
43;61;33857;23857;1,431;14;61
47;61;34897;26881;1,431;14;61
53;61;33647;29231;1,434;14;62
59;61;32999;31907;1,454;14;62
3;67;32999;1471;1,455;14;62
5;67;35171;2621;1,403;14;91
7;67;33851;3533;1,463;14;63
11;67;34607;5669;1,437;14;62
13;67;35081;6803;1,416;14;62
17;67;33941;8609;1,417;14;62
19;67;34673;9829;1,427;14;62
23;67;35099;12043;1,415;14;62
29;67;33679;14563;1,452;14;62
31;67;34283;15859;1,437;14;62
37;67;32917;18169;1,460;13;63
41;67;33461;20443;1,441;14;62
43;67;34313;22013;1,426;14;61
47;67;33347;23371;1,452;14;62
53;67;33773;26713;1,434;14;74
59;67;35911;31607;1,395;14;61
61;67;34157;31091;1,431;14;62
3;71;34483;1453;1,423;14;61
5;71;34537;2423;1,428;14;61
7;71;33637;3313;1,428;13;64
11;71;32507;5023;1,465;14;63
13;71;35753;6529;1,403;14;61
17;71;33347;7963;1,444;14;62
19;71;35141;9397;1,410;14;61
23;71;32621;10559;1,475;14;63
29;71;33637;13729;1,429;14;136
31;71;33599;14657;1,443;14;62
37;71;34361;17903;1,396;14;86
41;71;33757;19489;1,435;14;92
43;71;34583;20939;1,413;14;61
47;71;34589;22877;1,441;14;62
53;71;35353;26387;1,418;14;61
59;71;35323;29347;1,406;14;61
61;71;35597;30577;1,401;14;61
67;71;34537;32587;1,425;14;62
3;73;34613;1409;1,418;14;61
5;73;32969;2251;1,453;14;63
7;73;33049;3167;1,448;14;63
11;73;33863;5101;1,435;14;62
13;73;34439;6131;1,456;14;62
17;73;33629;7829;1,455;14;62
19;73;34739;9029;1,421;14;62
23;73;33071;10399;1,469;14;87
29;73;33359;13249;1,460;14;62
31;73;33767;14327;1,422;14;61
37;73;32939;16693;1,490;14;83
41;73;33739;18947;1,438;14;61
43;73;33937;19979;1,432;14;62
47;73;33767;21739;1,422;14;82
53;73;33359;24203;1,435;14;62
59;73;34361;27767;1,401;13;61
61;73;33827;28229;1,443;14;62
67;73;34421;31583;1,423;14;97
71;73;33053;32143;1,447;14;63
3;79;35027;1327;1,410;14;93
5;79;34283;2161;1,432;14;62
7;79;34439;3049;1,432;14;98
11;79;34679;4817;1,416;14;61
13;79;34667;5701;1,405;14;65
17;79;33637;7237;1,428;14;61
19;79;34469;8287;1,417;14;61
23;79;34439;10009;1,433;14;62
29;79;33427;12269;1,448;13;62
31;79;33893;13297;1,445;14;81
37;79;33863;15823;1,439;14;65
41;79;32983;17107;1,450;14;62
43;79;34613;18803;1,431;14;61
47;79;33457;19891;1,457;14;63
53;79;33961;22777;1,435;14;62
59;79;32983;24631;1,465;14;63
61;79;34337;26501;1,428;14;61
67;79;33547;28447;1,458;14;63
71;79;32653;29339;1,473;14;63
73;79;34679;32029;1,429;14;62
3;83;35407;1277;1,405;14;81
5;83;32797;1973;1,451;14;93
7;83;33049;2777;1,443;14;94
11;83;33889;4483;1,431;14;61
13;83;35159;5503;1,409;14;93
17;83;34949;7151;1,412;14;61
19;83;32957;7541;1,467;14;83
23;83;32569;9013;1,470;14;64
29;83;33287;11621;1,474;14;63
31;83;33911;12659;1,448;13;62
37;83;33487;14923;1,456;14;81
41;83;33587;16573;1,438;13;61
43;83;34019;17623;1,435;14;62
47;83;31769;17987;1,483;14;65
53;83;33049;21101;1,451;14;62
59;83;32369;23003;1,465;14;77
61;83;32653;23993;1,469;14;63
67;83;33599;27109;1,437;14;62
71;83;33713;28837;1,452;14;63
73;83;33703;29641;1,454;14;63
79;83;34583;32911;1,417;14;61
3;89;34147;1129;1,415;13;62
5;89;32797;1831;1,461;14;62
7;89;33679;2647;1,443;14;63
11;89;34543;4261;1,427;13;62
13;89;34603;5051;1,419;14;61
17;89;34061;6491;1,444;14;62
19;89;34457;7351;1,422;14;62
23;89;33529;8663;1,450;14;63
29;89;34283;11161;1,431;14;62
31;89;35027;12197;1,411;13;61
37;89;34259;14221;1,403;14;60
41;89;33997;15649;1,434;14;61
43;89;33911;16127;1,445;14;62
47;89;34949;18451;1,419;14;61
53;89;34367;20443;1,434;14;61
59;89;33791;22397;1,430;14;80
61;89;34961;23957;1,404;14;60
67;89;33863;25471;1,433;13;61
71;89;35149;28031;1,414;14;61
73;89;33113;27143;1,447;14;62
79;89;32909;29209;1,458;14;62
83;89;33617;31337;1,400;14;61
3;97;34211;1051;1,448;14;62
5;97;34807;1789;1,430;14;61
7;97;33547;2417;1,446;14;62
11;97;35171;3967;1,407;14;60
13;97;32479;4349;1,474;14;63
17;97;34319;6011;1,444;14;62
19;97;32381;6337;1,491;14;66
23;97;33617;7963;1,421;14;61
29;97;33767;10093;1,423;14;61
31;97;33641;10739;1,447;14;63
37;97;34589;13187;1,425;13;61
41;97;34171;14437;1,451;14;62
43;97;31973;14159;1,484;14;63
47;97;33911;16127;1,445;14;62
53;97;34031;18593;1,448;14;63
59;97;32579;19813;1,457;14;64
61;97;34421;21617;1,417;13;62
67;97;33739;23297;1,448;14;89
71;97;33739;24691;1,435;14;91
73;97;33863;25471;1,433;13;62
79;97;34381;27997;1,419;14;92
83;97;33967;29063;1,446;14;63
89;97;33521;30727;1,441;14;63

Cols 1 and 2 are used to calculate the rehash factor given a certain index size (see code). The next two are the first index size/rehash factor combination which averages less than 1.5 searches for a lookup with a worst case of 14 searches. Then average and worst case. Finally, the last column is the average number of clock cycles per lookup. It does not take into account the time required to read the time stamp register.

The actual memory space for the best sizes (# of indeces = 31253 and rehash factor = 28591) comes out to more than I initially indicated (16000*2*8 + 1,25*16000*2 => 296000 bytes). The actual size is 16000*2*8+31253*2 => 318506

share|improve this answer
    
...and still no code. I'll let you in on a secret. The reason I've been pushing you for code, is because while bsearch() qsort() are simple, easy, and in the lib, you would have to make a substantial investment of time to create a hash function to satisfy the requirements above. IE: being so reluctant to do the work of creating and performance testing the proposed hash function, you're making my point for me. Also, my claim is not that the rehash is computationally expensive, it's that other things will hash to the same rehash location, causing cascading failures. –  RocketRoy Dec 21 '12 at 8:23
    
Then I'll let you in on a secret. The OP wrote "fastest way to store and retrieve" which you and I obviously read quite differently. Though I can't look inside your head I assume you have focused on "fastest way to get something up and running" whereas I read it as "the most processing efficient way (i e fastest execution time)." Nobody with any significant knowledge on hashing - oh yes, I am one of them - will claim that efficient hash algorithms are easy to implement. But that was not an issue the OP appeared interested in so I didn't assume he was. –  Olof Forshell Dec 21 '12 at 12:29
    
My RX to the OP was based on balancing the potential minor improvement in performance (a bad hash would perform worse) against a very large investment of time. Since other's here had already benchmarked bsearch() and found it nearly an order of magnitude beyond the OP's requirements that was the correct call. Now if money/time is no object, and you want to learn a lot about writing hash routines, then you might want to use a hash, but the OP was looking for off-the-shelf solutions, so that wasn't his situation. –  RocketRoy Dec 21 '12 at 23:24
1  
Like I said: our respective understandings of the word "fastest" are quite different. I read it literally and try to answer the question accordingly. You read in lot's of other things which may or may not be pertinent. I guess if someone were to ask us "what's the fastest way to lap at Indianapolis" I'd give a backgrounder on racing car construction (if that were my field of expertise) and you'd say buy a standard car, drop in the biggest engine you can find and drive. So my approach is to explain from a theoretical/practical standpoint and yours is time to market. –  Olof Forshell Dec 22 '12 at 7:37
1  
I've seen some good benchmarks comparing the STL's map and unordered set containers, and for those the unordered set (aka, a hashtable) was about 3X as fast. Not sure about search(). The Achilles Heel of hash tables is an unknown # of values, and in some cases, like large, variable-length strings, the poor performance of the hash function. Search would also require that the number of values be known up front. –  user2548100 Dec 18 '13 at 1:21

Perform memonization, or in simple terms, cache the values you've computed already and calculate the new ones. You should hash the input and check the cache for that result. You can even start off with a set of cache values that you think the function would get called more often for. Besides that, I don't think you need to go to any extreme as the other answer suggest. Do things simple and when you are done with your application you can use a profiling tool to find bottle necks.

EDIT: Some code

#include <iostream>
#include <ctime>
using namespace std;

const int MAX_SIZE = 16000;

int preCalcData[MAX_SIZE] = {};

int getPrecalculatedResult(int x){
 return preCalcData[x];
}

void setupPreCalcDataCache(){
  for(int i = 0; i < MAX_SIZE; ++i){
    preCalcData[i] = i*i; //or whatever calculation
  }
}

int main(){
  setupPreCalcDataCache();

  cout << getPrecalculatedResult(0) << endl;
  cout << getPrecalculatedResult(15999) << endl;

  return 0;
}    
share|improve this answer
    
I've used this approach, and it works well, but only because I had a 28-part key, and converting all those doubles to ascii so I could concatenate them into a string to use as hash fodder was VERY expensive. It was cheaper to use an n-dimensional tree and compare native types. Very complex code. Stick with a bsearch() or hash if your key is a single value (as you indicated it was). –  RocketRoy Dec 16 '12 at 7:20
    
Well OP doesn't necessarily need to convert the numerical value to string in order to get a hash? I think this should be faster than the binary search method –  user814628 Dec 17 '12 at 20:37
    
Asking a Hash function "have I already done this" 16,000 times cannot possibly be faster than already knowing you have. Read the OP's spec. It's a completely redundant question. For the Nth time, Hashing CAN be faster than searching, but unless you know a lot about the data, and know it's size, it seldom is because most data has hot-spots that create cascading collisions. It's nearly impossible to create a perfect Hash function. Conjecture is useless. FASTER can only be answered by benchmarking. Provide some code and we'll know. –  RocketRoy Dec 21 '12 at 8:11
    
To already know you have hashed you have to ask first right? Anyways, if we can spare memory then it will be a constant lookup and code will be very trivial. I say it is feasible in terms of memory because it is only 16000 ints. So as a result, we can simply do CALC[x] and not even hash x. Maybe I am missing something here. –  user814628 Dec 21 '12 at 19:05
    
..."check the cache" how? –  RocketRoy Dec 21 '12 at 23:20

You need to store 16 thousand values efficiently, preferably in memory. We are assuming that the computation of these values is more time consuming than accessing them from storage.

You have at your disposal many different data structures to get the job done, including databases. If you access these values in queriable chunks, then the DB overhead may very well be absorbed and spread accross your processing.

You mentioned map and hashmap (or hashtable) already in your question tags, but these are probably not the best possible answers for your problem, although they could do a fair job, provided that the hashing function isn't more expensive than the direct computation of the target UINT64 value, which has to be your reference benchmark.

Are probably much better suited. Having some experience with it, I would probably go for a B-tree: they support fairly well serialization. That should let you prepare your dataset in advance in a different program. VEB trees have a very good access time (O(log log(n)), but I don't know how easily they may be serialized.

Later on, if you need even more performance, it would also be interesting to know usage patterns of your "database" to figure out what caching techniques you could implement on top of the store.

share|improve this answer
    
This answer is clearly incorrect. Trees are wonderful things, but completely inappropriate where you know how many entries you need to store in advance. Their advantage is they are self-extending. They are expensive though, and take up a lot of memory. Hash or bsearch() are the correct answers. Databases are too slow by many thousands of times. –  RocketRoy Dec 16 '12 at 7:15
    
@RocketRoy databases ate slow because they need to parse and complie high level language queries (SQL like), but when it comes to indexing, the algorithms they use are fast enough. The problem is to find a good tradeof between speed and ease of use, and b-trees are good candidates for that. –  didierc Dec 16 '12 at 16:13
    
No. They're slow because you're calling malloc() thousands of times to create the tree, you have to move a lot of data around to create balanced trees (or suffer still poorer performance if the tree degrades into a very long linked list reading sorted data) and because you're following pointers to navigate. You use trees when you don't know up front how much data you have. If you know this up front, bsearch() is about an order of magnitude faster. IE: it will work fine for OLAP, but not for transactional stuff. Again, CS 101. Look up the characteristics of associative data structures. –  RocketRoy Dec 17 '12 at 2:19
    
@RocketRoy thank you for your kind advices. I'd never used bsearch before, and it seems a very handy function to do dichotomic search on a sorted array. Now may I kindly suggest that you do the same and educate yourself on what a B-tree exaclty is? And I am not talking about binary trees. –  didierc Dec 17 '12 at 8:42
    
LOL. Written tons of them, so already know. Suggest you crack a book on Data Structures & Algorithms. The primary reason anyone uses binary trees instead of binary searches (for flat data) is because if you're adding elements trees remain sorted, while the array does not. Therefore, if you have a static dataset, bsearch() works perfectly, and you don't have to pay the higher price of chasing pointers around in memory to probe for comparisons. –  RocketRoy Dec 17 '12 at 22:38

I wouldn't worry about performance too much. This simple example, using an array and binary search lower_bound

#include <stdint.h>
#include <algorithm>
#include <cstdlib>
#include <iostream>
#include <memory>

const int N = 16000;
typedef std::pair<uint64_t, uint64_t> CALC;
CALC calc[N];

static inline bool cmp_calcs(const CALC &c1, const CALC &c2)
{
    return c1.first < c2.first;
}

int main(int argc, char **argv)
{
    std::iostream::sync_with_stdio(false);
    for (int i = 0; i < N; ++i)
        calc[i] = std::make_pair(i, i);

    std::sort(&calc[0], &calc[N], cmp_calcs);

    for (long i = 0; i < 10000000; ++i) {
        int r = rand() % 16000;
        CALC *p = std::lower_bound(&calc[0], &calc[N], std::make_pair(r, 0), cmp_calcs);
        if (p->first == r)
            std::cout << "found\n";
    }

    return 0;
}

and compiled with

g++ -O2 example.cpp

does, including setup, 10,000,000 searches in about 2 seconds on my 5 year old PC.

share|improve this answer
1  
YOU wouldn't worry but it appears the OP may well be. –  Olof Forshell Dec 16 '12 at 8:47
    
@OlofForshell Within the constraints of about 16000 entries with some thousands to millions lookups per second, this is well achieved with my old PC. A current machine should do a lot better. So, when the goal is met, I wouldn't worry. ;-) –  Olaf Dietsche Dec 16 '12 at 13:19

Make an array of structures of key val pairs.

Sort the array by key, put this in your program as static array, would only be 128kbyte.

Then in your program a simple binary look up by key will need on average only 14 key comparisons to find the right value. Should be able to approach speeds of 300 million look ups per second on modern pc.

You can sort with qsort and search with bsearch, both std lib functions.

share|improve this answer
    
Simple, straight-forward, and robust. I would use this every time for the problem as stated. Hashes are fast, but only if you know the data well, and know it won't change. Typical hash use is for key-words in a parser. You know the words, their character content & distribution, and number, so you can optimize the hash. Not your problem AFAICT. –  RocketRoy Dec 16 '12 at 7:23
    
I would only allocate the storage on the stack if the number (~16,000) never changes. Otherwise you'll either have to constantly change the array size, allocate one arbitrarily large, or have your program blow up. IE: a maintenance nightmare. Use malloc() and allocate the exact storage you need. Foolproof. –  RocketRoy Dec 16 '12 at 7:39
    
300 million lookups per second. On a 3GHz machine this comes out to one lookup every 10 Hz. This means one comparison per 0.7 Hz. How do you propose to handle the (at least) three instructions (fetch, compare and conditional jump) for the comparison, several to find the new comparison position not to mention cache misses? Mutliple cores are of no help in case you didn't know. Back to the drawing board for you. –  Olof Forshell Dec 16 '12 at 8:22
    
@RocketRoy: if you have a need for speed you use the tools that can be brought to bear. Granted a binary search is faster to implement but will be up to an order of magnitude slower than a properly functioning hash routine. Foolproof? Not if you want the fastest possible solution. –  Olof Forshell Dec 16 '12 at 8:31
    
@OlofForshell ..and what do you do about collisions? Call malloc() and resort to linear searches of the extensions? You can't avoid collisions unless you know a lot about the nature of the data, AND, are willing to allocate at least 125% of the space that will be used. I've used and tested both extensively. Hashes never live up to their theoretical performance potential with this kind of data, and they take a lot of time to get right if you do know your data. Rehashes kill performance. Total wipeout. –  RocketRoy Dec 16 '12 at 9:08

Using std::pair is better than any of map for speed.

but if I were you, I firstly use a std::list to store the data, after I got them all, I move them into a simple vector, then retrieving goes very fast if you implement a simple binary tree search by yourself.

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