bird/misc/ips.c

#include <stdio.h>
#include <math.h>
#include <unistd.h>
#include <stdlib.h>

int h[65536];

/*
 *  Probability analysis of hashing function:
 *
 *  Let n be number of items and k number of boxes. For uniform distribution
 *  we get:
 *
 *  Expected value of "item i is in given box": Xi = 1/k
 *  Expected number of items in given box: a = EX = E(sum Xi) = sum E(Xi) = n/k
 *  Expected square value: E(X^2) = E((sum Xi)^2) = E((sum_i Xi^2) + (sum_i,j i<>j XiXj)) =
 *	= sum_i E(Xi^2) + sum_i,j i<>j E(XiXj) =
 *	= sum_i E(Xi) [Xi is binary] + sum_i,j i<>j E(XiXj) [those are independent] =
 *	= n/k + n*(n-1)/k^2
 *  Variance: var X = E(X^2) - (EX)^2 = n/k + n*(n-1)/k^2 - n^2/k^2 =
 *	= n/k - n/k^2 = a * (1-1/k)
 *  Probability of fixed box being zero: Pz = ((k-1)/k)^n = (1-1/k)^n = (1-1/k)^(ak) =
 *	= ((1-1/k)^k)^a which we can approximate by e^-a.
 */

uint hf(uint n)
{
#if 0
	n = (n ^ (n >> 16)) & 0xffff;
	n = (n ^ (n << 8)) & 0xffff;
#elif 1
	n = (n >> 16) ^ n;
	n = (n ^ (n << 10)) & 0xffff;
#elif 0
	n = (n >> 16) ^ n;
	n *= 259309;
#elif 0
	n ^= (n >> 20);
	n ^= (n >> 10);
	n ^= (n >> 5);
#elif 0
	n = (n * 259309) + ((n >> 16) * 123479);
#else
	return random();
#endif
	return n;
}

int
main(int argc, char **argv)
{
	int cnt=0;
	int i;

	int bits = atol(argv[1]);
	int z = 1 << bits;
	int max = atol(argv[2]);

	while (max--)
	  {
	    uint i, e;
	    if (scanf("%x/%d", &i, &e) != 2)
	      if (feof(stdin))
		break;
	    else
	      fprintf(stderr, "BUGGG\n");
//	    i >>= (32-e);
//	    i |= (i >> e);
            cnt++;
	    h[(hf(i) >> 1*(16 - bits)) & (z-1)]++;
	  }
//	printf(">>> %d addresses\n", cnt);
#if 0
	for(i=0; i<z; i++)
		printf("%d\t%d\n", i, h[i]);
#else
{
	int min=cnt, max=0, zer=0;
	double delta=0;
	double avg = (double) cnt / z;
	double exdelta = avg*(1-1/(double)z);
	double exzer = exp(-avg);
	for(i=0; i<z; i++) {
		if (h[i] < min) min=h[i];
		if (h[i] > max) max=h[i];
		delta += (h[i] - avg) * (h[i] - avg);
		if (!h[i]) zer++;
	}
	printf("size=%5d, min=%d, max=%2d, delta=%-7.6g (%-7.6g), avg=%-5.3g, zero=%g%% (%g%%)\n", z, min, max, delta/z, exdelta, avg, zer/(double)z*100, exzer*100);
}
#endif

	return 0;
}
Added several tools for fib hashing function analysis. It turned out we can use very simple function which is monotonic with respect to re-hashing: n ^= n >> 16; n ^= n << 10; h = (n >> (16 - o)) & ((1 << o) - 1); where o is table order. Statistical analysis for both backbone routing table and local OSPF routing tables gives values near theoretical optimum for uniform distribution (see ips.c for formulae). The trick is very simple: We always calculate a 16-bit hash value n and use o most significant bits (this gives us monotonity wrt. rehashing if we sort the chains by the value of n). The first shift/xor pair reduces the IP address to a 16-bit one, the second pair makes higher bits of the 16-bit value uniformly distributed even for tables containing lots of long prefixes (typical interior routing case with 24-bit or even longer prefixes). 1998-12-19 19:51:47 +08:00			`#include <stdio.h>`
			`#include <math.h>`
			`#include <unistd.h>`
			`#include <stdlib.h>`

			`int h[65536];`

			`/*`
			`* Probability analysis of hashing function:`
			`*`
			`* Let n be number of items and k number of boxes. For uniform distribution`
			`* we get:`
			`*`
			`* Expected value of "item i is in given box": Xi = 1/k`
			`* Expected number of items in given box: a = EX = E(sum Xi) = sum E(Xi) = n/k`
			`* Expected square value: E(X^2) = E((sum Xi)^2) = E((sum_i Xi^2) + (sum_i,j i<>j XiXj)) =`
			`* = sum_i E(Xi^2) + sum_i,j i<>j E(XiXj) =`
			`* = sum_i E(Xi) [Xi is binary] + sum_i,j i<>j E(XiXj) [those are independent] =`
			`* = n/k + n*(n-1)/k^2`
			`* Variance: var X = E(X^2) - (EX)^2 = n/k + n*(n-1)/k^2 - n^2/k^2 =`
			`* = n/k - n/k^2 = a * (1-1/k)`
			`* Probability of fixed box being zero: Pz = ((k-1)/k)^n = (1-1/k)^n = (1-1/k)^(ak) =`
			`* = ((1-1/k)^k)^a which we can approximate by e^-a.`
			`*/`

unsigned [int] -> uint 2015-05-19 14:53:34 +08:00			`uint hf(uint n)`
Added several tools for fib hashing function analysis. It turned out we can use very simple function which is monotonic with respect to re-hashing: n ^= n >> 16; n ^= n << 10; h = (n >> (16 - o)) & ((1 << o) - 1); where o is table order. Statistical analysis for both backbone routing table and local OSPF routing tables gives values near theoretical optimum for uniform distribution (see ips.c for formulae). The trick is very simple: We always calculate a 16-bit hash value n and use o most significant bits (this gives us monotonity wrt. rehashing if we sort the chains by the value of n). The first shift/xor pair reduces the IP address to a 16-bit one, the second pair makes higher bits of the 16-bit value uniformly distributed even for tables containing lots of long prefixes (typical interior routing case with 24-bit or even longer prefixes). 1998-12-19 19:51:47 +08:00			`{`
			`#if 0`
			`n = (n ^ (n >> 16)) & 0xffff;`
			`n = (n ^ (n << 8)) & 0xffff;`
			`#elif 1`
			`n = (n >> 16) ^ n;`
			`n = (n ^ (n << 10)) & 0xffff;`
			`#elif 0`
			`n = (n >> 16) ^ n;`
			`n *= 259309;`
			`#elif 0`
			`n ^= (n >> 20);`
			`n ^= (n >> 10);`
			`n ^= (n >> 5);`
			`#elif 0`
			`n = (n * 259309) + ((n >> 16) * 123479);`
			`#else`
			`return random();`
			`#endif`
			`return n;`
			`}`

			`int`
			`main(int argc, char **argv)`
			`{`
			`int cnt=0;`
			`int i;`

			`int bits = atol(argv[1]);`
			`int z = 1 << bits;`
			`int max = atol(argv[2]);`

			`while (max--)`
			`{`
unsigned [int] -> uint 2015-05-19 14:53:34 +08:00			`uint i, e;`
Added several tools for fib hashing function analysis. It turned out we can use very simple function which is monotonic with respect to re-hashing: n ^= n >> 16; n ^= n << 10; h = (n >> (16 - o)) & ((1 << o) - 1); where o is table order. Statistical analysis for both backbone routing table and local OSPF routing tables gives values near theoretical optimum for uniform distribution (see ips.c for formulae). The trick is very simple: We always calculate a 16-bit hash value n and use o most significant bits (this gives us monotonity wrt. rehashing if we sort the chains by the value of n). The first shift/xor pair reduces the IP address to a 16-bit one, the second pair makes higher bits of the 16-bit value uniformly distributed even for tables containing lots of long prefixes (typical interior routing case with 24-bit or even longer prefixes). 1998-12-19 19:51:47 +08:00			`if (scanf("%x/%d", &i, &e) != 2)`
			`if (feof(stdin))`
			`break;`
			`else`
			`fprintf(stderr, "BUGGG\n");`
			`// i >>= (32-e);`
			`// i \|= (i >> e);`
			`cnt++;`
			`h[(hf(i) >> 1*(16 - bits)) & (z-1)]++;`
			`}`
			`// printf(">>> %d addresses\n", cnt);`
			`#if 0`
			`for(i=0; i<z; i++)`
			`printf("%d\t%d\n", i, h[i]);`
			`#else`
			`{`
			`int min=cnt, max=0, zer=0;`
			`double delta=0;`
			`double avg = (double) cnt / z;`
Variance estimation fixed. 1998-12-20 05:53:28 +08:00			`double exdelta = avg*(1-1/(double)z);`
Added several tools for fib hashing function analysis. It turned out we can use very simple function which is monotonic with respect to re-hashing: n ^= n >> 16; n ^= n << 10; h = (n >> (16 - o)) & ((1 << o) - 1); where o is table order. Statistical analysis for both backbone routing table and local OSPF routing tables gives values near theoretical optimum for uniform distribution (see ips.c for formulae). The trick is very simple: We always calculate a 16-bit hash value n and use o most significant bits (this gives us monotonity wrt. rehashing if we sort the chains by the value of n). The first shift/xor pair reduces the IP address to a 16-bit one, the second pair makes higher bits of the 16-bit value uniformly distributed even for tables containing lots of long prefixes (typical interior routing case with 24-bit or even longer prefixes). 1998-12-19 19:51:47 +08:00			`double exzer = exp(-avg);`
			`for(i=0; i<z; i++) {`
			`if (h[i] < min) min=h[i];`
			`if (h[i] > max) max=h[i];`
			`delta += (h[i] - avg) * (h[i] - avg);`
			`if (!h[i]) zer++;`
			`}`
			`printf("size=%5d, min=%d, max=%2d, delta=%-7.6g (%-7.6g), avg=%-5.3g, zero=%g%% (%g%%)\n", z, min, max, delta/z, exdelta, avg, zer/(double)z100, exzer100);`
			`}`
			`#endif`

			`return 0;`
			`}`