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38ceb554fd
The code that is there to run some unit tests on some internal features was moved to tests/unit. Ideally it should be buildable from the main makefile though this is not yet the case. The code that is kept for experimentation purposes (hashes, syscall optimization etc) as well as some captures of the results was moved to tests/exp. A few totally obsolete files which couldn't build anymore and were not relevant to current versions were removed.
203 lines
5.6 KiB
C
203 lines
5.6 KiB
C
/*
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* Integer hashing tests. These functions work with 32-bit integers, so are
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* perfectly suited for IPv4 addresses. A few tests show that they may also
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* be chained for larger keys (eg: IPv6), this way :
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* f(x[0-3]) = f(f(f(f(x[0])^x[1])^x[2])^x[3])
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*
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* See also bob jenkin's site for more info on hashing, and check perfect
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* hashing for constants (eg: header names).
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*/
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#include <stdio.h>
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#include <string.h>
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#include <arpa/inet.h>
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#include <math.h>
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#define NSERV 8
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#define MAXLINE 1000
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int counts_id[NSERV][NSERV];
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uint32_t hash_id( uint32_t a)
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{
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return a;
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}
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/* Full-avalanche integer hashing function from Thomas Wang, suitable for use
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* with a modulo. See below, worth a read !
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* http://www.concentric.net/~Ttwang/tech/inthash.htm
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*
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* See also tests performed by Bob Jenkins (says it's faster than his) :
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* http://burtleburtle.net/bob/hash/integer.html
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*
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* This function is small and fast. It does not seem as smooth as bj6 though.
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* About 0x40 bytes, 6 shifts.
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*/
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int counts_tw1[NSERV][NSERV];
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uint32_t hash_tw1(uint32_t a)
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{
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a += ~(a<<15);
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a ^= (a>>10);
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a += (a<<3);
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a ^= (a>>6);
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a += ~(a<<11);
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a ^= (a>>16);
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return a;
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}
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/* Thomas Wang's mix function. The multiply is optimized away by the compiler
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* on most platforms.
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* It is about equivalent to the one above.
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*/
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int counts_tw2[NSERV][NSERV];
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uint32_t hash_tw2(uint32_t a)
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{
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a = ~a + (a << 15);
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a = a ^ (a >> 12);
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a = a + (a << 2);
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a = a ^ (a >> 4);
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a = a * 2057;
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a = a ^ (a >> 16);
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return a;
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}
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/* Thomas Wang's multiplicative hash function. About 0x30 bytes, and it is
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* extremely fast on recent processors with a fast multiply. However, it
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* must not be used on low bits only, as multiples of 0x00100010 only return
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* even values !
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*/
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int counts_tw3[NSERV][NSERV];
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uint32_t hash_tw3(uint32_t a)
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{
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a = (a ^ 61) ^ (a >> 16);
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a = a + (a << 3);
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a = a ^ (a >> 4);
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a = a * 0x27d4eb2d;
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a = a ^ (a >> 15);
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return a;
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}
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/* Full-avalanche integer hashing function from Bob Jenkins, suitable for use
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* with a modulo. It has a very smooth distribution.
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* http://burtleburtle.net/bob/hash/integer.html
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* About 0x50 bytes, 6 shifts.
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*/
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int counts_bj6[NSERV][NSERV];
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int counts_bj6x[NSERV][NSERV];
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uint32_t hash_bj6(uint32_t a)
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{
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a = (a+0x7ed55d16) + (a<<12);
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a = (a^0xc761c23c) ^ (a>>19);
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a = (a+0x165667b1) + (a<<5);
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a = (a+0xd3a2646c) ^ (a<<9);
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a = (a+0xfd7046c5) + (a<<3);
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a = (a^0xb55a4f09) ^ (a>>16);
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return a;
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}
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/* Similar function with one more shift and no magic number. It is slightly
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* slower but provides the overall smoothest distribution.
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* About 0x40 bytes, 7 shifts.
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*/
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int counts_bj7[NSERV][NSERV];
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int counts_bj7x[NSERV][NSERV];
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uint32_t hash_bj7(uint32_t a)
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{
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a -= (a<<6);
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a ^= (a>>17);
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a -= (a<<9);
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a ^= (a<<4);
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a -= (a<<3);
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a ^= (a<<10);
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a ^= (a>>15);
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return a;
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}
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void count_hash_results(unsigned long hash, int counts[NSERV][NSERV]) {
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int srv, nsrv;
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for (nsrv = 0; nsrv < NSERV; nsrv++) {
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srv = hash % (nsrv + 1);
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counts[nsrv][srv]++;
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}
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}
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void dump_hash_results(char *name, int counts[NSERV][NSERV]) {
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int srv, nsrv;
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double err, total_err, max_err;
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printf("%s:\n", name);
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for (nsrv = 0; nsrv < NSERV; nsrv++) {
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total_err = 0.0;
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max_err = 0.0;
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printf("%02d srv: ", nsrv+1);
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for (srv = 0; srv <= nsrv; srv++) {
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err = 100.0*(counts[nsrv][srv] - (double)counts[0][0]/(nsrv+1)) / (double)counts[0][0];
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//printf("%6d ", counts[nsrv][srv]);
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printf("% 3.1f%%%c ", err,
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counts[nsrv][srv]?' ':'*'); /* display '*' when a server is never selected */
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err = fabs(err);
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total_err += err;
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if (err > max_err)
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max_err = err;
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}
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total_err /= (double)(nsrv+1);
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for (srv = nsrv+1; srv < NSERV; srv++)
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printf(" ");
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printf(" avg_err=%3.1f, max_err=%3.1f\n", total_err, max_err);
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}
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printf("\n");
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}
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int main() {
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int nr;
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unsigned int address = 0;
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unsigned int mask = ~0;
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memset(counts_id, 0, sizeof(counts_id));
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memset(counts_tw1, 0, sizeof(counts_tw1));
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memset(counts_tw2, 0, sizeof(counts_tw2));
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memset(counts_tw3, 0, sizeof(counts_tw3));
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memset(counts_bj6, 0, sizeof(counts_bj6));
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memset(counts_bj7, 0, sizeof(counts_bj7));
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address = 0x10000000;
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mask = 0xffffff00; // user mask to apply to addresses
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for (nr = 0; nr < 0x10; nr++) {
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//address += ~nr; // semi-random addresses.
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//address += 1;
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address += 0x00000100;
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//address += 0x11111111;
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//address += 7;
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//address += 8;
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//address += 256;
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//address += 65536;
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//address += 131072;
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//address += 0x00100010; // this increment kills tw3 !
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count_hash_results(hash_id (address & mask), counts_id); // 0.69s / 100M
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count_hash_results(hash_tw1(address & mask), counts_tw1); // 1.04s / 100M
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count_hash_results(hash_tw2(address & mask), counts_tw2); // 1.13s / 100M
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count_hash_results(hash_tw3(address & mask), counts_tw3); // 1.01s / 100M
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count_hash_results(hash_bj6(address & mask), counts_bj6); // 1.07s / 100M
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count_hash_results(hash_bj7(address & mask), counts_bj7); // 1.20s / 100M
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/* adding the original address after the hash reduces the error
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* rate in in presence of very small data sets (eg: 16 source
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* addresses for 8 servers). In this case, bj7 is very good.
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*/
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count_hash_results(hash_bj6(address & mask)+(address&mask), counts_bj6x); // 1.07s / 100M
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count_hash_results(hash_bj7(address & mask)+(address&mask), counts_bj7x); // 1.20s / 100M
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}
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dump_hash_results("hash_id", counts_id);
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dump_hash_results("hash_tw1", counts_tw1);
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dump_hash_results("hash_tw2", counts_tw2);
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dump_hash_results("hash_tw3", counts_tw3);
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dump_hash_results("hash_bj6", counts_bj6);
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dump_hash_results("hash_bj6x", counts_bj6x);
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dump_hash_results("hash_bj7", counts_bj7);
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dump_hash_results("hash_bj7x", counts_bj7x);
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return 0;
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}
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