audiodb: lshlib.cpp annotate

annotate lshlib.cpp @ 296:f922c234462f

fixed file size allocation for FORMAT2 files. Made LSH index size() in bytes an unsigned long long. Changed the name of lsh_inCore flag to lsh_on_disk (to reverse the sense of the 'flag').

author	mas01mc
date	Fri, 01 Aug 2008 15:04:31 +0000
parents	071a108580a4
children	b10ad7b6427f

rev	line source
mas01mc@292	1 #include "lshlib.h"
mas01mc@292	2
mas01mc@292	3 //#define __LSH_DUMP_CORE_TABLES__
mas01mc@292	4 //#define USE_U_FUNCTIONS
mas01mc@296	5 #define LSH_BLOCK_FULL_ROWS
mas01mc@292	6
mas01mc@292	7 void err(char*s){cout << s << endl;exit(2);}
mas01mc@292	8
mas01mc@292	9 Uns32T get_page_logn(){
mas01mc@292	10 int pagesz = (int)sysconf(_SC_PAGESIZE);
mas01mc@292	11 return (Uns32T)log2((double)pagesz);
mas01mc@292	12 }
mas01mc@292	13
mas01mc@292	14 unsigned align_up(unsigned x, unsigned w){ return ((x) + ((1<<w)-1) & ~((1<<w)-1)); }
mas01mc@292	15
mas01mc@292	16 void H::error(const char* a, const char* b, const char *sysFunc) {
mas01mc@292	17 cerr << a << ": " << b << endl;
mas01mc@292	18 if (sysFunc) {
mas01mc@292	19 perror(sysFunc);
mas01mc@292	20 }
mas01mc@292	21 exit(1);
mas01mc@292	22 }
mas01mc@292	23
mas01mc@293	24 H::H(){
mas01mc@293	25 // Delay initialization of lsh functions until we know the parameters
mas01mc@293	26 }
mas01mc@293	27
mas01mc@293	28 H::H(Uns32T kk, Uns32T mm, Uns32T dd, Uns32T NN, Uns32T CC, float ww, float rr):
mas01mc@292	29 #ifdef USE_U_FUNCTIONS
mas01mc@292	30 use_u_functions(true),
mas01mc@292	31 #else
mas01mc@292	32 use_u_functions(false),
mas01mc@292	33 #endif
mas01mc@293	34 maxp(0),
mas01mc@292	35 bucketCount(0),
mas01mc@292	36 pointCount(0),
mas01mc@292	37 N(NN),
mas01mc@292	38 C(CC),
mas01mc@292	39 k(kk),
mas01mc@292	40 m(mm),
mas01mc@293	41 L((mm*(mm-1))/2),
mas01mc@293	42 d(dd),
mas01mc@293	43 w(ww),
mas01mc@293	44 radius(rr)
mas01mc@292	45 {
mas01mc@292	46
mas01mc@292	47 if(m<2){
mas01mc@292	48 m=2;
mas01mc@292	49 L=1; // check value of L
mas01mc@292	50 cout << "warning: setting m=2, L=1" << endl;
mas01mc@292	51 }
mas01mc@292	52 if(use_u_functions && k%2){
mas01mc@292	53 k++; // make sure k is even
mas01mc@292	54 cout << "warning: setting k even" << endl;
mas01mc@292	55 }
mas01mc@293	56
mas01mc@293	57 // We have the necessary parameters, so construct hashfunction datastructures
mas01mc@293	58 initialize_lsh_functions();
mas01mc@292	59 }
mas01mc@292	60
mas01mc@293	61 void H::initialize_lsh_functions(){
mas01mc@292	62 H::P = UH_PRIME_DEFAULT;
mas01mc@292	63
mas01mc@292	64 /* FIXME: don't use time(); instead use /dev/random or similar */
mas01mc@292	65 /* FIXME: write out the seed somewhere, so that we can get
mas01mc@292	66 repeatability */
mas01mc@292	67 #ifdef MT19937
mas01mc@292	68 init_genrand(time(NULL));
mas01mc@292	69 #else
mas01mc@292	70 srand(time(NULL)); // seed random number generator
mas01mc@292	71 #endif
mas01mc@293	72 Uns32T i,j, kk;
mas01mc@293	73 #ifdef USE_U_FUNCTIONS
mas01mc@293	74 H::A = new float**[ H::m ]; // m x k x d random projectors
mas01mc@293	75 H::b = new float*[ H::m ]; // m x k random biases
mas01mc@293	76 #else
mas01mc@293	77 H::A = new float**[ H::L ]; // m x k x d random projectors
mas01mc@293	78 H::b = new float*[ H::L ]; // m x k random biases
mas01mc@293	79 #endif
mas01mc@293	80 H::g = new Uns32T*[ H::L ]; // L x k random projections
mas01mc@293	81 assert( H::g && H::A && H::b ); // failure
mas01mc@293	82 #ifdef USE_U_FUNCTIONS
mas01mc@293	83 // Use m \times u_i functions \in R^{(k/2) \times (d)}
mas01mc@293	84 // Combine to make L=m(m-1)/2 hash functions \in R^{k \times d}
mas01mc@293	85 for( j = 0; j < H::m ; j++ ){ // m functions u_i(v)
mas01mc@293	86 H::A[j] = new float*[ H::k/2 ]; // k/2 x d 2-stable distribution coefficients
mas01mc@293	87 H::b[j] = new float[ H::k/2 ]; // bias
mas01mc@293	88 assert( H::A[j] && H::b[j] ); // failure
mas01mc@293	89 for( kk = 0; kk < H::k/2 ; kk++ ){
mas01mc@293	90 H::A[j][kk] = new float[ H::d ];
mas01mc@293	91 assert( H::A[j][kk] ); // failure
mas01mc@293	92 for(Uns32T i = 0 ; i < H::d ; i++ )
mas01mc@293	93 H::A[j][kk][i] = H::randn(); // Normal
mas01mc@293	94 H::b[j][kk] = H::ranf()*H::w; // Uniform
mas01mc@293	95 }
mas01mc@293	96 }
mas01mc@293	97 #else
mas01mc@293	98 // Use m \times u_i functions \in R^{k \times (d)}
mas01mc@293	99 // Combine to make L=m(m-1)/2 hash functions \in R^{k \times d}
mas01mc@293	100 for( j = 0; j < H::L ; j++ ){ // m functions u_i(v)
mas01mc@293	101 H::A[j] = new float*[ H::k ]; // k x d 2-stable distribution coefficients
mas01mc@293	102 H::b[j] = new float[ H::k ]; // bias
mas01mc@293	103 assert( H::A[j] && H::b[j] ); // failure
mas01mc@293	104 for( kk = 0; kk < H::k ; kk++ ){
mas01mc@293	105 H::A[j][kk] = new float[ H::d ];
mas01mc@293	106 assert( H::A[j][kk] ); // failure
mas01mc@293	107 for(Uns32T i = 0 ; i < H::d ; i++ )
mas01mc@293	108 H::A[j][kk][i] = H::randn(); // Normal
mas01mc@293	109 H::b[j][kk] = H::ranf()*H::w; // Uniform
mas01mc@293	110 }
mas01mc@293	111 }
mas01mc@293	112 #endif
mas01mc@293	113
mas01mc@293	114 // Storage for LSH hash function output (Uns32T)
mas01mc@293	115 for( j = 0 ; j < H::L ; j++ ){ // L functions g_j(u_a, u_b) a,b \in nchoosek(m,2)
mas01mc@293	116 H::g[j] = new Uns32T[ H::k ]; // k x 32-bit hash values, gj(v)=[x0 x1 ... xk-1] xk \in Z
mas01mc@293	117 assert( H::g[j] );
mas01mc@292	118 }
mas01mc@292	119
mas01mc@293	120 // LSH Hash tables
mas01mc@293	121 H::h = new bucket**[ H::L ];
mas01mc@293	122 assert( H::h );
mas01mc@292	123 for( j = 0 ; j < H::L ; j++ ){
mas01mc@292	124 H::h[j] = new bucket*[ H::N ];
mas01mc@292	125 assert( H::h[j] );
mas01mc@292	126 for( i = 0 ; i < H::N ; i++)
mas01mc@292	127 H::h[j][i] = 0;
mas01mc@292	128 }
mas01mc@293	129
mas01mc@293	130 // Standard hash functions
mas01mc@293	131 H::r1 = new Uns32T*[ H::L ];
mas01mc@293	132 H::r2 = new Uns32T*[ H::L ];
mas01mc@293	133 assert( H::r1 && H::r2 ); // failure
mas01mc@293	134 for( j = 0 ; j < H::L ; j++ ){
mas01mc@293	135 H::r1[ j ] = new Uns32T[ H::k ];
mas01mc@293	136 H::r2[ j ] = new Uns32T[ H::k ];
mas01mc@293	137 assert( H::r1[j] && H::r2[j] ); // failure
mas01mc@293	138 for( i = 0; i<H::k; i++){
mas01mc@293	139 H::r1[j][i] = randr();
mas01mc@293	140 H::r2[j][i] = randr();
mas01mc@293	141 }
mas01mc@293	142 }
mas01mc@293	143
mas01mc@293	144 // Storage for whole or partial function evaluation depdenting on USE_U_FUNCTIONS
mas01mc@293	145 H::initialize_partial_functions();
mas01mc@293	146 }
mas01mc@293	147
mas01mc@293	148 void H::initialize_partial_functions(){
mas01mc@293	149
mas01mc@293	150 #ifdef USE_U_FUNCTIONS
mas01mc@293	151 H::uu = vector<vector<Uns32T> >(H::m);
mas01mc@293	152 for( Uns32T aa=0 ; aa < H::m ; aa++ )
mas01mc@293	153 H::uu[aa] = vector<Uns32T>( H::k/2 );
mas01mc@293	154 #else
mas01mc@293	155 H::uu = vector<vector<Uns32T> >(H::L);
mas01mc@293	156 for( Uns32T aa=0 ; aa < H::L ; aa++ )
mas01mc@293	157 H::uu[aa] = vector<Uns32T>( H::k );
mas01mc@293	158 #endif
mas01mc@293	159 }
mas01mc@293	160
mas01mc@293	161
mas01mc@293	162 // Generate z ~ N(0,1)
mas01mc@293	163 float H::randn(){
mas01mc@293	164 // Box-Muller
mas01mc@293	165 float x1, x2;
mas01mc@293	166 do{
mas01mc@293	167 x1 = ranf();
mas01mc@293	168 } while (x1 == 0); // cannot take log of 0
mas01mc@293	169 x2 = ranf();
mas01mc@293	170 float z;
mas01mc@293	171 z = sqrtf(-2.0 * logf(x1)) * cosf(2.0 * M_PI * x2);
mas01mc@293	172 return z;
mas01mc@293	173 }
mas01mc@293	174
mas01mc@293	175 float H::ranf(){
mas01mc@293	176 #ifdef MT19937
mas01mc@293	177 return (float) genrand_real2();
mas01mc@293	178 #else
mas01mc@293	179 return (float)( (double)rand() / ((double)(RAND_MAX)+(double)(1)) );
mas01mc@293	180 #endif
mas01mc@293	181 }
mas01mc@293	182
mas01mc@293	183 // range is 1..2^29
mas01mc@293	184 /* FIXME: that looks like an ... odd range. Still. */
mas01mc@293	185 Uns32T H::randr(){
mas01mc@293	186 #ifdef MT19937
mas01mc@293	187 return (Uns32T)((genrand_int32() >> 3) + 1);
mas01mc@293	188 #else
mas01mc@293	189 return (Uns32T) ((rand() >> 2) + 1);
mas01mc@293	190 #endif
mas01mc@292	191 }
mas01mc@292	192
mas01mc@292	193 // Destruct hash tables
mas01mc@292	194 H::~H(){
mas01mc@293	195 Uns32T i,j,kk;
mas01mc@293	196 #ifdef USE_U_FUNCTIONS
mas01mc@293	197 for( j = 0 ; j < H::m ; j++ ){
mas01mc@293	198 for( kk = 0 ; kk < H::k/2 ; kk++ )
mas01mc@293	199 delete[] A[j][kk];
mas01mc@293	200 delete[] A[j];
mas01mc@293	201 }
mas01mc@293	202 delete[] A;
mas01mc@293	203 for( j = 0 ; j < H::m ; j++ )
mas01mc@293	204 delete[] b[j];
mas01mc@293	205 delete[] b;
mas01mc@293	206 #else
mas01mc@293	207 for( j = 0 ; j < H::L ; j++ ){
mas01mc@293	208 for( kk = 0 ; kk < H::k ; kk++ )
mas01mc@293	209 delete[] A[j][kk];
mas01mc@293	210 delete[] A[j];
mas01mc@293	211 }
mas01mc@293	212 delete[] A;
mas01mc@293	213 for( j = 0 ; j < H::L ; j++ )
mas01mc@293	214 delete[] b[j];
mas01mc@293	215 delete[] b;
mas01mc@293	216 #endif
mas01mc@293	217
mas01mc@293	218 for( j = 0 ; j < H::L ; j++ )
mas01mc@293	219 delete[] g[j];
mas01mc@293	220 delete[] g;
mas01mc@292	221 for( j=0 ; j < H::L ; j++ ){
mas01mc@292	222 delete[] H::r1[ j ];
mas01mc@292	223 delete[] H::r2[ j ];
mas01mc@292	224 for(i = 0; i< H::N ; i++)
mas01mc@292	225 delete H::h[ j ][ i ];
mas01mc@292	226 delete[] H::h[ j ];
mas01mc@292	227 }
mas01mc@292	228 delete[] H::r1;
mas01mc@292	229 delete[] H::r2;
mas01mc@292	230 delete[] H::h;
mas01mc@292	231 }
mas01mc@292	232
mas01mc@292	233
mas01mc@293	234 // Compute all hash functions for vector v
mas01mc@293	235 // #ifdef USE_U_FUNCTIONS use Combination of m \times h_i \in R^{(k/2) \times d}
mas01mc@293	236 // to make L \times g_j functions \in Z^k
mas01mc@293	237 void H::compute_hash_functions(vector<float>& v){ // v \in R^d
mas01mc@293	238 float iw = 1. / H::w; // hash bucket width
mas01mc@293	239 Uns32T aa, kk;
mas01mc@293	240 if( v.size() != H::d )
mas01mc@293	241 error("v.size != H::d","","compute_hash_functions"); // check input vector dimensionality
mas01mc@293	242 double tmp = 0;
mas01mc@293	243 float pA, pb;
mas01mc@293	244 Uns32T *pg;
mas01mc@293	245 int dd;
mas01mc@293	246 vector<float>::iterator vi;
mas01mc@293	247 vector<Uns32T>::iterator ui;
mas01mc@293	248
mas01mc@293	249 #ifdef USE_U_FUNCTIONS
mas01mc@293	250 Uns32T bb;
mas01mc@293	251 // Store m dot products to expand
mas01mc@293	252 for( aa=0; aa < H::m ; aa++ ){
mas01mc@293	253 ui = H::uu[aa].begin();
mas01mc@293	254 for( kk = 0 ; kk < H::k/2 ; kk++ ){
mas01mc@293	255 pb = *( H::b + aa ) + kk;
mas01mc@293	256 pA = * ( * ( H::A + aa ) + kk );
mas01mc@293	257 dd = H::d;
mas01mc@293	258 tmp = 0.;
mas01mc@293	259 vi = v.begin();
mas01mc@293	260 while( dd-- )
mas01mc@293	261 tmp += pA++ *vi++; // project
mas01mc@293	262 tmp += *pb; // translate
mas01mc@293	263 tmp *= iw; // scale
mas01mc@293	264 *ui++ = (Uns32T) floor(tmp); // floor
mas01mc@293	265 }
mas01mc@293	266 }
mas01mc@293	267 // Binomial combinations of functions u_{a,b} \in Z^{(k/2) \times d}
mas01mc@293	268 Uns32T j;
mas01mc@293	269 for( aa=0, j=0 ; aa < H::m-1 ; aa++ )
mas01mc@293	270 for( bb = aa + 1 ; bb < H::m ; bb++, j++ ){
mas01mc@293	271 pg= *( H::g + j ); // L \times functions g_j(v) \in Z^k
mas01mc@293	272 // u_1 \in Z^{(k/2) \times d}
mas01mc@293	273 ui = H::uu[aa].begin();
mas01mc@293	274 kk=H::k/2;
mas01mc@293	275 while( kk-- )
mas01mc@293	276 pg++ = ui++; // hash function g_j(v)=[x1 x2 ... x(k/2)]; xk \in Z
mas01mc@293	277 // u_2 \in Z^{(k/2) \times d}
mas01mc@293	278 ui = H::uu[bb].begin();
mas01mc@293	279 kk=H::k/2;
mas01mc@293	280 while( kk--)
mas01mc@293	281 pg++ = ui++; // hash function g_j(v)=[x(k/2+1) x(k/2+2) ... xk]; xk \in Z
mas01mc@293	282 }
mas01mc@293	283 #else
mas01mc@293	284 for( aa=0; aa < H::L ; aa++ ){
mas01mc@293	285 ui = H::uu[aa].begin();
mas01mc@293	286 for( kk = 0 ; kk < H::k ; kk++ ){
mas01mc@293	287 pb = *( H::b + aa ) + kk;
mas01mc@293	288 pA = * ( * ( H::A + aa ) + kk );
mas01mc@293	289 dd = H::d;
mas01mc@293	290 tmp = 0.;
mas01mc@293	291 vi = v.begin();
mas01mc@293	292 while( dd-- )
mas01mc@293	293 tmp += pA++ *vi++; // project
mas01mc@293	294 tmp += *pb; // translate
mas01mc@293	295 tmp *= iw; // scale
mas01mc@293	296 *ui++ = (Uns32T) (floor(tmp)); // floor
mas01mc@293	297 }
mas01mc@293	298 }
mas01mc@293	299 // Compute hash functions
mas01mc@293	300 for( aa=0 ; aa < H::L ; aa++ ){
mas01mc@293	301 pg= *( H::g + aa ); // L \times functions g_j(v) \in Z^k
mas01mc@293	302 // u_1 \in Z^{k \times d}
mas01mc@293	303 ui = H::uu[aa].begin();
mas01mc@293	304 kk=H::k;
mas01mc@293	305 while( kk-- )
mas01mc@293	306 pg++ = ui++; // hash function g_j(v)=[x1 x2 ... xk]; xk \in Z
mas01mc@293	307 }
mas01mc@293	308 #endif
mas01mc@293	309 }
mas01mc@293	310
mas01mc@292	311 // make hash value \in Z
mas01mc@293	312 void H::generate_hash_keys(Uns32Tg, Uns32T r1, Uns32T* r2){
mas01mc@293	313 H::t1 = computeProductModDefaultPrime( g, r1, H::k ) % H::N;
mas01mc@293	314 H::t2 = computeProductModDefaultPrime( g, r2, H::k );
mas01mc@292	315 }
mas01mc@292	316
mas01mc@292	317 #define CR_ASSERT(b){if(!(b)){fprintf(stderr, "ASSERT failed on line %d, file %s.\n", __LINE__, __FILE__); exit(1);}}
mas01mc@292	318
mas01mc@292	319 // Computes (a.b) mod UH_PRIME_DEFAULT
mas01mc@293	320 inline Uns32T H::computeProductModDefaultPrime(Uns32T a, Uns32T b, IntT size){
mas01mc@292	321 LongUns64T h = 0;
mas01mc@292	322
mas01mc@292	323 for(IntT i = 0; i < size; i++){
mas01mc@292	324 h = h + (LongUns64T)a[i] * (LongUns64T)b[i];
mas01mc@292	325 h = (h & TWO_TO_32_MINUS_1) + 5 * (h >> 32);
mas01mc@292	326 if (h >= UH_PRIME_DEFAULT) {
mas01mc@292	327 h = h - UH_PRIME_DEFAULT;
mas01mc@292	328 }
mas01mc@292	329 CR_ASSERT(h < UH_PRIME_DEFAULT);
mas01mc@292	330 }
mas01mc@292	331 return h;
mas01mc@292	332 }
mas01mc@292	333
mas01mc@292	334 Uns32T H::bucket_insert_point(bucket **pp){
mas01mc@296	335 collisionCount = 0;
mas01mc@292	336 if(!*pp){
mas01mc@292	337 *pp = new bucket();
mas01mc@292	338 #ifdef LSH_BLOCK_FULL_ROWS
mas01mc@292	339 (*pp)->t2 = 0; // Use t2 as a collision counter for the row
mas01mc@292	340 (*pp)->next = new bucket();
mas01mc@292	341 #endif
mas01mc@292	342 }
mas01mc@292	343 #ifdef LSH_BLOCK_FULL_ROWS
mas01mc@292	344 collisionCount = (*pp)->t2;
mas01mc@292	345 if(collisionCount < H::C){ // Block if row is full
mas01mc@292	346 (*pp)->t2++; // Increment collision counter
mas01mc@292	347 pointCount++;
mas01mc@292	348 collisionCount++;
mas01mc@292	349 __bucket_insert_point((*pp)->next); // First bucket holds collision count
mas01mc@292	350 }
mas01mc@292	351 #else
mas01mc@296	352 pointCount++;
mas01mc@296	353 __bucket_insert_point(*pp); // No collision count storage
mas01mc@292	354 #endif
mas01mc@292	355 return collisionCount;
mas01mc@292	356 }
mas01mc@292	357
mas01mc@292	358 void H::__bucket_insert_point(bucket* p){
mas01mc@292	359 if(p->t2 == IFLAG){ // initialization flag, is it in the domain of t2?
mas01mc@292	360 p->t2 = H::t2;
mas01mc@292	361 bucketCount++; // Record start of new point-locale collision chain
mas01mc@292	362 p->snext = new sbucket();
mas01mc@292	363 __sbucket_insert_point(p->snext);
mas01mc@292	364 return;
mas01mc@292	365 }
mas01mc@292	366
mas01mc@292	367 if(p->t2 == H::t2){
mas01mc@292	368 __sbucket_insert_point(p->snext);
mas01mc@292	369 return;
mas01mc@292	370 }
mas01mc@292	371
mas01mc@292	372 if(p->next){
mas01mc@292	373 __bucket_insert_point(p->next);
mas01mc@292	374 }
mas01mc@292	375
mas01mc@292	376 else{
mas01mc@292	377 p->next = new bucket();
mas01mc@292	378 __bucket_insert_point(p->next);
mas01mc@292	379 }
mas01mc@292	380
mas01mc@292	381 }
mas01mc@292	382
mas01mc@292	383 void H::__sbucket_insert_point(sbucket* p){
mas01mc@292	384 if(p->pointID==IFLAG){
mas01mc@292	385 p->pointID = H::p;
mas01mc@292	386 return;
mas01mc@292	387 }
mas01mc@292	388
mas01mc@292	389 // Search for pointID
mas01mc@292	390 if(p->snext){
mas01mc@292	391 __sbucket_insert_point(p->snext);
mas01mc@292	392 }
mas01mc@292	393 else{
mas01mc@292	394 // Make new point collision bucket at end of list
mas01mc@292	395 p->snext = new sbucket();
mas01mc@292	396 __sbucket_insert_point(p->snext);
mas01mc@292	397 }
mas01mc@292	398 }
mas01mc@292	399
mas01mc@293	400 inline bucket** H::get_bucket(int j){
mas01mc@292	401 return *(h+j);
mas01mc@292	402 }
mas01mc@292	403
mas01mc@293	404 // Interface to Locality Sensitive Hashing G
mas01mc@293	405 G::G(float ww, Uns32T kk,Uns32T mm, Uns32T dd, Uns32T NN, Uns32T CC, float rr):
mas01mc@293	406 H(kk,mm,dd,NN,CC,ww,rr), // constructor to initialize data structures
mas01mc@293	407 lshHeader(0),
mas01mc@292	408 calling_instance(0),
mas01mc@293	409 add_point_callback(0)
mas01mc@292	410 {
mas01mc@293	411
mas01mc@292	412 }
mas01mc@292	413
mas01mc@292	414 // Serialize from file LSH constructor
mas01mc@292	415 // Read parameters from database file
mas01mc@292	416 // Load the hash functions, close the database
mas01mc@292	417 // Optionally load the LSH tables into head-allocated lists in core
mas01mc@292	418 G::G(char* filename, bool lshInCoreFlag):
mas01mc@293	419 H(), // default base-class constructor call delays data-structure initialization
mas01mc@293	420 lshHeader(0),
mas01mc@292	421 calling_instance(0),
mas01mc@292	422 add_point_callback(0)
mas01mc@292	423 {
mas01mc@292	424 int dbfid = unserialize_lsh_header(filename);
mas01mc@293	425
mas01mc@293	426 H::initialize_lsh_functions(); // Base-class data-structure initialization
mas01mc@293	427 unserialize_lsh_functions(dbfid); // populate with on-disk hashfunction values
mas01mc@292	428
mas01mc@292	429 // Format1 only needs unserializing if specifically requested
mas01mc@292	430 if(!(lshHeader->flags&O2_SERIAL_FILEFORMAT2) && lshInCoreFlag){
mas01mc@292	431 unserialize_lsh_hashtables_format1(dbfid);
mas01mc@292	432 }
mas01mc@292	433
mas01mc@292	434 // Format2 always needs unserializing
mas01mc@292	435 if(lshHeader->flags&O2_SERIAL_FILEFORMAT2 && lshInCoreFlag){
mas01mc@292	436 unserialize_lsh_hashtables_format2(dbfid);
mas01mc@292	437 }
mas01mc@292	438
mas01mc@293	439 close(dbfid);}
mas01mc@292	440
mas01mc@292	441 G::~G(){
mas01mc@292	442 delete lshHeader;
mas01mc@292	443 }
mas01mc@292	444
mas01mc@292	445 // single point insertion; inserted values are hash value and pointID
mas01mc@292	446 Uns32T G::insert_point(vector<float>& v, Uns32T pp){
mas01mc@292	447 Uns32T collisionCount = 0;
mas01mc@292	448 H::p = pp;
mas01mc@296	449 if(pp<=H::maxp)
mas01mc@296	450 error("points must be indexed in strict ascending order", "LSH::insert_point(vector<float>&, Uns32T pointID)");
mas01mc@296	451 H::maxp=pp; // Store highest pointID in database
mas01mc@293	452 H::compute_hash_functions( v );
mas01mc@292	453 for(Uns32T j = 0 ; j < H::L ; j++ ){ // insertion
mas01mc@293	454 H::generate_hash_keys( ( H::g + j ), ( H::r1 + j ), *( H::r2 + j ) );
mas01mc@292	455 collisionCount += bucket_insert_point( *(h + j) + t1 );
mas01mc@292	456 }
mas01mc@292	457 return collisionCount;
mas01mc@292	458 }
mas01mc@292	459
mas01mc@292	460
mas01mc@292	461 // batch insert for a point set
mas01mc@292	462 // inserted values are vector hash value and pointID starting at basePointID
mas01mc@292	463 void G::insert_point_set(vector<vector<float> >& vv, Uns32T basePointID){
mas01mc@292	464 for(Uns32T point=0; point<vv.size(); point++)
mas01mc@292	465 insert_point(vv[point], basePointID+point);
mas01mc@292	466 }
mas01mc@292	467
mas01mc@292	468 // point retrieval routine
mas01mc@292	469 void G::retrieve_point(vector<float>& v, Uns32T qpos, ReporterCallbackPtr add_point, void* caller){
mas01mc@292	470 calling_instance = caller;
mas01mc@292	471 add_point_callback = add_point;
mas01mc@293	472 H::compute_hash_functions( v );
mas01mc@292	473 for(Uns32T j = 0 ; j < H::L ; j++ ){
mas01mc@293	474 H::generate_hash_keys( ( H::g + j ), ( H::r1 + j ), *( H::r2 + j ) );
mas01mc@293	475 if( bucket* bPtr = *(get_bucket(j) + get_t1()) )
mas01mc@292	476 #ifdef LSH_BLOCK_FULL_ROWS
mas01mc@292	477 bucket_chain_point( bPtr->next, qpos);
mas01mc@292	478 #else
mas01mc@292	479 bucket_chain_point( bPtr , qpos);
mas01mc@292	480 #endif
mas01mc@292	481 }
mas01mc@292	482 }
mas01mc@292	483
mas01mc@292	484 void G::retrieve_point_set(vector<vector<float> >& vv, ReporterCallbackPtr add_point, void* caller){
mas01mc@292	485 for(Uns32T qpos = 0 ; qpos < vv.size() ; qpos++ )
mas01mc@292	486 retrieve_point(vv[qpos], qpos, add_point, caller);
mas01mc@292	487 }
mas01mc@292	488
mas01mc@292	489 // export lsh tables to table structure on disk
mas01mc@292	490 //
mas01mc@292	491 // LSH TABLE STRUCTURE
mas01mc@292	492 // ---header 64 bytes ---
mas01mc@292	493 // [magic #tables #rows #cols elementSize databaseSize version flags dim #funs 0 0 0 0 0 0]
mas01mc@292	494 //
mas01mc@292	495 // ---random projections L x k x d float ---
mas01mc@292	496 // A[0][0][0] A[0][0][1] ... A[0][0][d-1]
mas01mc@292	497 // A[0][1][0] A[0][1][1] ... A[1][1][d-1]
mas01mc@292	498 // ...
mas01mc@292	499 // A[0][K-1][0] A[0][1][1] ... A[0][k-1][d-1]
mas01mc@292	500 // ...
mas01mc@292	501 // ...
mas01mc@292	502 // A[L-1][0][0] A[M-1][0][1] ... A[L-1][0][d-1]
mas01mc@292	503 // A[L-1][1][0] A[M-1][1][1] ... A[L-1][1][d-1]
mas01mc@292	504 // ...
mas01mc@292	505 // A[L-1][k-1][0] A[M-1][1][1] ... A[L-1][k-1][d-1]
mas01mc@292	506 //
mas01mc@292	507 // ---bias L x k float ---
mas01mc@292	508 // b[0][0] b[0][1] ... b[0][k-1]
mas01mc@292	509 // b[1][0] b[1][1] ... b[1][k-1]
mas01mc@292	510 // ...
mas01mc@292	511 // b[L-1][0] b[L-1][1] ... b[L-1][k-1]
mas01mc@292	512 //
mas01mc@292	513 // ---random r1 L x k float ---
mas01mc@292	514 // r1[0][0] r1[0][1] ... r1[0][k-1]
mas01mc@292	515 // r1[1][0] r1[1][1] ... r1[1][k-1]
mas01mc@292	516 // ...
mas01mc@292	517 // r1[L-1][0] r1[L-1][1] ... r1[L-1][k-1]
mas01mc@292	518 //
mas01mc@292	519 // ---random r2 L x k float ---
mas01mc@292	520 // r2[0][0] r2[0][1] ... r2[0][k-1]
mas01mc@292	521 // r2[1][0] r2[1][1] ... r2[1][k-1]
mas01mc@292	522 // ...
mas01mc@292	523 // r2[L-1][0] r2[L-1][1] ... r2[L-1][k-1]
mas01mc@292	524 //
mas01mc@293	525 // ***** HASHTABLES FORMAT1 (optimized for LSH_ON_DISK retrieval) *****
mas01mc@292	526 // ---hash table 0: N x C x 8 ---
mas01mc@292	527 // [t2 pointID][t2 pointID]...[t2 pointID]
mas01mc@292	528 // [t2 pointID][t2 pointID]...[t2 pointID]
mas01mc@292	529 // ...
mas01mc@292	530 // [t2 pointID][t2 pointID]...[t2 pointID]
mas01mc@292	531 //
mas01mc@292	532 // ---hash table 1: N x C x 8 ---
mas01mc@292	533 // [t2 pointID][t2 pointID]...[t2 pointID]
mas01mc@292	534 // [t2 pointID][t2 pointID]...[t2 pointID]
mas01mc@292	535 // ...
mas01mc@292	536 // [t2 pointID][t2 pointID]...[t2 pointID]
mas01mc@292	537 //
mas01mc@292	538 // ...
mas01mc@292	539 //
mas01mc@292	540 // ---hash table L-1: N x C x 8 ---
mas01mc@292	541 // [t2 pointID][t2 pointID]...[t2 pointID]
mas01mc@292	542 // [t2 pointID][t2 pointID]...[t2 pointID]
mas01mc@292	543 // ...
mas01mc@292	544 // [t2 pointID][t2 pointID]...[t2 pointID]
mas01mc@292	545 //
mas01mc@293	546 // ***** HASHTABLES FORMAT2 (optimized for LSH_IN_CORE retrieval) *****
mas01mc@293	547 //
mas01mc@293	548 // State machine controlled by regular expression.
mas01mc@293	549 // legend:
mas01mc@293	550 //
mas01mc@293	551 // O2_SERIAL_FLAGS_T1_BIT = 0x80000000U
mas01mc@293	552 // O2_SERIAL_FLAGS_T2_BIT = 0x40000000U
mas01mc@293	553 // O2_SERIAL_FLAGS_END_BIT = 0x20000000U
mas01mc@293	554 //
mas01mc@293	555 // T1(t1) - T1 hash token containing t1 hash key with O2_SERIAL_FLAGS_T1_BIT set (t1 range 0..2^29-1)
mas01mc@293	556 // T2 - T2 hash token with O2_SERIAL_FLAGS_T2_BIT set
mas01mc@293	557 // t2 - t2 hash key (range 1..2^32-6)
mas01mc@293	558 // p - point identifier (range 0..2^32-1)
mas01mc@293	559 // E - end hash table token with O2_SERIAL_FLAGS_END_BIT set
mas01mc@293	560 // {...} required arguments
mas01mc@293	561 // [...] optional arguments
mas01mc@293	562 // * - match zero or more occurences
mas01mc@293	563 // + - match one or more occurences
mas01mc@293	564 // {...}^L - repeat argument L times
mas01mc@293	565 //
mas01mc@293	566 // FORMAT2 Regular expression:
mas01mc@293	567 // { [T1(t1) T2 t2 p+ [T2 t2 p+]* ]* E. }^L
mas01mc@293	568 //
mas01mc@292	569
mas01mc@292	570 // Serial header constructors
mas01mc@292	571 SerialHeader::SerialHeader(){;}
mas01mc@296	572 SerialHeader::SerialHeader(float W, Uns32T L, Uns32T N, Uns32T C, Uns32T k, Uns32T d, float r, Uns32T p, Uns32T FMT, Uns32T pc):
mas01mc@292	573 lshMagic(O2_SERIAL_MAGIC),
mas01mc@292	574 binWidth(W),
mas01mc@292	575 numTables(L),
mas01mc@292	576 numRows(N),
mas01mc@292	577 numCols(C),
mas01mc@292	578 elementSize(O2_SERIAL_ELEMENT_SIZE),
mas01mc@296	579 version(O2_SERIAL_VERSION),
mas01mc@296	580 size(0), // we are deprecating this value
mas01mc@292	581 flags(FMT),
mas01mc@292	582 dataDim(d),
mas01mc@292	583 numFuns(k),
mas01mc@292	584 radius(r),
mas01mc@296	585 maxp(p),
mas01mc@296	586 size_long((unsigned long long)L * align_up((unsigned long long)N * C * O2_SERIAL_ELEMENT_SIZE, get_page_logn()) // hash tables
mas01mc@296	587 + align_up(O2_SERIAL_HEADER_SIZE + // header + hash functions
mas01mc@296	588 (unsigned long long)Lk( sizeof(float)d+2sizeof(Uns32T)+sizeof(float)),get_page_logn())),
mas01mc@296	589 pointCount(pc){
mas01mc@296	590
mas01mc@296	591 if(FMT==O2_SERIAL_FILEFORMAT2)
mas01mc@296	592 size_long = (unsigned long long)align_up(O2_SERIAL_HEADER_SIZE
mas01mc@296	593 + (unsigned long long)Lk(sizeof(float)*d+2+sizeof(Uns32T)
mas01mc@296	594 +sizeof(float)) + (unsigned long long)pc*16UL,get_page_logn());
mas01mc@296	595 } // header
mas01mc@292	596
mas01mc@292	597 float* G::get_serial_hashfunction_base(char* db){
mas01mc@292	598 if(db&&lshHeader)
mas01mc@292	599 return (float*)(db+O2_SERIAL_HEADER_SIZE);
mas01mc@292	600 else return NULL;
mas01mc@292	601 }
mas01mc@292	602
mas01mc@292	603 SerialElementT* G::get_serial_hashtable_base(char* db){
mas01mc@292	604 if(db&&lshHeader)
mas01mc@292	605 return (SerialElementT*)(db+get_serial_hashtable_offset());
mas01mc@292	606 else
mas01mc@292	607 return NULL;
mas01mc@292	608 }
mas01mc@292	609
mas01mc@292	610 Uns32T G::get_serial_hashtable_offset(){
mas01mc@292	611 if(lshHeader)
mas01mc@292	612 return align_up(O2_SERIAL_HEADER_SIZE +
mas01mc@292	613 LlshHeader->numFuns( sizeof(float)lshHeader->dataDim+2sizeof(Uns32T)+sizeof(float)),get_page_logn());
mas01mc@292	614 else
mas01mc@292	615 return 0;
mas01mc@292	616 }
mas01mc@292	617
mas01mc@292	618 void G::serialize(char* filename, Uns32T serialFormat){
mas01mc@292	619 int dbfid;
mas01mc@292	620 char* db;
mas01mc@292	621 int dbIsNew=0;
mas01mc@292	622
mas01mc@292	623 // Check requested serialFormat
mas01mc@292	624 if(!(serialFormat==O2_SERIAL_FILEFORMAT1 \|\| serialFormat==O2_SERIAL_FILEFORMAT2))
mas01mc@292	625 error("Unrecognized serial file format request: ", "serialize()");
mas01mc@296	626
mas01mc@292	627 // Test to see if file exists
mas01mc@292	628 if((dbfid = open (filename, O_RDONLY)) < 0)
mas01mc@292	629 // If it doesn't, then create the file (CREATE)
mas01mc@292	630 if(errno == ENOENT){
mas01mc@292	631 // Create the file
mas01mc@292	632 std::cout << "Creating new serialized LSH database:" << filename << "...";
mas01mc@292	633 std::cout.flush();
mas01mc@292	634 serial_create(filename, serialFormat);
mas01mc@292	635 dbIsNew=1;
mas01mc@292	636 }
mas01mc@292	637 else
mas01mc@292	638 // The file can't be opened
mas01mc@292	639 error("Can't open the file", filename, "open");
mas01mc@292	640
mas01mc@292	641 // Load the on-disk header into core
mas01mc@292	642 dbfid = serial_open(filename, 1); // open for write
mas01mc@292	643 db = serial_mmap(dbfid, O2_SERIAL_HEADER_SIZE, 1);// get database pointer
mas01mc@292	644 serial_get_header(db); // read header
mas01mc@292	645 serial_munmap(db, O2_SERIAL_HEADER_SIZE); // drop mmap
mas01mc@292	646
mas01mc@292	647 // Check compatibility of core and disk data structures
mas01mc@292	648 if( !serial_can_merge(serialFormat) )
mas01mc@292	649 error("Incompatible core and serial LSH, data structure dimensions mismatch.");
mas01mc@292	650
mas01mc@292	651 // For new LSH databases write the hashfunctions
mas01mc@292	652 if(dbIsNew)
mas01mc@292	653 serialize_lsh_hashfunctions(dbfid);
mas01mc@292	654 // Write the hashtables in the requested format
mas01mc@292	655 if(serialFormat == O2_SERIAL_FILEFORMAT1)
mas01mc@292	656 serialize_lsh_hashtables_format1(dbfid, !dbIsNew);
mas01mc@292	657 else
mas01mc@292	658 serialize_lsh_hashtables_format2(dbfid, !dbIsNew);
mas01mc@292	659
mas01mc@292	660 if(!dbIsNew){
mas01mc@292	661 db = serial_mmap(dbfid, O2_SERIAL_HEADER_SIZE, 1);// get database pointer
mas01mc@292	662 //serial_get_header(db); // read header
mas01mc@293	663 cout << "maxp = " << H::maxp << endl;
mas01mc@293	664 lshHeader->maxp=H::maxp;
mas01mc@292	665 // Default to FILEFORMAT1
mas01mc@292	666 if(!(lshHeader->flags&O2_SERIAL_FILEFORMAT2))
mas01mc@294	667 lshHeader->flags\|=O2_SERIAL_FILEFORMAT1;
mas01mc@292	668 memcpy((char)db, (char)lshHeader, sizeof(SerialHeaderT));
mas01mc@292	669 serial_munmap(db, O2_SERIAL_HEADER_SIZE); // drop mmap
mas01mc@292	670 }
mas01mc@292	671
mas01mc@292	672 serial_close(dbfid);
mas01mc@292	673 }
mas01mc@292	674
mas01mc@292	675 // Test to see if core structure and requested format is
mas01mc@292	676 // compatible with currently opened database
mas01mc@292	677 int G::serial_can_merge(Uns32T format){
mas01mc@292	678 SerialHeaderT* that = lshHeader;
mas01mc@292	679 if( (format==O2_SERIAL_FILEFORMAT2 && !that->flags&O2_SERIAL_FILEFORMAT2)
mas01mc@292	680 \|\| (format!=O2_SERIAL_FILEFORMAT2 && that->flags&O2_SERIAL_FILEFORMAT2)
mas01mc@292	681 \|\| !( this->w == that->binWidth &&
mas01mc@296	682 this->L == that->numTables &&
mas01mc@296	683 this->N == that->numRows &&
mas01mc@296	684 this->k == that->numFuns &&
mas01mc@296	685 this->d == that->dataDim &&
mas01mc@296	686 sizeof(SerialElementT) == that->elementSize &&
mas01mc@296	687 this->radius == that->radius)){
mas01mc@292	688 serial_print_header(format);
mas01mc@292	689 return 0;
mas01mc@292	690 }
mas01mc@292	691 else
mas01mc@292	692 return 1;
mas01mc@292	693 }
mas01mc@292	694
mas01mc@292	695 // Used as an error message for serial_can_merge()
mas01mc@292	696 void G::serial_print_header(Uns32T format){
mas01mc@292	697 std::cout << "Fc:" << format << " Fs:" << lshHeader->flags << endl;
mas01mc@292	698 std::cout << "Wc:" << w << " Ls:" << lshHeader->binWidth << endl;
mas01mc@292	699 std::cout << "Lc:" << L << " Ls:" << lshHeader->numTables << endl;
mas01mc@292	700 std::cout << "Nc:" << N << " Ns:" << lshHeader->numRows << endl;
mas01mc@292	701 std::cout << "kc:" << k << " ks:" << lshHeader->numFuns << endl;
mas01mc@292	702 std::cout << "dc:" << d << " ds:" << lshHeader->dataDim << endl;
mas01mc@292	703 std::cout << "sc:" << sizeof(SerialElementT) << " ss:" << lshHeader->elementSize << endl;
mas01mc@292	704 std::cout << "rc:" << this->radius << " rs:" << lshHeader->radius << endl;
mas01mc@292	705 }
mas01mc@292	706
mas01mc@292	707 int G::serialize_lsh_hashfunctions(int fid){
mas01mc@292	708 float* pf;
mas01mc@292	709 Uns32T *pu;
mas01mc@292	710 Uns32T x,y,z;
mas01mc@292	711
mas01mc@293	712 char* db = serial_mmap(fid, get_serial_hashtable_offset(), 1);// get database pointer
mas01mc@292	713 pf = get_serial_hashfunction_base(db);
mas01mc@292	714
mas01mc@292	715 // HASH FUNCTIONS
mas01mc@292	716 // Write the random projectors A[][][]
mas01mc@292	717 #ifdef USE_U_FUNCTIONS
mas01mc@292	718 for( x = 0 ; x < H::m ; x++ )
mas01mc@292	719 for( y = 0 ; y < H::k/2 ; y++ )
mas01mc@292	720 #else
mas01mc@292	721 for( x = 0 ; x < H::L ; x++ )
mas01mc@292	722 for( y = 0 ; y < H::k ; y++ )
mas01mc@292	723 #endif
mas01mc@292	724 for( z = 0 ; z < d ; z++ )
mas01mc@293	725 *pf++ = H::A[x][y][z];
mas01mc@292	726
mas01mc@292	727 // Write the random biases b[][]
mas01mc@292	728 #ifdef USE_U_FUNCTIONS
mas01mc@292	729 for( x = 0 ; x < H::m ; x++ )
mas01mc@292	730 for( y = 0 ; y < H::k/2 ; y++ )
mas01mc@292	731 #else
mas01mc@292	732 for( x = 0 ; x < H::L ; x++ )
mas01mc@292	733 for( y = 0 ; y < H::k ; y++ )
mas01mc@292	734 #endif
mas01mc@293	735 *pf++ = H::b[x][y];
mas01mc@292	736
mas01mc@292	737 pu = (Uns32T*)pf;
mas01mc@292	738
mas01mc@292	739 // Write the Z projectors r1[][]
mas01mc@292	740 for( x = 0 ; x < H::L ; x++)
mas01mc@292	741 for( y = 0 ; y < H::k ; y++)
mas01mc@293	742 *pu++ = H::r1[x][y];
mas01mc@292	743
mas01mc@292	744 // Write the Z projectors r2[][]
mas01mc@292	745 for( x = 0 ; x < H::L ; x++)
mas01mc@292	746 for( y = 0; y < H::k ; y++)
mas01mc@293	747 *pu++ = H::r2[x][y];
mas01mc@292	748
mas01mc@292	749 serial_munmap(db, get_serial_hashtable_offset());
mas01mc@292	750 return 1;
mas01mc@292	751 }
mas01mc@292	752
mas01mc@292	753 int G::serialize_lsh_hashtables_format1(int fid, int merge){
mas01mc@292	754 SerialElementT pe, pt;
mas01mc@292	755 Uns32T x,y;
mas01mc@292	756
mas01mc@292	757 if( merge && !serial_can_merge(O2_SERIAL_FILEFORMAT1) )
mas01mc@292	758 error("Cannot merge core and serial LSH, data structure dimensions mismatch.");
mas01mc@292	759
mas01mc@292	760 Uns32T hashTableSize=sizeof(SerialElementT)lshHeader->numRowslshHeader->numCols;
mas01mc@292	761 Uns32T colCount, meanColCount, colCountN, maxColCount, minColCount;
mas01mc@292	762 // Write the hash tables
mas01mc@292	763 for( x = 0 ; x < H::L ; x++ ){
mas01mc@292	764 std::cout << (merge ? "merging":"writing") << " hash table " << x << " FORMAT1...";
mas01mc@292	765 std::cout.flush();
mas01mc@292	766 // memory map a single hash table for sequential access
mas01mc@292	767 // Align each hash table to page boundary
mas01mc@292	768 char* dbtable = serial_mmap(fid, hashTableSize, 1,
mas01mc@292	769 align_up(get_serial_hashtable_offset()+x*hashTableSize, get_page_logn()));
mas01mc@292	770 if(madvise(dbtable, hashTableSize, MADV_SEQUENTIAL)<0)
mas01mc@292	771 error("could not advise hashtable memory","","madvise");
mas01mc@292	772
mas01mc@292	773 maxColCount=0;
mas01mc@292	774 minColCount=O2_SERIAL_MAX_COLS;
mas01mc@292	775 meanColCount=0;
mas01mc@292	776 colCountN=0;
mas01mc@292	777 pt=(SerialElementT*)dbtable;
mas01mc@292	778 for( y = 0 ; y < H::N ; y++ ){
mas01mc@292	779 // Move disk pointer to beginning of row
mas01mc@292	780 pe=pt+y*lshHeader->numCols;
mas01mc@292	781
mas01mc@292	782 colCount=0;
mas01mc@292	783 if(bucket* bPtr = h[x][y])
mas01mc@292	784 if(merge)
mas01mc@292	785 #ifdef LSH_BLOCK_FULL_ROWS
mas01mc@292	786 serial_merge_hashtable_row_format1(pe, bPtr->next, colCount); // skip collision counter bucket
mas01mc@292	787 else
mas01mc@292	788 serial_write_hashtable_row_format1(pe, bPtr->next, colCount); // skip collision counter bucket
mas01mc@292	789 #else
mas01mc@292	790 serial_merge_hashtable_row_format1(pe, bPtr, colCount);
mas01mc@292	791 else
mas01mc@292	792 serial_write_hashtable_row_format1(pe, bPtr, colCount);
mas01mc@292	793 #endif
mas01mc@292	794 if(colCount){
mas01mc@292	795 if(colCount<minColCount)
mas01mc@292	796 minColCount=colCount;
mas01mc@292	797 if(colCount>maxColCount)
mas01mc@292	798 maxColCount=colCount;
mas01mc@292	799 meanColCount+=colCount;
mas01mc@292	800 colCountN++;
mas01mc@292	801 }
mas01mc@292	802 }
mas01mc@292	803 if(colCountN)
mas01mc@292	804 std::cout << "#rows with collisions =" << colCountN << ", mean = " << meanColCount/(float)colCountN
mas01mc@292	805 << ", min = " << minColCount << ", max = " << maxColCount
mas01mc@292	806 << endl;
mas01mc@292	807 serial_munmap(dbtable, hashTableSize);
mas01mc@292	808 }
mas01mc@292	809
mas01mc@292	810 // We're done writing
mas01mc@292	811 return 1;
mas01mc@292	812 }
mas01mc@292	813
mas01mc@292	814 void G::serial_merge_hashtable_row_format1(SerialElementT* pr, bucket* b, Uns32T& colCount){
mas01mc@292	815 while(b && b->t2!=IFLAG){
mas01mc@292	816 SerialElementT*pe=pr; // reset disk pointer to beginning of row
mas01mc@292	817 serial_merge_element_format1(pe, b->snext, b->t2, colCount);
mas01mc@292	818 b=b->next;
mas01mc@292	819 }
mas01mc@292	820 }
mas01mc@292	821
mas01mc@292	822 void G::serial_merge_element_format1(SerialElementT* pe, sbucket* sb, Uns32T t2, Uns32T& colCount){
mas01mc@292	823 while(sb){
mas01mc@292	824 if(colCount==lshHeader->numCols){
mas01mc@292	825 std::cout << "!point-chain full " << endl;
mas01mc@292	826 return;
mas01mc@292	827 }
mas01mc@292	828 Uns32T c=0;
mas01mc@292	829 // Merge collision chains
mas01mc@292	830 while(c<lshHeader->numCols){
mas01mc@292	831 if( (pe+c)->hashValue==IFLAG){
mas01mc@292	832 (pe+c)->hashValue=t2;
mas01mc@292	833 (pe+c)->pointID=sb->pointID;
mas01mc@292	834 colCount=c+1;
mas01mc@292	835 if(c+1<lshHeader->numCols)
mas01mc@292	836 (pe+c+1)->hashValue=IFLAG;
mas01mc@292	837 break;
mas01mc@292	838 }
mas01mc@292	839 c++;
mas01mc@292	840 }
mas01mc@292	841 sb=sb->snext;
mas01mc@292	842 }
mas01mc@292	843 return;
mas01mc@292	844 }
mas01mc@292	845
mas01mc@292	846 void G::serial_write_hashtable_row_format1(SerialElementT& pe, bucket b, Uns32T& colCount){
mas01mc@292	847 pe->hashValue=IFLAG;
mas01mc@292	848 while(b && b->t2!=IFLAG){
mas01mc@292	849 serial_write_element_format1(pe, b->snext, b->t2, colCount);
mas01mc@292	850 b=b->next;
mas01mc@292	851 }
mas01mc@292	852 }
mas01mc@292	853
mas01mc@292	854 void G::serial_write_element_format1(SerialElementT& pe, sbucket sb, Uns32T t2, Uns32T& colCount){
mas01mc@292	855 while(sb){
mas01mc@292	856 if(colCount==lshHeader->numCols){
mas01mc@292	857 std::cout << "!point-chain full " << endl;
mas01mc@292	858 return;
mas01mc@292	859 }
mas01mc@292	860 pe->hashValue=t2;
mas01mc@292	861 pe->pointID=sb->pointID;
mas01mc@292	862 pe++;
mas01mc@292	863 colCount++;
mas01mc@292	864 sb=sb->snext;
mas01mc@292	865 }
mas01mc@292	866 pe->hashValue=IFLAG;
mas01mc@292	867 return;
mas01mc@292	868 }
mas01mc@292	869
mas01mc@292	870 int G::serialize_lsh_hashtables_format2(int fid, int merge){
mas01mc@292	871 Uns32T x,y;
mas01mc@292	872
mas01mc@292	873 if( merge && !serial_can_merge(O2_SERIAL_FILEFORMAT2) )
mas01mc@292	874 error("Cannot merge core and serial LSH, data structure dimensions mismatch.");
mas01mc@292	875
mas01mc@292	876 // We must pereform FORMAT1 merges in core
mas01mc@292	877 if(merge)
mas01mc@292	878 unserialize_lsh_hashtables_format2(fid);
mas01mc@292	879
mas01mc@292	880 Uns32T colCount, meanColCount, colCountN, maxColCount, minColCount, t1;
mas01mc@292	881 lseek(fid, get_serial_hashtable_offset(), SEEK_SET);
mas01mc@292	882
mas01mc@292	883 // Write the hash tables
mas01mc@292	884 for( x = 0 ; x < H::L ; x++ ){
mas01mc@292	885 std::cout << (merge ? "merging":"writing") << " hash table " << x << " FORMAT2...";
mas01mc@292	886 std::cout.flush();
mas01mc@292	887 maxColCount=0;
mas01mc@292	888 minColCount=O2_SERIAL_MAX_COLS;
mas01mc@292	889 meanColCount=0;
mas01mc@292	890 colCountN=0;
mas01mc@292	891 for( y = 0 ; y < H::N ; y++ ){
mas01mc@292	892 colCount=0;
mas01mc@292	893 if(bucket* bPtr = h[x][y]){
mas01mc@292	894 t1 = y \| O2_SERIAL_FLAGS_T1_BIT;
mas01mc@292	895 if( write(fid, &t1, sizeof(Uns32T)) != sizeof(Uns32T) ){
mas01mc@292	896 close(fid);
mas01mc@292	897 error("write error in serial_write_hashtable_format2() [t1]");
mas01mc@292	898 }
mas01mc@292	899 #ifdef LSH_BLOCK_FULL_ROWS
mas01mc@292	900 serial_write_hashtable_row_format2(fid, bPtr->next, colCount); // skip collision counter bucket
mas01mc@292	901 #else
mas01mc@292	902 serial_write_hashtable_row_format2(fid, bPtr, colCount);
mas01mc@292	903 #endif
mas01mc@292	904 }
mas01mc@292	905 if(colCount){
mas01mc@292	906 if(colCount<minColCount)
mas01mc@292	907 minColCount=colCount;
mas01mc@292	908 if(colCount>maxColCount)
mas01mc@292	909 maxColCount=colCount;
mas01mc@292	910 meanColCount+=colCount;
mas01mc@292	911 colCountN++;
mas01mc@292	912 }
mas01mc@292	913 }
mas01mc@292	914 // Write END of table marker
mas01mc@292	915 t1 = O2_SERIAL_FLAGS_END_BIT;
mas01mc@292	916 if( write(fid, &t1, sizeof(Uns32T)) != sizeof(Uns32T) ){
mas01mc@292	917 close(fid);
mas01mc@292	918 error("write error in serial_write_hashtable_format2() [end]");
mas01mc@292	919 }
mas01mc@292	920
mas01mc@292	921 if(colCountN)
mas01mc@292	922 std::cout << "#rows with collisions =" << colCountN << ", mean = " << meanColCount/(float)colCountN
mas01mc@292	923 << ", min = " << minColCount << ", max = " << maxColCount
mas01mc@292	924 << endl;
mas01mc@292	925 }
mas01mc@292	926
mas01mc@292	927 // We're done writing
mas01mc@292	928 return 1;
mas01mc@292	929 }
mas01mc@292	930
mas01mc@292	931 void G::serial_write_hashtable_row_format2(int fid, bucket* b, Uns32T& colCount){
mas01mc@292	932 while(b && b->t2!=IFLAG){
mas01mc@292	933 t2 = O2_SERIAL_FLAGS_T2_BIT;
mas01mc@292	934 if( write(fid, &t2, sizeof(Uns32T)) != sizeof(Uns32T) ){
mas01mc@292	935 close(fid);
mas01mc@292	936 error("write error in serial_write_hashtable_row_format2()");
mas01mc@292	937 }
mas01mc@292	938 t2 = b->t2;
mas01mc@292	939 if( write(fid, &t2, sizeof(Uns32T)) != sizeof(Uns32T) ){
mas01mc@292	940 close(fid);
mas01mc@292	941 error("write error in serial_write_hashtable_row_format2()");
mas01mc@292	942 }
mas01mc@292	943 serial_write_element_format2(fid, b->snext, colCount);
mas01mc@292	944 b=b->next;
mas01mc@292	945 }
mas01mc@292	946 }
mas01mc@292	947
mas01mc@292	948 void G::serial_write_element_format2(int fid, sbucket* sb, Uns32T& colCount){
mas01mc@292	949 while(sb){
mas01mc@292	950 if(write(fid, &sb->pointID, sizeof(Uns32T))!=sizeof(Uns32T)){
mas01mc@292	951 close(fid);
mas01mc@292	952 error("Write error in serial_write_element_format2()");
mas01mc@292	953 }
mas01mc@292	954 colCount++;
mas01mc@292	955 sb=sb->snext;
mas01mc@292	956 }
mas01mc@292	957 }
mas01mc@292	958
mas01mc@292	959
mas01mc@292	960 int G::serial_create(char* filename, Uns32T FMT){
mas01mc@292	961 return serial_create(filename, w, L, N, C, k, d, FMT);
mas01mc@292	962 }
mas01mc@292	963
mas01mc@292	964
mas01mc@292	965 int G::serial_create(char* filename, float binWidth, Uns32T numTables, Uns32T numRows, Uns32T numCols,
mas01mc@292	966 Uns32T numFuns, Uns32T dim, Uns32T FMT){
mas01mc@292	967
mas01mc@292	968 if(numTables > O2_SERIAL_MAX_TABLES \|\| numRows > O2_SERIAL_MAX_ROWS
mas01mc@292	969 \|\| numCols > O2_SERIAL_MAX_COLS \|\| numFuns > O2_SERIAL_MAX_FUNS
mas01mc@292	970 \|\| dim>O2_SERIAL_MAX_DIM){
mas01mc@292	971 error("LSH parameters out of bounds for serialization");
mas01mc@292	972 }
mas01mc@292	973
mas01mc@292	974 int dbfid;
mas01mc@292	975 if ((dbfid = open (filename, O_RDWR\|O_CREAT\|O_EXCL, S_IRUSR\|S_IWUSR\|S_IRGRP\|S_IWGRP\|S_IROTH\|S_IWOTH)) < 0)
mas01mc@292	976 error("Can't create serial file", filename, "open");
mas01mc@292	977 get_lock(dbfid, 1);
mas01mc@292	978
mas01mc@292	979 // Make header first to get size of serialized database
mas01mc@296	980 lshHeader = new SerialHeaderT(binWidth, numTables, numRows, numCols, numFuns, dim, radius, maxp, FMT, pointCount);
mas01mc@296	981
mas01mc@296	982 cout << "file size: <=" << lshHeader->get_size()/1024UL << "KB" << endl;
mas01mc@296	983 if(lshHeader->get_size()>O2_SERIAL_MAXFILESIZE)
mas01mc@296	984 error("Maximum size of LSH file exceded: > 4000MB");
mas01mc@296	985
mas01mc@292	986 // go to the location corresponding to the last byte
mas01mc@292	987 if (lseek (dbfid, lshHeader->get_size() - 1, SEEK_SET) == -1)
mas01mc@292	988 error("lseek error in db file", "", "lseek");
mas01mc@292	989
mas01mc@292	990 // write a dummy byte at the last location
mas01mc@292	991 if (write (dbfid, "", 1) != 1)
mas01mc@292	992 error("write error", "", "write");
mas01mc@292	993
mas01mc@293	994 char* db = serial_mmap(dbfid, O2_SERIAL_HEADER_SIZE, 1);
mas01mc@296	995
mas01mc@292	996 memcpy (db, lshHeader, O2_SERIAL_HEADER_SIZE);
mas01mc@296	997
mas01mc@292	998 serial_munmap(db, O2_SERIAL_HEADER_SIZE);
mas01mc@296	999
mas01mc@292	1000 close(dbfid);
mas01mc@292	1001
mas01mc@292	1002 std::cout << "done initializing tables." << endl;
mas01mc@292	1003
mas01mc@292	1004 return 1;
mas01mc@292	1005 }
mas01mc@292	1006
mas01mc@292	1007 char* G::serial_mmap(int dbfid, Uns32T memSize, Uns32T forWrite, off_t offset){
mas01mc@293	1008 char* db;
mas01mc@292	1009 if(forWrite){
mas01mc@292	1010 if ((db = (char*) mmap(0, memSize, PROT_READ \| PROT_WRITE,
mas01mc@292	1011 MAP_SHARED, dbfid, offset)) == (caddr_t) -1)
mas01mc@292	1012 error("mmap error in request for writable serialized database", "", "mmap");
mas01mc@292	1013 }
mas01mc@292	1014 else if ((db = (char*) mmap(0, memSize, PROT_READ, MAP_SHARED, dbfid, offset)) == (caddr_t) -1)
mas01mc@292	1015 error("mmap error in read-only serialized database", "", "mmap");
mas01mc@292	1016
mas01mc@292	1017 return db;
mas01mc@292	1018 }
mas01mc@292	1019
mas01mc@292	1020 SerialHeaderT* G::serial_get_header(char* db){
mas01mc@292	1021 lshHeader = new SerialHeaderT();
mas01mc@292	1022 memcpy((char*)lshHeader, db, sizeof(SerialHeaderT));
mas01mc@292	1023
mas01mc@292	1024 if(lshHeader->lshMagic!=O2_SERIAL_MAGIC)
mas01mc@292	1025 error("Not an LSH database file");
mas01mc@292	1026
mas01mc@292	1027 return lshHeader;
mas01mc@292	1028 }
mas01mc@292	1029
mas01mc@292	1030 void G::serial_munmap(char* db, Uns32T N){
mas01mc@292	1031 munmap(db, N);
mas01mc@292	1032 }
mas01mc@292	1033
mas01mc@292	1034 int G::serial_open(char* filename, int writeFlag){
mas01mc@292	1035 int dbfid;
mas01mc@292	1036 if(writeFlag){
mas01mc@292	1037 if ((dbfid = open (filename, O_RDWR)) < 0)
mas01mc@292	1038 error("Can't open serial file for read/write", filename, "open");
mas01mc@292	1039 get_lock(dbfid, writeFlag);
mas01mc@292	1040 }
mas01mc@292	1041 else{
mas01mc@292	1042 if ((dbfid = open (filename, O_RDONLY)) < 0)
mas01mc@292	1043 error("Can't open serial file for read", filename, "open");
mas01mc@292	1044 get_lock(dbfid, 0);
mas01mc@292	1045 }
mas01mc@292	1046
mas01mc@292	1047 return dbfid;
mas01mc@292	1048 }
mas01mc@292	1049
mas01mc@292	1050 void G::serial_close(int dbfid){
mas01mc@292	1051
mas01mc@292	1052 release_lock(dbfid);
mas01mc@292	1053 close(dbfid);
mas01mc@292	1054 }
mas01mc@292	1055
mas01mc@292	1056 int G::unserialize_lsh_header(char* filename){
mas01mc@292	1057
mas01mc@292	1058 int dbfid;
mas01mc@292	1059 char* db;
mas01mc@292	1060 // Test to see if file exists
mas01mc@292	1061 if((dbfid = open (filename, O_RDONLY)) < 0)
mas01mc@292	1062 error("Can't open the file", filename, "open");
mas01mc@292	1063 close(dbfid);
mas01mc@292	1064 dbfid = serial_open(filename, 0); // open for read
mas01mc@292	1065 db = serial_mmap(dbfid, O2_SERIAL_HEADER_SIZE, 0);// get database pointer
mas01mc@292	1066 serial_get_header(db); // read header
mas01mc@292	1067 serial_munmap(db, O2_SERIAL_HEADER_SIZE); // drop mmap
mas01mc@292	1068
mas01mc@292	1069 // Unserialize header parameters
mas01mc@292	1070 H::L = lshHeader->numTables;
mas01mc@292	1071 H::m = (Uns32T)( (1.0 + sqrt(1 + 8.0*(int)H::L)) / 2.0);
mas01mc@292	1072 H::N = lshHeader->numRows;
mas01mc@292	1073 H::C = lshHeader->numCols;
mas01mc@292	1074 H::k = lshHeader->numFuns;
mas01mc@292	1075 H::d = lshHeader->dataDim;
mas01mc@293	1076 H::w = lshHeader->binWidth;
mas01mc@293	1077 H::radius = lshHeader->radius;
mas01mc@293	1078 H::maxp = lshHeader->maxp;
mas01mc@296	1079 H::pointCount = lshHeader->pointCount;
mas01mc@292	1080
mas01mc@292	1081 return dbfid;
mas01mc@292	1082 }
mas01mc@292	1083
mas01mc@292	1084 // unserialize the LSH parameters
mas01mc@292	1085 // we leave the LSH tree on disk as a flat file
mas01mc@292	1086 // it is this flat file that we search by memory mapping
mas01mc@292	1087 void G::unserialize_lsh_functions(int dbfid){
mas01mc@292	1088 Uns32T j, kk;
mas01mc@292	1089 float* pf;
mas01mc@292	1090 Uns32T* pu;
mas01mc@292	1091
mas01mc@292	1092 // Load the hash functions into core
mas01mc@292	1093 char* db = serial_mmap(dbfid, get_serial_hashtable_offset(), 0);// get database pointer again
mas01mc@292	1094
mas01mc@292	1095 pf = get_serial_hashfunction_base(db);
mas01mc@292	1096
mas01mc@292	1097 #ifdef USE_U_FUNCTIONS
mas01mc@292	1098 for( j = 0 ; j < H::m ; j++ ){ // L functions gj(v)
mas01mc@292	1099 for( kk = 0 ; kk < H::k/2 ; kk++ ){ // Normally distributed hash functions
mas01mc@292	1100 #else
mas01mc@292	1101 for( j = 0 ; j < H::L ; j++ ){ // L functions gj(v)
mas01mc@292	1102 for( kk = 0 ; kk < H::k ; kk++ ){ // Normally distributed hash functions
mas01mc@292	1103 #endif
mas01mc@292	1104 for(Uns32T i = 0 ; i < H::d ; i++ )
mas01mc@293	1105 H::A[j][kk][i] = *pf++; // Normally distributed random vectors
mas01mc@292	1106 }
mas01mc@292	1107 }
mas01mc@292	1108 #ifdef USE_U_FUNCTIONS
mas01mc@292	1109 for( j = 0 ; j < H::m ; j++ ) // biases b
mas01mc@292	1110 for( kk = 0 ; kk < H::k/2 ; kk++ )
mas01mc@292	1111 #else
mas01mc@292	1112 for( j = 0 ; j < H::L ; j++ ) // biases b
mas01mc@292	1113 for( kk = 0 ; kk < H::k ; kk++ )
mas01mc@292	1114 #endif
mas01mc@293	1115 H::b[j][kk] = *pf++;
mas01mc@292	1116
mas01mc@292	1117 pu = (Uns32T*)pf;
mas01mc@292	1118 for( j = 0 ; j < H::L ; j++ ) // Z projectors r1
mas01mc@292	1119 for( kk = 0 ; kk < H::k ; kk++ )
mas01mc@292	1120 H::r1[j][kk] = *pu++;
mas01mc@292	1121
mas01mc@292	1122 for( j = 0 ; j < H::L ; j++ ) // Z projectors r2
mas01mc@292	1123 for( kk = 0 ; kk < H::k ; kk++ )
mas01mc@292	1124 H::r2[j][kk] = *pu++;
mas01mc@292	1125
mas01mc@293	1126 serial_munmap(db, get_serial_hashtable_offset());
mas01mc@292	1127 }
mas01mc@292	1128
mas01mc@292	1129 void G::unserialize_lsh_hashtables_format1(int fid){
mas01mc@292	1130 SerialElementT pe, pt;
mas01mc@292	1131 Uns32T x,y;
mas01mc@292	1132 Uns32T hashTableSize=sizeof(SerialElementT)lshHeader->numRowslshHeader->numCols;
mas01mc@292	1133 // Read the hash tables into core
mas01mc@292	1134 for( x = 0 ; x < H::L ; x++ ){
mas01mc@292	1135 // memory map a single hash table
mas01mc@292	1136 // Align each hash table to page boundary
mas01mc@292	1137 char* dbtable = serial_mmap(fid, hashTableSize, 0,
mas01mc@292	1138 align_up(get_serial_hashtable_offset()+x*hashTableSize, get_page_logn()));
mas01mc@292	1139 if(madvise(dbtable, hashTableSize, MADV_SEQUENTIAL)<0)
mas01mc@292	1140 error("could not advise hashtable memory","","madvise");
mas01mc@292	1141 pt=(SerialElementT*)dbtable;
mas01mc@292	1142 for( y = 0 ; y < H::N ; y++ ){
mas01mc@292	1143 // Move disk pointer to beginning of row
mas01mc@292	1144 pe=pt+y*lshHeader->numCols;
mas01mc@292	1145 unserialize_hashtable_row_format1(pe, h[x]+y);
mas01mc@292	1146 #ifdef __LSH_DUMP_CORE_TABLES__
mas01mc@292	1147 printf("S[%d,%d]", x, y);
mas01mc@292	1148 serial_bucket_dump(pe);
mas01mc@292	1149 printf("C[%d,%d]", x, y);
mas01mc@292	1150 dump_hashtable_row(h[x][y]);
mas01mc@292	1151 #endif
mas01mc@292	1152 }
mas01mc@292	1153 serial_munmap(dbtable, hashTableSize);
mas01mc@292	1154 }
mas01mc@292	1155 }
mas01mc@292	1156
mas01mc@292	1157 void G::unserialize_hashtable_row_format1(SerialElementT* pe, bucket** b){
mas01mc@292	1158 Uns32T colCount = 0;
mas01mc@292	1159 while(colCount!=lshHeader->numCols && pe->hashValue !=IFLAG){
mas01mc@292	1160 H::p = pe->pointID; // current point ID
mas01mc@292	1161 t2 = pe->hashValue;
mas01mc@292	1162 bucket_insert_point(b);
mas01mc@292	1163 pe++;
mas01mc@292	1164 colCount++;
mas01mc@292	1165 }
mas01mc@292	1166 }
mas01mc@292	1167
mas01mc@292	1168 void G::unserialize_lsh_hashtables_format2(int fid){
mas01mc@292	1169 Uns32T x=0,y=0;
mas01mc@292	1170
mas01mc@292	1171 // Seek to hashtable base offset
mas01mc@292	1172 if(lseek(fid, get_serial_hashtable_offset(), SEEK_SET)!=get_serial_hashtable_offset()){
mas01mc@292	1173 close(fid);
mas01mc@292	1174 error("Seek error in unserialize_lsh_hashtables_format2");
mas01mc@292	1175 }
mas01mc@292	1176
mas01mc@292	1177 // Read the hash tables into core (structure is given in header)
mas01mc@292	1178 while( x < H::L){
mas01mc@292	1179 if(read(fid, &(H::t1), sizeof(Uns32T))!=sizeof(Uns32T)){
mas01mc@292	1180 close(fid);
mas01mc@292	1181 error("Read error","unserialize_lsh_hashtables_format2()");
mas01mc@292	1182 }
mas01mc@292	1183 if(H::t1&O2_SERIAL_FLAGS_END_BIT)
mas01mc@292	1184 x++; // End of table
mas01mc@292	1185 else
mas01mc@292	1186 while(y < H::N){
mas01mc@292	1187 // Read a row and move file pointer to beginning of next row or table
mas01mc@292	1188 if(!(H::t1&O2_SERIAL_FLAGS_T1_BIT)){
mas01mc@292	1189 close(fid);
mas01mc@292	1190 error("State matchine error t1","unserialize_lsh_hashtables_format2()");
mas01mc@292	1191 }
mas01mc@292	1192 y = H::t1 ^ O2_SERIAL_FLAGS_T1_BIT;
mas01mc@292	1193 if(y>=H::N){
mas01mc@292	1194 close(fid);
mas01mc@292	1195 error("Unserialized hashtable row pointer out of range","unserialize_lsh_hashtables_format2()");
mas01mc@292	1196 }
mas01mc@292	1197 Uns32T token = unserialize_hashtable_row_format2(fid, h[x]+y);
mas01mc@292	1198
mas01mc@292	1199 #ifdef __LSH_DUMP_CORE_TABLES__
mas01mc@292	1200 printf("C[%d,%d]", x, y);
mas01mc@292	1201 dump_hashtable_row(h[x][y]);
mas01mc@292	1202 #endif
mas01mc@292	1203 // Check that token is valid
mas01mc@292	1204 if( !(token&O2_SERIAL_FLAGS_T1_BIT \|\| token&O2_SERIAL_FLAGS_END_BIT) ){
mas01mc@292	1205 close(fid);
mas01mc@292	1206 error("State machine error end of row/table", "unserialize_lsh_hashtables_format2()");
mas01mc@292	1207 }
mas01mc@292	1208 // Check for end of table flag
mas01mc@292	1209 if(token&O2_SERIAL_FLAGS_END_BIT){
mas01mc@292	1210 x++;
mas01mc@292	1211 break;
mas01mc@292	1212 }
mas01mc@292	1213 // Check for new row flag
mas01mc@292	1214 if(token&O2_SERIAL_FLAGS_T1_BIT)
mas01mc@292	1215 H::t1 = token;
mas01mc@292	1216 }
mas01mc@292	1217 }
mas01mc@292	1218 }
mas01mc@292	1219
mas01mc@292	1220 Uns32T G::unserialize_hashtable_row_format2(int fid, bucket** b){
mas01mc@292	1221 bool pointFound = false;
mas01mc@292	1222 if(read(fid, &(H::t2), sizeof(Uns32T)) != sizeof(Uns32T)){
mas01mc@292	1223 close(fid);
mas01mc@292	1224 error("Read error T2 token","unserialize_hashtable_row_format2");
mas01mc@292	1225 }
mas01mc@292	1226 if( !(H::t2==O2_SERIAL_FLAGS_END_BIT \|\| H::t2==O2_SERIAL_FLAGS_T2_BIT)){
mas01mc@292	1227 close(fid);
mas01mc@292	1228 error("State machine error: expected E or T2");
mas01mc@292	1229 }
mas01mc@292	1230 while(!(H::t2==O2_SERIAL_FLAGS_END_BIT \|\| H::t2&O2_SERIAL_FLAGS_T1_BIT)){
mas01mc@292	1231 pointFound=false;
mas01mc@292	1232 // Check for T2 token
mas01mc@292	1233 if(H::t2!=O2_SERIAL_FLAGS_T2_BIT)
mas01mc@292	1234 error("State machine error T2 token", "unserialize_hashtable_row_format2()");
mas01mc@292	1235 // Read t2 value
mas01mc@292	1236 if(read(fid, &(H::t2), sizeof(Uns32T)) != sizeof(Uns32T)){
mas01mc@292	1237 close(fid);
mas01mc@292	1238 error("Read error t2","unserialize_hashtable_row_format2");
mas01mc@292	1239 }
mas01mc@292	1240 if(read(fid, &(H::p), sizeof(Uns32T)) != sizeof(Uns32T)){
mas01mc@292	1241 close(fid);
mas01mc@292	1242 error("Read error H::p","unserialize_hashtable_row_format2");
mas01mc@292	1243 }
mas01mc@292	1244 while(!(H::p==O2_SERIAL_FLAGS_END_BIT \|\| H::p&O2_SERIAL_FLAGS_T1_BIT \|\| H::p==O2_SERIAL_FLAGS_T2_BIT )){
mas01mc@292	1245 pointFound=true;
mas01mc@292	1246 bucket_insert_point(b);
mas01mc@292	1247 if(read(fid, &(H::p), sizeof(Uns32T)) != sizeof(Uns32T)){
mas01mc@292	1248 close(fid);
mas01mc@292	1249 error("Read error H::p","unserialize_hashtable_row_format2");
mas01mc@292	1250 }
mas01mc@292	1251 }
mas01mc@292	1252 H::t2 = H::p; // Copy last found token to t2
mas01mc@292	1253 if(!pointFound)
mas01mc@292	1254 error("State machine error: point", "unserialize_hashtable_row_format2()");
mas01mc@292	1255 }
mas01mc@292	1256 return H::t2; // holds current token
mas01mc@292	1257 }
mas01mc@292	1258
mas01mc@292	1259 void G::dump_hashtable_row(bucket* p){
mas01mc@292	1260 while(p && p->t2!=IFLAG){
mas01mc@292	1261 sbucket* sbp = p->snext;
mas01mc@292	1262 while(sbp){
mas01mc@292	1263 printf("(%0X,%u)", p->t2, sbp->pointID);
mas01mc@292	1264 fflush(stdout);
mas01mc@292	1265 sbp=sbp->snext;
mas01mc@292	1266 }
mas01mc@292	1267 p=p->next;
mas01mc@292	1268 }
mas01mc@292	1269 printf("\n");
mas01mc@292	1270 }
mas01mc@292	1271
mas01mc@292	1272
mas01mc@292	1273 // G::serial_retrieve_point( ... )
mas01mc@292	1274 // retrieves (pointID) from a serialized LSH database
mas01mc@292	1275 //
mas01mc@292	1276 // inputs:
mas01mc@292	1277 // filename - file name of serialized LSH database
mas01mc@292	1278 // vv - query point set
mas01mc@292	1279 //
mas01mc@292	1280 // outputs:
mas01mc@292	1281 // inserts retrieved points into add_point() callback method
mas01mc@292	1282 void G::serial_retrieve_point_set(char* filename, vector<vector<float> >& vv, ReporterCallbackPtr add_point, void* caller)
mas01mc@292	1283 {
mas01mc@292	1284 int dbfid = serial_open(filename, 0); // open for read
mas01mc@292	1285 char* dbheader = serial_mmap(dbfid, O2_SERIAL_HEADER_SIZE, 0);// get database pointer
mas01mc@292	1286 serial_get_header(dbheader); // read header
mas01mc@292	1287 serial_munmap(dbheader, O2_SERIAL_HEADER_SIZE); // drop header mmap
mas01mc@292	1288
mas01mc@292	1289 if((lshHeader->flags & O2_SERIAL_FILEFORMAT2)){
mas01mc@292	1290 close(dbfid);
mas01mc@292	1291 error("serial_retrieve_point_set is for SERIAL_FILEFORMAT1 only");
mas01mc@292	1292 }
mas01mc@292	1293
mas01mc@292	1294 // size of each hash table
mas01mc@292	1295 Uns32T hashTableSize=sizeof(SerialElementT)lshHeader->numRowslshHeader->numCols;
mas01mc@292	1296 calling_instance = caller; // class instance variable used in ...bucket_chain_point()
mas01mc@292	1297 add_point_callback = add_point;
mas01mc@292	1298
mas01mc@292	1299 for(Uns32T j=0; j<L; j++){
mas01mc@292	1300 // memory map a single hash table for random access
mas01mc@292	1301 char* db = serial_mmap(dbfid, hashTableSize, 0,
mas01mc@292	1302 align_up(get_serial_hashtable_offset()+j*hashTableSize,get_page_logn()));
mas01mc@292	1303 if(madvise(db, hashTableSize, MADV_RANDOM)<0)
mas01mc@292	1304 error("could not advise local hashtable memory","","madvise");
mas01mc@292	1305 SerialElementT* pe = (SerialElementT*)db ;
mas01mc@292	1306 for(Uns32T qpos=0; qpos<vv.size(); qpos++){
mas01mc@293	1307 H::compute_hash_functions(vv[qpos]);
mas01mc@293	1308 H::generate_hash_keys((g+j),(r1+j),*(r2+j));
mas01mc@292	1309 serial_bucket_chain_point(pe+t1*lshHeader->numCols, qpos); // Point to correct row
mas01mc@292	1310 }
mas01mc@292	1311 serial_munmap(db, hashTableSize); // drop hashtable mmap
mas01mc@292	1312 }
mas01mc@292	1313 serial_close(dbfid);
mas01mc@292	1314 }
mas01mc@292	1315
mas01mc@292	1316 void G::serial_retrieve_point(char* filename, vector<float>& v, Uns32T qpos, ReporterCallbackPtr add_point, void* caller){
mas01mc@292	1317 int dbfid = serial_open(filename, 0); // open for read
mas01mc@292	1318 char* dbheader = serial_mmap(dbfid, O2_SERIAL_HEADER_SIZE, 0);// get database pointer
mas01mc@292	1319 serial_get_header(dbheader); // read header
mas01mc@292	1320 serial_munmap(dbheader, O2_SERIAL_HEADER_SIZE); // drop header mmap
mas01mc@292	1321
mas01mc@292	1322 if((lshHeader->flags & O2_SERIAL_FILEFORMAT2)){
mas01mc@292	1323 close(dbfid);
mas01mc@292	1324 error("serial_retrieve_point is for SERIAL_FILEFORMAT1 only");
mas01mc@292	1325 }
mas01mc@292	1326
mas01mc@292	1327 // size of each hash table
mas01mc@292	1328 Uns32T hashTableSize=sizeof(SerialElementT)lshHeader->numRowslshHeader->numCols;
mas01mc@292	1329 calling_instance = caller;
mas01mc@292	1330 add_point_callback = add_point;
mas01mc@293	1331 H::compute_hash_functions(v);
mas01mc@292	1332 for(Uns32T j=0; j<L; j++){
mas01mc@292	1333 // memory map a single hash table for random access
mas01mc@292	1334 char* db = serial_mmap(dbfid, hashTableSize, 0,
mas01mc@292	1335 align_up(get_serial_hashtable_offset()+j*hashTableSize,get_page_logn()));
mas01mc@292	1336 if(madvise(db, hashTableSize, MADV_RANDOM)<0)
mas01mc@292	1337 error("could not advise local hashtable memory","","madvise");
mas01mc@292	1338 SerialElementT* pe = (SerialElementT*)db ;
mas01mc@293	1339 H::generate_hash_keys((g+j),(r1+j),*(r2+j));
mas01mc@292	1340 serial_bucket_chain_point(pe+t1*lshHeader->numCols, qpos); // Point to correct row
mas01mc@292	1341 serial_munmap(db, hashTableSize); // drop hashtable mmap
mas01mc@292	1342 }
mas01mc@292	1343 serial_close(dbfid);
mas01mc@292	1344 }
mas01mc@292	1345
mas01mc@292	1346 void G::serial_dump_tables(char* filename){
mas01mc@292	1347 int dbfid = serial_open(filename, 0); // open for read
mas01mc@292	1348 char* dbheader = serial_mmap(dbfid, O2_SERIAL_HEADER_SIZE, 0);// get database pointer
mas01mc@292	1349 serial_get_header(dbheader); // read header
mas01mc@292	1350 serial_munmap(dbheader, O2_SERIAL_HEADER_SIZE); // drop header mmap
mas01mc@292	1351 Uns32T hashTableSize=sizeof(SerialElementT)lshHeader->numRowslshHeader->numCols;
mas01mc@292	1352 for(Uns32T j=0; j<L; j++){
mas01mc@292	1353 // memory map a single hash table for random access
mas01mc@292	1354 char* db = serial_mmap(dbfid, hashTableSize, 0,
mas01mc@292	1355 align_up(get_serial_hashtable_offset()+j*hashTableSize,get_page_logn()));
mas01mc@292	1356 if(madvise(db, hashTableSize, MADV_SEQUENTIAL)<0)
mas01mc@292	1357 error("could not advise local hashtable memory","","madvise");
mas01mc@292	1358 SerialElementT* pe = (SerialElementT*)db ;
mas01mc@292	1359 printf("********* TABLE %d *************\n", j);
mas01mc@292	1360 fflush(stdout);
mas01mc@292	1361 int count=0;
mas01mc@292	1362 do{
mas01mc@292	1363 printf("[%d,%d]", j, count++);
mas01mc@292	1364 fflush(stdout);
mas01mc@292	1365 serial_bucket_dump(pe);
mas01mc@292	1366 pe+=lshHeader->numCols;
mas01mc@292	1367 }while(pe<(SerialElementT)db+lshHeader->numRowslshHeader->numCols);
mas01mc@292	1368 }
mas01mc@292	1369
mas01mc@292	1370 }
mas01mc@292	1371
mas01mc@292	1372 void G::serial_bucket_dump(SerialElementT* pe){
mas01mc@292	1373 SerialElementT* pend = pe+lshHeader->numCols;
mas01mc@292	1374 while( !(pe->hashValue==IFLAG \|\| pe==pend ) ){
mas01mc@292	1375 printf("(%0X,%u)",pe->hashValue,pe->pointID);
mas01mc@292	1376 pe++;
mas01mc@292	1377 }
mas01mc@292	1378 printf("\n");
mas01mc@292	1379 fflush(stdout);
mas01mc@292	1380 }
mas01mc@292	1381
mas01mc@292	1382 void G::serial_bucket_chain_point(SerialElementT* pe, Uns32T qpos){
mas01mc@292	1383 SerialElementT* pend = pe+lshHeader->numCols;
mas01mc@292	1384 while( !(pe->hashValue==IFLAG \|\| pe==pend ) ){
mas01mc@292	1385 if(pe->hashValue==t2){ // new match
mas01mc@292	1386 add_point_callback(calling_instance, pe->pointID, qpos, radius);
mas01mc@292	1387 }
mas01mc@292	1388 pe++;
mas01mc@292	1389 }
mas01mc@292	1390 }
mas01mc@292	1391
mas01mc@292	1392 void G::bucket_chain_point(bucket* p, Uns32T qpos){
mas01mc@292	1393 if(!p \|\| p->t2==IFLAG)
mas01mc@292	1394 return;
mas01mc@292	1395 if(p->t2==t2){ // match
mas01mc@292	1396 sbucket_chain_point(p->snext, qpos); // add to reporter
mas01mc@292	1397 }
mas01mc@292	1398 if(p->next){
mas01mc@292	1399 bucket_chain_point(p->next, qpos); // recurse
mas01mc@292	1400 }
mas01mc@292	1401 }
mas01mc@292	1402
mas01mc@292	1403 void G::sbucket_chain_point(sbucket* p, Uns32T qpos){
mas01mc@292	1404 add_point_callback(calling_instance, p->pointID, qpos, radius);
mas01mc@292	1405 if(p->snext){
mas01mc@292	1406 sbucket_chain_point(p->snext, qpos);
mas01mc@292	1407 }
mas01mc@292	1408 }
mas01mc@292	1409
mas01mc@292	1410 void G::get_lock(int fd, bool exclusive) {
mas01mc@292	1411 struct flock lock;
mas01mc@292	1412 int status;
mas01mc@292	1413 lock.l_type = exclusive ? F_WRLCK : F_RDLCK;
mas01mc@292	1414 lock.l_whence = SEEK_SET;
mas01mc@292	1415 lock.l_start = 0;
mas01mc@292	1416 lock.l_len = 0; /* "the whole file" */
mas01mc@292	1417 retry:
mas01mc@292	1418 do {
mas01mc@292	1419 status = fcntl(fd, F_SETLKW, &lock);
mas01mc@292	1420 } while (status != 0 && errno == EINTR);
mas01mc@292	1421 if (status) {
mas01mc@292	1422 if (errno == EAGAIN) {
mas01mc@292	1423 sleep(1);
mas01mc@292	1424 goto retry;
mas01mc@292	1425 } else {
mas01mc@292	1426 error("fcntl lock error", "", "fcntl");
mas01mc@292	1427 }
mas01mc@292	1428 }
mas01mc@292	1429 }
mas01mc@292	1430
mas01mc@292	1431 void G::release_lock(int fd) {
mas01mc@292	1432 struct flock lock;
mas01mc@292	1433 int status;
mas01mc@292	1434
mas01mc@292	1435 lock.l_type = F_UNLCK;
mas01mc@292	1436 lock.l_whence = SEEK_SET;
mas01mc@292	1437 lock.l_start = 0;
mas01mc@292	1438 lock.l_len = 0;
mas01mc@292	1439
mas01mc@292	1440 status = fcntl(fd, F_SETLKW, &lock);
mas01mc@292	1441
mas01mc@292	1442 if (status)
mas01mc@292	1443 error("fcntl unlock error", "", "fcntl");
mas01mc@292	1444 }

Mercurial > hg > audiodb

annotate lshlib.cpp @ 296:f922c234462f