+/* icsa.c
+ * Copyright (C) 2011, Antonio Fariña and Eduardo Rodriguez, all rights reserved.
+ *
+ * icsa.c: Implementation of the interface "../intIndex/interfaceIntIndex.h"
+ * that permits to represent a sequence of uint32 integers with an iCSA:
+ * An integer-oriented Compressed Suffix Array.
+ * Such representation will be handled as a "ticsa" data structure, that
+ * the WCSA self-index will use (as an opaque type) to
+ * create/save/load/search/recover/getSize of the representation of the
+ * original sequence.
+ * Suffix sorting is done via Larson/Sadakane suffix sort algorithm
+ * from the char-based csa.
+ *
+ * Ref: Larsson, N. J. and Sadakane, K. 2007. Faster suffix sorting. Theoretical
+ * Computer Science 387, 3, 258–272.
+ *
+ *
+ * See more details in:
+ * Antonio Fariña, Nieves Brisaboa, Gonzalo Navarro, Francisco Claude, Ángeles Places,
+ * and Eduardo Rodríguez. Word-based Self-Indexes for Natural Language Text. ACM
+ * Transactions on Information Systems (TOIS), 2012.
+ * http://vios.dc.fi.udc.es/indexing/wsi/publications.html
+ * http://www.dcc.uchile.cl/~gnavarro/ps/tois11.pdf
+ *
+ * This library is free software; you can redistribute it and/or
+ * modify it under the terms of the GNU Lesser General Public
+ * License as published by the Free Software Foundation; either
+ * version 2.1 of the License, or (at your option) any later version.
+ *
+ * This library is distributed in the hope that it will be useful,
+ * but WITHOUT ANY WARRANTY; without even the implied warranty of
+ * MERCHANTABILITY or FITNESS FOR A PARTICULAR PURPOSE. See the GNU
+ * Lesser General Public License for more details.
+ *
+ * You should have received a copy of the GNU Lesser General Public
+ * License along with this library; if not, write to the Free Software
+ * Foundation, Inc., 51 Franklin St, Fifth Floor, Boston, MA 02110-1301 USA
+ *
+ */
+
+#include <limits.h>
#include "icsa.h"
-// Global para que funcione a funcion de comparacion do quicksort
-uint *intVector;
-
-// Para o quicksort
-int suffixCmp(const void *arg1, const void *arg2) {
+#define KEY(p) (V[*(p)+(h)])
+#define SWAP(p, q) (tmp=*(p), *(p)=*(q), *(q)=tmp)
+#define MED3(a, b, c) (KEY(a)<KEY(b) ? \
+ (KEY(b)<KEY(c) ? (b) : KEY(a)<KEY(c) ? (c) : (a)) \
+ : (KEY(b)>KEY(c) ? (b) : KEY(a)>KEY(c) ? (c) : (a)))
+
+static int *I, /* group array, ultimately suffix array.*/
+ *V, /* inverse array, ultimately inverse of I.*/
+ r, /* number of symbols aggregated by transform.*/
+ h; /* length of already-sorted prefixes.*/
+
+/* Subroutine for select_sort_split and sort_split. Sets group numbers for a
+ group whose lowest position in I is pl and highest position is pm.*/
+
+static void update_group(int *pl, int *pm)
+{
+ int g;
+
+ g=pm-I; /* group number.*/
+ V[*pl]=g; /* update group number of first position.*/
+ if (pl==pm)
+ *pl=-1; /* one element, sorted group.*/
+ else
+ do /* more than one element, unsorted group.*/
+ V[*++pl]=g; /* update group numbers.*/
+ while (pl<pm);
+}
- register uint a,b;
- a=*((uint *) arg1);
- b=*((uint *) arg2);
+/* Quadratic sorting method to use for small subarrays. To be able to update
+ group numbers consistently, a variant of selection sorting is used.*/
+
+static void select_sort_split(int *p, int n) {
+ int *pa, *pb, *pi, *pn;
+ int f, v, tmp;
+
+ pa=p; /* pa is start of group being picked out.*/
+ pn=p+n-1; /* pn is last position of subarray.*/
+ while (pa<pn) {
+ for (pi=pb=pa+1, f=KEY(pa); pi<=pn; ++pi)
+ if ((v=KEY(pi))<f) {
+ f=v; /* f is smallest key found.*/
+ SWAP(pi, pa); /* place smallest element at beginning.*/
+ pb=pa+1; /* pb is position for elements equal to f.*/
+ } else if (v==f) { /* if equal to smallest key.*/
+ SWAP(pi, pb); /* place next to other smallest elements.*/
+ ++pb;
+ }
+ update_group(pa, pb-1); /* update group values for new group.*/
+ pa=pb; /* continue sorting rest of the subarray.*/
+ }
+ if (pa==pn) { /* check if last part is single element.*/
+ V[*pa]=pa-I;
+ *pa=-1; /* sorted group.*/
+ }
+}
- while(intVector[a] == intVector[b]) { a++; b++; }
- return (intVector[a] - intVector[b]);
+/* Subroutine for sort_split, algorithm by Bentley & McIlroy.*/
+
+static int choose_pivot(int *p, int n) {
+ int *pl, *pm, *pn;
+ int s;
+
+ pm=p+(n>>1); /* small arrays, middle element.*/
+ if (n>7) {
+ pl=p;
+ pn=p+n-1;
+ if (n>40) { /* big arrays, pseudomedian of 9.*/
+ s=n>>3;
+ pl=MED3(pl, pl+s, pl+s+s);
+ pm=MED3(pm-s, pm, pm+s);
+ pn=MED3(pn-s-s, pn-s, pn);
+ }
+ pm=MED3(pl, pm, pn); /* midsize arrays, median of 3.*/
+ }
+ return KEY(pm);
+}
+/* Sorting routine called for each unsorted group. Sorts the array of integers
+ (suffix numbers) of length n starting at p. The algorithm is a ternary-split
+ quicksort taken from Bentley & McIlroy, "Engineering a Sort Function",
+ Software -- Practice and Experience 23(11), 1249-1265 (November 1993). This
+ function is based on Program 7.*/
+
+static void sort_split(int *p, int n)
+{
+ int *pa, *pb, *pc, *pd, *pl, *pm, *pn;
+ int f, v, s, t, tmp;
+
+ if (n<7) { /* multi-selection sort smallest arrays.*/
+ select_sort_split(p, n);
+ return;
+ }
+
+ v=choose_pivot(p, n);
+ pa=pb=p;
+ pc=pd=p+n-1;
+ while (1) { /* split-end partition.*/
+ while (pb<=pc && (f=KEY(pb))<=v) {
+ if (f==v) {
+ SWAP(pa, pb);
+ ++pa;
+ }
+ ++pb;
+ }
+ while (pc>=pb && (f=KEY(pc))>=v) {
+ if (f==v) {
+ SWAP(pc, pd);
+ --pd;
+ }
+ --pc;
+ }
+ if (pb>pc)
+ break;
+ SWAP(pb, pc);
+ ++pb;
+ --pc;
+ }
+ pn=p+n;
+ if ((s=pa-p)>(t=pb-pa))
+ s=t;
+ for (pl=p, pm=pb-s; s; --s, ++pl, ++pm)
+ SWAP(pl, pm);
+ if ((s=pd-pc)>(t=pn-pd-1))
+ s=t;
+ for (pl=pb, pm=pn-s; s; --s, ++pl, ++pm)
+ SWAP(pl, pm);
+
+ s=pb-pa;
+ t=pd-pc;
+ if (s>0)
+ sort_split(p, s);
+ update_group(p+s, p+n-t-1);
+ if (t>0)
+ sort_split(p+n-t, t);
}
+/* Bucketsort for first iteration.
+
+ Input: x[0...n-1] holds integers in the range 1...k-1, all of which appear
+ at least once. x[n] is 0. (This is the corresponding output of transform.) k
+ must be at most n+1. p is array of size n+1 whose contents are disregarded.
+
+ Output: x is V and p is I after the initial sorting stage of the refined
+ suffix sorting algorithm.*/
+
+static void bucketsort(int *x, int *p, int n, int k)
+{
+ int *pi, i, c, d, g;
+
+ for (pi=p; pi<p+k; ++pi)
+ *pi=-1; /* mark linked lists empty.*/
+ for (i=0; i<=n; ++i) {
+ x[i]=p[c=x[i]]; /* insert in linked list.*/
+ p[c]=i;
+ }
+ for (pi=p+k-1, i=n; pi>=p; --pi) {
+ d=x[c=*pi]; /* c is position, d is next in list.*/
+ x[c]=g=i; /* last position equals group number.*/
+ if (d>=0) { /* if more than one element in group.*/
+ p[i--]=c; /* p is permutation for the sorted x.*/
+ do {
+ d=x[c=d]; /* next in linked list.*/
+ x[c]=g; /* group number in x.*/
+ p[i--]=c; /* permutation in p.*/
+ } while (d>=0);
+ } else
+ p[i--]=-1; /* one element, sorted group.*/
+ }
+}
+/* Transforms the alphabet of x by attempting to aggregate several symbols into
+ one, while preserving the suffix order of x. The alphabet may also be
+ compacted, so that x on output comprises all integers of the new alphabet
+ with no skipped numbers.
+
+ Input: x is an array of size n+1 whose first n elements are positive
+ integers in the range l...k-1. p is array of size n+1, used for temporary
+ storage. q controls aggregation and compaction by defining the maximum value
+ for any symbol during transformation: q must be at least k-l; if q<=n,
+ compaction is guaranteed; if k-l>n, compaction is never done; if q is
+ INT_MAX, the maximum number of symbols are aggregated into one.
+
+ Output: Returns an integer j in the range 1...q representing the size of the
+ new alphabet. If j<=n+1, the alphabet is compacted. The global variable r is
+ set to the number of old symbols grouped into one. Only x[n] is 0.*/
+
+static int transform(int *x, int *p, int n, int k, int l, int q)
+{
+ int b, c, d, e, i, j, m, s;
+ int *pi, *pj;
+
+ for (s=0, i=k-l; i; i>>=1)
+ ++s; /* s is number of bits in old symbol.*/
+ e=INT_MAX>>s; /* e is for overflow checking.*/
+ for (b=d=r=0; r<n && d<=e && (c=d<<s|(k-l))<=q; ++r) {
+ b=b<<s|(x[r]-l+1); /* b is start of x in chunk alphabet.*/
+ d=c; /* d is max symbol in chunk alphabet.*/
+ }
+ m=(1<<(r-1)*s)-1; /* m masks off top old symbol from chunk.*/
+ x[n]=l-1; /* emulate zero terminator.*/
+ if (d<=n) { /* if bucketing possible, compact alphabet.*/
+ for (pi=p; pi<=p+d; ++pi)
+ *pi=0; /* zero transformation table.*/
+ for (pi=x+r, c=b; pi<=x+n; ++pi) {
+ p[c]=1; /* mark used chunk symbol.*/
+ c=(c&m)<<s|(*pi-l+1); /* shift in next old symbol in chunk.*/
+ }
+ for (i=1; i<r; ++i) { /* handle last r-1 positions.*/
+ p[c]=1; /* mark used chunk symbol.*/
+ c=(c&m)<<s; /* shift in next old symbol in chunk.*/
+ }
+ for (pi=p, j=1; pi<=p+d; ++pi)
+ if (*pi)
+ *pi=j++; /* j is new alphabet size.*/
+ for (pi=x, pj=x+r, c=b; pj<=x+n; ++pi, ++pj) {
+ *pi=p[c]; /* transform to new alphabet.*/
+ c=(c&m)<<s|(*pj-l+1); /* shift in next old symbol in chunk.*/
+ }
+ while (pi<x+n) { /* handle last r-1 positions.*/
+ *pi++=p[c]; /* transform to new alphabet.*/
+ c=(c&m)<<s; /* shift right-end zero in chunk.*/
+ }
+ } else { /* bucketing not possible, don't compact.*/
+ for (pi=x, pj=x+r, c=b; pj<=x+n; ++pi, ++pj) {
+ *pi=c; /* transform to new alphabet.*/
+ c=(c&m)<<s|(*pj-l+1); /* shift in next old symbol in chunk.*/
+ }
+ while (pi<x+n) { /* handle last r-1 positions.*/
+ *pi++=c; /* transform to new alphabet.*/
+ c=(c&m)<<s; /* shift right-end zero in chunk.*/
+ }
+ j=d+1; /* new alphabet size.*/
+ }
+ x[n]=0; /* end-of-string symbol is zero.*/
+ return j; /* return new alphabet size.*/
+}
-/* **NO REVISADO TAMAÑO FILE.
-int buildIntIndexFromFile (char *filename, char *build_options,void **index) {
- //char filename[255];
- int file;
- struct stat f_stat;
- //sprintf(filename, "%s.%s", basename,SE_FILE_EXT);
-
- if( (file = open(filename, O_RDONLY)) < 0) {
- printf("Cannot open file %s\n", filename);
- exit(0);
- }
- if( fstat(file, &f_stat) < 0) {
- printf("Cannot read information from file %s\n", filename); exit(0);
- }
- uint sizeFile = (f_stat.st_size)/sizeof(uint);
-
- uint *se = (uint *) malloc (sizeFile);
- uint seSize = sizeFile / sizeof(uint);
- read(file, se, sizeFile); //the samples
- close(file);
- return (buildIntIndex(se,seSize,build_options,index));
+/* Makes suffix array p of x. x becomes inverse of p. p and x are both of size
+ n+1. Contents of x[0...n-1] are integers in the range l...k-1. Original
+ contents of x[n] is disregarded, the n-th symbol being regarded as
+ end-of-string smaller than all other symbols.*/
+
+void suffixsort(int *x, int *p, int n, int k, int l)
+{
+ int *pi, *pk;
+ int i, j, s, sl;
+
+ V=x; /* set global values.*/
+ I=p;
+
+ if (n>=k-l) { /* if bucketing possible,*/
+ j=transform(V, I, n, k, l, n);
+ bucketsort(V, I, n, j); /* bucketsort on first r positions.*/
+ } else {
+ transform(V, I, n, k, l, INT_MAX);
+ for (i=0; i<=n; ++i)
+ I[i]=i; /* initialize I with suffix numbers.*/
+ h=0;
+ sort_split(I, n+1); /* quicksort on first r positions.*/
+ }
+ h=r; /* number of symbols aggregated by transform.*/
+
+ while (*I>=-n) {
+ pi=I; /* pi is first position of group.*/
+ sl=0; /* sl is negated length of sorted groups.*/
+ do {
+ if ((s=*pi)<0) {
+ pi-=s; /* skip over sorted group.*/
+ sl+=s; /* add negated length to sl.*/
+ } else {
+ if (sl) {
+ *(pi+sl)=sl; /* combine sorted groups before pi.*/
+ sl=0;
+ }
+ pk=I+V[s]+1; /* pk-1 is last position of unsorted group.*/
+ sort_split(pi, pk-pi);
+ pi=pk; /* next group.*/
+ }
+ } while (pi<=I+n);
+ if (sl) /* if the array ends with a sorted group.*/
+ *(pi+sl)=sl; /* combine sorted groups at end of I.*/
+ h=2*h; /* double sorted-depth.*/
+ }
+
+ for (i=0; i<=n; ++i) /* reconstruct suffix array from inverse.*/
+ I[V[i]]=i;
}
-*/
-//ticsa *createIntegerCSA(uint **aintVector, uint textSize, char *build_options) {
-int buildIntIndex (uint *aintVector, uint n, char *build_options, void **index ){
- uint textSize=n;
- intVector = aintVector; //global variable
+
+//ticsa *createIntegerCSA(uint **intVector, uint textSize, char *build_options) {
+int buildIntIndex (uint *intVector, uint n, char *build_options, void **index ){
+ uint textSize=n;
ticsa *myicsa;
myicsa = (ticsa *) malloc (sizeof (ticsa));
uint *Psi, *SAI, *C, vocSize;
uint nsHUFF;
parametersCSA(myicsa, build_options);
-
+
nsHUFF=myicsa->tempNSHUFF;
-
+
// Almacenamos o valor dalguns parametros
+
myicsa->suffixArraySize = textSize;
- myicsa->D = (uint*) malloc (sizeof(uint) * ((textSize+31)/32));
-
- myicsa->samplesASize = (textSize + myicsa->T_A - 1) / myicsa->T_A + 1;
- myicsa->samplesA = (uint *)malloc(sizeof(int) * myicsa->samplesASize);
+ myicsa->D = (uint*) malloc (sizeof(uint) * ((textSize+31)/32));
+
+ myicsa->samplesASize = (textSize + myicsa->T_A - 1) / myicsa->T_A + 1; //--> última pos siempre sampleada!
+// myicsa->samplesASize = (textSize + myicsa->T_A - 1) / myicsa->T_A ;//+ 1;
+ myicsa->samplesA = (uint *)malloc(sizeof(uint) * myicsa->samplesASize);
+ myicsa->samplesA[myicsa->samplesASize-1] = 0000;
myicsa->BA = (uint*) malloc (sizeof(uint) * ((textSize+31)/32));
myicsa->samplesAInvSize = (textSize + myicsa->T_AInv - 1) / myicsa->T_AInv;
myicsa->samplesAInv = (uint *)malloc(sizeof(int) * myicsa->samplesAInvSize);
- // Reservamos espacio para os vectores
- Psi = (uint *) malloc (sizeof(uint) * textSize);
-
// CONSTRUIMOS A FUNCION C
vocSize = 0;
for(i=0;i<textSize;i++) if(intVector[i]>vocSize) vocSize = intVector[i];
for(i=vocSize;i>0;i--) C[i] = C[i-1];
C[0] = 0;
- // Construimos o array de sufixos (en Psi) - con quicksort
- printf("\n\t *BUILDING THE SUFFIX ARRAY over %d integers... (with qsort)", textSize);fflush(stdout);
- for(i=0; i<textSize; i++) Psi[i]=i;
-
- qsort(Psi, textSize, sizeof(uint), suffixCmp);
-
-
+ // Reservamos espacio para os array de sufijos
+ Psi = (uint *) malloc (sizeof(uint) * (textSize+1));
+ printf("\n\t *BUILDING THE SUFFIX ARRAY over %d integers... (with larsson-sadakane)", textSize);fflush(stdout);
+
+/* Makes suffix array p of x. x becomes inverse of p. p and x are both of size
+ n+1. Contents of x[0...n-1] are integers in the range l...k-1. Original
+ contents of x[n] is disregarded, the n-th symbol being regarded as
+ end-of-string smaller than all other symbols.*/
+ //void suffixsort(int *x, int *p, int n, int k, int l)
+
+ //suffixsort((int *)intVector, (int *)Psi, n, vocSize+1, 1);
+ suffixsort((int *)intVector, (int *)Psi, n-1, vocSize+1, 1);
+ //*Psi = *Psi++; // Con esto temos o array de sufixos desde a primeira posición (sen o terminador)
printf("\n\t ...... ended.");
+
+
// CONSTRUIMOS A INVERSA DO ARRAY DE SUFIXOS
+ //SAI = (uint *) malloc (sizeof(uint) * (textSize + 1)); // +1 para repetir na ultima posición. Evitamos un if
+ //for(i=0;i<textSize;i++) SAI[Psi[i]] = i;
+ //SAI[textSize] = SAI[0];
+
+ //SAI = intVector;
+
SAI = (uint *) malloc (sizeof(uint) * (textSize + 1)); // +1 para repetir na ultima posición. Evitamos un if
- for(i=0;i<textSize;i++) SAI[Psi[i]] = i;
+ for(i=0;i<textSize;i++) SAI[i] = intVector[i];
SAI[textSize] = SAI[0];
+ //SAI[textSize] = SAI[0];
+
// ALMACENAMOS AS MOSTRAS DO ARRAY DE SUFIXOS
for(i=0;i<((textSize+31)/32);i++) myicsa->BA[i] = 0;
for(i=0; i<textSize; i+=myicsa->T_A) bitset(myicsa->BA, SAI[i]);
//printf("TextSize = %d\n", textSize);
myicsa->bBA = createBitmap(myicsa->BA, textSize);
for(i=0,j=0; i<textSize; i++) if(bitget(myicsa->BA, i)) myicsa->samplesA[j++] = Psi[i];
-
+
// ALMACENAMOS AS MOSTRAS DA INVERSA DO ARRAY DE SUFIXOS
for(i=0,j=0;i<textSize;i+=myicsa->T_AInv) myicsa->samplesAInv[j++] = SAI[i];
-
+
// CONSTRUIMOS E COMPRIMIMOS PSI
printf("\n\t Creating compressed Psi...");
for(i=0;i<textSize;i++) Psi[i] = SAI[Psi[i]+1];
+
+ //FILE *ff = fopen("psi.log","w");
+ //for (i=0;i<textSize;i++) fprintf(ff,"%d::%u",i,Psi[i]);
+ //fclose(ff);
+
free(SAI);
- #ifdef PSI_HUFFMANRLE
+
+
+ #ifdef PSI_HUFFMANRLE
myicsa->hcPsi = huffmanCompressPsi(Psi,textSize,myicsa->T_Psi,nsHUFF);
- #endif
- #ifdef PSI_GONZALO
+ #endif
+ #ifdef PSI_GONZALO
myicsa->gcPsi = gonzaloCompressPsi(Psi,textSize,myicsa->T_Psi,nsHUFF);
- #endif
+ #endif
#ifdef PSI_DELTACODES
- myicsa->dcPsi = deltaCompressPsi(Psi,textSize,myicsa->T_Psi);
+ myicsa->dcPsi = deltaCompressPsi(Psi,textSize,myicsa->T_Psi);
#endif
- free(Psi);
-
+
+ free(Psi);
+
// Contruimos D
- for(i=0;i<((textSize+31)/32);i++) myicsa->D[i] = 0;
+ for(i=0;i<((textSize+31)/32);i++) myicsa->D[i] = 0;
for(i=0;i<=vocSize;i++) bitset(myicsa->D, C[i]);
myicsa->bD = createBitmap(myicsa->D,textSize);
free(C);
// coa que podemos obter o símbolo pedido, e actualizamos displayState
myicsa->displayCSAState = 0;
myicsa->displayCSAPrevPosition = -2; //needed by DisplayCSA(position)
-
- aintVector = intVector;
- // Liberamos o espacion non necesario
+
+ //aintVector = intVector;
+ // Liberamos o espacio non necesario
*index = myicsa;
//return (myicsa);
int saveIntIndex(void *index, char *pathname) {
//void storeStructsCSA(ticsa *myicsa, char *basename) {
-
- ticsa *myicsa = (ticsa *) index;
+
+ ticsa *myicsa = (ticsa *) index;
char *basename=pathname;
char *filename;
int file;
-
+
// Reservamos espacio para o nome do ficheiro
filename = (char *)malloc(sizeof(char)*MAX_FILENAME_LENGTH);
-
+
// Ficheiro co n�mero de elementos indexados (enteiros do texto orixinal)
strcpy(filename, basename);
strcat(filename, ".");
exit(0);
}
write(file, &(myicsa->suffixArraySize), sizeof(int));
- close(file);
+ close(file);
strcpy(filename, basename);
strcat(filename, ".");
- strcat(filename, PSI_COMPRESSED_FILE_EXT);
+ strcat(filename, PSI_COMPRESSED_FILE_EXT);
#ifdef PSI_HUFFMANRLE
- storeHuffmanCompressedPsi(&(myicsa->hcPsi), filename);
- #endif
+ storeHuffmanCompressedPsi(&(myicsa->hcPsi), filename);
+ #endif
#ifdef PSI_GONZALO
- storeGonzaloCompressedPsi(&(myicsa->gcPsi), filename);
+ storeGonzaloCompressedPsi(&(myicsa->gcPsi), filename);
#endif
#ifdef PSI_DELTACODES
storeDeltaCompressedPsi(&(myicsa->dcPsi), filename);
#endif
-
+
// Ficheiro co vector de bits D
strcpy(filename, basename);
strcat(filename, ".");
- strcat(filename, D_FILE_EXT);
+ strcat(filename, D_FILE_EXT);
unlink(filename);
if( (file = open(filename, O_WRONLY|O_CREAT,S_IRWXG | S_IRWXU)) < 0) {
printf("Cannot open file %s\n", filename);
strcat(filename, ".");
strcat(filename, D_RANK_DIRECTORY_FILE_EXT);
saveBitmap(filename,myicsa->bD);
-
+
// Ficheiro coas mostras de A
strcpy(filename, basename);
strcat(filename, ".");
- strcat(filename, SAMPLES_A_FILE_EXT);
+ strcat(filename, SAMPLES_A_FILE_EXT);
unlink(filename);
if( (file = open(filename, O_WRONLY|O_CREAT,S_IRWXG | S_IRWXU)) < 0) {
printf("Cannot open file %s\n", filename);
// Ficheiro co vector BA (marca as posicions de A muestreadas)
strcpy(filename, basename);
strcat(filename, ".");
- strcat(filename, BA_FILE_EXT);
+ strcat(filename, BA_FILE_EXT);
unlink(filename);
if( (file = open(filename, O_WRONLY|O_CREAT,S_IRWXG | S_IRWXU)) < 0) {
printf("Cannot open file %s\n", filename);
strcat(filename, ".");
strcat(filename, BA_RANK_DIRECTORY_FILE_EXT);
saveBitmap(filename, myicsa->bBA);
-
+
// Ficheiro coas mostras de A inversa
strcpy(filename, basename);
strcat(filename, ".");
exit(0);
}
write(file, myicsa->samplesAInv, sizeof(int) * (myicsa->samplesAInvSize));
- close(file);
+ close(file);
// Ficheiro co periodo de muestreo de A e A inversa
strcpy(filename, basename);
}
write(file, &(myicsa->T_A), sizeof(int));
write(file, &(myicsa->T_AInv), sizeof(int));
-
+
write(file, &(myicsa->psiSearchFactorJump), sizeof(uint));
close(file);
- free(filename);
+ free(filename);
return 0; //no error.
}
size += sizeof(uint)*((myicsa->suffixArraySize+31)/32) ; //BA vector
size += myicsa->bBA->mem_usage;
#ifdef PSI_HUFFMANRLE
- size +=myicsa->hcPsi.totalMem;
- #endif
+ size +=myicsa->hcPsi.totalMem;
+ #endif
#ifdef PSI_GONZALO
- size +=myicsa->gcPsi.totalMem;
+ size +=myicsa->gcPsi.totalMem;
#endif
#ifdef PSI_DELTACODES
size +=myicsa->dcPsi.totalMem;
- #endif
+ #endif
*numBytes = size;
return 0; //no error.
}
uint length;
char c;
char *word;
- struct stat f_stat;
+ struct stat f_stat;
uint suffixArraySize;
ticsa *myicsa;
myicsa = (ticsa *) malloc (sizeof (ticsa) * 1);
-
-
+
+
// VARIABLE GLOBAL QUE ALMACENA O ESTADO DOS DISPLAYS (IMPORTANTE PARA DISPLAY SECUENCIAL)
// Almacena a �ltima posici�n do array de sufixos que mostramos con display ou displayNext
// Se nos piden un displayNext, aplicamos PSI sobre esta posici�n e obtemos a seguinte,
// coa que podemos obter o s�mbolo pedido, e actualizamos displayState
myicsa->displayCSAState = 0;
myicsa->displayCSAPrevPosition = -2; //needed by DisplayCSA(position)
-
+
// Reservamos espacio para o nome do ficheiro
filename = (char *)malloc(sizeof(char)*MAX_FILENAME_LENGTH);
strcpy(filename, basename);
strcat(filename, ".");
strcat(filename, NUMBER_OF_ELEMENTS_FILE_EXT);
- if( (file = open(filename, O_RDONLY)) < 0) {
+ if( (file = open(filename, O_RDONLY)) < 0) {
printf("Cannot read file %s\n", filename);exit(0);
- }
- read(file, &suffixArraySize, sizeof(uint));
+ }
+ read(file, &suffixArraySize, sizeof(uint));
myicsa->suffixArraySize = suffixArraySize;
printf("Number of indexed elements (suffix array size) = %d\n", suffixArraySize);
-
- // LEEMOS OS DATOS DO FICHEIRO QUE ALMACENA PSI COMPRIMIDA
+
+ // LEEMOS OS DATOS DO FICHEIRO QUE ALMACENA PSI COMPRIMIDA
strcpy(filename, basename);
strcat(filename, ".");
- strcat(filename, PSI_COMPRESSED_FILE_EXT);
+ strcat(filename, PSI_COMPRESSED_FILE_EXT);
#ifdef PSI_HUFFMANRLE
- myicsa->hcPsi = loadHuffmanCompressedPsi(filename);
- #endif
+ myicsa->hcPsi = loadHuffmanCompressedPsi(filename);
+ #endif
#ifdef PSI_GONZALO
- myicsa->gcPsi = loadGonzaloCompressedPsi(filename);
+ myicsa->gcPsi = loadGonzaloCompressedPsi(filename);
#endif
#ifdef PSI_DELTACODES
myicsa->dcPsi = loadDeltaCompressedPsi(filename);
- #endif
-
+ #endif
+
// LEEMOS OS DATOS DO FICHEIRO QUE ALMACENA D
strcpy(filename, basename);
strcat(filename, ".");
strcat(filename, D_FILE_EXT);
if( (file = open(filename, O_RDONLY)) < 0) {
printf("Cannot read file %s\n", filename); exit(0);
- }
+ }
myicsa->D = (uint *) malloc (sizeof(uint)*((suffixArraySize+31)/32));
read(file, myicsa->D, sizeof(uint)*((suffixArraySize+31)/32));
printf("Bit vector D loaded (%d bits)\n", suffixArraySize);
// LEEMOS OS DATOS DO FICHEIRO QUE ALMACENA O DIRECTORIO DE RANK1 PARA D
strcpy(filename, basename);
strcat(filename, ".");
- strcat(filename, D_RANK_DIRECTORY_FILE_EXT);
+ strcat(filename, D_RANK_DIRECTORY_FILE_EXT);
myicsa->bD = loadBitmap(filename,myicsa->D,suffixArraySize);
- { uint ns, nb;
+ { uint ns, nb;
ns = myicsa->bD->sSize;
nb = myicsa->bD->bSize;
myicsa->bD->data = myicsa->D;
- printf("Rank1 Directory for D loaded (%d superblocks, %d blocks)\n", ns, nb);
+ printf("Rank1 Directory for D loaded (%d superblocks, %d blocks)\n", ns, nb);
}
-
+
// LEEMOS OS DATOS DO FICHEIRO QUE ALMACENA SAMPLES A
strcpy(filename, basename);
strcat(filename, ".");
}
if( fstat(file, &f_stat) < 0) {
printf("Cannot read information from file %s\n", filename); exit(0);
- }
+ }
myicsa->samplesASize = (f_stat.st_size)/sizeof(uint);
myicsa->samplesA = (uint *)malloc(sizeof(uint) * myicsa->samplesASize);
- read(file, myicsa->samplesA, sizeof(uint) * myicsa->samplesASize);
- printf("Suffix array samples loaded (%d samples)\n", myicsa->samplesASize);
-
+ read(file, myicsa->samplesA, sizeof(uint) * myicsa->samplesASize);
+ printf("Suffix array samples loaded (%d samples)\n", myicsa->samplesASize);
+
// LEEMOS OS DATOS DO FICHEIRO QUE ALMACENA BA
strcpy(filename, basename);
strcat(filename, ".");
strcat(filename, BA_FILE_EXT);
if( (file = open(filename, O_RDONLY)) < 0) {
printf("Cannot read file %s\n", filename); exit(0);
- }
+ }
myicsa->BA = (uint *) malloc (sizeof(uint)*((suffixArraySize+31)/32));
read(file, myicsa->BA, sizeof(uint)*((suffixArraySize+31)/32));
printf("Bit vector BA loaded (%d bits)\n", suffixArraySize);
// LEEMOS OS DATOS DO FICHEIRO QUE ALMACENA O DIRECTORIO DE RANK1 PARA BA
strcpy(filename, basename);
strcat(filename, ".");
- strcat(filename, BA_RANK_DIRECTORY_FILE_EXT);
+ strcat(filename, BA_RANK_DIRECTORY_FILE_EXT);
myicsa->bBA = loadBitmap(filename,myicsa->BA,suffixArraySize);
- { uint ns, nb;
+ { uint ns, nb;
ns = myicsa->bBA->sSize;
nb = myicsa->bBA->bSize;
myicsa->bBA->data = myicsa->BA;
- printf("Rank1 Directory for BA loaded (%d superblocks, %d blocks)\n", ns, nb);
+ printf("Rank1 Directory for BA loaded (%d superblocks, %d blocks)\n", ns, nb);
}
// LEEMOS OS DATOS DO FICHEIRO QUE ALMACENA SAMPLES A INVERSA
}
if( fstat(file, &f_stat) < 0) {
printf("Cannot read information from file %s\n", filename); exit(0);
- }
+ }
myicsa->samplesAInvSize = (f_stat.st_size)/(sizeof(uint));
myicsa->samplesAInv = (uint *)malloc(sizeof(uint) * myicsa->samplesAInvSize);
- read(file, myicsa->samplesAInv, sizeof(uint) * myicsa->samplesAInvSize);
+ read(file, myicsa->samplesAInv, sizeof(uint) * myicsa->samplesAInvSize);
printf("Suffix array inverse samples loaded (%d samples)\n", myicsa->samplesAInvSize);
-
+
// LEEMOS OS DATOS DO FICHEIRO QUE ALMACENA O PERIODO DE MUESTREO DO ARRAY DE SUFIXOS E DA INVERSA
strcpy(filename, basename);
strcat(filename, ".");
strcat(filename, SAMPLING_PERIOD_A_FILE_EXT);
if( (file = open(filename, O_RDONLY)) < 0) {
printf("Cannot read file %s\n", filename); exit(0);
- }
+ }
read(file, &(myicsa->T_A), sizeof(uint));
- read(file, &(myicsa->T_AInv), sizeof(uint));
- printf("Sampling A Period T = %d, Sampling A inv Period TInv = %d\n", myicsa->T_A, myicsa->T_AInv);
-
+ read(file, &(myicsa->T_AInv), sizeof(uint));
+ printf("Sampling A Period T = %d, Sampling A inv Period TInv = %d\n", myicsa->T_A, myicsa->T_AInv);
+
read(file, &(myicsa->psiSearchFactorJump), sizeof(uint));
- printf("Psi Bin Search Factor-Jump is = %d\n", myicsa->psiSearchFactorJump);
-
+ printf("Psi Bin Search Factor-Jump is = %d\n", myicsa->psiSearchFactorJump);
+
close(file);
free(filename);
*index = myicsa;
return 0;
}
-
-//uint destroyStructsCSA(ticsa *myicsa) {
-int freeIntIndex(void *index) {
+
+//uint destroyStructsCSA(ticsa *myicsa) {
+int freeIntIndex(void *index) {
ticsa *myicsa = (ticsa *) index;
// Liberamos o espacio reservado
-
+
if (!myicsa) return 0;
-
- uint total=0, totaltmp=0;
-
+
+ size_t total=0, totaltmp=0;
+
uint nbytes;sizeIntIndex(index, &nbytes);
-
+
total +=(sizeof (ticsa) * 1);;
-
+
#ifdef PSI_HUFFMANRLE
total+= totaltmp = myicsa->hcPsi.totalMem;
destroyHuffmanCompressedPsi(&(myicsa->hcPsi));
#endif
#ifdef PSI_DELTACODES
total+= totaltmp = myicsa->dcPsi.totalMem;
- destroyDeltaCodesCompressedPsi(&(myicsa->dcPsi));
+ destroyDeltaCodesCompressedPsi(&(myicsa->dcPsi));
#endif
- printf("\n\t[destroying SA: compressed PSI structure] ...Freed %u bytes... RAM",totaltmp);
-
- free(myicsa->D); total+= totaltmp = (sizeof(uint)*((myicsa->suffixArraySize+31)/32));
- printf("\n\t[destroying SA: D vector] ...Freed %u bytes... RAM",totaltmp);
- free(myicsa->samplesA); total+= totaltmp = (sizeof(uint) * myicsa->samplesASize);
- printf("\n\t[destroying Samples A: A ] ...Freed %u bytes... RAM",totaltmp);
- free(myicsa->samplesAInv); total+= totaltmp = (sizeof(uint) * myicsa->samplesAInvSize);
- printf("\n\t[destroying Samples AInv: A ] ...Freed %u bytes... RAM",totaltmp);
- printf("\n\t[destroying rank bit D ] ...Freed %u bytes... RAM",myicsa->bD->mem_usage);
- free(myicsa->BA); total+= totaltmp = (sizeof(uint)*((myicsa->suffixArraySize+31)/32));
- printf("\n\t[destroying SA: BA vector] ...Freed %u bytes... RAM",totaltmp);
-
+ printf("\n\t[destroying SA: compressed PSI structure] ...Freed %zu bytes... RAM", totaltmp);
+
+ free(myicsa->D); total+= totaltmp = (sizeof(uint)*((myicsa->suffixArraySize+31)/32));
+ printf("\n\t[destroying SA: D vector] ...Freed %zu bytes... RAM",totaltmp);
+ free(myicsa->samplesA); total+= totaltmp = (sizeof(uint) * myicsa->samplesASize);
+ printf("\n\t[destroying Samples A: A ] ...Freed %zu bytes... RAM",totaltmp);
+ free(myicsa->samplesAInv); total+= totaltmp = (sizeof(uint) * myicsa->samplesAInvSize);
+ printf("\n\t[destroying Samples AInv: A ] ...Freed %zubytes... RAM",totaltmp);
+ printf("\n\t[destroying rank bit D ] ...Freed %zu bytes... RAM", (size_t)myicsa->bD->mem_usage);
+ free(myicsa->BA); total+= totaltmp = (sizeof(uint)*((myicsa->suffixArraySize+31)/32));
+ printf("\n\t[destroying SA: BA vector] ...Freed %zu bytes... RAM",totaltmp);
+
total += myicsa->bD->mem_usage;
- destroyBitmap(myicsa->bD);
+ destroyBitmap(myicsa->bD);
total += myicsa->bBA->mem_usage;
destroyBitmap(myicsa->bBA);
-
- printf("\n\t**** [the whole iCSA ocuppied ... %u bytes... RAM",total);
- printf("\n\t**** iCSA size = %d bytes ",nbytes);
+
+ printf("\n\t**** [the whole iCSA ocuppied ... %zu bytes... RAM",total);
+ printf("\n\t**** iCSA size = %zu bytes ", (size_t) nbytes);
printf("\n");
-
+
free(myicsa);
-
+
return 0; //no error.
}
int printInfoIntIndex(void *index, const char tab[]) {
ticsa *myicsa = (ticsa *) index;
if (!myicsa) return 0;
-
+
uint structure, totalpsi, totalD, totalBD, totalSA,totalSAinv, totalBA,totalBBA;
-
+
structure=sizeof(ticsa);
-
+
#ifdef PSI_HUFFMANRLE
totalpsi = myicsa->hcPsi.totalMem;
#endif
totalD = (sizeof(uint)*((myicsa->suffixArraySize+31)/32));
totalBD = myicsa->bD->mem_usage;
- totalSA = (sizeof(uint) * myicsa->samplesASize);
- totalSAinv = (sizeof(uint) * myicsa->samplesAInvSize);
+ totalSA = (sizeof(uint) * myicsa->samplesASize);
+ totalSAinv = (sizeof(uint) * myicsa->samplesAInvSize);
totalBA = (sizeof(uint)*((myicsa->suffixArraySize+31)/32));
totalBBA = myicsa->bBA->mem_usage;
-
+
uint nbytes; sizeIntIndex(index, &nbytes); //whole self-index
-
- printf("\n ===================================================:");
- printf("\n%sSummary Self-index on integers (icsa) layer:",tab);
+
+ printf("\n ===================================================:");
+ printf("\n%sSummary Self-index on integers (icsa) layer:",tab);
printf("\n%s icsa structure = %d bytes",tab, structure);
printf("\n%s psi = %8d bytes",tab, totalpsi);
printf("\n%s D (bitmap) = %8d bytes",tab, totalD);
printf("\n%s rank for BA = %8d bytes",tab, totalBBA);
printf("\n%sTotal = ** %9d bytes (in RAM) ** ",tab, nbytes);
printf("\n");
-
+
return 0; //no error.
}
// b) O pivote é unha ocorrencia do patrón -> Faise unha busca exponencial sobre mostras hacia a esquerda e outra hacia a dereita, ata atopar a unha mostra á esquerda e outra
// á dereita do intervalo de ocorrencias. Entre cada unha destas e a inmediatamente anterior da busca exponencial, faise unha busca binaria para atopar os extremos do intervalo.
-int countIntIndex(void *index, uint *pattern, uint length, ulong *numocc, ulong *left, ulong *right){
+int countIntIndex(void *index, uint *pattern, uint length, ulong *numocc, ulong *left, ulong *right){
//unsigned int countCSA(ticsa *myicsa, uint *pattern, uint patternSize, uint *left, uint *right) {
uint patternSize = length;
ticsa *myicsa = (ticsa *) index;
-
+
register unsigned long l, r, i;
register long comp, p, previousP;
//register unsigned int l, r, i;
//register int comp, p, previousP;
register uint bin_search_psi_skip_interval = myicsa->psiSearchFactorJump;
-
+
//fprintf(stderr,"\n psiSearchFactor = %d",myicsa->psiSearchFactorJump);
-
- l = 0;
+
+ l = 0;
r = (myicsa->suffixArraySize+bin_search_psi_skip_interval-2)/bin_search_psi_skip_interval*bin_search_psi_skip_interval;
p = ((l+r)/2)/bin_search_psi_skip_interval * bin_search_psi_skip_interval;
previousP = 0;
-
+
// BUSCA BINARIA SOBRE MOSTRAS
while( (p != previousP) && (comp = SadCSACompare(myicsa, pattern, patternSize, p)) ) {
if(comp > 0) l = p;
}
if(p==previousP) {
-
+
// BUSCA BINARIA ENTRE O PIVOTE E A SEGUINTE MOSTRA
- l = previousP;
+ l = previousP;
r = previousP+bin_search_psi_skip_interval;
if(r > myicsa->suffixArraySize) r = myicsa->suffixArraySize - 1;
while(l < r) {
- p = (l+r)/2;
+ p = (l+r)/2;
if(SadCSACompare(myicsa, pattern, patternSize, p) <= 0) r = p;
else l = p+1;
}
return 0; //no error.
}
*left = r;
-
- l = previousP;
+
+ l = previousP;
r = previousP+bin_search_psi_skip_interval;
if(r > myicsa->suffixArraySize) r = myicsa->suffixArraySize - 1;
while(l < r) {
p = (l+r+1)/2;
if(SadCSACompare(myicsa, pattern, patternSize, p) >= 0) l = p;
- else r = p-1;
+ else r = p-1;
}
*right = l;
-
+
} else {
-
+
previousP = p; // En previousP poñemos o p atopado na busca sobre as mostras
-
+
// BUSCA EXPONENCIAL HACIA ATRÁS
i = 1;
p -= bin_search_psi_skip_interval;
// Busca binaria entre as duas ultimas mostras da exponencial
if(previousP > i*bin_search_psi_skip_interval) l = previousP-(i*bin_search_psi_skip_interval);
else l=0;
- i>>=1;
+ i>>=1;
r = previousP-(i*bin_search_psi_skip_interval);
while(l < r) {
- p = (l+r)/2;
+ p = (l+r)/2;
if(SadCSACompare(myicsa, pattern, patternSize, p) <= 0) r = p;
else l = p+1;
}
*left = r;
-
+
// BUSCA EXPONENCIAL HACIA ADIANTE
i = 1;
p = previousP+bin_search_psi_skip_interval;
while(p<myicsa->suffixArraySize && !SadCSACompare(myicsa, pattern, patternSize, p)) {
i<<=1;
- p = previousP+(i*bin_search_psi_skip_interval);
+ p = previousP+(i*bin_search_psi_skip_interval);
}
// Busca binaria entre as duas ultimas mostras da exponencial
if(p < myicsa->suffixArraySize) r = previousP+(i*bin_search_psi_skip_interval);
else r = myicsa->suffixArraySize-1;
- i>>=1;
+ i>>=1;
l = previousP+(i*bin_search_psi_skip_interval);
while(l < r) {
p = (l+r+1)/2;
if(SadCSACompare(myicsa, pattern, patternSize, p) >= 0) l = p;
- else r = p-1;
+ else r = p-1;
}
- *right = l;
+ *right = l;
}
//return *right-*left+1;
*numocc = (uint) *right-*left+1;
- return 0; //no error
+ return 0; //no error
}
// Version inicial de busca binaria
unsigned int countCSABin(ticsa *myicsa, uint *pattern, uint patternSize, uint *left, uint *right) {
register ulong l, r, p;
- l = 0;
+ l = 0;
r = myicsa->suffixArraySize-1;
while(l < r) {
- p = (l+r)/2;
+ p = (l+r)/2;
if(SadCSACompare(myicsa, pattern, patternSize, p) <= 0) r = p;
else l = p+1;
}
*right = r;
return 0;
}
-
+
// Almacenamos o limite esquerdo
*left = r;
// SE SON IGUALES (O PATRON APARECE NO TEXTO), BUSCAMOS AGORA O LIMITE DEREITO, QUE ALMACENAREMOS EN right
// NOTA: INICIAMOS A BUSQUEDA A PARTIR DO ESQUERDO...
- l = r;
+ l = r;
r = myicsa->suffixArraySize-1;
-
+
while(l < r) {
p = (l+r+1)/2;
if(SadCSACompare(myicsa, pattern, patternSize, p) >= 0) l = p;
- else r = p-1;
+ else r = p-1;
}
-
+
// Gardamos o limite dereito
*right = l;
-
- return (uint) *right-*left+1;
+
+ return (uint) *right-*left+1;
}
int locateIntIndex(void *index, uint *pattern, uint length, ulong **occ, ulong *numocc) {
//unsigned int *locateCSA(ticsa *myicsa, uint *pattern, uint patternSize, uint *occ) {
-
+
ticsa *myicsa = (ticsa *) index;
uint patternSize = length;
ulong *positions;
ulong occurrences;
register ulong left, right;
-
+
//occurrences = countCSA(myicsa, pattern, patternSize, &left, &right);
int err;
err = countIntIndex((void *) myicsa, pattern, patternSize, &occurrences, &left, &right);
if (occurrences) {
register ulong idx = 0;
positions = (ulong*) malloc(sizeof(ulong) * occurrences);
- while(left<=right) positions[idx++] = A(myicsa,left++);
-
+ while(left<=right) positions[idx++] = A(myicsa,left++);
+
*occ = positions;
- return 0;
+ return 0;
//return positions;
}
-
+
(*occ)=NULL;
return 0; //no error, but no occurrences.
-
+
//return NULL;
}
/**********************************************************************/
-// Devolve o enteiro do texto que ocupa a posicion dada, e fixa o estado
+// Devolve o enteiro do texto que ocupa a posicion dada, e fixa o estado
// para poder seguir obtendo os seguintes enteiros con displayNext();
uint displayCSAFirst(ticsa *myicsa, uint position) {
register uint positionAux, index;
register uint T_AInv = myicsa->T_AInv;
-
+
positionAux = myicsa->samplesAInv[position / T_AInv];
for(index = 0; index < position%T_AInv; index++) {
#ifdef PSI_HUFFMANRLE
positionAux=getHuffmanPsiValue(&(myicsa->hcPsi),positionAux);
- #endif
+ #endif
#ifdef PSI_GONZALO
positionAux=getGonzaloPsiValue(&(myicsa->gcPsi),positionAux);
#endif
#ifdef PSI_DELTACODES
positionAux=getDeltaPsiValue(&(myicsa->dcPsi),positionAux);
- #endif
+ #endif
}
-
+
// Fijamos a variable global para a chamada a displayNext
myicsa->displayCSAState = positionAux;
-
+
// return rank1(D, Dir, positionAux) - 1;
return rank(myicsa->bD, positionAux) - 1;
}
// Devolve o seguinte enteiro do texto (a partir do estado)
-unsigned int displayCSANext(ticsa *myicsa) {
+unsigned int displayCSANext(ticsa *myicsa) {
#ifdef PSI_HUFFMANRLE
myicsa->displayCSAState=getHuffmanPsiValue(&(myicsa->hcPsi),myicsa->displayCSAState);
- #endif
+ #endif
#ifdef PSI_GONZALO
myicsa->displayCSAState = getGonzaloPsiValue(&(myicsa->gcPsi),myicsa->displayCSAState);
#endif
#ifdef PSI_DELTACODES
myicsa->displayCSAState = getDeltaPsiValue(&(myicsa->dcPsi),myicsa->displayCSAState);
- #endif
- return rank(myicsa->bD, myicsa->displayCSAState) - 1;
+ #endif
+ return rank(myicsa->bD, myicsa->displayCSAState) - 1;
}
// ESTRUCTURAS PARA CSA
printf("Basic CSA structures:\n\n");
-
+
// VALORES DA FUNCI�N PSI (decodificando)
printf("\tPSI: (Sampling period = %d)\n", myicsa->T_Psi);
- for(index=0; index < myicsa->suffixArraySize; index++)
+ for(index=0; index < myicsa->suffixArraySize; index++)
#ifdef PSI_HUFFMANRLE
printf("\tPsi[%d] = %d\n", index, getHuffmanPsiValue(&(myicsa->hcPsi),index));
#endif
printf("\tPsi[%d] = %d\n", index, getGonzaloPsiValue(&(myicsa->gcPsi),index));
#endif
#ifdef PSI_DELTACODES
- printf("\tPsi[%d] = %d\n", index, getDeltaPsiValue(&(myicsa->dcPsi),index));
- #endif
+ printf("\tPsi[%d] = %d\n", index, getDeltaPsiValue(&(myicsa->dcPsi),index));
+ #endif
printf("\n");
-
+
// VECTOR D DE SADAKANE CO DIRECTORIO DE RANK ASOCIADO
printf("\tD = ");
showBitVector(myicsa->D, myicsa->suffixArraySize);
printf("\tDs[%d] = %d\n", index, myicsa->bD->sdata[index]);
}
printf("\nBloques de D:\n");
-
+
for(index=0; index<nb; index++) {
//printf("\tDb[%d] = %d\n", index, Dir.Db[index]);
- printf("\tDb[%d] = %d\n", index, myicsa->bD->bdata[index]);
- }
+ printf("\tDb[%d] = %d\n", index, myicsa->bD->bdata[index]);
+ }
printf("\n\n");
}
// ESTRUCTURAS PARA ACCEDER O ARRAY DE SUFIXOS E A SUA INVERSA
printf("Suffix Array Sampling Structures: (Sampling period = %d)\n", myicsa->T_A);
printf("\tSuffix Array Samples:\n");
- for(index=0; index < myicsa->samplesASize; index++)
+ for(index=0; index < myicsa->samplesASize; index++)
printf("\tSamplesA[%d] = %d\n", index, myicsa->samplesA[index]);
- printf("\n");
+ printf("\n");
printf("\tInverse Suffix Array Samples:\n");
- for(index=0; index < myicsa->samplesASize; index++)
+ for(index=0; index < myicsa->samplesASize; index++)
printf("\tSamplesAInv[%d] = %d\n", index, myicsa->samplesAInv[index]);
printf("\n");
-
+
}
int SadCSACompare(ticsa *myicsa, uint *pattern, uint patternSize, uint p) {
register unsigned int j, i, currentInteger, diff;
-
+
i = p;
j = 0;
-
+
while(1) {
currentInteger = rank(myicsa->bD, i) - 1;
diff = pattern[j++] - currentInteger;
if(diff) return diff;
if(j == patternSize) return 0;
- else
+ else
#ifdef PSI_HUFFMANRLE
i=getHuffmanPsiValue(&(myicsa->hcPsi),i);
#endif
#ifdef PSI_GONZALO
i=getGonzaloPsiValue(&(myicsa->gcPsi),i);
- #endif
+ #endif
#ifdef PSI_DELTACODES
i=getDeltaPsiValue(&(myicsa->dcPsi),i);
#endif
}
-
+
}
register uint timesPsi, sampleValue;
register uint T_A = myicsa->T_A;
-
+
uint proba = position;
-
+
timesPsi = 0;
while(!bitget(myicsa->BA, position)) {
-
+
#ifdef PSI_HUFFMANRLE
position=getHuffmanPsiValue(&(myicsa->hcPsi),position);
- #endif
+ #endif
#ifdef PSI_GONZALO
position=getGonzaloPsiValue(&(myicsa->gcPsi),position);
#endif
position=getDeltaPsiValue(&(myicsa->dcPsi),position);
#endif
timesPsi++;
-
+
}
sampleValue = myicsa->samplesA[rank(myicsa->bBA, position)-1];
-
+
return sampleValue - timesPsi;
}
register uint index, inverseValue;
register uint T_AInv = myicsa->T_AInv;
-
+
inverseValue = myicsa->samplesAInv[offset/T_AInv];
- for(index=0; index<(offset%T_AInv); index++)
+ for(index=0; index<(offset%T_AInv); index++)
#ifdef PSI_HUFFMANRLE
inverseValue=getHuffmanPsiValue(&(myicsa->hcPsi),inverseValue);
- #endif
+ #endif
#ifdef PSI_GONZALO
inverseValue = getGonzaloPsiValue(&(myicsa->gcPsi),inverseValue);
- #endif
+ #endif
#ifdef PSI_DELTACODES
inverseValue = getDeltaPsiValue(&(myicsa->dcPsi),inverseValue);
#endif
return inverseValue;
-
+
}
// Initializes the parameters of the index.
-uint parametersCSA(ticsa *myicsa, char *build_options){
+uint parametersCSA(ticsa *myicsa, char *build_options){
char delimiters[] = " =;";
int j,num_parameters;
char ** parameters;
int ssA,ssAinv,ssPsi,nsHuff,psiSearchFactor;
-
+
ssA = DEFAULT_A_SAMPLING_PERIOD;
ssAinv = DEFAULT_A_INV_SAMPLING_PERIOD;
ssPsi = DEFAULT_PSI_SAMPLING_PERIOD;
nsHuff = DEFAULT_nsHUFF;
psiSearchFactor = DEFAULT_PSI_BINARY_SEARCH_FACTOR;
-
+
if (build_options != NULL) {
parse_parameters(build_options,&num_parameters, ¶meters, delimiters);
for (j=0; j<num_parameters;j++) {
-
+
if ((strcmp(parameters[j], "sA") == 0 ) && (j < num_parameters-1) ) {
- ssA=atoi(parameters[j+1]);
- }
+ ssA=atoi(parameters[j+1]);
+ }
if ((strcmp(parameters[j], "sAinv") == 0 ) && (j < num_parameters-1) ) {
- ssAinv=atoi(parameters[j+1]);
- }
+ ssAinv=atoi(parameters[j+1]);
+ }
if ((strcmp(parameters[j], "sPsi") == 0 ) && (j < num_parameters-1) ) {
- ssPsi=atoi(parameters[j+1]);
- }
+ ssPsi=atoi(parameters[j+1]);
+ }
if ((strcmp(parameters[j], "nsHuff") == 0 ) && (j < num_parameters-1) ) {
nsHuff=atoi(parameters[j+1]);
- nsHuff *=1024;
- }
+ nsHuff *=1024;
+ }
if ((strcmp(parameters[j], "psiSF") == 0 ) && (j < num_parameters-1) ) {
psiSearchFactor=atoi(parameters[j+1]);
- }
+ }
j++;
}
free_parameters(num_parameters, ¶meters);
- }
+ }
myicsa->T_A = ssA;
myicsa->T_AInv = ssAinv;
myicsa->T_Psi = ssPsi;
myicsa->tempNSHUFF = nsHuff;
- myicsa->psiSearchFactorJump = psiSearchFactor * ssPsi;
+ myicsa->psiSearchFactorJump = psiSearchFactor * ssPsi;
printf("\n\t parameters for iCSA: sampleA=%d, sampleAinv=%d, samplePsi=%d",ssA,ssAinv,ssPsi);
printf("\n\t : nsHuff=%d, psiSearchFactor = %d --> jump = %d", nsHuff,psiSearchFactor, myicsa->psiSearchFactorJump);