* Guardo el k en el array de salida del BS para que el MTF lo tenga en cuenta.

[z.facultad/75.06/jacu.git] / src / blocksorting / bs.c

#include "bs.h"
#include <stdlib.h>

/* Block Sorting Optimizado en memoria! */

typedef struct _bs_decode_t_ {
        char c;
        unsigned long int pos;
} t_BlockSortDecode;

char es_menor(char *data, t_BlockSort *bs, int i, int j);

int _compare(const void *d1, const void *d2) {
        t_BlockSortDecode *s1, *s2;

        s1 = (t_BlockSortDecode *)d1;
        s2 = (t_BlockSortDecode *)d2;

        return (s1->c - s2->c);
}

int __compare(const void *d1, const void *d2) {
        t_BlockSortData *s1, *s2;

        s1 = (t_BlockSortData *)d1;
        s2 = (t_BlockSortData *)d2;

        return es_menor(s1->bs->data, s1->bs, s1->pos_inicial, s2->pos_inicial);
}

char es_menor(char *data, t_BlockSort *bs, int i, int j)
{
        unsigned long int pi, pj, k;

        for(k=0; k<bs->len; k++) {
                pi = (i+k)%bs->len;
                pj = (j+k)%bs->len;

                if (data[pi] > data[pj]) return 1; /* El primero es mayor */
                if (data[pi] < data[pj]) return -1; /* El primero es menor */
        }

        /* Son iguales! */
        return 0;
}

void generar_array(char *data, t_BlockSort *bs)
{
        int i;
        for(i=0; i<bs->len; i++) {
                bs->array[i].pos_inicial = i;
                bs->array[i].pos_final = (i+bs->len-1)%bs->len;
                bs->array[i].ord = (i==0)?1:0;
                bs->array[i].bs = bs;
        }
}

void ordenar_array(char *data, t_BlockSort *bs)
{
        qsort(bs->array, bs->len, sizeof(t_BlockSortData), __compare);
}

void print_(char *data, unsigned long int pos, unsigned long int len)
{
        unsigned long int i;

        for(i=0; i<len; i++)
                printf("%c", data[(pos+i)%len]);
        printf("\n");
}

int generar_salida(char *data, t_BlockSort *bs, char *salida)
{
        unsigned long int i, k;
        k=-1;
        for(i=0; i<bs->len; i++) {
                /* print_(data, bs->array[i].pos_inicial, bs->len); */
                salida[i] = data[bs->array[i].pos_final];
                if (bs->array[i].ord == 1) k = i;
        }
        return k;
}

void bs_solve(char *in, char *out, t_BlockSort *bs, unsigned long int *k, unsigned int leido)
{
        unsigned int l;
        l = bs->len;
        /* Hack para pedasos menores a la pagina */
        if (leido < bs->len) bs->len = leido;
        bs->data = in;

        generar_array(in, bs);
        ordenar_array(in, bs);
        (*k) = generar_salida(in, bs, out);

        /* Guardo el k en el array */
        memcpy(out+leido, k, sizeof(unsigned long int));

        bs->len = l;
}

void bs_restore(char *dst, char *c, unsigned long int k, unsigned long int len)
{
        unsigned long int i, current;
        t_BlockSortDecode *in;

        in = malloc(sizeof(t_BlockSortDecode)*len);

        for(i=0; i<len; i++) {
                in[i].c = c[i];
                in[i].pos = i;
        }

        qsort(in, len, sizeof(t_BlockSortDecode), _compare);
        
        current = k;
        i=0;
        do {
                dst[i++] = in[current].c;
                current = in[current].pos;
        } while (current != k);
        free(in);
}

t_BlockSort *bs_create(unsigned long int len)
{
        t_BlockSort *tmp;

        tmp = malloc(sizeof(t_BlockSort));
        tmp->array = malloc(sizeof(t_BlockSortData)*len);
        tmp->len = len;

        return tmp;
}


void bs_destroy(t_BlockSort *bs)
{
        free(bs->array);
        free(bs);
}