postgresql/contrib/tsearch2/snowball/utilities.c


#include <stdio.h>
#include <stdlib.h>
#include <string.h>

#include "header.h"

#define unless(C) if(!(C))

#define CREATE_SIZE 1

extern symbol * create_s(void)
{   symbol * p = (symbol *) (HEAD + (char *) malloc(HEAD + (CREATE_SIZE + 1) * sizeof(symbol)));
    CAPACITY(p) = CREATE_SIZE;
    SET_SIZE(p, CREATE_SIZE);
    return p;
}

extern void lose_s(symbol * p) { free((char *) p - HEAD); }

extern int in_grouping(struct SN_env * z, unsigned char * s, int min, int max)
{   if (z->c >= z->l) return 0;
    {   int ch = z->p[z->c];
        if
        (ch > max || (ch -= min) < 0 ||
         (s[ch >> 3] & (0X1 << (ch & 0X7))) == 0) return 0;
    }
    z->c++; return 1;
}

extern int in_grouping_b(struct SN_env * z, unsigned char * s, int min, int max)
{   if (z->c <= z->lb) return 0;
    {   int ch = z->p[z->c - 1];
        if
        (ch > max || (ch -= min) < 0 ||
         (s[ch >> 3] & (0X1 << (ch & 0X7))) == 0) return 0;
    }
    z->c--; return 1;
}

extern int out_grouping(struct SN_env * z, unsigned char * s, int min, int max)
{   if (z->c >= z->l) return 0;
    {   int ch = z->p[z->c];
        unless
        (ch > max || (ch -= min) < 0 ||
         (s[ch >> 3] & (0X1 << (ch & 0X7))) == 0) return 0;
    }
    z->c++; return 1;
}

extern int out_grouping_b(struct SN_env * z, unsigned char * s, int min, int max)
{   if (z->c <= z->lb) return 0;
    {   int ch = z->p[z->c - 1];
        unless
        (ch > max || (ch -= min) < 0 ||
         (s[ch >> 3] & (0X1 << (ch & 0X7))) == 0) return 0;
    }
    z->c--; return 1;
}


extern int in_range(struct SN_env * z, int min, int max)
{   if (z->c >= z->l) return 0;
    {   int ch = z->p[z->c];
        if
        (ch > max || ch < min) return 0;
    }
    z->c++; return 1;
}

extern int in_range_b(struct SN_env * z, int min, int max)
{   if (z->c <= z->lb) return 0;
    {   int ch = z->p[z->c - 1];
        if
        (ch > max || ch < min) return 0;
    }
    z->c--; return 1;
}

extern int out_range(struct SN_env * z, int min, int max)
{   if (z->c >= z->l) return 0;
    {   int ch = z->p[z->c];
        unless
        (ch > max || ch < min) return 0;
    }
    z->c++; return 1;
}

extern int out_range_b(struct SN_env * z, int min, int max)
{   if (z->c <= z->lb) return 0;
    {   int ch = z->p[z->c - 1];
        unless
        (ch > max || ch < min) return 0;
    }
    z->c--; return 1;
}

extern int eq_s(struct SN_env * z, int s_size, symbol * s)
{   if (z->l - z->c < s_size ||
        memcmp(z->p + z->c, s, s_size * sizeof(symbol)) != 0) return 0;
    z->c += s_size; return 1;
}

extern int eq_s_b(struct SN_env * z, int s_size, symbol * s)
{   if (z->c - z->lb < s_size ||
        memcmp(z->p + z->c - s_size, s, s_size * sizeof(symbol)) != 0) return 0;
    z->c -= s_size; return 1;
}

extern int eq_v(struct SN_env * z, symbol * p)
{   return eq_s(z, SIZE(p), p);
}

extern int eq_v_b(struct SN_env * z, symbol * p)
{   return eq_s_b(z, SIZE(p), p);
}

extern int find_among(struct SN_env * z, struct among * v, int v_size)
{
    int i = 0;
    int j = v_size;

    int c = z->c; int l = z->l;
    symbol * q = z->p + c;

    struct among * w;

    int common_i = 0;
    int common_j = 0;

    int first_key_inspected = 0;

    while(1)
    {   int k = i + ((j - i) >> 1);
        int diff = 0;
        int common = common_i < common_j ? common_i : common_j; /* smaller */
        w = v + k;
        {   int i; for (i = common; i < w->s_size; i++)
            {   if (c + common == l) { diff = -1; break; }
                diff = q[common] - w->s[i];
                if (diff != 0) break;
                common++;
            }
        }
        if (diff < 0) { j = k; common_j = common; }
                 else { i = k; common_i = common; }
        if (j - i <= 1)
        {   if (i > 0) break; /* v->s has been inspected */
            if (j == i) break; /* only one item in v */

            /* - but now we need to go round once more to get
               v->s inspected. This looks messy, but is actually
               the optimal approach.  */

            if (first_key_inspected) break;
            first_key_inspected = 1;
        }
    }
    while(1)
    {   w = v + i;
        if (common_i >= w->s_size)
        {   z->c = c + w->s_size;
            if (w->function == 0) return w->result;
            {   int res = w->function(z);
                z->c = c + w->s_size;
                if (res) return w->result;
            }
        }
        i = w->substring_i;
        if (i < 0) return 0;
    }
}

/* find_among_b is for backwards processing. Same comments apply */

extern int find_among_b(struct SN_env * z, struct among * v, int v_size)
{
    int i = 0;
    int j = v_size;

    int c = z->c; int lb = z->lb;
    symbol * q = z->p + c - 1;

    struct among * w;

    int common_i = 0;
    int common_j = 0;

    int first_key_inspected = 0;

    while(1)
    {   int k = i + ((j - i) >> 1);
        int diff = 0;
        int common = common_i < common_j ? common_i : common_j;
        w = v + k;
        {   int i; for (i = w->s_size - 1 - common; i >= 0; i--)
            {   if (c - common == lb) { diff = -1; break; }
                diff = q[- common] - w->s[i];
                if (diff != 0) break;
                common++;
            }
        }
        if (diff < 0) { j = k; common_j = common; }
                 else { i = k; common_i = common; }
        if (j - i <= 1)
        {   if (i > 0) break;
            if (j == i) break;
            if (first_key_inspected) break;
            first_key_inspected = 1;
        }
    }
    while(1)
    {   w = v + i;
        if (common_i >= w->s_size)
        {   z->c = c - w->s_size;
            if (w->function == 0) return w->result;
            {   int res = w->function(z);
                z->c = c - w->s_size;
                if (res) return w->result;
            }
        }
        i = w->substring_i;
        if (i < 0) return 0;
    }
}


extern symbol * increase_size(symbol * p, int n)
{   int new_size = n + 20;
    symbol * q = (symbol *) (HEAD + (char *) malloc(HEAD + (new_size + 1) * sizeof(symbol)));
    CAPACITY(q) = new_size;
    memmove(q, p, CAPACITY(p) * sizeof(symbol)); lose_s(p); return q;
}

/* to replace symbols between c_bra and c_ket in z->p by the
   s_size symbols at s
*/

extern int replace_s(struct SN_env * z, int c_bra, int c_ket, int s_size, const symbol * s)
{   int adjustment = s_size - (c_ket - c_bra);
    int len = SIZE(z->p);
    if (adjustment != 0)
    {   if (adjustment + len > CAPACITY(z->p)) z->p = increase_size(z->p, adjustment + len);
        memmove(z->p + c_ket + adjustment, z->p + c_ket, (len - c_ket) * sizeof(symbol));
        SET_SIZE(z->p, adjustment + len);
        z->l += adjustment;
        if (z->c >= c_ket) z->c += adjustment; else
            if (z->c > c_bra) z->c = c_bra;
    }
    unless (s_size == 0) memmove(z->p + c_bra, s, s_size * sizeof(symbol));
    return adjustment;
}

static void slice_check(struct SN_env * z)
{
    if (!(0 <= z->bra &&
          z->bra <= z->ket &&
          z->ket <= z->l &&
          z->l <= SIZE(z->p)))   /* this line could be removed */
    {
        fprintf(stderr, "faulty slice operation:\n");
        debug(z, -1, 0);
        exit(1);
    }
}

extern void slice_from_s(struct SN_env * z, int s_size, symbol * s)
{   slice_check(z);
    replace_s(z, z->bra, z->ket, s_size, s);
}

extern void slice_from_v(struct SN_env * z, symbol * p)
{   slice_from_s(z, SIZE(p), p);
}

extern void slice_del(struct SN_env * z)
{   slice_from_s(z, 0, 0);
}

extern void insert_s(struct SN_env * z, int bra, int ket, int s_size, symbol * s)
{   int adjustment = replace_s(z, bra, ket, s_size, s);
    if (bra <= z->bra) z->bra += adjustment;
    if (bra <= z->ket) z->ket += adjustment;
}

extern void insert_v(struct SN_env * z, int bra, int ket, symbol * p)
{   int adjustment = replace_s(z, bra, ket, SIZE(p), p);
    if (bra <= z->bra) z->bra += adjustment;
    if (bra <= z->ket) z->ket += adjustment;
}

extern symbol * slice_to(struct SN_env * z, symbol * p)
{   slice_check(z);
    {   int len = z->ket - z->bra;
        if (CAPACITY(p) < len) p = increase_size(p, len);
        memmove(p, z->p + z->bra, len * sizeof(symbol));
        SET_SIZE(p, len);
    }
    return p;
}

extern symbol * assign_to(struct SN_env * z, symbol * p)
{   int len = z->l;
    if (CAPACITY(p) < len) p = increase_size(p, len);
    memmove(p, z->p, len * sizeof(symbol));
    SET_SIZE(p, len);
    return p;
}

extern void debug(struct SN_env * z, int number, int line_count)
{   int i;
    int limit = SIZE(z->p);
    /*if (number >= 0) printf("%3d (line %4d): '", number, line_count);*/
    if (number >= 0) printf("%3d (line %4d): [%d]'", number, line_count,limit);
    for (i = 0; i <= limit; i++)
    {   if (z->lb == i) printf("{");
        if (z->bra == i) printf("[");
        if (z->c == i) printf("|");
        if (z->ket == i) printf("]");
        if (z->l == i) printf("}");
        if (i < limit)
        {   int ch = z->p[i];
            if (ch == 0) ch = '#';
            printf("%c", ch);
        }
    }
    printf("'\n");
}
tsearch2 module 2003-07-21 18:27:44 +08:00
			`#include <stdio.h>`
			`#include <stdlib.h>`
			`#include <string.h>`

			`#include "header.h"`

			`#define unless(C) if(!(C))`

			`#define CREATE_SIZE 1`

			`extern symbol * create_s(void)`
			`{ symbol * p = (symbol ) (HEAD + (char ) malloc(HEAD + (CREATE_SIZE + 1) * sizeof(symbol)));`
			`CAPACITY(p) = CREATE_SIZE;`
			`SET_SIZE(p, CREATE_SIZE);`
			`return p;`
			`}`

			`extern void lose_s(symbol * p) { free((char *) p - HEAD); }`

			`extern int in_grouping(struct SN_env * z, unsigned char * s, int min, int max)`
			`{ if (z->c >= z->l) return 0;`
			`{ int ch = z->p[z->c];`
			`if`
			`(ch > max \|\| (ch -= min) < 0 \|\|`
			`(s[ch >> 3] & (0X1 << (ch & 0X7))) == 0) return 0;`
			`}`
			`z->c++; return 1;`
			`}`

			`extern int in_grouping_b(struct SN_env * z, unsigned char * s, int min, int max)`
			`{ if (z->c <= z->lb) return 0;`
			`{ int ch = z->p[z->c - 1];`
			`if`
			`(ch > max \|\| (ch -= min) < 0 \|\|`
			`(s[ch >> 3] & (0X1 << (ch & 0X7))) == 0) return 0;`
			`}`
			`z->c--; return 1;`
			`}`

			`extern int out_grouping(struct SN_env * z, unsigned char * s, int min, int max)`
			`{ if (z->c >= z->l) return 0;`
			`{ int ch = z->p[z->c];`
			`unless`
			`(ch > max \|\| (ch -= min) < 0 \|\|`
			`(s[ch >> 3] & (0X1 << (ch & 0X7))) == 0) return 0;`
			`}`
			`z->c++; return 1;`
			`}`

			`extern int out_grouping_b(struct SN_env * z, unsigned char * s, int min, int max)`
			`{ if (z->c <= z->lb) return 0;`
			`{ int ch = z->p[z->c - 1];`
			`unless`
			`(ch > max \|\| (ch -= min) < 0 \|\|`
			`(s[ch >> 3] & (0X1 << (ch & 0X7))) == 0) return 0;`
			`}`
			`z->c--; return 1;`
			`}`


			`extern int in_range(struct SN_env * z, int min, int max)`
			`{ if (z->c >= z->l) return 0;`
			`{ int ch = z->p[z->c];`
			`if`
			`(ch > max \|\| ch < min) return 0;`
			`}`
			`z->c++; return 1;`
			`}`

			`extern int in_range_b(struct SN_env * z, int min, int max)`
			`{ if (z->c <= z->lb) return 0;`
			`{ int ch = z->p[z->c - 1];`
			`if`
			`(ch > max \|\| ch < min) return 0;`
			`}`
			`z->c--; return 1;`
			`}`

			`extern int out_range(struct SN_env * z, int min, int max)`
			`{ if (z->c >= z->l) return 0;`
			`{ int ch = z->p[z->c];`
			`unless`
			`(ch > max \|\| ch < min) return 0;`
			`}`
			`z->c++; return 1;`
			`}`

			`extern int out_range_b(struct SN_env * z, int min, int max)`
			`{ if (z->c <= z->lb) return 0;`
			`{ int ch = z->p[z->c - 1];`
			`unless`
			`(ch > max \|\| ch < min) return 0;`
			`}`
			`z->c--; return 1;`
			`}`

			`extern int eq_s(struct SN_env * z, int s_size, symbol * s)`
			`{ if (z->l - z->c < s_size \|\|`
			`memcmp(z->p + z->c, s, s_size * sizeof(symbol)) != 0) return 0;`
			`z->c += s_size; return 1;`
			`}`

			`extern int eq_s_b(struct SN_env * z, int s_size, symbol * s)`
			`{ if (z->c - z->lb < s_size \|\|`
			`memcmp(z->p + z->c - s_size, s, s_size * sizeof(symbol)) != 0) return 0;`
			`z->c -= s_size; return 1;`
			`}`

			`extern int eq_v(struct SN_env * z, symbol * p)`
			`{ return eq_s(z, SIZE(p), p);`
			`}`

			`extern int eq_v_b(struct SN_env * z, symbol * p)`
			`{ return eq_s_b(z, SIZE(p), p);`
			`}`

			`extern int find_among(struct SN_env * z, struct among * v, int v_size)`
			`{`
			`int i = 0;`
			`int j = v_size;`

			`int c = z->c; int l = z->l;`
			`symbol * q = z->p + c;`

			`struct among * w;`

			`int common_i = 0;`
			`int common_j = 0;`

			`int first_key_inspected = 0;`

			`while(1)`
			`{ int k = i + ((j - i) >> 1);`
			`int diff = 0;`
			`int common = common_i < common_j ? common_i : common_j; /* smaller */`
			`w = v + k;`
			`{ int i; for (i = common; i < w->s_size; i++)`
			`{ if (c + common == l) { diff = -1; break; }`
			`diff = q[common] - w->s[i];`
			`if (diff != 0) break;`
			`common++;`
			`}`
			`}`
			`if (diff < 0) { j = k; common_j = common; }`
			`else { i = k; common_i = common; }`
			`if (j - i <= 1)`
			`{ if (i > 0) break; /* v->s has been inspected */`
			`if (j == i) break; /* only one item in v */`

			`/* - but now we need to go round once more to get`
			`v->s inspected. This looks messy, but is actually`
			`the optimal approach. */`

			`if (first_key_inspected) break;`
			`first_key_inspected = 1;`
			`}`
			`}`
			`while(1)`
			`{ w = v + i;`
			`if (common_i >= w->s_size)`
			`{ z->c = c + w->s_size;`
			`if (w->function == 0) return w->result;`
			`{ int res = w->function(z);`
			`z->c = c + w->s_size;`
			`if (res) return w->result;`
			`}`
			`}`
			`i = w->substring_i;`
			`if (i < 0) return 0;`
			`}`
			`}`

			`/* find_among_b is for backwards processing. Same comments apply */`

			`extern int find_among_b(struct SN_env * z, struct among * v, int v_size)`
			`{`
			`int i = 0;`
			`int j = v_size;`

			`int c = z->c; int lb = z->lb;`
			`symbol * q = z->p + c - 1;`

			`struct among * w;`

			`int common_i = 0;`
			`int common_j = 0;`

			`int first_key_inspected = 0;`

			`while(1)`
			`{ int k = i + ((j - i) >> 1);`
			`int diff = 0;`
			`int common = common_i < common_j ? common_i : common_j;`
			`w = v + k;`
			`{ int i; for (i = w->s_size - 1 - common; i >= 0; i--)`
			`{ if (c - common == lb) { diff = -1; break; }`
			`diff = q[- common] - w->s[i];`
			`if (diff != 0) break;`
			`common++;`
			`}`
			`}`
			`if (diff < 0) { j = k; common_j = common; }`
			`else { i = k; common_i = common; }`
			`if (j - i <= 1)`
			`{ if (i > 0) break;`
			`if (j == i) break;`
			`if (first_key_inspected) break;`
			`first_key_inspected = 1;`
			`}`
			`}`
			`while(1)`
			`{ w = v + i;`
			`if (common_i >= w->s_size)`
			`{ z->c = c - w->s_size;`
			`if (w->function == 0) return w->result;`
			`{ int res = w->function(z);`
			`z->c = c - w->s_size;`
			`if (res) return w->result;`
			`}`
			`}`
			`i = w->substring_i;`
			`if (i < 0) return 0;`
			`}`
			`}`


			`extern symbol * increase_size(symbol * p, int n)`
			`{ int new_size = n + 20;`
			`symbol * q = (symbol ) (HEAD + (char ) malloc(HEAD + (new_size + 1) * sizeof(symbol)));`
			`CAPACITY(q) = new_size;`
			`memmove(q, p, CAPACITY(p) * sizeof(symbol)); lose_s(p); return q;`
			`}`

			`/* to replace symbols between c_bra and c_ket in z->p by the`
			`s_size symbols at s`
			`*/`

			`extern int replace_s(struct SN_env * z, int c_bra, int c_ket, int s_size, const symbol * s)`
			`{ int adjustment = s_size - (c_ket - c_bra);`
			`int len = SIZE(z->p);`
			`if (adjustment != 0)`
			`{ if (adjustment + len > CAPACITY(z->p)) z->p = increase_size(z->p, adjustment + len);`
			`memmove(z->p + c_ket + adjustment, z->p + c_ket, (len - c_ket) * sizeof(symbol));`
			`SET_SIZE(z->p, adjustment + len);`
			`z->l += adjustment;`
			`if (z->c >= c_ket) z->c += adjustment; else`
			`if (z->c > c_bra) z->c = c_bra;`
			`}`
			`unless (s_size == 0) memmove(z->p + c_bra, s, s_size * sizeof(symbol));`
			`return adjustment;`
			`}`

			`static void slice_check(struct SN_env * z)`
			`{`
			`if (!(0 <= z->bra &&`
			`z->bra <= z->ket &&`
			`z->ket <= z->l &&`
			`z->l <= SIZE(z->p))) /* this line could be removed */`
			`{`
			`fprintf(stderr, "faulty slice operation:\n");`
			`debug(z, -1, 0);`
			`exit(1);`
			`}`
			`}`

			`extern void slice_from_s(struct SN_env * z, int s_size, symbol * s)`
			`{ slice_check(z);`
			`replace_s(z, z->bra, z->ket, s_size, s);`
			`}`

			`extern void slice_from_v(struct SN_env * z, symbol * p)`
			`{ slice_from_s(z, SIZE(p), p);`
			`}`

			`extern void slice_del(struct SN_env * z)`
			`{ slice_from_s(z, 0, 0);`
			`}`

			`extern void insert_s(struct SN_env * z, int bra, int ket, int s_size, symbol * s)`
			`{ int adjustment = replace_s(z, bra, ket, s_size, s);`
			`if (bra <= z->bra) z->bra += adjustment;`
			`if (bra <= z->ket) z->ket += adjustment;`
			`}`

			`extern void insert_v(struct SN_env * z, int bra, int ket, symbol * p)`
			`{ int adjustment = replace_s(z, bra, ket, SIZE(p), p);`
			`if (bra <= z->bra) z->bra += adjustment;`
			`if (bra <= z->ket) z->ket += adjustment;`
			`}`

			`extern symbol * slice_to(struct SN_env * z, symbol * p)`
			`{ slice_check(z);`
			`{ int len = z->ket - z->bra;`
			`if (CAPACITY(p) < len) p = increase_size(p, len);`
			`memmove(p, z->p + z->bra, len * sizeof(symbol));`
			`SET_SIZE(p, len);`
			`}`
			`return p;`
			`}`

			`extern symbol * assign_to(struct SN_env * z, symbol * p)`
			`{ int len = z->l;`
			`if (CAPACITY(p) < len) p = increase_size(p, len);`
			`memmove(p, z->p, len * sizeof(symbol));`
			`SET_SIZE(p, len);`
			`return p;`
			`}`

			`extern void debug(struct SN_env * z, int number, int line_count)`
			`{ int i;`
			`int limit = SIZE(z->p);`
			`/if (number >= 0) printf("%3d (line %4d): '", number, line_count);/`
			`if (number >= 0) printf("%3d (line %4d): [%d]'", number, line_count,limit);`
			`for (i = 0; i <= limit; i++)`
			`{ if (z->lb == i) printf("{");`
			`if (z->bra == i) printf("[");`
			`if (z->c == i) printf("\|");`
			`if (z->ket == i) printf("]");`
			`if (z->l == i) printf("}");`
			`if (i < limit)`
			`{ int ch = z->p[i];`
			`if (ch == 0) ch = '#';`
			`printf("%c", ch);`
			`}`
			`}`
			`printf("'\n");`
			`}`