#include "snowball_runtime.h" #ifdef SNOWBALL_RUNTIME_THROW_EXCEPTIONS # include # include # define SNOWBALL_RETURN_OK return # define SNOWBALL_RETURN_OR_THROW(R, E) throw E # define SNOWBALL_PROPAGATE_ERR(F) F #else # define SNOWBALL_RETURN_OK return 0 # define SNOWBALL_RETURN_OR_THROW(R, E) return R # define SNOWBALL_PROPAGATE_ERR(F) do { \ int snowball_err = F; \ if (snowball_err < 0) return snowball_err; \ } while (0) #endif #define CREATE_SIZE 1 extern symbol * create_s(void) { symbol * p; void * mem = malloc(HEAD + (CREATE_SIZE + 1) * sizeof(symbol)); if (mem == NULL) SNOWBALL_RETURN_OR_THROW(NULL, std::bad_alloc()); p = (symbol *) (HEAD + (char *) mem); CAPACITY(p) = CREATE_SIZE; SET_SIZE(p, 0); return p; } extern void lose_s(symbol * p) { if (p == NULL) return; free((char *) p - HEAD); } /* new_p = skip_utf8(p, c, l, n); skips n characters forwards from p + c. new_p is the new position, or -1 on failure. -- used to implement hop and next in the utf8 case. */ extern int skip_utf8(const symbol * p, int c, int limit, int n) { int b; if (n < 0) return -1; for (; n > 0; n--) { if (c >= limit) return -1; b = p[c++]; if (b >= 0xC0) { /* 1100 0000 */ while (c < limit) { b = p[c]; if (b >= 0xC0 || b < 0x80) break; /* break unless b is 10------ */ c++; } } } return c; } /* new_p = skip_b_utf8(p, c, lb, n); skips n characters backwards from p + c - 1 new_p is the new position, or -1 on failure. -- used to implement hop and next in the utf8 case. */ extern int skip_b_utf8(const symbol * p, int c, int limit, int n) { int b; if (n < 0) return -1; for (; n > 0; n--) { if (c <= limit) return -1; b = p[--c]; if (b >= 0x80) { /* 1000 0000 */ while (c > limit) { b = p[c]; if (b >= 0xC0) break; /* 1100 0000 */ c--; } } } return c; } /* Code for character groupings: utf8 cases */ static int get_utf8(const symbol * p, int c, int l, int * slot) { int b0, b1, b2; if (c >= l) return 0; b0 = p[c++]; if (b0 < 0xC0 || c == l) { /* 1100 0000 */ *slot = b0; return 1; } b1 = p[c++] & 0x3F; if (b0 < 0xE0 || c == l) { /* 1110 0000 */ *slot = (b0 & 0x1F) << 6 | b1; return 2; } b2 = p[c++] & 0x3F; if (b0 < 0xF0 || c == l) { /* 1111 0000 */ *slot = (b0 & 0xF) << 12 | b1 << 6 | b2; return 3; } *slot = (b0 & 0x7) << 18 | b1 << 12 | b2 << 6 | (p[c] & 0x3F); return 4; } static int get_b_utf8(const symbol * p, int c, int lb, int * slot) { int a, b; if (c <= lb) return 0; b = p[--c]; if (b < 0x80 || c == lb) { /* 1000 0000 */ *slot = b; return 1; } a = b & 0x3F; b = p[--c]; if (b >= 0xC0 || c == lb) { /* 1100 0000 */ *slot = (b & 0x1F) << 6 | a; return 2; } a |= (b & 0x3F) << 6; b = p[--c]; if (b >= 0xE0 || c == lb) { /* 1110 0000 */ *slot = (b & 0xF) << 12 | a; return 3; } *slot = (p[--c] & 0x7) << 18 | (b & 0x3F) << 12 | a; return 4; } extern int in_grouping_U(struct SN_env * z, const unsigned char * s, int min, int max, int repeat) { do { int ch; int w = get_utf8(z->p, z->c, z->l, & ch); if (!w) return -1; if (ch > max || (ch -= min) < 0 || (s[ch >> 3] & (0X1 << (ch & 0X7))) == 0) return w; z->c += w; } while (repeat); return 0; } extern int in_grouping_b_U(struct SN_env * z, const unsigned char * s, int min, int max, int repeat) { do { int ch; int w = get_b_utf8(z->p, z->c, z->lb, & ch); if (!w) return -1; if (ch > max || (ch -= min) < 0 || (s[ch >> 3] & (0X1 << (ch & 0X7))) == 0) return w; z->c -= w; } while (repeat); return 0; } extern int out_grouping_U(struct SN_env * z, const unsigned char * s, int min, int max, int repeat) { do { int ch; int w = get_utf8(z->p, z->c, z->l, & ch); if (!w) return -1; if (!(ch > max || (ch -= min) < 0 || (s[ch >> 3] & (0X1 << (ch & 0X7))) == 0)) return w; z->c += w; } while (repeat); return 0; } extern int out_grouping_b_U(struct SN_env * z, const unsigned char * s, int min, int max, int repeat) { do { int ch; int w = get_b_utf8(z->p, z->c, z->lb, & ch); if (!w) return -1; if (!(ch > max || (ch -= min) < 0 || (s[ch >> 3] & (0X1 << (ch & 0X7))) == 0)) return w; z->c -= w; } while (repeat); return 0; } /* Code for character groupings: non-utf8 cases */ extern int in_grouping(struct SN_env * z, const unsigned char * s, int min, int max, int repeat) { do { int ch; if (z->c >= z->l) return -1; ch = z->p[z->c]; if (ch > max || (ch -= min) < 0 || (s[ch >> 3] & (0X1 << (ch & 0X7))) == 0) return 1; z->c++; } while (repeat); return 0; } extern int in_grouping_b(struct SN_env * z, const unsigned char * s, int min, int max, int repeat) { do { int ch; if (z->c <= z->lb) return -1; ch = z->p[z->c - 1]; if (ch > max || (ch -= min) < 0 || (s[ch >> 3] & (0X1 << (ch & 0X7))) == 0) return 1; z->c--; } while (repeat); return 0; } extern int out_grouping(struct SN_env * z, const unsigned char * s, int min, int max, int repeat) { do { int ch; if (z->c >= z->l) return -1; ch = z->p[z->c]; if (!(ch > max || (ch -= min) < 0 || (s[ch >> 3] & (0X1 << (ch & 0X7))) == 0)) return 1; z->c++; } while (repeat); return 0; } extern int out_grouping_b(struct SN_env * z, const unsigned char * s, int min, int max, int repeat) { do { int ch; if (z->c <= z->lb) return -1; ch = z->p[z->c - 1]; if (!(ch > max || (ch -= min) < 0 || (s[ch >> 3] & (0X1 << (ch & 0X7))) == 0)) return 1; z->c--; } while (repeat); return 0; } extern int eq_s(struct SN_env * z, int s_size, const 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, const 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, const symbol * p) { return eq_s(z, SIZE(p), p); } extern int eq_v_b(struct SN_env * z, const symbol * p) { return eq_s_b(z, SIZE(p), p); } extern int find_among(struct SN_env * z, const struct among * v, int v_size, int (*call_among_func)(struct SN_env*)) { int i = 0; int j = v_size; int c = z->c; int l = z->l; const symbol * q = z->p + c; const 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 i2; for (i2 = common; i2 < w->s_size; i2++) { if (c + common == l) { diff = -1; break; } diff = q[common] - w->s[i2]; 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; } } w = v + i; while (1) { if (common_i >= w->s_size) { z->c = c + w->s_size; if (!w->function) return w->result; z->af = w->function; if (call_among_func(z)) { z->c = c + w->s_size; return w->result; } } if (!w->substring_i) return 0; w += w->substring_i; } } /* find_among_b is for backwards processing. Same comments apply */ extern int find_among_b(struct SN_env * z, const struct among * v, int v_size, int (*call_among_func)(struct SN_env*)) { int i = 0; int j = v_size; int c = z->c; int lb = z->lb; const symbol * q = z->p + c - 1; const 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 i2; for (i2 = w->s_size - 1 - common; i2 >= 0; i2--) { if (c - common == lb) { diff = -1; break; } diff = q[- common] - w->s[i2]; 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; } } w = v + i; while (1) { if (common_i >= w->s_size) { z->c = c - w->s_size; if (!w->function) return w->result; z->af = w->function; if (call_among_func(z)) { z->c = c - w->s_size; return w->result; } } if (!w->substring_i) return 0; w += w->substring_i; } } /* Increase the size of the buffer pointed to by p to at least n symbols. * On success, returns 0. If insufficient memory, returns -1. */ static int increase_size(symbol ** p, int n) { int new_size = n + 20; void * mem = realloc((char *) *p - HEAD, HEAD + (new_size + 1) * sizeof(symbol)); symbol * q; if (mem == NULL) return -1; q = (symbol *) (HEAD + (char *)mem); CAPACITY(q) = new_size; *p = q; return 0; } /* to replace symbols between c_bra and c_ket in z->p by the s_size symbols at s. Returns 0 on success, -1 on error. */ extern SNOWBALL_ERR 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); if (adjustment != 0) { int len = SIZE(z->p); if (adjustment + len > CAPACITY(z->p)) { SNOWBALL_PROPAGATE_ERR(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; } if (s_size) memmove(z->p + c_bra, s, s_size * sizeof(symbol)); SNOWBALL_RETURN_OK; } # define REPLACE_S(Z, B, K, SIZE, S) \ SNOWBALL_PROPAGATE_ERR(replace_s(Z, B, K, SIZE, S)) static SNOWBALL_ERR slice_check(struct SN_env * z) { if (z->bra < 0 || z->bra > z->ket || z->ket > z->l || z->l > SIZE(z->p)) /* this line could be removed */ { #if 0 fprintf(stderr, "faulty slice operation:\n"); debug(z, -1, 0); #endif SNOWBALL_RETURN_OR_THROW(-1, std::logic_error("Snowball slice invalid")); } SNOWBALL_RETURN_OK; } # define SLICE_CHECK(Z) SNOWBALL_PROPAGATE_ERR(slice_check(Z)) extern SNOWBALL_ERR slice_from_s(struct SN_env * z, int s_size, const symbol * s) { SLICE_CHECK(z); REPLACE_S(z, z->bra, z->ket, s_size, s); z->ket = z->bra + s_size; SNOWBALL_RETURN_OK; } extern SNOWBALL_ERR slice_from_v(struct SN_env * z, const symbol * p) { return slice_from_s(z, SIZE(p), p); } extern SNOWBALL_ERR slice_del(struct SN_env * z) { SLICE_CHECK(z); { int slice_size = z->ket - z->bra; if (slice_size != 0) { int len = SIZE(z->p); memmove(z->p + z->bra, z->p + z->ket, (len - z->ket) * sizeof(symbol)); SET_SIZE(z->p, len - slice_size); z->l -= slice_size; if (z->c >= z->ket) z->c -= slice_size; else if (z->c > z->bra) z->c = z->bra; } } z->ket = z->bra; SNOWBALL_RETURN_OK; } extern SNOWBALL_ERR insert_s(struct SN_env * z, int bra, int ket, int s_size, const symbol * s) { REPLACE_S(z, bra, ket, s_size, s); if (bra <= z->ket) { int adjustment = s_size - (ket - bra); z->ket += adjustment; if (bra <= z->bra) z->bra += adjustment; } SNOWBALL_RETURN_OK; } extern SNOWBALL_ERR insert_v(struct SN_env * z, int bra, int ket, const symbol * p) { return insert_s(z, bra, ket, SIZE(p), p); } extern SNOWBALL_ERR slice_to(struct SN_env * z, symbol ** p) { SLICE_CHECK(z); { int len = z->ket - z->bra; if (CAPACITY(*p) < len) { SNOWBALL_PROPAGATE_ERR(increase_size(p, len)); } memmove(*p, z->p + z->bra, len * sizeof(symbol)); SET_SIZE(*p, len); } SNOWBALL_RETURN_OK; } extern SNOWBALL_ERR assign_to(struct SN_env * z, symbol ** p) { int len = z->l; if (CAPACITY(*p) < len) { SNOWBALL_PROPAGATE_ERR(increase_size(p, len)); } memmove(*p, z->p, len * sizeof(symbol)); SET_SIZE(*p, len); SNOWBALL_RETURN_OK; } extern int len_utf8(const symbol * p) { int size = SIZE(p); int len = 0; while (size--) { symbol b = *p++; if (b >= 0xC0 || b < 0x80) ++len; } return len; }