/* * This file and its contents are supplied under the terms of the * Common Development and Distribution License ("CDDL"), version 1.0. * You may only use this file in accordance with the terms version 1.0 * of the CDDL. * * A full copy of the text of the CDDL should have accompanied this * source. A copy of the CDDL is also available via the Internet at * http://www.illumos.org/license/CDDL. */ /* * Copyright 2010 Nexenta Systems, Inc. All rights reserved. */ /* * LC_COLLATE database generation routines for localedef. */ #include #include #include #include #include #include #include #include #include #include #include #include "localedef.h" #include "parser.tab.h" #include "collate.h" /* * Design notes. * * It will be extremely helpful to the reader if they have access to * the localedef and locale file format specifications available. * Latest versions of these are available from www.opengroup.org. * * The design for the collation code is a bit complex. The goal is a * single collation database as described in collate.h (in * libc/port/locale). However, there are some other tidbits: * * a) The substitution entries are now a directly indexable array. A * priority elsewhere in the table is taken as an index into the * substitution table if it has a high bit (COLLATE_SUBST_PRIORITY) * set. (The bit is cleared and the result is the index into the * table. * * b) We eliminate duplicate entries into the substitution table. * This saves a lot of space. * * c) The priorities for each level are "compressed", so that each * sorting level has consecutively numbered priorities starting at 1. * (O is reserved for the ignore priority.) This means sort levels * which only have a few distinct priorities can represent the * priority level in fewer bits, which makes the strxfrm output * smaller. * * d) We record the total number of priorities so that strxfrm can * figure out how many bytes to expand a numeric priority into. * * e) For the UNDEFINED pass (the last pass), we record the maximum * number of bits needed to uniquely prioritize these entries, so that * the last pass can also use smaller strxfrm output when possible. * * f) Priorities with the sign bit set are verboten. This works out * because no active character set needs that bit to carry significant * information once the character is in wide form. * * To process the entire data to make the database, we actually run * multiple passes over the data. * * The first pass, which is done at parse time, identifies elements, * substitutions, and such, and records them in priority order. As * some priorities can refer to other priorities, using forward * references, we use a table of references indicating whether the * priority's value has been resolved, or whether it is still a * reference. * * The second pass walks over all the items in priority order, noting * that they are used directly, and not just an indirect reference. * This is done by creating a "weight" structure for the item. The * weights are stashed in an AVL tree sorted by relative "priority". * * The third pass walks over all the weight structures, in priority * order, and assigns a new monotonically increasing (per sort level) * weight value to them. These are the values that will actually be * written to the file. * * The fourth pass just writes the data out. */ /* * In order to resolve the priorities, we create a table of priorities. * Entries in the table can be in one of three states. * * UNKNOWN is for newly allocated entries, and indicates that nothing * is known about the priority. (For example, when new entries are created * for collating-symbols, this is the value assigned for them until the * collating symbol's order has been determined. * * RESOLVED is used for an entry where the priority indicates the final * numeric weight. * * REFER is used for entries that reference other entries. Typically * this is used for forward references. A collating-symbol can never * have this value. * * The "pass" field is used during final resolution to aid in detection * of referencing loops. (For example depends on , but has its * priority dependent on .) */ typedef enum { UNKNOWN, /* priority is totally unknown */ RESOLVED, /* priority value fully resolved */ REFER /* priority is a reference (index) */ } res_t; typedef struct weight { int32_t pri; int opt; avl_node_t avl; } weight_t; typedef struct priority { res_t res; int32_t pri; int pass; int lineno; } collpri_t; #define NUM_WT collinfo.directive_count /* * These are the abstract collating symbols, which are just a symbolic * way to reference a priority. */ struct collsym { char *name; int32_t ref; avl_node_t avl; }; /* * These are also abstract collating symbols, but we allow them to have * different priorities at different levels. */ typedef struct collundef { char *name; int32_t ref[COLL_WEIGHTS_MAX]; avl_node_t avl; } collundef_t; /* * These are called "chains" in libc. This records the fact that two * more characters should be treated as a single collating entity when * they appear together. For example, in Spanish gets collated * as a character between and . */ struct collelem { char *symbol; wchar_t *expand; int32_t ref[COLL_WEIGHTS_MAX]; avl_node_t avl_bysymbol; avl_node_t avl_byexpand; }; /* * Individual characters have a sequence of weights as well. */ typedef struct collchar { wchar_t wc; int32_t ref[COLL_WEIGHTS_MAX]; avl_node_t avl; } collchar_t; /* * Substitution entries. The key is itself a priority. Note that * when we create one of these, we *automatically* wind up with a * fully resolved priority for the key, because creation of * substitutions creates a resolved priority at the same time. */ typedef struct { int32_t key; int32_t ref[COLLATE_STR_LEN]; avl_node_t avl; avl_node_t avl_ref; } subst_t; static avl_tree_t collsyms; static avl_tree_t collundefs; static avl_tree_t elem_by_symbol; static avl_tree_t elem_by_expand; static avl_tree_t collchars; static avl_tree_t substs[COLL_WEIGHTS_MAX]; static avl_tree_t substs_ref[COLL_WEIGHTS_MAX]; static avl_tree_t weights[COLL_WEIGHTS_MAX]; static int32_t nweight[COLL_WEIGHTS_MAX]; /* * This is state tracking for the ellipsis token. Note that we start * the initial values so that the ellipsis logic will think we got a * magic starting value of NUL. It starts at minus one because the * starting point is exclusive -- i.e. the starting point is not * itself handled by the ellipsis code. */ static int currorder = EOF; static int lastorder = EOF; static collelem_t *currelem; static collchar_t *currchar; static collundef_t *currundef; static wchar_t ellipsis_start = 0; static int32_t ellipsis_weights[COLL_WEIGHTS_MAX]; /* * We keep a running tally of weights. */ static int nextpri = 1; static int nextsubst[COLL_WEIGHTS_MAX] = { 0 }; /* * This array collects up the weights for each level. */ static int32_t order_weights[COLL_WEIGHTS_MAX]; static int curr_weight = 0; static int32_t subst_weights[COLLATE_STR_LEN]; static int curr_subst = 0; /* * Some initial priority values. */ static int32_t pri_undefined[COLL_WEIGHTS_MAX]; static int32_t pri_ignore; static collate_info_t collinfo; static collpri_t *prilist = NULL; static int numpri = 0; static int maxpri = 0; static void start_order(int); static int32_t new_pri(void) { int i; if (numpri >= maxpri) { maxpri = maxpri ? maxpri * 2 : 1024; prilist = realloc(prilist, sizeof (collpri_t) * maxpri); if (prilist == NULL) { errf(_("out of memory")); return (-1); } for (i = numpri; i < maxpri; i++) { prilist[i].res = UNKNOWN; prilist[i].pri = 0; prilist[i].pass = 0; } } return (numpri++); } static collpri_t * get_pri(int32_t ref) { if ((ref < 0) || (ref > numpri)) { INTERR; return (NULL); } return (&prilist[ref]); } static void set_pri(int32_t ref, int32_t v, res_t res) { collpri_t *pri; pri = get_pri(ref); if ((res == REFER) && ((v < 0) || (v >= numpri))) { INTERR; } /* Resolve self references */ if ((res == REFER) && (ref == v)) { v = nextpri; res = RESOLVED; } if (pri->res != UNKNOWN) { warn(_("repeated item in order list (first on %d)"), pri->lineno); return; } pri->lineno = lineno; pri->pri = v; pri->res = res; } static int32_t resolve_pri(int32_t ref) { collpri_t *pri; static int32_t pass = 0; pri = get_pri(ref); pass++; while (pri->res == REFER) { if (pri->pass == pass) { /* report a line with the circular symbol */ lineno = pri->lineno; errf(_("circular reference in order list")); return (-1); } if ((pri->pri < 0) || (pri->pri >= numpri)) { INTERR; return (-1); } pri->pass = pass; pri = &prilist[pri->pri]; } if (pri->res == UNKNOWN) { return (-1); } if (pri->res != RESOLVED) INTERR; return (pri->pri); } static int weight_compare(const void *n1, const void *n2) { int32_t k1 = ((const weight_t *)n1)->pri; int32_t k2 = ((const weight_t *)n2)->pri; return (k1 < k2 ? -1 : k1 > k2 ? 1 : 0); } static int collsym_compare(const void *n1, const void *n2) { const collsym_t *c1 = n1; const collsym_t *c2 = n2; int rv; rv = strcmp(c1->name, c2->name); return ((rv < 0) ? -1 : (rv > 0) ? 1 : 0); } static int collundef_compare(const void *n1, const void *n2) { const collundef_t *c1 = n1; const collundef_t *c2 = n2; int rv; rv = strcmp(c1->name, c2->name); return ((rv < 0) ? -1 : (rv > 0) ? 1 : 0); } static int element_compare_symbol(const void *n1, const void *n2) { const collelem_t *c1 = n1; const collelem_t *c2 = n2; int rv; rv = strcmp(c1->symbol, c2->symbol); return ((rv < 0) ? -1 : (rv > 0) ? 1 : 0); } static int element_compare_expand(const void *n1, const void *n2) { const collelem_t *c1 = n1; const collelem_t *c2 = n2; int rv; rv = wcscmp(c1->expand, c2->expand); return ((rv < 0) ? -1 : (rv > 0) ? 1 : 0); } static int collchar_compare(const void *n1, const void *n2) { wchar_t k1 = ((const collchar_t *)n1)->wc; wchar_t k2 = ((const collchar_t *)n2)->wc; return (k1 < k2 ? -1 : k1 > k2 ? 1 : 0); } static int subst_compare(const void *n1, const void *n2) { int32_t k1 = ((const subst_t *)n1)->key; int32_t k2 = ((const subst_t *)n2)->key; return (k1 < k2 ? -1 : k1 > k2 ? 1 : 0); } static int subst_compare_ref(const void *n1, const void *n2) { int32_t *c1 = ((subst_t *)n1)->ref; int32_t *c2 = ((subst_t *)n2)->ref; int rv; rv = wcscmp((wchar_t *)c1, (wchar_t *)c2); return ((rv < 0) ? -1 : (rv > 0) ? 1 : 0); } void init_collate(void) { int i; avl_create(&collsyms, collsym_compare, sizeof (collsym_t), offsetof(collsym_t, avl)); avl_create(&collundefs, collundef_compare, sizeof (collsym_t), offsetof(collundef_t, avl)); avl_create(&elem_by_symbol, element_compare_symbol, sizeof (collelem_t), offsetof(collelem_t, avl_bysymbol)); avl_create(&elem_by_expand, element_compare_expand, sizeof (collelem_t), offsetof(collelem_t, avl_byexpand)); avl_create(&collchars, collchar_compare, sizeof (collchar_t), offsetof(collchar_t, avl)); for (i = 0; i < COLL_WEIGHTS_MAX; i++) { avl_create(&substs[i], subst_compare, sizeof (subst_t), offsetof(subst_t, avl)); avl_create(&substs_ref[i], subst_compare_ref, sizeof (subst_t), offsetof(subst_t, avl_ref)); avl_create(&weights[i], weight_compare, sizeof (weight_t), offsetof(weight_t, avl)); nweight[i] = 1; } (void) memset(&collinfo, 0, sizeof (collinfo)); /* allocate some initial priorities */ pri_ignore = new_pri(); set_pri(pri_ignore, 0, RESOLVED); for (i = 0; i < COLL_WEIGHTS_MAX; i++) { pri_undefined[i] = new_pri(); /* we will override this later */ set_pri(pri_undefined[i], COLLATE_MAX_PRIORITY, UNKNOWN); } } void define_collsym(char *name) { collsym_t *sym; avl_index_t where; if ((sym = calloc(sizeof (*sym), 1)) == NULL) { errf(_("out of memory")); return; } sym->name = name; sym->ref = new_pri(); if (avl_find(&collsyms, sym, &where) != NULL) { /* * This should never happen because we are only called * for undefined symbols. */ INTERR; return; } avl_insert(&collsyms, sym, where); } collsym_t * lookup_collsym(char *name) { collsym_t srch; srch.name = name; return (avl_find(&collsyms, &srch, NULL)); } collelem_t * lookup_collelem(char *symbol) { collelem_t srch; srch.symbol = symbol; return (avl_find(&elem_by_symbol, &srch, NULL)); } static collundef_t * get_collundef(char *name) { collundef_t srch; collundef_t *ud; avl_index_t where; int i; srch.name = name; if ((ud = avl_find(&collundefs, &srch, &where)) == NULL) { if (((ud = calloc(sizeof (*ud), 1)) == NULL) || ((ud->name = strdup(name)) == NULL)) { errf(_("out of memory")); return (NULL); } for (i = 0; i < NUM_WT; i++) { ud->ref[i] = new_pri(); } avl_insert(&collundefs, ud, where); } add_charmap_undefined(name); return (ud); } static collchar_t * get_collchar(wchar_t wc, int create) { collchar_t srch; collchar_t *cc; avl_index_t where; int i; srch.wc = wc; cc = avl_find(&collchars, &srch, &where); if ((cc == NULL) && create) { if ((cc = calloc(sizeof (*cc), 1)) == NULL) { errf(_("out of memory")); return (NULL); } for (i = 0; i < NUM_WT; i++) { cc->ref[i] = new_pri(); } cc->wc = wc; avl_insert(&collchars, cc, where); } return (cc); } void end_order_collsym(collsym_t *sym) { start_order(T_COLLSYM); /* update the weight */ set_pri(sym->ref, nextpri, RESOLVED); nextpri++; } void end_order(void) { int i; int32_t pri; int32_t ref; collpri_t *p; /* advance the priority/weight */ pri = nextpri; switch (currorder) { case T_CHAR: for (i = 0; i < NUM_WT; i++) { if (((ref = order_weights[i]) < 0) || ((p = get_pri(ref)) == NULL) || (p->pri == -1)) { /* unspecified weight is a self reference */ set_pri(currchar->ref[i], pri, RESOLVED); } else { set_pri(currchar->ref[i], ref, REFER); } order_weights[i] = -1; } /* leave a cookie trail in case next symbol is ellipsis */ ellipsis_start = currchar->wc + 1; currchar = NULL; break; case T_ELLIPSIS: /* save off the weights were we can find them */ for (i = 0; i < NUM_WT; i++) { ellipsis_weights[i] = order_weights[i]; order_weights[i] = -1; } break; case T_COLLELEM: if (currelem == NULL) { INTERR; } else { for (i = 0; i < NUM_WT; i++) { if (((ref = order_weights[i]) < 0) || ((p = get_pri(ref)) == NULL) || (p->pri == -1)) { set_pri(currelem->ref[i], pri, RESOLVED); } else { set_pri(currelem->ref[i], ref, REFER); } order_weights[i] = -1; } } break; case T_UNDEFINED: for (i = 0; i < NUM_WT; i++) { if (((ref = order_weights[i]) < 0) || ((p = get_pri(ref)) == NULL) || (p->pri == -1)) { set_pri(pri_undefined[i], -1, RESOLVED); } else { set_pri(pri_undefined[i], ref, REFER); } order_weights[i] = -1; } break; case T_SYMBOL: if (((ref = order_weights[i]) < 0) || ((p = get_pri(ref)) == NULL) || (p->pri == -1)) { set_pri(currundef->ref[i], pri, RESOLVED); } else { set_pri(currundef->ref[i], ref, REFER); } order_weights[i] = -1; break; default: INTERR; } nextpri++; } static void start_order(int type) { int i; lastorder = currorder; currorder = type; /* this is used to protect ELLIPSIS processing */ if ((lastorder == T_ELLIPSIS) && (type != T_CHAR)) { errf(_("character value expected")); } for (i = 0; i < COLL_WEIGHTS_MAX; i++) { order_weights[i] = -1; } curr_weight = 0; } void start_order_undefined(void) { start_order(T_UNDEFINED); } void start_order_symbol(char *name) { currundef = get_collundef(name); start_order(T_SYMBOL); } void start_order_char(wchar_t wc) { collchar_t *cc; int32_t ref; start_order(T_CHAR); /* * If we last saw an ellipsis, then we need to close the range. * Handle that here. Note that we have to be careful because the * items *inside* the range are treated exclusiveley to the items * outside of the range. The ends of the range can have quite * different weights than the range members. */ if (lastorder == T_ELLIPSIS) { int i; if (wc < ellipsis_start) { errf(_("malformed range!")); return; } while (ellipsis_start < wc) { /* * pick all of the saved weights for the * ellipsis. note that -1 encodes for the * ellipsis itself, which means to take the * current relative priority. */ if ((cc = get_collchar(ellipsis_start, 1)) == NULL) { INTERR; return; } for (i = 0; i < NUM_WT; i++) { collpri_t *p; if (((ref = ellipsis_weights[i]) == -1) || ((p = get_pri(ref)) == NULL) || (p->pri == -1)) { set_pri(cc->ref[i], nextpri, RESOLVED); } else { set_pri(cc->ref[i], ref, REFER); } ellipsis_weights[i] = NULL; } ellipsis_start++; nextpri++; } } currchar = get_collchar(wc, 1); } void start_order_collelem(collelem_t *e) { start_order(T_COLLELEM); currelem = e; } void start_order_ellipsis(void) { int i; start_order(T_ELLIPSIS); if (lastorder != T_CHAR) { errf(_("illegal starting point for range")); return; } for (i = 0; i < NUM_WT; i++) { ellipsis_weights[i] = order_weights[i]; } } void define_collelem(char *name, wchar_t *wcs) { collelem_t *e; avl_index_t where1; avl_index_t where2; int i; if (wcslen(wcs) >= COLLATE_STR_LEN) { errf(_("expanded collation element too long")); return; } if ((e = calloc(sizeof (*e), 1)) == NULL) { errf(_("out of memory")); return; } e->expand = wcs; e->symbol = name; /* * This is executed before the order statement, so we don't * know how many priorities we *really* need. We allocate one * for each possible weight. Not a big deal, as collating-elements * prove to be quite rare. */ for (i = 0; i < COLL_WEIGHTS_MAX; i++) { e->ref[i] = new_pri(); } /* A character sequence can only reduce to one element. */ if ((avl_find(&elem_by_symbol, e, &where1) != NULL) || (avl_find(&elem_by_expand, e, &where2) != NULL)) { errf(_("duplicate collating element definition")); return; } avl_insert(&elem_by_symbol, e, where1); avl_insert(&elem_by_expand, e, where2); } void add_order_bit(int kw) { uint8_t bit = DIRECTIVE_UNDEF; switch (kw) { case T_FORWARD: bit = DIRECTIVE_FORWARD; break; case T_BACKWARD: bit = DIRECTIVE_BACKWARD; break; case T_POSITION: bit = DIRECTIVE_POSITION; break; default: INTERR; break; } collinfo.directive[collinfo.directive_count] |= bit; } void add_order_directive(void) { if (collinfo.directive_count >= COLL_WEIGHTS_MAX) { errf(_("too many directives (max %d)"), COLL_WEIGHTS_MAX); } collinfo.directive_count++; } static void add_order_pri(int32_t ref) { if (curr_weight >= NUM_WT) { errf(_("too many weights (max %d)"), NUM_WT); return; } order_weights[curr_weight] = ref; curr_weight++; } void add_order_collsym(collsym_t *s) { add_order_pri(s->ref); } void add_order_char(wchar_t wc) { collchar_t *cc; if ((cc = get_collchar(wc, 1)) == NULL) { INTERR; return; } add_order_pri(cc->ref[curr_weight]); } void add_order_collelem(collelem_t *e) { add_order_pri(e->ref[curr_weight]); } void add_order_ignore(void) { add_order_pri(pri_ignore); } void add_order_symbol(char *sym) { collundef_t *c; if ((c = get_collundef(sym)) == NULL) { INTERR; return; } add_order_pri(c->ref[curr_weight]); } void add_order_ellipsis(void) { /* special NULL value indicates self reference */ add_order_pri(NULL); } void add_order_subst(void) { subst_t srch; subst_t *s; avl_index_t where; int i; (void) memset(&srch, 0, sizeof (srch)); for (i = 0; i < curr_subst; i++) { srch.ref[i] = subst_weights[i]; subst_weights[i] = 0; } s = avl_find(&substs_ref[curr_weight], &srch, &where); if (s == NULL) { if ((s = calloc(sizeof (*s), 1)) == NULL) { errf(_("out of memory")); return; } s->key = new_pri(); /* * We use a self reference for our key, but we set a * high bit to indicate that this is a substitution * reference. This will expedite table lookups later, * and prevent table lookups for situations that don't * require it. (In short, its a big win, because we * can skip a lot of binary searching.) */ set_pri(s->key, (nextsubst[curr_weight] | COLLATE_SUBST_PRIORITY), RESOLVED); nextsubst[curr_weight] += 1; for (i = 0; i < curr_subst; i++) { s->ref[i] = srch.ref[i]; } avl_insert(&substs_ref[curr_weight], s, where); if (avl_find(&substs[curr_weight], s, &where) != NULL) { INTERR; return; } avl_insert(&substs[curr_weight], s, where); } curr_subst = 0; /* * We are using the current (unique) priority as a search key * in the substitution table. */ add_order_pri(s->key); } static void add_subst_pri(int32_t ref) { if (curr_subst >= COLLATE_STR_LEN) { errf(_("substitution string is too long")); return; } subst_weights[curr_subst] = ref; curr_subst++; } void add_subst_char(wchar_t wc) { collchar_t *cc; if (((cc = get_collchar(wc, 1)) == NULL) || (cc->wc != wc)) { INTERR; return; } /* we take the weight for the character at that position */ add_subst_pri(cc->ref[curr_weight]); } void add_subst_collelem(collelem_t *e) { add_subst_pri(e->ref[curr_weight]); } void add_subst_collsym(collsym_t *s) { add_subst_pri(s->ref); } void add_subst_symbol(char *ptr) { collundef_t *cu; if ((cu = get_collundef(ptr)) != NULL) { add_subst_pri(cu->ref[curr_weight]); } } void add_weight(int32_t ref, int pass) { weight_t srch; weight_t *w; avl_index_t where; srch.pri = resolve_pri(ref); /* No translation of ignores */ if (srch.pri == 0) return; /* Substitution priorities are not weights */ if (srch.pri & COLLATE_SUBST_PRIORITY) return; if (avl_find(&weights[pass], &srch, &where) != NULL) return; if ((w = calloc(sizeof (*w), 1)) == NULL) { errf(_("out of memory")); return; } w->pri = srch.pri; avl_insert(&weights[pass], w, where); } void add_weights(int32_t *refs) { int i; for (i = 0; i < NUM_WT; i++) { add_weight(refs[i], i); } } int32_t get_weight(int32_t ref, int pass) { weight_t srch; weight_t *w; int32_t pri; pri = resolve_pri(ref); if (pri & COLLATE_SUBST_PRIORITY) { return (pri); } if (pri <= 0) { return (pri); } srch.pri = pri; if ((w = avl_find(&weights[pass], &srch, NULL)) == NULL) { INTERR; return (-1); } return (w->opt); } void dump_collate(void) { FILE *f; int i, j, n; size_t sz; int32_t pri; collelem_t *ce; collchar_t *cc; subst_t *sb; char vers[COLLATE_STR_LEN]; collate_char_t chars[UCHAR_MAX + 1]; collate_large_t *large; collate_subst_t *subst[COLL_WEIGHTS_MAX]; collate_chain_t *chain; /* * We have to run throught a preliminary pass to identify all the * weights that we use for each sorting level. */ for (i = 0; i < NUM_WT; i++) { add_weight(pri_ignore, i); } for (i = 0; i < NUM_WT; i++) { for (sb = avl_first(&substs[i]); sb; sb = AVL_NEXT(&substs[i], sb)) { for (j = 0; sb->ref[j]; j++) { add_weight(sb->ref[j], i); } } } for (ce = avl_first(&elem_by_expand); ce != NULL; ce = AVL_NEXT(&elem_by_expand, ce)) { add_weights(ce->ref); } for (cc = avl_first(&collchars); cc; cc = AVL_NEXT(&collchars, cc)) { add_weights(cc->ref); } /* * Now we walk the entire set of weights, removing the gaps * in the weights. This gives us optimum usage. The walk * occurs in priority. */ for (i = 0; i < NUM_WT; i++) { weight_t *w; for (w = avl_first(&weights[i]); w; w = AVL_NEXT(&weights[i], w)) { w->opt = nweight[i]; nweight[i] += 1; } } (void) memset(&chars, 0, sizeof (chars)); (void) memset(vers, 0, COLLATE_STR_LEN); (void) strlcpy(vers, COLLATE_VERSION, sizeof (vers)); /* * We need to make sure we arrange for the UNDEFINED field * to show up. Also, set the total weight counts. */ for (i = 0; i < NUM_WT; i++) { if (resolve_pri(pri_undefined[i]) == -1) { set_pri(pri_undefined[i], -1, RESOLVED); /* they collate at the end of everything else */ collinfo.undef_pri[i] = COLLATE_MAX_PRIORITY; } collinfo.pri_count[i] = nweight[i]; } collinfo.pri_count[NUM_WT] = max_wide(); collinfo.undef_pri[NUM_WT] = COLLATE_MAX_PRIORITY; collinfo.directive[NUM_WT] = DIRECTIVE_UNDEFINED; /* * Ordinary character priorities */ for (i = 0; i <= UCHAR_MAX; i++) { if ((cc = get_collchar(i, 0)) != NULL) { for (j = 0; j < NUM_WT; j++) { chars[i].pri[j] = get_weight(cc->ref[j], j); } } else { for (j = 0; j < NUM_WT; j++) { chars[i].pri[j] = get_weight(pri_undefined[j], j); } /* * Per POSIX, for undefined characters, we * also have to add a last item, which is the * character code. */ chars[i].pri[NUM_WT] = i; } } /* * Substitution tables */ for (i = 0; i < NUM_WT; i++) { collate_subst_t *st = NULL; n = collinfo.subst_count[i] = avl_numnodes(&substs[i]); if ((st = calloc(sizeof (collate_subst_t) * n, 1)) == NULL) { errf(_("out of memory")); return; } n = 0; for (sb = avl_first(&substs[i]); sb; sb = AVL_NEXT(&substs[i], sb)) { if ((st[n].key = resolve_pri(sb->key)) < 0) { /* by definition these resolve! */ INTERR; } if (st[n].key != (n | COLLATE_SUBST_PRIORITY)) { INTERR; } for (j = 0; sb->ref[j]; j++) { st[n].pri[j] = get_weight(sb->ref[j], i); } n++; } if (n != collinfo.subst_count[i]) INTERR; subst[i] = st; } /* * Chains, i.e. collating elements */ collinfo.chain_count = avl_numnodes(&elem_by_expand); chain = calloc(sizeof (collate_chain_t), collinfo.chain_count); if (chain == NULL) { errf(_("out of memory")); return; } for (n = 0, ce = avl_first(&elem_by_expand); ce != NULL; ce = AVL_NEXT(&elem_by_expand, ce), n++) { (void) wsncpy(chain[n].str, ce->expand, COLLATE_STR_LEN); for (i = 0; i < NUM_WT; i++) { chain[n].pri[i] = get_weight(ce->ref[i], i); } } if (n != collinfo.chain_count) INTERR; /* * Large (> UCHAR_MAX) character priorities */ large = calloc(sizeof (collate_large_t) * avl_numnodes(&collchars), 1); if (large == NULL) { errf(_("out of memory")); return; } i = 0; for (cc = avl_first(&collchars); cc; cc = AVL_NEXT(&collchars, cc)) { int undef = 0; /* we already gathered those */ if (cc->wc <= UCHAR_MAX) continue; for (j = 0; j < NUM_WT; j++) { if ((pri = get_weight(cc->ref[j], j)) < 0) { undef = 1; } if (undef && (pri >= 0)) { /* if undefined, then all priorities are */ INTERR; } else { large[i].pri.pri[j] = pri; } } if (!undef) { large[i].val = cc->wc; collinfo.large_count = i++; } } if ((f = open_category()) == NULL) { return; } /* Time to write the entire data set out */ if ((wr_category(vers, COLLATE_STR_LEN, f) < 0) || (wr_category(&collinfo, sizeof (collinfo), f) < 0) || (wr_category(&chars, sizeof (chars), f) < 0)) { return; } for (i = 0; i < NUM_WT; i++) { sz = sizeof (collate_subst_t) * collinfo.subst_count[i]; if (wr_category(subst[i], sz, f) < 0) { return; } } sz = sizeof (collate_chain_t) * collinfo.chain_count; if (wr_category(chain, sz, f) < 0) { return; } sz = sizeof (collate_large_t) * collinfo.large_count; if (wr_category(large, sz, f) < 0) { return; } close_category(f); }