/* $Id: d1_read.c,v 1.8.2.1 2005/01/17 22:12:51 adam Exp $ Copyright (C) 1995,1996,1997,1998,1999,2000,2001,2002,2003,2004 Index Data Aps This file is part of the Zebra server. Zebra is free software; you can redistribute it and/or modify it under the terms of the GNU General Public License as published by the Free Software Foundation; either version 2, or (at your option) any later version. Zebra 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 General Public License for more details. You should have received a copy of the GNU General Public License along with Zebra; see the file LICENSE.zebra. If not, write to the Free Software Foundation, 59 Temple Place - Suite 330, Boston, MA 02111-1307, USA. */ /* * This module reads "loose" SGML and converts it to data1 tree */ #include #include #include #include #include #include #include data1_node *data1_get_root_tag (data1_handle dh, data1_node *n) { if (!n) return 0; if (data1_is_xmlmode(dh)) { n = n->child; while (n && n->which != DATA1N_tag) n = n->next; } return n; } /* * get the tag which is the immediate parent of this node (this may mean * traversing intermediate things like variants and stuff. */ data1_node *get_parent_tag (data1_handle dh, data1_node *n) { if (data1_is_xmlmode(dh)) { for (; n && n->which != DATA1N_root; n = n->parent) if (n->which == DATA1N_tag && n->parent && n->parent->which != DATA1N_root) return n; } else { for (; n && n->which != DATA1N_root; n = n->parent) if (n->which == DATA1N_tag) return n; } return 0; } data1_node *data1_mk_node (data1_handle dh, NMEM m) { return data1_mk_node2 (dh, m, DATA1N_root, 0); } data1_node *data1_mk_node_type (data1_handle dh, NMEM m, int type) { return data1_mk_node2 (dh, m, type, 0); } static void data1_init_node (data1_handle dh, data1_node *r, int type) { r->which = type; switch(type) { case DATA1N_tag: r->u.tag.tag = 0; r->u.tag.element = 0; r->u.tag.no_data_requested = 0; r->u.tag.node_selected = 0; r->u.tag.make_variantlist = 0; r->u.tag.get_bytes = -1; r->u.tag.attributes = 0; break; case DATA1N_root: r->u.root.type = 0; r->u.root.absyn = 0; break; case DATA1N_data: r->u.data.data = 0; r->u.data.len = 0; r->u.data.what = 0; r->u.data.formatted_text = 0; break; case DATA1N_comment: r->u.data.data = 0; r->u.data.len = 0; r->u.data.what = 0; r->u.data.formatted_text = 1; break; case DATA1N_variant: r->u.variant.type = 0; r->u.variant.value = 0; break; case DATA1N_preprocess: r->u.preprocess.target = 0; r->u.preprocess.attributes = 0; break; default: logf (LOG_WARN, "data_mk_node_type. bad type = %d\n", type); } } data1_node *data1_append_node (data1_handle dh, NMEM m, int type, data1_node *parent) { data1_node *r = (data1_node *)nmem_malloc(m, sizeof(*r)); r->next = r->child = r->last_child = 0; r->destroy = 0; r->parent = parent; if (!parent) r->root = r; else { r->root = parent->root; if (!parent->child) parent->child = parent->last_child = r; else parent->last_child->next = r; parent->last_child = r; } data1_init_node(dh, r, type); return r; } data1_node *data1_mk_node2 (data1_handle dh, NMEM m, int type, data1_node *parent) { return data1_append_node (dh, m, type, parent); } data1_node *data1_insert_node (data1_handle dh, NMEM m, int type, data1_node *parent) { data1_node *r = (data1_node *)nmem_malloc(m, sizeof(*r)); r->next = r->child = r->last_child = 0; r->destroy = 0; if (!parent) r->root = r; else { r->root = parent->root; r->parent = parent; if (!parent->child) parent->last_child = r; else r->next = parent->child; parent->child = r; } data1_init_node(dh, r, type); return r; } void data1_free_tree (data1_handle dh, data1_node *t) { data1_node *p = t->child, *pn; while (p) { pn = p->next; data1_free_tree (dh, p); p = pn; } if (t->destroy) (*t->destroy)(t); } data1_node *data1_mk_root (data1_handle dh, NMEM nmem, const char *name) { data1_absyn *absyn = data1_get_absyn (dh, name); data1_node *res; if (!absyn) { yaz_log(LOG_WARN, "Unable to acquire abstract syntax " "for '%s'", name); /* It's now OK for a record not to have an absyn */ } res = data1_mk_node2 (dh, nmem, DATA1N_root, 0); res->u.root.type = data1_insert_string (dh, res, nmem, name); res->u.root.absyn = absyn; return res; } void data1_set_root(data1_handle dh, data1_node *res, NMEM nmem, const char *name) { data1_absyn *absyn = data1_get_absyn (dh, name); res->u.root.type = data1_insert_string (dh, res, nmem, name); res->u.root.absyn = absyn; } void data1_add_attrs(data1_handle dh, NMEM nmem, const char **attr, data1_xattr **p) { while (*p) p = &(*p)->next; while (attr && *attr) { *p = (data1_xattr*) nmem_malloc (nmem, sizeof(**p)); (*p)->name = nmem_strdup (nmem, *attr++); (*p)->value = nmem_strdup (nmem, *attr++); (*p)->what = DATA1I_text; p = &(*p)->next; } *p = 0; } data1_node *data1_mk_preprocess (data1_handle dh, NMEM nmem, const char *target, const char **attr, data1_node *at) { return data1_mk_preprocess_n (dh, nmem, target, strlen(target), attr, at); } data1_node *data1_mk_preprocess_n (data1_handle dh, NMEM nmem, const char *target, size_t len, const char **attr, data1_node *at) { data1_node *res = data1_mk_node2 (dh, nmem, DATA1N_preprocess, at); res->u.preprocess.target = data1_insert_string_n (dh, res, nmem, target, len); data1_add_attrs(dh, nmem, attr, &res->u.preprocess.attributes); return res; } data1_node *data1_insert_preprocess (data1_handle dh, NMEM nmem, const char *target, const char **attr, data1_node *at) { return data1_insert_preprocess_n (dh, nmem, target, strlen(target), attr, at); } data1_node *data1_insert_preprocess_n (data1_handle dh, NMEM nmem, const char *target, size_t len, const char **attr, data1_node *at) { data1_node *res = data1_insert_node (dh, nmem, DATA1N_preprocess, at); res->u.preprocess.target = data1_insert_string_n (dh, res, nmem, target, len); data1_add_attrs(dh, nmem, attr, &res->u.preprocess.attributes); return res; } data1_node *data1_mk_tag_n (data1_handle dh, NMEM nmem, const char *tag, size_t len, const char **attr, data1_node *at) { data1_node *partag = get_parent_tag(dh, at); data1_node *res = data1_mk_node2 (dh, nmem, DATA1N_tag, at); data1_element *e = 0; res->u.tag.tag = data1_insert_string_n (dh, res, nmem, tag, len); if (!partag) /* top tag? */ e = data1_getelementbytagname (dh, at->root->u.root.absyn, 0 /* index as local */, res->u.tag.tag); else { /* only set element for known tags */ e = partag->u.tag.element; if (e) e = data1_getelementbytagname (dh, at->root->u.root.absyn, e, res->u.tag.tag); } res->u.tag.element = e; data1_add_attrs(dh, nmem, attr, &res->u.tag.attributes); return res; } void data1_tag_add_attr (data1_handle dh, NMEM nmem, data1_node *res, const char **attr) { if (res->which != DATA1N_tag) return; data1_add_attrs(dh, nmem, attr, &res->u.tag.attributes); } data1_node *data1_mk_tag (data1_handle dh, NMEM nmem, const char *tag, const char **attr, data1_node *at) { return data1_mk_tag_n (dh, nmem, tag, strlen(tag), attr, at); } data1_node *data1_search_tag (data1_handle dh, data1_node *n, const char *tag) { if (*tag == '/') { n = data1_get_root_tag (dh, n); if (n) n = n->child; tag++; } for (; n; n = n->next) if (n->which == DATA1N_tag && n->u.tag.tag && !yaz_matchstr (n->u.tag.tag, tag)) { return n; } return 0; } data1_node *data1_mk_tag_uni (data1_handle dh, NMEM nmem, const char *tag, data1_node *at) { data1_node *node = data1_search_tag (dh, at->child, tag); if (!node) node = data1_mk_tag (dh, nmem, tag, 0 /* attr */, at); else node->child = node->last_child = 0; return node; } data1_node *data1_mk_text_n (data1_handle dh, NMEM mem, const char *buf, size_t len, data1_node *parent) { data1_node *res = data1_mk_node2 (dh, mem, DATA1N_data, parent); res->u.data.what = DATA1I_text; res->u.data.len = len; res->u.data.data = data1_insert_string_n (dh, res, mem, buf, len); return res; } data1_node *data1_mk_text_nf (data1_handle dh, NMEM mem, const char *buf, size_t len, data1_node *parent) { data1_node *res = data1_mk_text_n (dh, mem, buf, len, parent); res->u.data.formatted_text = 1; return res; } data1_node *data1_mk_text (data1_handle dh, NMEM mem, const char *buf, data1_node *parent) { return data1_mk_text_n (dh, mem, buf, strlen(buf), parent); } data1_node *data1_mk_comment_n (data1_handle dh, NMEM mem, const char *buf, size_t len, data1_node *parent) { data1_node *res = data1_mk_node2 (dh, mem, DATA1N_comment, parent); res->u.data.what = DATA1I_text; res->u.data.len = len; res->u.data.data = data1_insert_string_n (dh, res, mem, buf, len); return res; } data1_node *data1_mk_comment (data1_handle dh, NMEM mem, const char *buf, data1_node *parent) { return data1_mk_comment_n (dh, mem, buf, strlen(buf), parent); } char *data1_insert_string_n (data1_handle dh, data1_node *res, NMEM m, const char *str, size_t len) { char *b; if (len >= DATA1_LOCALDATA) b = (char *) nmem_malloc (m, len+1); else b = res->lbuf; memcpy (b, str, len); b[len] = 0; return b; } char *data1_insert_string (data1_handle dh, data1_node *res, NMEM m, const char *str) { return data1_insert_string_n (dh, res, m, str, strlen(str)); } static data1_node *data1_add_insert_taggeddata(data1_handle dh, data1_node *at, const char *tagname, NMEM m, int local_allowed, int insert_mode) { data1_node *root = at->root; data1_node *partag = get_parent_tag (dh, at); data1_element *e = NULL; data1_node *datn = 0; data1_node *tagn = 0; if (!partag) e = data1_getelementbytagname (dh, root->u.root.absyn, 0, tagname); else { e = partag->u.tag.element; if (e) e = data1_getelementbytagname (dh, root->u.root.absyn, e, tagname); } if (local_allowed || e) { if (insert_mode) tagn = data1_insert_node (dh, m, DATA1N_tag, at); else tagn = data1_append_node (dh, m, DATA1N_tag, at); tagn->u.tag.tag = data1_insert_string (dh, tagn, m, tagname); tagn->u.tag.element = e; datn = data1_mk_node2 (dh, m, DATA1N_data, tagn); } return datn; } data1_node *data1_mk_tag_data(data1_handle dh, data1_node *at, const char *tagname, NMEM m) { return data1_add_insert_taggeddata (dh, at, tagname, m, 1, 0); } /* * Insert a tagged node into the record root as first child of the node at * which should be root or tag itself). Returns pointer to the data node, * which can then be modified. */ data1_node *data1_mk_tag_data_wd(data1_handle dh, data1_node *at, const char *tagname, NMEM m) { return data1_add_insert_taggeddata (dh, at, tagname, m, 0, 1); } data1_node *data1_insert_taggeddata (data1_handle dh, data1_node *root, data1_node *at, const char *tagname, NMEM m) { return data1_add_insert_taggeddata (dh, at, tagname, m, 0, 1); } data1_node *data1_add_taggeddata (data1_handle dh, data1_node *root, data1_node *at, const char *tagname, NMEM m) { return data1_add_insert_taggeddata (dh, at, tagname, m, 1, 0); } data1_node *data1_mk_tag_data_int (data1_handle dh, data1_node *at, const char *tag, int num, NMEM nmem) { data1_node *node_data; node_data = data1_mk_tag_data (dh, at, tag, nmem); if (!node_data) return 0; node_data->u.data.what = DATA1I_num; node_data->u.data.data = node_data->lbuf; sprintf (node_data->u.data.data, "%d", num); node_data->u.data.len = strlen (node_data->u.data.data); return node_data; } data1_node *data1_mk_tag_data_oid (data1_handle dh, data1_node *at, const char *tag, Odr_oid *oid, NMEM nmem) { data1_node *node_data; char str[128], *p = str; Odr_oid *ii; node_data = data1_mk_tag_data (dh, at, tag, nmem); if (!node_data) return 0; for (ii = oid; *ii >= 0; ii++) { if (ii != oid) *p++ = '.'; sprintf (p, "%d", *ii); p += strlen (p); } node_data->u.data.what = DATA1I_oid; node_data->u.data.len = strlen (str); node_data->u.data.data = data1_insert_string (dh, node_data, nmem, str); return node_data; } data1_node *data1_mk_tag_data_text (data1_handle dh, data1_node *at, const char *tag, const char *str, NMEM nmem) { data1_node *node_data; node_data = data1_mk_tag_data (dh, at, tag, nmem); if (!node_data) return 0; node_data->u.data.what = DATA1I_text; node_data->u.data.len = strlen (str); node_data->u.data.data = data1_insert_string (dh, node_data, nmem, str); return node_data; } data1_node *data1_mk_tag_data_text_uni (data1_handle dh, data1_node *at, const char *tag, const char *str, NMEM nmem) { data1_node *node = data1_search_tag (dh, at->child, tag); if (!node) return data1_mk_tag_data_text (dh, at, tag, str, nmem); else { data1_node *node_data = node->child; node_data->u.data.what = DATA1I_text; node_data->u.data.len = strlen (str); node_data->u.data.data = data1_insert_string (dh, node_data, nmem, str); node_data->child = node_data->last_child = 0; return node_data; } } static int ampr (int (*get_byte)(void *fh), void *fh, int *amp) { #if 1 int c = (*get_byte)(fh); *amp = 0; return c; #else int c = (*get_byte)(fh); *amp = 0; if (c == '&') { char ent[20]; int i = 0; while (1) { c = (*get_byte)(fh); if (c == ';') { ent[i] = 0; c = ' '; if (!strcmp (ent, "quot")) c = '"'; if (!strcmp (ent, "apos")) c = '\''; if (!strcmp (ent, "gt")) c = '>'; if (!strcmp (ent, "lt")) c = '<'; if (!strcmp (ent, "amp")) c = '&'; *amp = 1; break; } else if (c == 0 || d1_isspace(c)) break; if (i < 19) ent[i++] = c; } } return c; #endif } data1_xattr *data1_read_xattr (data1_handle dh, NMEM m, int (*get_byte)(void *fh), void *fh, WRBUF wrbuf, int *ch, int *amp) { data1_xattr *p_first = 0; data1_xattr **pp = &p_first; int c = *ch; for (;;) { data1_xattr *p; int len; while (*amp || (c && d1_isspace(c))) c = ampr (get_byte, fh, amp); if (*amp == 0 && (c == 0 || c == '>' || c == '/')) break; *pp = p = (data1_xattr *) nmem_malloc (m, sizeof(*p)); p->next = 0; pp = &p->next; p->value = 0; p->what = DATA1I_xmltext; wrbuf_rewind(wrbuf); while (c && c != '=' && c != '>' && c != '/' && !d1_isspace(c)) { wrbuf_putc (wrbuf, c); c = ampr (get_byte, fh, amp); } wrbuf_putc (wrbuf, '\0'); len = wrbuf_len(wrbuf); p->name = (char*) nmem_malloc (m, len); strcpy (p->name, wrbuf_buf(wrbuf)); if (c == '=') { c = ampr (get_byte, fh, amp); if (*amp == 0 && c == '"') { c = ampr (get_byte, fh, amp); wrbuf_rewind(wrbuf); while (*amp || (c && c != '"')) { wrbuf_putc (wrbuf, c); c = ampr (get_byte, fh, amp); } if (c) c = ampr (get_byte, fh, amp); } else if (*amp == 0 && c == '\'') { c = ampr (get_byte, fh, amp); wrbuf_rewind(wrbuf); while (*amp || (c && c != '\'')) { wrbuf_putc (wrbuf, c); c = ampr (get_byte, fh, amp); } if (c) c = ampr (get_byte, fh, amp); } else { wrbuf_rewind(wrbuf); while (*amp || (c && c != '>' && c != '/')) { wrbuf_putc (wrbuf, c); c = ampr (get_byte, fh, amp); } } wrbuf_putc (wrbuf, '\0'); len = wrbuf_len(wrbuf); p->value = (char*) nmem_malloc (m, len); strcpy (p->value, wrbuf_buf(wrbuf)); } } *ch = c; return p_first; } /* * Ugh. Sometimes functions just grow and grow on you. This one reads a * 'node' and its children. */ data1_node *data1_read_nodex (data1_handle dh, NMEM m, int (*get_byte)(void *fh), void *fh, WRBUF wrbuf) { data1_node *d1_stack[256]; data1_node *res; int c, amp; int level = 0; int line = 1; d1_stack[level] = 0; c = ampr (get_byte, fh, &); while (c != '\0') { data1_node *parent = level ? d1_stack[level-1] : 0; if (amp == 0 && c == '<') /* beginning of tag */ { data1_xattr *xattr; char tag[64]; char args[256]; int null_tag = 0; int end_tag = 0; size_t i = 0; c = ampr (get_byte, fh, &); if (amp == 0 && c == '/') { end_tag = 1; c = ampr (get_byte, fh, &); } else if (amp == 0 && c == '!') { int c0, amp0; wrbuf_rewind(wrbuf); c0 = ampr (get_byte, fh, &0); if (amp0 == 0 && c0 == '\0') break; c = ampr (get_byte, fh, &); if (amp0 == 0 && c0 == '-' && amp == 0 && c == '-') { /* COMMENT: */ int no_dash = 0; c = ampr (get_byte, fh, &); while (amp || c) { if (amp == 0 && c == '-') no_dash++; else if (amp == 0 && c == '>' && no_dash >= 2) { if (level > 0) d1_stack[level] = data1_mk_comment_n ( dh, m, wrbuf_buf(wrbuf), wrbuf_len(wrbuf)-2, d1_stack[level-1]); c = ampr (get_byte, fh, &); /* skip > */ break; } else no_dash = 0; wrbuf_putc (wrbuf, c); c = ampr (get_byte, fh, &); } continue; } else { /* DIRECTIVE: */ int blevel = 0; while (amp || c) { if (amp == 0 && c == '>' && blevel == 0) { c = ampr (get_byte, fh, &); break; } if (amp == 0 && c == '[') blevel++; if (amp == 0 && c == ']' && blevel > 0) blevel--; c = ampr (get_byte, fh, &); } continue; } } while (amp || (c && c != '>' && c != '/' && !d1_isspace(c))) { if (i < (sizeof(tag)-1)) tag[i++] = c; c = ampr (get_byte, fh, &); } tag[i] = '\0'; xattr = data1_read_xattr (dh, m, get_byte, fh, wrbuf, &c, &); args[0] = '\0'; if (amp == 0 && c == '/') { /* or */ null_tag = 1; c = ampr (get_byte, fh, &); } if (amp || c != '>') { yaz_log(LOG_WARN, "d1: %d: Malformed tag", line); return 0; } else c = ampr (get_byte, fh, &); /* End tag? */ if (end_tag) { if (*tag == '\0') --level; /* */ else { /* */ int i = level; while (i > 0) { parent = d1_stack[--i]; if ((parent->which == DATA1N_root && !strcmp(tag, parent->u.root.type)) || (parent->which == DATA1N_tag && !strcmp(tag, parent->u.tag.tag))) { level = i; break; } } if (i != level) { yaz_log (LOG_WARN, "%d: no begin tag for %s", line, tag); break; } } if (data1_is_xmlmode(dh)) { if (level <= 1) return d1_stack[0]; } else { if (level <= 0) return d1_stack[0]; } continue; } else if (!strcmp(tag, "var")) { char tclass[DATA1_MAX_SYMBOL], type[DATA1_MAX_SYMBOL]; data1_vartype *tp; int val_offset; if (sscanf(args, "%s %s %n", tclass, type, &val_offset) != 2) { yaz_log(LOG_WARN, "Malformed variant triple at '%s'", tag); continue; } if (!(tp = data1_getvartypebyct(dh, parent->root->u.root.absyn->varset, tclass, type))) continue; /* * If we're the first variant in this group, create a parent * variant, and insert it before the current variant. */ if (parent->which != DATA1N_variant) { res = data1_mk_node2 (dh, m, DATA1N_variant, parent); } else { /* * now determine if one of our ancestor triples is of * same type. If so, we break here. */ int i; for (i = level-1; d1_stack[i]->which==DATA1N_variant; --i) if (d1_stack[i]->u.variant.type == tp) { level = i; break; } res = data1_mk_node2 (dh, m, DATA1N_variant, parent); res->u.variant.type = tp; res->u.variant.value = data1_insert_string (dh, res, m, args + val_offset); } } else { /* tag .. acquire our element in the abstract syntax */ if (level == 0) { parent = data1_mk_root (dh, m, tag); res = d1_stack[level] = parent; if (data1_is_xmlmode(dh)) { level++; res = data1_mk_tag (dh, m, tag, 0 /* attr */, parent); res->u.tag.attributes = xattr; } } else { res = data1_mk_tag (dh, m, tag, 0 /* attr */, parent); res->u.tag.attributes = xattr; } } d1_stack[level] = res; d1_stack[level+1] = 0; if (level < 250 && !null_tag) ++level; } else /* != '<'... this is a body of text */ { int len; if (level == 0) { c = ampr (get_byte, fh, &); continue; } res = data1_mk_node2 (dh, m, DATA1N_data, parent); res->u.data.what = DATA1I_xmltext; res->u.data.formatted_text = 0; d1_stack[level] = res; wrbuf_rewind(wrbuf); while (amp || (c && c != '<')) { wrbuf_putc (wrbuf, c); c = ampr (get_byte, fh, &); } len = wrbuf_len(wrbuf); /* use local buffer of nmem if too large */ if (len >= DATA1_LOCALDATA) res->u.data.data = (char*) nmem_malloc (m, len); else res->u.data.data = res->lbuf; if (len) memcpy (res->u.data.data, wrbuf_buf(wrbuf), len); else res->u.data.data = 0; res->u.data.len = len; } } return 0; } int getc_mem (void *fh) { const char **p = (const char **) fh; if (**p) return *(*p)++; return 0; } data1_node *data1_read_node (data1_handle dh, const char **buf, NMEM m) { WRBUF wrbuf = wrbuf_alloc(); data1_node *node; node = data1_read_nodex(dh, m, getc_mem, (void *) (buf), wrbuf); wrbuf_free (wrbuf, 1); return node; } /* * Read a record in the native syntax. */ data1_node *data1_read_record(data1_handle dh, int (*rf)(void *, char *, size_t), void *fh, NMEM m) { int *size; char **buf = data1_get_read_buf (dh, &size); const char *bp; int rd = 0, res; if (!*buf) *buf = (char *)xmalloc(*size = 4096); for (;;) { if (rd + 2048 >= *size && !(*buf =(char *)xrealloc(*buf, *size *= 2))) abort(); if ((res = (*rf)(fh, *buf + rd, 2048)) <= 0) { if (!res) { bp = *buf; (*buf)[rd] = '\0'; return data1_read_node(dh, &bp, m); } else return 0; } rd += res; } } data1_node *data1_read_sgml (data1_handle dh, NMEM m, const char *buf) { const char *bp = buf; return data1_read_node (dh, &bp, m); } static int conv_item (NMEM m, yaz_iconv_t t, WRBUF wrbuf, char *inbuf, size_t inlen) { wrbuf_rewind (wrbuf); if (wrbuf->size < 10) wrbuf_grow (wrbuf, 10); for (;;) { char *outbuf = wrbuf->buf + wrbuf->pos; size_t outlen = wrbuf->size - wrbuf->pos; if (yaz_iconv (t, &inbuf, &inlen, &outbuf, &outlen) == (size_t)(-1) && yaz_iconv_error(t) != YAZ_ICONV_E2BIG) { /* bad data. stop and skip conversion entirely */ return -1; } else if (inlen == 0) { /* finished converting */ wrbuf->pos = wrbuf->size - outlen; break; } else { /* buffer too small: make sure we expand buffer */ wrbuf->pos = wrbuf->size - outlen; wrbuf_grow(wrbuf, 20); } } return 0; } static void data1_iconv_s (data1_handle dh, NMEM m, data1_node *n, yaz_iconv_t t, WRBUF wrbuf, const char *tocode) { for (; n; n = n->next) { switch (n->which) { case DATA1N_data: case DATA1N_comment: if (conv_item (m, t, wrbuf, n->u.data.data, n->u.data.len) == 0) { n->u.data.data = data1_insert_string_n (dh, n, m, wrbuf->buf, wrbuf->pos); n->u.data.len = wrbuf->pos; } break; case DATA1N_tag: if (conv_item (m, t, wrbuf, n->u.tag.tag, strlen(n->u.tag.tag)) == 0) { n->u.tag.tag = data1_insert_string_n (dh, n, m, wrbuf->buf, wrbuf->pos); } if (n->u.tag.attributes) { data1_xattr *p; for (p = n->u.tag.attributes; p; p = p->next) { if (p->value && conv_item(m, t, wrbuf, p->value, strlen(p->value)) == 0) { wrbuf_puts (wrbuf, ""); p->value = nmem_strdup (m, wrbuf->buf); } } } break; case DATA1N_preprocess: if (strcmp(n->u.preprocess.target, "xml") == 0) { data1_xattr *p = n->u.preprocess.attributes; for (; p; p = p->next) if (strcmp (p->name, "encoding") == 0) p->value = nmem_strdup (m, tocode); } break; } data1_iconv_s (dh, m, n->child, t, wrbuf, tocode); } } const char *data1_get_encoding (data1_handle dh, data1_node *n) { /* see if we have an xml header that specifies encoding */ if (n && n->child && n->child->which == DATA1N_preprocess && strcmp (n->child->u.preprocess.target, "xml") == 0) { data1_xattr *xp = n->child->u.preprocess.attributes; for (; xp; xp = xp->next) if (!strcmp (xp->name, "encoding") == 0) return xp->value; } /* no encoding in header, so see if "encoding" was specified for abs */ if (n && n->which == DATA1N_root && n->u.root.absyn && n->u.root.absyn->encoding) return n->u.root.absyn->encoding; /* none of above, return a hard coded default */ return "ISO-8859-1"; } int data1_iconv (data1_handle dh, NMEM m, data1_node *n, const char *tocode, const char *fromcode) { if (yaz_matchstr (tocode, fromcode)) { WRBUF wrbuf = wrbuf_alloc(); yaz_iconv_t t = yaz_iconv_open (tocode, fromcode); if (!t) { wrbuf_free(wrbuf, 1); return -1; } data1_iconv_s (dh, m, n, t, wrbuf, tocode); yaz_iconv_close (t); wrbuf_free (wrbuf, 1); } return 0; } void data1_concat_text(data1_handle dh, NMEM m, data1_node *n) { for (; n; n = n->next) { if (n->which == DATA1N_data && n->next && n->next->which == DATA1N_data) { int sz = 0; int off = 0; char *ndata; data1_node *np; for (np = n; np && np->which == DATA1N_data; np=np->next) sz += np->u.data.len; ndata = nmem_malloc(m, sz); for (np = n; np && np->which == DATA1N_data; np=np->next) { memcpy(ndata+off, np->u.data.data, np->u.data.len); off += np->u.data.len; } n->u.data.data = ndata; n->u.data.len = sz; n->next = np; if (!np && n->parent) n->parent->last_child = n; } data1_concat_text(dh, m, n->child); } }