/* Copyright (c) 2005, 2011, Oracle and/or its affiliates. This program 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; version 2 of the License. This program 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 this program; if not, write to the Free Software Foundation, Inc., 51 Franklin St, Fifth Floor, Boston, MA 02110-1301 USA */ #ifdef __GNUC__ #pragma implementation #endif #include "sql_priv.h" /* It is necessary to include set_var.h instead of item.h because there are dependencies on include order for set_var.h and item.h. This will be resolved later. */ #include "sql_class.h" // set_var.h: THD #include "set_var.h" #include "my_xml.h" #include "sp_pcontext.h" #include "sql_class.h" // THD /* TODO: future development directions: 1. add real constants for XPATH_NODESET_CMP and XPATH_NODESET into enum Type in item.h. 2. add nodeset_to_nodeset_comparator 3. add lacking functions: - name() - lang() - string() - id() - translate() - local-name() - starts-with() - namespace-uri() - substring-after() - normalize-space() - substring-before() 4. add lacking axis: - following-sibling - following, - preceding-sibling - preceding */ /* Structure to store a parsed XML tree */ typedef struct my_xml_node_st { uint level; /* level in XML tree, 0 means root node */ enum my_xml_node_type type; /* node type: node, or attribute, or text */ uint parent; /* link to the parent */ const char *beg; /* beginning of the name or text */ const char *end; /* end of the name or text */ const char *tagend; /* where this tag ends */ } MY_XML_NODE; /* Lexical analizer token */ typedef struct my_xpath_lex_st { int term; /* token type, see MY_XPATH_LEX_XXXXX below */ const char *beg; /* beginnign of the token */ const char *end; /* end of the token */ } MY_XPATH_LEX; /* Structure to store nodesets */ typedef struct my_xpath_flt_st { uint num; /* absolute position in MY_XML_NODE array */ uint pos; /* relative position in context */ uint size; /* context size */ } MY_XPATH_FLT; /* XPath function creator */ typedef struct my_xpath_function_names_st { const char *name; /* function name */ size_t length; /* function name length */ size_t minargs; /* min number of arguments */ size_t maxargs; /* max number of arguments */ Item *(*create)(struct my_xpath_st *xpath, Item **args, uint nargs); } MY_XPATH_FUNC; /* XPath query parser */ typedef struct my_xpath_st { int debug; MY_XPATH_LEX query; /* Whole query */ MY_XPATH_LEX lasttok; /* last scanned token */ MY_XPATH_LEX prevtok; /* previous scanned token */ int axis; /* last scanned axis */ int extra; /* last scanned "extra", context dependent */ MY_XPATH_FUNC *func; /* last scanned function creator */ Item *item; /* current expression */ Item *context; /* last scanned context */ Item *rootelement; /* The root element */ String *context_cache; /* last context provider */ String *pxml; /* Parsed XML, an array of MY_XML_NODE */ CHARSET_INFO *cs; /* character set/collation string comparison */ int error; } MY_XPATH; /* Dynamic array of MY_XPATH_FLT */ class XPathFilter :public String { public: XPathFilter() :String() {} inline bool append_element(MY_XPATH_FLT *flt) { String *str= this; return str->append((const char*)flt, (uint32) sizeof(MY_XPATH_FLT)); } inline bool append_element(uint32 num, uint32 pos) { MY_XPATH_FLT add; add.num= num; add.pos= pos; add.size= 0; return append_element(&add); } inline bool append_element(uint32 num, uint32 pos, uint32 size) { MY_XPATH_FLT add; add.num= num; add.pos= pos; add.size= size; return append_element(&add); } inline MY_XPATH_FLT *element(uint i) { return (MY_XPATH_FLT*) (ptr() + i * sizeof(MY_XPATH_FLT)); } inline uint32 numelements() { return length() / sizeof(MY_XPATH_FLT); } }; /* Common features of the functions returning a node set. */ class Item_nodeset_func :public Item_str_func { protected: String tmp_value, tmp2_value; MY_XPATH_FLT *fltbeg, *fltend; MY_XML_NODE *nodebeg, *nodeend; uint numnodes; public: String *pxml; String context_cache; Item_nodeset_func(String *pxml_arg) :Item_str_func(), pxml(pxml_arg) {} Item_nodeset_func(Item *a, String *pxml_arg) :Item_str_func(a), pxml(pxml_arg) {} Item_nodeset_func(Item *a, Item *b, String *pxml_arg) :Item_str_func(a, b), pxml(pxml_arg) {} Item_nodeset_func(Item *a, Item *b, Item *c, String *pxml_arg) :Item_str_func(a,b,c), pxml(pxml_arg) {} void prepare_nodes() { nodebeg= (MY_XML_NODE*) pxml->ptr(); nodeend= (MY_XML_NODE*) (pxml->ptr() + pxml->length()); numnodes= nodeend - nodebeg; } void prepare(String *nodeset) { prepare_nodes(); String *res= args[0]->val_nodeset(&tmp_value); fltbeg= (MY_XPATH_FLT*) res->ptr(); fltend= (MY_XPATH_FLT*) (res->ptr() + res->length()); nodeset->length(0); } enum Type type() const { return XPATH_NODESET; } String *val_str(String *str) { prepare_nodes(); String *res= val_nodeset(&tmp2_value); fltbeg= (MY_XPATH_FLT*) res->ptr(); fltend= (MY_XPATH_FLT*) (res->ptr() + res->length()); String active; active.alloc(numnodes); bzero((char*) active.ptr(), numnodes); for (MY_XPATH_FLT *flt= fltbeg; flt < fltend; flt++) { MY_XML_NODE *node; uint j; for (j=0, node= nodebeg ; j < numnodes; j++, node++) { if (node->type == MY_XML_NODE_TEXT && node->parent == flt->num) active[j]= 1; } } str->length(0); str->set_charset(collation.collation); for (uint i=0 ; i < numnodes; i++) { if(active[i]) { if (str->length()) str->append(" ", 1, &my_charset_latin1); str->append(nodebeg[i].beg, nodebeg[i].end - nodebeg[i].beg); } } return str; } enum Item_result result_type () const { return STRING_RESULT; } void fix_length_and_dec() { max_length= MAX_BLOB_WIDTH; collation.collation= pxml->charset(); } const char *func_name() const { return "nodeset"; } bool check_vcol_func_processor(uchar *int_arg) { return trace_unsupported_by_check_vcol_func_processor(func_name()); } }; /* Returns an XML root */ class Item_nodeset_func_rootelement :public Item_nodeset_func { public: Item_nodeset_func_rootelement(String *pxml): Item_nodeset_func(pxml) {} const char *func_name() const { return "xpath_rootelement"; } String *val_nodeset(String *nodeset); }; /* Returns a Union of two node sets */ class Item_nodeset_func_union :public Item_nodeset_func { public: Item_nodeset_func_union(Item *a, Item *b, String *pxml) :Item_nodeset_func(a, b, pxml) {} const char *func_name() const { return "xpath_union"; } String *val_nodeset(String *nodeset); }; /* Makes one step towards the given axis */ class Item_nodeset_func_axisbyname :public Item_nodeset_func { const char *node_name; uint node_namelen; public: Item_nodeset_func_axisbyname(Item *a, const char *n_arg, uint l_arg, String *pxml): Item_nodeset_func(a, pxml), node_name(n_arg), node_namelen(l_arg) { } const char *func_name() const { return "xpath_axisbyname"; } bool validname(MY_XML_NODE *n) { if (node_name[0] == '*') return 1; return (node_namelen == (uint) (n->end - n->beg)) && !memcmp(node_name, n->beg, node_namelen); } }; /* Returns self */ class Item_nodeset_func_selfbyname: public Item_nodeset_func_axisbyname { public: Item_nodeset_func_selfbyname(Item *a, const char *n_arg, uint l_arg, String *pxml): Item_nodeset_func_axisbyname(a, n_arg, l_arg, pxml) {} const char *func_name() const { return "xpath_selfbyname"; } String *val_nodeset(String *nodeset); }; /* Returns children */ class Item_nodeset_func_childbyname: public Item_nodeset_func_axisbyname { public: Item_nodeset_func_childbyname(Item *a, const char *n_arg, uint l_arg, String *pxml): Item_nodeset_func_axisbyname(a, n_arg, l_arg, pxml) {} const char *func_name() const { return "xpath_childbyname"; } String *val_nodeset(String *nodeset); }; /* Returns descendants */ class Item_nodeset_func_descendantbyname: public Item_nodeset_func_axisbyname { bool need_self; public: Item_nodeset_func_descendantbyname(Item *a, const char *n_arg, uint l_arg, String *pxml, bool need_self_arg): Item_nodeset_func_axisbyname(a, n_arg, l_arg, pxml), need_self(need_self_arg) {} const char *func_name() const { return "xpath_descendantbyname"; } String *val_nodeset(String *nodeset); }; /* Returns ancestors */ class Item_nodeset_func_ancestorbyname: public Item_nodeset_func_axisbyname { bool need_self; public: Item_nodeset_func_ancestorbyname(Item *a, const char *n_arg, uint l_arg, String *pxml, bool need_self_arg): Item_nodeset_func_axisbyname(a, n_arg, l_arg, pxml), need_self(need_self_arg) {} const char *func_name() const { return "xpath_ancestorbyname"; } String *val_nodeset(String *nodeset); }; /* Returns parents */ class Item_nodeset_func_parentbyname: public Item_nodeset_func_axisbyname { public: Item_nodeset_func_parentbyname(Item *a, const char *n_arg, uint l_arg, String *pxml): Item_nodeset_func_axisbyname(a, n_arg, l_arg, pxml) {} const char *func_name() const { return "xpath_parentbyname"; } String *val_nodeset(String *nodeset); }; /* Returns attributes */ class Item_nodeset_func_attributebyname: public Item_nodeset_func_axisbyname { public: Item_nodeset_func_attributebyname(Item *a, const char *n_arg, uint l_arg, String *pxml): Item_nodeset_func_axisbyname(a, n_arg, l_arg, pxml) {} const char *func_name() const { return "xpath_attributebyname"; } String *val_nodeset(String *nodeset); }; /* Condition iterator: goes through all nodes in the current context and checks a condition, returning those nodes giving TRUE condition result. */ class Item_nodeset_func_predicate :public Item_nodeset_func { public: Item_nodeset_func_predicate(Item *a, Item *b, String *pxml): Item_nodeset_func(a, b, pxml) {} const char *func_name() const { return "xpath_predicate"; } String *val_nodeset(String *nodeset); }; /* Selects nodes with a given position in context */ class Item_nodeset_func_elementbyindex :public Item_nodeset_func { public: Item_nodeset_func_elementbyindex(Item *a, Item *b, String *pxml): Item_nodeset_func(a, b, pxml) { } const char *func_name() const { return "xpath_elementbyindex"; } String *val_nodeset(String *nodeset); }; /* We need to distinguish a number from a boolean: a[1] and a[true] are different things in XPath. */ class Item_bool :public Item_int { public: Item_bool(int32 i): Item_int(i) {} const char *func_name() const { return "xpath_bool"; } bool is_bool_func() { return 1; } }; /* Converts its argument into a boolean value. * a number is true if it is non-zero * a node-set is true if and only if it is non-empty * a string is true if and only if its length is non-zero */ class Item_xpath_cast_bool :public Item_int_func { String *pxml; String tmp_value; public: Item_xpath_cast_bool(Item *a, String *pxml_arg) :Item_int_func(a), pxml(pxml_arg) {} const char *func_name() const { return "xpath_cast_bool"; } bool is_bool_func() { return 1; } longlong val_int() { if (args[0]->type() == XPATH_NODESET) { String *flt= args[0]->val_nodeset(&tmp_value); return flt->length() == sizeof(MY_XPATH_FLT) ? 1 : 0; } return args[0]->val_real() ? 1 : 0; } }; /* Converts its argument into a number */ class Item_xpath_cast_number :public Item_real_func { public: Item_xpath_cast_number(Item *a): Item_real_func(a) {} const char *func_name() const { return "xpath_cast_number"; } virtual double val_real() { return args[0]->val_real(); } }; /* Context cache, for predicate */ class Item_nodeset_context_cache :public Item_nodeset_func { public: String *string_cache; Item_nodeset_context_cache(String *str_arg, String *pxml): Item_nodeset_func(pxml), string_cache(str_arg) { } String *val_nodeset(String *res) { return string_cache; } void fix_length_and_dec() { max_length= MAX_BLOB_WIDTH; } }; class Item_func_xpath_position :public Item_int_func { String *pxml; String tmp_value; public: Item_func_xpath_position(Item *a, String *p) :Item_int_func(a), pxml(p) {} const char *func_name() const { return "xpath_position"; } void fix_length_and_dec() { max_length=10; } longlong val_int() { String *flt= args[0]->val_nodeset(&tmp_value); if (flt->length() == sizeof(MY_XPATH_FLT)) return ((MY_XPATH_FLT*)flt->ptr())->pos + 1; return 0; } }; class Item_func_xpath_count :public Item_int_func { String *pxml; String tmp_value; public: Item_func_xpath_count(Item *a, String *p) :Item_int_func(a), pxml(p) {} const char *func_name() const { return "xpath_count"; } void fix_length_and_dec() { max_length=10; } longlong val_int() { uint predicate_supplied_context_size; String *res= args[0]->val_nodeset(&tmp_value); if (res->length() == sizeof(MY_XPATH_FLT) && (predicate_supplied_context_size= ((MY_XPATH_FLT*)res->ptr())->size)) return predicate_supplied_context_size; return res->length() / sizeof(MY_XPATH_FLT); } }; class Item_func_xpath_sum :public Item_real_func { String *pxml; String tmp_value; public: Item_func_xpath_sum(Item *a, String *p) :Item_real_func(a), pxml(p) {} const char *func_name() const { return "xpath_sum"; } double val_real() { double sum= 0; String *res= args[0]->val_nodeset(&tmp_value); MY_XPATH_FLT *fltbeg= (MY_XPATH_FLT*) res->ptr(); MY_XPATH_FLT *fltend= (MY_XPATH_FLT*) (res->ptr() + res->length()); uint numnodes= pxml->length() / sizeof(MY_XML_NODE); MY_XML_NODE *nodebeg= (MY_XML_NODE*) pxml->ptr(); for (MY_XPATH_FLT *flt= fltbeg; flt < fltend; flt++) { MY_XML_NODE *self= &nodebeg[flt->num]; for (uint j= flt->num + 1; j < numnodes; j++) { MY_XML_NODE *node= &nodebeg[j]; if (node->level <= self->level) break; if ((node->parent == flt->num) && (node->type == MY_XML_NODE_TEXT)) { char *end; int err; double add= my_strntod(collation.collation, (char*) node->beg, node->end - node->beg, &end, &err); if (!err) sum+= add; } } } return sum; } }; class Item_nodeset_to_const_comparator :public Item_bool_func { String *pxml; String tmp_nodeset; public: Item_nodeset_to_const_comparator(Item *nodeset, Item *cmpfunc, String *p) :Item_bool_func(nodeset,cmpfunc), pxml(p) {} enum Type type() const { return XPATH_NODESET_CMP; }; const char *func_name() const { return "xpath_nodeset_to_const_comparator"; } bool is_bool_func() { return 1; } bool check_vcol_func_processor(uchar *int_arg) { return trace_unsupported_by_check_vcol_func_processor(func_name()); } longlong val_int() { Item_func *comp= (Item_func*)args[1]; Item_string *fake= (Item_string*)(comp->arguments()[0]); String *res= args[0]->val_nodeset(&tmp_nodeset); MY_XPATH_FLT *fltbeg= (MY_XPATH_FLT*) res->ptr(); MY_XPATH_FLT *fltend= (MY_XPATH_FLT*) (res->ptr() + res->length()); MY_XML_NODE *nodebeg= (MY_XML_NODE*) pxml->ptr(); uint numnodes= pxml->length() / sizeof(MY_XML_NODE); for (MY_XPATH_FLT *flt= fltbeg; flt < fltend; flt++) { MY_XML_NODE *self= &nodebeg[flt->num]; for (uint j= flt->num + 1; j < numnodes; j++) { MY_XML_NODE *node= &nodebeg[j]; if (node->level <= self->level) break; if ((node->parent == flt->num) && (node->type == MY_XML_NODE_TEXT)) { fake->str_value.set(node->beg, node->end - node->beg, collation.collation); if (args[1]->val_int()) return 1; } } } return 0; } }; String *Item_nodeset_func_rootelement::val_nodeset(String *nodeset) { nodeset->length(0); ((XPathFilter*)nodeset)->append_element(0, 0); return nodeset; } String * Item_nodeset_func_union::val_nodeset(String *nodeset) { uint num_nodes= pxml->length() / sizeof(MY_XML_NODE); String set0, *s0= args[0]->val_nodeset(&set0); String set1, *s1= args[1]->val_nodeset(&set1); String both_str; both_str.alloc(num_nodes); char *both= (char*) both_str.ptr(); bzero((void*)both, num_nodes); MY_XPATH_FLT *flt; fltbeg= (MY_XPATH_FLT*) s0->ptr(); fltend= (MY_XPATH_FLT*) (s0->ptr() + s0->length()); for (flt= fltbeg; flt < fltend; flt++) both[flt->num]= 1; fltbeg= (MY_XPATH_FLT*) s1->ptr(); fltend= (MY_XPATH_FLT*) (s1->ptr() + s1->length()); for (flt= fltbeg; flt < fltend; flt++) both[flt->num]= 1; nodeset->length(0); for (uint i= 0, pos= 0; i < num_nodes; i++) { if (both[i]) ((XPathFilter*)nodeset)->append_element(i, pos++); } return nodeset; } String *Item_nodeset_func_selfbyname::val_nodeset(String *nodeset) { prepare(nodeset); for (MY_XPATH_FLT *flt= fltbeg; flt < fltend; flt++) { uint pos= 0; MY_XML_NODE *self= &nodebeg[flt->num]; if (validname(self)) ((XPathFilter*)nodeset)->append_element(flt->num,pos++); } return nodeset; } String *Item_nodeset_func_childbyname::val_nodeset(String *nodeset) { prepare(nodeset); for (MY_XPATH_FLT *flt= fltbeg; flt < fltend; flt++) { MY_XML_NODE *self= &nodebeg[flt->num]; for (uint pos= 0, j= flt->num + 1 ; j < numnodes; j++) { MY_XML_NODE *node= &nodebeg[j]; if (node->level <= self->level) break; if ((node->parent == flt->num) && (node->type == MY_XML_NODE_TAG) && validname(node)) ((XPathFilter*)nodeset)->append_element(j, pos++); } } return nodeset; } String *Item_nodeset_func_descendantbyname::val_nodeset(String *nodeset) { prepare(nodeset); for (MY_XPATH_FLT *flt= fltbeg; flt < fltend; flt++) { uint pos= 0; MY_XML_NODE *self= &nodebeg[flt->num]; if (need_self && validname(self)) ((XPathFilter*)nodeset)->append_element(flt->num,pos++); for (uint j= flt->num + 1 ; j < numnodes ; j++) { MY_XML_NODE *node= &nodebeg[j]; if (node->level <= self->level) break; if ((node->type == MY_XML_NODE_TAG) && validname(node)) ((XPathFilter*)nodeset)->append_element(j,pos++); } } return nodeset; } String *Item_nodeset_func_ancestorbyname::val_nodeset(String *nodeset) { char *active; String active_str; prepare(nodeset); active_str.alloc(numnodes); active= (char*) active_str.ptr(); bzero((void*)active, numnodes); uint pos= 0; for (MY_XPATH_FLT *flt= fltbeg; flt < fltend; flt++) { /* Go to the root and add all nodes on the way. Don't add the root if context is the root itelf */ MY_XML_NODE *self= &nodebeg[flt->num]; if (need_self && validname(self)) { active[flt->num]= 1; pos++; } for (uint j= self->parent; nodebeg[j].parent != j; j= nodebeg[j].parent) { if (flt->num && validname(&nodebeg[j])) { active[j]= 1; pos++; } } } for (uint j= 0; j < numnodes ; j++) { if (active[j]) ((XPathFilter*)nodeset)->append_element(j, --pos); } return nodeset; } String *Item_nodeset_func_parentbyname::val_nodeset(String *nodeset) { char *active; String active_str; prepare(nodeset); active_str.alloc(numnodes); active= (char*) active_str.ptr(); bzero((void*)active, numnodes); for (MY_XPATH_FLT *flt= fltbeg; flt < fltend; flt++) { uint j= nodebeg[flt->num].parent; if (flt->num && validname(&nodebeg[j])) active[j]= 1; } for (uint j= 0, pos= 0; j < numnodes ; j++) { if (active[j]) ((XPathFilter*)nodeset)->append_element(j, pos++); } return nodeset; } String *Item_nodeset_func_attributebyname::val_nodeset(String *nodeset) { prepare(nodeset); for (MY_XPATH_FLT *flt= fltbeg; flt < fltend; flt++) { MY_XML_NODE *self= &nodebeg[flt->num]; for (uint pos=0, j= flt->num + 1 ; j < numnodes; j++) { MY_XML_NODE *node= &nodebeg[j]; if (node->level <= self->level) break; if ((node->parent == flt->num) && (node->type == MY_XML_NODE_ATTR) && validname(node)) ((XPathFilter*)nodeset)->append_element(j, pos++); } } return nodeset; } String *Item_nodeset_func_predicate::val_nodeset(String *str) { Item_nodeset_func *nodeset_func= (Item_nodeset_func*) args[0]; Item_func *comp_func= (Item_func*)args[1]; uint pos= 0, size; prepare(str); size= fltend - fltbeg; for (MY_XPATH_FLT *flt= fltbeg; flt < fltend; flt++) { nodeset_func->context_cache.length(0); ((XPathFilter*)(&nodeset_func->context_cache))->append_element(flt->num, flt->pos, size); if (comp_func->val_int()) ((XPathFilter*)str)->append_element(flt->num, pos++); } return str; } String *Item_nodeset_func_elementbyindex::val_nodeset(String *nodeset) { Item_nodeset_func *nodeset_func= (Item_nodeset_func*) args[0]; prepare(nodeset); MY_XPATH_FLT *flt; uint pos, size= fltend - fltbeg; for (pos= 0, flt= fltbeg; flt < fltend; flt++) { nodeset_func->context_cache.length(0); ((XPathFilter*)(&nodeset_func->context_cache))->append_element(flt->num, flt->pos, size); int index= (int) (args[1]->val_int()) - 1; if (index >= 0 && (flt->pos == (uint) index || args[1]->is_bool_func())) ((XPathFilter*)nodeset)->append_element(flt->num, pos++); } return nodeset; } /* If item is a node set, then casts it to boolean, otherwise returns the item itself. */ static Item* nodeset2bool(MY_XPATH *xpath, Item *item) { if (item->type() == Item::XPATH_NODESET) return new Item_xpath_cast_bool(item, xpath->pxml); return item; } /* XPath lexical tokens */ #define MY_XPATH_LEX_DIGITS 'd' #define MY_XPATH_LEX_IDENT 'i' #define MY_XPATH_LEX_STRING 's' #define MY_XPATH_LEX_SLASH '/' #define MY_XPATH_LEX_LB '[' #define MY_XPATH_LEX_RB ']' #define MY_XPATH_LEX_LP '(' #define MY_XPATH_LEX_RP ')' #define MY_XPATH_LEX_EQ '=' #define MY_XPATH_LEX_LESS '<' #define MY_XPATH_LEX_GREATER '>' #define MY_XPATH_LEX_AT '@' #define MY_XPATH_LEX_COLON ':' #define MY_XPATH_LEX_ASTERISK '*' #define MY_XPATH_LEX_DOT '.' #define MY_XPATH_LEX_VLINE '|' #define MY_XPATH_LEX_MINUS '-' #define MY_XPATH_LEX_PLUS '+' #define MY_XPATH_LEX_EXCL '!' #define MY_XPATH_LEX_COMMA ',' #define MY_XPATH_LEX_DOLLAR '$' #define MY_XPATH_LEX_ERROR 'A' #define MY_XPATH_LEX_EOF 'B' #define MY_XPATH_LEX_AND 'C' #define MY_XPATH_LEX_OR 'D' #define MY_XPATH_LEX_DIV 'E' #define MY_XPATH_LEX_MOD 'F' #define MY_XPATH_LEX_FUNC 'G' #define MY_XPATH_LEX_NODETYPE 'H' #define MY_XPATH_LEX_AXIS 'I' #define MY_XPATH_LEX_LE 'J' #define MY_XPATH_LEX_GE 'K' /* XPath axis type */ #define MY_XPATH_AXIS_ANCESTOR 0 #define MY_XPATH_AXIS_ANCESTOR_OR_SELF 1 #define MY_XPATH_AXIS_ATTRIBUTE 2 #define MY_XPATH_AXIS_CHILD 3 #define MY_XPATH_AXIS_DESCENDANT 4 #define MY_XPATH_AXIS_DESCENDANT_OR_SELF 5 #define MY_XPATH_AXIS_FOLLOWING 6 #define MY_XPATH_AXIS_FOLLOWING_SIBLING 7 #define MY_XPATH_AXIS_NAMESPACE 8 #define MY_XPATH_AXIS_PARENT 9 #define MY_XPATH_AXIS_PRECEDING 10 #define MY_XPATH_AXIS_PRECEDING_SIBLING 11 #define MY_XPATH_AXIS_SELF 12 /* Create scalar comparator SYNOPSYS Create a comparator function for scalar arguments, for the given arguments and operation. RETURN The newly created item. */ static Item *eq_func(int oper, Item *a, Item *b) { switch (oper) { case '=': return new Item_func_eq(a, b); case '!': return new Item_func_ne(a, b); case MY_XPATH_LEX_GE: return new Item_func_ge(a, b); case MY_XPATH_LEX_LE: return new Item_func_le(a, b); case MY_XPATH_LEX_GREATER: return new Item_func_gt(a, b); case MY_XPATH_LEX_LESS: return new Item_func_lt(a, b); } return 0; } /* Create scalar comparator SYNOPSYS Create a comparator function for scalar arguments, for the given arguments and reverse operation, e.g. A > B is converted into B < A RETURN The newly created item. */ static Item *eq_func_reverse(int oper, Item *a, Item *b) { switch (oper) { case '=': return new Item_func_eq(a, b); case '!': return new Item_func_ne(a, b); case MY_XPATH_LEX_GE: return new Item_func_le(a, b); case MY_XPATH_LEX_LE: return new Item_func_ge(a, b); case MY_XPATH_LEX_GREATER: return new Item_func_lt(a, b); case MY_XPATH_LEX_LESS: return new Item_func_gt(a, b); } return 0; } /* Create a comparator SYNOPSYS Create a comparator for scalar or non-scalar arguments, for the given arguments and operation. RETURN The newly created item. */ static Item *create_comparator(MY_XPATH *xpath, int oper, MY_XPATH_LEX *context, Item *a, Item *b) { if (a->type() != Item::XPATH_NODESET && b->type() != Item::XPATH_NODESET) { return eq_func(oper, a, b); // two scalar arguments } else if (a->type() == Item::XPATH_NODESET && b->type() == Item::XPATH_NODESET) { uint len= xpath->query.end - context->beg; set_if_smaller(len, 32); my_printf_error(ER_UNKNOWN_ERROR, "XPATH error: " "comparison of two nodesets is not supported: '%.*s'", MYF(0), len, context->beg); return 0; // TODO: Comparison of two nodesets } else { /* Compare a node set to a scalar value. We just create a fake Item_string() argument, which will be filled to the partular value in a loop through all of the nodes in the node set. */ Item_string *fake= new Item_string("", 0, xpath->cs); /* Don't cache fake because its value will be changed during comparison.*/ fake->set_used_tables(RAND_TABLE_BIT); Item_nodeset_func *nodeset; Item *scalar, *comp; if (a->type() == Item::XPATH_NODESET) { nodeset= (Item_nodeset_func*) a; scalar= b; comp= eq_func(oper, (Item*)fake, scalar); } else { nodeset= (Item_nodeset_func*) b; scalar= a; comp= eq_func_reverse(oper, fake, scalar); } return new Item_nodeset_to_const_comparator(nodeset, comp, xpath->pxml); } } /* Create a step SYNOPSYS Create a step function for the given argument and axis. RETURN The newly created item. */ static Item* nametestfunc(MY_XPATH *xpath, int type, Item *arg, const char *beg, uint len) { DBUG_ASSERT(arg != 0); DBUG_ASSERT(arg->type() == Item::XPATH_NODESET); DBUG_ASSERT(beg != 0); DBUG_ASSERT(len > 0); Item *res; switch (type) { case MY_XPATH_AXIS_ANCESTOR: res= new Item_nodeset_func_ancestorbyname(arg, beg, len, xpath->pxml, 0); break; case MY_XPATH_AXIS_ANCESTOR_OR_SELF: res= new Item_nodeset_func_ancestorbyname(arg, beg, len, xpath->pxml, 1); break; case MY_XPATH_AXIS_PARENT: res= new Item_nodeset_func_parentbyname(arg, beg, len, xpath->pxml); break; case MY_XPATH_AXIS_DESCENDANT: res= new Item_nodeset_func_descendantbyname(arg, beg, len, xpath->pxml, 0); break; case MY_XPATH_AXIS_DESCENDANT_OR_SELF: res= new Item_nodeset_func_descendantbyname(arg, beg, len, xpath->pxml, 1); break; case MY_XPATH_AXIS_ATTRIBUTE: res= new Item_nodeset_func_attributebyname(arg, beg, len, xpath->pxml); break; case MY_XPATH_AXIS_SELF: res= new Item_nodeset_func_selfbyname(arg, beg, len, xpath->pxml); break; default: res= new Item_nodeset_func_childbyname(arg, beg, len, xpath->pxml); } return res; } /* Tokens consisting of one character, for faster lexical analizer. */ static char simpletok[128]= { 0,0,0,0,0,0,0,0,0,0,0,0,0,0,0,0,0,0,0,0,0,0,0,0,0,0,0,0,0,0,0,0, /* ! " # $ % & ' ( ) * + , - . / 0 1 2 3 4 5 6 7 8 9 : ; < = > ? @ A B C D E F G H I J K L M N O P Q R S T U V W X Y Z [ \ ] ^ _ ` a b c d e f g h i j k l m n o p q r s t u v w x y z { | } ~ € */ 0,1,0,0,1,0,0,0,1,1,1,1,1,1,1,1,0,0,0,0,0,0,0,0,0,0,1,0,1,1,1,0, 1,0,0,0,0,0,0,0,0,0,0,0,0,0,0,0,0,0,0,0,0,0,0,0,0,0,0,1,0,1,0,0, 0,0,0,0,0,0,0,0,0,0,0,0,0,0,0,0,0,0,0,0,0,0,0,0,0,0,0,0,1,0,0,0 }; /* XPath keywords */ struct my_xpath_keyword_names_st { int tok; const char *name; size_t length; int extra; }; static struct my_xpath_keyword_names_st my_keyword_names[] = { {MY_XPATH_LEX_AND , "and" , 3, 0 }, {MY_XPATH_LEX_OR , "or" , 2, 0 }, {MY_XPATH_LEX_DIV , "div" , 3, 0 }, {MY_XPATH_LEX_MOD , "mod" , 3, 0 }, {0,NULL,0,0} }; static struct my_xpath_keyword_names_st my_axis_names[]= { {MY_XPATH_LEX_AXIS,"ancestor" , 8,MY_XPATH_AXIS_ANCESTOR }, {MY_XPATH_LEX_AXIS,"ancestor-or-self" ,16,MY_XPATH_AXIS_ANCESTOR_OR_SELF }, {MY_XPATH_LEX_AXIS,"attribute" , 9,MY_XPATH_AXIS_ATTRIBUTE }, {MY_XPATH_LEX_AXIS,"child" , 5,MY_XPATH_AXIS_CHILD }, {MY_XPATH_LEX_AXIS,"descendant" ,10,MY_XPATH_AXIS_DESCENDANT }, {MY_XPATH_LEX_AXIS,"descendant-or-self",18,MY_XPATH_AXIS_DESCENDANT_OR_SELF}, {MY_XPATH_LEX_AXIS,"following" , 9,MY_XPATH_AXIS_FOLLOWING }, {MY_XPATH_LEX_AXIS,"following-sibling" ,17,MY_XPATH_AXIS_FOLLOWING_SIBLING }, {MY_XPATH_LEX_AXIS,"namespace" , 9,MY_XPATH_AXIS_NAMESPACE }, {MY_XPATH_LEX_AXIS,"parent" , 6,MY_XPATH_AXIS_PARENT }, {MY_XPATH_LEX_AXIS,"preceding" , 9,MY_XPATH_AXIS_PRECEDING }, {MY_XPATH_LEX_AXIS,"preceding-sibling" ,17,MY_XPATH_AXIS_PRECEDING_SIBLING }, {MY_XPATH_LEX_AXIS,"self" , 4,MY_XPATH_AXIS_SELF }, {0,NULL,0,0} }; static struct my_xpath_keyword_names_st my_nodetype_names[]= { {MY_XPATH_LEX_NODETYPE, "comment" , 7, 0 }, {MY_XPATH_LEX_NODETYPE, "text" , 4, 0 }, {MY_XPATH_LEX_NODETYPE, "processing-instruction" , 22,0 }, {MY_XPATH_LEX_NODETYPE, "node" , 4, 0 }, {0,NULL,0,0} }; /* Lookup a keyword SYNOPSYS Check that the last scanned identifier is a keyword. RETURN - Token type, on lookup success. - MY_XPATH_LEX_IDENT, on lookup failure. */ static int my_xpath_keyword(MY_XPATH *x, struct my_xpath_keyword_names_st *keyword_names, const char *beg, const char *end) { struct my_xpath_keyword_names_st *k; size_t length= end-beg; for (k= keyword_names; k->name; k++) { if (length == k->length && !strncasecmp(beg, k->name, length)) { x->extra= k->extra; return k->tok; } } return MY_XPATH_LEX_IDENT; } /* Functions to create an item, a-la those in item_create.cc */ static Item *create_func_true(MY_XPATH *xpath, Item **args, uint nargs) { return new Item_bool(1); } static Item *create_func_false(MY_XPATH *xpath, Item **args, uint nargs) { return new Item_bool(0); } static Item *create_func_not(MY_XPATH *xpath, Item **args, uint nargs) { return new Item_func_not(nodeset2bool(xpath, args[0])); } static Item *create_func_ceiling(MY_XPATH *xpath, Item **args, uint nargs) { return new Item_func_ceiling(args[0]); } static Item *create_func_floor(MY_XPATH *xpath, Item **args, uint nargs) { return new Item_func_floor(args[0]); } static Item *create_func_bool(MY_XPATH *xpath, Item **args, uint nargs) { return new Item_xpath_cast_bool(args[0], xpath->pxml); } static Item *create_func_number(MY_XPATH *xpath, Item **args, uint nargs) { return new Item_xpath_cast_number(args[0]); } static Item *create_func_string_length(MY_XPATH *xpath, Item **args, uint nargs) { Item *arg= nargs ? args[0] : xpath->context; return arg ? new Item_func_char_length(arg) : 0; } static Item *create_func_round(MY_XPATH *xpath, Item **args, uint nargs) { return new Item_func_round(args[0], new Item_int((char*)"0",0,1),0); } static Item *create_func_last(MY_XPATH *xpath, Item **args, uint nargs) { return xpath->context ? new Item_func_xpath_count(xpath->context, xpath->pxml) : NULL; } static Item *create_func_position(MY_XPATH *xpath, Item **args, uint nargs) { return xpath->context ? new Item_func_xpath_position(xpath->context, xpath->pxml) : NULL; } static Item *create_func_contains(MY_XPATH *xpath, Item **args, uint nargs) { return new Item_xpath_cast_bool(new Item_func_locate(args[0], args[1]), xpath->pxml); } static Item *create_func_concat(MY_XPATH *xpath, Item **args, uint nargs) { return new Item_func_concat(args[0], args[1]); } static Item *create_func_substr(MY_XPATH *xpath, Item **args, uint nargs) { if (nargs == 2) return new Item_func_substr(args[0], args[1]); else return new Item_func_substr(args[0], args[1], args[2]); } static Item *create_func_count(MY_XPATH *xpath, Item **args, uint nargs) { if (args[0]->type() != Item::XPATH_NODESET) return 0; return new Item_func_xpath_count(args[0], xpath->pxml); } static Item *create_func_sum(MY_XPATH *xpath, Item **args, uint nargs) { if (args[0]->type() != Item::XPATH_NODESET) return 0; return new Item_func_xpath_sum(args[0], xpath->pxml); } /* Functions names. Separate lists for names with lengths 3,4,5 and 6 for faster lookups. */ static MY_XPATH_FUNC my_func_names3[]= { {"sum", 3, 1 , 1 , create_func_sum}, {"not", 3, 1 , 1 , create_func_not}, {0 , 0, 0 , 0, 0} }; static MY_XPATH_FUNC my_func_names4[]= { {"last", 4, 0, 0, create_func_last}, {"true", 4, 0, 0, create_func_true}, {"name", 4, 0, 1, 0}, {"lang", 4, 1, 1, 0}, {0 , 0, 0, 0, 0} }; static MY_XPATH_FUNC my_func_names5[]= { {"count", 5, 1, 1, create_func_count}, {"false", 5, 0, 0, create_func_false}, {"floor", 5, 1, 1, create_func_floor}, {"round", 5, 1, 1, create_func_round}, {0 , 0, 0, 0, 0} }; static MY_XPATH_FUNC my_func_names6[]= { {"concat", 6, 2, 255, create_func_concat}, {"number", 6, 0, 1 , create_func_number}, {"string", 6, 0, 1 , 0}, {0 , 0, 0, 0 , 0} }; /* Other functions, with name longer than 6, all together */ static MY_XPATH_FUNC my_func_names[] = { {"id" , 2 , 1 , 1 , 0}, {"boolean" , 7 , 1 , 1 , create_func_bool}, {"ceiling" , 7 , 1 , 1 , create_func_ceiling}, {"position" , 8 , 0 , 0 , create_func_position}, {"contains" , 8 , 2 , 2 , create_func_contains}, {"substring" , 9 , 2 , 3 , create_func_substr}, {"translate" , 9 , 3 , 3 , 0}, {"local-name" , 10 , 0 , 1 , 0}, {"starts-with" , 11 , 2 , 2 , 0}, {"namespace-uri" , 13 , 0 , 1 , 0}, {"string-length" , 13 , 0 , 1 , create_func_string_length}, {"substring-after" , 15 , 2 , 2 , 0}, {"normalize-space" , 15 , 0 , 1 , 0}, {"substring-before" , 16 , 2 , 2 , 0}, {NULL,0,0,0,0} }; /* Lookup a function by name SYNOPSYS Lookup a function by its name. RETURN Pointer to a MY_XPATH_FUNC variable on success. 0 - on failure. */ MY_XPATH_FUNC * my_xpath_function(const char *beg, const char *end) { MY_XPATH_FUNC *k, *function_names; uint length= end-beg; switch (length) { case 1: return 0; case 3: function_names= my_func_names3; break; case 4: function_names= my_func_names4; break; case 5: function_names= my_func_names5; break; case 6: function_names= my_func_names6; break; default: function_names= my_func_names; } for (k= function_names; k->name; k++) if (k->create && length == k->length && !strncasecmp(beg, k->name, length)) return k; return NULL; } /* Initialize a lex analizer token */ static void my_xpath_lex_init(MY_XPATH_LEX *lex, const char *str, const char *strend) { lex->beg= str; lex->end= strend; } /* Initialize an XPath query parser */ static void my_xpath_init(MY_XPATH *xpath) { bzero((void*)xpath, sizeof(xpath[0])); } static int my_xdigit(int c) { return ((c) >= '0' && (c) <= '9'); } /* Scan the next token SYNOPSYS Scan the next token from the input. lex->term is set to the scanned token type. lex->beg and lex->end are set to the beginnig and to the end of the token. RETURN N/A */ static void my_xpath_lex_scan(MY_XPATH *xpath, MY_XPATH_LEX *lex, const char *beg, const char *end) { int ch, ctype, length; for ( ; beg < end && *beg == ' ' ; beg++) ; // skip leading spaces lex->beg= beg; if (beg >= end) { lex->end= beg; lex->term= MY_XPATH_LEX_EOF; // end of line reached return; } // Check ident, or a function call, or a keyword if ((length= xpath->cs->cset->ctype(xpath->cs, &ctype, (const uchar*) beg, (const uchar*) end)) > 0 && ((ctype & (_MY_L | _MY_U)) || *beg == '_')) { // scan untill the end of the idenfitier for (beg+= length; (length= xpath->cs->cset->ctype(xpath->cs, &ctype, (const uchar*) beg, (const uchar*) end)) > 0 && ((ctype & (_MY_L | _MY_U | _MY_NMR)) || *beg == '_' || *beg == '-' || *beg == '.') ; beg+= length) /* no op */; lex->end= beg; if (beg < end) { if (*beg == '(') { /* check if a function call, e.g.: count(/a/b) or a nodetype test, e.g.: /a/b/text() */ if ((xpath->func= my_xpath_function(lex->beg, beg))) lex->term= MY_XPATH_LEX_FUNC; else lex->term= my_xpath_keyword(xpath, my_nodetype_names, lex->beg, beg); return; } // check if an axis specifier, e.g.: /a/b/child::* else if (*beg == ':' && beg + 1 < end && beg[1] == ':') { lex->term= my_xpath_keyword(xpath, my_axis_names, lex->beg, beg); return; } } // check if a keyword lex->term= my_xpath_keyword(xpath, my_keyword_names, lex->beg, beg); return; } ch= *beg++; if (ch > 0 && ch < 128 && simpletok[ch]) { // a token consisting of one character found lex->end= beg; lex->term= ch; return; } if (my_xdigit(ch)) // a sequence of digits { for ( ; beg < end && my_xdigit(*beg) ; beg++) ; lex->end= beg; lex->term= MY_XPATH_LEX_DIGITS; return; } if (ch == '"' || ch == '\'') // a string: either '...' or "..." { for ( ; beg < end && *beg != ch ; beg++) ; if (beg < end) { lex->end= beg+1; lex->term= MY_XPATH_LEX_STRING; return; } else { // unexpected end-of-line, without closing quot sign lex->end= end; lex->term= MY_XPATH_LEX_ERROR; return; } } lex->end= beg; lex->term= MY_XPATH_LEX_ERROR; // unknown character return; } /* Scan the given token SYNOPSYS Scan the given token and rotate lasttok to prevtok on success. RETURN 1 - success 0 - failure */ static int my_xpath_parse_term(MY_XPATH *xpath, int term) { if (xpath->lasttok.term == term && !xpath->error) { xpath->prevtok= xpath->lasttok; my_xpath_lex_scan(xpath, &xpath->lasttok, xpath->lasttok.end, xpath->query.end); return 1; } return 0; } /* Scan AxisName SYNOPSYS Scan an axis name and store the scanned axis type into xpath->axis. RETURN 1 - success 0 - failure */ static int my_xpath_parse_AxisName(MY_XPATH *xpath) { int rc= my_xpath_parse_term(xpath, MY_XPATH_LEX_AXIS); xpath->axis= xpath->extra; return rc; } /********************************************* ** Grammar rules, according to http://www.w3.org/TR/xpath ** Implemented using recursive descendant method. ** All the following grammar processing functions accept ** a signle "xpath" argument and return 1 on success and 0 on error. ** They also modify "xpath" argument by creating new items. */ /* [9] PredicateExpr ::= Expr */ #define my_xpath_parse_PredicateExpr(x) my_xpath_parse_Expr((x)) /* [14] Expr ::= OrExpr */ #define my_xpath_parse_Expr(x) my_xpath_parse_OrExpr((x)) static int my_xpath_parse_LocationPath(MY_XPATH *xpath); static int my_xpath_parse_AbsoluteLocationPath(MY_XPATH *xpath); static int my_xpath_parse_RelativeLocationPath(MY_XPATH *xpath); static int my_xpath_parse_AbbreviatedStep(MY_XPATH *xpath); static int my_xpath_parse_Step(MY_XPATH *xpath); static int my_xpath_parse_AxisSpecifier(MY_XPATH *xpath); static int my_xpath_parse_NodeTest(MY_XPATH *xpath); static int my_xpath_parse_AbbreviatedAxisSpecifier(MY_XPATH *xpath); static int my_xpath_parse_NameTest(MY_XPATH *xpath); static int my_xpath_parse_FunctionCall(MY_XPATH *xpath); static int my_xpath_parse_Number(MY_XPATH *xpath); static int my_xpath_parse_FilterExpr(MY_XPATH *xpath); static int my_xpath_parse_PathExpr(MY_XPATH *xpath); static int my_xpath_parse_OrExpr(MY_XPATH *xpath); static int my_xpath_parse_UnaryExpr(MY_XPATH *xpath); static int my_xpath_parse_MultiplicativeExpr(MY_XPATH *xpath); static int my_xpath_parse_AdditiveExpr(MY_XPATH *xpath); static int my_xpath_parse_RelationalExpr(MY_XPATH *xpath); static int my_xpath_parse_AndExpr(MY_XPATH *xpath); static int my_xpath_parse_EqualityExpr(MY_XPATH *xpath); static int my_xpath_parse_VariableReference(MY_XPATH *xpath); /* Scan LocationPath SYNOPSYS [1] LocationPath ::= RelativeLocationPath | AbsoluteLocationPath RETURN 1 - success 0 - failure */ static int my_xpath_parse_LocationPath(MY_XPATH *xpath) { Item *context= xpath->context; if (!xpath->context) xpath->context= xpath->rootelement; int rc= my_xpath_parse_RelativeLocationPath(xpath) || my_xpath_parse_AbsoluteLocationPath(xpath); xpath->item= xpath->context; xpath->context= context; return rc; } /* Scan Absolute Location Path SYNOPSYS [2] AbsoluteLocationPath ::= '/' RelativeLocationPath? | AbbreviatedAbsoluteLocationPath [10] AbbreviatedAbsoluteLocationPath ::= '//' RelativeLocationPath We combine these two rules into one rule for better performance: [2,10] AbsoluteLocationPath ::= '/' RelativeLocationPath? | '//' RelativeLocationPath RETURN 1 - success 0 - failure */ static int my_xpath_parse_AbsoluteLocationPath(MY_XPATH *xpath) { if (!my_xpath_parse_term(xpath, MY_XPATH_LEX_SLASH)) return 0; xpath->context= xpath->rootelement; if (my_xpath_parse_term(xpath, MY_XPATH_LEX_SLASH)) { xpath->context= new Item_nodeset_func_descendantbyname(xpath->context, "*", 1, xpath->pxml, 1); return my_xpath_parse_RelativeLocationPath(xpath); } my_xpath_parse_RelativeLocationPath(xpath); return (xpath->error == 0); } /* Scan Relative Location Path SYNOPSYS For better performance we combine these two rules [3] RelativeLocationPath ::= Step | RelativeLocationPath '/' Step | AbbreviatedRelativeLocationPath [11] AbbreviatedRelativeLocationPath ::= RelativeLocationPath '//' Step Into this one: [3-11] RelativeLocationPath ::= Step | RelativeLocationPath '/' Step | RelativeLocationPath '//' Step RETURN 1 - success 0 - failure */ static int my_xpath_parse_RelativeLocationPath(MY_XPATH *xpath) { if (!my_xpath_parse_Step(xpath)) return 0; while (my_xpath_parse_term(xpath, MY_XPATH_LEX_SLASH)) { if (my_xpath_parse_term(xpath, MY_XPATH_LEX_SLASH)) xpath->context= new Item_nodeset_func_descendantbyname(xpath->context, "*", 1, xpath->pxml, 1); if (!my_xpath_parse_Step(xpath)) { xpath->error= 1; return 0; } } return 1; } /* Scan non-abbreviated or abbreviated Step SYNOPSYS [4] Step ::= AxisSpecifier NodeTest Predicate* | AbbreviatedStep [8] Predicate ::= '[' PredicateExpr ']' RETURN 1 - success 0 - failure */ static int my_xpath_parse_AxisSpecifier_NodeTest_opt_Predicate_list(MY_XPATH *xpath) { if (!my_xpath_parse_AxisSpecifier(xpath)) return 0; if (!my_xpath_parse_NodeTest(xpath)) return 0; while (my_xpath_parse_term(xpath, MY_XPATH_LEX_LB)) { Item *prev_context= xpath->context; String *context_cache; context_cache= &((Item_nodeset_func*)xpath->context)->context_cache; xpath->context= new Item_nodeset_context_cache(context_cache, xpath->pxml); xpath->context_cache= context_cache; if(!my_xpath_parse_PredicateExpr(xpath)) { xpath->error= 1; return 0; } if (!my_xpath_parse_term(xpath, MY_XPATH_LEX_RB)) { xpath->error= 1; return 0; } xpath->item= nodeset2bool(xpath, xpath->item); if (xpath->item->is_bool_func()) { xpath->context= new Item_nodeset_func_predicate(prev_context, xpath->item, xpath->pxml); } else { xpath->context= new Item_nodeset_func_elementbyindex(prev_context, xpath->item, xpath->pxml); } } return 1; } static int my_xpath_parse_Step(MY_XPATH *xpath) { return my_xpath_parse_AxisSpecifier_NodeTest_opt_Predicate_list(xpath) || my_xpath_parse_AbbreviatedStep(xpath); } /* Scan Abbreviated Axis Specifier SYNOPSYS [5] AxisSpecifier ::= AxisName '::' | AbbreviatedAxisSpecifier RETURN 1 - success 0 - failure */ static int my_xpath_parse_AbbreviatedAxisSpecifier(MY_XPATH *xpath) { if (my_xpath_parse_term(xpath, MY_XPATH_LEX_AT)) xpath->axis= MY_XPATH_AXIS_ATTRIBUTE; else xpath->axis= MY_XPATH_AXIS_CHILD; return 1; } /* Scan non-abbreviated axis specifier SYNOPSYS RETURN 1 - success 0 - failure */ static int my_xpath_parse_AxisName_colon_colon(MY_XPATH *xpath) { return my_xpath_parse_AxisName(xpath) && my_xpath_parse_term(xpath, MY_XPATH_LEX_COLON) && my_xpath_parse_term(xpath, MY_XPATH_LEX_COLON); } /* Scan Abbreviated AxisSpecifier SYNOPSYS [13] AbbreviatedAxisSpecifier ::= '@'? RETURN 1 - success 0 - failure */ static int my_xpath_parse_AxisSpecifier(MY_XPATH *xpath) { return my_xpath_parse_AxisName_colon_colon(xpath) || my_xpath_parse_AbbreviatedAxisSpecifier(xpath); } /* Scan NodeType followed by parens SYNOPSYS RETURN 1 - success 0 - failure */ static int my_xpath_parse_NodeTest_lp_rp(MY_XPATH *xpath) { return my_xpath_parse_term(xpath, MY_XPATH_LEX_NODETYPE) && my_xpath_parse_term(xpath, MY_XPATH_LEX_LP) && my_xpath_parse_term(xpath, MY_XPATH_LEX_RP); } /* Scan NodeTest SYNOPSYS [7] NodeTest ::= NameTest | NodeType '(' ')' | 'processing-instruction' '(' Literal ')' RETURN 1 - success 0 - failure */ static int my_xpath_parse_NodeTest(MY_XPATH *xpath) { return my_xpath_parse_NameTest(xpath) || my_xpath_parse_NodeTest_lp_rp(xpath); } /* Scan Abbreviated Step SYNOPSYS [12] AbbreviatedStep ::= '.' | '..' RETURN 1 - success 0 - failure */ static int my_xpath_parse_AbbreviatedStep(MY_XPATH *xpath) { if (!my_xpath_parse_term(xpath, MY_XPATH_LEX_DOT)) return 0; if (my_xpath_parse_term(xpath, MY_XPATH_LEX_DOT)) xpath->context= new Item_nodeset_func_parentbyname(xpath->context, "*", 1, xpath->pxml); return 1; } /* Scan Primary Expression SYNOPSYS [15] PrimaryExpr ::= VariableReference | '(' Expr ')' | Literal | Number | FunctionCall RETURN 1 - success 0 - failure */ static int my_xpath_parse_lp_Expr_rp(MY_XPATH *xpath) { return my_xpath_parse_term(xpath, MY_XPATH_LEX_LP) && my_xpath_parse_Expr(xpath) && my_xpath_parse_term(xpath, MY_XPATH_LEX_RP); } static int my_xpath_parse_PrimaryExpr_literal(MY_XPATH *xpath) { if (!my_xpath_parse_term(xpath, MY_XPATH_LEX_STRING)) return 0; xpath->item= new Item_string(xpath->prevtok.beg + 1, xpath->prevtok.end - xpath->prevtok.beg - 2, xpath->cs); return 1; } static int my_xpath_parse_PrimaryExpr(MY_XPATH *xpath) { return my_xpath_parse_lp_Expr_rp(xpath) || my_xpath_parse_VariableReference(xpath) || my_xpath_parse_PrimaryExpr_literal(xpath) || my_xpath_parse_Number(xpath) || my_xpath_parse_FunctionCall(xpath); } /* Scan Function Call SYNOPSYS [16] FunctionCall ::= FunctionName '(' ( Argument ( ',' Argument )* )? ')' [17] Argument ::= Expr RETURN 1 - success 0 - failure */ static int my_xpath_parse_FunctionCall(MY_XPATH *xpath) { Item *args[256]; uint nargs; if (!my_xpath_parse_term(xpath, MY_XPATH_LEX_FUNC)) return 0; MY_XPATH_FUNC *func= xpath->func; if (!my_xpath_parse_term(xpath, MY_XPATH_LEX_LP)) return 0; for (nargs= 0 ; nargs < func->maxargs; ) { if (!my_xpath_parse_Expr(xpath)) { if (nargs < func->minargs) return 0; goto right_paren; } args[nargs++]= xpath->item; if (!my_xpath_parse_term(xpath, MY_XPATH_LEX_COMMA)) { if (nargs < func->minargs) return 0; else break; } } right_paren: if (!my_xpath_parse_term(xpath, MY_XPATH_LEX_RP)) return 0; return ((xpath->item= func->create(xpath, args, nargs))) ? 1 : 0; } /* Scan Union Expression SYNOPSYS [18] UnionExpr ::= PathExpr | UnionExpr '|' PathExpr RETURN 1 - success 0 - failure */ static int my_xpath_parse_UnionExpr(MY_XPATH *xpath) { if (!my_xpath_parse_PathExpr(xpath)) return 0; while (my_xpath_parse_term(xpath, MY_XPATH_LEX_VLINE)) { Item *prev= xpath->item; if (prev->type() != Item::XPATH_NODESET) return 0; if (!my_xpath_parse_PathExpr(xpath) || xpath->item->type() != Item::XPATH_NODESET) { xpath->error= 1; return 0; } xpath->item= new Item_nodeset_func_union(prev, xpath->item, xpath->pxml); } return 1; } /* Scan Path Expression SYNOPSYS [19] PathExpr ::= LocationPath | FilterExpr | FilterExpr '/' RelativeLocationPath | FilterExpr '//' RelativeLocationPath RETURN 1 - success 0 - failure */ static int my_xpath_parse_FilterExpr_opt_slashes_RelativeLocationPath(MY_XPATH *xpath) { Item *context= xpath->context; int rc; if (!my_xpath_parse_FilterExpr(xpath)) return 0; if (!my_xpath_parse_term(xpath, MY_XPATH_LEX_SLASH)) return 1; if (xpath->item->type() != Item::XPATH_NODESET) { xpath->lasttok= xpath->prevtok; xpath->error= 1; return 0; } /* The context for the next relative path is the nodeset returned by FilterExpr */ xpath->context= xpath->item; /* treat double slash (//) as /descendant-or-self::node()/ */ if (my_xpath_parse_term(xpath, MY_XPATH_LEX_SLASH)) xpath->context= new Item_nodeset_func_descendantbyname(xpath->context, "*", 1, xpath->pxml, 1); rc= my_xpath_parse_RelativeLocationPath(xpath); /* push back the context and restore the item */ xpath->item= xpath->context; xpath->context= context; return rc; } static int my_xpath_parse_PathExpr(MY_XPATH *xpath) { return my_xpath_parse_LocationPath(xpath) || my_xpath_parse_FilterExpr_opt_slashes_RelativeLocationPath(xpath); } /* Scan Filter Expression SYNOPSYS [20] FilterExpr ::= PrimaryExpr | FilterExpr Predicate or in other words: [20] FilterExpr ::= PrimaryExpr Predicate* RETURN 1 - success 0 - failure */ static int my_xpath_parse_FilterExpr(MY_XPATH *xpath) { return my_xpath_parse_PrimaryExpr(xpath); } /* Scan Or Expression SYNOPSYS [21] OrExpr ::= AndExpr | OrExpr 'or' AndExpr RETURN 1 - success 0 - failure */ static int my_xpath_parse_OrExpr(MY_XPATH *xpath) { if (!my_xpath_parse_AndExpr(xpath)) return 0; while (my_xpath_parse_term(xpath, MY_XPATH_LEX_OR)) { Item *prev= xpath->item; if (!my_xpath_parse_AndExpr(xpath)) { xpath->error= 1; return 0; } xpath->item= new Item_cond_or(nodeset2bool(xpath, prev), nodeset2bool(xpath, xpath->item)); } return 1; } /* Scan And Expression SYNOPSYS [22] AndExpr ::= EqualityExpr | AndExpr 'and' EqualityExpr RETURN 1 - success 0 - failure */ static int my_xpath_parse_AndExpr(MY_XPATH *xpath) { if (!my_xpath_parse_EqualityExpr(xpath)) return 0; while (my_xpath_parse_term(xpath, MY_XPATH_LEX_AND)) { Item *prev= xpath->item; if (!my_xpath_parse_EqualityExpr(xpath)) { xpath->error= 1; return 0; } xpath->item= new Item_cond_and(nodeset2bool(xpath,prev), nodeset2bool(xpath,xpath->item)); } return 1; } /* Scan Equality Expression SYNOPSYS [23] EqualityExpr ::= RelationalExpr | EqualityExpr '=' RelationalExpr | EqualityExpr '!=' RelationalExpr or in other words: [23] EqualityExpr ::= RelationalExpr ( EqualityOperator EqualityExpr )* RETURN 1 - success 0 - failure */ static int my_xpath_parse_ne(MY_XPATH *xpath) { MY_XPATH_LEX prevtok= xpath->prevtok; if (!my_xpath_parse_term(xpath, MY_XPATH_LEX_EXCL)) return 0; if (!my_xpath_parse_term(xpath, MY_XPATH_LEX_EQ)) { /* Unget the exclamation mark */ xpath->lasttok= xpath->prevtok; xpath->prevtok= prevtok; return 0; } return 1; } static int my_xpath_parse_EqualityOperator(MY_XPATH *xpath) { if (my_xpath_parse_ne(xpath)) { xpath->extra= '!'; return 1; } if (my_xpath_parse_term(xpath, MY_XPATH_LEX_EQ)) { xpath->extra= '='; return 1; } return 0; } static int my_xpath_parse_EqualityExpr(MY_XPATH *xpath) { MY_XPATH_LEX operator_context; if (!my_xpath_parse_RelationalExpr(xpath)) return 0; operator_context= xpath->lasttok; while (my_xpath_parse_EqualityOperator(xpath)) { Item *prev= xpath->item; int oper= xpath->extra; if (!my_xpath_parse_RelationalExpr(xpath)) { xpath->error= 1; return 0; } if (!(xpath->item= create_comparator(xpath, oper, &operator_context, prev, xpath->item))) return 0; operator_context= xpath->lasttok; } return 1; } /* Scan Relational Expression SYNOPSYS [24] RelationalExpr ::= AdditiveExpr | RelationalExpr '<' AdditiveExpr | RelationalExpr '>' AdditiveExpr | RelationalExpr '<=' AdditiveExpr | RelationalExpr '>=' AdditiveExpr or in other words: [24] RelationalExpr ::= AdditiveExpr (RelationalOperator RelationalExpr)* RETURN 1 - success 0 - failure */ static int my_xpath_parse_RelationalOperator(MY_XPATH *xpath) { if (my_xpath_parse_term(xpath, MY_XPATH_LEX_LESS)) { xpath->extra= my_xpath_parse_term(xpath, MY_XPATH_LEX_EQ) ? MY_XPATH_LEX_LE : MY_XPATH_LEX_LESS; return 1; } else if (my_xpath_parse_term(xpath, MY_XPATH_LEX_GREATER)) { xpath->extra= my_xpath_parse_term(xpath, MY_XPATH_LEX_EQ) ? MY_XPATH_LEX_GE : MY_XPATH_LEX_GREATER; return 1; } return 0; } static int my_xpath_parse_RelationalExpr(MY_XPATH *xpath) { MY_XPATH_LEX operator_context; if (!my_xpath_parse_AdditiveExpr(xpath)) return 0; operator_context= xpath->lasttok; while (my_xpath_parse_RelationalOperator(xpath)) { Item *prev= xpath->item; int oper= xpath->extra; if (!my_xpath_parse_AdditiveExpr(xpath)) { xpath->error= 1; return 0; } if (!(xpath->item= create_comparator(xpath, oper, &operator_context, prev, xpath->item))) return 0; operator_context= xpath->lasttok; } return 1; } /* Scan Additive Expression SYNOPSYS [25] AdditiveExpr ::= MultiplicativeExpr | AdditiveExpr '+' MultiplicativeExpr | AdditiveExpr '-' MultiplicativeExpr RETURN 1 - success 0 - failure */ static int my_xpath_parse_AdditiveOperator(MY_XPATH *xpath) { return my_xpath_parse_term(xpath, MY_XPATH_LEX_PLUS) || my_xpath_parse_term(xpath, MY_XPATH_LEX_MINUS); } static int my_xpath_parse_AdditiveExpr(MY_XPATH *xpath) { if (!my_xpath_parse_MultiplicativeExpr(xpath)) return 0; while (my_xpath_parse_AdditiveOperator(xpath)) { int oper= xpath->prevtok.term; Item *prev= xpath->item; if (!my_xpath_parse_MultiplicativeExpr(xpath)) { xpath->error= 1; return 0; } if (oper == MY_XPATH_LEX_PLUS) xpath->item= new Item_func_plus(prev, xpath->item); else xpath->item= new Item_func_minus(prev, xpath->item); }; return 1; } /* Scan Multiplicative Expression SYNOPSYS [26] MultiplicativeExpr ::= UnaryExpr | MultiplicativeExpr MultiplyOperator UnaryExpr | MultiplicativeExpr 'div' UnaryExpr | MultiplicativeExpr 'mod' UnaryExpr or in other words: [26] MultiplicativeExpr ::= UnaryExpr (MulOper MultiplicativeExpr)* RETURN 1 - success 0 - failure */ static int my_xpath_parse_MultiplicativeOperator(MY_XPATH *xpath) { return my_xpath_parse_term(xpath, MY_XPATH_LEX_ASTERISK) || my_xpath_parse_term(xpath, MY_XPATH_LEX_DIV) || my_xpath_parse_term(xpath, MY_XPATH_LEX_MOD); } static int my_xpath_parse_MultiplicativeExpr(MY_XPATH *xpath) { if (!my_xpath_parse_UnaryExpr(xpath)) return 0; while (my_xpath_parse_MultiplicativeOperator(xpath)) { int oper= xpath->prevtok.term; Item *prev= xpath->item; if (!my_xpath_parse_UnaryExpr(xpath)) { xpath->error= 1; return 0; } switch (oper) { case MY_XPATH_LEX_ASTERISK: xpath->item= new Item_func_mul(prev, xpath->item); break; case MY_XPATH_LEX_DIV: xpath->item= new Item_func_int_div(prev, xpath->item); break; case MY_XPATH_LEX_MOD: xpath->item= new Item_func_mod(prev, xpath->item); break; } } return 1; } /* Scan Unary Expression SYNOPSYS [27] UnaryExpr ::= UnionExpr | '-' UnaryExpr RETURN 1 - success 0 - failure */ static int my_xpath_parse_UnaryExpr(MY_XPATH *xpath) { if (!my_xpath_parse_term(xpath, MY_XPATH_LEX_MINUS)) return my_xpath_parse_UnionExpr(xpath); if (!my_xpath_parse_UnaryExpr(xpath)) return 0; xpath->item= new Item_func_neg(xpath->item); return 1; } /* Scan Number SYNOPSYS [30] Number ::= Digits ('.' Digits?)? | '.' Digits) or in other words: [30] Number ::= Digits | Digits '.' | Digits '.' Digits | '.' Digits Note: the last rule is not supported yet, as it is in conflict with abbreviated step. 1 + .123 does not work, 1 + 0.123 does. Perhaps it is better to move this code into lex analizer. RETURN 1 - success 0 - failure */ static int my_xpath_parse_Number(MY_XPATH *xpath) { const char *beg; if (!my_xpath_parse_term(xpath, MY_XPATH_LEX_DIGITS)) return 0; beg= xpath->prevtok.beg; if (!my_xpath_parse_term(xpath, MY_XPATH_LEX_DOT)) { xpath->item= new Item_int(xpath->prevtok.beg, xpath->prevtok.end - xpath->prevtok.beg); return 1; } my_xpath_parse_term(xpath, MY_XPATH_LEX_DIGITS); xpath->item= new Item_float(beg, xpath->prevtok.end - beg); return 1; } /* Scan NCName. SYNOPSYS The keywords AND, OR, MOD, DIV are valid identitiers when they are in identifier context: SELECT ExtractValue('
VALUE
', '/and/or/mod/div') -> VALUE RETURN 1 - success 0 - failure */ static int my_xpath_parse_NCName(MY_XPATH *xpath) { return my_xpath_parse_term(xpath, MY_XPATH_LEX_IDENT) || my_xpath_parse_term(xpath, MY_XPATH_LEX_AND) || my_xpath_parse_term(xpath, MY_XPATH_LEX_OR) || my_xpath_parse_term(xpath, MY_XPATH_LEX_MOD) || my_xpath_parse_term(xpath, MY_XPATH_LEX_DIV) ? 1 : 0; } /* QName grammar can be found in a separate document http://www.w3.org/TR/REC-xml-names/#NT-QName [6] QName ::= (Prefix ':')? LocalPart [7] Prefix ::= NCName [8] LocalPart ::= NCName */ static int my_xpath_parse_QName(MY_XPATH *xpath) { const char *beg; if (!my_xpath_parse_NCName(xpath)) return 0; beg= xpath->prevtok.beg; if (!my_xpath_parse_term(xpath, MY_XPATH_LEX_COLON)) return 1; /* Non qualified name */ if (!my_xpath_parse_NCName(xpath)) return 0; xpath->prevtok.beg= beg; return 1; } /** Scan Variable reference @details Implements parsing of two syntax structures: 1. Standard XPath syntax [36], for SP variables: VariableReference ::= '$' QName Finds a SP variable with the given name. If outside of a SP context, or variable with the given name doesn't exists, then error is returned. 2. Non-standard syntax - MySQL extension for user variables: VariableReference ::= '$' '@' QName Item, corresponding to the variable, is returned in xpath->item in both cases. @param xpath pointer to XPath structure @return Operation status @retval 1 Success @retval 0 Failure */ static int my_xpath_parse_VariableReference(MY_XPATH *xpath) { LEX_STRING name; int user_var; const char *dollar_pos; if (!my_xpath_parse_term(xpath, MY_XPATH_LEX_DOLLAR) || (!(dollar_pos= xpath->prevtok.beg)) || (!((user_var= my_xpath_parse_term(xpath, MY_XPATH_LEX_AT) && my_xpath_parse_term(xpath, MY_XPATH_LEX_IDENT))) && !my_xpath_parse_term(xpath, MY_XPATH_LEX_IDENT))) return 0; name.length= xpath->prevtok.end - xpath->prevtok.beg; name.str= (char*) xpath->prevtok.beg; if (user_var) xpath->item= new Item_func_get_user_var(name); else { sp_variable_t *spv; sp_pcontext *spc; LEX *lex; if ((lex= current_thd->lex) && (spc= lex->spcont) && (spv= spc->find_variable(&name))) { Item_splocal *splocal= new Item_splocal(name, spv->offset, spv->type, 0); #ifndef DBUG_OFF if (splocal) splocal->m_sp= lex->sphead; #endif xpath->item= (Item*) splocal; } else { xpath->item= NULL; DBUG_ASSERT(xpath->query.end > dollar_pos); uint len= xpath->query.end - dollar_pos; set_if_smaller(len, 32); my_printf_error(ER_UNKNOWN_ERROR, "Unknown XPATH variable at: '%.*s'", MYF(0), len, dollar_pos); } } return xpath->item ? 1 : 0; } /* Scan Name Test SYNOPSYS [37] NameTest ::= '*' | NCName ':' '*' | QName RETURN 1 - success 0 - failure */ static int my_xpath_parse_NodeTest_QName(MY_XPATH *xpath) { if (!my_xpath_parse_QName(xpath)) return 0; DBUG_ASSERT(xpath->context); uint len= xpath->prevtok.end - xpath->prevtok.beg; xpath->context= nametestfunc(xpath, xpath->axis, xpath->context, xpath->prevtok.beg, len); return 1; } static int my_xpath_parse_NodeTest_asterisk(MY_XPATH *xpath) { if (!my_xpath_parse_term(xpath, MY_XPATH_LEX_ASTERISK)) return 0; DBUG_ASSERT(xpath->context); xpath->context= nametestfunc(xpath, xpath->axis, xpath->context, "*", 1); return 1; } static int my_xpath_parse_NameTest(MY_XPATH *xpath) { return my_xpath_parse_NodeTest_asterisk(xpath) || my_xpath_parse_NodeTest_QName(xpath); } /* Scan an XPath expression SYNOPSYS Scan xpath expression. The expression is returned in xpath->expr. RETURN 1 - success 0 - failure */ static int my_xpath_parse(MY_XPATH *xpath, const char *str, const char *strend) { my_xpath_lex_init(&xpath->query, str, strend); my_xpath_lex_init(&xpath->prevtok, str, strend); my_xpath_lex_scan(xpath, &xpath->lasttok, str, strend); xpath->rootelement= new Item_nodeset_func_rootelement(xpath->pxml); return my_xpath_parse_Expr(xpath) && my_xpath_parse_term(xpath, MY_XPATH_LEX_EOF); } void Item_xml_str_func::fix_length_and_dec() { String *xp, tmp; MY_XPATH xpath; int rc; status_var_increment(current_thd->status_var.feature_xml); nodeset_func= 0; set_persist_maybe_null(1); if (agg_arg_charsets_for_comparison(collation, args, arg_count)) return; if (collation.collation->mbminlen > 1) { /* UCS2 is not supported */ my_printf_error(ER_UNKNOWN_ERROR, "Character set '%s' is not supported by XPATH", MYF(0), collation.collation->csname); return; } if (!args[1]->const_item()) { my_printf_error(ER_UNKNOWN_ERROR, "Only constant XPATH queries are supported", MYF(0)); return; } if (!(xp= args[1]->val_str(&tmp))) return; my_xpath_init(&xpath); xpath.cs= collation.collation; xpath.debug= 0; xpath.pxml= &pxml; pxml.set_charset(collation.collation); rc= my_xpath_parse(&xpath, xp->ptr(), xp->ptr() + xp->length()); if (!rc) { uint clen= xpath.query.end - xpath.lasttok.beg; set_if_smaller(clen, 32); my_printf_error(ER_UNKNOWN_ERROR, "XPATH syntax error: '%.*s'", MYF(0), clen, xpath.lasttok.beg); return; } nodeset_func= xpath.item; if (nodeset_func) nodeset_func->fix_fields(current_thd, &nodeset_func); max_length= MAX_BLOB_WIDTH; } #define MAX_LEVEL 256 typedef struct { uint level; String *pxml; // parsed XML uint pos[MAX_LEVEL]; // Tag position stack uint parent; // Offset of the parent of the current node } MY_XML_USER_DATA; static bool append_node(String *str, MY_XML_NODE *node) { /* If "str" doesn't have space for a new node, it will allocate two times more space that it has had so far. (2*len+512) is a heuristic value, which gave the best performance during tests. The ideas behind this formula are: - It allows to have a very small number of reallocs: about 10 reallocs on a 1Mb-long XML value. - At the same time, it avoids excessive memory use. */ if (str->reserve(sizeof(MY_XML_NODE), 2 * str->length() + 512)) return TRUE; str->q_append((const char*) node, sizeof(MY_XML_NODE)); return FALSE; } /* Process tag beginning SYNOPSYS A call-back function executed when XML parser is entering a tag or an attribue. Appends the new node into data->pxml. Increments data->level. RETURN Currently only MY_XML_OK */ extern "C" int xml_enter(MY_XML_PARSER *st,const char *attr, size_t len); int xml_enter(MY_XML_PARSER *st,const char *attr, size_t len) { MY_XML_USER_DATA *data= (MY_XML_USER_DATA*)st->user_data; uint numnodes= data->pxml->length() / sizeof(MY_XML_NODE); MY_XML_NODE node; node.parent= data->parent; // Set parent for the new node to old parent data->parent= numnodes; // Remember current node as new parent DBUG_ASSERT(data->level <= MAX_LEVEL); data->pos[data->level]= numnodes; if (data->level < MAX_LEVEL) node.level= data->level++; else return MY_XML_ERROR; node.type= st->current_node_type; // TAG or ATTR node.beg= attr; node.end= attr + len; return append_node(data->pxml, &node) ? MY_XML_ERROR : MY_XML_OK; } /* Process text node SYNOPSYS A call-back function executed when XML parser is entering into a tag or an attribue textual value. The value is appended into data->pxml. RETURN Currently only MY_XML_OK */ extern "C" int xml_value(MY_XML_PARSER *st,const char *attr, size_t len); int xml_value(MY_XML_PARSER *st,const char *attr, size_t len) { MY_XML_USER_DATA *data= (MY_XML_USER_DATA*)st->user_data; MY_XML_NODE node; node.parent= data->parent; // Set parent for the new text node to old parent node.level= data->level; node.type= MY_XML_NODE_TEXT; node.beg= attr; node.end= attr + len; return append_node(data->pxml, &node) ? MY_XML_ERROR : MY_XML_OK; } /* Leave a tag or an attribute SYNOPSYS A call-back function executed when XML parser is leaving a tag or an attribue. Decrements data->level. RETURN Currently only MY_XML_OK */ extern "C" int xml_leave(MY_XML_PARSER *st,const char *attr, size_t len); int xml_leave(MY_XML_PARSER *st,const char *attr, size_t len) { MY_XML_USER_DATA *data= (MY_XML_USER_DATA*)st->user_data; DBUG_ASSERT(data->level > 0); data->level--; MY_XML_NODE *nodes= (MY_XML_NODE*) data->pxml->ptr(); data->parent= nodes[data->parent].parent; nodes+= data->pos[data->level]; nodes->tagend= st->cur; return MY_XML_OK; } /* Parse raw XML SYNOPSYS RETURN Currently pointer to parsed XML on success 0 on parse error */ String *Item_xml_str_func::parse_xml(String *raw_xml, String *parsed_xml_buf) { MY_XML_PARSER p; MY_XML_USER_DATA user_data; int rc; parsed_xml_buf->length(0); /* Prepare XML parser */ my_xml_parser_create(&p); p.flags= MY_XML_FLAG_RELATIVE_NAMES | MY_XML_FLAG_SKIP_TEXT_NORMALIZATION; user_data.level= 0; user_data.pxml= parsed_xml_buf; user_data.parent= 0; my_xml_set_enter_handler(&p, xml_enter); my_xml_set_value_handler(&p, xml_value); my_xml_set_leave_handler(&p, xml_leave); my_xml_set_user_data(&p, (void*) &user_data); /* Add root node */ p.current_node_type= MY_XML_NODE_TAG; xml_enter(&p, raw_xml->ptr(), 0); /* Execute XML parser */ if ((rc= my_xml_parse(&p, raw_xml->ptr(), raw_xml->length())) != MY_XML_OK) { char buf[128]; my_snprintf(buf, sizeof(buf)-1, "parse error at line %d pos %lu: %s", my_xml_error_lineno(&p) + 1, (ulong) my_xml_error_pos(&p) + 1, my_xml_error_string(&p)); push_warning_printf(current_thd, MYSQL_ERROR::WARN_LEVEL_WARN, ER_WRONG_VALUE, ER(ER_WRONG_VALUE), "XML", buf); } my_xml_parser_free(&p); return rc == MY_XML_OK ? parsed_xml_buf : 0; } String *Item_func_xml_extractvalue::val_str(String *str) { String *res; null_value= 0; if (!nodeset_func || !(res= args[0]->val_str(str)) || !parse_xml(res, &pxml) || !(res= nodeset_func->val_str(&tmp_value))) { null_value= 1; return 0; } return res; } String *Item_func_xml_update::val_str(String *str) { String *res, *nodeset, *rep; null_value= 0; if (!nodeset_func || !(res= args[0]->val_str(str)) || !(rep= args[2]->val_str(&tmp_value3)) || !parse_xml(res, &pxml) || !(nodeset= nodeset_func->val_nodeset(&tmp_value2))) { null_value= 1; return 0; } MY_XML_NODE *nodebeg= (MY_XML_NODE*) pxml.ptr(); MY_XPATH_FLT *fltbeg= (MY_XPATH_FLT*) nodeset->ptr(); MY_XPATH_FLT *fltend= (MY_XPATH_FLT*) (nodeset->ptr() + nodeset->length()); /* Allow replacing of one tag only */ if (fltend - fltbeg != 1) { /* TODO: perhaps add a warning that more than one tag selected */ return res; } nodebeg+= fltbeg->num; if (!nodebeg->level) { /* Root element, without NameTest: UpdateXML(xml, '/', 'replacement'); Just return the replacement string. */ return rep; } tmp_value.length(0); tmp_value.set_charset(collation.collation); uint offs= nodebeg->type == MY_XML_NODE_TAG ? 1 : 0; tmp_value.append(res->ptr(), nodebeg->beg - res->ptr() - offs); tmp_value.append(rep->ptr(), rep->length()); const char *end= nodebeg->tagend + offs; tmp_value.append(end, res->ptr() + res->length() - end); return &tmp_value; }