/* Copyright (c) 2005, 2016, Oracle and/or its affiliates. Copyright (c) 2009, 2017, MariaDB 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 */ #include #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 { THD *thd; 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(THD *thd, String *pxml_arg): Item_str_func(thd), pxml(pxml_arg) {} Item_nodeset_func(THD *thd, Item *a, String *pxml_arg): Item_str_func(thd, a), pxml(pxml_arg) {} Item_nodeset_func(THD *thd, Item *a, Item *b, String *pxml_arg): Item_str_func(thd, a, b), pxml(pxml_arg) {} Item_nodeset_func(THD *thd, Item *a, Item *b, Item *c, String *pxml_arg): Item_str_func(thd, 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(); // To avoid premature evaluation, mark all nodeset functions as non-const. used_tables_cache= RAND_TABLE_BIT; const_item_cache= false; } const char *func_name() const { return "nodeset"; } bool check_vcol_func_processor(void *arg) { return mark_unsupported_function(func_name(), arg, VCOL_IMPOSSIBLE); } }; /* Returns an XML root */ class Item_nodeset_func_rootelement :public Item_nodeset_func { public: Item_nodeset_func_rootelement(THD *thd, String *pxml): Item_nodeset_func(thd, pxml) {} const char *func_name() const { return "xpath_rootelement"; } String *val_nodeset(String *nodeset); Item *get_copy(THD *thd, MEM_ROOT *mem_root) { return get_item_copy(thd, mem_root, this); } }; /* Returns a Union of two node sets */ class Item_nodeset_func_union :public Item_nodeset_func { public: Item_nodeset_func_union(THD *thd, Item *a, Item *b, String *pxml): Item_nodeset_func(thd, a, b, pxml) {} const char *func_name() const { return "xpath_union"; } String *val_nodeset(String *nodeset); Item *get_copy(THD *thd, MEM_ROOT *mem_root) { return get_item_copy(thd, mem_root, this); } }; /* 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(THD *thd, Item *a, const char *n_arg, uint l_arg, String *pxml): Item_nodeset_func(thd, 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(THD *thd, Item *a, const char *n_arg, uint l_arg, String *pxml): Item_nodeset_func_axisbyname(thd, a, n_arg, l_arg, pxml) {} const char *func_name() const { return "xpath_selfbyname"; } String *val_nodeset(String *nodeset); Item *get_copy(THD *thd, MEM_ROOT *mem_root) { return get_item_copy(thd, mem_root, this); } }; /* Returns children */ class Item_nodeset_func_childbyname: public Item_nodeset_func_axisbyname { public: Item_nodeset_func_childbyname(THD *thd, Item *a, const char *n_arg, uint l_arg, String *pxml): Item_nodeset_func_axisbyname(thd, a, n_arg, l_arg, pxml) {} const char *func_name() const { return "xpath_childbyname"; } String *val_nodeset(String *nodeset); Item *get_copy(THD *thd, MEM_ROOT *mem_root) { return get_item_copy(thd, mem_root, this); } }; /* Returns descendants */ class Item_nodeset_func_descendantbyname: public Item_nodeset_func_axisbyname { bool need_self; public: Item_nodeset_func_descendantbyname(THD *thd, Item *a, const char *n_arg, uint l_arg, String *pxml, bool need_self_arg): Item_nodeset_func_axisbyname(thd, a, n_arg, l_arg, pxml), need_self(need_self_arg) {} const char *func_name() const { return "xpath_descendantbyname"; } String *val_nodeset(String *nodeset); Item *get_copy(THD *thd, MEM_ROOT *mem_root) { return get_item_copy(thd, mem_root, this); } }; /* Returns ancestors */ class Item_nodeset_func_ancestorbyname: public Item_nodeset_func_axisbyname { bool need_self; public: Item_nodeset_func_ancestorbyname(THD *thd, Item *a, const char *n_arg, uint l_arg, String *pxml, bool need_self_arg): Item_nodeset_func_axisbyname(thd, a, n_arg, l_arg, pxml), need_self(need_self_arg) {} const char *func_name() const { return "xpath_ancestorbyname"; } String *val_nodeset(String *nodeset); Item *get_copy(THD *thd, MEM_ROOT *mem_root) { return get_item_copy(thd, mem_root, this); } }; /* Returns parents */ class Item_nodeset_func_parentbyname: public Item_nodeset_func_axisbyname { public: Item_nodeset_func_parentbyname(THD *thd, Item *a, const char *n_arg, uint l_arg, String *pxml): Item_nodeset_func_axisbyname(thd, a, n_arg, l_arg, pxml) {} const char *func_name() const { return "xpath_parentbyname"; } String *val_nodeset(String *nodeset); Item *get_copy(THD *thd, MEM_ROOT *mem_root) { return get_item_copy(thd, mem_root, this); } }; /* Returns attributes */ class Item_nodeset_func_attributebyname: public Item_nodeset_func_axisbyname { public: Item_nodeset_func_attributebyname(THD *thd, Item *a, const char *n_arg, uint l_arg, String *pxml): Item_nodeset_func_axisbyname(thd, a, n_arg, l_arg, pxml) {} const char *func_name() const { return "xpath_attributebyname"; } String *val_nodeset(String *nodeset); Item *get_copy(THD *thd, MEM_ROOT *mem_root) { return get_item_copy(thd, mem_root, this); } }; /* 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(THD *thd, Item *a, Item *b, String *pxml): Item_nodeset_func(thd, a, b, pxml) {} const char *func_name() const { return "xpath_predicate"; } String *val_nodeset(String *nodeset); Item *get_copy(THD *thd, MEM_ROOT *mem_root) { return get_item_copy(thd, mem_root, this); } }; /* Selects nodes with a given position in context */ class Item_nodeset_func_elementbyindex :public Item_nodeset_func { public: Item_nodeset_func_elementbyindex(THD *thd, Item *a, Item *b, String *pxml): Item_nodeset_func(thd, a, b, pxml) { } const char *func_name() const { return "xpath_elementbyindex"; } String *val_nodeset(String *nodeset); Item *get_copy(THD *thd, MEM_ROOT *mem_root) { return get_item_copy(thd, mem_root, this); } }; /* 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_bool_func { String *pxml; String tmp_value; public: Item_xpath_cast_bool(THD *thd, Item *a, String *pxml_arg): Item_bool_func(thd, a), pxml(pxml_arg) {} const char *func_name() const { return "xpath_cast_bool"; } 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; } Item *get_copy(THD *thd, MEM_ROOT *mem_root) { return get_item_copy(thd, mem_root, this); } }; /* Converts its argument into a number */ class Item_xpath_cast_number :public Item_real_func { public: Item_xpath_cast_number(THD *thd, Item *a): Item_real_func(thd, a) {} const char *func_name() const { return "xpath_cast_number"; } virtual double val_real() { return args[0]->val_real(); } Item *get_copy(THD *thd, MEM_ROOT *mem_root) { return get_item_copy(thd, mem_root, this); } }; /* Context cache, for predicate */ class Item_nodeset_context_cache :public Item_nodeset_func { public: String *string_cache; Item_nodeset_context_cache(THD *thd, String *str_arg, String *pxml): Item_nodeset_func(thd, pxml), string_cache(str_arg) { } String *val_nodeset(String *res) { return string_cache; } void fix_length_and_dec() { max_length= MAX_BLOB_WIDTH; } Item *get_copy(THD *thd, MEM_ROOT *mem_root) { return get_item_copy(thd, mem_root, this); } }; class Item_func_xpath_position :public Item_long_func { String *pxml; String tmp_value; public: Item_func_xpath_position(THD *thd, Item *a, String *p): Item_long_func(thd, 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; } Item *get_copy(THD *thd, MEM_ROOT *mem_root) { return get_item_copy(thd, mem_root, this); } }; class Item_func_xpath_count :public Item_long_func { String *pxml; String tmp_value; public: Item_func_xpath_count(THD *thd, Item *a, String *p): Item_long_func(thd, 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); } Item *get_copy(THD *thd, MEM_ROOT *mem_root) { return get_item_copy(thd, mem_root, this); } }; class Item_func_xpath_sum :public Item_real_func { String *pxml; String tmp_value; public: Item_func_xpath_sum(THD *thd, Item *a, String *p): Item_real_func(thd, 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; } Item *get_copy(THD *thd, MEM_ROOT *mem_root) { return get_item_copy(thd, mem_root, this); } }; /** A string whose value may be changed during execution. */ class Item_string_xml_non_const: public Item_string { public: Item_string_xml_non_const(THD *thd, const char *str, uint length, CHARSET_INFO *cs): Item_string(thd, str, length, cs) { } bool const_item() const { return false ; } bool basic_const_item() const { return false; } void set_value(const char *str, uint length, CHARSET_INFO *cs) { str_value.set(str, length, cs); } Item *safe_charset_converter(THD *thd, CHARSET_INFO *tocs) { /* Item_string::safe_charset_converter() does not accept non-constants. Note, conversion is not really needed here anyway. */ return this; } }; class Item_nodeset_to_const_comparator :public Item_bool_func { String *pxml; String tmp_nodeset; public: Item_nodeset_to_const_comparator(THD *thd, Item *nodeset, Item *cmpfunc, String *p): Item_bool_func(thd, nodeset, cmpfunc), pxml(p) {} enum Type type() const { return XPATH_NODESET_CMP; }; const char *func_name() const { return "xpath_nodeset_to_const_comparator"; } bool check_vcol_func_processor(void *arg) { return mark_unsupported_function(func_name(), arg, VCOL_IMPOSSIBLE); } longlong val_int() { Item_func *comp= (Item_func*)args[1]; Item_string_xml_non_const *fake= (Item_string_xml_non_const*)(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->set_value(node->beg, node->end - node->beg, collation.collation); if (args[1]->val_int()) return 1; } } } return 0; } Item *get_copy(THD *thd, MEM_ROOT *mem_root) { return get_item_copy(thd, mem_root, this); } }; 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_type())) ((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 (xpath->thd->mem_root) Item_xpath_cast_bool(xpath->thd, 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(THD *thd, int oper, Item *a, Item *b) { MEM_ROOT *mem_root= thd->mem_root; switch (oper) { case '=': return new (mem_root) Item_func_eq(thd, a, b); case '!': return new (mem_root) Item_func_ne(thd, a, b); case MY_XPATH_LEX_GE: return new (mem_root) Item_func_ge(thd, a, b); case MY_XPATH_LEX_LE: return new (mem_root) Item_func_le(thd, a, b); case MY_XPATH_LEX_GREATER: return new (mem_root) Item_func_gt(thd, a, b); case MY_XPATH_LEX_LESS: return new (mem_root) Item_func_lt(thd, 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(THD *thd, int oper, Item *a, Item *b) { MEM_ROOT *mem_root= thd->mem_root; switch (oper) { case '=': return new (mem_root) Item_func_eq(thd, a, b); case '!': return new (mem_root) Item_func_ne(thd, a, b); case MY_XPATH_LEX_GE: return new (mem_root) Item_func_le(thd, a, b); case MY_XPATH_LEX_LE: return new (mem_root) Item_func_ge(thd, a, b); case MY_XPATH_LEX_GREATER: return new (mem_root) Item_func_lt(thd, a, b); case MY_XPATH_LEX_LESS: return new (mem_root) Item_func_gt(thd, 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(xpath->thd, 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_xml_non_const() argument, which will be filled to the partular value in a loop through all of the nodes in the node set. */ THD *thd= xpath->thd; Item_string *fake= (new (thd->mem_root) Item_string_xml_non_const(thd, "", 0, xpath->cs)); Item_nodeset_func *nodeset; Item *scalar, *comp; if (a->type() == Item::XPATH_NODESET) { nodeset= (Item_nodeset_func*) a; scalar= b; comp= eq_func(thd, oper, (Item*)fake, scalar); } else { nodeset= (Item_nodeset_func*) b; scalar= a; comp= eq_func_reverse(thd, oper, fake, scalar); } return (new (thd->mem_root) Item_nodeset_to_const_comparator(thd, 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) { THD *thd= xpath->thd; MEM_ROOT *mem_root= thd->mem_root; 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 (mem_root) Item_nodeset_func_ancestorbyname(thd, arg, beg, len, xpath->pxml, 0); break; case MY_XPATH_AXIS_ANCESTOR_OR_SELF: res= new (mem_root) Item_nodeset_func_ancestorbyname(thd, arg, beg, len, xpath->pxml, 1); break; case MY_XPATH_AXIS_PARENT: res= new (mem_root) Item_nodeset_func_parentbyname(thd, arg, beg, len, xpath->pxml); break; case MY_XPATH_AXIS_DESCENDANT: res= new (mem_root) Item_nodeset_func_descendantbyname(thd, arg, beg, len, xpath->pxml, 0); break; case MY_XPATH_AXIS_DESCENDANT_OR_SELF: res= new (mem_root) Item_nodeset_func_descendantbyname(thd, arg, beg, len, xpath->pxml, 1); break; case MY_XPATH_AXIS_ATTRIBUTE: res= new (mem_root) Item_nodeset_func_attributebyname(thd, arg, beg, len, xpath->pxml); break; case MY_XPATH_AXIS_SELF: res= new (mem_root) Item_nodeset_func_selfbyname(thd, arg, beg, len, xpath->pxml); break; default: res= new (mem_root) Item_nodeset_func_childbyname(thd, 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 { | } ~ \200 */ 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 (xpath->thd->mem_root) Item_bool(xpath->thd, "xpath_bool", 1); } static Item *create_func_false(MY_XPATH *xpath, Item **args, uint nargs) { return new (xpath->thd->mem_root) Item_bool(xpath->thd, "xpath_bool", 0); } static Item *create_func_not(MY_XPATH *xpath, Item **args, uint nargs) { return new (xpath->thd->mem_root) Item_func_not(xpath->thd, nodeset2bool(xpath, args[0])); } static Item *create_func_ceiling(MY_XPATH *xpath, Item **args, uint nargs) { return new (xpath->thd->mem_root) Item_func_ceiling(xpath->thd, args[0]); } static Item *create_func_floor(MY_XPATH *xpath, Item **args, uint nargs) { return new (xpath->thd->mem_root) Item_func_floor(xpath->thd, args[0]); } static Item *create_func_bool(MY_XPATH *xpath, Item **args, uint nargs) { return new (xpath->thd->mem_root) Item_xpath_cast_bool(xpath->thd, args[0], xpath->pxml); } static Item *create_func_number(MY_XPATH *xpath, Item **args, uint nargs) { return new (xpath->thd->mem_root) Item_xpath_cast_number(xpath->thd, 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 (xpath->thd->mem_root) Item_func_char_length(xpath->thd, arg) : 0; } static Item *create_func_round(MY_XPATH *xpath, Item **args, uint nargs) { return new (xpath->thd->mem_root) Item_func_round(xpath->thd, args[0], new (xpath->thd->mem_root) Item_int(xpath->thd, (char *) "0", 0, 1), 0); } static Item *create_func_last(MY_XPATH *xpath, Item **args, uint nargs) { return (xpath->context ? new (xpath->thd->mem_root) Item_func_xpath_count(xpath->thd, xpath->context, xpath->pxml) : NULL); } static Item *create_func_position(MY_XPATH *xpath, Item **args, uint nargs) { return (xpath->context ? new (xpath->thd->mem_root) Item_func_xpath_position(xpath->thd, xpath->context, xpath->pxml) : NULL); } static Item *create_func_contains(MY_XPATH *xpath, Item **args, uint nargs) { return (new (xpath->thd->mem_root) Item_xpath_cast_bool(xpath->thd, new (xpath->thd->mem_root) Item_func_locate(xpath->thd, args[0], args[1]), xpath->pxml)); } static Item *create_func_concat(MY_XPATH *xpath, Item **args, uint nargs) { return new (xpath->thd->mem_root) Item_func_concat(xpath->thd, args[0], args[1]); } static Item *create_func_substr(MY_XPATH *xpath, Item **args, uint nargs) { THD *thd= xpath->thd; if (nargs == 2) return new (thd->mem_root) Item_func_substr(thd, args[0], args[1]); return new (thd->mem_root) Item_func_substr(thd, 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 (xpath->thd->mem_root) Item_func_xpath_count(xpath->thd, 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 (xpath->thd->mem_root) Item_func_xpath_sum(xpath->thd, 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 (xpath->thd->mem_root) Item_nodeset_func_descendantbyname(xpath->thd, 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 (xpath->thd->mem_root) Item_nodeset_func_descendantbyname(xpath->thd, 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 (xpath->thd->mem_root) Item_nodeset_context_cache(xpath->thd, 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_type()) { xpath->context= new (xpath->thd->mem_root) Item_nodeset_func_predicate(xpath->thd, prev_context, xpath->item, xpath->pxml); } else { xpath->context= new (xpath->thd->mem_root) Item_nodeset_func_elementbyindex(xpath->thd, 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 (xpath->thd->mem_root) Item_nodeset_func_parentbyname(xpath->thd, 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 (xpath->thd->mem_root) Item_string(xpath->thd, 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 (xpath->thd->mem_root) Item_nodeset_func_union(xpath->thd, 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 (xpath->thd->mem_root) Item_nodeset_func_descendantbyname(xpath->thd, 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 (xpath->thd->mem_root) Item_cond_or(xpath->thd, 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 (xpath->thd->mem_root) Item_cond_and(xpath->thd, 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; THD *thd= xpath->thd; if (!my_xpath_parse_MultiplicativeExpr(xpath)) { xpath->error= 1; return 0; } if (oper == MY_XPATH_LEX_PLUS) xpath->item= new (thd->mem_root) Item_func_plus(thd, prev, xpath->item); else xpath->item= new (thd->mem_root) Item_func_minus(thd, 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; THD *thd= xpath->thd; 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 (thd->mem_root) Item_func_mul(thd, prev, xpath->item); break; case MY_XPATH_LEX_DIV: xpath->item= new (thd->mem_root) Item_func_int_div(thd, prev, xpath->item); break; case MY_XPATH_LEX_MOD: xpath->item= new (thd->mem_root) Item_func_mod(thd, 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 (xpath->thd->mem_root) Item_func_neg(xpath->thd, 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; THD *thd; if (!my_xpath_parse_term(xpath, MY_XPATH_LEX_DIGITS)) return 0; beg= xpath->prevtok.beg; thd= xpath->thd; if (!my_xpath_parse_term(xpath, MY_XPATH_LEX_DOT)) { xpath->item= new (thd->mem_root) Item_int(thd, xpath->prevtok.beg, xpath->prevtok.end - xpath->prevtok.beg); return 1; } my_xpath_parse_term(xpath, MY_XPATH_LEX_DIGITS); xpath->item= new (thd->mem_root) Item_float(thd, 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_CSTRING name; int user_var; const char *dollar_pos; THD *thd= xpath->thd; 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 (thd->mem_root) Item_func_get_user_var(thd, &name); else { sp_variable *spv; sp_pcontext *spc; LEX *lex; if ((lex= thd->lex) && (spc= lex->spcont) && (spv= spc->find_variable(&name, false))) { Item_splocal *splocal= new (thd->mem_root) Item_splocal(thd, &name, spv->offset, spv->sql_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 (xpath->thd->mem_root) Item_nodeset_func_rootelement(xpath->thd, 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() { max_length= MAX_BLOB_WIDTH; agg_arg_charsets_for_comparison(collation, args, arg_count); } bool Item_xml_str_func::fix_fields(THD *thd, Item **ref) { String *xp, tmp; MY_XPATH xpath; int rc; if (Item_str_func::fix_fields(thd, ref)) return true; status_var_increment(current_thd->status_var.feature_xml); nodeset_func= 0; 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 true; } if (!args[1]->const_item()) { my_printf_error(ER_UNKNOWN_ERROR, "Only constant XPATH queries are supported", MYF(0)); return true; } if (!(xp= args[1]->val_str(&tmp))) return false; // Will return NULL my_xpath_init(&xpath); xpath.thd= thd; xpath.cs= collation.collation; xpath.debug= 0; xpath.pxml= xml.parsed(); xml.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 true; } /* Parsing XML is a heavy operation, so if the first argument is constant, then parse XML only one time and cache the parsed representation together with raw text representation. Note, we cannot cache the entire function result even if the first and the second arguments are constants, because the XPath expression may have user and SP variable references, so the function result can vary between executions. */ if ((args[0]->const_item() && get_xml(&xml, true)) || !(nodeset_func= xpath.item)) return false; // Will return NULL return nodeset_func->fix_fields(thd, &nodeset_func); } #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 - 1) 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 false on success true on error */ bool Item_xml_str_func::XML::parse() { MY_XML_PARSER p; MY_XML_USER_DATA user_data; int rc; m_parsed_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= &m_parsed_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, m_raw_ptr->ptr(), 0); /* Execute XML parser */ if ((rc= my_xml_parse(&p, m_raw_ptr->ptr(), m_raw_ptr->length())) != MY_XML_OK) { THD *thd= current_thd; 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(thd, Sql_condition::WARN_LEVEL_WARN, ER_WRONG_VALUE, ER_THD(thd, ER_WRONG_VALUE), "XML", buf); m_raw_ptr= (String *) 0; } my_xml_parser_free(&p); return rc != MY_XML_OK; } /* Parse the raw XML from the given source, optionally cache the raw XML, remember the pointer to the raw XML. */ bool Item_xml_str_func::XML::parse(String *raw_xml, bool cache) { m_raw_ptr= raw_xml; if (cache) { m_cached= true; if (m_raw_ptr != &m_raw_buf && m_raw_buf.copy(*m_raw_ptr)) { m_raw_ptr= (String *) 0; return true; } m_raw_ptr= &m_raw_buf; } return parse(); } const MY_XML_NODE *Item_xml_str_func::XML::node(uint idx) { const MY_XML_NODE *nodebeg= (MY_XML_NODE*) m_parsed_buf.ptr(); DBUG_ASSERT(idx < m_parsed_buf.length() / sizeof (MY_XML_NODE)); return nodebeg + idx; } String *Item_func_xml_extractvalue::val_str(String *str) { String *res; null_value= 0; if (!nodeset_func || get_xml(&xml) || !(res= nodeset_func->val_str(str))) { null_value= 1; return 0; } return res; } bool Item_func_xml_update::collect_result(String *str, const MY_XML_NODE *cut, const String *replace) { uint offs= cut->type == MY_XML_NODE_TAG ? 1 : 0; const char *end= cut->tagend + offs; str->length(0); str->set_charset(collation.collation); return /* Put the XML part preceding the replaced piece */ str->append(xml.raw()->ptr(), cut->beg - xml.raw()->ptr() - offs) || /* Put the replacement */ str->append(replace->ptr(), replace->length()) || /* Put the XML part following the replaced piece */ str->append(end, xml.raw()->ptr() + xml.raw()->length() - end); } String *Item_func_xml_update::val_str(String *str) { String *nodeset, *rep; null_value= 0; if (!nodeset_func || get_xml(&xml) || !(rep= args[2]->val_str(&tmp_value3)) || !(nodeset= nodeset_func->val_nodeset(&tmp_value2))) { null_value= 1; return 0; } 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 xml.raw(); } const MY_XML_NODE *nodebeg= xml.node(fltbeg->num); if (!nodebeg->level) { /* Root element, without NameTest: UpdateXML(xml, '/', 'replacement'); Just return the replacement string. */ return rep; } return collect_result(str, nodebeg, rep) ? (String *) NULL : str; }