// #include <algorithm>
using namespace std;
-vector<int32_t> myvector;
-vector<int32_t>::iterator it=myvector.begin();
-vector<int32_t> myvector2;
-vector<int32_t>::iterator it2=myvector2.begin();
-xml_tree * tree;
-xml_tree::tag_t tag;
-xml_tree::tag_t tag2;
+struct myclass {
+ xml_tree * tree;
+ bool operator() (int32_t i,int32_t j) {
+ return (strcmp((const char*) tree->get_text(i),
+ (const char*) tree->get_text(j))<0);}
+} myobject;
-//define a type for the lexicographic index
+void printVector(vector<int32_t> v){
+ vector<int32_t>::iterator i=v.begin();
+ if (i!=v.end()) {
+ printf("[%i", *i);
+ for (++i; i!=v.end(); ++i)
+ printf(",%i", *i);
+ printf("]\n");
+ }
+}
+//define a type for the lexicographic index
class lex_index {
public:
- //The tag ID
+ //The tag IDs
xml_tree::tag_t tag;
+ xml_tree::tag_t tag2;
//The text data
- std::vector<std::pair<std::string, xml_tree::node_t> > data;
+ vector<int32_t> tagVector;
+ vector<int32_t>::iterator tagVectorIt;
+ vector<int32_t> tag2Vector;
+ vector<int32_t>::iterator tag2VectorIt;
+ void preorderTraverse(xml_tree * tree, xml_tree::tag_t parent_tag, xml_tree::node_t node);
+ void createIndex(xml_tree * tree);
+ void print();
+};
+
+void lex_index::preorderTraverse(xml_tree * tree, xml_tree::tag_t parent_tag, xml_tree::node_t node){
+ if (tree->tag(node)==tree->PCDATA_OPEN_TAG_ID)
+ if (parent_tag==tag) tagVectorIt = tagVector.insert(tagVectorIt, tree->text_id(node));
+ else if (parent_tag==tag2) tag2VectorIt = tag2Vector.insert(tag2VectorIt, tree->text_id(node));
+ if (tree->tag(tree->first_child(node))!=0) preorderTraverse(tree,tree->tag(node),tree->first_child(node));
+ if (tree->tag(tree->next_sibling(node))!=0) preorderTraverse(tree,parent_tag,tree->next_sibling(node));
+}
+
+void lex_index::createIndex(xml_tree * tree){
+ tagVectorIt=tagVector.begin();
+ tag2VectorIt=tag2Vector.begin();
+ preorderTraverse(tree, 0, tree->first_child(tree->ROOT));
+ sort(tagVector.begin(), tagVector.end(), myobject);
+ sort(tag2Vector.begin(), tag2Vector.end(), myobject);
+}
+
+void lex_index::print(){
+ printf("%i-vector: ", tag);
+ printVector(tagVector);
+ printf("%i-vector: ", tag2);
+ printVector(tag2Vector);
+}
+
+class VectorMergeJoin {
+public:
+ xml_tree * tree;
+ //The tag IDs to be semi-joined
+ const char * tagname1;
+ const char * tagname2;
+ vector<int32_t> resultVector;
+ void mergeJoin(vector<int32_t> v1, vector<int32_t> v2);
};
+void VectorMergeJoin::mergeJoin(vector<int32_t> v1, vector<int32_t> v2){
+ vector<int32_t>::iterator i=resultVector.begin();
+ vector<int32_t>::iterator i1=v1.begin();
+ vector<int32_t>::iterator i2=v2.begin();
+ int k;
+
+ while((i1!=v1.end()) && (i2!=v2.end())){
+ k = strcmp((const char*) tree->get_text(*i1),
+ (const char*) tree->get_text(*i2));
+ if (k==0)
+ {
+ i = resultVector.insert( i, *i1 );
+ //advance left
+ i1++;
+ //advance right
+ i2++;
+ }
+ else if (k<0) i1++; //advance left
+ else i2++; //advance right
+ }
+}
+
// class prefix_treeNode {
// public:
// std::map<char, prefix_treeNode> Children;
using namespace SXSI;
-
static xml_tree*& XMLTREE(value v)
{
return Obj_val<xml_tree*>(v);
return static_cast<xml_tree::tag_t>(Int_val(i));
}
-void preorderTraverse(xml_tree::tag_t parent_tag, xml_tree::node_t node){
- if (tree->tag(node)==tree->PCDATA_OPEN_TAG_ID)
- if (parent_tag==tag) it = myvector.insert(it, tree->text_id(node));
- else if (parent_tag==tag2) it2 = myvector2.insert(it2, tree->text_id(node));
- if (tree->tag(tree->first_child(node))!=0) preorderTraverse(tree->tag(node), tree->first_child(node));
- if (tree->tag(tree->next_sibling(node))!=0) preorderTraverse(parent_tag, tree->next_sibling(node));
-}
-
-bool myfunction (int32_t i,int32_t j) {
- return (strcmp((const char*) tree->get_text(i),
- (const char*) tree->get_text(j))<0);
-}
-
-vector<int32_t> mergeJoin(vector<int32_t> v1, vector<int32_t> v2){
- vector<int32_t> v;
- vector<int32_t>::iterator i=v.begin();
- vector<int32_t>::iterator i1=v1.begin();
- vector<int32_t>::iterator i2=v2.begin();
- int k;
-
- while((i1!=v1.end()) && (i2!=v2.end())){
- k = strcmp((const char*) tree->get_text(*i1),
- (const char*) tree->get_text(*i2));
- if (k==0)
- {
- i = v.insert( i, *i1 );
- //advance left
- i1++;
- //advance right
- i2++;
- }
- else if (k<0) i1++; //advance left
- else i2++; //advance right
- }
- return(v);
-}
-
-void printIndex(const char * label, vector<int32_t> v){
- vector<int32_t>::iterator i=v.begin();
- if (i!=v.end()) {
- printf("%s-vector: [%i", label, *i);
- for (++i; i!=v.end(); ++i)
- printf(",%i", *i);
- printf("]\n");
- }
-}
-
-extern "C" value caml_build_lex_index(value vtree, value vtag, value vtag2)
+ML_BINDING value caml_build_lex_index(value vtree, value vtag, value vtag2)
{
+ if ((TAG(vtag)==-1) || (TAG(vtag2)==-1)) caml_failwith("<INVALID TAG>");
CAMLparam2(vtree, vtag);
CAMLlocal1(vindex);
- const char * s;
vindex = sxsi_alloc_custom<lex_index*>();
- tree = XMLTREE(vtree);
- tag = TAG(vtag);
- tag2 = TAG(vtag2);
- //Uncomment the following and comment the failwith line
- //LEXINDEX(vindex) = ... return a lex_index* ....
-
- if ((tag==-1) || (tag2==-1)) caml_failwith("<INVALID TAG>");
- preorderTraverse(0, tree->first_child(tree->ROOT));
- sort(myvector.begin(), myvector.end(), myfunction);
- sort(myvector2.begin(), myvector2.end(), myfunction);
- printIndex(tree->get_tag_name_by_ref(tag), myvector);
- printIndex(tree->get_tag_name_by_ref(tag2), myvector2);
- printIndex("Result" , mergeJoin(myvector, myvector2));
+ xml_tree * tree = XMLTREE(vtree);
+ myobject.tree = tree;
+
+ //create the index
+ lex_index* mylindex = new lex_index();
+ mylindex->tag = TAG(vtag);
+ mylindex->tag2 = TAG(vtag2);
+ mylindex->createIndex(tree);
+
+ //do a join
+ VectorMergeJoin* myVMJoin = new VectorMergeJoin();
+ myVMJoin->tree = tree;
+ myVMJoin->mergeJoin(mylindex->tagVector, mylindex->tag2Vector);
+ printf("Result-vector: ");
+ printVector(myVMJoin->resultVector);
+
+ LEXINDEX(vindex)=mylindex;
}
-extern "C" value caml_print_lex_index(value vindex)
+ML_BINDING value caml_print_lex_index(value vindex)
{
CAMLparam1(vindex);
lex_index* index = LEXINDEX(vindex);
//Print the index to the terminal
- caml_failwith("print_lex_index not implemented");
+ // caml_failwith("print_lex_index not implemented");
+ index->print();
CAMLreturn (Val_unit);
}