/** Routines for parsing and processing an XML document into an R/S data structure. * See Copyright for the license status of this software. */ #include "DocParse.h" #define R_USE_XML_ENCODING 1 #include "Utils.h" /* For isBlank() */ /* For the call to stat. */ #include #include #include "RSDTD.h" #include #include #include int RS_XML(setNodeClass)(xmlNodePtr node, USER_OBJECT_ ans); USER_OBJECT_ RS_XML(notifyNamespaceDefinition)(USER_OBJECT_ ns, R_XMLSettings *parserSettings); void RS_XML(ValidationWarning)(void *ctx, const char *msg, ...); void RS_XML(ValidationError)(void *ctx, const char *msg, ...); static USER_OBJECT_ convertNode(USER_OBJECT_ ans, xmlNodePtr node, R_XMLSettings *parserSettings); static void NodeTraverse(xmlNodePtr doc, USER_OBJECT_ converterFunctions, R_XMLSettings *parserSettings, int rootFirst); static USER_OBJECT_ makeSchemaReference(xmlSchemaPtr ref); USER_OBJECT_ RS_XML(libxmlVersionRuntime)(void) { return(mkString( #if LIBXML_VERSION < 21200 *__xmlParserVersion() #else xmlParserVersion #endif )); } USER_OBJECT_ RS_XML(getDefaultValiditySetting)(USER_OBJECT_ val) { #ifdef HAVE_VALIDITY // extern int xmlDoValidityCheckingDefaultValue; USER_OBJECT_ ans; ans = NEW_INTEGER(1); INTEGER_DATA(ans)[0] = xmlDoValidityCheckingDefaultValue; if(GET_LENGTH(val)) xmlDoValidityCheckingDefaultValue = INTEGER_DATA(val)[0]; return(ans); #else return(NEW_INTEGER(0)); #endif } #include void R_xmlStructuredErrorHandler(void *data, xmlErrorPtr err) { RSXML_structuredStop((SEXP) data, err); } /** Entry point for reading, parsing and converting an XML tree to an R object. fileName is the string identifying the file, and is expanded using the normal rules for an R file name. That is, it can contain environment variables, ~, etc. converterFunctions is a collection of functions used to map a node into an R object. This would normally be a closure. It is not currently used, but will be enabled in the future. skipBlankLines controls whether text elements consisting simply of white space are included in the resulting structure. The return value is a simple list with named elements file, version and children The children element is itself a list consisting of objects of class `XMLNode'. Each of these has the characteristic */ USER_OBJECT_ RS_XML(ParseTree)(USER_OBJECT_ fileName, USER_OBJECT_ converterFunctions, USER_OBJECT_ skipBlankLines, USER_OBJECT_ replaceEntities, USER_OBJECT_ asText, USER_OBJECT_ trim, USER_OBJECT_ validate, USER_OBJECT_ getDTD, USER_OBJECT_ isURL, USER_OBJECT_ addNamespaceAttributes, USER_OBJECT_ internalNodeReferences, USER_OBJECT_ s_useHTML, USER_OBJECT_ isSchema, USER_OBJECT_ fullNamespaceInfo, USER_OBJECT_ r_encoding, USER_OBJECT_ useDotNames, USER_OBJECT_ xinclude, USER_OBJECT_ errorFun, USER_OBJECT_ manageMemory, USER_OBJECT_ r_parserOptions, USER_OBJECT_ r_rootFirst) { const char *name; xmlDocPtr doc; USER_OBJECT_ rdoc, rdocObj; /* rdocObj is used to put the doc object * under R's garbage collection.*/ USER_OBJECT_ className; R_XMLSettings parserSettings; int asTextBuffer = LOGICAL_DATA(asText)[0]; int isURLDoc = LOGICAL_DATA(isURL)[0]; int useHTML = LOGICAL_DATA(s_useHTML)[0]; const char *encoding = NULL; int freeName = 0; int parserOptions = 0; int rootFirst = INTEGER(r_rootFirst)[0]; if(GET_LENGTH(r_encoding)) { encoding = CHAR(STRING_ELT(r_encoding, 0)); if(!encoding[0]) encoding = NULL; } if(Rf_length(r_parserOptions)) parserOptions = INTEGER(r_parserOptions)[0]; parserSettings.skipBlankLines = LOGICAL_DATA(skipBlankLines)[0]; parserSettings.converters = converterFunctions; parserSettings.useDotNames = LOGICAL_DATA(useDotNames)[0]; parserSettings.trim = LOGICAL_DATA(trim)[0]; parserSettings.xinclude = LOGICAL_DATA(xinclude)[0]; parserSettings.fullNamespaceInfo = LOGICAL_DATA(fullNamespaceInfo)[0]; parserSettings.internalNodeReferences = LOGICAL_DATA(internalNodeReferences)[0]; parserSettings.addAttributeNamespaces = LOGICAL_DATA(addNamespaceAttributes)[0]; parserSettings.finalize = manageMemory; if(asTextBuffer == 0) { struct stat tmp_stat; #ifdef USE_R name = CHAR(STRING_ELT(fileName, 0)); #else name = CHARACTER_DATA(fileName)[0]; #endif if(!isURLDoc && (name == NULL || stat(name, &tmp_stat) < 0)) { Rf_error("Can't find file %s", CHAR_DEREF(STRING_ELT(fileName, 0)) ); } } else { name = strdup(CHAR_DEREF(STRING_ELT(fileName, 0))); freeName = 1; } #if 0 /* Done in R now.*/ /* If one wants entities expanded directly and to appear as text. */ if(LOGICAL_DATA(replaceEntities)[0]) xmlSubstituteEntitiesDefault(1); #endif if(LOGICAL_DATA(isSchema)[0]) { xmlSchemaPtr schema = NULL; xmlSchemaParserCtxtPtr ctxt; ctxt = xmlSchemaNewParserCtxt(name); schema = xmlSchemaParse(ctxt); xmlSchemaFreeParserCtxt(ctxt); /*XXX make certain to cleanup the settings. Put a finalizer on this in makeSchemaReference. */ return(makeSchemaReference(schema)); } #ifdef RS_XML_SET_STRUCTURED_ERROR xmlSetStructuredErrorFunc(errorFun == NULL_USER_OBJECT ? NULL : errorFun, R_xmlStructuredErrorHandler); #endif if(asTextBuffer) { doc = useHTML ? htmlParseDoc(CHAR_TO_XMLCHAR(name), encoding) : xmlReadMemory(name, (int)strlen(name), NULL, encoding, parserOptions) ; /* xmlParseMemory(name, strlen(name)) */ if(doc != NULL) doc->name = (char *) xmlStrdup(CHAR_TO_XMLCHAR("")); } else { doc = useHTML ? htmlParseFile(XMLCHAR_TO_CHAR(name), encoding) : xmlReadFile(name, encoding, parserOptions) /* xmlParseFile(name) */ ; } #ifdef RS_XML_SET_STRUCTURED_ERROR xmlSetStructuredErrorFunc(NULL, NULL); #endif if(doc == NULL) { if(freeName && name) { #ifdef EXPERIMENTING free((char *) name); #endif } /*XXX Just freed the name ! */ if(errorFun != NULL_USER_OBJECT) { RSXML_structuredStop(errorFun, NULL); } else return(stop("XMLParseError", "error in creating parser for %s", name)); Rf_error("error in creating parser for %s", name); } if(TYPEOF(xinclude) == LGLSXP && LOGICAL_DATA(xinclude)[0]) { xmlXIncludeProcessFlags(doc, XML_PARSE_XINCLUDE); } else if(TYPEOF(xinclude) == INTSXP && GET_LENGTH(xinclude) > 0) { xmlXIncludeProcessFlags(doc, INTEGER(xinclude)[0]); } if(!useHTML && LOGICAL_DATA(validate)[0]) { xmlValidCtxt ctxt; ctxt.error = RS_XML(ValidationError); ctxt.warning = RS_XML(ValidationWarning); if(!xmlValidateDocument(&ctxt, doc)) { if(freeName && name) free((char *) name); Rf_error("XML document is invalid"); } } if(parserSettings.internalNodeReferences) { /* Use a different approach - pass internal nodes to the converter functions*/ if(GET_LENGTH(converterFunctions) > 0) { xmlNodePtr root; #ifdef USE_OLD_ROOT_CHILD_NAMES root = doc->root; #else root = doc->xmlRootNode; #ifdef ROOT_HAS_DTD_NODE if(root->next && root->children == NULL) root = root->next; #endif #endif PROTECT(rdocObj = R_createXMLDocRef(doc)); NodeTraverse(root, converterFunctions, &parserSettings, rootFirst); UNPROTECT(1); } PROTECT(rdoc = NULL_USER_OBJECT); } else { PROTECT(rdoc = RS_XML(convertXMLDoc)(name, doc, converterFunctions, &parserSettings)); } if(asTextBuffer && name) free((char *) name); if(!useHTML && !parserSettings.internalNodeReferences && LOGICAL_DATA(getDTD)[0]) { USER_OBJECT_ ans, klass, tmp; const char *names[] = {"doc", "dtd"}; PROTECT(ans = NEW_LIST(2)); SET_VECTOR_ELT(ans, 0, rdoc); SET_VECTOR_ELT(ans, 1, tmp = RS_XML(ConstructDTDList)(doc, 1, NULL)); PROTECT(klass = NEW_CHARACTER(1)); SET_STRING_ELT( klass, 0, mkChar("DTDList")); SET_CLASS(tmp, klass); RS_XML(SetNames)(sizeof(names)/sizeof(names[0]), names, ans); UNPROTECT(2); /* release the ans */ rdoc = ans; } if(parserSettings.internalNodeReferences && GET_LENGTH(converterFunctions) < 1) { UNPROTECT(1); return(R_createXMLDocRef(doc)); } if(!parserSettings.internalNodeReferences) { /* Set the class for the document. */ className = NEW_CHARACTER(1); PROTECT(className); SET_STRING_ELT(className, 0, mkChar(useHTML ? "HTMLDocument" : "XMLDocument")); SET_CLASS(rdoc, className); UNPROTECT(1); } UNPROTECT(1); return(rdoc); } enum { FILE_ELEMENT_NAME, VERSION_ELEMENT_NAME, CHILDREN_ELEMENT_NAME, NUM_DOC_ELEMENTS}; void NodeTraverse(xmlNodePtr root, USER_OBJECT_ converterFunctions, R_XMLSettings *parserSettings, int rootFirst) { xmlNodePtr c, tmp; c = root; while(c) { USER_OBJECT_ ref; #ifndef USE_OLD_ROOT_CHILD_NAMES tmp = c->xmlChildrenNode; #else c->childs; #endif if(!rootFirst && tmp) NodeTraverse(tmp, converterFunctions, parserSettings, rootFirst); PROTECT(ref = R_createXMLNodeRef(c, parserSettings->finalize)); convertNode(ref, c, parserSettings); UNPROTECT(1); if(rootFirst && tmp) NodeTraverse(tmp, converterFunctions, parserSettings, rootFirst); c = c->next; } } /** Returns a named list whose elements are file: the name of the file being processed. version: the XML version. root: the collection of children. */ USER_OBJECT_ RS_XML(convertXMLDoc)(const char *fileName, xmlDocPtr doc, USER_OBJECT_ converterFunctions, R_XMLSettings *parserSettings) { USER_OBJECT_ rdoc; USER_OBJECT_ rdoc_el_names, klass; int n = NUM_DOC_ELEMENTS; const char *version = ""; DECL_ENCODING_FROM_DOC(doc) PROTECT(rdoc = NEW_LIST(n)); PROTECT(rdoc_el_names = NEW_CHARACTER(n)); /* Insert the name of the file being processed */ SET_VECTOR_ELT(rdoc, FILE_ELEMENT_NAME, NEW_CHARACTER(1)); SET_STRING_ELT(VECTOR_ELT(rdoc, FILE_ELEMENT_NAME), 0, ENC_COPY_TO_USER_STRING(doc->name ? (const xmlChar*)doc->name : (const xmlChar*)fileName)); //SET_STRING_ELT(VECTOR_ELT(rdoc, FILE_ELEMENT_NAME), 0, ENC_COPY_TO_USER_STRING(doc->name ? XMLCHAR_TO_CHAR(doc->name) : fileName)); SET_STRING_ELT(rdoc_el_names, FILE_ELEMENT_NAME, COPY_TO_USER_STRING("file")); /* Insert the XML version information */ SET_VECTOR_ELT(rdoc, VERSION_ELEMENT_NAME, NEW_CHARACTER(1)); if(doc->version) version = XMLCHAR_TO_CHAR(doc->version); SET_STRING_ELT(VECTOR_ELT(rdoc, VERSION_ELEMENT_NAME), 0, COPY_TO_USER_STRING(version)); SET_STRING_ELT(rdoc_el_names, VERSION_ELEMENT_NAME, COPY_TO_USER_STRING("version")); /* Compute the nodes for this tree, recursively. Note the SIDEWAYS argument to get the sibling nodes at the root, rather than just the first and its children. */ { xmlNodePtr root; #ifdef USE_OLD_ROOT_CHILD_NAMES root = doc->root; #else root = doc->xmlRootNode; #ifdef ROOT_HAS_DTD_NODE if(root->next && root->children == NULL) root = root->next; #endif #endif SET_VECTOR_ELT(rdoc, CHILDREN_ELEMENT_NAME, RS_XML(createNodeChildren)(root, SIDEWAYS, parserSettings)); } SET_STRING_ELT(rdoc_el_names, CHILDREN_ELEMENT_NAME, COPY_TO_USER_STRING("children")); SET_NAMES(rdoc, rdoc_el_names); PROTECT(klass = NEW_CHARACTER(1)); SET_STRING_ELT(klass, 0, COPY_TO_USER_STRING("XMLDocumentContent")); SET_CLASS(rdoc, klass); UNPROTECT(3); return(rdoc); } USER_OBJECT_ processNamespaceDefinitions(xmlNs *ns, xmlNodePtr node, R_XMLSettings *parserSettings) { int n = 0; xmlNs *ptr = ns; USER_OBJECT_ ans, tmp, names; DECL_ENCODING_FROM_NODE(node) while(ptr) { ptr = ptr->next; n++; } PROTECT(ans = NEW_LIST(n)); PROTECT(names = NEW_CHARACTER(n)); for(n = 0, ptr = ns; ptr ; n++, ptr = ptr->next) { // protection suggested by rchk tmp = PROTECT(RS_XML(createNameSpaceIdentifier)(ptr,node)); (void) RS_XML(notifyNamespaceDefinition)(tmp, parserSettings); SET_VECTOR_ELT(ans, n, tmp); UNPROTECT(1); if(ptr->prefix) SET_STRING_ELT(names, n, ENC_COPY_TO_USER_STRING(XMLCHAR_TO_CHAR(ptr->prefix))); } SET_NAMES(ans, names); SET_CLASS(ans, mkString("XMLNamespaceDefinitions")); UNPROTECT(2); return(ans); } /** Creates an R object representing the specified node, and its children if recursive is non-zero. Certain types of nodes have direction controls whether we take the siblings of this node or alternatively its children. parentUserNode the previously created user-leve node for the parent of the target node. */ enum { NODE_NAME, NODE_ATTRIBUTES, NODE_CHILDREN, NODE_NAMESPACE, NODE_NAMESPACE_DEFS, NUM_NODE_ELEMENTS}; USER_OBJECT_ getNamespaceDefs(xmlNodePtr node, int recursive) { USER_OBJECT_ nsDef = NULL_USER_OBJECT; if(node->nsDef || recursive) { int numProtects = 0; xmlNs *ptr = node->nsDef; int n = 0; while(ptr) { n++; ptr = ptr->next; } PROTECT(nsDef = NEW_LIST(n)); numProtects++; ptr = node->nsDef; n = 0; while(ptr) { SET_VECTOR_ELT(nsDef, n, RS_XML(createNameSpaceIdentifier)(ptr, node)); n++; ptr = ptr->next; } if(recursive && node->children) { xmlNodePtr ptr = node->children; USER_OBJECT_ tmp; int i; PROTECT(nsDef); numProtects++; while(ptr) { PROTECT(tmp = getNamespaceDefs(ptr, 1)); /* nsDef = Rf_appendList(nsDef, tmp); */ if(Rf_length(tmp)) { n = Rf_length(nsDef); PROTECT(SET_LENGTH(nsDef, n + Rf_length(tmp))); for(i = 0; i < Rf_length(tmp); i++) SET_VECTOR_ELT(nsDef, n + i, VECTOR_ELT(tmp, i)); UNPROTECT(3); /* old nsDef, tmp, new nsDef */ PROTECT(nsDef); } else UNPROTECT(1); /* tmp */ ptr = ptr->next; } } SET_CLASS(nsDef, mkString("NamespaceDefinitionList")); UNPROTECT(numProtects); } return(nsDef); } USER_OBJECT_ RS_XML(internalNodeNamespaceDefinitions)(USER_OBJECT_ r_node, USER_OBJECT_ recursive) { xmlNodePtr node; if(TYPEOF(r_node) != EXTPTRSXP) { Rf_error("R_internalNodeNamespaceDefinitions expects InternalXMLNode objects"); } node = (xmlNodePtr) R_ExternalPtrAddr(r_node); return(getNamespaceDefs(node, LOGICAL(recursive)[0])); } static USER_OBJECT_ RS_XML(createXMLNode)(xmlNodePtr node, int recursive, int direction, R_XMLSettings *parserSettings, USER_OBJECT_ parentUserNode) { int n = NUM_NODE_ELEMENTS; USER_OBJECT_ ans; USER_OBJECT_ ans_el_names; USER_OBJECT_ nsDef = NULL_USER_OBJECT; int addValue; DECL_ENCODING_FROM_NODE(node) char *contentValue = XMLCHAR_TO_CHAR(node->content); #ifdef ROOT_HAS_DTD_NODE if(node->type == XML_DTD_NODE) return(NULL); #endif if(parserSettings->trim) { contentValue = trim(XMLCHAR_TO_CHAR(node->content)); } addValue = (contentValue && strlen(contentValue) && isBlank(contentValue) == 0); #ifdef LIBXML2 if(node->type == XML_ENTITY_DECL) return(NULL); #endif /* Drop text nodes that are blank, if that is what the user wanted. */ if(parserSettings->skipBlankLines && addValue == 0 && node->type == XML_TEXT_NODE) return(NULL); if(addValue) n++; /* If we have a */ if(node->type != XML_ELEMENT_DECL) { /* Create the default return value being a list of name, attributes, children and possibly value. */ PROTECT(ans = NEW_LIST(n)); PROTECT(ans_el_names = NEW_CHARACTER(n)); /* If there are namespace definitions within this node, */ if(node->nsDef) { nsDef = processNamespaceDefinitions(node->nsDef, node, parserSettings); SET_VECTOR_ELT(ans, NODE_NAMESPACE_DEFS, nsDef); } SET_VECTOR_ELT(ans, NODE_NAME, NEW_CHARACTER(1)); if(node->name) SET_STRING_ELT(VECTOR_ELT(ans, NODE_NAME), 0, ENC_COPY_TO_USER_STRING(XMLCHAR_TO_CHAR(node->name))); SET_VECTOR_ELT(ans, NODE_ATTRIBUTES, RS_XML(AttributeList)(node, parserSettings)); if(recursive) SET_VECTOR_ELT(ans, NODE_CHILDREN, RS_XML(createNodeChildren)(node, direction, parserSettings)); else SET_VECTOR_ELT(ans, NODE_CHILDREN, NULL_USER_OBJECT); SET_STRING_ELT(ans_el_names, NODE_NAME, mkChar("name")); SET_STRING_ELT(ans_el_names, NODE_ATTRIBUTES, mkChar("attributes")); SET_STRING_ELT(ans_el_names, NODE_CHILDREN, mkChar("children")); SET_STRING_ELT(ans_el_names, NODE_NAMESPACE, mkChar("namespace")); SET_STRING_ELT(ans_el_names, NODE_NAMESPACE_DEFS, mkChar("namespaceDefinitions")); if(node->ns) { PROTECT(nsDef = NEW_CHARACTER(1)); if(!parserSettings->fullNamespaceInfo) { if(node->ns->prefix) { SET_STRING_ELT(nsDef, 0, ENC_COPY_TO_USER_STRING(XMLCHAR_TO_CHAR(node->ns->prefix))); SET_CLASS(nsDef, mkString("XMLNamespacePrefix")); } } else { if(node->ns->href) SET_STRING_ELT(nsDef, 0, ENC_COPY_TO_USER_STRING(XMLCHAR_TO_CHAR(node->ns->href))); if(node->ns->prefix) SET_NAMES(nsDef, ScalarString(ENC_COPY_TO_USER_STRING(XMLCHAR_TO_CHAR(node->ns->prefix)))); /* XXX change! */ SET_CLASS(nsDef, mkString("XMLNamespace")); } SET_VECTOR_ELT(ans, NODE_NAMESPACE, nsDef); UNPROTECT(1); } if(addValue) { SET_STRING_ELT(ans_el_names, NUM_NODE_ELEMENTS, COPY_TO_USER_STRING("value")); SET_VECTOR_ELT(ans, NUM_NODE_ELEMENTS, NEW_CHARACTER(1)); SET_STRING_ELT(VECTOR_ELT(ans, NUM_NODE_ELEMENTS), 0, ENC_COPY_TO_USER_STRING(contentValue)); if(node->type == XML_ENTITY_REF_NODE) SET_NAMES(VECTOR_ELT(ans, NUM_NODE_ELEMENTS), ScalarString(ENC_COPY_TO_USER_STRING(node->name))); } SET_NAMES(ans, ans_el_names); /* Compute the class of this object based on the type in the XML node. */ RS_XML(setNodeClass)(node, ans); } else { /* XML_ELEMENT_DECL */ ans = NULL_USER_OBJECT; PROTECT(ans); PROTECT(ans); } /* Now invoke any user-level converters. */ if(recursive || direction) ans = convertNode(ans, node, parserSettings); UNPROTECT(1); UNPROTECT(1); return(ans); } static USER_OBJECT_ convertNode(USER_OBJECT_ ans, xmlNodePtr node, R_XMLSettings *parserSettings) { USER_OBJECT_ val = ans; if(parserSettings != NULL) { USER_OBJECT_ fun = NULL; const char *funName; if(parserSettings->xinclude && (node->type == XML_XINCLUDE_START || node->type == XML_XINCLUDE_END)) { return(NULL); } if(node->name) { funName = XMLCHAR_TO_CHAR(node->name); fun = RS_XML(findFunction)(funName, parserSettings->converters); } if(fun == NULL) { /* Didn't find the tag-specific function in the handlers. So see if there is one for this type node. */ fun = RS_XML(lookupGenericNodeConverter)(node, ans, parserSettings); } if(fun != NULL) { USER_OBJECT_ opArgs = NEW_LIST(1); PROTECT(opArgs); SET_VECTOR_ELT(opArgs, 0, ans); val = RS_XML(invokeFunction)(fun, opArgs, NULL, NULL); UNPROTECT(1); } } return(val); } const char * const XMLNodeClassHierarchy[] = {"XMLNode", "RXMLAbstractNode", "XMLAbstractNode", "oldClass"}; int RS_XML(setNodeClass)(xmlNodePtr node, USER_OBJECT_ ans) { char *className = NULL; int numEls = 1; int lenHier = sizeof(XMLNodeClassHierarchy)/sizeof(XMLNodeClassHierarchy[0]); numEls = lenHier + 1; switch(node->type) { case XML_ENTITY_REF_NODE: className = "XMLEntityRef"; break; case XML_PI_NODE: className = "XMLProcessingInstruction"; break; case XML_COMMENT_NODE: className = "XMLCommentNode"; break; case XML_TEXT_NODE: className = "XMLTextNode"; break; case XML_CDATA_SECTION_NODE: className = "XMLCDataNode"; break; #ifdef LIBXML2 case XML_ENTITY_DECL: className = "XMLEntityDeclaration"; break; #endif default: numEls--; break; } if(1) { USER_OBJECT_ Class; int ctr = 0, i; PROTECT(Class = NEW_CHARACTER(numEls)); if(className) SET_STRING_ELT(Class, ctr++, mkChar(className)); for(i = 0; i < lenHier; i++) SET_STRING_ELT(Class, ctr++, mkChar(XMLNodeClassHierarchy[i])); SET_CLASS(ans, Class); UNPROTECT(1); } return(node->type); } const char *RS_XML(NameSpaceSlotNames)[] = {"id", "uri", "local"}; enum {NAMESPACE_PREFIX_SLOT, NAMESPACE_URI_SLOT, NAMESPACE_TYPE_SLOT, NAMESPACE_NUM_SLOTS}; /** Create a local object identifying the name space used by a particular node. This is not the name space definition which would have a URL/URI and a type. */ USER_OBJECT_ RS_XML(createNameSpaceIdentifier)(xmlNs *space, xmlNodePtr node) { USER_OBJECT_ ans; DECL_ENCODING_FROM_NODE(node) if(node->nsDef) { PROTECT(ans = NEW_LIST(3)); SET_VECTOR_ELT(ans, NAMESPACE_PREFIX_SLOT, NEW_CHARACTER(1)); SET_STRING_ELT(VECTOR_ELT(ans, NAMESPACE_PREFIX_SLOT), 0, ENC_COPY_TO_USER_STRING(XMLCHAR_TO_CHAR( (space->prefix ? space->prefix : (xmlChar*)"")))); SET_VECTOR_ELT(ans, NAMESPACE_URI_SLOT, NEW_CHARACTER(1)); SET_STRING_ELT(VECTOR_ELT(ans, NAMESPACE_URI_SLOT), 0, space->href ? ENC_COPY_TO_USER_STRING(XMLCHAR_TO_CHAR(space->href)) : NA_STRING); SET_VECTOR_ELT(ans, NAMESPACE_TYPE_SLOT, NEW_LOGICAL(1)); LOGICAL_DATA(VECTOR_ELT(ans, NAMESPACE_TYPE_SLOT))[0] = (space->type == XML_LOCAL_NAMESPACE); RS_XML(SetNames)(NAMESPACE_NUM_SLOTS, RS_XML(NameSpaceSlotNames), ans); { USER_OBJECT_ klass; PROTECT(klass = NEW_CHARACTER(1)); SET_STRING_ELT(klass, 0, COPY_TO_USER_STRING("XMLNamespaceDefinition")); SET_CLASS(ans, klass); UNPROTECT(1); } UNPROTECT(1); } else { PROTECT(ans = NEW_CHARACTER(1)); if(space->prefix) SET_STRING_ELT(ans, 0, ENC_COPY_TO_USER_STRING(XMLCHAR_TO_CHAR(space->prefix))); UNPROTECT(1); } return(ans); } /** Attempt to find a function in the handler methods corresponding to the type of the node, not its specific tag name. */ USER_OBJECT_ RS_XML(lookupGenericNodeConverter)(xmlNodePtr node, USER_OBJECT_ defaultNodeValue, R_XMLSettings *parserSettings) { #define DOT(x) parserSettings->useDotNames ? "." x : x char *name; USER_OBJECT_ fun = NULL; switch(node->type) { case XML_ENTITY_REF_NODE: name = DOT("entity"); break; case XML_ENTITY_NODE: name = DOT("entity"); break; case XML_ELEMENT_NODE: name = DOT("startElement"); break; case XML_PI_NODE: name = DOT("proccesingInstruction"); break; case XML_COMMENT_NODE: name = DOT("comment"); break; case XML_TEXT_NODE: name = DOT("text"); break; case XML_CDATA_SECTION_NODE: name = DOT("cdata"); break; default: name = NULL; } if(name && name[0]) fun = RS_XML(findFunction)(name, parserSettings->converters); return(fun); } /* XXX Unravel this recursive call into a loop. Starting at the top node, fix the id to be empty. Then add the node and get the ID. Then loop over the children, and the node and call the routine on its children */ /* at a given node, make the node */ void addNodeAndChildrenToTree(xmlNodePtr node, SEXP id, SEXP e, R_XMLSettings *parserSettings, int *ctr) { SEXP tmp; xmlNodePtr n; if(!node) return; /* Create a skeleton node with no children. */ tmp = RS_XML(createXMLNode)(node, 0, 0/* doesn't matter */, parserSettings, R_NilValue);/*XXX*/ if(!tmp) return; SETCAR(CDR(e), tmp); (*ctr)++; id = Rf_eval(e, R_GlobalEnv); PROTECT(id); n = node->children; while(n) { SETCAR(CDR(CDR(e)), id); addNodeAndChildrenToTree(n, id, e, parserSettings, ctr); (*ctr)++; n = n->next; } UNPROTECT(1); } SEXP addNodesToTree(xmlNodePtr node, R_XMLSettings *parserSettings) { xmlNodePtr ptr = node; SEXP e, id; int ctr = 0; PROTECT(e = allocVector(LANGSXP, 3)); SETCAR(e, parserSettings->converters); PROTECT(id = NEW_CHARACTER(0)); ptr = node; /* loop over the sibling nodes here in case we have multiple roots, e.g. a comment, PI and a real node. See xysize.svg */ while(ptr) { SETCAR(CDR(CDR(e)), id); addNodeAndChildrenToTree(ptr, id, e, parserSettings, &ctr); ptr = ptr->next; } UNPROTECT(2); /* e, id */ return(ScalarInteger(ctr)); } /** Creates the R objects representing the children or siblings of the specified node, handling simple text cases with no children, as well as recursively processing the children. node the node whose children or siblings should be converted. direction DOWN or SIDEWAYS indicating the children or siblings should be processed, respectively. If SIDEWAYS is specified, the node itself is included in the result. parserSettings "global" information about the parsing conversion for the duration of the parser. Return list of XMLNode objects. */ USER_OBJECT_ RS_XML(createNodeChildren)(xmlNodePtr node, int direction, R_XMLSettings *parserSettings) { int n = 0, i; USER_OBJECT_ ans = NULL_USER_OBJECT; USER_OBJECT_ elNames = NULL; int unProtect = 0; xmlNodePtr base, c = (direction == SIDEWAYS) ? node : #ifndef USE_OLD_ROOT_CHILD_NAMES node->xmlChildrenNode; #else node->childs; #endif DECL_ENCODING_FROM_NODE(node) base = c; if(IS_FUNCTION(parserSettings->converters)) { return(addNodesToTree(node, parserSettings)); } /* Count the number of elements being converted. */ while(c) { c = c->next; n++; } if(n > 0) { USER_OBJECT_ tmp; USER_OBJECT_ tmpNames; int count = 0; c = base; PROTECT(ans = NEW_LIST(n)); PROTECT(elNames = NEW_CHARACTER(n)); unProtect = 2; for(i = 0; i < n; i++, c = c->next) { tmp = RS_XML(createXMLNode)(c, 1, DOWN, parserSettings, ans); if(tmp && tmp != NULL_USER_OBJECT) { SET_VECTOR_ELT(ans, count, tmp); if(c->name) SET_STRING_ELT(elNames, count, ENC_COPY_TO_USER_STRING(XMLCHAR_TO_CHAR(c->name))); count++; } } if(count < n) { /* Reset the length! */ #ifdef USE_S #else PROTECT(tmp = NEW_LIST(count)); PROTECT(tmpNames = NEW_CHARACTER(count)); for(i = 0 ; i < count ; i++) { SET_VECTOR_ELT(tmp, i, VECTOR_ELT(ans, i)); SET_STRING_ELT(tmpNames, i, STRING_ELT(elNames, i)); } ans = tmp; SET_NAMES(ans, tmpNames); UNPROTECT(4); PROTECT(ans); unProtect = 1; #endif } else { SET_NAMES(ans, elNames); } if(unProtect > 0) UNPROTECT(unProtect); } return(ans); } USER_OBJECT_ RS_XML(notifyNamespaceDefinition)(USER_OBJECT_ arg, R_XMLSettings *parserSettings) { USER_OBJECT_ fun, ans = NULL_USER_OBJECT; fun = RS_XML(findFunction)("namespace", parserSettings->converters); if(fun != NULL) { USER_OBJECT_ opArgs = NEW_LIST(1); USER_OBJECT_ tmp; PROTECT(opArgs); SET_VECTOR_ELT(opArgs, 0, arg); tmp = RS_XML(invokeFunction)(fun, opArgs, NULL, NULL); ans = tmp; UNPROTECT(1); } return(ans); } #ifdef USE_XML_VERSION_H #ifndef LIBXML_TEST_VERSION #include #endif #endif USER_OBJECT_ RS_XML(libxmlVersion)(void) { USER_OBJECT_ ans; unsigned int val; #ifdef LIBXML_VERSION_NUMBER val = LIBXML_VERSION_NUMBER; #else #ifdef LIBXML_VERSION val = LIBXML_VERSION; #else val = 0; #endif #endif ans = NEW_NUMERIC(1); NUMERIC_DATA(ans)[0] = val; return(ans); } static void notifyError(const char *msg, va_list ap, Rboolean isError) { #if 0 if(isError) { Rf_error("error in validating XML document"); } else { Rf_error("warning when validating XML document"); } #else #define BUFSIZE 2048 char buf[BUFSIZE]; memset(buf, '\0', BUFSIZE); vsnprintf(buf, BUFSIZE, msg, ap); Rf_warning("%s", buf); #endif } void RS_XML(ValidationError)(void *ctx, const char *format, ...) { char *msg = "Message unavailable"; va_list(ap); va_start(ap, format); if(strcmp(format, "%s") == 0) msg = va_arg(ap, char *); va_end(ap); notifyError(msg, ap, TRUE); } void RS_XML(ValidationWarning)(void *ctx, const char *format, ...) { char *msg = "Message unavailable"; va_list(ap); va_start(ap, format); if(strcmp(format, "%s") == 0) msg = va_arg(ap, char *); va_end(ap); notifyError(msg, ap, FALSE); } USER_OBJECT_ R_createXMLNode(USER_OBJECT_ snode, USER_OBJECT_ handlers, USER_OBJECT_ r_trim, USER_OBJECT_ r_skipBlankLines) { xmlNodePtr node = (xmlNodePtr) R_ExternalPtrAddr(snode); R_XMLSettings parserSettings; parserSettings.converters = handlers; parserSettings.trim = LOGICAL(r_trim)[0]; parserSettings.skipBlankLines = LOGICAL(r_skipBlankLines)[0]; return(RS_XML(createNodeChildren)(node, SIDEWAYS, &parserSettings)); } USER_OBJECT_ RS_XML_xmlNodeName(USER_OBJECT_ snode) { xmlNodePtr node = (xmlNodePtr) R_ExternalPtrAddr(snode); USER_OBJECT_ ans; DECL_ENCODING_FROM_NODE(node) PROTECT(ans = NEW_CHARACTER(1)); SET_STRING_ELT(ans, 0, node->name ? ENC_COPY_TO_USER_STRING(XMLCHAR_TO_CHAR(node->name)) : R_NaString); UNPROTECT(1); return(ans); } USER_OBJECT_ RS_XML_xmlNodeNamespace(USER_OBJECT_ snode) { xmlNodePtr node = (xmlNodePtr) R_ExternalPtrAddr(snode); USER_OBJECT_ ans; xmlNs *ns; DECL_ENCODING_FROM_NODE(node) ns = node->ns; if(!ns) return(NEW_CHARACTER(0)); PROTECT(ans = NEW_CHARACTER(1)); if(ns->href) SET_STRING_ELT(ans, 0, ENC_COPY_TO_USER_STRING(XMLCHAR_TO_CHAR(ns->href))); if(ns->prefix) SET_NAMES(ans, ScalarString(ENC_COPY_TO_USER_STRING(ns->prefix))); SET_CLASS(ans, mkString("XMLNamespace")); UNPROTECT(1); return(ans); } enum { R_XML_NS_ADD_PREFIX = 1, R_XML_NS_ADD_URL_DEFS = 2 }; USER_OBJECT_ RS_XML_xmlNodeAttributes(USER_OBJECT_ snode, USER_OBJECT_ addNamespaces, USER_OBJECT_ addNamespaceURLs) { xmlNodePtr node = (xmlNodePtr) R_ExternalPtrAddr(snode); R_XMLSettings parserSettings; parserSettings.addAttributeNamespaces = 0; if(LOGICAL_DATA(addNamespaces)[0]) parserSettings.addAttributeNamespaces |= R_XML_NS_ADD_PREFIX; if(LOGICAL_DATA(addNamespaceURLs)[0]) parserSettings.addAttributeNamespaces |= R_XML_NS_ADD_URL_DEFS; return(RS_XML(AttributeList)(node, &parserSettings)); } USER_OBJECT_ RS_XML_xmlNodeParent(USER_OBJECT_ snode, USER_OBJECT_ manageMemory) { xmlNodePtr node = (xmlNodePtr) R_ExternalPtrAddr(snode); if(node->parent && (node->parent->type == XML_DOCUMENT_NODE || node->parent->type == XML_HTML_DOCUMENT_NODE)) return(NULL_USER_OBJECT); return(R_createXMLNodeRef(node->parent, manageMemory)); } USER_OBJECT_ RS_XML_xmlNodeNumChildren(USER_OBJECT_ snode) { xmlNodePtr node = (xmlNodePtr) R_ExternalPtrAddr(snode); int count = 0; xmlNodePtr ptr = node->children; while(ptr) { count++; ptr = ptr->next; } return(ScalarInteger(count)); } USER_OBJECT_ RS_XML_xmlNodeChildrenReferences(USER_OBJECT_ snode, USER_OBJECT_ r_addNames, USER_OBJECT_ manageMemory) { xmlNodePtr node = (xmlNodePtr) R_ExternalPtrAddr(snode); USER_OBJECT_ ans, names = R_NilValue; int count = 0, i; xmlNodePtr ptr = node->children; int addNames = LOGICAL(r_addNames)[0]; DECL_ENCODING_FROM_NODE(node) int nprot = 0; while(ptr) { count++; ptr = ptr->next; } ptr = node->children; PROTECT(ans = NEW_LIST(count)); nprot++; if(addNames) { PROTECT(names = NEW_CHARACTER(count)); nprot++; } for(i = 0; i < count ; i++, ptr = ptr->next) { SET_VECTOR_ELT(ans, i, R_createXMLNodeRef(ptr, manageMemory)); if(addNames) SET_STRING_ELT(names, i, ENC_COPY_TO_USER_STRING(ptr->name ? ptr->name : (const xmlChar *)"")); } if(addNames) SET_NAMES(ans, names); UNPROTECT(nprot); return(ans); } USER_OBJECT_ R_getNodeChildByIndex(USER_OBJECT_ snode, USER_OBJECT_ r_index, USER_OBJECT_ manageMemory) { xmlNodePtr node = (xmlNodePtr) R_ExternalPtrAddr(snode); int count = 0, num; xmlNodePtr ptr = node->children; num = INTEGER(r_index)[0] - 1; if(num < 0) { Rf_error("cannot index an internal node with a negative number %d", num); } while(ptr && count < num) { count++; ptr = ptr->next; } return(ptr ? R_createXMLNodeRef(ptr, manageMemory) : NULL_USER_OBJECT); } static USER_OBJECT_ makeSchemaReference(xmlSchemaPtr schema) { return(R_makeRefObject(schema, "xmlSchemaRef")); /* USER_OBJECT_ ans; PROTECT(ans = R_MakeExternalPtr(schema, Rf_install("XMLSchema"), R_NilValue)); SET_CLASS(ans, mkString("XMLSchema")); UNPROTECT(1); return(ans); */ } // unused #define NO_XML_MEMORY_SHOW_ROUTINE 1 #ifndef NO_XML_MEMORY_SHOW_ROUTINE void RS_XML_MemoryShow() { xmlMemDisplay(stderr); } #endif USER_OBJECT_ RS_XML_setDocumentName(USER_OBJECT_ sdoc, USER_OBJECT_ sname) { /* if doc is NULL in C , return NULL in R If doc->name is NULL in C, return NA Otherwise, return the string. */ xmlDocPtr doc = (xmlDocPtr) R_ExternalPtrAddr(sdoc); if(!doc) { Rf_warning("NULL pointer supplied for internal document"); return(R_NilValue); } doc->URL = xmlStrdup(CHAR_TO_XMLCHAR(CHAR_DEREF(STRING_ELT(sname, 0)))); return(sdoc); } USER_OBJECT_ RS_XML_getDocumentName(USER_OBJECT_ sdoc) { /* if doc is NULL in C , return NULL in R If doc->name is NULL in C, return NA Otherwise, return the string. */ xmlDocPtr doc = (xmlDocPtr) R_ExternalPtrAddr(sdoc); USER_OBJECT_ ans; const xmlChar *encoding; if(!doc) { Rf_warning("NULL pointer supplied for internal document"); return(R_NilValue); } encoding = doc->encoding; PROTECT(ans = NEW_CHARACTER(1)); SET_STRING_ELT(ans, 0, doc->URL ? ENC_COPY_TO_USER_STRING(XMLCHAR_TO_CHAR(doc->URL)) : R_NaString); UNPROTECT(1); return(ans); } USER_OBJECT_ RS_XML_setKeepBlanksDefault(USER_OBJECT_ val) { int prev; prev = xmlKeepBlanksDefault(INTEGER(val)[0]); return(ScalarInteger(prev)); } USER_OBJECT_ RS_XML_xmlXIncludeProcessFlags(USER_OBJECT_ r_doc, USER_OBJECT_ r_flags) { xmlDocPtr doc = (xmlDocPtr) R_ExternalPtrAddr(r_doc); int ans; ans = xmlXIncludeProcessFlags(doc, INTEGER(r_flags)[0]); return(ScalarInteger(ans)); } USER_OBJECT_ RS_XML_xmlXIncludeProcessTreeFlags(USER_OBJECT_ r_node, USER_OBJECT_ r_flags) { xmlNodePtr node; int flags = INTEGER(r_flags)[0]; int n; //xmlNodePtr prev, parent; SEXP ans = R_NilValue; node = (xmlNodePtr) R_ExternalPtrAddr(r_node); //prev = node->prev; //parent = node->parent; n = xmlXIncludeProcessTreeFlags(node, flags); if(n == 0) return(R_NilValue); else if(n == -1) { Rf_error("failed in XInclude"); } #if 0 if(!prev) { fprintf(stderr, "Adding to children of %s\n", prev->name); prev = parent->children; } else { fprintf(stderr, "Adding after %s\n", prev->name); prev = prev->next; } prev = node->next; PROTECT(ans = NEW_LIST(n)); for(i = 0; i < n; i++) { SET_VECTOR_ELT(ans, i, prev ? R_createXMLNodeRef(prev) : R_NilValue); prev = prev->next; } UNPROTECT(1); #endif return(ans); } /** Create an R named list containing the attributes of the specified node. */ /* We could use the CONS mechanism rather than doing a double pass. Not certain what is quicker in this situation. Also, doesn't work that way in S4, so keep it this way. */ USER_OBJECT_ RS_XML(AttributeList)(xmlNodePtr node, R_XMLSettings *parserSettings) { USER_OBJECT_ ans = NULL_USER_OBJECT; USER_OBJECT_ ans_names; xmlAttr * atts; const xmlChar *encoding = node->doc ? node->doc->encoding : NULL; int n = 0, i; /* Count the number of attributes*/ atts = node->properties; while(atts) { n++; atts = atts->next; } if(n > 0) { SEXP ans_namespaces, ans_namespaceDefs; int nonTrivialAttrNamespaces = 0; int addNSPrefix = parserSettings->addAttributeNamespaces & R_XML_NS_ADD_PREFIX; int retNSDefs = parserSettings->addAttributeNamespaces & R_XML_NS_ADD_URL_DEFS; PROTECT(ans = NEW_CHARACTER(n)); PROTECT(ans_names = NEW_CHARACTER(n)); PROTECT(ans_namespaces = NEW_CHARACTER(n)); PROTECT(ans_namespaceDefs = NEW_CHARACTER(retNSDefs ? n : 0)); /* Loop over the attributes and create the string elements and the elements of the name vector. */ atts = node->properties; for(i=0; i < n ; i++) { /* Have to be careful that atts->val and atts->val->context are non-null. Something like kills it otherwise. */ #ifdef LIBXML2 SET_STRING_ELT(ans, i, ENC_COPY_TO_USER_STRING( XMLCHAR_TO_CHAR( ((atts->xmlChildrenNode != (xmlNode*)NULL && atts->xmlChildrenNode->content != (xmlChar*)NULL ) ? atts->xmlChildrenNode->content : (xmlChar*)"")))); #else SET_STRING_ELT(ans, i, ENC_COPY_TO_USER_STRING(XMLCHAR_TO_CHAR(((atts->val != (xmlNode*)NULL && atts->val->content != (xmlChar*)NULL ) ? atts->val->content : (xmlChar*)"")))); #endif if(atts->name) { if(addNSPrefix && atts->ns && atts->ns->prefix) { char buf[400]; snprintf(buf, 400, "%s:%s", atts->ns->prefix, atts->name); SET_STRING_ELT(ans_names, i, ENC_COPY_TO_USER_STRING(buf)); } else SET_STRING_ELT(ans_names, i, ENC_COPY_TO_USER_STRING(XMLCHAR_TO_CHAR(atts->name))); if((addNSPrefix | retNSDefs) && atts->ns && atts->ns->prefix) { SET_STRING_ELT(ans_namespaces, i, ENC_COPY_TO_USER_STRING(XMLCHAR_TO_CHAR(atts->ns->prefix))); if(retNSDefs) SET_STRING_ELT(ans_namespaceDefs, i, ENC_COPY_TO_USER_STRING(XMLCHAR_TO_CHAR(atts->ns->href))); nonTrivialAttrNamespaces++; } } atts = atts->next; } if(nonTrivialAttrNamespaces) { if(retNSDefs) Rf_setAttrib(ans_namespaces, Rf_install("names"), ans_namespaceDefs); Rf_setAttrib(ans, Rf_install("namespaces"), ans_namespaces); } SET_NAMES(ans, ans_names); UNPROTECT(4); } #if 0 else ans = NEW_CHARACTER(0); #endif return(ans); } SEXP R_getDocEncoding(SEXP r_doc) { xmlDocPtr doc = (xmlDocPtr) R_ExternalPtrAddr(r_doc); const xmlChar *encoding; SEXP ans; if(doc->type != XML_DOCUMENT_NODE && doc->type != XML_HTML_DOCUMENT_NODE) doc = ((xmlNodePtr) doc)->doc; if(!doc) return(NEW_CHARACTER(0)); encoding = doc->encoding; PROTECT(ans = NEW_CHARACTER(1)); SET_STRING_ELT(ans, 0, encoding ? CreateCharSexpWithEncoding(doc->encoding, doc->encoding) : R_NaString); UNPROTECT(1); return(ans); } int getTextElementLineNumber(xmlNodePtr node) { int val = -1; if(node->parent) val = node->parent->line; xmlNodePtr prev = node->prev; while(prev) { if(prev->line > 0) { val = prev->line; break; } prev = prev->prev; } return(val); } SEXP R_getLineNumber(SEXP r_node) { xmlNodePtr node = (xmlNodePtr) R_ExternalPtrAddr(r_node); if(!node) { return(NEW_INTEGER(0)); } // XML_GET_LINE(node) return(ScalarInteger(node->line == 0 ? getTextElementLineNumber(node) : node->line)); } SEXP R_xmlReadFile(SEXP r_filename, SEXP r_encoding, SEXP r_options) //, SEXP manageMemory) { const char *filename; const char *encoding = NULL; int options; xmlDocPtr doc; filename = CHAR_DEREF(STRING_ELT(r_filename, 0)); if(Rf_length(r_encoding)) encoding = CHAR_DEREF(STRING_ELT(r_encoding, 0)); options = INTEGER(r_options)[0]; doc = xmlReadFile(filename, encoding, options); return(R_createXMLDocRef(doc)); } SEXP R_xmlReadMemory(SEXP r_txt, SEXP len, SEXP r_encoding, SEXP r_options, SEXP r_base) //, SEXP manageMemory) { const char *txt; const char *encoding = NULL; const char *baseURL = NULL; int options; xmlDocPtr doc; txt = CHAR_DEREF(STRING_ELT(r_txt, 0)); if(Rf_length(r_encoding)) encoding = CHAR_DEREF(STRING_ELT(r_encoding, 0)); options = INTEGER(r_options)[0]; if(Rf_length(r_base)) baseURL = CHAR_DEREF(STRING_ELT(r_base, 0)); doc = xmlReadMemory(txt, INTEGER(len)[0], baseURL, encoding, options); return(R_createXMLDocRef(doc)); } #if 1 int addXInclude(xmlNodePtr ptr, SEXP *ans, int level, SEXP manageMemory) { if(ptr->type == XML_XINCLUDE_START) { int len = Rf_length(*ans) + 1; SEXP oans = *ans; // avoid sequence-point error PROTECT(*ans = SET_LENGTH(oans, len)); SET_VECTOR_ELT(*ans, len - 1, R_createXMLNodeRef(ptr, manageMemory)); UNPROTECT(1); return(1); } else return(0); } int processKids(xmlNodePtr ptr, SEXP *ans, int level, SEXP manageMemory) { xmlNodePtr kids; int count = 0; kids = ptr->children; while(kids) { count += addXInclude(kids, ans, level, manageMemory); count += processKids(kids, ans, level + 1, manageMemory); kids = kids->next; } return(count); } #if 0 int findXIncludeStartNodes(xmlNodePtr node, SEXP *ans, int level) { const char * prefix[] = {"", " ", " ", " " }; xmlNodePtr ptr = node; int count = 0; addXInclude(node, ans, level); ptr = node; while(ptr) { count += addXInclude(ptr, ans, level); count += processKids(ptr, ans, level); ptr = ptr->next; } //fprintf(stderr, "%s level = %d, %s: %p, type = %d\n", prefix[level], level, ptr->name, node, ptr->type); //fprintf(stderr, "%p, %s, level = %d, type = %d\n", ptr, ptr->name, level, ptr->type); return(count); } #endif /* This is a recursive version. We want an iterative version. */ SEXP R_findXIncludeStartNodes(SEXP r_root, SEXP manageMemory) { xmlNodePtr root; SEXP ans; root = (xmlNodePtr) R_ExternalPtrAddr(r_root); if(!root) return(R_NilValue); PROTECT(ans = allocVector(VECSXP, 0)); addXInclude(root, &ans, 0, manageMemory); processKids(root, &ans, 0, manageMemory); UNPROTECT(1); return(ans); } #endif