#include "cmPrefix.h" #include "cmGlobal.h" #include "cmFloatTypes.h" #include "cmRpt.h" #include "cmErr.h" #include "cmCtx.h" #include "cmJson.h" #include "cmMem.h" #include "cmMallocDebug.h" #include "cmLex.h" #include "cmLinkedHeap.h" #include "cmFile.h" #include "cmXml.h" #include "cmText.h" /* To Do: 1) Escape node data strings and attribute values. 2) Attribute values must be quoted by they may be quoted with either single or double quotes. 3) Consider not buffering the XML file and reading directly from the file. */ cmXmlH_t cmXmlNullHandle = cmSTATIC_NULL_HANDLE; typedef struct { cmErr_t err; // cmLHeapH_t heapH; // linked heap stores all node memory cmChar_t* b; // base of the text buffer unsigned bn; // length of the text buffer in characters cmChar_t* c; // current lexer position unsigned line; // lexer line number cmXmlNode_t* root; // root XML tree node cmXmlNode_t* doctype; // DOCTYPE node cmXmlNode_t* stack; // parsing stack } cmXml_t; cmXml_t* _cmXmlHandleToPtr( cmXmlH_t h ) { cmXml_t* p = (cmXml_t*)h.h; assert( p != NULL ); return p; } cmXmlRC_t _cmXmlFree( cmXml_t* p ) { cmXmlRC_t rc = kOkXmlRC; cmLHeapDestroy( &p->heapH ); cmMemPtrFree(&p->b); p->bn = 0; p->c = NULL; cmMemFree(p); return rc; } cmXmlRC_t cmXmlAlloc( cmCtx_t* ctx, cmXmlH_t* hp, const cmChar_t* fn ) { cmXmlRC_t rc = kOkXmlRC; cmXml_t* p = NULL; // finalize before initialize if((rc = cmXmlFree(hp)) != kOkXmlRC ) return rc; // allocate the main object record if((p = cmMemAllocZ( cmXml_t, 1 )) == NULL ) return cmErrMsg(&ctx->err,kMemAllocErrXmlRC,"Object memory allocation failed."); cmErrSetup(&p->err,&ctx->rpt,"XML Parser"); // allocate the linked heap mgr if( cmLHeapIsValid(p->heapH = cmLHeapCreate(1024,ctx)) == false ) { rc = cmErrMsg(&p->err,kMemAllocErrXmlRC,"Linked heap object allocation failed."); goto errLabel; } hp->h = p; if( fn != NULL ) if((rc = cmXmlParse(*hp,fn)) != kOkXmlRC ) hp->h = NULL; errLabel: if(rc != kOkXmlRC ) _cmXmlFree(p); return rc; } cmXmlRC_t cmXmlFree( cmXmlH_t* hp ) { cmXmlRC_t rc = kOkXmlRC; if( hp==NULL || cmXmlIsValid(*hp)==false ) return kOkXmlRC; cmXml_t* p = _cmXmlHandleToPtr(*hp); if((rc = _cmXmlFree(p)) != kOkXmlRC ) return rc; hp->h = NULL; return rc; } bool cmXmlIsValid( cmXmlH_t h ) { return h.h != NULL; } cmXmlRC_t _cmXmlSyntaxError( cmXml_t* p ) { return cmErrMsg(&p->err,kSyntaxErrorXmlRC,"Syntax error on line %i.",p->line); } cmXmlNode_t* _cmXmlNodeAlloc( cmXml_t* p, unsigned flags, const cmChar_t* label, unsigned labelN ) { cmXmlNode_t* np = cmLhAllocZ(p->heapH,cmXmlNode_t,1); np->parent = p->stack; if( p->stack != NULL ) { if( p->stack->children == NULL ) p->stack->children = np; else { cmXmlNode_t* n0p = NULL; cmXmlNode_t* n1p = p->stack->children; for(; n1p != NULL; n1p=n1p->sibling ) n0p = n1p; n0p->sibling = np; } } // all new nodes are put on the top of the stack p->stack = np; // all nodes must have a valid 'type' flag if( (flags & kTypeXmlFlags) == 0 ) { _cmXmlSyntaxError(p); return NULL; } // if this is the root node if( cmIsFlag(flags,kRootXmlFl) ) { assert( p->root == NULL ); p->root = np; } // if this is the 'doctype' node if( cmIsFlag(flags,kDoctypeXmlFl ) ) p->doctype = np; if( label != NULL ) np->label = cmLhAllocStrN(p->heapH,label,labelN); np->line = p->line; np->flags = flags; return np; } cmXmlNode_t* _cmXmlAttrAlloc( cmXml_t* p, cmXmlNode_t* np, const cmChar_t* label, unsigned labelN, const cmChar_t* value, unsigned valueN ) { cmXmlAttr_t* ap = cmLhAllocZ(p->heapH, cmXmlAttr_t,1); if( label != NULL && labelN > 0 ) ap->label = cmLhAllocStrN(p->heapH,label,labelN); if( value != NULL && valueN > 0 ) ap->value = cmLhAllocStrN(p->heapH,value,valueN); ap->link = np->attr; np->attr = ap; return np; } bool _cmXmlIsEof( cmXml_t* p ) { return p->c >= p->b + p->bn; } // Return false if EOF is encountered bool _cmXmlAdvance( cmXml_t* p ) { if( _cmXmlIsEof(p) ) return false; p->c += 1; if( *p->c == '\n' ) p->line += 1; return true; } // Advance the cursor to the next non-white char // Return a pointer to a non-space character. // Return NULL if the EOF is encountered. const cmChar_t* _cmXmlAdvanceToNextNonWhite( cmXml_t* p ) { if( _cmXmlIsEof(p) ) return NULL; while( isspace(*p->c) ) if( _cmXmlAdvance(p) == false ) return NULL; return p->c; } // Advance to the next white space character or 'c'. // Returns a pointer to a white space or 'c'. const cmChar_t* _cmXmlAdvanceToNextWhiteOr( cmXml_t* p, cmChar_t c0, cmChar_t c1 ) { if( _cmXmlIsEof(p) ) return NULL; while( isspace(*p->c)==false && *p->c!=c0 && *p->c!=c1 ) if(_cmXmlAdvance(p) == false ) return NULL; return p->c; } // Advance past leading white space followed by 's'. // Note that 's' is expected to immediately follow any leading white space. // Returns a pointer to the character after 's'. // Returns NULL if 'c' is not encountered const cmChar_t* _cmXmlAdvancePast( cmXml_t* p, const cmChar_t* s ) { if( _cmXmlIsEof(p) ) return NULL; while( isspace(*p->c) ) if( _cmXmlAdvance(p) == false ) return NULL; for(; *s && *p->c == *s; ++s ) if( _cmXmlAdvance(p) == false ) return NULL; return *s==0 ? p->c : NULL; } // Advance past the current character and then // advance to the next occurrence of 's' and return // a pointer to the last char in 's'. const cmChar_t* _cmXmlAdvanceToNext( cmXml_t* p, cmChar_t* s ) { unsigned i = 0; unsigned n = strlen(s); while( i0 && *p->c == s[i] ) { i += 1; } else { i = *p->c==s[0]; } } return p->c; } // Return the character following the current character. const cmChar_t* _cmXmlAdvanceOne( cmXml_t* p ) { if( _cmXmlAdvance(p) ) return p->c; return NULL; } cmXmlRC_t _cmXmlParseAttr( cmXml_t* p, cmChar_t endChar, cmXmlNode_t* np ) { cmXmlRC_t rc = kOkXmlRC; const cmChar_t* l0 = NULL; const cmChar_t* l1 = NULL; const cmChar_t* v0 = NULL; const cmChar_t* v1 = NULL; // advance to the next label if(( l0 = _cmXmlAdvanceToNextNonWhite(p)) == NULL ) return _cmXmlSyntaxError(p); // if the 'endChar' was encountered if( *p->c == endChar ) return kOkXmlRC; // advance past last character in label if((l1 = _cmXmlAdvanceToNextWhiteOr(p,'=',' ')) == NULL ) return _cmXmlSyntaxError(p); // advance past the next '=' if( _cmXmlAdvancePast(p,"=") == NULL ) { if( endChar=='?') { if((v1 = _cmXmlAdvanceToNext(p,"?")) != NULL ) { v0 = l1+1; goto allocLabel; } } return _cmXmlSyntaxError(p); } // advance to the next non-white character if((v0 = _cmXmlAdvanceToNextNonWhite(p)) == NULL ) return _cmXmlSyntaxError(p); // the first character in the value must be a single quote if( *p->c == '\'' ) { if((v0 = _cmXmlAdvanceOne(p)) == NULL ) return _cmXmlSyntaxError(p); // advance to the next single quote v1 = _cmXmlAdvanceToNext(p,"'"); } else { v1 = _cmXmlAdvanceToNextWhiteOr(p,endChar,' '); } if( v1 == NULL ) return _cmXmlSyntaxError(p); // advance past the ending single quote if( *p->c != endChar ) if( _cmXmlAdvanceOne(p) == NULL ) return _cmXmlSyntaxError(p); allocLabel: _cmXmlAttrAlloc(p, np, l0, l1-l0, v0, v1-v0 ); // p->c now points just past the ending single quote return rc; } cmXmlRC_t _cmXmlParseAttrList( cmXml_t* p, cmChar_t endChar, cmXmlNode_t* np ) { cmXmlRC_t rc = kOkXmlRC; while( *p->c != endChar && *p->c != '>' ) if((rc = _cmXmlParseAttr(p,endChar,np)) != kOkXmlRC ) break; if( *p->c == endChar ) { // if this node is terminated at the end of its beginning tag if( endChar == '/' ) { np->flags = cmSetFlag(np->flags,kClosedXmlFl); //p->stack = p->stack->parent; } if( _cmXmlAdvanceOne(p) == NULL ) return _cmXmlSyntaxError(p); } if( *p->c != '>' ) return _cmXmlSyntaxError(p); if( _cmXmlAdvancePast(p,">") == NULL ) return _cmXmlSyntaxError(p); // p->c is now past the ending '>' return rc; } cmXmlRC_t _cmXmlParseDoctypeToken( cmXml_t* p, cmXmlNode_t* np ) { const cmChar_t* t0 = NULL; const cmChar_t* t1 = NULL; // advance to the first char in the doctype token if((t0 = _cmXmlAdvanceToNextNonWhite(p) ) == NULL ) { return _cmXmlSyntaxError(p); } // if the end of the tag was encountered if( *p->c == '>' ) return kOkXmlRC; // if the token begins with a quote if( *p->c == '\'' ) { if((t1 = _cmXmlAdvanceToNext(p,"'")) == NULL ) return _cmXmlSyntaxError(p); if( _cmXmlAdvanceOne(p) == NULL ) return _cmXmlSyntaxError(p); } else { if((t1 = _cmXmlAdvanceToNextWhiteOr(p,'>',' ')) == NULL ) return _cmXmlSyntaxError(p); } // t1 and p->c now point just past the last character in the token return kOkXmlRC; } cmXmlRC_t _cmXmlParseDoctype( cmXml_t* p, cmXmlNode_t** newNodeRef ) { cmXmlRC_t rc = kOkXmlRC; if((*newNodeRef = _cmXmlNodeAlloc(p,kDoctypeXmlFl | kClosedXmlFl,"DOCTYPE",strlen("DOCTYPE"))) == NULL ) return cmErrLastRC(&p->err); while( *p->c != '>' ) if((rc = _cmXmlParseDoctypeToken(p,*newNodeRef)) != kOkXmlRC ) break; if( *p->c == '>' ) _cmXmlAdvanceOne(p); return rc; } // Node tags are tags that begin with a '<' and are not // followed by any special character. cmXmlRC_t _cmXmlParseNodeTag( cmXml_t* p, cmXmlNode_t** newNodeRef ) { cmXmlRC_t rc = kOkXmlRC; const cmChar_t* l0 = NULL; const cmChar_t* l1 = NULL; // Advance to the first character of the tag label. if((l0 = _cmXmlAdvanceToNextNonWhite(p)) == NULL ) return _cmXmlSyntaxError(p); // Advance to the last character following the tag label. if((l1 = _cmXmlAdvanceToNextWhiteOr(p,'/','>')) == NULL ) return _cmXmlSyntaxError(p); // Create the node. if( (*newNodeRef = _cmXmlNodeAlloc(p,kNormalXmlFl,l0,l1-l0)) == NULL ) return cmErrLastRC(&p->err); // look for attributes if((rc = _cmXmlParseAttrList(p,'/',*newNodeRef)) != kOkXmlRC ) return _cmXmlSyntaxError(p); // p->c is now past the ending '>' return rc; } cmXmlRC_t _cmXmlParseDeclTag( cmXml_t* p, cmXmlNode_t** newNodeRef ) { assert( *p->c == '?' ); const cmChar_t* l0 = NULL; const cmChar_t* l1 = NULL; if((l0 = _cmXmlAdvanceOne(p)) == NULL) return _cmXmlSyntaxError(p); if((l1 = _cmXmlAdvanceToNextWhiteOr(p,'?',' ')) == NULL ) return _cmXmlSyntaxError(p); if( (*newNodeRef = _cmXmlNodeAlloc(p,kDeclXmlFl | kClosedXmlFl,l0,l1-l0)) == NULL ) return cmErrLastRC(&p->err); return _cmXmlParseAttrList(p,'?',*newNodeRef); } cmXmlRC_t _cmXmlReadEndTag( cmXml_t* p, cmXmlNode_t* np ) { const cmChar_t* l0 = NULL; const cmChar_t* l1 = NULL; assert( *p->c == '/' ); // advance past the '/' if(( l0 = _cmXmlAdvanceOne(p)) == NULL ) return _cmXmlSyntaxError(p); // advance to the ending '>' if(( l1 = _cmXmlAdvanceToNext(p,">")) == NULL ) return _cmXmlSyntaxError(p); // advance past the if( _cmXmlAdvanceOne(p) == NULL ) return _cmXmlSyntaxError(p); // trim trailing space on label l1 -= 1; while( l1>l0 && isspace(*l1) ) --l1; // verify that the label has a length if( l0 == l1 ) return _cmXmlSyntaxError(p); assert( !isspace(*l1) ); // if the label on the top of the stack does not match this label if( strncmp( p->stack->label, l0, (l1-l0)+1 ) ) return kOkXmlRC; // since we just parsed an end-tag there should be at least one node on the stack if( p->stack == NULL ) return _cmXmlSyntaxError(p); p->stack->flags = cmSetFlag(p->stack->flags,kClosedXmlFl); // pop the stack //p->stack = p->stack->parent; return kOkXmlRC; } // *newNodeRef will be NULL on error or if the // the parsed tag was an end tag, or if the last line is comment node. cmXmlRC_t _cmXmlReadTag( cmXml_t* p, cmXmlNode_t** newNodeRef ) { cmXmlRC_t rc = kOkXmlRC; assert(newNodeRef != NULL ); *newNodeRef = NULL; // No leading '<' was found if( _cmXmlAdvancePast(p,"<") == NULL ) { // error or EOF return _cmXmlIsEof(p) ? kOkXmlRC : cmErrLastRC(&p->err); } // examine the character following the opening '<' switch( *p->c ) { // node end tag case '/': return _cmXmlReadEndTag(p,*newNodeRef); // declaration tag case '?': rc = _cmXmlParseDeclTag(p,newNodeRef); break; case '!': if( _cmXmlAdvanceOne(p) == NULL ) return _cmXmlSyntaxError(p); switch( *p->c ) { // comment node case '-': if( _cmXmlAdvancePast(p,"--") == NULL ) return _cmXmlSyntaxError(p); if( _cmXmlAdvanceToNext(p,"->") == NULL ) return _cmXmlSyntaxError(p); if( _cmXmlAdvanceOne(p) == NULL ) return _cmXmlSyntaxError(p); // p->c is just after "-->" // Recurse to avoid returning NULL in newNodeRef. // (*newNodeRef can only be NULL if we just parsed an end-tag). return _cmXmlReadTag(p,newNodeRef); // DOCTYPE node case 'D': if( _cmXmlAdvancePast(p,"DOCTYPE")==NULL ) return _cmXmlSyntaxError(p); if((rc = _cmXmlParseDoctype(p,newNodeRef)) != kOkXmlRC ) return _cmXmlSyntaxError(p); // p->c is just after ">" break; default: return _cmXmlSyntaxError(p); } break; default: // normal node if((rc = _cmXmlParseNodeTag(p,newNodeRef)) != kOkXmlRC ) return rc; // p->c is just after ">" } return rc; } cmXmlRC_t _cmXmlReadNode( cmXml_t* p, cmXmlNode_t* parent ) { cmXmlRC_t rc; while( !_cmXmlIsEof(p) ) { cmXmlNode_t* np = NULL; // Read a tag. if((rc = _cmXmlReadTag(p,&np)) != kOkXmlRC ) return rc; // If we just read the parents end-tag if( cmIsFlag(parent->flags,kClosedXmlFl) ) { assert(np==NULL && parent == p->stack ); p->stack = p->stack->parent; return rc; } if( np==NULL && p->stack==NULL) break; // if an end-tag was just read or node was created but closed then pop the stack if( np==NULL || (np==p->stack && cmIsFlag(np->flags,kClosedXmlFl)) ) p->stack = p->stack->parent; // if we just read an end-tag or a special node then there is no node-body if( np == NULL || cmIsFlag(np->flags,kClosedXmlFl) ) continue; // Advance to the node body. if( _cmXmlAdvanceToNextNonWhite(p) == NULL ) return _cmXmlSyntaxError(p); // if the the node body contains nodes if( *p->c == '<' ) { if((rc = _cmXmlReadNode(p,np)) != kOkXmlRC ) return rc; } else // the node body contains a string { const cmChar_t* s0 = p->c; const cmChar_t* s1 = NULL; if((s1 = _cmXmlAdvanceToNext(p,"<")) == NULL ) return _cmXmlSyntaxError(p); np->dataStr = cmLhAllocStrN(p->heapH,s0,s1-s0); } } return rc; } cmXmlRC_t cmXmlParse( cmXmlH_t h, const cmChar_t* fn ) { cmXmlRC_t rc = kOkXmlRC; cmXml_t* p = _cmXmlHandleToPtr(h); cmXmlNode_t* np = NULL; cmLHeapClear( p->heapH, false ); cmMemPtrFree(&p->b); if( (p->b = cmFileFnToBuf(fn, p->err.rpt, &p->bn )) == NULL ) { rc = cmErrMsg(&p->err,kMemAllocErrXmlRC,"Unable to buffer the file '%s'.",cmStringNullGuard(fn)); goto errLabel; } p->c = p->b; p->line = 1; if((np = _cmXmlNodeAlloc(p,kRootXmlFl,"root",strlen("root"))) == NULL ) { rc = cmErrMsg(&p->err,kMemAllocErrXmlRC,"Root node alloc failed."); goto errLabel; } if((rc = _cmXmlReadNode(p,np)) != kOkXmlRC ) goto errLabel; errLabel: return rc; } cmXmlRC_t cmXmlClear( cmXmlH_t h ) { cmXmlRC_t rc = kOkXmlRC; return rc; } const cmXmlNode_t* cmXmlRoot( cmXmlH_t h ) { cmXml_t* p = _cmXmlHandleToPtr(h); return p->root; } void _cmXmlPrintNode( const cmXmlNode_t* np, cmRpt_t* rpt, unsigned indent ) { cmChar_t s[ indent + 1 ]; memset(s,' ',indent); s[indent] = 0; // print indent and label cmRptPrintf(rpt,"%s%s: ",s,np->label); // print this node's attributes cmXmlAttr_t* ap = np->attr; for(; ap!=NULL; ap=ap->link) cmRptPrintf(rpt,"%s='%s' ",ap->label,ap->value); // print this nodes data string if( np->dataStr != NULL ) cmRptPrintf(rpt," (%s)",np->dataStr); cmRptPrintf(rpt,"\n"); // print this nodes children via recursion cmXmlNode_t* cnp = np->children; for(; cnp!=NULL; cnp=cnp->sibling ) _cmXmlPrintNode(cnp,rpt,indent+2); } void cmXmlPrint( cmXmlH_t h , cmRpt_t* rpt ) { cmXml_t* p = _cmXmlHandleToPtr(h); if( p->root != NULL ) _cmXmlPrintNode(p->root,rpt,0); } const cmXmlNode_t* cmXmlSearch( const cmXmlNode_t* np, const cmChar_t* label, const cmXmlAttr_t* attrV, unsigned attrN ) { // if the 'label' matches this node's label ... if( cmTextCmp(np->label,label) == 0 ) { if( attrN == 0 ) return np; unsigned matchN = 0; const cmXmlAttr_t* a = np->attr; unsigned i; // ... then check for attribute matches also. for(i=0; ilink) { if( cmTextCmp(a->label,attrV[i].label) == 0 && cmTextCmp(a->value,attrV[i].value) == 0 ) { ++matchN; // if a match was found for all attributes then the return np as the solution if( matchN == attrN ) return np; break; } } } } // this node did not match - try each of this nodes children const cmXmlNode_t* cnp = np->children; for(; cnp!=NULL; cnp=cnp->sibling) if(( np = cmXmlSearch(cnp,label,attrV,attrN)) != NULL ) return np; // a child matched // no match was found. return NULL; } const cmXmlNode_t* cmXmlSearchV( const cmXmlNode_t* np, const cmChar_t* label, const cmXmlAttr_t* attrV, unsigned attrN, va_list vl ) { while( label != NULL ) { if((np = cmXmlSearch(np,label,attrV,attrN)) == NULL ) return NULL; if((label = va_arg(vl,cmChar_t*)) != NULL) { attrV = va_arg(vl,const cmXmlAttr_t*); attrN = va_arg(vl,unsigned); } } return np; } const cmXmlNode_t* cmXmlSearchN( const cmXmlNode_t* np, const cmChar_t* label, const cmXmlAttr_t* attrV, unsigned attrN, ... ) { va_list vl; va_start(vl,attrN); np = cmXmlSearchV(np,label,attrV,attrN,vl); va_end(vl); return np; } const cmXmlAttr_t* cmXmlFindAttrib( const cmXmlNode_t* np, const cmChar_t* label ) { const cmXmlAttr_t* a = np->attr; for(; a!=NULL; a=a->link) if( cmTextCmp(a->label,label) == 0 ) return a; return NULL; } cmXmlRC_t cmXmlAttrInt( const cmXmlNode_t* np, const cmChar_t* attrLabel, int* retRef ) { const cmXmlAttr_t* a; if((a = cmXmlFindAttrib(np,attrLabel)) == NULL ) return kNodeNotFoundXmlRC; assert(retRef != NULL); *retRef = 0; if( a->value != NULL ) { errno = 0; // convert the string to an integer *retRef = strtol(a->value,NULL,10); if( errno != 0 ) return kInvalidTypeXmlRC; } return kOkXmlRC; } cmXmlRC_t cmXmlAttrUInt( const cmXmlNode_t* np, const cmChar_t* attrLabel, unsigned* retRef ) { return cmXmlAttrInt(np,attrLabel,(int*)retRef); } cmXmlRC_t cmXmlGetInt( const cmXmlNode_t* np, int* retRef, const cmChar_t* label, const cmXmlAttr_t* attrV, unsigned attrN, ... ) { cmXmlRC_t rc = kNodeNotFoundXmlRC; va_list vl; va_start(vl,attrN); // find the requsted node if((np = cmXmlSearchV(np,label,attrV,attrN,vl)) != NULL ) { // if the returned node does not have a data string if( np->dataStr == NULL ) return kInvalidTypeXmlRC; errno = 0; // convert the string to an integer strtol(np->dataStr,NULL,10); if( errno != 0 ) return kInvalidTypeXmlRC; rc = kOkXmlRC; } va_end(vl); return rc; } const cmXmlNode_t* _cmXmlNodeFindChild( const cmXmlNode_t* np, const cmChar_t* label ) { const cmXmlNode_t* cnp = np->children; for(; cnp!=NULL; cnp=cnp->sibling) if( cmTextCmp(cnp->label,label) == 0 ) return cnp; return NULL; } const cmChar_t* cmXmlNodeValueV( const cmXmlNode_t* np, va_list vl ) { const cmChar_t* label; // for each node label while( (label = va_arg(vl,const cmChar_t*)) != NULL ) if((np = _cmXmlNodeFindChild(np,label)) == NULL ) break; return np==NULL ? NULL : np->dataStr; } const cmChar_t* cmXmlNodeValue( const cmXmlNode_t* np, ... ) { va_list vl; va_start(vl,np); const cmChar_t* str = cmXmlNodeValueV(np,vl); va_end(vl); return str; } cmXmlRC_t cmXmlNodeIntV(const cmXmlNode_t* np, int* retRef, va_list vl ) { const cmChar_t* valueStr; if((valueStr = cmXmlNodeValueV(np,vl)) == NULL ) return kNodeNotFoundXmlRC; errno = 0; // convert the string to an integer *retRef = strtol(valueStr,NULL,10); if( errno != 0 ) return kInvalidTypeXmlRC; return kOkXmlRC; } cmXmlRC_t cmXmlNodeUIntV(const cmXmlNode_t* np, unsigned* retRef, va_list vl ) { return cmXmlNodeIntV(np,(int*)retRef,vl); } cmXmlRC_t cmXmlNodeDoubleV(const cmXmlNode_t* np, double* retRef, va_list vl ) { const cmChar_t* valueStr; if((valueStr = cmXmlNodeValueV(np,vl)) == NULL ) return kNodeNotFoundXmlRC; errno = 0; // convert the string to a double *retRef = strtod(valueStr,NULL); if( errno != 0 ) return kInvalidTypeXmlRC; return kOkXmlRC; } cmXmlRC_t cmXmlNodeInt( const cmXmlNode_t* np, int* retRef, ... ) { cmXmlRC_t rc; va_list vl; va_start(vl,retRef); rc = cmXmlNodeIntV(np,retRef,vl); va_end(vl); return rc; } cmXmlRC_t cmXmlNodeUInt( const cmXmlNode_t* np, unsigned* retRef, ... ) { cmXmlRC_t rc; va_list vl; va_start(vl,retRef); rc = cmXmlNodeUIntV(np,retRef,vl); va_end(vl); return rc; } cmXmlRC_t cmXmlNodeDouble(const cmXmlNode_t* np, double* retRef, ...) { cmXmlRC_t rc; va_list vl; va_start(vl,retRef); rc = cmXmlNodeDoubleV(np,retRef,vl); va_end(vl); return rc; } unsigned _cmXmlLabelCount( const cmChar_t* firstLabel, va_list vl ) { unsigned n = 0; if( firstLabel != NULL ) { n = 1; va_list vl0; va_copy(vl0,vl); while( va_arg(vl0,const cmChar_t*) != NULL ) n += 1; va_end(vl0); } return n; } const cmXmlNode_t* _cmXmlNodeHasChildR( const cmXmlNode_t* np, unsigned argIdx, const cmChar_t**argV, unsigned argN, const cmChar_t* attrLabel, const cmChar_t* valueStr) { const cmXmlNode_t* cnp = np->children; for(; cnp!=NULL; cnp=cnp->sibling) if( cmTextCmp(cnp->label,argV[argIdx]) == 0 ) { // The node path ending at cnp matches all node labels up through argV[argIdx] // if there are still node labels to match in argV[] if( argIdx < argN-1 ) return _cmXmlNodeHasChildR(cnp,argIdx+1,argV,argN,attrLabel,valueStr); // The path ending at cnp matches all node labels in argV[]. // if an attr. label was given if( attrLabel != NULL ) { const cmXmlAttr_t* a; if((a = cmXmlFindAttrib(cnp,attrLabel)) == NULL ) continue; // if a value string was given if( valueStr != NULL ) if( cmTextCmp(a->value,valueStr) != 0 ) continue; } return cnp; } return NULL; } /* const cmXmlNode_t* _cmXmlNodeHasChildR( const cmXmlNode_t* np, unsigned argIdx, const cmChar_t**argV, unsigned argN, const cmChar_t* attrLabel, const cmChar_t* valueStr) { if( argIdx == argN ) return NULL; const cmXmlNode_t* cnp = np->children; for(; cnp!=NULL; cnp=cnp->sibling) if( cmTextCmp(cnp->label,argV[argIdx]) == 0 ) { const cmXmlNode_t* tnp; if((tnp = _cmXmlNodeHasChildR(cnp,argIdx+1,argV,argN,attrLabel,valueStr)) != NULL) { if( attrLabel != NULL ) { const cmXmlAttr_t* a; if((a = cmXmlFindAttrib(tnp,attrLabel)) == NULL ) continue; if( valueStr != NULL ) { if( cmTextCmp(a->value,valueStr) != 0 ) continue; } } } if( tnp != NULL ) return tnp; } return NULL; } */ const cmXmlNode_t* _cmXmlNodeHasChildV( const cmXmlNode_t* np, const cmChar_t* label, va_list vl, unsigned argN, const cmChar_t* attrLabel, const cmChar_t* valueStr ) { unsigned i; const cmChar_t* argV[ argN+1 ]; argV[0] = label; for(i=1; i n-1 ); // an attribute label must be given. if( argN <= n-1 ) goto errLabel; argN -= n; // advance vl0 to the attribute label for(i=1; ierr,rc,"XML alloc failed."); if((rc = cmXmlParse(h,fn)) != kOkXmlRC ) goto errLabel; cmXmlAttr_t aV[] = { { "id","P1"} }; if( cmXmlSearch(cmXmlRoot(h),"part",aV,1) == NULL ) { cmErrMsg(&ctx->err,kTestFailXmlRC,"Search failed."); goto errLabel; } //cmXmlPrint(h,&ctx->rpt); errLabel: cmXmlFree(&h); return rc; }