/** @file * IPRT - XML Helper APIs. */ /* * Copyright (C) 2007-2019 Oracle Corporation * * This file is part of VirtualBox Open Source Edition (OSE), as * available from http://www.virtualbox.org. This file is free software; * you can redistribute it and/or modify it under the terms of the GNU * General Public License (GPL) as published by the Free Software * Foundation, in version 2 as it comes in the "COPYING" file of the * VirtualBox OSE distribution. VirtualBox OSE is distributed in the * hope that it will be useful, but WITHOUT ANY WARRANTY of any kind. * * The contents of this file may alternatively be used under the terms * of the Common Development and Distribution License Version 1.0 * (CDDL) only, as it comes in the "COPYING.CDDL" file of the * VirtualBox OSE distribution, in which case the provisions of the * CDDL are applicable instead of those of the GPL. * * You may elect to license modified versions of this file under the * terms and conditions of either the GPL or the CDDL or both. */ #ifndef ___iprt_xml_h #define ___iprt_xml_h #ifndef RT_WITHOUT_PRAGMA_ONCE # pragma once #endif #ifndef IN_RING3 # error "There are no XML APIs available in Ring-0 Context!" #endif #include #include #include #include #include /** @defgroup grp_rt_cpp_xml C++ XML support * @ingroup grp_rt_cpp * @{ */ /* Forwards */ typedef struct _xmlParserInput xmlParserInput; typedef xmlParserInput *xmlParserInputPtr; typedef struct _xmlParserCtxt xmlParserCtxt; typedef xmlParserCtxt *xmlParserCtxtPtr; typedef struct _xmlError xmlError; typedef xmlError *xmlErrorPtr; typedef struct _xmlAttr xmlAttr; typedef struct _xmlNode xmlNode; /** @} */ namespace xml { /** * @addtogroup grp_rt_cpp_xml * @{ */ // Exceptions ////////////////////////////////////////////////////////////////////////////// class RT_DECL_CLASS LogicError : public RTCError { public: LogicError(const char *aMsg = NULL) : RTCError(aMsg) {} LogicError(RT_SRC_POS_DECL); }; class RT_DECL_CLASS RuntimeError : public RTCError { public: RuntimeError(const char *aMsg = NULL) : RTCError(aMsg) {} }; class RT_DECL_CLASS XmlError : public RuntimeError { public: XmlError(xmlErrorPtr aErr); static char* Format(xmlErrorPtr aErr); }; // Logical errors ////////////////////////////////////////////////////////////////////////////// class RT_DECL_CLASS ENotImplemented : public LogicError { public: ENotImplemented(const char *aMsg = NULL) : LogicError(aMsg) {} ENotImplemented(RT_SRC_POS_DECL) : LogicError(RT_SRC_POS_ARGS) {} }; class RT_DECL_CLASS EInvalidArg : public LogicError { public: EInvalidArg(const char *aMsg = NULL) : LogicError(aMsg) {} EInvalidArg(RT_SRC_POS_DECL) : LogicError(RT_SRC_POS_ARGS) {} }; class RT_DECL_CLASS EDocumentNotEmpty : public LogicError { public: EDocumentNotEmpty(const char *aMsg = NULL) : LogicError(aMsg) {} EDocumentNotEmpty(RT_SRC_POS_DECL) : LogicError(RT_SRC_POS_ARGS) {} }; class RT_DECL_CLASS ENodeIsNotElement : public LogicError { public: ENodeIsNotElement(const char *aMsg = NULL) : LogicError(aMsg) {} ENodeIsNotElement(RT_SRC_POS_DECL) : LogicError(RT_SRC_POS_ARGS) {} }; // Runtime errors ////////////////////////////////////////////////////////////////////////////// class RT_DECL_CLASS EIPRTFailure : public RuntimeError { public: EIPRTFailure(int aRC, const char *pcszContext, ...); int rc() const { return mRC; } private: int mRC; }; /** * The Stream class is a base class for I/O streams. */ class RT_DECL_CLASS Stream { public: virtual ~Stream() {} virtual const char *uri() const = 0; /** * Returns the current read/write position in the stream. The returned * position is a zero-based byte offset from the beginning of the file. * * Throws ENotImplemented if this operation is not implemented for the * given stream. */ virtual uint64_t pos() const = 0; /** * Sets the current read/write position in the stream. * * @param aPos Zero-based byte offset from the beginning of the stream. * * Throws ENotImplemented if this operation is not implemented for the * given stream. */ virtual void setPos (uint64_t aPos) = 0; }; /** * The Input class represents an input stream. * * This input stream is used to read the settings tree from. * This is an abstract class that must be subclassed in order to fill it with * useful functionality. */ class RT_DECL_CLASS Input : virtual public Stream { public: /** * Reads from the stream to the supplied buffer. * * @param aBuf Buffer to store read data to. * @param aLen Buffer length. * * @return Number of bytes read. */ virtual int read (char *aBuf, int aLen) = 0; }; /** * */ class RT_DECL_CLASS Output : virtual public Stream { public: /** * Writes to the stream from the supplied buffer. * * @param aBuf Buffer to write data from. * @param aLen Buffer length. * * @return Number of bytes written. */ virtual int write (const char *aBuf, int aLen) = 0; /** * Truncates the stream from the current position and upto the end. * The new file size will become exactly #pos() bytes. * * Throws ENotImplemented if this operation is not implemented for the * given stream. */ virtual void truncate() = 0; }; ////////////////////////////////////////////////////////////////////////////// /** * The File class is a stream implementation that reads from and writes to * regular files. * * The File class uses IPRT File API for file operations. Note that IPRT File * API is not thread-safe. This means that if you pass the same RTFILE handle to * different File instances that may be simultaneously used on different * threads, you should care about serialization; otherwise you will get garbage * when reading from or writing to such File instances. */ class RT_DECL_CLASS File : public Input, public Output { public: /** * Possible file access modes. */ enum Mode { Mode_Read, Mode_WriteCreate, Mode_Overwrite, Mode_ReadWrite }; /** * Opens a file with the given name in the given mode. If @a aMode is Read * or ReadWrite, the file must exist. If @a aMode is Write, the file must * not exist. Otherwise, an EIPRTFailure excetion will be thrown. * * @param aMode File mode. * @param aFileName File name. * @param aFlushIt Whether to flush a writable file before closing it. */ File(Mode aMode, const char *aFileName, bool aFlushIt = false); /** * Uses the given file handle to perform file operations. This file * handle must be already open in necessary mode (read, or write, or mixed). * * The read/write position of the given handle will be reset to the * beginning of the file on success. * * Note that the given file handle will not be automatically closed upon * this object destruction. * * @note It you pass the same RTFILE handle to more than one File instance, * please make sure you have provided serialization in case if these * instasnces are to be simultaneously used by different threads. * Otherwise you may get garbage when reading or writing. * * @param aHandle Open file handle. * @param aFileName File name (for reference). * @param aFlushIt Whether to flush a writable file before closing it. */ File(RTFILE aHandle, const char *aFileName = NULL, bool aFlushIt = false); /** * Destroys the File object. If the object was created from a file name * the corresponding file will be automatically closed. If the object was * created from a file handle, it will remain open. */ virtual ~File(); const char *uri() const; uint64_t pos() const; void setPos(uint64_t aPos); /** * See Input::read(). If this method is called in wrong file mode, * LogicError will be thrown. */ int read(char *aBuf, int aLen); /** * See Output::write(). If this method is called in wrong file mode, * LogicError will be thrown. */ int write(const char *aBuf, int aLen); /** * See Output::truncate(). If this method is called in wrong file mode, * LogicError will be thrown. */ void truncate(); private: /* Obscure class data */ struct Data; Data *m; /* auto_ptr data doesn't have proper copy semantics */ DECLARE_CLS_COPY_CTOR_ASSIGN_NOOP(File); }; /** * The MemoryBuf class represents a stream implementation that reads from the * memory buffer. */ class RT_DECL_CLASS MemoryBuf : public Input { public: MemoryBuf (const char *aBuf, size_t aLen, const char *aURI = NULL); virtual ~MemoryBuf(); const char *uri() const; int read(char *aBuf, int aLen); uint64_t pos() const; void setPos(uint64_t aPos); private: /* Obscure class data */ struct Data; Data *m; /* auto_ptr data doesn't have proper copy semantics */ DECLARE_CLS_COPY_CTOR_ASSIGN_NOOP(MemoryBuf); }; /* * GlobalLock * * */ typedef xmlParserInput* FNEXTERNALENTITYLOADER(const char *aURI, const char *aID, xmlParserCtxt *aCtxt); typedef FNEXTERNALENTITYLOADER *PFNEXTERNALENTITYLOADER; class RT_DECL_CLASS GlobalLock { public: GlobalLock(); ~GlobalLock(); void setExternalEntityLoader(PFNEXTERNALENTITYLOADER pFunc); static xmlParserInput* callDefaultLoader(const char *aURI, const char *aID, xmlParserCtxt *aCtxt); private: /* Obscure class data. */ struct Data; struct Data *m; }; class ElementNode; typedef std::list ElementNodesList; class AttributeNode; class ContentNode; /** * Node base class. * * Cannot be used directly, but ElementNode, ContentNode and AttributeNode * derive from this. This does implement useful public methods though. * * */ class RT_DECL_CLASS Node { public: virtual ~Node(); const char *getName() const; const char *getPrefix() const; const char *getNamespaceURI() const; bool nameEqualsNS(const char *pcszNamespace, const char *pcsz) const; bool nameEquals(const char *pcsz) const { return nameEqualsNS(NULL, pcsz); } bool nameEqualsN(const char *pcsz, size_t cchMax, const char *pcszNamespace = NULL) const; const char *getValue() const; bool copyValue(int32_t &i) const; bool copyValue(uint32_t &i) const; bool copyValue(int64_t &i) const; bool copyValue(uint64_t &i) const; /** @name Introspection. * @{ */ /** Is this an ElementNode instance. * @returns true / false */ bool isElement() const { return m_Type == IsElement; } /** Is this an ContentNode instance. * @returns true / false */ bool isContent() const { return m_Type == IsContent; } /** Is this an AttributeNode instance. * @returns true / false */ bool isAttribute() const { return m_Type == IsElement; } int getLineNumber() const; /** @} */ /** @name General tree enumeration. * * Use the introspection methods isElement() and isContent() before doing static * casting. Parents are always or ElementNode type, but siblings and children * can be of both ContentNode and ElementNode types. * * @remarks Attribute node are in the attributes list, while both content and * element nodes are in the list of children. See ElementNode. * * @remarks Careful mixing tree walking with node removal! * @{ */ /** Get the parent node * @returns Pointer to the parent node, or NULL if root. */ const Node *getParent() const { return m_pParent; } /** Get the previous sibling. * @returns Pointer to the previous sibling node, NULL if first child. */ const Node *getPrevSibiling() const { if (!m_pParentListAnchor) return NULL; return RTListGetPrevCpp(m_pParentListAnchor, this, const Node, m_listEntry); } /** Get the next sibling. * @returns Pointer to the next sibling node, NULL if last child. */ const Node *getNextSibiling() const { if (!m_pParentListAnchor) return NULL; return RTListGetNextCpp(m_pParentListAnchor, this, const Node, m_listEntry); } /** @} */ protected: /** Node types. */ typedef enum { IsElement, IsAttribute, IsContent } EnumType; /** The type of node this is an instance of. */ EnumType m_Type; /** The parent node (always an element), NULL if root. */ Node *m_pParent; xmlNode *m_pLibNode; ///< != NULL if this is an element or content node xmlAttr *m_pLibAttr; ///< != NULL if this is an attribute node const char *m_pcszNamespacePrefix; ///< not always set const char *m_pcszNamespaceHref; ///< full http:// spec const char *m_pcszName; ///< element or attribute name, points either into pLibNode or pLibAttr; ///< NULL if this is a content node /** Child list entry of this node. (List head m_pParent->m_children.) */ RTLISTNODE m_listEntry; /** Pointer to the parent list anchor. * This allows us to use m_listEntry both for children and attributes. */ PRTLISTANCHOR m_pParentListAnchor; // hide the default constructor so people use only our factory methods Node(EnumType type, Node *pParent, PRTLISTANCHOR pListAnchor, xmlNode *pLibNode, xmlAttr *pLibAttr); Node(const Node &x); // no copying friend class AttributeNode; friend class ElementNode; /* C list hack. */ }; /** * Node subclass that represents an attribute of an element. * * For attributes, Node::getName() returns the attribute name, and Node::getValue() * returns the attribute value, if any. * * Since the Node constructor is private, one can create new attribute nodes * only through the following factory methods: * * -- ElementNode::setAttribute() */ class RT_DECL_CLASS AttributeNode : public Node { public: protected: // hide the default constructor so people use only our factory methods AttributeNode(const ElementNode *pElmRoot, Node *pParent, PRTLISTANCHOR pListAnchor, xmlAttr *pLibAttr); AttributeNode(const AttributeNode &x); // no copying friend class Node; friend class ElementNode; }; /** * Node subclass that represents an element. * * For elements, Node::getName() returns the element name, and Node::getValue() * returns the text contents, if any. * * Since the Node constructor is private, one can create element nodes * only through the following factory methods: * * -- Document::createRootElement() * -- ElementNode::createChild() */ class RT_DECL_CLASS ElementNode : public Node { public: int getChildElements(ElementNodesList &children, const char *pcszMatch = NULL) const; const ElementNode *findChildElementNS(const char *pcszNamespace, const char *pcszMatch) const; const ElementNode *findChildElement(const char *pcszMatch) const { return findChildElementNS(NULL, pcszMatch); } const ElementNode *findChildElementFromId(const char *pcszId) const; /** Finds the first decendant matching the name at the end of @a pcszPath and * optionally namespace. * * @returns Pointer to the child string value, NULL if not found or no value. * @param pcszPath The attribute name. Slashes can be used to make a * simple path to any decendant. * @param pcszNamespace The namespace to match, NULL (default) match any * namespace. When using a path, this matches all * elements along the way. * @see findChildElement, findChildElementP */ const ElementNode *findChildElementP(const char *pcszPath, const char *pcszNamespace = NULL) const; /** Finds the first child with matching the give name and optionally namspace, * returning its value. * * @returns Pointer to the child string value, NULL if not found or no value. * @param pcszPath The attribute name. Slashes can be used to make a * simple path to any decendant. * @param pcszNamespace The namespace to match, NULL (default) match any * namespace. When using a path, this matches all * elements along the way. * @see findChildElement, findChildElementP */ const char *findChildElementValueP(const char *pcszPath, const char *pcszNamespace = NULL) const { const ElementNode *pElem = findChildElementP(pcszPath, pcszNamespace); if (pElem) return pElem->getValue(); return NULL; } /** Combines findChildElementP and findAttributeValue. * * @returns Pointer to attribute string value, NULL if either the element or * the attribute was not found. * @param pcszPath The attribute name. Slashes can be used to make a * simple path to any decendant. * @param pcszAttribute The attribute name. * @param pcszPathNamespace The namespace to match @a pcszPath with, NULL * (default) match any namespace. When using a * path, this matches all elements along the way. * @param pcszAttributeNamespace The namespace prefix to apply to the * attribute, NULL (default) match any namespace. * @see findChildElementP and findAttributeValue */ const char *findChildElementAttributeValueP(const char *pcszPath, const char *pcszAttribute, const char *pcszPathNamespace = NULL, const char *pcszAttributeNamespace = NULL) const { const ElementNode *pElem = findChildElementP(pcszPath, pcszPathNamespace); if (pElem) return pElem->findAttributeValue(pcszAttribute, pcszAttributeNamespace); return NULL; } /** @name Tree enumeration. * @{ */ /** Get the next tree element in a full tree enumeration. * * By starting with the root node, this can be used to enumerate the entire tree * (or sub-tree if @a pElmRoot is used). * * @returns Pointer to the next element in the tree, NULL if we're done. * @param pElmRoot The root of the tree we're enumerating. NULL if * it's the entire tree. */ ElementNode const *getNextTreeElement(ElementNode const *pElmRoot = NULL) const; RT_CPP_GETTER_UNCONST_RET(ElementNode *, ElementNode, getNextTreeElement, (const ElementNode *pElmRoot = NULL), (pElmRoot)) /** Get the first child node. * @returns Pointer to the first child node, NULL if no children. */ const Node *getFirstChild() const { return RTListGetFirstCpp(&m_children, const Node, m_listEntry); } RT_CPP_GETTER_UNCONST_RET(Node *, ElementNode, getFirstChild,(),()) /** Get the last child node. * @returns Pointer to the last child node, NULL if no children. */ const Node *getLastChild() const { return RTListGetLastCpp(&m_children, const Node, m_listEntry); } /** Get the first child node. * @returns Pointer to the first child node, NULL if no children. */ const ElementNode *getFirstChildElement() const; /** Get the last child node. * @returns Pointer to the last child node, NULL if no children. */ const ElementNode *getLastChildElement() const; /** Get the previous sibling element. * @returns Pointer to the previous sibling element, NULL if first child * element. * @see getNextSibilingElement, getPrevSibling */ const ElementNode *getPrevSibilingElement() const; /** Get the next sibling element. * @returns Pointer to the next sibling element, NULL if last child element. * @see getPrevSibilingElement, getNextSibling */ const ElementNode *getNextSibilingElement() const; /** Find the previous element matching the given name and namespace (optionally). * @returns Pointer to the previous sibling element, NULL if first child * element. * @param pcszName The element name to match. * @param pcszNamespace The namespace name, default is NULL which means * anything goes. * @note Changed the order of the arguments. */ const ElementNode *findPrevSibilingElement(const char *pcszName, const char *pcszNamespace = NULL) const; /** Find the next element matching the given name and namespace (optionally). * @returns Pointer to the previous sibling element, NULL if first child * element. * @param pcszName The element name to match. * @param pcszNamespace The namespace name, default is NULL which means * anything goes. * @note Changed the order of the arguments. */ const ElementNode *findNextSibilingElement(const char *pcszName, const char *pcszNamespace = NULL) const; /** @} */ const AttributeNode *findAttribute(const char *pcszMatch, const char *pcszNamespace = NULL) const; /** Find the first attribute with the given name, returning its value string. * @returns Pointer to the attribute string value. * @param pcszName The attribute name. * @param pcszNamespace The namespace name, default is NULL which means * anything goes. * @see getAttributeValue */ const char *findAttributeValue(const char *pcszName, const char *pcszNamespace = NULL) const { const AttributeNode *pAttr = findAttribute(pcszName, pcszNamespace); if (pAttr) return pAttr->getValue(); return NULL; } bool getAttributeValue(const char *pcszMatch, const char *&pcsz, const char *pcszNamespace = NULL) const { return getAttributeValue(pcszMatch, &pcsz, pcszNamespace); } bool getAttributeValue(const char *pcszMatch, RTCString &str, const char *pcszNamespace = NULL) const { return getAttributeValue(pcszMatch, &str, pcszNamespace); } bool getAttributeValuePath(const char *pcszMatch, RTCString &str, const char *pcszNamespace = NULL) const { return getAttributeValue(pcszMatch, &str, pcszNamespace); } bool getAttributeValue(const char *pcszMatch, int32_t &i, const char *pcszNamespace = NULL) const { return getAttributeValue(pcszMatch, &i, pcszNamespace); } bool getAttributeValue(const char *pcszMatch, uint32_t &i, const char *pcszNamespace = NULL) const { return getAttributeValue(pcszMatch, &i, pcszNamespace); } bool getAttributeValue(const char *pcszMatch, int64_t &i, const char *pcszNamespace = NULL) const { return getAttributeValue(pcszMatch, &i, pcszNamespace); } bool getAttributeValue(const char *pcszMatch, uint64_t &u, const char *pcszNamespace = NULL) const { return getAttributeValue(pcszMatch, &u, pcszNamespace); } bool getAttributeValue(const char *pcszMatch, bool &f, const char *pcszNamespace = NULL) const { return getAttributeValue(pcszMatch, &f, pcszNamespace); } /** @name Variants that for clarity does not use references for output params. * @{ */ bool getAttributeValue(const char *pcszMatch, const char **ppcsz, const char *pcszNamespace = NULL) const; bool getAttributeValue(const char *pcszMatch, RTCString *pStr, const char *pcszNamespace = NULL) const; bool getAttributeValuePath(const char *pcszMatch, RTCString *pStr, const char *pcszNamespace = NULL) const; bool getAttributeValue(const char *pcszMatch, int32_t *pi, const char *pcszNamespace = NULL) const; bool getAttributeValue(const char *pcszMatch, uint32_t *pu, const char *pcszNamespace = NULL) const; bool getAttributeValue(const char *pcszMatch, int64_t *piValue, const char *pcszNamespace = NULL) const; bool getAttributeValue(const char *pcszMatch, uint64_t *pu, const char *pcszNamespace = NULL) const; bool getAttributeValue(const char *pcszMatch, bool *pf, const char *pcszNamespace = NULL) const; /** @} */ /** @name Convenience methods for convering the element value. * @{ */ bool getElementValue(int32_t *piValue) const; bool getElementValue(uint32_t *puValue) const; bool getElementValue(int64_t *piValue) const; bool getElementValue(uint64_t *puValue) const; bool getElementValue(bool *pfValue) const; /** @} */ /** @name Convenience findChildElementAttributeValueP and getElementValue. * @{ */ bool getChildElementValueP(const char *pcszPath, int32_t *piValue, const char *pcszNamespace = NULL) const { const ElementNode *pElem = findChildElementP(pcszPath, pcszNamespace); return pElem && pElem->getElementValue(piValue); } bool getChildElementValueP(const char *pcszPath, uint32_t *puValue, const char *pcszNamespace = NULL) const { const ElementNode *pElem = findChildElementP(pcszPath, pcszNamespace); return pElem && pElem->getElementValue(puValue); } bool getChildElementValueP(const char *pcszPath, int64_t *piValue, const char *pcszNamespace = NULL) const { const ElementNode *pElem = findChildElementP(pcszPath, pcszNamespace); return pElem && pElem->getElementValue(piValue); } bool getChildElementValueP(const char *pcszPath, uint64_t *puValue, const char *pcszNamespace = NULL) const { const ElementNode *pElem = findChildElementP(pcszPath, pcszNamespace); return pElem && pElem->getElementValue(puValue); } bool getChildElementValueP(const char *pcszPath, bool *pfValue, const char *pcszNamespace = NULL) const { const ElementNode *pElem = findChildElementP(pcszPath, pcszNamespace); return pElem && pElem->getElementValue(pfValue); } /** @} */ /** @name Convenience findChildElementAttributeValueP and getElementValue with a * default value being return if the child element isn't present. * * @remarks These will return false on conversion errors. * @{ */ bool getChildElementValueDefP(const char *pcszPath, int32_t iDefault, int32_t *piValue, const char *pcszNamespace = NULL) const { const ElementNode *pElem = findChildElementP(pcszPath, pcszNamespace); if (pElem) return pElem->getElementValue(piValue); *piValue = iDefault; return true; } bool getChildElementValueDefP(const char *pcszPath, uint32_t uDefault, uint32_t *puValue, const char *pcszNamespace = NULL) const { const ElementNode *pElem = findChildElementP(pcszPath, pcszNamespace); if (pElem) return pElem->getElementValue(puValue); *puValue = uDefault; return true; } bool getChildElementValueDefP(const char *pcszPath, int64_t iDefault, int64_t *piValue, const char *pcszNamespace = NULL) const { const ElementNode *pElem = findChildElementP(pcszPath, pcszNamespace); if (pElem) return pElem->getElementValue(piValue); *piValue = iDefault; return true; } bool getChildElementValueDefP(const char *pcszPath, uint64_t uDefault, uint64_t *puValue, const char *pcszNamespace = NULL) const { const ElementNode *pElem = findChildElementP(pcszPath, pcszNamespace); if (pElem) return pElem->getElementValue(puValue); *puValue = uDefault; return true; } bool getChildElementValueDefP(const char *pcszPath, bool fDefault, bool *pfValue, const char *pcszNamespace = NULL) const { const ElementNode *pElem = findChildElementP(pcszPath, pcszNamespace); if (pElem) return pElem->getElementValue(pfValue); *pfValue = fDefault; return true; } /** @} */ ElementNode *createChild(const char *pcszElementName); ContentNode *addContent(const char *pcszContent); ContentNode *addContent(const RTCString &strContent) { return addContent(strContent.c_str()); } ContentNode *setContent(const char *pcszContent); ContentNode *setContent(const RTCString &strContent) { return setContent(strContent.c_str()); } AttributeNode *setAttribute(const char *pcszName, const char *pcszValue); AttributeNode *setAttribute(const char *pcszName, const RTCString &strValue) { return setAttribute(pcszName, strValue.c_str()); } AttributeNode *setAttributePath(const char *pcszName, const RTCString &strValue); AttributeNode *setAttribute(const char *pcszName, int32_t i); AttributeNode *setAttribute(const char *pcszName, uint32_t i); AttributeNode *setAttribute(const char *pcszName, int64_t i); AttributeNode *setAttribute(const char *pcszName, uint64_t i); AttributeNode *setAttributeHex(const char *pcszName, uint32_t i); AttributeNode *setAttribute(const char *pcszName, bool f); virtual ~ElementNode(); protected: // hide the default constructor so people use only our factory methods ElementNode(const ElementNode *pElmRoot, Node *pParent, PRTLISTANCHOR pListAnchor, xmlNode *pLibNode); ElementNode(const ElementNode &x); // no copying /** We keep a pointer to the root element for attribute namespace handling. */ const ElementNode *m_pElmRoot; /** List of child elements and content nodes. */ RTLISTANCHOR m_children; /** List of attributes nodes. */ RTLISTANCHOR m_attributes; static void buildChildren(ElementNode *pElmRoot); friend class Node; friend class Document; friend class XmlFileParser; }; /** * Node subclass that represents content (non-element text). * * Since the Node constructor is private, one can create new content nodes * only through the following factory methods: * * -- ElementNode::addContent() */ class RT_DECL_CLASS ContentNode : public Node { public: protected: // hide the default constructor so people use only our factory methods ContentNode(Node *pParent, PRTLISTANCHOR pListAnchor, xmlNode *pLibNode); ContentNode(const ContentNode &x); // no copying friend class Node; friend class ElementNode; }; /** * Handy helper class with which one can loop through all or some children * of a particular element. See NodesLoop::forAllNodes() for details. */ class RT_DECL_CLASS NodesLoop { public: NodesLoop(const ElementNode &node, const char *pcszMatch = NULL); ~NodesLoop(); const ElementNode* forAllNodes() const; private: /* Obscure class data */ struct Data; Data *m; }; /** * The XML document class. An instance of this needs to be created by a user * of the XML classes and then passed to * * -- XmlMemParser or XmlFileParser to read an XML document; those classes then * fill the caller's Document with ElementNode, ContentNode and AttributeNode * instances. The typical sequence then is: * @code Document doc; XmlFileParser parser; parser.read("file.xml", doc); Element *pElmRoot = doc.getRootElement(); @endcode * * -- XmlMemWriter or XmlFileWriter to write out an XML document after it has * been created and filled. Example: * * @code Document doc; Element *pElmRoot = doc.createRootElement(); // add children xml::XmlFileWriter writer(doc); writer.write("file.xml", true); @endcode */ class RT_DECL_CLASS Document { public: Document(); ~Document(); Document(const Document &x); Document& operator=(const Document &x); const ElementNode* getRootElement() const; ElementNode* getRootElement(); ElementNode* createRootElement(const char *pcszRootElementName, const char *pcszComment = NULL); private: friend class XmlMemParser; friend class XmlFileParser; friend class XmlMemWriter; friend class XmlStringWriter; friend class XmlFileWriter; void refreshInternals(); /* Obscure class data */ struct Data; Data *m; }; /* * XmlParserBase * */ class RT_DECL_CLASS XmlParserBase { protected: XmlParserBase(); ~XmlParserBase(); xmlParserCtxtPtr m_ctxt; }; /* * XmlMemParser * */ class RT_DECL_CLASS XmlMemParser : public XmlParserBase { public: XmlMemParser(); ~XmlMemParser(); void read(const void* pvBuf, size_t cbSize, const RTCString &strFilename, Document &doc); }; /* * XmlFileParser * */ class RT_DECL_CLASS XmlFileParser : public XmlParserBase { public: XmlFileParser(); ~XmlFileParser(); void read(const RTCString &strFilename, Document &doc); private: /* Obscure class data */ struct Data; struct Data *m; static int ReadCallback(void *aCtxt, char *aBuf, int aLen); static int CloseCallback (void *aCtxt); }; /** * XmlMemWriter */ class RT_DECL_CLASS XmlMemWriter { public: XmlMemWriter(); ~XmlMemWriter(); void write(const Document &doc, void** ppvBuf, size_t *pcbSize); private: void* m_pBuf; }; /** * XmlStringWriter - writes the XML to an RTCString instance. */ class RT_DECL_CLASS XmlStringWriter { public: XmlStringWriter(); int write(const Document &rDoc, RTCString *pStrDst); private: static int WriteCallbackForSize(void *pvUser, const char *pachBuf, int cbToWrite); static int WriteCallbackForReal(void *pvUser, const char *pachBuf, int cbToWrite); static int CloseCallback(void *pvUser); /** Pointer to the destination string while we're in the write() call. */ RTCString *m_pStrDst; /** Set by WriteCallback if we cannot grow the destination string. */ bool m_fOutOfMemory; }; /** * XmlFileWriter */ class RT_DECL_CLASS XmlFileWriter { public: XmlFileWriter(Document &doc); ~XmlFileWriter(); /** * Writes the XML document to the specified file. * * @param pcszFilename The name of the output file. * @param fSafe If @c true, some extra safety precautions will be * taken when writing the file: * -# The file is written with a '-tmp' suffix. * -# It is flushed to disk after writing. * -# Any original file is renamed to '-prev'. * -# The '-tmp' file is then renamed to the * specified name. * -# The directory changes are flushed to disk. * The suffixes are available via s_pszTmpSuff and * s_pszPrevSuff. */ void write(const char *pcszFilename, bool fSafe); static int WriteCallback(void *aCtxt, const char *aBuf, int aLen); static int CloseCallback(void *aCtxt); /** The suffix used by XmlFileWriter::write() for the temporary file. */ static const char * const s_pszTmpSuff; /** The suffix used by XmlFileWriter::write() for the previous (backup) file. */ static const char * const s_pszPrevSuff; private: void writeInternal(const char *pcszFilename, bool fSafe); /* Obscure class data */ struct Data; Data *m; }; #if defined(_MSC_VER) #pragma warning (default:4251) #endif /** @} */ } // end namespace xml #endif /* !___iprt_xml_h */