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zen::Xml
Simple C++ XML Processing
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zen::Xml
Simple C++ XML Processing
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zen::Xml is an XML library serializing structured user data in a convenient way. Using compile-time information gathered by techniques of template metaprogramming it minimizes the manual overhead required and frees the user from implementing fundamental type conversions by himself. Basic data types such as
are handled automatically. Thereby a large number of recurring problems is solved by the library:
The design follows the philosophy of the Loki library:
http://loki-lib.sourceforge.net/index.php?n=Main.Philosophy
1. Download zen::Xml: http://sourceforge.net/projects/zenxml
2. Setup a preprocessor macro for your project to identify the platform (this is only required if you use C-stream-based file IO)
ZEN_PLATFORM_WINDOWS
or
ZEN_PLATFORM_OTHER
3. For optimal performance define this global macro in release build: (following convention of the assert macro)
NDEBUG
4. Include the main header:
#include <zenxml/xml.h>
5. Start serializing user data:
size_t a = 10; double b = 2.0; int c = -1;
zen::XmlDoc doc; //empty XML document zen::XmlOut out(doc); //the simplest way to fill the document is to use a data output proxy out["elem1"](a); // out["elem2"](b); //map data types to XML elements out["elem3"](c); // try { save(doc, "file.xml"); //throw zen::XmlFileError } catch (const zen::XmlFileError& e) { /* handle error */ }
The following XML file will be created:
<?xml version="1.0" encoding="UTF-8"?>
<Root>
<elem1>10</elem1>
<elem2>2.000000</elem2>
<elem3>-1</elem3>
</Root>
Load an XML file and map its content to user data:
zen::XmlDoc doc; //empty XML document try { load("file.xml", doc); //throw XmlFileError, XmlParsingError } catch (const zen::XmlError& e) { /* handle error */ } zen::XmlIn in(doc); //the simplest way to read the document is to use a data input proxy in["elem1"](a); // in["elem2"](b); //map XML elements into user data in["elem3"](c); // //check for mapping errors, i.e. missing elements or conversion errors: you may consider these as warnings only if (in.errorsOccured()) { std::vector<std::wstring> failedElements = in.getErrorsAs<std::wstring>(); /* generate error message showing the XML element names that failed to convert */ }
zen::Xml is written in a platform independent manner and runs on any rudimentary C++11 compliant compiler. It has been tested successfully under:
Note: In order to enable C++11 features in GCC it is required to specify either of the following compiler options:
-std=c++11 -std=c++0x -std=gnu++0x
Depending on what granularity of control is required in a particular application, zen::Xml allows the user to choose between full control or simplicity.
The library is structured into the following parts, each of which can be used in isolation:
<File>
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| io.h
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<Byte Stream>
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| parser.h
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<Document Object Model>
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| bind.h
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<C++ user data>
zen::XmlDoc doc; ... //fill it std::string stream = serialize(doc); //throw () /* you now have a binary XML stream */ saveStream(stream, "file.xml"); //throw XmlFileError //if all you need is to store XmlDoc in a file direcly you can use zen::save() instead
//get XML byte stream: std::string stream = loadStream("file.xml"); //throw XmlFileError zen::XmlDoc doc; //parse byte stream into an XML document: parse(stream, doc); //throw XmlParsingError //if all you need is to load an XmlDoc from a file you can use zen::load() directly
zen::XmlIn in(doc); //map XML elements into user data if (!in["elem1"](a)) throw MyCustomException(); if (!in["elem2"](b)) throw MyCustomException(); if (!in["elem3"](c)) throw MyCustomException(); //if (in.errorsOccured()) ... <- not required here: contains the same conversion errors checked manually before
using namespace zen; XmlDoc doc; XmlElement& child = doc.root().addChild("elem1"); child.setValue(1234); save(doc, "file.xml"); //throw XmlFileError
using namespace zen; XmlDoc doc; load("file.xml", doc); //throw XmlFileError, XmlParsingError XmlElement* child = doc.root().getChild("elem1"); if (child) { int value = -1; if (!child->getValue(value)) ... //handle conversion error } else ... //XML element not found
//write a value into one deeply nested XML element - note the different types used seamlessly: char[], wchar_t[], char, wchar_t, int zen::XmlOut out(doc); out["elemento1"][L"элемент2"][L"要素3"][L"στοιχείο4"]["elem5"][L"元素6"][L'元']['z'](-1234);
The resulting XML:
<?xml version="1.0" encoding="UTF-8"?>
<Root>
<elemento1>
<элемент2>
<要素3>
<στοιχείο4>
<elem5>
<元素6>
<元>
<z>-1234</z>
</元>
</元素6>
</elem5>
</στοιχείο4>
</要素3>
</элемент2>
</elemento1>
</Root>
zen::XmlDoc doc; zen::XmlOut out(doc); out["elem"].attribute("attr1", -1); // out["elem"].attribute("attr2", 2.1); //write data into XML attributes out["elem"].attribute("attr3", true); // save(doc, "file.xml"); //throw XmlFileError
The resulting XML:
<?xml version="1.0" encoding="UTF-8"?>
<Root>
<elem attr1="-1" attr2="2.1" attr3="true"/>
</Root>
All built-in arithmetic types and bool are detected at compile time and a proper conversion is applied. Common conversions for integer-like types such as int, long, long long, ect. as well as floating point types are optimized for maximum performance.
zen::XmlOut out(doc); out["int"] (-1234); out["double"](1.23); out["float"] (4.56f); out["ulong"] (1234UL); out["bool"] (false);
The resulting XML:
<?xml version="1.0" encoding="UTF-8"?>
<Root>
<int>-1234</int>
<double>1.23</double>
<float>4.56</float>
<ulong>1234</ulong>
<bool>false</bool>
</Root>
The document object model of zen::Xml internally stores all names and values as a std::string. Consequently everything that is not a std::string but is "string-like" is UTF-converted into a std::string representation. By default zen::Xml accepts all character arrays like char[], wchar_t[], char*, wchar_t*, single characters like char, wchar_t, standard string classes like std::string, std::wstring and user-defined string classes. If the input string is based on char, it will simply be copied and thereby preserves any local encodings. If the input string is based on wchar_t it will be converted to an UTF-8 encoded std::string. The correct wchar_t encoding of the system will be detected at compile time, for example UTF-16 on Windows, UTF-32 on most Linux distributions.
Note: User-defined string classes are automatically supported if they fulfill the following string concept by defining:
value_type for the underlying character type: must be char or wchar_t c_str() returning something that can be converted into a const value_type*length() returning the number of characters returned by c_str()std::string elem1 = "elemento1"; std::wstring elem2 = L"элемент2"; wxString elem3 = L"要素3"; MyString elem4 = L"στοιχείο4"; zen::XmlOut out(doc); out["string"] (elem1); out["wstring"] (elem2); out["wxString"] (elem3); out["MyString"] (elem4); out["char[6]"] ("elem5"); out["wchar_t[4]"](L"元素6"); out["wchar_t"] (L'元'); out["char"] ('z');
The resulting XML:
<?xml version="1.0" encoding="UTF-8"?>
<Root>
<string>elemento1</string>
<wstring>элемент2</wstring>
<wxString>要素3</wxString>
<MyString>στοιχείο4</MyString>
<char[6]>elem5</char[6]>
<wchar_t[4]>元素6</wchar_t[4]>
<wchar_t>元</wchar_t>
<char>z</char>
</Root>
value_type for the underlying element type of the containeriterator for a non-const iterator into the containerconst_iterator for a const iterator into the container begin() returning an iterator pointing to the first element in the containerend() returning an iterator pointing just after the last element in the containerinsert() with the signature iterator insert(iterator position, const value_type& x)clear() removing all elements from the containerstd::vector<MyType> or std::vector<std::list<MyType>> it is sufficient to only integrate MyType into zen::Xml. std::deque <float> testDeque; std::list <size_t> testList; std::map <double, char> testMap; std::multimap<short, double> testMultiMap; std::set <int> testSet; std::multiset<std::string> testMultiSet; std::vector <wchar_t> testVector; std::vector <std::list<wchar_t>> testVectorList; std::pair <char, wchar_t> testPair; /* fill container */ zen::XmlOut out(doc); out["deque"] (testDeque); out["list"] (testList); out["map"] (testMap); out["multimap"] (testMultiMap); out["set"] (testSet); out["multiset"] (testMultiSet); out["vector"] (testVector); out["vect_list"](testVectorList); out["pair" ] (testPair);
The resulting XML:
<?xml version="1.0" encoding="UTF-8"?>
<Root>
<deque>
<Item>1.234</Item>
<Item>5.678</Item>
</deque>
<list>
<Item>1</Item>
<Item>2</Item>
</list>
<map>
<Item>
<one>1.1</one>
<two>a</two>
</Item>
<Item>
<one>2.2</one>
<two>b</two>
</Item>
</map>
<multimap>
<Item>
<one>3</one>
<two>99</two>
</Item>
<Item>
<one>3</one>
<two>100</two>
</Item>
<Item>
<one>4</one>
<two>101</two>
</Item>
</multimap>
<set>
<Item>1</Item>
<Item>2</Item>
</set>
<multiset>
<Item>1</Item>
<Item>1</Item>
<Item>2</Item>
</multiset>
<vector>
<Item>Ä</Item>
<Item>Ö</Item>
</vector>
<vect_list>
<Item>
<Item>ä</Item>
<Item>ö</Item>
<Item>ü</Item>
</Item>
<Item>
<Item>ä</Item>
<Item>ö</Item>
<Item>ü</Item>
</Item>
</vect_list>
<pair>
<one>a</one>
<two>â</two>
</pair>
</Root>
User types can be integrated into zen::Xml by providing specializations of zen::readText() and zen::writeText() or zen::readStruc() and zen::writeStruc(). The first pair should be used for all non-structured types that can be represented as a simple text string. This specialization is then used to convert the type to XML elements and XML attributes. The second pair should be specialized for structured types that require an XML representation as a hierarchy of elements. This specialization is used when converting the type to XML elements only.
See section Type Safety for a discussion of type categories.
Example: Specialization for an enum type
enum UnitTime { UNIT_SECOND, UNIT_MINUTE, UNIT_HOUR }; namespace zen { template <> inline void writeText(const UnitTime& value, std::string& output) { switch (value) { case UNIT_SECOND: output = "second"; break; case UNIT_MINUTE: output = "minute"; break; case UNIT_HOUR: output = "hour" ; break; } } template <> inline bool readText(const std::string& input, UnitTime& value) { std::string tmp = input; zen::trim(tmp); if (tmp == "second") value = UNIT_SECOND; else if (tmp == "minute") value = UNIT_MINUTE; else if (tmp == "hour") value = UNIT_HOUR; else return false; return true; } }
Example: Brute-force specialization for an enum type
namespace zen { template <> inline void writeText(const EnumType& value, std::string& output) { output = zen::numberTo<std::string>(static_cast<int>(value)); //treat enum like an integer } template <> inline bool readText(const std::string& input, EnumType& value) { value = static_cast<EnumType>(zen::stringTo<int>(input)); //treat enum like an integer return true; } }
Example: Specialization for a structured user type
struct Config { int a; std::wstring b; }; namespace zen { template <> inline void writeStruc(const Config& value, XmlElement& output) { XmlOut out(output); out["number" ](value.a); out["address"](value.b); } template <> inline bool readStruc(const XmlElement& input, Config& value) { XmlIn in(input); bool rv1 = in["number" ](value.a); bool rv2 = in["address"](value.b); return rv1 && rv2; } } int main() { Config cfg = { 2, L"Abc 3" }; std::vector<Config> cfgList; cfgList.push_back(cfg); zen::XmlDoc doc; zen::XmlOut out(doc); //write to Xml via output proxy out["config"](cfgList); save(doc, "file.xml"); //throw XmlFileError }
The resulting XML:
<?xml version="1.0" encoding="UTF-8"?>
<Root>
<config>
<Item>
<number>2</number>
<address>Abc 3</address>
</Item>
</config>
</Root>
Although it is possible to enable conversion of structured user types by specializing zen::readStruc() and zen::writeStruc() (see Support for user-defined types), this approach has one drawback: If a mapping error occurs when converting an XML element to structured user data, for example a child-element is missing, the input proxy class zen::XmlIn is only able to detect that the whole conversion failed. It cannot say which child-elements in particular failed to convert.
Therefore it may be appropriate to convert structured types by calling subroutines in order to enable fine-granular logging:
void readConfig(const zen::XmlIn& in, Config& cfg) { in["number" ](value.a); //failed conversions will now be logged for each single item by XmlIn in["address"](value.b); //instead of only once for the complete Config type! } void loadConfig(const wxString& filename, Config& cfg) { zen::XmlDoc doc; //empty XML document try { load(filename, doc); //throw XmlFileError, XmlParsingError } catch (const zen::XmlError& e) { /* handle error */ } zen::XmlIn in(doc); zen::XmlIn inConfig = in["config"]; //get input proxy for child element "config" readConfig(inConfig, cfg); //map child element to user data by calling subroutine //check for mapping errors: errors occuring in subroutines are considered, too! if (in.errorsOccured()) /* show mapping errors */ }
zen::Xml heavily uses methods of compile-time introspection in order to free the user from managing basic type conversions by himself. Thereby it is important to find the right balance between automatic conversions and type safety so that program correctness is not compromised. In the context of XML processing three fundamental type categories can be recognized:
std::string, wchar_t*, char[], wchar_t, wxString, MyStringClass, ...boolstd::pair, structured user typesThese categories can be seen as a sequence of inclusive sets:
----------------------------- | structured | Used as: XML element value | ------------------------- | Conversion via: readStruc(), writeStruc() - may be specialized for user-defined types! | | to-string-convertible | | Used as: XML element/attribute value | | --------------- | | Conversion via: readText(), writeText() - may be specialized for user-defined types! | | | string-like | | | Used as: XML element/attribute value or element name | | --------------- | | Conversion via: utfCvrtTo<>() | ------------------------- | -----------------------------
A practical implication of this design is that conversions that do not make sense in a particular context simply lead to compile-time errors:
zen::XmlOut out(doc); out[L'Z'](someValue); //fine: a wchar_t is acceptable as an element name out[1234](someValue); //compiler error: an integer is NOT "string-like"!
int i = 0; std::vector<int> v; zen::XmlOut out(doc); out["elem1"](i); //fine: both i and v can be converted to an XML element out["elem2"](v); // out["elem"].attribute("attr1", i); //fine: an integer can be converted to an XML attribute out["elem"].attribute("attr2", v); //compiler error: a std::vector<int> is NOT "to-string-convertible"!
1.8.0