boost/python/object_core.hpp
// Copyright David Abrahams 2002. // Distributed under the Boost Software License, Version 1.0. (See // accompanying file LICENSE_1_0.txt or copy at // http://www.boost.org/LICENSE_1_0.txt) #ifndef OBJECT_CORE_DWA2002615_HPP # define OBJECT_CORE_DWA2002615_HPP # define BOOST_PYTHON_OBJECT_HAS_IS_NONE // added 2010-03-15 by rwgk # include <boost/python/detail/prefix.hpp> # include <boost/type.hpp> # include <boost/python/call.hpp> # include <boost/python/handle_fwd.hpp> # include <boost/python/errors.hpp> # include <boost/python/refcount.hpp> # include <boost/python/detail/preprocessor.hpp> # include <boost/python/tag.hpp> # include <boost/python/def_visitor.hpp> # include <boost/python/detail/raw_pyobject.hpp> # include <boost/python/detail/dependent.hpp> # include <boost/python/object/forward.hpp> # include <boost/python/object/add_to_namespace.hpp> # include <boost/preprocessor/iterate.hpp> # include <boost/preprocessor/debug/line.hpp> # include <boost/python/detail/is_xxx.hpp> # include <boost/python/detail/string_literal.hpp> # include <boost/python/detail/def_helper_fwd.hpp> # include <boost/type_traits/is_same.hpp> # include <boost/type_traits/is_convertible.hpp> # include <boost/type_traits/remove_reference.hpp> # if BOOST_WORKAROUND(BOOST_MSVC, <= 1300) # include <boost/type_traits/add_pointer.hpp> # endif # include <boost/mpl/if.hpp> namespace boost { namespace python { namespace detail { class kwds_proxy; class args_proxy; } namespace converter { template <class T> struct arg_to_python; } // Put this in an inner namespace so that the generalized operators won't take over namespace api { // This file contains the definition of the object class and enough to // construct/copy it, but not enough to do operations like // attribute/item access or addition. template <class Policies> class proxy; struct const_attribute_policies; struct attribute_policies; struct const_objattribute_policies; struct objattribute_policies; struct const_item_policies; struct item_policies; struct const_slice_policies; struct slice_policies; class slice_nil; typedef proxy<const_attribute_policies> const_object_attribute; typedef proxy<attribute_policies> object_attribute; typedef proxy<const_objattribute_policies> const_object_objattribute; typedef proxy<objattribute_policies> object_objattribute; typedef proxy<const_item_policies> const_object_item; typedef proxy<item_policies> object_item; typedef proxy<const_slice_policies> const_object_slice; typedef proxy<slice_policies> object_slice; // // is_proxy -- proxy type detection // BOOST_PYTHON_IS_XXX_DEF(proxy, boost::python::api::proxy, 1) template <class T> struct object_initializer; class object; typedef PyObject* (object::*bool_type)() const; template <class U> class object_operators : public def_visitor<U> { protected: # if !defined(BOOST_MSVC) || BOOST_MSVC >= 1300 typedef object const& object_cref; # else typedef object object_cref; # endif public: // function call // object operator()() const; # define BOOST_PP_ITERATION_PARAMS_1 (3, (1, BOOST_PYTHON_MAX_ARITY, <boost/python/object_call.hpp>)) # include BOOST_PP_ITERATE() detail::args_proxy operator* () const; object operator()(detail::args_proxy const &args) const; object operator()(detail::args_proxy const &args, detail::kwds_proxy const &kwds) const; // truth value testing // operator bool_type() const; bool operator!() const; // needed for vc6 // Attribute access // const_object_attribute attr(char const*) const; object_attribute attr(char const*); const_object_objattribute attr(object const&) const; object_objattribute attr(object const&); // Wrap 'in' operator (aka. __contains__) template <class T> object contains(T const& key) const; // item access // const_object_item operator[](object_cref) const; object_item operator[](object_cref); template <class T> const_object_item operator[](T const& key) const # if !defined(BOOST_MSVC) || BOOST_MSVC > 1300 ; # else { return (*this)[object(key)]; } # endif template <class T> object_item operator[](T const& key) # if !defined(BOOST_MSVC) || BOOST_MSVC > 1300 ; # else { return (*this)[object(key)]; } # endif // slicing // const_object_slice slice(object_cref, object_cref) const; object_slice slice(object_cref, object_cref); const_object_slice slice(slice_nil, object_cref) const; object_slice slice(slice_nil, object_cref); const_object_slice slice(object_cref, slice_nil) const; object_slice slice(object_cref, slice_nil); const_object_slice slice(slice_nil, slice_nil) const; object_slice slice(slice_nil, slice_nil); template <class T, class V> const_object_slice slice(T const& start, V const& end) const # if !defined(BOOST_MSVC) || BOOST_MSVC > 1300 ; # else { return this->slice( slice_bound<T>::type(start) , slice_bound<V>::type(end)); } # endif template <class T, class V> object_slice slice(T const& start, V const& end) # if !defined(BOOST_MSVC) || BOOST_MSVC > 1300 ; # else { return this->slice( slice_bound<T>::type(start) , slice_bound<V>::type(end)); } # endif private: // def visitation for adding callable objects as class methods template <class ClassT, class DocStringT> void visit(ClassT& cl, char const* name, python::detail::def_helper<DocStringT> const& helper) const { // It's too late to specify anything other than docstrings if // the callable object is already wrapped. BOOST_STATIC_ASSERT( (is_same<char const*,DocStringT>::value || detail::is_string_literal<DocStringT const>::value)); objects::add_to_namespace(cl, name, this->derived_visitor(), helper.doc()); } friend class python::def_visitor_access; private: // there is a confirmed CWPro8 codegen bug here. We prevent the // early destruction of a temporary by binding a named object // instead. # if __MWERKS__ < 0x3000 || __MWERKS__ > 0x3003 typedef object const& object_cref2; # else typedef object const object_cref2; # endif }; // VC6 and VC7 require this base class in order to generate the // correct copy constructor for object. We can't define it there // explicitly or it will complain of ambiguity. struct object_base : object_operators<object> { // copy constructor without NULL checking, for efficiency. inline object_base(object_base const&); inline object_base(PyObject* ptr); inline object_base& operator=(object_base const& rhs); inline ~object_base(); // Underlying object access -- returns a borrowed reference inline PyObject* ptr() const; inline bool is_none() const; private: PyObject* m_ptr; }; # ifdef BOOST_NO_TEMPLATE_PARTIAL_SPECIALIZATION template <class T, class U> struct is_derived_impl { static T x; template <class X> static X* to_pointer(X const&); static char test(U const*); typedef char (&no)[2]; static no test(...); BOOST_STATIC_CONSTANT(bool, value = sizeof(test(to_pointer(x))) == 1); }; template <class T, class U> struct is_derived : mpl::bool_<is_derived_impl<T,U>::value> {}; # else template <class T, class U> struct is_derived : is_convertible< typename remove_reference<T>::type* , U const* > {}; # endif template <class T> typename objects::unforward_cref<T>::type do_unforward_cref(T const& x) { # if BOOST_WORKAROUND(__GNUC__, == 2) typedef typename objects::unforward_cref<T>::type ret; return ret(x); # else return x; # endif } # if BOOST_WORKAROUND(__GNUC__, == 2) // GCC 2.x has non-const string literals; this hacks around that problem. template <unsigned N> char const (& do_unforward_cref(char const(&x)[N]) )[N] { return x; } # endif class object; template <class T> PyObject* object_base_initializer(T const& x) { typedef typename is_derived< BOOST_DEDUCED_TYPENAME objects::unforward_cref<T>::type , object >::type is_obj; return object_initializer< BOOST_DEDUCED_TYPENAME unwrap_reference<T>::type >::get( x , is_obj() ); } class object : public object_base { public: // default constructor creates a None object object(); // explicit conversion from any C++ object to Python template <class T> explicit object( T const& x # if BOOST_WORKAROUND(BOOST_MSVC, < 1300) // use some SFINAE to un-confuse MSVC about its // copy-initialization ambiguity claim. , typename mpl::if_<is_proxy<T>,int&,int>::type* = 0 # endif ) : object_base(object_base_initializer(x)) { } // Throw error_already_set() if the handle is null. BOOST_PYTHON_DECL explicit object(handle<> const&); private: public: // implementation detail -- for internal use only explicit object(detail::borrowed_reference); explicit object(detail::new_reference); explicit object(detail::new_non_null_reference); }; // Macros for forwarding constructors in classes derived from // object. Derived classes will usually want these as an // implementation detail # define BOOST_PYTHON_FORWARD_OBJECT_CONSTRUCTORS_(derived, base) \ inline explicit derived(python::detail::borrowed_reference p) \ : base(p) {} \ inline explicit derived(python::detail::new_reference p) \ : base(p) {} \ inline explicit derived(python::detail::new_non_null_reference p) \ : base(p) {} # if !defined(BOOST_MSVC) || BOOST_MSVC >= 1300 # define BOOST_PYTHON_FORWARD_OBJECT_CONSTRUCTORS BOOST_PYTHON_FORWARD_OBJECT_CONSTRUCTORS_ # else // MSVC6 has a bug which causes an explicit template constructor to // be preferred over an appropriate implicit conversion operator // declared on the argument type. Normally, that would cause a // runtime failure when using extract<T> to extract a type with a // templated constructor. This additional constructor will turn that // runtime failure into an ambiguity error at compile-time due to // the lack of partial ordering, or at least a link-time error if no // generalized template constructor is declared. # define BOOST_PYTHON_FORWARD_OBJECT_CONSTRUCTORS(derived, base) \ BOOST_PYTHON_FORWARD_OBJECT_CONSTRUCTORS_(derived, base) \ template <class T> \ explicit derived(extract<T> const&); # endif // // object_initializer -- get the handle to construct the object with, // based on whether T is a proxy or derived from object // template <bool is_proxy = false, bool is_object_manager = false> struct object_initializer_impl { static PyObject* get(object const& x, mpl::true_) { return python::incref(x.ptr()); } template <class T> static PyObject* get(T const& x, mpl::false_) { return python::incref(converter::arg_to_python<T>(x).get()); } }; template <> struct object_initializer_impl<true, false> { template <class Policies> static PyObject* get(proxy<Policies> const& x, mpl::false_) { return python::incref(x.operator object().ptr()); } }; template <> struct object_initializer_impl<false, true> { template <class T, class U> static PyObject* get(T const& x, U) { return python::incref(get_managed_object(x, boost::python::tag)); } }; template <> struct object_initializer_impl<true, true> {}; // empty implementation should cause an error template <class T> struct object_initializer : object_initializer_impl< is_proxy<T>::value , converter::is_object_manager<T>::value > {}; } using api::object; template <class T> struct extract; // // implementation // namespace detail { class call_proxy { public: call_proxy(object target) : m_target(target) {} operator object() const { return m_target;} private: object m_target; }; class kwds_proxy : public call_proxy { public: kwds_proxy(object o = object()) : call_proxy(o) {} }; class args_proxy : public call_proxy { public: args_proxy(object o) : call_proxy(o) {} kwds_proxy operator* () const { return kwds_proxy(*this);} }; } template <typename U> detail::args_proxy api::object_operators<U>::operator* () const { object_cref2 x = *static_cast<U const*>(this); return boost::python::detail::args_proxy(x); } template <typename U> object api::object_operators<U>::operator()(detail::args_proxy const &args) const { U const& self = *static_cast<U const*>(this); PyObject *result = PyObject_Call(get_managed_object(self, boost::python::tag), args.operator object().ptr(), 0); return object(boost::python::detail::new_reference(result)); } template <typename U> object api::object_operators<U>::operator()(detail::args_proxy const &args, detail::kwds_proxy const &kwds) const { U const& self = *static_cast<U const*>(this); PyObject *result = PyObject_Call(get_managed_object(self, boost::python::tag), args.operator object().ptr(), kwds.operator object().ptr()); return object(boost::python::detail::new_reference(result)); } template <typename U> template <class T> object api::object_operators<U>::contains(T const& key) const { return this->attr("__contains__")(object(key)); } inline object::object() : object_base(python::incref(Py_None)) {} // copy constructor without NULL checking, for efficiency inline api::object_base::object_base(object_base const& rhs) : m_ptr(python::incref(rhs.m_ptr)) {} inline api::object_base::object_base(PyObject* p) : m_ptr(p) {} inline api::object_base& api::object_base::operator=(api::object_base const& rhs) { Py_INCREF(rhs.m_ptr); Py_DECREF(this->m_ptr); this->m_ptr = rhs.m_ptr; return *this; } inline api::object_base::~object_base() { Py_DECREF(m_ptr); } inline object::object(detail::borrowed_reference p) : object_base(python::incref((PyObject*)p)) {} inline object::object(detail::new_reference p) : object_base(expect_non_null((PyObject*)p)) {} inline object::object(detail::new_non_null_reference p) : object_base((PyObject*)p) {} inline PyObject* api::object_base::ptr() const { return m_ptr; } inline bool api::object_base::is_none() const { return (m_ptr == Py_None); } // // Converter specialization implementations // namespace converter { template <class T> struct object_manager_traits; template <> struct object_manager_traits<object> { BOOST_STATIC_CONSTANT(bool, is_specialized = true); static bool check(PyObject*) { return true; } static python::detail::new_non_null_reference adopt(PyObject* x) { return python::detail::new_non_null_reference(x); } #ifndef BOOST_PYTHON_NO_PY_SIGNATURES static PyTypeObject const *get_pytype() {return 0;} #endif }; } inline PyObject* get_managed_object(object const& x, tag_t) { return x.ptr(); } }} // namespace boost::python # include <boost/python/slice_nil.hpp> #endif // OBJECT_CORE_DWA2002615_HPP