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Size: 1866
Comment: the c++ code did not compile at all the way it was presented
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Size: 1977
Comment: fixed grammar mistakes and made more readable
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| Since Python handles memory allocation and garbage collection automatically, the concept "pointer" is not meaningful within Python. However, many C++ API exposes either raw pointers or shared pointers, and to wrap such APIs one would need to deal with pointers. | Since Python handles memory allocation and garbage collection automatically, the concept of a "pointer" is not meaningful in Python. However, many C++ APIs expose either raw pointers or shared pointers, to wrap these APIs we need to deal with pointers. |
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| === Pointers (raw C++ pointers) === | === Raw C++ Pointers === |
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| The life time of C++ objects created by "new A" can be handled by Python's garbage collection by using the {{{manage_new_object}}} storage policy: | The lifetime of C++ objects created by {{{new A}}} can be handled by Python's garbage collection by using the {{{manage_new_object}}} return policy: |
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| .def("create",&A::create,return_value_policy<manage_new_object>()) | .def("create",&A::create, return_value_policy<manage_new_object>()) |
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| Smart pointers, e.g. boost::shared_ptr<T>, is another common way to give away ownership of objects in C++. Theese kind of smart pointer are automatically handled, if you declare their existence, when declaring the class to boost.python. E.g. |
The usage of smart pointers (e.g. {{{boost::shared_ptr<T>}}}) is another common way to give away ownership of objects in C++. These kinds of smart pointer are automatically handled if you declare their existence when declaring the class to boost::python. This is done by including the holding type as a template parameter to {{{class_<>}}}, like in the following example: |
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Pointers and smart pointers
Since Python handles memory allocation and garbage collection automatically, the concept of a "pointer" is not meaningful in Python. However, many C++ APIs expose either raw pointers or shared pointers, to wrap these APIs we need to deal with pointers.
Raw C++ Pointers
The lifetime of C++ objects created by new A can be handled by Python's garbage collection by using the manage_new_object return policy:
struct A {
static A* create () { return new A; }
std::string hello () { return "Hello, is there anybody in there?"; }
};
BOOST_PYTHON_MODULE(shared_ptr)
{
class_<A>("A",no_init)
.def("create",&A::create, return_value_policy<manage_new_object>())
.staticmethod("create")
.def("hello",&A::hello)
;
}A sample python program:
from pointer import * an_A = A.create() print an_A.hello()
Smart pointers
The usage of smart pointers (e.g. boost::shared_ptr<T>) is another common way to give away ownership of objects in C++. These kinds of smart pointer are automatically handled if you declare their existence when declaring the class to boost::python. This is done by including the holding type as a template parameter to class_<>, like in the following example:
#include <string>
#include <boost/shared_ptr.hpp>
#include <boost/python.hpp>
using namespace boost;
using namespace std;
using namespace boost::python;
struct A {
static shared_ptr<A> create () { return shared_ptr<A>(new A); }
std::string hello () { return "Just nod if you can hear me!"; }
};
BOOST_PYTHON_MODULE(shared_ptr)
{
class_<A, shared_ptr<A> >("A",init<>())
.def("create",&A::create )
.staticmethod("create")
.def("hello",&A::hello)
;
}A sample python program:
from shared_ptr import * an_A = A.create() print an_A.hello()