pybind11/tests/test_smart_ptr.cpp

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/*
tests/test_smart_ptr.cpp -- binding classes with custom reference counting,
implicit conversions between types
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Copyright (c) 2016 Wenzel Jakob <wenzel.jakob@epfl.ch>
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All rights reserved. Use of this source code is governed by a
BSD-style license that can be found in the LICENSE file.
*/
#include "pybind11_tests.h"
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#include "object.h"
/// Custom object with builtin reference counting (see 'object.h' for the implementation)
class MyObject1 : public Object {
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public:
MyObject1(int value) : value(value) {
Improve constructor/destructor tracking This commit rewrites the examples that look for constructor/destructor calls to do so via static variable tracking rather than output parsing. The added ConstructorStats class provides methods to keep track of constructors and destructors, number of default/copy/move constructors, and number of copy/move assignments. It also provides a mechanism for storing values (e.g. for value construction), and then allows all of this to be checked at the end of a test by getting the statistics for a C++ (or python mapping) class. By not relying on the precise pattern of constructions/destructions, but rather simply ensuring that every construction is matched with a destruction on the same object, we ensure that everything that gets created also gets destroyed as expected. This replaces all of the various "std::cout << whatever" code in constructors/destructors with `print_created(this)`/`print_destroyed(this)`/etc. functions which provide similar output, but now has a unified format across the different examples, including a new ### prefix that makes mixed example output and lifecycle events easier to distinguish. With this change, relaxed mode is no longer needed, which enables testing for proper destruction under MSVC, and under any other compiler that generates code calling extra constructors, or optimizes away any constructors. GCC/clang are used as the baseline for move constructors; the tests are adapted to allow more move constructors to be evoked (but other types are constructors much have matching counts). This commit also disables output buffering of tests, as the buffering sometimes results in C++ output ending up in the middle of python output (or vice versa), depending on the OS/python version.
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print_created(this, toString());
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}
std::string toString() const {
return "MyObject1[" + std::to_string(value) + "]";
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}
protected:
virtual ~MyObject1() {
Improve constructor/destructor tracking This commit rewrites the examples that look for constructor/destructor calls to do so via static variable tracking rather than output parsing. The added ConstructorStats class provides methods to keep track of constructors and destructors, number of default/copy/move constructors, and number of copy/move assignments. It also provides a mechanism for storing values (e.g. for value construction), and then allows all of this to be checked at the end of a test by getting the statistics for a C++ (or python mapping) class. By not relying on the precise pattern of constructions/destructions, but rather simply ensuring that every construction is matched with a destruction on the same object, we ensure that everything that gets created also gets destroyed as expected. This replaces all of the various "std::cout << whatever" code in constructors/destructors with `print_created(this)`/`print_destroyed(this)`/etc. functions which provide similar output, but now has a unified format across the different examples, including a new ### prefix that makes mixed example output and lifecycle events easier to distinguish. With this change, relaxed mode is no longer needed, which enables testing for proper destruction under MSVC, and under any other compiler that generates code calling extra constructors, or optimizes away any constructors. GCC/clang are used as the baseline for move constructors; the tests are adapted to allow more move constructors to be evoked (but other types are constructors much have matching counts). This commit also disables output buffering of tests, as the buffering sometimes results in C++ output ending up in the middle of python output (or vice versa), depending on the OS/python version.
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print_destroyed(this);
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}
private:
int value;
};
/// Object managed by a std::shared_ptr<>
class MyObject2 {
public:
MyObject2(int value) : value(value) {
Improve constructor/destructor tracking This commit rewrites the examples that look for constructor/destructor calls to do so via static variable tracking rather than output parsing. The added ConstructorStats class provides methods to keep track of constructors and destructors, number of default/copy/move constructors, and number of copy/move assignments. It also provides a mechanism for storing values (e.g. for value construction), and then allows all of this to be checked at the end of a test by getting the statistics for a C++ (or python mapping) class. By not relying on the precise pattern of constructions/destructions, but rather simply ensuring that every construction is matched with a destruction on the same object, we ensure that everything that gets created also gets destroyed as expected. This replaces all of the various "std::cout << whatever" code in constructors/destructors with `print_created(this)`/`print_destroyed(this)`/etc. functions which provide similar output, but now has a unified format across the different examples, including a new ### prefix that makes mixed example output and lifecycle events easier to distinguish. With this change, relaxed mode is no longer needed, which enables testing for proper destruction under MSVC, and under any other compiler that generates code calling extra constructors, or optimizes away any constructors. GCC/clang are used as the baseline for move constructors; the tests are adapted to allow more move constructors to be evoked (but other types are constructors much have matching counts). This commit also disables output buffering of tests, as the buffering sometimes results in C++ output ending up in the middle of python output (or vice versa), depending on the OS/python version.
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print_created(this, toString());
}
std::string toString() const {
return "MyObject2[" + std::to_string(value) + "]";
}
virtual ~MyObject2() {
Improve constructor/destructor tracking This commit rewrites the examples that look for constructor/destructor calls to do so via static variable tracking rather than output parsing. The added ConstructorStats class provides methods to keep track of constructors and destructors, number of default/copy/move constructors, and number of copy/move assignments. It also provides a mechanism for storing values (e.g. for value construction), and then allows all of this to be checked at the end of a test by getting the statistics for a C++ (or python mapping) class. By not relying on the precise pattern of constructions/destructions, but rather simply ensuring that every construction is matched with a destruction on the same object, we ensure that everything that gets created also gets destroyed as expected. This replaces all of the various "std::cout << whatever" code in constructors/destructors with `print_created(this)`/`print_destroyed(this)`/etc. functions which provide similar output, but now has a unified format across the different examples, including a new ### prefix that makes mixed example output and lifecycle events easier to distinguish. With this change, relaxed mode is no longer needed, which enables testing for proper destruction under MSVC, and under any other compiler that generates code calling extra constructors, or optimizes away any constructors. GCC/clang are used as the baseline for move constructors; the tests are adapted to allow more move constructors to be evoked (but other types are constructors much have matching counts). This commit also disables output buffering of tests, as the buffering sometimes results in C++ output ending up in the middle of python output (or vice versa), depending on the OS/python version.
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print_destroyed(this);
}
private:
int value;
};
/// Object managed by a std::shared_ptr<>, additionally derives from std::enable_shared_from_this<>
class MyObject3 : public std::enable_shared_from_this<MyObject3> {
public:
MyObject3(int value) : value(value) {
Improve constructor/destructor tracking This commit rewrites the examples that look for constructor/destructor calls to do so via static variable tracking rather than output parsing. The added ConstructorStats class provides methods to keep track of constructors and destructors, number of default/copy/move constructors, and number of copy/move assignments. It also provides a mechanism for storing values (e.g. for value construction), and then allows all of this to be checked at the end of a test by getting the statistics for a C++ (or python mapping) class. By not relying on the precise pattern of constructions/destructions, but rather simply ensuring that every construction is matched with a destruction on the same object, we ensure that everything that gets created also gets destroyed as expected. This replaces all of the various "std::cout << whatever" code in constructors/destructors with `print_created(this)`/`print_destroyed(this)`/etc. functions which provide similar output, but now has a unified format across the different examples, including a new ### prefix that makes mixed example output and lifecycle events easier to distinguish. With this change, relaxed mode is no longer needed, which enables testing for proper destruction under MSVC, and under any other compiler that generates code calling extra constructors, or optimizes away any constructors. GCC/clang are used as the baseline for move constructors; the tests are adapted to allow more move constructors to be evoked (but other types are constructors much have matching counts). This commit also disables output buffering of tests, as the buffering sometimes results in C++ output ending up in the middle of python output (or vice versa), depending on the OS/python version.
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print_created(this, toString());
}
std::string toString() const {
return "MyObject3[" + std::to_string(value) + "]";
}
virtual ~MyObject3() {
Improve constructor/destructor tracking This commit rewrites the examples that look for constructor/destructor calls to do so via static variable tracking rather than output parsing. The added ConstructorStats class provides methods to keep track of constructors and destructors, number of default/copy/move constructors, and number of copy/move assignments. It also provides a mechanism for storing values (e.g. for value construction), and then allows all of this to be checked at the end of a test by getting the statistics for a C++ (or python mapping) class. By not relying on the precise pattern of constructions/destructions, but rather simply ensuring that every construction is matched with a destruction on the same object, we ensure that everything that gets created also gets destroyed as expected. This replaces all of the various "std::cout << whatever" code in constructors/destructors with `print_created(this)`/`print_destroyed(this)`/etc. functions which provide similar output, but now has a unified format across the different examples, including a new ### prefix that makes mixed example output and lifecycle events easier to distinguish. With this change, relaxed mode is no longer needed, which enables testing for proper destruction under MSVC, and under any other compiler that generates code calling extra constructors, or optimizes away any constructors. GCC/clang are used as the baseline for move constructors; the tests are adapted to allow more move constructors to be evoked (but other types are constructors much have matching counts). This commit also disables output buffering of tests, as the buffering sometimes results in C++ output ending up in the middle of python output (or vice versa), depending on the OS/python version.
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print_destroyed(this);
}
private:
int value;
};
class MyObject4 {
public:
MyObject4(int value) : value{value} {
print_created(this);
}
int value;
private:
~MyObject4() {
print_destroyed(this);
}
};
/// Make pybind aware of the ref-counted wrapper type (s)
// ref<T> is a wrapper for 'Object' which uses intrusive reference counting
// It is always possible to construct a ref<T> from an Object* pointer without
// possible incosistencies, hence the 'true' argument at the end.
PYBIND11_DECLARE_HOLDER_TYPE(T, ref<T>, true);
PYBIND11_DECLARE_HOLDER_TYPE(T, std::shared_ptr<T>); // Not required any more for std::shared_ptr,
// but it should compile without error
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// Make pybind11 aware of the non-standard getter member function
namespace pybind11 { namespace detail {
template <typename T>
struct holder_helper<ref<T>> {
static const T *get(const ref<T> &p) { return p.get_ptr(); }
};
}}
Object *make_object_1() { return new MyObject1(1); }
ref<Object> make_object_2() { return new MyObject1(2); }
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MyObject1 *make_myobject1_1() { return new MyObject1(4); }
ref<MyObject1> make_myobject1_2() { return new MyObject1(5); }
MyObject2 *make_myobject2_1() { return new MyObject2(6); }
std::shared_ptr<MyObject2> make_myobject2_2() { return std::make_shared<MyObject2>(7); }
MyObject3 *make_myobject3_1() { return new MyObject3(8); }
std::shared_ptr<MyObject3> make_myobject3_2() { return std::make_shared<MyObject3>(9); }
void print_object_1(const Object *obj) { py::print(obj->toString()); }
void print_object_2(ref<Object> obj) { py::print(obj->toString()); }
void print_object_3(const ref<Object> &obj) { py::print(obj->toString()); }
void print_object_4(const ref<Object> *obj) { py::print((*obj)->toString()); }
void print_myobject1_1(const MyObject1 *obj) { py::print(obj->toString()); }
void print_myobject1_2(ref<MyObject1> obj) { py::print(obj->toString()); }
void print_myobject1_3(const ref<MyObject1> &obj) { py::print(obj->toString()); }
void print_myobject1_4(const ref<MyObject1> *obj) { py::print((*obj)->toString()); }
void print_myobject2_1(const MyObject2 *obj) { py::print(obj->toString()); }
void print_myobject2_2(std::shared_ptr<MyObject2> obj) { py::print(obj->toString()); }
void print_myobject2_3(const std::shared_ptr<MyObject2> &obj) { py::print(obj->toString()); }
void print_myobject2_4(const std::shared_ptr<MyObject2> *obj) { py::print((*obj)->toString()); }
void print_myobject3_1(const MyObject3 *obj) { py::print(obj->toString()); }
void print_myobject3_2(std::shared_ptr<MyObject3> obj) { py::print(obj->toString()); }
void print_myobject3_3(const std::shared_ptr<MyObject3> &obj) { py::print(obj->toString()); }
void print_myobject3_4(const std::shared_ptr<MyObject3> *obj) { py::print((*obj)->toString()); }
test_initializer smart_ptr([](py::module &m) {
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py::class_<Object, ref<Object>> obj(m, "Object");
obj.def("getRefCount", &Object::getRefCount);
py::class_<MyObject1, ref<MyObject1>>(m, "MyObject1", obj)
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.def(py::init<int>());
m.def("test_object1_refcounting",
[]() -> bool {
ref<MyObject1> o = new MyObject1(0);
bool good = o->getRefCount() == 1;
py::object o2 = py::cast(o, py::return_value_policy::reference);
// always request (partial) ownership for objects with intrusive
// reference counting even when using the 'reference' RVP
good &= o->getRefCount() == 2;
return good;
}
);
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m.def("make_object_1", &make_object_1);
m.def("make_object_2", &make_object_2);
m.def("make_myobject1_1", &make_myobject1_1);
m.def("make_myobject1_2", &make_myobject1_2);
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m.def("print_object_1", &print_object_1);
m.def("print_object_2", &print_object_2);
m.def("print_object_3", &print_object_3);
m.def("print_object_4", &print_object_4);
m.def("print_myobject1_1", &print_myobject1_1);
m.def("print_myobject1_2", &print_myobject1_2);
m.def("print_myobject1_3", &print_myobject1_3);
m.def("print_myobject1_4", &print_myobject1_4);
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py::class_<MyObject2, std::shared_ptr<MyObject2>>(m, "MyObject2")
.def(py::init<int>());
m.def("make_myobject2_1", &make_myobject2_1);
m.def("make_myobject2_2", &make_myobject2_2);
m.def("print_myobject2_1", &print_myobject2_1);
m.def("print_myobject2_2", &print_myobject2_2);
m.def("print_myobject2_3", &print_myobject2_3);
m.def("print_myobject2_4", &print_myobject2_4);
py::class_<MyObject3, std::shared_ptr<MyObject3>>(m, "MyObject3")
.def(py::init<int>());
m.def("make_myobject3_1", &make_myobject3_1);
m.def("make_myobject3_2", &make_myobject3_2);
m.def("print_myobject3_1", &print_myobject3_1);
m.def("print_myobject3_2", &print_myobject3_2);
m.def("print_myobject3_3", &print_myobject3_3);
m.def("print_myobject3_4", &print_myobject3_4);
py::class_<MyObject4, std::unique_ptr<MyObject4, py::nodelete>>(m, "MyObject4")
.def(py::init<int>())
.def_readwrite("value", &MyObject4::value);
py::implicitly_convertible<py::int_, MyObject1>();
Improve constructor/destructor tracking This commit rewrites the examples that look for constructor/destructor calls to do so via static variable tracking rather than output parsing. The added ConstructorStats class provides methods to keep track of constructors and destructors, number of default/copy/move constructors, and number of copy/move assignments. It also provides a mechanism for storing values (e.g. for value construction), and then allows all of this to be checked at the end of a test by getting the statistics for a C++ (or python mapping) class. By not relying on the precise pattern of constructions/destructions, but rather simply ensuring that every construction is matched with a destruction on the same object, we ensure that everything that gets created also gets destroyed as expected. This replaces all of the various "std::cout << whatever" code in constructors/destructors with `print_created(this)`/`print_destroyed(this)`/etc. functions which provide similar output, but now has a unified format across the different examples, including a new ### prefix that makes mixed example output and lifecycle events easier to distinguish. With this change, relaxed mode is no longer needed, which enables testing for proper destruction under MSVC, and under any other compiler that generates code calling extra constructors, or optimizes away any constructors. GCC/clang are used as the baseline for move constructors; the tests are adapted to allow more move constructors to be evoked (but other types are constructors much have matching counts). This commit also disables output buffering of tests, as the buffering sometimes results in C++ output ending up in the middle of python output (or vice versa), depending on the OS/python version.
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// Expose constructor stats for the ref type
m.def("cstats_ref", &ConstructorStats::get<ref_tag>);
});
struct SharedPtrRef {
struct A {
A() { print_created(this); }
A(const A &) { print_copy_created(this); }
A(A &&) { print_move_created(this); }
~A() { print_destroyed(this); }
};
A value = {};
std::shared_ptr<A> shared = std::make_shared<A>();
};
struct SharedFromThisRef {
struct B : std::enable_shared_from_this<B> {
B() { print_created(this); }
B(const B &) : std::enable_shared_from_this<B>() { print_copy_created(this); }
B(B &&) : std::enable_shared_from_this<B>() { print_move_created(this); }
~B() { print_destroyed(this); }
};
B value = {};
std::shared_ptr<B> shared = std::make_shared<B>();
};
template <typename T>
class CustomUniquePtr {
std::unique_ptr<T> impl;
public:
CustomUniquePtr(T* p) : impl(p) { }
T* get() const { return impl.get(); }
T* release_ptr() { return impl.release(); }
};
PYBIND11_DECLARE_HOLDER_TYPE(T, CustomUniquePtr<T>);
test_initializer smart_ptr_and_references([](py::module &pm) {
auto m = pm.def_submodule("smart_ptr");
using A = SharedPtrRef::A;
py::class_<A, std::shared_ptr<A>>(m, "A");
py::class_<SharedPtrRef>(m, "SharedPtrRef")
.def(py::init<>())
.def_readonly("ref", &SharedPtrRef::value)
.def_property_readonly("copy", [](const SharedPtrRef &s) { return s.value; },
py::return_value_policy::copy)
.def_readonly("holder_ref", &SharedPtrRef::shared)
.def_property_readonly("holder_copy", [](const SharedPtrRef &s) { return s.shared; },
py::return_value_policy::copy)
.def("set_ref", [](SharedPtrRef &, const A &) { return true; })
.def("set_holder", [](SharedPtrRef &, std::shared_ptr<A>) { return true; });
using B = SharedFromThisRef::B;
py::class_<B, std::shared_ptr<B>>(m, "B");
py::class_<SharedFromThisRef>(m, "SharedFromThisRef")
.def(py::init<>())
.def_readonly("bad_wp", &SharedFromThisRef::value)
.def_property_readonly("ref", [](const SharedFromThisRef &s) -> const B & { return *s.shared; })
.def_property_readonly("copy", [](const SharedFromThisRef &s) { return s.value; },
py::return_value_policy::copy)
.def_readonly("holder_ref", &SharedFromThisRef::shared)
.def_property_readonly("holder_copy", [](const SharedFromThisRef &s) { return s.shared; },
py::return_value_policy::copy)
.def("set_ref", [](SharedFromThisRef &, const B &) { return true; })
.def("set_holder", [](SharedFromThisRef &, std::shared_ptr<B>) { return true; });
struct C {
C() { print_created(this); }
~C() { print_destroyed(this); }
};
py::class_<C, CustomUniquePtr<C>>(m, "TypeWithMoveOnlyHolder")
.def_static("make", []() { return CustomUniquePtr<C>(new C); });
struct HeldByDefaultHolder { };
py::class_<HeldByDefaultHolder>(m, "HeldByDefaultHolder")
.def(py::init<>())
.def_static("load_shared_ptr", [](std::shared_ptr<HeldByDefaultHolder>) {});
});