pybind11/tests/test_cases_for_stubgen.cpp
2023-11-16 00:08:23 -08:00

223 lines
8.2 KiB
C++

#include "pybind11/stl.h"
#include "pybind11/stl_bind.h"
#include "pybind11_tests.h"
#include <array>
#include <map>
#include <vector>
namespace test_cases_for_stubgen {
// The `basics` code was copied from here (to have all test cases for stubgen in one place):
// https://github.com/python/mypy/blob/c6cb3c6282003dd3dadcf028735f9ba6190a0c84/test-data/pybind11_mypy_demo/src/main.cpp
// Copyright (c) 2016 The Pybind Development Team, All rights reserved.
namespace basics {
int answer() { return 42; }
int sum(int a, int b) { return a + b; }
double midpoint(double left, double right) { return left + (right - left) / 2; }
double weighted_midpoint(double left, double right, double alpha = 0.5) {
return left + (right - left) * alpha;
}
struct Point {
enum class LengthUnit { mm = 0, pixel, inch };
enum class AngleUnit { radian = 0, degree };
Point() : Point(0, 0) {}
Point(double x, double y) : x(x), y(y) {}
static const Point origin;
static const Point x_axis;
static const Point y_axis;
static LengthUnit length_unit;
static AngleUnit angle_unit;
double length() const { return std::sqrt(x * x + y * y); }
double distance_to(double other_x, double other_y) const {
double dx = x - other_x;
double dy = y - other_y;
return std::sqrt(dx * dx + dy * dy);
}
double distance_to(const Point &other) const { return distance_to(other.x, other.y); }
double x, y;
};
const Point Point::origin = Point(0, 0);
const Point Point::x_axis = Point(1, 0);
const Point Point::y_axis = Point(0, 1);
Point::LengthUnit Point::length_unit = Point::LengthUnit::mm;
Point::AngleUnit Point::angle_unit = Point::AngleUnit::radian;
} // namespace basics
void bind_basics(py::module &basics) {
using namespace basics;
// Functions
basics.def(
"answer", &answer, "answer docstring, with end quote\""); // tests explicit docstrings
basics.def("sum", &sum, "multiline docstring test, edge case quotes \"\"\"'''");
basics.def("midpoint", &midpoint, py::arg("left"), py::arg("right"));
basics.def("weighted_midpoint",
weighted_midpoint,
py::arg("left"),
py::arg("right"),
py::arg("alpha") = 0.5);
// Classes
py::class_<Point> pyPoint(basics, "Point");
py::enum_<Point::LengthUnit> pyLengthUnit(pyPoint, "LengthUnit");
py::enum_<Point::AngleUnit> pyAngleUnit(pyPoint, "AngleUnit");
pyPoint.def(py::init<>())
.def(py::init<double, double>(), py::arg("x"), py::arg("y"))
#ifdef PYBIND11_CPP14
.def("distance_to",
py::overload_cast<double, double>(&Point::distance_to, py::const_),
py::arg("x"),
py::arg("y"))
.def("distance_to",
py::overload_cast<const Point &>(&Point::distance_to, py::const_),
py::arg("other"))
#else
.def("distance_to",
static_cast<double (Point::*)(double, double) const>(&Point::distance_to),
py::arg("x"),
py::arg("y"))
.def("distance_to",
static_cast<double (Point::*)(const Point &) const>(&Point::distance_to),
py::arg("other"))
#endif
.def_readwrite("x", &Point::x)
.def_property(
"y",
[](Point &self) { return self.y; },
[](Point &self, double value) { self.y = value; })
.def_property_readonly("length", &Point::length)
.def_property_readonly_static("x_axis", [](py::handle /*cls*/) { return Point::x_axis; })
.def_property_readonly_static("y_axis", [](py::handle /*cls*/) { return Point::y_axis; })
.def_readwrite_static("length_unit", &Point::length_unit)
.def_property_static(
"angle_unit",
[](py::handle /*cls*/) { return Point::angle_unit; },
[](py::handle /*cls*/, Point::AngleUnit value) { Point::angle_unit = value; });
pyPoint.attr("origin") = Point::origin;
pyLengthUnit.value("mm", Point::LengthUnit::mm)
.value("pixel", Point::LengthUnit::pixel)
.value("inch", Point::LengthUnit::inch);
pyAngleUnit.value("radian", Point::AngleUnit::radian)
.value("degree", Point::AngleUnit::degree);
// Module-level attributes
basics.attr("PI") = std::acos(-1);
basics.attr("__version__") = "0.0.1";
}
struct UserType {
bool operator<(const UserType &) const { return false; }
};
struct minimal_caster {
static constexpr auto name = py::detail::const_name<UserType>();
static py::handle
cast(UserType const & /*src*/, py::return_value_policy /*policy*/, py::handle /*parent*/) {
return py::none().release();
}
// Maximizing simplicity. This will go terribly wrong for other arg types.
template <typename>
using cast_op_type = const UserType &;
// NOLINTNEXTLINE(google-explicit-constructor)
operator UserType const &() {
static UserType obj;
return obj;
}
bool load(py::handle /*src*/, bool /*convert*/) { return false; }
};
} // namespace test_cases_for_stubgen
namespace pybind11 {
namespace detail {
template <>
struct type_caster<test_cases_for_stubgen::UserType> : test_cases_for_stubgen::minimal_caster {};
} // namespace detail
} // namespace pybind11
PYBIND11_MAKE_OPAQUE(std::map<int, test_cases_for_stubgen::UserType>);
PYBIND11_MAKE_OPAQUE(std::map<test_cases_for_stubgen::UserType, int>);
PYBIND11_MAKE_OPAQUE(std::map<float, test_cases_for_stubgen::UserType>);
PYBIND11_MAKE_OPAQUE(std::map<test_cases_for_stubgen::UserType, float>);
TEST_SUBMODULE(cases_for_stubgen, m) {
auto basics = m.def_submodule("basics");
test_cases_for_stubgen::bind_basics(basics);
using UserType = test_cases_for_stubgen::UserType;
m.def("pass_user_type", [](const UserType &) {});
m.def("return_user_type", []() { return UserType(); });
py::bind_map<std::map<int, UserType>>(m, "MapIntUserType");
py::bind_map<std::map<UserType, int>>(m, "MapUserTypeInt");
#define LOCAL_HELPER(MapTypePythonName, ...) \
py::class_<__VA_ARGS__>(m, MapTypePythonName) \
.def( \
"keys", \
[](const __VA_ARGS__ &v) { return py::make_key_iterator(v); }, \
py::keep_alive<0, 1>()) \
.def( \
"values", \
[](const __VA_ARGS__ &v) { return py::make_value_iterator(v); }, \
py::keep_alive<0, 1>()) \
.def( \
"__iter__", \
[](const __VA_ARGS__ &v) { return py::make_iterator(v.begin(), v.end()); }, \
py::keep_alive<0, 1>())
LOCAL_HELPER("MapFloatUserType", std::map<float, UserType>);
LOCAL_HELPER("MapUserTypeFloat", std::map<UserType, float>);
#undef LOCAL_HELPER
m.def("pass_std_array_int_2", [](const std::array<int, 2> &) {});
m.def("return_std_array_int_3", []() { return std::array<int, 3>{{1, 2, 3}}; });
// Rather arbitrary, meant to be a torture test for recursive processing.
using nested_case_01a = std::vector<std::array<int, 2>>;
using nested_case_02a = std::vector<UserType>;
using nested_case_03a = std::map<std::array<int, 2>, UserType>;
using nested_case_04a = std::map<nested_case_01a, nested_case_02a>;
using nested_case_05a = std::vector<nested_case_04a>;
using nested_case_06a = std::map<nested_case_04a, nested_case_05a>;
#define LOCAL_HELPER(name) m.def(#name, [](const name &) {})
LOCAL_HELPER(nested_case_01a);
LOCAL_HELPER(nested_case_02a);
LOCAL_HELPER(nested_case_03a);
LOCAL_HELPER(nested_case_04a);
LOCAL_HELPER(nested_case_05a);
LOCAL_HELPER(nested_case_06a);
#undef LOCAL_HELPER
}