knx/examples/knxPython/pybind11/tests/test_kwargs_and_defaults.cpp
2024-09-14 19:38:30 +02:00

326 lines
11 KiB
C++

/*
tests/test_kwargs_and_defaults.cpp -- keyword arguments and default values
Copyright (c) 2016 Wenzel Jakob <wenzel.jakob@epfl.ch>
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/stl.h>
#include "constructor_stats.h"
#include "pybind11_tests.h"
#include <utility>
TEST_SUBMODULE(kwargs_and_defaults, m) {
auto kw_func
= [](int x, int y) { return "x=" + std::to_string(x) + ", y=" + std::to_string(y); };
// test_named_arguments
m.def("kw_func0", kw_func);
m.def("kw_func1", kw_func, py::arg("x"), py::arg("y"));
m.def("kw_func2", kw_func, py::arg("x") = 100, py::arg("y") = 200);
m.def("kw_func3", [](const char *) {}, py::arg("data") = std::string("Hello world!"));
/* A fancier default argument */
std::vector<int> list{{13, 17}};
m.def(
"kw_func4",
[](const std::vector<int> &entries) {
std::string ret = "{";
for (int i : entries) {
ret += std::to_string(i) + " ";
}
ret.back() = '}';
return ret;
},
py::arg("myList") = list);
m.def("kw_func_udl", kw_func, "x"_a, "y"_a = 300);
m.def("kw_func_udl_z", kw_func, "x"_a, "y"_a = 0);
// test line breaks in default argument representation
struct CustomRepr {
std::string repr_string;
explicit CustomRepr(const std::string &repr) : repr_string(repr) {}
std::string __repr__() const { return repr_string; }
};
py::class_<CustomRepr>(m, "CustomRepr")
.def(py::init<const std::string &>())
.def("__repr__", &CustomRepr::__repr__);
m.def(
"kw_lb_func0",
[](const CustomRepr &) {},
py::arg("custom") = CustomRepr(" array([[A, B], [C, D]]) "));
m.def(
"kw_lb_func1",
[](const CustomRepr &) {},
py::arg("custom") = CustomRepr(" array([[A, B],\n[C, D]]) "));
m.def(
"kw_lb_func2",
[](const CustomRepr &) {},
py::arg("custom") = CustomRepr("\v\n array([[A, B], [C, D]])"));
m.def(
"kw_lb_func3",
[](const CustomRepr &) {},
py::arg("custom") = CustomRepr("array([[A, B], [C, D]]) \f\n"));
m.def(
"kw_lb_func4",
[](const CustomRepr &) {},
py::arg("custom") = CustomRepr("array([[A, B],\n\f\n[C, D]])"));
m.def(
"kw_lb_func5",
[](const CustomRepr &) {},
py::arg("custom") = CustomRepr("array([[A, B],\r [C, D]])"));
m.def("kw_lb_func6", [](const CustomRepr &) {}, py::arg("custom") = CustomRepr(" \v\t "));
m.def(
"kw_lb_func7",
[](const std::string &) {},
py::arg("str_arg") = "First line.\n Second line.");
m.def("kw_lb_func8", [](const CustomRepr &) {}, py::arg("custom") = CustomRepr(""));
// test_args_and_kwargs
m.def("args_function", [](py::args args) -> py::tuple {
PYBIND11_WARNING_PUSH
#ifdef PYBIND11_DETECTED_CLANG_WITH_MISLEADING_CALL_STD_MOVE_EXPLICITLY_WARNING
PYBIND11_WARNING_DISABLE_CLANG("-Wreturn-std-move")
#endif
return args;
PYBIND11_WARNING_POP
});
m.def("args_kwargs_function", [](const py::args &args, const py::kwargs &kwargs) {
return py::make_tuple(args, kwargs);
});
// test_mixed_args_and_kwargs
m.def("mixed_plus_args",
[](int i, double j, const py::args &args) { return py::make_tuple(i, j, args); });
m.def("mixed_plus_kwargs",
[](int i, double j, const py::kwargs &kwargs) { return py::make_tuple(i, j, kwargs); });
auto mixed_plus_both = [](int i, double j, const py::args &args, const py::kwargs &kwargs) {
return py::make_tuple(i, j, args, kwargs);
};
m.def("mixed_plus_args_kwargs", mixed_plus_both);
m.def("mixed_plus_args_kwargs_defaults",
mixed_plus_both,
py::arg("i") = 1,
py::arg("j") = 3.14159);
m.def(
"args_kwonly",
[](int i, double j, const py::args &args, int z) { return py::make_tuple(i, j, args, z); },
"i"_a,
"j"_a,
"z"_a);
m.def(
"args_kwonly_kwargs",
[](int i, double j, const py::args &args, int z, const py::kwargs &kwargs) {
return py::make_tuple(i, j, args, z, kwargs);
},
"i"_a,
"j"_a,
py::kw_only{},
"z"_a);
m.def(
"args_kwonly_kwargs_defaults",
[](int i, double j, const py::args &args, int z, const py::kwargs &kwargs) {
return py::make_tuple(i, j, args, z, kwargs);
},
"i"_a = 1,
"j"_a = 3.14159,
"z"_a = 42);
m.def(
"args_kwonly_full_monty",
[](int h, int i, double j, const py::args &args, int z, const py::kwargs &kwargs) {
return py::make_tuple(h, i, j, args, z, kwargs);
},
py::arg() = 1,
py::arg() = 2,
py::pos_only{},
"j"_a = 3.14159,
"z"_a = 42);
// test_args_refcount
// PyPy needs a garbage collection to get the reference count values to match CPython's behaviour
// PyPy uses the top few bits for REFCNT_FROM_PYPY & REFCNT_FROM_PYPY_LIGHT, so truncate
#ifdef PYPY_VERSION
# define GC_IF_NEEDED ConstructorStats::gc()
# define REFCNT(x) (int) Py_REFCNT(x)
#else
# define GC_IF_NEEDED
# define REFCNT(x) Py_REFCNT(x)
#endif
m.def("arg_refcount_h", [](py::handle h) {
GC_IF_NEEDED;
return h.ref_count();
});
m.def("arg_refcount_h", [](py::handle h, py::handle, py::handle) {
GC_IF_NEEDED;
return h.ref_count();
});
m.def("arg_refcount_o", [](const py::object &o) {
GC_IF_NEEDED;
return o.ref_count();
});
m.def("args_refcount", [](py::args a) {
GC_IF_NEEDED;
py::tuple t(a.size());
for (size_t i = 0; i < a.size(); i++) {
// Use raw Python API here to avoid an extra, intermediate incref on the tuple item:
t[i] = REFCNT(PyTuple_GET_ITEM(a.ptr(), static_cast<py::ssize_t>(i)));
}
return t;
});
m.def("mixed_args_refcount", [](const py::object &o, py::args a) {
GC_IF_NEEDED;
py::tuple t(a.size() + 1);
t[0] = o.ref_count();
for (size_t i = 0; i < a.size(); i++) {
// Use raw Python API here to avoid an extra, intermediate incref on the tuple item:
t[i + 1] = REFCNT(PyTuple_GET_ITEM(a.ptr(), static_cast<py::ssize_t>(i)));
}
return t;
});
// pybind11 won't allow these to be bound: args and kwargs, if present, must be at the end.
// Uncomment these to test that the static_assert is indeed working:
// m.def("bad_args1", [](py::args, int) {});
// m.def("bad_args2", [](py::kwargs, int) {});
// m.def("bad_args3", [](py::kwargs, py::args) {});
// m.def("bad_args4", [](py::args, int, py::kwargs) {});
// m.def("bad_args5", [](py::args, py::kwargs, int) {});
// m.def("bad_args6", [](py::args, py::args) {});
// m.def("bad_args7", [](py::kwargs, py::kwargs) {});
// test_keyword_only_args
m.def(
"kw_only_all",
[](int i, int j) { return py::make_tuple(i, j); },
py::kw_only(),
py::arg("i"),
py::arg("j"));
m.def(
"kw_only_some",
[](int i, int j, int k) { return py::make_tuple(i, j, k); },
py::arg(),
py::kw_only(),
py::arg("j"),
py::arg("k"));
m.def(
"kw_only_with_defaults",
[](int i, int j, int k, int z) { return py::make_tuple(i, j, k, z); },
py::arg() = 3,
"j"_a = 4,
py::kw_only(),
"k"_a = 5,
"z"_a);
m.def(
"kw_only_mixed",
[](int i, int j) { return py::make_tuple(i, j); },
"i"_a,
py::kw_only(),
"j"_a);
m.def(
"kw_only_plus_more",
[](int i, int j, int k, const py::kwargs &kwargs) {
return py::make_tuple(i, j, k, kwargs);
},
py::arg() /* positional */,
py::arg("j") = -1 /* both */,
py::kw_only(),
py::arg("k") /* kw-only */);
m.def("register_invalid_kw_only", [](py::module_ m) {
m.def(
"bad_kw_only",
[](int i, int j) { return py::make_tuple(i, j); },
py::kw_only(),
py::arg() /* invalid unnamed argument */,
"j"_a);
});
// test_positional_only_args
m.def(
"pos_only_all",
[](int i, int j) { return py::make_tuple(i, j); },
py::arg("i"),
py::arg("j"),
py::pos_only());
m.def(
"pos_only_mix",
[](int i, int j) { return py::make_tuple(i, j); },
py::arg("i"),
py::pos_only(),
py::arg("j"));
m.def(
"pos_kw_only_mix",
[](int i, int j, int k) { return py::make_tuple(i, j, k); },
py::arg("i"),
py::pos_only(),
py::arg("j"),
py::kw_only(),
py::arg("k"));
m.def(
"pos_only_def_mix",
[](int i, int j, int k) { return py::make_tuple(i, j, k); },
py::arg("i"),
py::arg("j") = 2,
py::pos_only(),
py::arg("k") = 3);
// These should fail to compile:
#ifdef PYBIND11_NEVER_DEFINED_EVER
// argument annotations are required when using kw_only
m.def("bad_kw_only1", [](int) {}, py::kw_only());
// can't specify both `py::kw_only` and a `py::args` argument
m.def("bad_kw_only2", [](int i, py::args) {}, py::kw_only(), "i"_a);
#endif
// test_function_signatures (along with most of the above)
struct KWClass {
void foo(int, float) {}
};
py::class_<KWClass>(m, "KWClass")
.def("foo0", &KWClass::foo)
.def("foo1", &KWClass::foo, "x"_a, "y"_a);
// Make sure a class (not an instance) can be used as a default argument.
// The return value doesn't matter, only that the module is importable.
m.def(
"class_default_argument",
[](py::object a) { return py::repr(std::move(a)); },
"a"_a = py::module_::import("decimal").attr("Decimal"));
// Initial implementation of kw_only was broken when used on a method/constructor before any
// other arguments
// https://github.com/pybind/pybind11/pull/3402#issuecomment-963341987
struct first_arg_kw_only {};
py::class_<first_arg_kw_only>(m, "first_arg_kw_only")
.def(py::init([](int) { return first_arg_kw_only(); }),
py::kw_only(), // This being before any args was broken
py::arg("i") = 0)
.def(
"method",
[](first_arg_kw_only &, int, int) {},
py::kw_only(), // and likewise here
py::arg("i") = 1,
py::arg("j") = 2)
// Closely related: pos_only marker didn't show up properly when it was before any other
// arguments (although that is fairly useless in practice).
.def(
"pos_only",
[](first_arg_kw_only &, int, int) {},
py::pos_only{},
py::arg("i"),
py::arg("j"));
}