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	/*
	pybind11/pybind11.h: Main header file of the C++11 python
	binding generator library

	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.
	*/

	#pragma once

	#include "detail/class.h"
	#include "detail/init.h"
	#include "attr.h"
	#include "gil.h"
	#include "options.h"

	#include <cstdlib>
	#include <cstring>
	#include <memory>
	#include <new>
	#include <string>
	#include <utility>
	#include <vector>

	#if defined(__cpp_lib_launder) && !(defined(_MSC_VER) && (_MSC_VER < 1914))
	# define PYBIND11_STD_LAUNDER std::launder
	# define PYBIND11_HAS_STD_LAUNDER 1
	#else
	# define PYBIND11_STD_LAUNDER
	# define PYBIND11_HAS_STD_LAUNDER 0
	#endif
	#if defined(__GNUG__) && !defined(__clang__)
	# include <cxxabi.h>
	#endif

	/* https://stackoverflow.com/questions/46798456/handling-gccs-noexcept-type-warning
	This warning is about ABI compatibility, not code health.
	It is only actually needed in a couple places, but apparently GCC 7 "generates this warning if
	and only if the first template instantiation ... involves noexcept" [stackoverflow], therefore
	it could get triggered from seemingly random places, depending on user code.
	No other GCC version generates this warning.
	*/
	#if defined(__GNUC__) && __GNUC__ == 7
	# pragma GCC diagnostic push
	# pragma GCC diagnostic ignored "-Wnoexcept-type"
	#endif

	PYBIND11_NAMESPACE_BEGIN(PYBIND11_NAMESPACE)

	PYBIND11_NAMESPACE_BEGIN(detail)

	// Apply all the extensions translators from a list
	// Return true if one of the translators completed without raising an exception
	// itself. Return of false indicates that if there are other translators
	// available, they should be tried.
	inline bool apply_exception_translators(std::forward_list<ExceptionTranslator> &translators) {
	auto last_exception = std::current_exception();

	for (auto &translator : translators) {
	try {
	translator(last_exception);
	return true;
	} catch (...) {
	last_exception = std::current_exception();
	}
	}
	return false;
	}

	#if defined(_MSC_VER)
	# define PYBIND11_COMPAT_STRDUP _strdup
	#else
	# define PYBIND11_COMPAT_STRDUP strdup
	#endif

	PYBIND11_NAMESPACE_END(detail)

	/// Wraps an arbitrary C++ function/method/lambda function/.. into a callable Python object
	class cpp_function : public function {
	public:
	cpp_function() = default;
	// NOLINTNEXTLINE(google-explicit-constructor)
	cpp_function(std::nullptr_t) {}

	/// Construct a cpp_function from a vanilla function pointer
	template <typename Return, typename... Args, typename... Extra>
	// NOLINTNEXTLINE(google-explicit-constructor)
	cpp_function(Return (*f)(Args...), const Extra &...extra) {
	initialize(f, f, extra...);
	}

	/// Construct a cpp_function from a lambda function (possibly with internal state)
	template <typename Func,
	typename... Extra,
	typename = detail::enable_if_t<detail::is_lambda<Func>::value>>
	// NOLINTNEXTLINE(google-explicit-constructor)
	cpp_function(Func &&f, const Extra &...extra) {
	initialize(
	std::forward<Func>(f), (detail::function_signature_t<Func> *) nullptr, extra...);
	}

	/// Construct a cpp_function from a class method (non-const, no ref-qualifier)
	template <typename Return, typename Class, typename... Arg, typename... Extra>
	// NOLINTNEXTLINE(google-explicit-constructor)
	cpp_function(Return (Class::*f)(Arg...), const Extra &...extra) {
	initialize(
	[f](Class c, Arg... args) -> Return { return (c->f)(std::forward<Arg>(args)...); },
	(Return()(Class , Arg...)) nullptr,
	extra...);
	}

	/// Construct a cpp_function from a class method (non-const, lvalue ref-qualifier)
	/// A copy of the overload for non-const functions without explicit ref-qualifier
	/// but with an added `&`.
	template <typename Return, typename Class, typename... Arg, typename... Extra>
	// NOLINTNEXTLINE(google-explicit-constructor)
	cpp_function(Return (Class::*f)(Arg...) &, const Extra &...extra) {
	initialize(
	[f](Class c, Arg... args) -> Return { return (c->f)(std::forward<Arg>(args)...); },
	(Return()(Class , Arg...)) nullptr,
	extra...);
	}

	/// Construct a cpp_function from a class method (const, no ref-qualifier)
	template <typename Return, typename Class, typename... Arg, typename... Extra>
	// NOLINTNEXTLINE(google-explicit-constructor)
	cpp_function(Return (Class::*f)(Arg...) const, const Extra &...extra) {
	initialize([f](const Class *c,
	Arg... args) -> Return { return (c->*f)(std::forward<Arg>(args)...); },
	(Return()(const Class , Arg...)) nullptr,
	extra...);
	}

	/// Construct a cpp_function from a class method (const, lvalue ref-qualifier)
	/// A copy of the overload for const functions without explicit ref-qualifier
	/// but with an added `&`.
	template <typename Return, typename Class, typename... Arg, typename... Extra>
	// NOLINTNEXTLINE(google-explicit-constructor)
	cpp_function(Return (Class::*f)(Arg...) const &, const Extra &...extra) {
	initialize([f](const Class *c,
	Arg... args) -> Return { return (c->*f)(std::forward<Arg>(args)...); },
	(Return()(const Class , Arg...)) nullptr,
	extra...);
	}

	/// Return the function name
	object name() const { return attr("__name__"); }

	protected:
	struct InitializingFunctionRecordDeleter {
	// `destruct(function_record, false)`: `initialize_generic` copies strings and
	// takes care of cleaning up in case of exceptions. So pass `false` to `free_strings`.
	void operator()(detail::function_record *rec) { destruct(rec, false); }
	};
	using unique_function_record
	= std::unique_ptr<detail::function_record, InitializingFunctionRecordDeleter>;

	/// Space optimization: don't inline this frequently instantiated fragment
	PYBIND11_NOINLINE unique_function_record make_function_record() {
	return unique_function_record(new detail::function_record());
	}

	/// Special internal constructor for functors, lambda functions, etc.
	template <typename Func, typename Return, typename... Args, typename... Extra>
	void initialize(Func &&f, Return (*)(Args...), const Extra &...extra) {
	using namespace detail;
	struct capture {
	remove_reference_t<Func> f;
	};

	/* Store the function including any extra state it might have (e.g. a lambda capture
	* object) */
	// The unique_ptr makes sure nothing is leaked in case of an exception.
	auto unique_rec = make_function_record();
	auto *rec = unique_rec.get();

	/* Store the capture object directly in the function record if there is enough space */
	if (PYBIND11_SILENCE_MSVC_C4127(sizeof(capture) <= sizeof(rec->data))) {
	/* Without these pragmas, GCC warns that there might not be
	enough space to use the placement new operator. However, the
	'if' statement above ensures that this is the case. */
	#if defined(__GNUG__) && __GNUC__ >= 6 && !defined(__clang__) && !defined(__INTEL_COMPILER)
	# pragma GCC diagnostic push
	# pragma GCC diagnostic ignored "-Wplacement-new"
	#endif
	new ((capture *) &rec->data) capture{std::forward<Func>(f)};
	#if defined(__GNUG__) && __GNUC__ >= 6 && !defined(__clang__) && !defined(__INTEL_COMPILER)
	# pragma GCC diagnostic pop
	#endif
	#if defined(__GNUG__) && !PYBIND11_HAS_STD_LAUNDER && !defined(__INTEL_COMPILER)
	# pragma GCC diagnostic push
	# pragma GCC diagnostic ignored "-Wstrict-aliasing"
	#endif
	// UB without std::launder, but without breaking ABI and/or
	// a significant refactoring it's "impossible" to solve.
	if (!std::is_trivially_destructible<capture>::value) {
	rec->free_data = [](function_record *r) {
	auto data = PYBIND11_STD_LAUNDER((capture *) &r->data);
	(void) data;
	data->~capture();
	};
	}
	#if defined(__GNUG__) && !PYBIND11_HAS_STD_LAUNDER && !defined(__INTEL_COMPILER)
	# pragma GCC diagnostic pop
	#endif
	} else {
	rec->data[0] = new capture{std::forward<Func>(f)};
	rec->free_data = [](function_record r) { delete ((capture ) r->data[0]); };
	}

	/* Type casters for the function arguments and return value */
	using cast_in = argument_loader<Args...>;
	using cast_out
	= make_caster<conditional_t<std::is_void<Return>::value, void_type, Return>>;

	static_assert(
	expected_num_args<Extra...>(
	sizeof...(Args), cast_in::args_pos >= 0, cast_in::has_kwargs),
	"The number of argument annotations does not match the number of function arguments");

	/* Dispatch code which converts function arguments and performs the actual function call */
	rec->impl = [](function_call &call) -> handle {
	cast_in args_converter;

	/* Try to cast the function arguments into the C++ domain */
	if (!args_converter.load_args(call)) {
	return PYBIND11_TRY_NEXT_OVERLOAD;
	}

	/* Invoke call policy pre-call hook */
	process_attributes<Extra...>::precall(call);

	/* Get a pointer to the capture object */
	const auto *data = (sizeof(capture) <= sizeof(call.func.data) ? &call.func.data
	: call.func.data[0]);
	auto cap = const_cast<capture >(reinterpret_cast<const capture *>(data));

	/* Override policy for rvalues -- usually to enforce rvp::move on an rvalue */
	return_value_policy policy
	= return_value_policy_override<Return>::policy(call.func.policy);

	/* Function scope guard -- defaults to the compile-to-nothing `void_type` */
	using Guard = extract_guard_t<Extra...>;

	/* Perform the function call */
	handle result
	= cast_out::cast(std::move(args_converter).template call<Return, Guard>(cap->f),
	policy,
	call.parent);

	/* Invoke call policy post-call hook */
	process_attributes<Extra...>::postcall(call, result);

	return result;
	};

	rec->nargs_pos = cast_in::args_pos >= 0
	? static_cast<std::uint16_t>(cast_in::args_pos)
	: sizeof...(Args) - cast_in::has_kwargs; // Will get reduced more if
	// we have a kw_only
	rec->has_args = cast_in::args_pos >= 0;
	rec->has_kwargs = cast_in::has_kwargs;

	/* Process any user-provided function attributes */
	process_attributes<Extra...>::init(extra..., rec);

	{
	constexpr bool has_kw_only_args = any_of<std::is_same<kw_only, Extra>...>::value,
	has_pos_only_args = any_of<std::is_same<pos_only, Extra>...>::value,
	has_arg_annotations = any_of<is_keyword<Extra>...>::value;
	static_assert(has_arg_annotations \|\| !has_kw_only_args,
	"py::kw_only requires the use of argument annotations");
	static_assert(has_arg_annotations \|\| !has_pos_only_args,
	"py::pos_only requires the use of argument annotations (for docstrings "
	"and aligning the annotations to the argument)");

	static_assert(constexpr_sum(is_kw_only<Extra>::value...) <= 1,
	"py::kw_only may be specified only once");
	static_assert(constexpr_sum(is_pos_only<Extra>::value...) <= 1,
	"py::pos_only may be specified only once");
	constexpr auto kw_only_pos = constexpr_first<is_kw_only, Extra...>();
	constexpr auto pos_only_pos = constexpr_first<is_pos_only, Extra...>();
	static_assert(!(has_kw_only_args && has_pos_only_args) \|\| pos_only_pos < kw_only_pos,
	"py::pos_only must come before py::kw_only");
	}

	/* Generate a readable signature describing the function's arguments and return
	value types */
	static constexpr auto signature
	= const_name("(") + cast_in::arg_names + const_name(") -> ") + cast_out::name;
	PYBIND11_DESCR_CONSTEXPR auto types = decltype(signature)::types();

	/* Register the function with Python from generic (non-templated) code */
	// Pass on the ownership over the `unique_rec` to `initialize_generic`. `rec` stays valid.
	initialize_generic(std::move(unique_rec), signature.text, types.data(), sizeof...(Args));

	/* Stash some additional information used by an important optimization in 'functional.h' */
	using FunctionType = Return (*)(Args...);
	constexpr bool is_function_ptr
	= std::is_convertible<Func, FunctionType>::value && sizeof(capture) == sizeof(void *);
	if (is_function_ptr) {
	rec->is_stateless = true;
	rec->data[1]
	= const_cast<void >(reinterpret_cast<const void >(&typeid(FunctionType)));
	}
	}

	// Utility class that keeps track of all duplicated strings, and cleans them up in its
	// destructor, unless they are released. Basically a RAII-solution to deal with exceptions
	// along the way.
	class strdup_guard {
	public:
	strdup_guard() = default;
	strdup_guard(const strdup_guard &) = delete;
	strdup_guard &operator=(const strdup_guard &) = delete;

	~strdup_guard() {
	for (auto *s : strings) {
	std::free(s);
	}
	}
	char operator()(const char s) {
	auto *t = PYBIND11_COMPAT_STRDUP(s);
	strings.push_back(t);
	return t;
	}
	void release() { strings.clear(); }

	private:
	std::vector<char *> strings;
	};

	/// Register a function call with Python (generic non-templated code goes here)
	void initialize_generic(unique_function_record &&unique_rec,
	const char *text,
	const std::type_info const types,
	size_t args) {
	// Do NOT receive `unique_rec` by value. If this function fails to move out the unique_ptr,
	// we do not want this to destruct the pointer. `initialize` (the caller) still relies on
	// the pointee being alive after this call. Only move out if a `capsule` is going to keep
	// it alive.
	auto *rec = unique_rec.get();

	// Keep track of strdup'ed strings, and clean them up as long as the function's capsule
	// has not taken ownership yet (when `unique_rec.release()` is called).
	// Note: This cannot easily be fixed by a `unique_ptr` with custom deleter, because the
	// strings are only referenced before strdup'ing. So only after the following block could
	// `destruct` safely be called, but even then, `repr` could still throw in the middle of
	// copying all strings.
	strdup_guard guarded_strdup;

	/* Create copies of all referenced C-style strings */
	rec->name = guarded_strdup(rec->name ? rec->name : "");
	if (rec->doc) {
	rec->doc = guarded_strdup(rec->doc);
	}
	for (auto &a : rec->args) {
	if (a.name) {
	a.name = guarded_strdup(a.name);
	}
	if (a.descr) {
	a.descr = guarded_strdup(a.descr);
	} else if (a.value) {
	a.descr = guarded_strdup(repr(a.value).cast<std::string>().c_str());
	}
	}

	rec->is_constructor = (std::strcmp(rec->name, "__init__") == 0)
	\|\| (std::strcmp(rec->name, "__setstate__") == 0);

	#if defined(PYBIND11_DETAILED_ERROR_MESSAGES) && !defined(PYBIND11_DISABLE_NEW_STYLE_INIT_WARNING)
	if (rec->is_constructor && !rec->is_new_style_constructor) {
	const auto class_name
	= detail::get_fully_qualified_tp_name((PyTypeObject *) rec->scope.ptr());
	const auto func_name = std::string(rec->name);
	PyErr_WarnEx(PyExc_FutureWarning,
	("pybind11-bound class '" + class_name
	+ "' is using an old-style "
	"placement-new '"
	+ func_name
	+ "' which has been deprecated. See "
	"the upgrade guide in pybind11's docs. This message is only visible "
	"when compiled in debug mode.")
	.c_str(),
	0);
	}
	#endif

	/* Generate a proper function signature */
	std::string signature;
	size_t type_index = 0, arg_index = 0;
	bool is_starred = false;
	for (const auto pc = text; pc != '\0'; ++pc) {
	const auto c = *pc;

	if (c == '{') {
	// Write arg name for everything except args and *kwargs.
	is_starred = (pc + 1) == '';
	if (is_starred) {
	continue;
	}
	// Separator for keyword-only arguments, placed before the kw
	// arguments start (unless we are already putting an *args)
	if (!rec->has_args && arg_index == rec->nargs_pos) {
	signature += "*, ";
	}
	if (arg_index < rec->args.size() && rec->args[arg_index].name) {
	signature += rec->args[arg_index].name;
	} else if (arg_index == 0 && rec->is_method) {
	signature += "self";
	} else {
	signature += "arg" + std::to_string(arg_index - (rec->is_method ? 1 : 0));
	}
	signature += ": ";
	} else if (c == '}') {
	// Write default value if available.
	if (!is_starred && arg_index < rec->args.size() && rec->args[arg_index].descr) {
	signature += " = ";
	signature += rec->args[arg_index].descr;
	}
	// Separator for positional-only arguments (placed after the
	// argument, rather than before like *
	if (rec->nargs_pos_only > 0 && (arg_index + 1) == rec->nargs_pos_only) {
	signature += ", /";
	}
	if (!is_starred) {
	arg_index++;
	}
	} else if (c == '%') {
	const std::type_info *t = types[type_index++];
	if (!t) {
	pybind11_fail("Internal error while parsing type signature (1)");
	}
	if (auto tinfo = detail::get_type_info(t)) {
	handle th((PyObject *) tinfo->type);
	signature += th.attr("__module__").cast<std::string>() + "."
	+ th.attr("__qualname__").cast<std::string>();
	} else if (rec->is_new_style_constructor && arg_index == 0) {
	// A new-style `__init__` takes `self` as `value_and_holder`.
	// Rewrite it to the proper class type.
	signature += rec->scope.attr("__module__").cast<std::string>() + "."
	+ rec->scope.attr("__qualname__").cast<std::string>();
	} else {
	std::string tname(t->name());
	detail::clean_type_id(tname);
	signature += tname;
	}
	} else {
	signature += c;
	}
	}

	if (arg_index != args - rec->has_args - rec->has_kwargs \|\| types[type_index] != nullptr) {
	pybind11_fail("Internal error while parsing type signature (2)");
	}

	rec->signature = guarded_strdup(signature.c_str());
	rec->args.shrink_to_fit();
	rec->nargs = (std::uint16_t) args;

	if (rec->sibling && PYBIND11_INSTANCE_METHOD_CHECK(rec->sibling.ptr())) {
	rec->sibling = PYBIND11_INSTANCE_METHOD_GET_FUNCTION(rec->sibling.ptr());
	}

	detail::function_record chain = nullptr, chain_start = rec;
	if (rec->sibling) {
	if (PyCFunction_Check(rec->sibling.ptr())) {
	auto *self = PyCFunction_GET_SELF(rec->sibling.ptr());
	capsule rec_capsule = isinstance<capsule>(self) ? reinterpret_borrow<capsule>(self)
	: capsule(self);
	chain = (detail::function_record *) rec_capsule;
	/* Never append a method to an overload chain of a parent class;
	instead, hide the parent's overloads in this case */
	if (!chain->scope.is(rec->scope)) {
	chain = nullptr;
	}
	}
	// Don't trigger for things like the default __init__, which are wrapper_descriptors
	// that we are intentionally replacing
	else if (!rec->sibling.is_none() && rec->name[0] != '_') {
	pybind11_fail("Cannot overload existing non-function object \""
	+ std::string(rec->name) + "\" with a function of the same name");
	}
	}

	if (!chain) {
	/* No existing overload was found, create a new function object */
	rec->def = new PyMethodDef();
	std::memset(rec->def, 0, sizeof(PyMethodDef));
	rec->def->ml_name = rec->name;
	rec->def->ml_meth
	= reinterpret_cast<PyCFunction>(reinterpret_cast<void (*)()>(dispatcher));
	rec->def->ml_flags = METH_VARARGS \| METH_KEYWORDS;

	capsule rec_capsule(unique_rec.release(),
	[](void ptr) { destruct((detail::function_record ) ptr); });
	guarded_strdup.release();

	object scope_module;
	if (rec->scope) {
	if (hasattr(rec->scope, "__module__")) {
	scope_module = rec->scope.attr("__module__");
	} else if (hasattr(rec->scope, "__name__")) {
	scope_module = rec->scope.attr("__name__");
	}
	}

	m_ptr = PyCFunction_NewEx(rec->def, rec_capsule.ptr(), scope_module.ptr());
	if (!m_ptr) {
	pybind11_fail("cpp_function::cpp_function(): Could not allocate function object");
	}
	} else {
	/* Append at the beginning or end of the overload chain */
	m_ptr = rec->sibling.ptr();
	inc_ref();
	if (chain->is_method != rec->is_method) {
	pybind11_fail(
	"overloading a method with both static and instance methods is not supported; "
	#if !defined(PYBIND11_DETAILED_ERROR_MESSAGES)
	"#define PYBIND11_DETAILED_ERROR_MESSAGES or compile in debug mode for more "
	"details"
	#else
	"error while attempting to bind "
	+ std::string(rec->is_method ? "instance" : "static") + " method "
	+ std::string(pybind11::str(rec->scope.attr("__name__"))) + "."
	+ std::string(rec->name) + signature
	#endif
	);
	}

	if (rec->prepend) {
	// Beginning of chain; we need to replace the capsule's current head-of-the-chain
	// pointer with this one, then make this one point to the previous head of the
	// chain.
	chain_start = rec;
	rec->next = chain;
	auto rec_capsule
	= reinterpret_borrow<capsule>(((PyCFunctionObject *) m_ptr)->m_self);
	rec_capsule.set_pointer(unique_rec.release());
	guarded_strdup.release();
	} else {
	// Or end of chain (normal behavior)
	chain_start = chain;
	while (chain->next) {
	chain = chain->next;
	}
	chain->next = unique_rec.release();
	guarded_strdup.release();
	}
	}

	std::string signatures;
	int index = 0;
	/* Create a nice pydoc rec including all signatures and
	docstrings of the functions in the overload chain */
	if (chain && options::show_function_signatures()) {
	// First a generic signature
	signatures += rec->name;
	signatures += "(args, *kwargs)\n";
	signatures += "Overloaded function.\n\n";
	}
	// Then specific overload signatures
	bool first_user_def = true;
	for (auto *it = chain_start; it != nullptr; it = it->next) {
	if (options::show_function_signatures()) {
	if (index > 0) {
	signatures += '\n';
	}
	if (chain) {
	signatures += std::to_string(++index) + ". ";
	}
	signatures += rec->name;
	signatures += it->signature;
	signatures += '\n';
	}
	if (it->doc && it->doc[0] != '\0' && options::show_user_defined_docstrings()) {
	// If we're appending another docstring, and aren't printing function signatures,
	// we need to append a newline first:
	if (!options::show_function_signatures()) {
	if (first_user_def) {
	first_user_def = false;
	} else {
	signatures += '\n';
	}
	}
	if (options::show_function_signatures()) {
	signatures += '\n';
	}
	signatures += it->doc;
	if (options::show_function_signatures()) {
	signatures += '\n';
	}
	}
	}

	/* Install docstring */
	auto func = (PyCFunctionObject ) m_ptr;
	std::free(const_cast<char *>(func->m_ml->ml_doc));
	// Install docstring if it's non-empty (when at least one option is enabled)
	func->m_ml->ml_doc
	= signatures.empty() ? nullptr : PYBIND11_COMPAT_STRDUP(signatures.c_str());

	if (rec->is_method) {
	m_ptr = PYBIND11_INSTANCE_METHOD_NEW(m_ptr, rec->scope.ptr());
	if (!m_ptr) {
	pybind11_fail(
	"cpp_function::cpp_function(): Could not allocate instance method object");
	}
	Py_DECREF(func);
	}
	}

	/// When a cpp_function is GCed, release any memory allocated by pybind11
	static void destruct(detail::function_record *rec, bool free_strings = true) {
	// If on Python 3.9, check the interpreter "MICRO" (patch) version.
	// If this is running on 3.9.0, we have to work around a bug.
	#if !defined(PYPY_VERSION) && PY_MAJOR_VERSION == 3 && PY_MINOR_VERSION == 9
	static bool is_zero = Py_GetVersion()[4] == '0';
	#endif

	while (rec) {
	detail::function_record *next = rec->next;
	if (rec->free_data) {
	rec->free_data(rec);
	}
	// During initialization, these strings might not have been copied yet,
	// so they cannot be freed. Once the function has been created, they can.
	// Check `make_function_record` for more details.
	if (free_strings) {
	std::free((char *) rec->name);
	std::free((char *) rec->doc);
	std::free((char *) rec->signature);
	for (auto &arg : rec->args) {
	std::free(const_cast<char *>(arg.name));
	std::free(const_cast<char *>(arg.descr));
	}
	}
	for (auto &arg : rec->args) {
	arg.value.dec_ref();
	}
	if (rec->def) {
	std::free(const_cast<char *>(rec->def->ml_doc));
	// Python 3.9.0 decref's these in the wrong order; rec->def
	// If loaded on 3.9.0, let these leak (use Python 3.9.1 at runtime to fix)
	// See https://github.com/python/cpython/pull/22670
	#if !defined(PYPY_VERSION) && PY_MAJOR_VERSION == 3 && PY_MINOR_VERSION == 9
	if (!is_zero) {
	delete rec->def;
	}
	#else
	delete rec->def;
	#endif
	}
	delete rec;
	rec = next;
	}
	}

	/// Main dispatch logic for calls to functions bound using pybind11
	static PyObject dispatcher(PyObject self, PyObject args_in, PyObject kwargs_in) {
	using namespace detail;

	/* Iterator over the list of potentially admissible overloads */
	const function_record overloads = (function_record ) PyCapsule_GetPointer(self, nullptr),
	*it = overloads;

	/* Need to know how many arguments + keyword arguments there are to pick the right
	overload */
	const auto n_args_in = (size_t) PyTuple_GET_SIZE(args_in);

	handle parent = n_args_in > 0 ? PyTuple_GET_ITEM(args_in, 0) : nullptr,
	result = PYBIND11_TRY_NEXT_OVERLOAD;

	auto self_value_and_holder = value_and_holder();
	if (overloads->is_constructor) {
	if (!parent
	\|\| !PyObject_TypeCheck(parent.ptr(), (PyTypeObject *) overloads->scope.ptr())) {
	PyErr_SetString(
	PyExc_TypeError,
	"__init__(self, ...) called with invalid or missing `self` argument");
	return nullptr;
	}

	auto const tinfo = get_type_info((PyTypeObject ) overloads->scope.ptr());
	auto const pi = reinterpret_cast<instance >(parent.ptr());
	self_value_and_holder = pi->get_value_and_holder(tinfo, true);

	// If this value is already registered it must mean __init__ is invoked multiple times;
	// we really can't support that in C++, so just ignore the second __init__.
	if (self_value_and_holder.instance_registered()) {
	return none().release().ptr();
	}
	}

	try {
	// We do this in two passes: in the first pass, we load arguments with `convert=false`;
	// in the second, we allow conversion (except for arguments with an explicit
	// py::arg().noconvert()). This lets us prefer calls without conversion, with
	// conversion as a fallback.
	std::vector<function_call> second_pass;

	// However, if there are no overloads, we can just skip the no-convert pass entirely
	const bool overloaded = it != nullptr && it->next != nullptr;

	for (; it != nullptr; it = it->next) {

	/* For each overload:
	1. Copy all positional arguments we were given, also checking to make sure that
	named positional arguments weren't also specified via kwarg.
	2. If we weren't given enough, try to make up the omitted ones by checking
	whether they were provided by a kwarg matching the `py::arg("name")` name. If
	so, use it (and remove it from kwargs); if not, see if the function binding
	provided a default that we can use.
	3. Ensure that either all keyword arguments were "consumed", or that the
	function takes a kwargs argument to accept unconsumed kwargs.
	4. Any positional arguments still left get put into a tuple (for args), and any
	leftover kwargs get put into a dict.
	5. Pack everything into a vector; if we have py::args or py::kwargs, they are an
	extra tuple or dict at the end of the positional arguments.
	6. Call the function call dispatcher (function_record::impl)

	If one of these fail, move on to the next overload and keep trying until we get
	a result other than PYBIND11_TRY_NEXT_OVERLOAD.
	*/

	const function_record &func = *it;
	size_t num_args = func.nargs; // Number of positional arguments that we need
	if (func.has_args) {
	--num_args; // (but don't count py::args
	}
	if (func.has_kwargs) {
	--num_args; // or py::kwargs)
	}
	size_t pos_args = func.nargs_pos;

	if (!func.has_args && n_args_in > pos_args) {
	continue; // Too many positional arguments for this overload
	}

	if (n_args_in < pos_args && func.args.size() < pos_args) {
	continue; // Not enough positional arguments given, and not enough defaults to
	// fill in the blanks
	}

	function_call call(func, parent);

	// Protect std::min with parentheses
	size_t args_to_copy = (std::min)(pos_args, n_args_in);
	size_t args_copied = 0;

	// 0. Inject new-style `self` argument
	if (func.is_new_style_constructor) {
	// The `value` may have been preallocated by an old-style `__init__`
	// if it was a preceding candidate for overload resolution.
	if (self_value_and_holder) {
	self_value_and_holder.type->dealloc(self_value_and_holder);
	}

	call.init_self = PyTuple_GET_ITEM(args_in, 0);
	call.args.emplace_back(reinterpret_cast<PyObject *>(&self_value_and_holder));
	call.args_convert.push_back(false);
	++args_copied;
	}

	// 1. Copy any position arguments given.
	bool bad_arg = false;
	for (; args_copied < args_to_copy; ++args_copied) {
	const argument_record *arg_rec
	= args_copied < func.args.size() ? &func.args[args_copied] : nullptr;
	if (kwargs_in && arg_rec && arg_rec->name
	&& dict_getitemstring(kwargs_in, arg_rec->name)) {
	bad_arg = true;
	break;
	}

	handle arg(PyTuple_GET_ITEM(args_in, args_copied));
	if (arg_rec && !arg_rec->none && arg.is_none()) {
	bad_arg = true;
	break;
	}
	call.args.push_back(arg);
	call.args_convert.push_back(arg_rec ? arg_rec->convert : true);
	}
	if (bad_arg) {
	continue; // Maybe it was meant for another overload (issue #688)
	}

	// Keep track of how many position args we copied out in case we need to come back
	// to copy the rest into a py::args argument.
	size_t positional_args_copied = args_copied;

	// We'll need to copy this if we steal some kwargs for defaults
	dict kwargs = reinterpret_borrow<dict>(kwargs_in);

	// 1.5. Fill in any missing pos_only args from defaults if they exist
	if (args_copied < func.nargs_pos_only) {
	for (; args_copied < func.nargs_pos_only; ++args_copied) {
	const auto &arg_rec = func.args[args_copied];
	handle value;

	if (arg_rec.value) {
	value = arg_rec.value;
	}
	if (value) {
	call.args.push_back(value);
	call.args_convert.push_back(arg_rec.convert);
	} else {
	break;
	}
	}

	if (args_copied < func.nargs_pos_only) {
	continue; // Not enough defaults to fill the positional arguments
	}
	}

	// 2. Check kwargs and, failing that, defaults that may help complete the list
	if (args_copied < num_args) {
	bool copied_kwargs = false;

	for (; args_copied < num_args; ++args_copied) {
	const auto &arg_rec = func.args[args_copied];

	handle value;
	if (kwargs_in && arg_rec.name) {
	value = dict_getitemstring(kwargs.ptr(), arg_rec.name);
	}

	if (value) {
	// Consume a kwargs value
	if (!copied_kwargs) {
	kwargs = reinterpret_steal<dict>(PyDict_Copy(kwargs.ptr()));
	copied_kwargs = true;
	}
	if (PyDict_DelItemString(kwargs.ptr(), arg_rec.name) == -1) {
	throw error_already_set();
	}
	} else if (arg_rec.value) {
	value = arg_rec.value;
	}

	if (!arg_rec.none && value.is_none()) {
	break;
	}

	if (value) {
	// If we're at the py::args index then first insert a stub for it to be
	// replaced later
	if (func.has_args && call.args.size() == func.nargs_pos) {
	call.args.push_back(none());
	}

	call.args.push_back(value);
	call.args_convert.push_back(arg_rec.convert);
	} else {
	break;
	}
	}

	if (args_copied < num_args) {
	continue; // Not enough arguments, defaults, or kwargs to fill the
	// positional arguments
	}
	}

	// 3. Check everything was consumed (unless we have a kwargs arg)
	if (kwargs && !kwargs.empty() && !func.has_kwargs) {
	continue; // Unconsumed kwargs, but no py::kwargs argument to accept them
	}

	// 4a. If we have a py::args argument, create a new tuple with leftovers
	if (func.has_args) {
	tuple extra_args;
	if (args_to_copy == 0) {
	// We didn't copy out any position arguments from the args_in tuple, so we
	// can reuse it directly without copying:
	extra_args = reinterpret_borrow<tuple>(args_in);
	} else if (positional_args_copied >= n_args_in) {
	extra_args = tuple(0);
	} else {
	size_t args_size = n_args_in - positional_args_copied;
	extra_args = tuple(args_size);
	for (size_t i = 0; i < args_size; ++i) {
	extra_args[i] = PyTuple_GET_ITEM(args_in, positional_args_copied + i);
	}
	}
	if (call.args.size() <= func.nargs_pos) {
	call.args.push_back(extra_args);
	} else {
	call.args[func.nargs_pos] = extra_args;
	}
	call.args_convert.push_back(false);
	call.args_ref = std::move(extra_args);
	}

	// 4b. If we have a py::kwargs, pass on any remaining kwargs
	if (func.has_kwargs) {
	if (!kwargs.ptr()) {
	kwargs = dict(); // If we didn't get one, send an empty one
	}
	call.args.push_back(kwargs);
	call.args_convert.push_back(false);
	call.kwargs_ref = std::move(kwargs);
	}

	// 5. Put everything in a vector. Not technically step 5, we've been building it
	// in `call.args` all along.
	#if defined(PYBIND11_DETAILED_ERROR_MESSAGES)
	if (call.args.size() != func.nargs \|\| call.args_convert.size() != func.nargs) {
	pybind11_fail("Internal error: function call dispatcher inserted wrong number "
	"of arguments!");
	}
	#endif

	std::vector<bool> second_pass_convert;
	if (overloaded) {
	// We're in the first no-convert pass, so swap out the conversion flags for a
	// set of all-false flags. If the call fails, we'll swap the flags back in for
	// the conversion-allowed call below.
	second_pass_convert.resize(func.nargs, false);
	call.args_convert.swap(second_pass_convert);
	}

	// 6. Call the function.
	try {
	loader_life_support guard{};
	result = func.impl(call);
	} catch (reference_cast_error &) {
	result = PYBIND11_TRY_NEXT_OVERLOAD;
	}

	if (result.ptr() != PYBIND11_TRY_NEXT_OVERLOAD) {
	break;
	}

	if (overloaded) {
	// The (overloaded) call failed; if the call has at least one argument that
	// permits conversion (i.e. it hasn't been explicitly specified `.noconvert()`)
	// then add this call to the list of second pass overloads to try.
	for (size_t i = func.is_method ? 1 : 0; i < pos_args; i++) {
	if (second_pass_convert[i]) {
	// Found one: swap the converting flags back in and store the call for
	// the second pass.
	call.args_convert.swap(second_pass_convert);
	second_pass.push_back(std::move(call));
	break;
	}
	}
	}
	}

	if (overloaded && !second_pass.empty() && result.ptr() == PYBIND11_TRY_NEXT_OVERLOAD) {
	// The no-conversion pass finished without success, try again with conversion
	// allowed
	for (auto &call : second_pass) {
	try {
	loader_life_support guard{};
	result = call.func.impl(call);
	} catch (reference_cast_error &) {
	result = PYBIND11_TRY_NEXT_OVERLOAD;
	}

	if (result.ptr() != PYBIND11_TRY_NEXT_OVERLOAD) {
	// The error reporting logic below expects 'it' to be valid, as it would be
	// if we'd encountered this failure in the first-pass loop.
	if (!result) {
	it = &call.func;
	}
	break;
	}
	}
	}
	} catch (error_already_set &e) {
	e.restore();
	return nullptr;
	#ifdef __GLIBCXX__
	} catch (abi::__forced_unwind &) {
	throw;
	#endif
	} catch (...) {
	/* When an exception is caught, give each registered exception
	translator a chance to translate it to a Python exception. First
	all module-local translators will be tried in reverse order of
	registration. If none of the module-locale translators handle
	the exception (or there are no module-locale translators) then
	the global translators will be tried, also in reverse order of
	registration.

	A translator may choose to do one of the following:

	- catch the exception and call PyErr_SetString or PyErr_SetObject
	to set a standard (or custom) Python exception, or
	- do nothing and let the exception fall through to the next translator, or
	- delegate translation to the next translator by throwing a new type of exception.
	*/

	auto &local_exception_translators
	= get_local_internals().registered_exception_translators;
	if (detail::apply_exception_translators(local_exception_translators)) {
	return nullptr;
	}
	auto &exception_translators = get_internals().registered_exception_translators;
	if (detail::apply_exception_translators(exception_translators)) {
	return nullptr;
	}

	PyErr_SetString(PyExc_SystemError,
	"Exception escaped from default exception translator!");
	return nullptr;
	}

	auto append_note_if_missing_header_is_suspected = [](std::string &msg) {
	if (msg.find("std::") != std::string::npos) {
	msg += "\n\n"
	"Did you forget to `#include <pybind11/stl.h>`? Or <pybind11/complex.h>,\n"
	"<pybind11/functional.h>, <pybind11/chrono.h>, etc. Some automatic\n"
	"conversions are optional and require extra headers to be included\n"
	"when compiling your pybind11 module.";
	}
	};

	if (result.ptr() == PYBIND11_TRY_NEXT_OVERLOAD) {
	if (overloads->is_operator) {
	return handle(Py_NotImplemented).inc_ref().ptr();
	}

	std::string msg = std::string(overloads->name) + "(): incompatible "
	+ std::string(overloads->is_constructor ? "constructor" : "function")
	+ " arguments. The following argument types are supported:\n";

	int ctr = 0;
	for (const function_record *it2 = overloads; it2 != nullptr; it2 = it2->next) {
	msg += " " + std::to_string(++ctr) + ". ";

	bool wrote_sig = false;
	if (overloads->is_constructor) {
	// For a constructor, rewrite `(self: Object, arg0, ...) -> NoneType` as
	// `Object(arg0, ...)`
	std::string sig = it2->signature;
	size_t start = sig.find('(') + 7; // skip "(self: "
	if (start < sig.size()) {
	// End at the , for the next argument
	size_t end = sig.find(", "), next = end + 2;
	size_t ret = sig.rfind(" -> ");
	// Or the ), if there is no comma:
	if (end >= sig.size()) {
	next = end = sig.find(')');
	}
	if (start < end && next < sig.size()) {
	msg.append(sig, start, end - start);
	msg += '(';
	msg.append(sig, next, ret - next);
	wrote_sig = true;
	}
	}
	}
	if (!wrote_sig) {
	msg += it2->signature;
	}

	msg += '\n';
	}
	msg += "\nInvoked with: ";
	auto args_ = reinterpret_borrow<tuple>(args_in);
	bool some_args = false;
	for (size_t ti = overloads->is_constructor ? 1 : 0; ti < args_.size(); ++ti) {
	if (!some_args) {
	some_args = true;
	} else {
	msg += ", ";
	}
	try {
	msg += pybind11::repr(args_[ti]);
	} catch (const error_already_set &) {
	msg += "<repr raised Error>";
	}
	}
	if (kwargs_in) {
	auto kwargs = reinterpret_borrow<dict>(kwargs_in);
	if (!kwargs.empty()) {
	if (some_args) {
	msg += "; ";
	}
	msg += "kwargs: ";
	bool first = true;
	for (auto kwarg : kwargs) {
	if (first) {
	first = false;
	} else {
	msg += ", ";
	}
	msg += pybind11::str("{}=").format(kwarg.first);
	try {
	msg += pybind11::repr(kwarg.second);
	} catch (const error_already_set &) {
	msg += "<repr raised Error>";
	}
	}
	}
	}

	append_note_if_missing_header_is_suspected(msg);
	// Attach additional error info to the exception if supported
	if (PyErr_Occurred()) {
	// #HelpAppreciated: unit test coverage for this branch.
	raise_from(PyExc_TypeError, msg.c_str());
	return nullptr;
	}
	PyErr_SetString(PyExc_TypeError, msg.c_str());
	return nullptr;
	}
	if (!result) {
	std::string msg = "Unable to convert function return value to a "
	"Python type! The signature was\n\t";
	msg += it->signature;
	append_note_if_missing_header_is_suspected(msg);
	// Attach additional error info to the exception if supported
	if (PyErr_Occurred()) {
	raise_from(PyExc_TypeError, msg.c_str());
	return nullptr;
	}
	PyErr_SetString(PyExc_TypeError, msg.c_str());
	return nullptr;
	}
	if (overloads->is_constructor && !self_value_and_holder.holder_constructed()) {
	auto pi = reinterpret_cast<instance >(parent.ptr());
	self_value_and_holder.type->init_instance(pi, nullptr);
	}
	return result.ptr();
	}
	};

	/// Wrapper for Python extension modules
	class module_ : public object {
	public:
	PYBIND11_OBJECT_DEFAULT(module_, object, PyModule_Check)

	/// Create a new top-level Python module with the given name and docstring
	PYBIND11_DEPRECATED("Use PYBIND11_MODULE or module_::create_extension_module instead")
	explicit module_(const char name, const char doc = nullptr) {
	*this = create_extension_module(name, doc, new PyModuleDef());
	}

	/** \rst
	Create Python binding for a new function within the module scope. ``Func``
	can be a plain C++ function, a function pointer, or a lambda function. For
	details on the ``Extra&& ... extra`` argument, see section :ref:`extras`.
	\endrst */
	template <typename Func, typename... Extra>
	module_ &def(const char *name_, Func &&f, const Extra &...extra) {
	cpp_function func(std::forward<Func>(f),
	name(name_),
	scope(*this),
	sibling(getattr(*this, name_, none())),
	extra...);
	// NB: allow overwriting here because cpp_function sets up a chain with the intention of
	// overwriting (and has already checked internally that it isn't overwriting
	// non-functions).
	add_object(name_, func, true /* overwrite */);
	return *this;
	}

	/** \rst
	Create and return a new Python submodule with the given name and docstring.
	This also works recursively, i.e.

	.. code-block:: cpp

	py::module_ m("example", "pybind11 example plugin");
	py::module_ m2 = m.def_submodule("sub", "A submodule of 'example'");
	py::module_ m3 = m2.def_submodule("subsub", "A submodule of 'example.sub'");
	\endrst */
	module_ def_submodule(const char name, const char doc = nullptr) {
	const char *this_name = PyModule_GetName(m_ptr);
	if (this_name == nullptr) {
	throw error_already_set();
	}
	std::string full_name = std::string(this_name) + '.' + name;
	handle submodule = PyImport_AddModule(full_name.c_str());
	if (!submodule) {
	throw error_already_set();
	}
	auto result = reinterpret_borrow<module_>(submodule);
	if (doc && options::show_user_defined_docstrings()) {
	result.attr("__doc__") = pybind11::str(doc);
	}
	attr(name) = result;
	return result;
	}

	/// Import and return a module or throws `error_already_set`.
	static module_ import(const char *name) {
	PyObject *obj = PyImport_ImportModule(name);
	if (!obj) {
	throw error_already_set();
	}
	return reinterpret_steal<module_>(obj);
	}

	/// Reload the module or throws `error_already_set`.
	void reload() {
	PyObject *obj = PyImport_ReloadModule(ptr());
	if (!obj) {
	throw error_already_set();
	}
	*this = reinterpret_steal<module_>(obj);
	}

	/** \rst
	Adds an object to the module using the given name. Throws if an object with the given name
	already exists.

	``overwrite`` should almost always be false: attempting to overwrite objects that pybind11
	has established will, in most cases, break things.
	\endrst */
	PYBIND11_NOINLINE void add_object(const char *name, handle obj, bool overwrite = false) {
	if (!overwrite && hasattr(*this, name)) {
	pybind11_fail(
	"Error during initialization: multiple incompatible definitions with name \""
	+ std::string(name) + "\"");
	}

	PyModule_AddObject(ptr(), name, obj.inc_ref().ptr() /* steals a reference */);
	}

	using module_def = PyModuleDef; // TODO: Can this be removed (it was needed only for Python 2)?

	/** \rst
	Create a new top-level module that can be used as the main module of a C extension.

	``def`` should point to a statically allocated module_def.
	\endrst */
	static module_ create_extension_module(const char name, const char doc, module_def *def) {
	// module_def is PyModuleDef
	// Placement new (not an allocation).
	def = new (def)
	PyModuleDef{/* m_base */ PyModuleDef_HEAD_INIT,
	/* m_name */ name,
	/* m_doc */ options::show_user_defined_docstrings() ? doc : nullptr,
	/* m_size */ -1,
	/* m_methods */ nullptr,
	/* m_slots */ nullptr,
	/* m_traverse */ nullptr,
	/* m_clear */ nullptr,
	/* m_free */ nullptr};
	auto *m = PyModule_Create(def);
	if (m == nullptr) {
	if (PyErr_Occurred()) {
	throw error_already_set();
	}
	pybind11_fail("Internal error in module_::create_extension_module()");
	}
	// TODO: Should be reinterpret_steal for Python 3, but Python also steals it again when
	// returned from PyInit_...
	// For Python 2, reinterpret_borrow was correct.
	return reinterpret_borrow<module_>(m);
	}
	};

	// When inside a namespace (or anywhere as long as it's not the first item on a line),
	// C++20 allows "module" to be used. This is provided for backward compatibility, and for
	// simplicity, if someone wants to use py::module for example, that is perfectly safe.
	using module = module_;

	/// \ingroup python_builtins
	/// Return a dictionary representing the global variables in the current execution frame,
	/// or ``__main__.__dict__`` if there is no frame (usually when the interpreter is embedded).
	inline dict globals() {
	PyObject *p = PyEval_GetGlobals();
	return reinterpret_borrow<dict>(p ? p : module_::import("__main__").attr("__dict__").ptr());
	}

	template <typename... Args, typename = detail::enable_if_t<args_are_all_keyword_or_ds<Args...>()>>
	PYBIND11_DEPRECATED("make_simple_namespace should be replaced with "
	"py::module_::import(\"types\").attr(\"SimpleNamespace\") ")
	object make_simple_namespace(Args &&...args_) {
	return module_::import("types").attr("SimpleNamespace")(std::forward<Args>(args_)...);
	}

	PYBIND11_NAMESPACE_BEGIN(detail)
	/// Generic support for creating new Python heap types
	class generic_type : public object {
	public:
	PYBIND11_OBJECT_DEFAULT(generic_type, object, PyType_Check)
	protected:
	void initialize(const type_record &rec) {
	if (rec.scope && hasattr(rec.scope, "__dict__")
	&& rec.scope.attr("__dict__").contains(rec.name)) {
	pybind11_fail("generic_type: cannot initialize type \"" + std::string(rec.name)
	+ "\": an object with that name is already defined");
	}

	if ((rec.module_local ? get_local_type_info(rec.type) : get_global_type_info(rec.type))
	!= nullptr) {
	pybind11_fail("generic_type: type \"" + std::string(rec.name)
	+ "\" is already registered!");
	}

	m_ptr = make_new_python_type(rec);

	/* Register supplemental type information in C++ dict */
	auto *tinfo = new detail::type_info();
	tinfo->type = (PyTypeObject *) m_ptr;
	tinfo->cpptype = rec.type;
	tinfo->type_size = rec.type_size;
	tinfo->type_align = rec.type_align;
	tinfo->operator_new = rec.operator_new;
	tinfo->holder_size_in_ptrs = size_in_ptrs(rec.holder_size);
	tinfo->init_instance = rec.init_instance;
	tinfo->dealloc = rec.dealloc;
	tinfo->simple_type = true;
	tinfo->simple_ancestors = true;
	tinfo->default_holder = rec.default_holder;
	tinfo->module_local = rec.module_local;

	auto &internals = get_internals();
	auto tindex = std::type_index(*rec.type);
	tinfo->direct_conversions = &internals.direct_conversions[tindex];
	if (rec.module_local) {
	get_local_internals().registered_types_cpp[tindex] = tinfo;
	} else {
	internals.registered_types_cpp[tindex] = tinfo;
	}
	internals.registered_types_py[(PyTypeObject *) m_ptr] = {tinfo};

	if (rec.bases.size() > 1 \|\| rec.multiple_inheritance) {
	mark_parents_nonsimple(tinfo->type);
	tinfo->simple_ancestors = false;
	} else if (rec.bases.size() == 1) {
	auto parent_tinfo = get_type_info((PyTypeObject ) rec.bases[0].ptr());
	assert(parent_tinfo != nullptr);
	bool parent_simple_ancestors = parent_tinfo->simple_ancestors;
	tinfo->simple_ancestors = parent_simple_ancestors;
	// The parent can no longer be a simple type if it has MI and has a child
	parent_tinfo->simple_type = parent_tinfo->simple_type && parent_simple_ancestors;
	}

	if (rec.module_local) {
	// Stash the local typeinfo and loader so that external modules can access it.
	tinfo->module_local_load = &type_caster_generic::local_load;
	setattr(m_ptr, PYBIND11_MODULE_LOCAL_ID, capsule(tinfo));
	}
	}

	/// Helper function which tags all parents of a type using mult. inheritance
	void mark_parents_nonsimple(PyTypeObject *value) {
	auto t = reinterpret_borrow<tuple>(value->tp_bases);
	for (handle h : t) {
	auto tinfo2 = get_type_info((PyTypeObject ) h.ptr());
	if (tinfo2) {
	tinfo2->simple_type = false;
	}
	mark_parents_nonsimple((PyTypeObject *) h.ptr());
	}
	}

	void install_buffer_funcs(buffer_info (get_buffer)(PyObject , void ),
	void *get_buffer_data) {
	auto type = (PyHeapTypeObject ) m_ptr;
	auto *tinfo = detail::get_type_info(&type->ht_type);

	if (!type->ht_type.tp_as_buffer) {
	pybind11_fail("To be able to register buffer protocol support for the type '"
	+ get_fully_qualified_tp_name(tinfo->type)
	+ "' the associated class<>(..) invocation must "
	"include the pybind11::buffer_protocol() annotation!");
	}

	tinfo->get_buffer = get_buffer;
	tinfo->get_buffer_data = get_buffer_data;
	}

	// rec_func must be set for either fget or fset.
	void def_property_static_impl(const char *name,
	handle fget,
	handle fset,
	detail::function_record *rec_func) {
	const auto is_static = (rec_func != nullptr) && !(rec_func->is_method && rec_func->scope);
	const auto has_doc = (rec_func != nullptr) && (rec_func->doc != nullptr)
	&& pybind11::options::show_user_defined_docstrings();
	auto property = handle(
	(PyObject *) (is_static ? get_internals().static_property_type : &PyProperty_Type));
	attr(name) = property(fget.ptr() ? fget : none(),
	fset.ptr() ? fset : none(),
	/deleter/ none(),
	pybind11::str(has_doc ? rec_func->doc : ""));
	}
	};

	/// Set the pointer to operator new if it exists. The cast is needed because it can be overloaded.
	template <typename T,
	typename = void_t<decltype(static_cast<void () (size_t)>(T::operator new))>>
	void set_operator_new(type_record *r) {
	r->operator_new = &T::operator new;
	}

	template <typename>
	void set_operator_new(...) {}

	template <typename T, typename SFINAE = void>
	struct has_operator_delete : std::false_type {};
	template <typename T>
	struct has_operator_delete<T, void_t<decltype(static_cast<void ()(void )>(T::operator delete))>>
	: std::true_type {};
	template <typename T, typename SFINAE = void>
	struct has_operator_delete_size : std::false_type {};
	template <typename T>
	struct has_operator_delete_size<
	T,
	void_t<decltype(static_cast<void ()(void , size_t)>(T::operator delete))>> : std::true_type {
	};
	/// Call class-specific delete if it exists or global otherwise. Can also be an overload set.
	template <typename T, enable_if_t<has_operator_delete<T>::value, int> = 0>
	void call_operator_delete(T *p, size_t, size_t) {
	T::operator delete(p);
	}
	template <
	typename T,
	enable_if_t<!has_operator_delete<T>::value && has_operator_delete_size<T>::value, int> = 0>
	void call_operator_delete(T *p, size_t s, size_t) {
	T::operator delete(p, s);
	}

	inline void call_operator_delete(void *p, size_t s, size_t a) {
	(void) s;
	(void) a;
	#if defined(__cpp_aligned_new) && (!defined(_MSC_VER) \|\| _MSC_VER >= 1912)
	if (a > __STDCPP_DEFAULT_NEW_ALIGNMENT__) {
	# ifdef __cpp_sized_deallocation
	::operator delete(p, s, std::align_val_t(a));
	# else
	::operator delete(p, std::align_val_t(a));
	# endif
	return;
	}
	#endif
	#ifdef __cpp_sized_deallocation
	::operator delete(p, s);
	#else
	::operator delete(p);
	#endif
	}

	inline void add_class_method(object &cls, const char *name_, const cpp_function &cf) {
	cls.attr(cf.name()) = cf;
	if (std::strcmp(name_, "__eq__") == 0 && !cls.attr("__dict__").contains("__hash__")) {
	cls.attr("__hash__") = none();
	}
	}

	PYBIND11_NAMESPACE_END(detail)

	/// Given a pointer to a member function, cast it to its `Derived` version.
	/// Forward everything else unchanged.
	template <typename /Derived/, typename F>
	auto method_adaptor(F &&f) -> decltype(std::forward<F>(f)) {
	return std::forward<F>(f);
	}

	template <typename Derived, typename Return, typename Class, typename... Args>
	auto method_adaptor(Return (Class::pmf)(Args...)) -> Return (Derived::)(Args...) {
	static_assert(
	detail::is_accessible_base_of<Class, Derived>::value,
	"Cannot bind an inaccessible base class method; use a lambda definition instead");
	return pmf;
	}

	template <typename Derived, typename Return, typename Class, typename... Args>
	auto method_adaptor(Return (Class::pmf)(Args...) const) -> Return (Derived::)(Args...) const {
	static_assert(
	detail::is_accessible_base_of<Class, Derived>::value,
	"Cannot bind an inaccessible base class method; use a lambda definition instead");
	return pmf;
	}

	template <typename type_, typename... options>
	class class_ : public detail::generic_type {
	template <typename T>
	using is_holder = detail::is_holder_type<type_, T>;
	template <typename T>
	using is_subtype = detail::is_strict_base_of<type_, T>;
	template <typename T>
	using is_base = detail::is_strict_base_of<T, type_>;
	// struct instead of using here to help MSVC:
	template <typename T>
	struct is_valid_class_option : detail::any_of<is_holder<T>, is_subtype<T>, is_base<T>> {};

	public:
	using type = type_;
	using type_alias = detail::exactly_one_t<is_subtype, void, options...>;
	constexpr static bool has_alias = !std::is_void<type_alias>::value;
	using holder_type = detail::exactly_one_t<is_holder, std::unique_ptr<type>, options...>;

	static_assert(detail::all_of<is_valid_class_option<options>...>::value,
	"Unknown/invalid class_ template parameters provided");

	static_assert(!has_alias \|\| std::is_polymorphic<type>::value,
	"Cannot use an alias class with a non-polymorphic type");

	PYBIND11_OBJECT(class_, generic_type, PyType_Check)

	template <typename... Extra>
	class_(handle scope, const char *name, const Extra &...extra) {
	using namespace detail;

	// MI can only be specified via class_ template options, not constructor parameters
	static_assert(
	none_of<is_pyobject<Extra>...>::value \|\| // no base class arguments, or:
	(constexpr_sum(is_pyobject<Extra>::value...) == 1 && // Exactly one base
	constexpr_sum(is_base<options>::value...) == 0 && // no template option bases
	// no multiple_inheritance attr
	none_of<std::is_same<multiple_inheritance, Extra>...>::value),
	"Error: multiple inheritance bases must be specified via class_ template options");

	type_record record;
	record.scope = scope;
	record.name = name;
	record.type = &typeid(type);
	record.type_size = sizeof(conditional_t<has_alias, type_alias, type>);
	record.type_align = alignof(conditional_t<has_alias, type_alias, type> &);
	record.holder_size = sizeof(holder_type);
	record.init_instance = init_instance;
	record.dealloc = dealloc;
	record.default_holder = detail::is_instantiation<std::unique_ptr, holder_type>::value;

	set_operator_new<type>(&record);

	/* Register base classes specified via template arguments to class_, if any */
	PYBIND11_EXPAND_SIDE_EFFECTS(add_base<options>(record));

	/* Process optional arguments, if any */
	process_attributes<Extra...>::init(extra..., &record);

	generic_type::initialize(record);

	if (has_alias) {
	auto &instances = record.module_local ? get_local_internals().registered_types_cpp
	: get_internals().registered_types_cpp;
	instances[std::type_index(typeid(type_alias))]
	= instances[std::type_index(typeid(type))];
	}
	}

	template <typename Base, detail::enable_if_t<is_base<Base>::value, int> = 0>
	static void add_base(detail::type_record &rec) {
	rec.add_base(typeid(Base), [](void src) -> void {
	return static_cast<Base >(reinterpret_cast<type >(src));
	});
	}

	template <typename Base, detail::enable_if_t<!is_base<Base>::value, int> = 0>
	static void add_base(detail::type_record &) {}

	template <typename Func, typename... Extra>
	class_ &def(const char *name_, Func &&f, const Extra &...extra) {
	cpp_function cf(method_adaptor<type>(std::forward<Func>(f)),
	name(name_),
	is_method(*this),
	sibling(getattr(*this, name_, none())),
	extra...);
	add_class_method(*this, name_, cf);
	return *this;
	}

	template <typename Func, typename... Extra>
	class_ &def_static(const char *name_, Func &&f, const Extra &...extra) {
	static_assert(!std::is_member_function_pointer<Func>::value,
	"def_static(...) called with a non-static member function pointer");
	cpp_function cf(std::forward<Func>(f),
	name(name_),
	scope(*this),
	sibling(getattr(*this, name_, none())),
	extra...);
	auto cf_name = cf.name();
	attr(std::move(cf_name)) = staticmethod(std::move(cf));
	return *this;
	}

	template <detail::op_id id, detail::op_type ot, typename L, typename R, typename... Extra>
	class_ &def(const detail::op_<id, ot, L, R> &op, const Extra &...extra) {
	op.execute(*this, extra...);
	return *this;
	}

	template <detail::op_id id, detail::op_type ot, typename L, typename R, typename... Extra>
	class_ &def_cast(const detail::op_<id, ot, L, R> &op, const Extra &...extra) {
	op.execute_cast(*this, extra...);
	return *this;
	}

	template <typename... Args, typename... Extra>
	class_ &def(const detail::initimpl::constructor<Args...> &init, const Extra &...extra) {
	PYBIND11_WORKAROUND_INCORRECT_MSVC_C4100(init);
	init.execute(*this, extra...);
	return *this;
	}

	template <typename... Args, typename... Extra>
	class_ &def(const detail::initimpl::alias_constructor<Args...> &init, const Extra &...extra) {
	PYBIND11_WORKAROUND_INCORRECT_MSVC_C4100(init);
	init.execute(*this, extra...);
	return *this;
	}

	template <typename... Args, typename... Extra>
	class_ &def(detail::initimpl::factory<Args...> &&init, const Extra &...extra) {
	std::move(init).execute(*this, extra...);
	return *this;
	}

	template <typename... Args, typename... Extra>
	class_ &def(detail::initimpl::pickle_factory<Args...> &&pf, const Extra &...extra) {
	std::move(pf).execute(*this, extra...);
	return *this;
	}

	template <typename Func>
	class_ &def_buffer(Func &&func) {
	struct capture {
	Func func;
	};
	auto *ptr = new capture{std::forward<Func>(func)};
	install_buffer_funcs(
	[](PyObject obj, void ptr) -> buffer_info * {
	detail::make_caster<type> caster;
	if (!caster.load(obj, false)) {
	return nullptr;
	}
	return new buffer_info(((capture *) ptr)->func(std::move(caster)));
	},
	ptr);
	weakref(m_ptr, cpp_function([ptr](handle wr) {
	delete ptr;
	wr.dec_ref();
	}))
	.release();
	return *this;
	}

	template <typename Return, typename Class, typename... Args>
	class_ &def_buffer(Return (Class::*func)(Args...)) {
	return def_buffer([func](type &obj) { return (obj.*func)(); });
	}

	template <typename Return, typename Class, typename... Args>
	class_ &def_buffer(Return (Class::*func)(Args...) const) {
	return def_buffer([func](const type &obj) { return (obj.*func)(); });
	}

	template <typename C, typename D, typename... Extra>
	class_ &def_readwrite(const char name, D C::pm, const Extra &...extra) {
	static_assert(std::is_same<C, type>::value \|\| std::is_base_of<C, type>::value,
	"def_readwrite() requires a class member (or base class member)");
	cpp_function fget([pm](const type &c) -> const D & { return c.pm; }, is_method(this)),
	fset([pm](type &c, const D &value) { c.pm = value; }, is_method(this));
	def_property(name, fget, fset, return_value_policy::reference_internal, extra...);
	return *this;
	}

	template <typename C, typename D, typename... Extra>
	class_ &def_readonly(const char name, const D C::pm, const Extra &...extra) {
	static_assert(std::is_same<C, type>::value \|\| std::is_base_of<C, type>::value,
	"def_readonly() requires a class member (or base class member)");
	cpp_function fget([pm](const type &c) -> const D & { return c.pm; }, is_method(this));
	def_property_readonly(name, fget, return_value_policy::reference_internal, extra...);
	return *this;
	}

	template <typename D, typename... Extra>
	class_ &def_readwrite_static(const char name, D pm, const Extra &...extra) {
	cpp_function fget([pm](const object &) -> const D & { return pm; }, scope(this)),
	fset([pm](const object &, const D &value) { pm = value; }, scope(this));
	def_property_static(name, fget, fset, return_value_policy::reference, extra...);
	return *this;
	}

	template <typename D, typename... Extra>
	class_ &def_readonly_static(const char name, const D pm, const Extra &...extra) {
	cpp_function fget([pm](const object &) -> const D & { return pm; }, scope(this));
	def_property_readonly_static(name, fget, return_value_policy::reference, extra...);
	return *this;
	}

	/// Uses return_value_policy::reference_internal by default
	template <typename Getter, typename... Extra>
	class_ &def_property_readonly(const char *name, const Getter &fget, const Extra &...extra) {
	return def_property_readonly(name,
	cpp_function(method_adaptor<type>(fget)),
	return_value_policy::reference_internal,
	extra...);
	}

	/// Uses cpp_function's return_value_policy by default
	template <typename... Extra>
	class_ &
	def_property_readonly(const char *name, const cpp_function &fget, const Extra &...extra) {
	return def_property(name, fget, nullptr, extra...);
	}

	/// Uses return_value_policy::reference by default
	template <typename Getter, typename... Extra>
	class_ &
	def_property_readonly_static(const char *name, const Getter &fget, const Extra &...extra) {
	return def_property_readonly_static(
	name, cpp_function(fget), return_value_policy::reference, extra...);
	}

	/// Uses cpp_function's return_value_policy by default
	template <typename... Extra>
	class_ &def_property_readonly_static(const char *name,
	const cpp_function &fget,
	const Extra &...extra) {
	return def_property_static(name, fget, nullptr, extra...);
	}

	/// Uses return_value_policy::reference_internal by default
	template <typename Getter, typename Setter, typename... Extra>
	class_ &
	def_property(const char *name, const Getter &fget, const Setter &fset, const Extra &...extra) {
	return def_property(name, fget, cpp_function(method_adaptor<type>(fset)), extra...);
	}
	template <typename Getter, typename... Extra>
	class_ &def_property(const char *name,
	const Getter &fget,
	const cpp_function &fset,
	const Extra &...extra) {
	return def_property(name,
	cpp_function(method_adaptor<type>(fget)),
	fset,
	return_value_policy::reference_internal,
	extra...);
	}

	/// Uses cpp_function's return_value_policy by default
	template <typename... Extra>
	class_ &def_property(const char *name,
	const cpp_function &fget,
	const cpp_function &fset,
	const Extra &...extra) {
	return def_property_static(name, fget, fset, is_method(*this), extra...);
	}

	/// Uses return_value_policy::reference by default
	template <typename Getter, typename... Extra>
	class_ &def_property_static(const char *name,
	const Getter &fget,
	const cpp_function &fset,
	const Extra &...extra) {
	return def_property_static(
	name, cpp_function(fget), fset, return_value_policy::reference, extra...);
	}

	/// Uses cpp_function's return_value_policy by default
	template <typename... Extra>
	class_ &def_property_static(const char *name,
	const cpp_function &fget,
	const cpp_function &fset,
	const Extra &...extra) {
	static_assert(0 == detail::constexpr_sum(std::is_base_of<arg, Extra>::value...),
	"Argument annotations are not allowed for properties");
	auto rec_fget = get_function_record(fget), rec_fset = get_function_record(fset);
	auto *rec_active = rec_fget;
	if (rec_fget) {
	char doc_prev = rec_fget->doc; / 'extra' field may include a property-specific
	documentation string */
	detail::process_attributes<Extra...>::init(extra..., rec_fget);
	if (rec_fget->doc && rec_fget->doc != doc_prev) {
	std::free(doc_prev);
	rec_fget->doc = PYBIND11_COMPAT_STRDUP(rec_fget->doc);
	}
	}
	if (rec_fset) {
	char *doc_prev = rec_fset->doc;
	detail::process_attributes<Extra...>::init(extra..., rec_fset);
	if (rec_fset->doc && rec_fset->doc != doc_prev) {
	std::free(doc_prev);
	rec_fset->doc = PYBIND11_COMPAT_STRDUP(rec_fset->doc);
	}
	if (!rec_active) {
	rec_active = rec_fset;
	}
	}
	def_property_static_impl(name, fget, fset, rec_active);
	return *this;
	}

	private:
	/// Initialize holder object, variant 1: object derives from enable_shared_from_this
	template <typename T>
	static void init_holder(detail::instance *inst,
	detail::value_and_holder &v_h,
	const holder_type * /* unused */,
	const std::enable_shared_from_this<T> * /* dummy */) {

	auto sh = std::dynamic_pointer_cast<typename holder_type::element_type>(
	detail::try_get_shared_from_this(v_h.value_ptr<type>()));
	if (sh) {
	new (std::addressof(v_h.holder<holder_type>())) holder_type(std::move(sh));
	v_h.set_holder_constructed();
	}

	if (!v_h.holder_constructed() && inst->owned) {
	new (std::addressof(v_h.holder<holder_type>())) holder_type(v_h.value_ptr<type>());
	v_h.set_holder_constructed();
	}
	}

	static void init_holder_from_existing(const detail::value_and_holder &v_h,
	const holder_type *holder_ptr,
	std::true_type /is_copy_constructible/) {
	new (std::addressof(v_h.holder<holder_type>()))
	holder_type(reinterpret_cast<const holder_type >(holder_ptr));
	}

	static void init_holder_from_existing(const detail::value_and_holder &v_h,
	const holder_type *holder_ptr,
	std::false_type /is_copy_constructible/) {
	new (std::addressof(v_h.holder<holder_type>()))
	holder_type(std::move(const_cast<holder_type >(holder_ptr)));
	}

	/// Initialize holder object, variant 2: try to construct from existing holder object, if
	/// possible
	static void init_holder(detail::instance *inst,
	detail::value_and_holder &v_h,
	const holder_type *holder_ptr,
	const void * /* dummy -- not enable_shared_from_this<T>) */) {
	if (holder_ptr) {
	init_holder_from_existing(v_h, holder_ptr, std::is_copy_constructible<holder_type>());
	v_h.set_holder_constructed();
	} else if (PYBIND11_SILENCE_MSVC_C4127(detail::always_construct_holder<holder_type>::value)
	\|\| inst->owned) {
	new (std::addressof(v_h.holder<holder_type>())) holder_type(v_h.value_ptr<type>());
	v_h.set_holder_constructed();
	}
	}

	/// Performs instance initialization including constructing a holder and registering the known
	/// instance. Should be called as soon as the `type` value_ptr is set for an instance. Takes
	/// an optional pointer to an existing holder to use; if not specified and the instance is
	/// `.owned`, a new holder will be constructed to manage the value pointer.
	static void init_instance(detail::instance inst, const void holder_ptr) {
	auto v_h = inst->get_value_and_holder(detail::get_type_info(typeid(type)));
	if (!v_h.instance_registered()) {
	register_instance(inst, v_h.value_ptr(), v_h.type);
	v_h.set_instance_registered();
	}
	init_holder(inst, v_h, (const holder_type *) holder_ptr, v_h.value_ptr<type>());
	}

	/// Deallocates an instance; via holder, if constructed; otherwise via operator delete.
	static void dealloc(detail::value_and_holder &v_h) {
	// We could be deallocating because we are cleaning up after a Python exception.
	// If so, the Python error indicator will be set. We need to clear that before
	// running the destructor, in case the destructor code calls more Python.
	// If we don't, the Python API will exit with an exception, and pybind11 will
	// throw error_already_set from the C++ destructor which is forbidden and triggers
	// std::terminate().
	error_scope scope;
	if (v_h.holder_constructed()) {
	v_h.holder<holder_type>().~holder_type();
	v_h.set_holder_constructed(false);
	} else {
	detail::call_operator_delete(
	v_h.value_ptr<type>(), v_h.type->type_size, v_h.type->type_align);
	}
	v_h.value_ptr() = nullptr;
	}

	static detail::function_record *get_function_record(handle h) {
	h = detail::get_function(h);
	return h ? (detail::function_record *) reinterpret_borrow<capsule>(
	PyCFunction_GET_SELF(h.ptr()))
	: nullptr;
	}
	};

	/// Binds an existing constructor taking arguments Args...
	template <typename... Args>
	detail::initimpl::constructor<Args...> init() {
	return {};
	}
	/// Like `init<Args...>()`, but the instance is always constructed through the alias class (even
	/// when not inheriting on the Python side).
	template <typename... Args>
	detail::initimpl::alias_constructor<Args...> init_alias() {
	return {};
	}

	/// Binds a factory function as a constructor
	template <typename Func, typename Ret = detail::initimpl::factory<Func>>
	Ret init(Func &&f) {
	return {std::forward<Func>(f)};
	}

	/// Dual-argument factory function: the first function is called when no alias is needed, the
	/// second when an alias is needed (i.e. due to python-side inheritance). Arguments must be
	/// identical.
	template <typename CFunc, typename AFunc, typename Ret = detail::initimpl::factory<CFunc, AFunc>>
	Ret init(CFunc &&c, AFunc &&a) {
	return {std::forward<CFunc>(c), std::forward<AFunc>(a)};
	}

	/// Binds pickling functions `__getstate__` and `__setstate__` and ensures that the type
	/// returned by `__getstate__` is the same as the argument accepted by `__setstate__`.
	template <typename GetState, typename SetState>
	detail::initimpl::pickle_factory<GetState, SetState> pickle(GetState &&g, SetState &&s) {
	return {std::forward<GetState>(g), std::forward<SetState>(s)};
	}

	PYBIND11_NAMESPACE_BEGIN(detail)

	inline str enum_name(handle arg) {
	dict entries = arg.get_type().attr("__entries");
	for (auto kv : entries) {
	if (handle(kv.second[int_(0)]).equal(arg)) {
	return pybind11::str(kv.first);
	}
	}
	return "???";
	}

	struct enum_base {
	enum_base(const handle &base, const handle &parent) : m_base(base), m_parent(parent) {}

	PYBIND11_NOINLINE void init(bool is_arithmetic, bool is_convertible) {
	m_base.attr("__entries") = dict();
	auto property = handle((PyObject *) &PyProperty_Type);
	auto static_property = handle((PyObject *) get_internals().static_property_type);

	m_base.attr("__repr__") = cpp_function(
	[](const object &arg) -> str {
	handle type = type::handle_of(arg);
	object type_name = type.attr("__name__");
	return pybind11::str("<{}.{}: {}>")
	.format(std::move(type_name), enum_name(arg), int_(arg));
	},
	name("__repr__"),
	is_method(m_base));

	m_base.attr("name") = property(cpp_function(&enum_name, name("name"), is_method(m_base)));

	m_base.attr("__str__") = cpp_function(
	[](handle arg) -> str {
	object type_name = type::handle_of(arg).attr("__name__");
	return pybind11::str("{}.{}").format(std::move(type_name), enum_name(arg));
	},
	name("name"),
	is_method(m_base));

	m_base.attr("__doc__") = static_property(
	cpp_function(
	[](handle arg) -> std::string {
	std::string docstring;
	dict entries = arg.attr("__entries");
	if (((PyTypeObject *) arg.ptr())->tp_doc) {
	docstring += std::string(((PyTypeObject *) arg.ptr())->tp_doc) + "\n\n";
	}
	docstring += "Members:";
	for (auto kv : entries) {
	auto key = std::string(pybind11::str(kv.first));
	auto comment = kv.second[int_(1)];
	docstring += "\n\n " + key;
	if (!comment.is_none()) {
	docstring += " : " + (std::string) pybind11::str(comment);
	}
	}
	return docstring;
	},
	name("__doc__")),
	none(),
	none(),
	"");

	m_base.attr("__members__") = static_property(cpp_function(
	[](handle arg) -> dict {
	dict entries = arg.attr("__entries"),
	m;
	for (auto kv : entries) {
	m[kv.first] = kv.second[int_(0)];
	}
	return m;
	},
	name("__members__")),
	none(),
	none(),
	"");

	#define PYBIND11_ENUM_OP_STRICT(op, expr, strict_behavior) \
	m_base.attr(op) = cpp_function( \
	[](const object &a, const object &b) { \
	if (!type::handle_of(a).is(type::handle_of(b))) \
	strict_behavior; /* NOLINT(bugprone-macro-parentheses) */ \
	return expr; \
	}, \
	name(op), \
	is_method(m_base), \
	arg("other"))

	#define PYBIND11_ENUM_OP_CONV(op, expr) \
	m_base.attr(op) = cpp_function( \
	[](const object &a_, const object &b_) { \
	int_ a(a_), b(b_); \
	return expr; \
	}, \
	name(op), \
	is_method(m_base), \
	arg("other"))

	#define PYBIND11_ENUM_OP_CONV_LHS(op, expr) \
	m_base.attr(op) = cpp_function( \
	[](const object &a_, const object &b) { \
	int_ a(a_); \
	return expr; \
	}, \
	name(op), \
	is_method(m_base), \
	arg("other"))

	if (is_convertible) {
	PYBIND11_ENUM_OP_CONV_LHS("__eq__", !b.is_none() && a.equal(b));
	PYBIND11_ENUM_OP_CONV_LHS("__ne__", b.is_none() \|\| !a.equal(b));

	if (is_arithmetic) {
	PYBIND11_ENUM_OP_CONV("__lt__", a < b);
	PYBIND11_ENUM_OP_CONV("__gt__", a > b);
	PYBIND11_ENUM_OP_CONV("__le__", a <= b);
	PYBIND11_ENUM_OP_CONV("__ge__", a >= b);
	PYBIND11_ENUM_OP_CONV("__and__", a & b);
	PYBIND11_ENUM_OP_CONV("__rand__", a & b);
	PYBIND11_ENUM_OP_CONV("__or__", a \| b);
	PYBIND11_ENUM_OP_CONV("__ror__", a \| b);
	PYBIND11_ENUM_OP_CONV("__xor__", a ^ b);
	PYBIND11_ENUM_OP_CONV("__rxor__", a ^ b);
	m_base.attr("__invert__")
	= cpp_function([](const object &arg) { return ~(int_(arg)); },
	name("__invert__"),
	is_method(m_base));
	}
	} else {
	PYBIND11_ENUM_OP_STRICT("__eq__", int_(a).equal(int_(b)), return false);
	PYBIND11_ENUM_OP_STRICT("__ne__", !int_(a).equal(int_(b)), return true);

	if (is_arithmetic) {
	#define PYBIND11_THROW throw type_error("Expected an enumeration of matching type!");
	PYBIND11_ENUM_OP_STRICT("__lt__", int_(a) < int_(b), PYBIND11_THROW);
	PYBIND11_ENUM_OP_STRICT("__gt__", int_(a) > int_(b), PYBIND11_THROW);
	PYBIND11_ENUM_OP_STRICT("__le__", int_(a) <= int_(b), PYBIND11_THROW);
	PYBIND11_ENUM_OP_STRICT("__ge__", int_(a) >= int_(b), PYBIND11_THROW);
	#undef PYBIND11_THROW
	}
	}

	#undef PYBIND11_ENUM_OP_CONV_LHS
	#undef PYBIND11_ENUM_OP_CONV
	#undef PYBIND11_ENUM_OP_STRICT

	m_base.attr("__getstate__") = cpp_function(
	[](const object &arg) { return int_(arg); }, name("__getstate__"), is_method(m_base));

	m_base.attr("__hash__") = cpp_function(
	[](const object &arg) { return int_(arg); }, name("__hash__"), is_method(m_base));
	}

	PYBIND11_NOINLINE void value(char const name_, object value, const char doc = nullptr) {
	dict entries = m_base.attr("__entries");
	str name(name_);
	if (entries.contains(name)) {
	std::string type_name = (std::string) str(m_base.attr("__name__"));
	throw value_error(std::move(type_name) + ": element \"" + std::string(name_)
	+ "\" already exists!");
	}

	entries[name] = std::make_pair(value, doc);
	m_base.attr(std::move(name)) = std::move(value);
	}

	PYBIND11_NOINLINE void export_values() {
	dict entries = m_base.attr("__entries");
	for (auto kv : entries) {
	m_parent.attr(kv.first) = kv.second[int_(0)];
	}
	}

	handle m_base;
	handle m_parent;
	};

	template <bool is_signed, size_t length>
	struct equivalent_integer {};
	template <>
	struct equivalent_integer<true, 1> {
	using type = int8_t;
	};
	template <>
	struct equivalent_integer<false, 1> {
	using type = uint8_t;
	};
	template <>
	struct equivalent_integer<true, 2> {
	using type = int16_t;
	};
	template <>
	struct equivalent_integer<false, 2> {
	using type = uint16_t;
	};
	template <>
	struct equivalent_integer<true, 4> {
	using type = int32_t;
	};
	template <>
	struct equivalent_integer<false, 4> {
	using type = uint32_t;
	};
	template <>
	struct equivalent_integer<true, 8> {
	using type = int64_t;
	};
	template <>
	struct equivalent_integer<false, 8> {
	using type = uint64_t;
	};

	template <typename IntLike>
	using equivalent_integer_t =
	typename equivalent_integer<std::is_signed<IntLike>::value, sizeof(IntLike)>::type;

	PYBIND11_NAMESPACE_END(detail)

	/// Binds C++ enumerations and enumeration classes to Python
	template <typename Type>
	class enum_ : public class_<Type> {
	public:
	using Base = class_<Type>;
	using Base::attr;
	using Base::def;
	using Base::def_property_readonly;
	using Base::def_property_readonly_static;
	using Underlying = typename std::underlying_type<Type>::type;
	// Scalar is the integer representation of underlying type
	using Scalar = detail::conditional_t<detail::any_of<detail::is_std_char_type<Underlying>,
	std::is_same<Underlying, bool>>::value,
	detail::equivalent_integer_t<Underlying>,
	Underlying>;

	template <typename... Extra>
	enum_(const handle &scope, const char *name, const Extra &...extra)
	: class_<Type>(scope, name, extra...), m_base(*this, scope) {
	constexpr bool is_arithmetic = detail::any_of<std::is_same<arithmetic, Extra>...>::value;
	constexpr bool is_convertible = std::is_convertible<Type, Underlying>::value;
	m_base.init(is_arithmetic, is_convertible);

	def(init([](Scalar i) { return static_cast<Type>(i); }), arg("value"));
	def_property_readonly("value", [](Type value) { return (Scalar) value; });
	def("__int__", [](Type value) { return (Scalar) value; });
	def("__index__", [](Type value) { return (Scalar) value; });
	attr("__setstate__") = cpp_function(
	[](detail::value_and_holder &v_h, Scalar arg) {
	detail::initimpl::setstate<Base>(
	v_h, static_cast<Type>(arg), Py_TYPE(v_h.inst) != v_h.type->type);
	},
	detail::is_new_style_constructor(),
	pybind11::name("__setstate__"),
	is_method(*this),
	arg("state"));
	}

	/// Export enumeration entries into the parent scope
	enum_ &export_values() {
	m_base.export_values();
	return *this;
	}

	/// Add an enumeration entry
	enum_ &value(char const name, Type value, const char doc = nullptr) {
	m_base.value(name, pybind11::cast(value, return_value_policy::copy), doc);
	return *this;
	}

	private:
	detail::enum_base m_base;
	};

	PYBIND11_NAMESPACE_BEGIN(detail)

	PYBIND11_NOINLINE void keep_alive_impl(handle nurse, handle patient) {
	if (!nurse \|\| !patient) {
	pybind11_fail("Could not activate keep_alive!");
	}

	if (patient.is_none() \|\| nurse.is_none()) {
	return; /* Nothing to keep alive or nothing to be kept alive by */
	}

	auto tinfo = all_type_info(Py_TYPE(nurse.ptr()));
	if (!tinfo.empty()) {
	/* It's a pybind-registered type, so we can store the patient in the
	* internal list. */
	add_patient(nurse.ptr(), patient.ptr());
	} else {
	/* Fall back to clever approach based on weak references taken from
	* Boost.Python. This is not used for pybind-registered types because
	* the objects can be destroyed out-of-order in a GC pass. */
	cpp_function disable_lifesupport([patient](handle weakref) {
	patient.dec_ref();
	weakref.dec_ref();
	});

	weakref wr(nurse, disable_lifesupport);

	patient.inc_ref(); /* reference patient and leak the weak reference */
	(void) wr.release();
	}
	}

	PYBIND11_NOINLINE void
	keep_alive_impl(size_t Nurse, size_t Patient, function_call &call, handle ret) {
	auto get_arg = [&](size_t n) {
	if (n == 0) {
	return ret;
	}
	if (n == 1 && call.init_self) {
	return call.init_self;
	}
	if (n <= call.args.size()) {
	return call.args[n - 1];
	}
	return handle();
	};

	keep_alive_impl(get_arg(Nurse), get_arg(Patient));
	}

	inline std::pair<decltype(internals::registered_types_py)::iterator, bool>
	all_type_info_get_cache(PyTypeObject *type) {
	auto res = get_internals()
	.registered_types_py
	#ifdef __cpp_lib_unordered_map_try_emplace
	.try_emplace(type);
	#else
	.emplace(type, std::vector<detail::type_info *>());
	#endif
	if (res.second) {
	// New cache entry created; set up a weak reference to automatically remove it if the type
	// gets destroyed:
	weakref((PyObject *) type, cpp_function([type](handle wr) {
	get_internals().registered_types_py.erase(type);

	// TODO consolidate the erasure code in pybind11_meta_dealloc() in class.h
	auto &cache = get_internals().inactive_override_cache;
	for (auto it = cache.begin(), last = cache.end(); it != last;) {
	if (it->first == reinterpret_cast<PyObject *>(type)) {
	it = cache.erase(it);
	} else {
	++it;
	}
	}

	wr.dec_ref();
	}))
	.release();
	}

	return res;
	}

	/* There are a large number of apparently unused template arguments because
	* each combination requires a separate py::class_ registration.
	*/
	template <typename Access,
	return_value_policy Policy,
	typename Iterator,
	typename Sentinel,
	typename ValueType,
	typename... Extra>
	struct iterator_state {
	Iterator it;
	Sentinel end;
	bool first_or_done;
	};

	// Note: these helpers take the iterator by non-const reference because some
	// iterators in the wild can't be dereferenced when const. The & after Iterator
	// is required for MSVC < 16.9. SFINAE cannot be reused for result_type due to
	// bugs in ICC, NVCC, and PGI compilers. See PR #3293.
	template <typename Iterator, typename SFINAE = decltype(*std::declval<Iterator &>())>
	struct iterator_access {
	using result_type = decltype(*std::declval<Iterator &>());
	// NOLINTNEXTLINE(readability-const-return-type) // PR #3263
	result_type operator()(Iterator &it) const { return *it; }
	};

	template <typename Iterator, typename SFINAE = decltype((*std::declval<Iterator &>()).first)>
	class iterator_key_access {
	private:
	using pair_type = decltype(*std::declval<Iterator &>());

	public:
	/* If either the pair itself or the element of the pair is a reference, we
	* want to return a reference, otherwise a value. When the decltype
	* expression is parenthesized it is based on the value category of the
	* expression; otherwise it is the declared type of the pair member.
	* The use of declval<pair_type> in the second branch rather than directly
	* using *std::declval<Iterator &>() is a workaround for nvcc
	* (it's not used in the first branch because going via decltype and back
	* through declval does not perfectly preserve references).
	*/
	using result_type
	= conditional_t<std::is_reference<decltype(*std::declval<Iterator &>())>::value,
	decltype(((*std::declval<Iterator &>()).first)),
	decltype(std::declval<pair_type>().first)>;
	result_type operator()(Iterator &it) const { return (*it).first; }
	};

	template <typename Iterator, typename SFINAE = decltype((*std::declval<Iterator &>()).second)>
	class iterator_value_access {
	private:
	using pair_type = decltype(*std::declval<Iterator &>());

	public:
	using result_type
	= conditional_t<std::is_reference<decltype(*std::declval<Iterator &>())>::value,
	decltype(((*std::declval<Iterator &>()).second)),
	decltype(std::declval<pair_type>().second)>;
	result_type operator()(Iterator &it) const { return (*it).second; }
	};

	template <typename Access,
	return_value_policy Policy,
	typename Iterator,
	typename Sentinel,
	typename ValueType,
	typename... Extra>
	iterator make_iterator_impl(Iterator &&first, Sentinel &&last, Extra &&...extra) {
	using state = detail::iterator_state<Access, Policy, Iterator, Sentinel, ValueType, Extra...>;
	// TODO: state captures only the types of Extra, not the values

	if (!detail::get_type_info(typeid(state), false)) {
	class_<state>(handle(), "iterator", pybind11::module_local())
	.def("__iter__", [](state &s) -> state & { return s; })
	.def(
	"__next__",
	[](state &s) -> ValueType {
	if (!s.first_or_done) {
	++s.it;
	} else {
	s.first_or_done = false;
	}
	if (s.it == s.end) {
	s.first_or_done = true;
	throw stop_iteration();
	}
	return Access()(s.it);
	// NOLINTNEXTLINE(readability-const-return-type) // PR #3263
	},
	std::forward<Extra>(extra)...,
	Policy);
	}

	return cast(state{std::forward<Iterator>(first), std::forward<Sentinel>(last), true});
	}

	PYBIND11_NAMESPACE_END(detail)

	/// Makes a python iterator from a first and past-the-end C++ InputIterator.
	template <return_value_policy Policy = return_value_policy::reference_internal,
	typename Iterator,
	typename Sentinel,
	typename ValueType = typename detail::iterator_access<Iterator>::result_type,
	typename... Extra>
	iterator make_iterator(Iterator &&first, Sentinel &&last, Extra &&...extra) {
	return detail::make_iterator_impl<detail::iterator_access<Iterator>,
	Policy,
	Iterator,
	Sentinel,
	ValueType,
	Extra...>(std::forward<Iterator>(first),
	std::forward<Sentinel>(last),
	std::forward<Extra>(extra)...);
	}

	/// Makes a python iterator over the keys (`.first`) of a iterator over pairs from a
	/// first and past-the-end InputIterator.
	template <return_value_policy Policy = return_value_policy::reference_internal,
	typename Iterator,
	typename Sentinel,
	typename KeyType = typename detail::iterator_key_access<Iterator>::result_type,
	typename... Extra>
	iterator make_key_iterator(Iterator &&first, Sentinel &&last, Extra &&...extra) {
	return detail::make_iterator_impl<detail::iterator_key_access<Iterator>,
	Policy,
	Iterator,
	Sentinel,
	KeyType,
	Extra...>(std::forward<Iterator>(first),
	std::forward<Sentinel>(last),
	std::forward<Extra>(extra)...);
	}

	/// Makes a python iterator over the values (`.second`) of a iterator over pairs from a
	/// first and past-the-end InputIterator.
	template <return_value_policy Policy = return_value_policy::reference_internal,
	typename Iterator,
	typename Sentinel,
	typename ValueType = typename detail::iterator_value_access<Iterator>::result_type,
	typename... Extra>
	iterator make_value_iterator(Iterator &&first, Sentinel &&last, Extra &&...extra) {
	return detail::make_iterator_impl<detail::iterator_value_access<Iterator>,
	Policy,
	Iterator,
	Sentinel,
	ValueType,
	Extra...>(std::forward<Iterator>(first),
	std::forward<Sentinel>(last),
	std::forward<Extra>(extra)...);
	}

	/// Makes an iterator over values of an stl container or other container supporting
	/// `std::begin()`/`std::end()`
	template <return_value_policy Policy = return_value_policy::reference_internal,
	typename Type,
	typename... Extra>
	iterator make_iterator(Type &value, Extra &&...extra) {
	return make_iterator<Policy>(
	std::begin(value), std::end(value), std::forward<Extra>(extra)...);
	}

	/// Makes an iterator over the keys (`.first`) of a stl map-like container supporting
	/// `std::begin()`/`std::end()`
	template <return_value_policy Policy = return_value_policy::reference_internal,
	typename Type,
	typename... Extra>
	iterator make_key_iterator(Type &value, Extra &&...extra) {
	return make_key_iterator<Policy>(
	std::begin(value), std::end(value), std::forward<Extra>(extra)...);
	}

	/// Makes an iterator over the values (`.second`) of a stl map-like container supporting
	/// `std::begin()`/`std::end()`
	template <return_value_policy Policy = return_value_policy::reference_internal,
	typename Type,
	typename... Extra>
	iterator make_value_iterator(Type &value, Extra &&...extra) {
	return make_value_iterator<Policy>(
	std::begin(value), std::end(value), std::forward<Extra>(extra)...);
	}

	template <typename InputType, typename OutputType>
	void implicitly_convertible() {
	struct set_flag {
	bool &flag;
	explicit set_flag(bool &flag_) : flag(flag_) { flag_ = true; }
	~set_flag() { flag = false; }
	};
	auto implicit_caster = [](PyObject obj, PyTypeObject type) -> PyObject * {
	static bool currently_used = false;
	if (currently_used) { // implicit conversions are non-reentrant
	return nullptr;
	}
	set_flag flag_helper(currently_used);
	if (!detail::make_caster<InputType>().load(obj, false)) {
	return nullptr;
	}
	tuple args(1);
	args[0] = obj;
	PyObject result = PyObject_Call((PyObject ) type, args.ptr(), nullptr);
	if (result == nullptr) {
	PyErr_Clear();
	}
	return result;
	};

	if (auto *tinfo = detail::get_type_info(typeid(OutputType))) {
	tinfo->implicit_conversions.emplace_back(std::move(implicit_caster));
	} else {
	pybind11_fail("implicitly_convertible: Unable to find type " + type_id<OutputType>());
	}
	}

	inline void register_exception_translator(ExceptionTranslator &&translator) {
	detail::get_internals().registered_exception_translators.push_front(
	std::forward<ExceptionTranslator>(translator));
	}

	/**
	* Add a new module-local exception translator. Locally registered functions
	* will be tried before any globally registered exception translators, which
	* will only be invoked if the module-local handlers do not deal with
	* the exception.
	*/
	inline void register_local_exception_translator(ExceptionTranslator &&translator) {
	detail::get_local_internals().registered_exception_translators.push_front(
	std::forward<ExceptionTranslator>(translator));
	}

	/**
	* Wrapper to generate a new Python exception type.
	*
	* This should only be used with PyErr_SetString for now.
	* It is not (yet) possible to use as a py::base.
	* Template type argument is reserved for future use.
	*/
	template <typename type>
	class exception : public object {
	public:
	exception() = default;
	exception(handle scope, const char *name, handle base = PyExc_Exception) {
	std::string full_name
	= scope.attr("__name__").cast<std::string>() + std::string(".") + name;
	m_ptr = PyErr_NewException(const_cast<char *>(full_name.c_str()), base.ptr(), nullptr);
	if (hasattr(scope, "__dict__") && scope.attr("__dict__").contains(name)) {
	pybind11_fail("Error during initialization: multiple incompatible "
	"definitions with name \""
	+ std::string(name) + "\"");
	}
	scope.attr(name) = *this;
	}

	// Sets the current python exception to this exception object with the given message
	void operator()(const char *message) { PyErr_SetString(m_ptr, message); }
	};

	PYBIND11_NAMESPACE_BEGIN(detail)
	// Returns a reference to a function-local static exception object used in the simple
	// register_exception approach below. (It would be simpler to have the static local variable
	// directly in register_exception, but that makes clang <3.5 segfault - issue #1349).
	template <typename CppException>
	exception<CppException> &get_exception_object() {
	static exception<CppException> ex;
	return ex;
	}

	// Helper function for register_exception and register_local_exception
	template <typename CppException>
	exception<CppException> &
	register_exception_impl(handle scope, const char *name, handle base, bool isLocal) {
	auto &ex = detail::get_exception_object<CppException>();
	if (!ex) {
	ex = exception<CppException>(scope, name, base);
	}

	auto register_func
	= isLocal ? &register_local_exception_translator : &register_exception_translator;

	register_func([](std::exception_ptr p) {
	if (!p) {
	return;
	}
	try {
	std::rethrow_exception(p);
	} catch (const CppException &e) {
	detail::get_exception_object<CppException>()(e.what());
	}
	});
	return ex;
	}

	PYBIND11_NAMESPACE_END(detail)

	/**
	* Registers a Python exception in `m` of the given `name` and installs a translator to
	* translate the C++ exception to the created Python exception using the what() method.
	* This is intended for simple exception translations; for more complex translation, register the
	* exception object and translator directly.
	*/
	template <typename CppException>
	exception<CppException> &
	register_exception(handle scope, const char *name, handle base = PyExc_Exception) {
	return detail::register_exception_impl<CppException>(scope, name, base, false /* isLocal */);
	}

	/**
	* Registers a Python exception in `m` of the given `name` and installs a translator to
	* translate the C++ exception to the created Python exception using the what() method.
	* This translator will only be used for exceptions that are thrown in this module and will be
	* tried before global exception translators, including those registered with register_exception.
	* This is intended for simple exception translations; for more complex translation, register the
	* exception object and translator directly.
	*/
	template <typename CppException>
	exception<CppException> &
	register_local_exception(handle scope, const char *name, handle base = PyExc_Exception) {
	return detail::register_exception_impl<CppException>(scope, name, base, true /* isLocal */);
	}

	PYBIND11_NAMESPACE_BEGIN(detail)
	PYBIND11_NOINLINE void print(const tuple &args, const dict &kwargs) {
	auto strings = tuple(args.size());
	for (size_t i = 0; i < args.size(); ++i) {
	strings[i] = str(args[i]);
	}
	auto sep = kwargs.contains("sep") ? kwargs["sep"] : str(" ");
	auto line = sep.attr("join")(std::move(strings));

	object file;
	if (kwargs.contains("file")) {
	file = kwargs["file"].cast<object>();
	} else {
	try {
	file = module_::import("sys").attr("stdout");
	} catch (const error_already_set &) {
	/* If print() is called from code that is executed as
	part of garbage collection during interpreter shutdown,
	importing 'sys' can fail. Give up rather than crashing the
	interpreter in this case. */
	return;
	}
	}

	auto write = file.attr("write");
	write(std::move(line));
	write(kwargs.contains("end") ? kwargs["end"] : str("\n"));

	if (kwargs.contains("flush") && kwargs["flush"].cast<bool>()) {
	file.attr("flush")();
	}
	}
	PYBIND11_NAMESPACE_END(detail)

	template <return_value_policy policy = return_value_policy::automatic_reference, typename... Args>
	void print(Args &&...args) {
	auto c = detail::collect_arguments<policy>(std::forward<Args>(args)...);
	detail::print(c.args(), c.kwargs());
	}

	inline void
	error_already_set::m_fetched_error_deleter(detail::error_fetch_and_normalize *raw_ptr) {
	gil_scoped_acquire gil;
	error_scope scope;
	delete raw_ptr;
	}

	inline const char *error_already_set::what() const noexcept {
	gil_scoped_acquire gil;
	error_scope scope;
	return m_fetched_error->error_string().c_str();
	}

	PYBIND11_NAMESPACE_BEGIN(detail)

	inline function
	get_type_override(const void this_ptr, const type_info this_type, const char *name) {
	handle self = get_object_handle(this_ptr, this_type);
	if (!self) {
	return function();
	}
	handle type = type::handle_of(self);
	auto key = std::make_pair(type.ptr(), name);

	/* Cache functions that aren't overridden in Python to avoid
	many costly Python dictionary lookups below */
	auto &cache = get_internals().inactive_override_cache;
	if (cache.find(key) != cache.end()) {
	return function();
	}

	function override = getattr(self, name, function());
	if (override.is_cpp_function()) {
	cache.insert(std::move(key));
	return function();
	}

	/* Don't call dispatch code if invoked from overridden function.
	Unfortunately this doesn't work on PyPy. */
	#if !defined(PYPY_VERSION)
	# if PY_VERSION_HEX >= 0x03090000
	PyFrameObject *frame = PyThreadState_GetFrame(PyThreadState_Get());
	if (frame != nullptr) {
	PyCodeObject *f_code = PyFrame_GetCode(frame);
	// f_code is guaranteed to not be NULL
	if ((std::string) str(f_code->co_name) == name && f_code->co_argcount > 0) {
	PyObject *locals = PyEval_GetLocals();
	if (locals != nullptr) {
	PyObject co_varnames = PyObject_GetAttrString((PyObject ) f_code, "co_varnames");
	PyObject *self_arg = PyTuple_GET_ITEM(co_varnames, 0);
	Py_DECREF(co_varnames);
	PyObject *self_caller = dict_getitem(locals, self_arg);
	if (self_caller == self.ptr()) {
	Py_DECREF(f_code);
	Py_DECREF(frame);
	return function();
	}
	}
	}
	Py_DECREF(f_code);
	Py_DECREF(frame);
	}
	# else
	PyFrameObject *frame = PyThreadState_Get()->frame;
	if (frame != nullptr && (std::string) str(frame->f_code->co_name) == name
	&& frame->f_code->co_argcount > 0) {
	PyFrame_FastToLocals(frame);
	PyObject *self_caller
	= dict_getitem(frame->f_locals, PyTuple_GET_ITEM(frame->f_code->co_varnames, 0));
	if (self_caller == self.ptr()) {
	return function();
	}
	}
	# endif

	#else
	/* PyPy currently doesn't provide a detailed cpyext emulation of
	frame objects, so we have to emulate this using Python. This
	is going to be slow..*/
	dict d;
	d["self"] = self;
	d["name"] = pybind11::str(name);
	PyObject *result
	= PyRun_String("import inspect\n"
	"frame = inspect.currentframe()\n"
	"if frame is not None:\n"
	" frame = frame.f_back\n"
	" if frame is not None and str(frame.f_code.co_name) == name and "
	"frame.f_code.co_argcount > 0:\n"
	" self_caller = frame.f_locals[frame.f_code.co_varnames[0]]\n"
	" if self_caller == self:\n"
	" self = None\n",
	Py_file_input,
	d.ptr(),
	d.ptr());
	if (result == nullptr)
	throw error_already_set();
	Py_DECREF(result);
	if (d["self"].is_none())
	return function();
	#endif

	return override;
	}
	PYBIND11_NAMESPACE_END(detail)

	/** \rst
	Try to retrieve a python method by the provided name from the instance pointed to by the
	this_ptr.

	:this_ptr: The pointer to the object the overridden method should be retrieved for. This should
	be the first non-trampoline class encountered in the inheritance chain.
	:name: The name of the overridden Python method to retrieve.
	:return: The Python method by this name from the object or an empty function wrapper.
	\endrst */
	template <class T>
	function get_override(const T this_ptr, const char name) {
	auto *tinfo = detail::get_type_info(typeid(T));
	return tinfo ? detail::get_type_override(this_ptr, tinfo, name) : function();
	}

	#define PYBIND11_OVERRIDE_IMPL(ret_type, cname, name, ...) \
	do { \
	pybind11::gil_scoped_acquire gil; \
	pybind11::function override \
	= pybind11::get_override(static_cast<const cname *>(this), name); \
	if (override) { \
	auto o = override(__VA_ARGS__); \
	if (pybind11::detail::cast_is_temporary_value_reference<ret_type>::value) { \
	static pybind11::detail::override_caster_t<ret_type> caster; \
	return pybind11::detail::cast_ref<ret_type>(std::move(o), caster); \
	} \
	return pybind11::detail::cast_safe<ret_type>(std::move(o)); \
	} \
	} while (false)

	/** \rst
	Macro to populate the virtual method in the trampoline class. This macro tries to look up a
	method named 'fn' from the Python side, deals with the :ref:`gil` and necessary argument
	conversions to call this method and return the appropriate type.
	See :ref:`overriding_virtuals` for more information. This macro should be used when the method
	name in C is not the same as the method name in Python. For example with `__str__`.

	.. code-block:: cpp

	std::string toString() override {
	PYBIND11_OVERRIDE_NAME(
	std::string, // Return type (ret_type)
	Animal, // Parent class (cname)
	"__str__", // Name of method in Python (name)
	toString, // Name of function in C++ (fn)
	);
	}
	\endrst */
	#define PYBIND11_OVERRIDE_NAME(ret_type, cname, name, fn, ...) \
	do { \
	PYBIND11_OVERRIDE_IMPL(PYBIND11_TYPE(ret_type), PYBIND11_TYPE(cname), name, __VA_ARGS__); \
	return cname::fn(__VA_ARGS__); \
	} while (false)

	/** \rst
	Macro for pure virtual functions, this function is identical to
	:c:macro:`PYBIND11_OVERRIDE_NAME`, except that it throws if no override can be found.
	\endrst */
	#define PYBIND11_OVERRIDE_PURE_NAME(ret_type, cname, name, fn, ...) \
	do { \
	PYBIND11_OVERRIDE_IMPL(PYBIND11_TYPE(ret_type), PYBIND11_TYPE(cname), name, __VA_ARGS__); \
	pybind11::pybind11_fail( \
	"Tried to call pure virtual function \"" PYBIND11_STRINGIFY(cname) "::" name "\""); \
	} while (false)

	/** \rst
	Macro to populate the virtual method in the trampoline class. This macro tries to look up the
	method from the Python side, deals with the :ref:`gil` and necessary argument conversions to
	call this method and return the appropriate type. This macro should be used if the method name
	in C and in Python are identical.
	See :ref:`overriding_virtuals` for more information.

	.. code-block:: cpp

	class PyAnimal : public Animal {
	public:
	// Inherit the constructors
	using Animal::Animal;

	// Trampoline (need one for each virtual function)
	std::string go(int n_times) override {
	PYBIND11_OVERRIDE_PURE(
	std::string, // Return type (ret_type)
	Animal, // Parent class (cname)
	go, // Name of function in C++ (must match Python name) (fn)
	n_times // Argument(s) (...)
	);
	}
	};
	\endrst */
	#define PYBIND11_OVERRIDE(ret_type, cname, fn, ...) \
	PYBIND11_OVERRIDE_NAME(PYBIND11_TYPE(ret_type), PYBIND11_TYPE(cname), #fn, fn, __VA_ARGS__)

	/** \rst
	Macro for pure virtual functions, this function is identical to :c:macro:`PYBIND11_OVERRIDE`,
	except that it throws if no override can be found.
	\endrst */
	#define PYBIND11_OVERRIDE_PURE(ret_type, cname, fn, ...) \
	PYBIND11_OVERRIDE_PURE_NAME( \
	PYBIND11_TYPE(ret_type), PYBIND11_TYPE(cname), #fn, fn, __VA_ARGS__)

	// Deprecated versions

	PYBIND11_DEPRECATED("get_type_overload has been deprecated")
	inline function
	get_type_overload(const void this_ptr, const detail::type_info this_type, const char *name) {
	return detail::get_type_override(this_ptr, this_type, name);
	}

	template <class T>
	inline function get_overload(const T this_ptr, const char name) {
	return get_override(this_ptr, name);
	}

	#define PYBIND11_OVERLOAD_INT(ret_type, cname, name, ...) \
	PYBIND11_OVERRIDE_IMPL(PYBIND11_TYPE(ret_type), PYBIND11_TYPE(cname), name, __VA_ARGS__)
	#define PYBIND11_OVERLOAD_NAME(ret_type, cname, name, fn, ...) \
	PYBIND11_OVERRIDE_NAME(PYBIND11_TYPE(ret_type), PYBIND11_TYPE(cname), name, fn, __VA_ARGS__)
	#define PYBIND11_OVERLOAD_PURE_NAME(ret_type, cname, name, fn, ...) \
	PYBIND11_OVERRIDE_PURE_NAME( \
	PYBIND11_TYPE(ret_type), PYBIND11_TYPE(cname), name, fn, __VA_ARGS__);
	#define PYBIND11_OVERLOAD(ret_type, cname, fn, ...) \
	PYBIND11_OVERRIDE(PYBIND11_TYPE(ret_type), PYBIND11_TYPE(cname), fn, __VA_ARGS__)
	#define PYBIND11_OVERLOAD_PURE(ret_type, cname, fn, ...) \
	PYBIND11_OVERRIDE_PURE(PYBIND11_TYPE(ret_type), PYBIND11_TYPE(cname), fn, __VA_ARGS__);

	PYBIND11_NAMESPACE_END(PYBIND11_NAMESPACE)

	#if defined(__GNUC__) && __GNUC__ == 7
	# pragma GCC diagnostic pop // -Wnoexcept-type
	#endif