ext/pybind11/include/pybind11/embed.h - public/gem5 - Git at Google

 /*
     pybind11/embed.h: Support for embedding the interpreter

     Copyright (c) 2017 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 "pybind11.h"
 #include "eval.h"

 #include <memory>
 #include <vector>

 #if defined(PYPY_VERSION)
 #  error Embedding the interpreter is not supported with PyPy
 #endif

 #if PY_MAJOR_VERSION >= 3
 #  define PYBIND11_EMBEDDED_MODULE_IMPL(name)            \
       extern "C" PyObject *pybind11_init_impl_##name();  \
       extern "C" PyObject *pybind11_init_impl_##name() { \
           return pybind11_init_wrapper_##name();         \
       }
 #else
 #  define PYBIND11_EMBEDDED_MODULE_IMPL(name)            \
       extern "C" void pybind11_init_impl_##name();       \
       extern "C" void pybind11_init_impl_##name() {      \
           pybind11_init_wrapper_##name();                \
       }
 #endif

 /** \rst
     Add a new module to the table of builtins for the interpreter. Must be
     defined in global scope. The first macro parameter is the name of the
     module (without quotes). The second parameter is the variable which will
     be used as the interface to add functions and classes to the module.

     .. code-block:: cpp

         PYBIND11_EMBEDDED_MODULE(example, m) {
             // ... initialize functions and classes here
             m.def("foo", []() {
                 return "Hello, World!";
             });
         }
  \endrst */
 #define PYBIND11_EMBEDDED_MODULE(name, variable)                                                  \
     static ::pybind11::module_::module_def PYBIND11_CONCAT(pybind11_module_def_, name);           \
     static void PYBIND11_CONCAT(pybind11_init_, name)(::pybind11::module_ &);                     \
     static PyObject PYBIND11_CONCAT(*pybind11_init_wrapper_, name)() {                            \
         auto m = ::pybind11::module_::create_extension_module(                                    \
             PYBIND11_TOSTRING(name), nullptr, &PYBIND11_CONCAT(pybind11_module_def_, name));      \
         try {                                                                                     \
             PYBIND11_CONCAT(pybind11_init_, name)(m);                                             \
             return m.ptr();                                                                       \
         }                                                                                         \
         PYBIND11_CATCH_INIT_EXCEPTIONS                                                            \
     }                                                                                             \
     PYBIND11_EMBEDDED_MODULE_IMPL(name)                                                           \
     ::pybind11::detail::embedded_module PYBIND11_CONCAT(pybind11_module_, name)(                  \
         PYBIND11_TOSTRING(name), PYBIND11_CONCAT(pybind11_init_impl_, name));                     \
     void PYBIND11_CONCAT(pybind11_init_, name)(::pybind11::module_                                \
                                                & variable) // NOLINT(bugprone-macro-parentheses)

 PYBIND11_NAMESPACE_BEGIN(PYBIND11_NAMESPACE)
 PYBIND11_NAMESPACE_BEGIN(detail)

 /// Python 2.7/3.x compatible version of `PyImport_AppendInittab` and error checks.
 struct embedded_module {
 #if PY_MAJOR_VERSION >= 3
     using init_t = PyObject *(*)();
 #else
     using init_t = void (*)();
 #endif
     embedded_module(const char *name, init_t init) {
         if (Py_IsInitialized() != 0)
             pybind11_fail("Can't add new modules after the interpreter has been initialized");

         auto result = PyImport_AppendInittab(name, init);
         if (result == -1)
             pybind11_fail("Insufficient memory to add a new module");
     }
 };

 struct wide_char_arg_deleter {
     void operator()(wchar_t *ptr) const {
 #if PY_VERSION_HEX >= 0x030500f0
         // API docs: https://docs.python.org/3/c-api/sys.html#c.Py_DecodeLocale
         PyMem_RawFree(ptr);
 #else
         delete[] ptr;
 #endif
     }
 };

 inline wchar_t *widen_chars(const char *safe_arg) {
 #if PY_VERSION_HEX >= 0x030500f0
     wchar_t *widened_arg = Py_DecodeLocale(safe_arg, nullptr);
 #else
     wchar_t *widened_arg = nullptr;
 #    if defined(HAVE_BROKEN_MBSTOWCS) && HAVE_BROKEN_MBSTOWCS
     size_t count = strlen(safe_arg);
 #    else
     size_t count = mbstowcs(nullptr, safe_arg, 0);
 #    endif
     if (count != static_cast<size_t>(-1)) {
         widened_arg = new wchar_t[count + 1];
         mbstowcs(widened_arg, safe_arg, count + 1);
     }
 #endif
     return widened_arg;
 }

 /// Python 2.x/3.x-compatible version of `PySys_SetArgv`
 inline void set_interpreter_argv(int argc, const char *const *argv, bool add_program_dir_to_path) {
     // Before it was special-cased in python 3.8, passing an empty or null argv
     // caused a segfault, so we have to reimplement the special case ourselves.
     bool special_case = (argv == nullptr || argc <= 0);

     const char *const empty_argv[]{"\0"};
     const char *const *safe_argv = special_case ? empty_argv : argv;
     if (special_case)
         argc = 1;

     auto argv_size = static_cast<size_t>(argc);
 #if PY_MAJOR_VERSION >= 3
     // SetArgv* on python 3 takes wchar_t, so we have to convert.
     std::unique_ptr<wchar_t *[]> widened_argv(new wchar_t *[argv_size]);
     std::vector<std::unique_ptr<wchar_t[], wide_char_arg_deleter>> widened_argv_entries;
     widened_argv_entries.reserve(argv_size);
     for (size_t ii = 0; ii < argv_size; ++ii) {
         widened_argv_entries.emplace_back(widen_chars(safe_argv[ii]));
         if (!widened_argv_entries.back()) {
             // A null here indicates a character-encoding failure or the python
             // interpreter out of memory. Give up.
             return;
         }
         widened_argv[ii] = widened_argv_entries.back().get();
     }

     auto pysys_argv = widened_argv.get();
 #else
     // python 2.x
     std::vector<std::string> strings{safe_argv, safe_argv + argv_size};
     std::vector<char *> char_strings{argv_size};
     for (std::size_t i = 0; i < argv_size; ++i)
         char_strings[i] = &strings[i][0];
     char **pysys_argv = char_strings.data();
 #endif

     PySys_SetArgvEx(argc, pysys_argv, static_cast<int>(add_program_dir_to_path));
 }

 PYBIND11_NAMESPACE_END(detail)

 /** \rst
     Initialize the Python interpreter. No other pybind11 or CPython API functions can be
     called before this is done; with the exception of `PYBIND11_EMBEDDED_MODULE`. The
     optional `init_signal_handlers` parameter can be used to skip the registration of
     signal handlers (see the `Python documentation`_ for details). Calling this function
     again after the interpreter has already been initialized is a fatal error.

     If initializing the Python interpreter fails, then the program is terminated.  (This
     is controlled by the CPython runtime and is an exception to pybind11's normal behavior
     of throwing exceptions on errors.)

     The remaining optional parameters, `argc`, `argv`, and `add_program_dir_to_path` are
     used to populate ``sys.argv`` and ``sys.path``.
     See the |PySys_SetArgvEx documentation|_ for details.

     .. _Python documentation: https://docs.python.org/3/c-api/init.html#c.Py_InitializeEx
     .. |PySys_SetArgvEx documentation| replace:: ``PySys_SetArgvEx`` documentation
     .. _PySys_SetArgvEx documentation: https://docs.python.org/3/c-api/init.html#c.PySys_SetArgvEx
  \endrst */
 inline void initialize_interpreter(bool init_signal_handlers = true,
                                    int argc = 0,
                                    const char *const *argv = nullptr,
                                    bool add_program_dir_to_path = true) {
     if (Py_IsInitialized() != 0)
         pybind11_fail("The interpreter is already running");

     Py_InitializeEx(init_signal_handlers ? 1 : 0);

     detail::set_interpreter_argv(argc, argv, add_program_dir_to_path);
 }

 /** \rst
     Shut down the Python interpreter. No pybind11 or CPython API functions can be called
     after this. In addition, pybind11 objects must not outlive the interpreter:

     .. code-block:: cpp

         { // BAD
             py::initialize_interpreter();
             auto hello = py::str("Hello, World!");
             py::finalize_interpreter();
         } // <-- BOOM, hello's destructor is called after interpreter shutdown

         { // GOOD
             py::initialize_interpreter();
             { // scoped
                 auto hello = py::str("Hello, World!");
             } // <-- OK, hello is cleaned up properly
             py::finalize_interpreter();
         }

         { // BETTER
             py::scoped_interpreter guard{};
             auto hello = py::str("Hello, World!");
         }

     .. warning::

         The interpreter can be restarted by calling `initialize_interpreter` again.
         Modules created using pybind11 can be safely re-initialized. However, Python
         itself cannot completely unload binary extension modules and there are several
         caveats with regard to interpreter restarting. All the details can be found
         in the CPython documentation. In short, not all interpreter memory may be
         freed, either due to reference cycles or user-created global data.

  \endrst */
 inline void finalize_interpreter() {
     handle builtins(PyEval_GetBuiltins());
     const char *id = PYBIND11_INTERNALS_ID;

     // Get the internals pointer (without creating it if it doesn't exist).  It's possible for the
     // internals to be created during Py_Finalize() (e.g. if a py::capsule calls `get_internals()`
     // during destruction), so we get the pointer-pointer here and check it after Py_Finalize().
     detail::internals **internals_ptr_ptr = detail::get_internals_pp();
     // It could also be stashed in builtins, so look there too:
     if (builtins.contains(id) && isinstance<capsule>(builtins[id]))
         internals_ptr_ptr = capsule(builtins[id]);

     Py_Finalize();

     if (internals_ptr_ptr) {
         delete *internals_ptr_ptr;
         *internals_ptr_ptr = nullptr;
     }
 }

 /** \rst
     Scope guard version of `initialize_interpreter` and `finalize_interpreter`.
     This a move-only guard and only a single instance can exist.

     See `initialize_interpreter` for a discussion of its constructor arguments.

     .. code-block:: cpp

         #include <pybind11/embed.h>

         int main() {
             py::scoped_interpreter guard{};
             py::print(Hello, World!);
         } // <-- interpreter shutdown
  \endrst */
 class scoped_interpreter {
 public:
     explicit scoped_interpreter(bool init_signal_handlers = true,
                                 int argc = 0,
                                 const char *const *argv = nullptr,
                                 bool add_program_dir_to_path = true) {
         initialize_interpreter(init_signal_handlers, argc, argv, add_program_dir_to_path);
     }

     scoped_interpreter(const scoped_interpreter &) = delete;
     scoped_interpreter(scoped_interpreter &&other) noexcept { other.is_valid = false; }
     scoped_interpreter &operator=(const scoped_interpreter &) = delete;
     scoped_interpreter &operator=(scoped_interpreter &&) = delete;

     ~scoped_interpreter() {
         if (is_valid)
             finalize_interpreter();
     }

 private:
     bool is_valid = true;
 };

 PYBIND11_NAMESPACE_END(PYBIND11_NAMESPACE)
	/*
	pybind11/embed.h: Support for embedding the interpreter

	Copyright (c) 2017 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 "pybind11.h"
	#include "eval.h"

	#include <memory>
	#include <vector>

	#if defined(PYPY_VERSION)
	# error Embedding the interpreter is not supported with PyPy
	#endif

	#if PY_MAJOR_VERSION >= 3
	# define PYBIND11_EMBEDDED_MODULE_IMPL(name) \
	extern "C" PyObject *pybind11_init_impl_##name(); \
	extern "C" PyObject *pybind11_init_impl_##name() { \
	return pybind11_init_wrapper_##name(); \
	}
	#else
	# define PYBIND11_EMBEDDED_MODULE_IMPL(name) \
	extern "C" void pybind11_init_impl_##name(); \
	extern "C" void pybind11_init_impl_##name() { \
	pybind11_init_wrapper_##name(); \
	}
	#endif

	/** \rst
	Add a new module to the table of builtins for the interpreter. Must be
	defined in global scope. The first macro parameter is the name of the
	module (without quotes). The second parameter is the variable which will
	be used as the interface to add functions and classes to the module.

	.. code-block:: cpp

	PYBIND11_EMBEDDED_MODULE(example, m) {
	// ... initialize functions and classes here
	m.def("foo", []() {
	return "Hello, World!";
	});
	}
	\endrst */
	#define PYBIND11_EMBEDDED_MODULE(name, variable) \
	static ::pybind11::module_::module_def PYBIND11_CONCAT(pybind11_module_def_, name); \
	static void PYBIND11_CONCAT(pybind11_init_, name)(::pybind11::module_ &); \
	static PyObject PYBIND11_CONCAT(*pybind11_init_wrapper_, name)() { \
	auto m = ::pybind11::module_::create_extension_module( \
	PYBIND11_TOSTRING(name), nullptr, &PYBIND11_CONCAT(pybind11_module_def_, name)); \
	try { \
	PYBIND11_CONCAT(pybind11_init_, name)(m); \
	return m.ptr(); \
	} \
	PYBIND11_CATCH_INIT_EXCEPTIONS \
	} \
	PYBIND11_EMBEDDED_MODULE_IMPL(name) \
	::pybind11::detail::embedded_module PYBIND11_CONCAT(pybind11_module_, name)( \
	PYBIND11_TOSTRING(name), PYBIND11_CONCAT(pybind11_init_impl_, name)); \
	void PYBIND11_CONCAT(pybind11_init_, name)(::pybind11::module_ \
	& variable) // NOLINT(bugprone-macro-parentheses)

	PYBIND11_NAMESPACE_BEGIN(PYBIND11_NAMESPACE)
	PYBIND11_NAMESPACE_BEGIN(detail)

	/// Python 2.7/3.x compatible version of `PyImport_AppendInittab` and error checks.
	struct embedded_module {
	#if PY_MAJOR_VERSION >= 3
	using init_t = PyObject ()();
	#else
	using init_t = void (*)();
	#endif
	embedded_module(const char *name, init_t init) {
	if (Py_IsInitialized() != 0)
	pybind11_fail("Can't add new modules after the interpreter has been initialized");

	auto result = PyImport_AppendInittab(name, init);
	if (result == -1)
	pybind11_fail("Insufficient memory to add a new module");
	}
	};

	struct wide_char_arg_deleter {
	void operator()(wchar_t *ptr) const {
	#if PY_VERSION_HEX >= 0x030500f0
	// API docs: https://docs.python.org/3/c-api/sys.html#c.Py_DecodeLocale
	PyMem_RawFree(ptr);
	#else
	delete[] ptr;
	#endif
	}
	};

	inline wchar_t widen_chars(const char safe_arg) {
	#if PY_VERSION_HEX >= 0x030500f0
	wchar_t *widened_arg = Py_DecodeLocale(safe_arg, nullptr);
	#else
	wchar_t *widened_arg = nullptr;
	# if defined(HAVE_BROKEN_MBSTOWCS) && HAVE_BROKEN_MBSTOWCS
	size_t count = strlen(safe_arg);
	# else
	size_t count = mbstowcs(nullptr, safe_arg, 0);
	# endif
	if (count != static_cast<size_t>(-1)) {
	widened_arg = new wchar_t[count + 1];
	mbstowcs(widened_arg, safe_arg, count + 1);
	}
	#endif
	return widened_arg;
	}

	/// Python 2.x/3.x-compatible version of `PySys_SetArgv`
	inline void set_interpreter_argv(int argc, const char const argv, bool add_program_dir_to_path) {
	// Before it was special-cased in python 3.8, passing an empty or null argv
	// caused a segfault, so we have to reimplement the special case ourselves.
	bool special_case = (argv == nullptr \|\| argc <= 0);

	const char *const empty_argv[]{"\0"};
	const char const safe_argv = special_case ? empty_argv : argv;
	if (special_case)
	argc = 1;

	auto argv_size = static_cast<size_t>(argc);
	#if PY_MAJOR_VERSION >= 3
	// SetArgv* on python 3 takes wchar_t, so we have to convert.
	std::unique_ptr<wchar_t []> widened_argv(new wchar_t [argv_size]);
	std::vector<std::unique_ptr<wchar_t[], wide_char_arg_deleter>> widened_argv_entries;
	widened_argv_entries.reserve(argv_size);
	for (size_t ii = 0; ii < argv_size; ++ii) {
	widened_argv_entries.emplace_back(widen_chars(safe_argv[ii]));
	if (!widened_argv_entries.back()) {
	// A null here indicates a character-encoding failure or the python
	// interpreter out of memory. Give up.
	return;
	}
	widened_argv[ii] = widened_argv_entries.back().get();
	}

	auto pysys_argv = widened_argv.get();
	#else
	// python 2.x
	std::vector<std::string> strings{safe_argv, safe_argv + argv_size};
	std::vector<char *> char_strings{argv_size};
	for (std::size_t i = 0; i < argv_size; ++i)
	char_strings[i] = &strings[i][0];
	char **pysys_argv = char_strings.data();
	#endif

	PySys_SetArgvEx(argc, pysys_argv, static_cast<int>(add_program_dir_to_path));
	}

	PYBIND11_NAMESPACE_END(detail)

	/** \rst
	Initialize the Python interpreter. No other pybind11 or CPython API functions can be
	called before this is done; with the exception of `PYBIND11_EMBEDDED_MODULE`. The
	optional `init_signal_handlers` parameter can be used to skip the registration of
	signal handlers (see the `Python documentation`_ for details). Calling this function
	again after the interpreter has already been initialized is a fatal error.

	If initializing the Python interpreter fails, then the program is terminated. (This
	is controlled by the CPython runtime and is an exception to pybind11's normal behavior
	of throwing exceptions on errors.)

	The remaining optional parameters, `argc`, `argv`, and `add_program_dir_to_path` are
	used to populate ``sys.argv`` and ``sys.path``.
	See the \|PySys_SetArgvEx documentation\|_ for details.

	.. _Python documentation: https://docs.python.org/3/c-api/init.html#c.Py_InitializeEx
	.. \|PySys_SetArgvEx documentation\| replace:: ``PySys_SetArgvEx`` documentation
	.. _PySys_SetArgvEx documentation: https://docs.python.org/3/c-api/init.html#c.PySys_SetArgvEx
	\endrst */
	inline void initialize_interpreter(bool init_signal_handlers = true,
	int argc = 0,
	const char const argv = nullptr,
	bool add_program_dir_to_path = true) {
	if (Py_IsInitialized() != 0)
	pybind11_fail("The interpreter is already running");

	Py_InitializeEx(init_signal_handlers ? 1 : 0);

	detail::set_interpreter_argv(argc, argv, add_program_dir_to_path);
	}

	/** \rst
	Shut down the Python interpreter. No pybind11 or CPython API functions can be called
	after this. In addition, pybind11 objects must not outlive the interpreter:

	.. code-block:: cpp

	{ // BAD
	py::initialize_interpreter();
	auto hello = py::str("Hello, World!");
	py::finalize_interpreter();
	} // <-- BOOM, hello's destructor is called after interpreter shutdown

	{ // GOOD
	py::initialize_interpreter();
	{ // scoped
	auto hello = py::str("Hello, World!");
	} // <-- OK, hello is cleaned up properly
	py::finalize_interpreter();
	}

	{ // BETTER
	py::scoped_interpreter guard{};
	auto hello = py::str("Hello, World!");
	}

	.. warning::

	The interpreter can be restarted by calling `initialize_interpreter` again.
	Modules created using pybind11 can be safely re-initialized. However, Python
	itself cannot completely unload binary extension modules and there are several
	caveats with regard to interpreter restarting. All the details can be found
	in the CPython documentation. In short, not all interpreter memory may be
	freed, either due to reference cycles or user-created global data.

	\endrst */
	inline void finalize_interpreter() {
	handle builtins(PyEval_GetBuiltins());
	const char *id = PYBIND11_INTERNALS_ID;

	// Get the internals pointer (without creating it if it doesn't exist). It's possible for the
	// internals to be created during Py_Finalize() (e.g. if a py::capsule calls `get_internals()`
	// during destruction), so we get the pointer-pointer here and check it after Py_Finalize().
	detail::internals **internals_ptr_ptr = detail::get_internals_pp();
	// It could also be stashed in builtins, so look there too:
	if (builtins.contains(id) && isinstance<capsule>(builtins[id]))
	internals_ptr_ptr = capsule(builtins[id]);

	Py_Finalize();

	if (internals_ptr_ptr) {
	delete *internals_ptr_ptr;
	*internals_ptr_ptr = nullptr;
	}
	}

	/** \rst
	Scope guard version of `initialize_interpreter` and `finalize_interpreter`.
	This a move-only guard and only a single instance can exist.

	See `initialize_interpreter` for a discussion of its constructor arguments.

	.. code-block:: cpp

	#include <pybind11/embed.h>

	int main() {
	py::scoped_interpreter guard{};
	py::print(Hello, World!);
	} // <-- interpreter shutdown
	\endrst */
	class scoped_interpreter {
	public:
	explicit scoped_interpreter(bool init_signal_handlers = true,
	int argc = 0,
	const char const argv = nullptr,
	bool add_program_dir_to_path = true) {
	initialize_interpreter(init_signal_handlers, argc, argv, add_program_dir_to_path);
	}

	scoped_interpreter(const scoped_interpreter &) = delete;
	scoped_interpreter(scoped_interpreter &&other) noexcept { other.is_valid = false; }
	scoped_interpreter &operator=(const scoped_interpreter &) = delete;
	scoped_interpreter &operator=(scoped_interpreter &&) = delete;

	~scoped_interpreter() {
	if (is_valid)
	finalize_interpreter();
	}

	private:
	bool is_valid = true;
	};

	PYBIND11_NAMESPACE_END(PYBIND11_NAMESPACE)