Files
pybind11/tests/test_embed/test_interpreter.cpp
b-pass 95e8f89be1 Support for sub-interpreters (#5564)
* Allow per-interpreter internals/local_internals

* Significant rewrite to avoid using thread_locals as much as possible.

Since we can avoid them by checking this atomic, the cmake config conditional shouldn't be necessary.

The slower path (with thread_locals and extra checks) only comes in when a second interpreter is actually instanciated.

* Add a test for per-interpreter GIL

Uses two extra threads to demonstrate that neither shares a GIL.

* Fix for nonconforming std::atomic constructors on some compilers

* style: pre-commit fixes

* Fix initializer to make MSVC happy.

* Switch to gil_scoped_acquire_simple, get rid of old copy of it from internals.h

* Use the PyThreadState's interp member rather than the thread state itself.

* Be more explicit about the type of the internalspp

* Suggested renamings and rewordings

* Rename find_internals_pp and change it to take in the state dict reference

* Use the old raise_from instead of pybind11_fail

* Move most of the internals initialization into its constructor.

* Move round_up_to_next_pow2 function upwards

* Remove redundant forward decl

* Add a python-driven subinterpreter test

* Disable the python subinterpreter test on emscripten

Can't load the native-built cpp modules.

* Switch the internals pointer pointer to a unique_ptr pointer

* Spelling

* Fix clang-tidy warning, compare pointer to nullptr

* Rename get_interpreter_counter to get_num_interpreters_seen

* Try simplifying the test's cmake set_target_properties

* Replace mod_* tags with a single tag w/enum

Update tests accordingly

* Add a test for shared-GIL (legacy) subinterpreters

* Update test to work around differences in the various versions of interpreters modules

* Fix unused parameter

* Rename tests and associated test modules.

* Switch get_internals_pp to a template function

* Rename curtstate to cur_tstate

* refactor: use simpler names

Signed-off-by: Henry Schreiner <henryschreineriii@gmail.com>

* style: pre-commit fixes

* fix: return class, not enum

Co-authored-by: Ralf W. Grosse-Kunstleve <rwgkio@gmail.com>
Signed-off-by: Henry Schreiner <henryschreineriii@gmail.com>

* Have to join these threads to make sure they are totally done before the test returns.

* Wrap module_def initialization in a static so it only happens once.

If it happens concurrently in multiple threads, badness ensues....

* style: pre-commit fixes

---------

Signed-off-by: Henry Schreiner <henryschreineriii@gmail.com>
Co-authored-by: pre-commit-ci[bot] <66853113+pre-commit-ci[bot]@users.noreply.github.com>
Co-authored-by: Henry Schreiner <henryschreineriii@gmail.com>
Co-authored-by: Ralf W. Grosse-Kunstleve <rwgkio@gmail.com>
2025-05-14 00:59:44 -07:00

731 lines
26 KiB
C++

#include <pybind11/embed.h>
// Silence MSVC C++17 deprecation warning from Catch regarding std::uncaught_exceptions (up to
// catch 2.0.1; this should be fixed in the next catch release after 2.0.1).
PYBIND11_WARNING_DISABLE_MSVC(4996)
#include <catch.hpp>
#include <cstdlib>
#include <fstream>
#include <functional>
#include <thread>
#include <utility>
namespace py = pybind11;
using namespace py::literals;
size_t get_sys_path_size() {
auto sys_path = py::module::import("sys").attr("path");
return py::len(sys_path);
}
class Widget {
public:
explicit Widget(std::string message) : message(std::move(message)) {}
virtual ~Widget() = default;
std::string the_message() const { return message; }
virtual int the_answer() const = 0;
virtual std::string argv0() const = 0;
private:
std::string message;
};
class PyWidget final : public Widget {
using Widget::Widget;
int the_answer() const override { PYBIND11_OVERRIDE_PURE(int, Widget, the_answer); }
std::string argv0() const override { PYBIND11_OVERRIDE_PURE(std::string, Widget, argv0); }
};
class test_override_cache_helper {
public:
virtual int func() { return 0; }
test_override_cache_helper() = default;
virtual ~test_override_cache_helper() = default;
// Non-copyable
test_override_cache_helper &operator=(test_override_cache_helper const &Right) = delete;
test_override_cache_helper(test_override_cache_helper const &Copy) = delete;
};
class test_override_cache_helper_trampoline : public test_override_cache_helper {
int func() override { PYBIND11_OVERRIDE(int, test_override_cache_helper, func); }
};
PYBIND11_EMBEDDED_MODULE(widget_module, m) {
py::class_<Widget, PyWidget>(m, "Widget")
.def(py::init<std::string>())
.def_property_readonly("the_message", &Widget::the_message);
m.def("add", [](int i, int j) { return i + j; });
auto sub = m.def_submodule("sub");
sub.def("add", [](int i, int j) { return i + j; });
}
PYBIND11_EMBEDDED_MODULE(trampoline_module, m) {
py::class_<test_override_cache_helper,
test_override_cache_helper_trampoline,
std::shared_ptr<test_override_cache_helper>>(m, "test_override_cache_helper")
.def(py::init_alias<>())
.def("func", &test_override_cache_helper::func);
}
PYBIND11_EMBEDDED_MODULE(throw_exception, ) { throw std::runtime_error("C++ Error"); }
PYBIND11_EMBEDDED_MODULE(throw_error_already_set, ) {
auto d = py::dict();
d["missing"].cast<py::object>();
}
TEST_CASE("PYTHONPATH is used to update sys.path") {
// The setup for this TEST_CASE is in catch.cpp!
auto sys_path = py::str(py::module_::import("sys").attr("path")).cast<std::string>();
REQUIRE_THAT(sys_path,
Catch::Matchers::Contains("pybind11_test_embed_PYTHONPATH_2099743835476552"));
}
TEST_CASE("Pass classes and data between modules defined in C++ and Python") {
auto module_ = py::module_::import("test_interpreter");
REQUIRE(py::hasattr(module_, "DerivedWidget"));
auto locals = py::dict("hello"_a = "Hello, World!", "x"_a = 5, **module_.attr("__dict__"));
py::exec(R"(
widget = DerivedWidget("{} - {}".format(hello, x))
message = widget.the_message
)",
py::globals(),
locals);
REQUIRE(locals["message"].cast<std::string>() == "Hello, World! - 5");
auto py_widget = module_.attr("DerivedWidget")("The question");
auto message = py_widget.attr("the_message");
REQUIRE(message.cast<std::string>() == "The question");
const auto &cpp_widget = py_widget.cast<const Widget &>();
REQUIRE(cpp_widget.the_answer() == 42);
}
TEST_CASE("Override cache") {
auto module_ = py::module_::import("test_trampoline");
REQUIRE(py::hasattr(module_, "func"));
REQUIRE(py::hasattr(module_, "func2"));
auto locals = py::dict(**module_.attr("__dict__"));
int i = 0;
for (; i < 1500; ++i) {
std::shared_ptr<test_override_cache_helper> p_obj;
std::shared_ptr<test_override_cache_helper> p_obj2;
py::object loc_inst = locals["func"]();
p_obj = py::cast<std::shared_ptr<test_override_cache_helper>>(loc_inst);
int ret = p_obj->func();
REQUIRE(ret == 42);
loc_inst = locals["func2"]();
p_obj2 = py::cast<std::shared_ptr<test_override_cache_helper>>(loc_inst);
p_obj2->func();
}
}
TEST_CASE("Import error handling") {
REQUIRE_NOTHROW(py::module_::import("widget_module"));
REQUIRE_THROWS_WITH(py::module_::import("throw_exception"), "ImportError: C++ Error");
REQUIRE_THROWS_WITH(py::module_::import("throw_error_already_set"),
Catch::Contains("ImportError: initialization failed"));
auto locals = py::dict("is_keyerror"_a = false, "message"_a = "not set");
py::exec(R"(
try:
import throw_error_already_set
except ImportError as e:
is_keyerror = type(e.__cause__) == KeyError
message = str(e.__cause__)
)",
py::globals(),
locals);
REQUIRE(locals["is_keyerror"].cast<bool>() == true);
REQUIRE(locals["message"].cast<std::string>() == "'missing'");
}
TEST_CASE("There can be only one interpreter") {
static_assert(std::is_move_constructible<py::scoped_interpreter>::value, "");
static_assert(!std::is_move_assignable<py::scoped_interpreter>::value, "");
static_assert(!std::is_copy_constructible<py::scoped_interpreter>::value, "");
static_assert(!std::is_copy_assignable<py::scoped_interpreter>::value, "");
REQUIRE_THROWS_WITH(py::initialize_interpreter(), "The interpreter is already running");
REQUIRE_THROWS_WITH(py::scoped_interpreter(), "The interpreter is already running");
py::finalize_interpreter();
REQUIRE_NOTHROW(py::scoped_interpreter());
{
auto pyi1 = py::scoped_interpreter();
auto pyi2 = std::move(pyi1);
}
py::initialize_interpreter();
}
#if PY_VERSION_HEX >= PYBIND11_PYCONFIG_SUPPORT_PY_VERSION_HEX
TEST_CASE("Custom PyConfig") {
py::finalize_interpreter();
PyConfig config;
PyConfig_InitPythonConfig(&config);
REQUIRE_NOTHROW(py::scoped_interpreter{&config});
{
py::scoped_interpreter p{&config};
REQUIRE(py::module_::import("widget_module").attr("add")(1, 41).cast<int>() == 42);
}
py::initialize_interpreter();
}
TEST_CASE("scoped_interpreter with PyConfig_InitIsolatedConfig and argv") {
py::finalize_interpreter();
{
PyConfig config;
PyConfig_InitIsolatedConfig(&config);
char *argv[] = {strdup("a.out")};
py::scoped_interpreter argv_scope{&config, 1, argv};
std::free(argv[0]);
auto module = py::module::import("test_interpreter");
auto py_widget = module.attr("DerivedWidget")("The question");
const auto &cpp_widget = py_widget.cast<const Widget &>();
REQUIRE(cpp_widget.argv0() == "a.out");
}
py::initialize_interpreter();
}
TEST_CASE("scoped_interpreter with PyConfig_InitPythonConfig and argv") {
py::finalize_interpreter();
{
PyConfig config;
PyConfig_InitPythonConfig(&config);
// `initialize_interpreter() overrides the default value for config.parse_argv (`1`) by
// changing it to `0`. This test exercises `scoped_interpreter` with the default config.
char *argv[] = {strdup("a.out"), strdup("arg1")};
py::scoped_interpreter argv_scope(&config, 2, argv);
std::free(argv[0]);
std::free(argv[1]);
auto module = py::module::import("test_interpreter");
auto py_widget = module.attr("DerivedWidget")("The question");
const auto &cpp_widget = py_widget.cast<const Widget &>();
REQUIRE(cpp_widget.argv0() == "arg1");
}
py::initialize_interpreter();
}
#endif
TEST_CASE("Add program dir to path pre-PyConfig") {
py::finalize_interpreter();
size_t path_size_add_program_dir_to_path_false = 0;
{
py::scoped_interpreter scoped_interp{true, 0, nullptr, false};
path_size_add_program_dir_to_path_false = get_sys_path_size();
}
{
py::scoped_interpreter scoped_interp{};
REQUIRE(get_sys_path_size() == path_size_add_program_dir_to_path_false + 1);
}
py::initialize_interpreter();
}
#if PY_VERSION_HEX >= PYBIND11_PYCONFIG_SUPPORT_PY_VERSION_HEX
TEST_CASE("Add program dir to path using PyConfig") {
py::finalize_interpreter();
size_t path_size_add_program_dir_to_path_false = 0;
{
PyConfig config;
PyConfig_InitPythonConfig(&config);
py::scoped_interpreter scoped_interp{&config, 0, nullptr, false};
path_size_add_program_dir_to_path_false = get_sys_path_size();
}
{
PyConfig config;
PyConfig_InitPythonConfig(&config);
py::scoped_interpreter scoped_interp{&config};
REQUIRE(get_sys_path_size() == path_size_add_program_dir_to_path_false + 1);
}
py::initialize_interpreter();
}
#endif
bool has_state_dict_internals_obj() {
py::dict state = py::detail::get_python_state_dict();
return state.contains(PYBIND11_INTERNALS_ID);
}
bool has_pybind11_internals_static() {
auto *&ipp = py::detail::get_internals_pp<py::detail::internals>();
return (ipp != nullptr) && *ipp;
}
uintptr_t get_details_as_uintptr() {
return reinterpret_cast<uintptr_t>(
py::detail::get_internals_pp<py::detail::internals>()->get());
}
TEST_CASE("Restart the interpreter") {
// Verify pre-restart state.
REQUIRE(py::module_::import("widget_module").attr("add")(1, 2).cast<int>() == 3);
REQUIRE(has_state_dict_internals_obj());
REQUIRE(has_pybind11_internals_static());
REQUIRE(py::module_::import("external_module").attr("A")(123).attr("value").cast<int>()
== 123);
// local and foreign module internals should point to the same internals:
REQUIRE(get_details_as_uintptr()
== py::module_::import("external_module").attr("internals_at")().cast<uintptr_t>());
// Restart the interpreter.
py::finalize_interpreter();
REQUIRE(Py_IsInitialized() == 0);
py::initialize_interpreter();
REQUIRE(Py_IsInitialized() == 1);
// Internals are deleted after a restart.
REQUIRE_FALSE(has_state_dict_internals_obj());
REQUIRE_FALSE(has_pybind11_internals_static());
pybind11::detail::get_internals();
REQUIRE(has_state_dict_internals_obj());
REQUIRE(has_pybind11_internals_static());
REQUIRE(get_details_as_uintptr()
== py::module_::import("external_module").attr("internals_at")().cast<uintptr_t>());
// Make sure that an interpreter with no get_internals() created until finalize still gets the
// internals destroyed
py::finalize_interpreter();
py::initialize_interpreter();
bool ran = false;
py::module_::import("__main__").attr("internals_destroy_test")
= py::capsule(&ran, [](void *ran) {
py::detail::get_internals();
REQUIRE(has_state_dict_internals_obj());
REQUIRE(has_pybind11_internals_static());
*static_cast<bool *>(ran) = true;
});
REQUIRE_FALSE(has_state_dict_internals_obj());
REQUIRE_FALSE(has_pybind11_internals_static());
REQUIRE_FALSE(ran);
py::finalize_interpreter();
REQUIRE(ran);
REQUIRE_FALSE(has_pybind11_internals_static());
py::initialize_interpreter();
REQUIRE_FALSE(has_state_dict_internals_obj());
REQUIRE_FALSE(has_pybind11_internals_static());
// C++ modules can be reloaded.
auto cpp_module = py::module_::import("widget_module");
REQUIRE(cpp_module.attr("add")(1, 2).cast<int>() == 3);
// Also verify submodules work
REQUIRE(cpp_module.attr("sub").attr("add")(1, 41).cast<int>() == 42);
// C++ type information is reloaded and can be used in python modules.
auto py_module = py::module_::import("test_interpreter");
auto py_widget = py_module.attr("DerivedWidget")("Hello after restart");
REQUIRE(py_widget.attr("the_message").cast<std::string>() == "Hello after restart");
}
TEST_CASE("Subinterpreter") {
py::module_::import("external_module"); // in the main interpreter
// Add tags to the modules in the main interpreter and test the basics.
py::module_::import("__main__").attr("main_tag") = "main interpreter";
{
auto m = py::module_::import("widget_module");
m.attr("extension_module_tag") = "added to module in main interpreter";
REQUIRE(m.attr("add")(1, 2).cast<int>() == 3);
}
REQUIRE(has_state_dict_internals_obj());
REQUIRE(has_pybind11_internals_static());
/// Create and switch to a subinterpreter.
auto *main_tstate = PyThreadState_Get();
auto *sub_tstate = Py_NewInterpreter();
py::detail::get_num_interpreters_seen()++;
// Subinterpreters get their own copy of builtins.
REQUIRE_FALSE(has_state_dict_internals_obj());
#if defined(PYBIND11_SUBINTERPRETER_SUPPORT) && PY_VERSION_HEX >= 0x030C0000
// internals hasn't been populated yet, but will be different for the subinterpreter
REQUIRE_FALSE(has_pybind11_internals_static());
py::list(py::module_::import("sys").attr("path")).append(py::str("."));
auto ext_int = py::module_::import("external_module").attr("internals_at")().cast<uintptr_t>();
py::detail::get_internals();
REQUIRE(has_pybind11_internals_static());
REQUIRE(get_details_as_uintptr() == ext_int);
#else
// This static is still defined
REQUIRE(has_pybind11_internals_static());
#endif
// Modules tags should be gone.
REQUIRE_FALSE(py::hasattr(py::module_::import("__main__"), "tag"));
{
auto m = py::module_::import("widget_module");
REQUIRE_FALSE(py::hasattr(m, "extension_module_tag"));
// Function bindings should still work.
REQUIRE(m.attr("add")(1, 2).cast<int>() == 3);
}
// The subinterpreter now has internals populated since we imported a pybind11 module
REQUIRE(has_pybind11_internals_static());
// Restore main interpreter.
Py_EndInterpreter(sub_tstate);
py::detail::get_num_interpreters_seen() = 1;
PyThreadState_Swap(main_tstate);
REQUIRE(py::hasattr(py::module_::import("__main__"), "main_tag"));
REQUIRE(py::hasattr(py::module_::import("widget_module"), "extension_module_tag"));
REQUIRE(has_state_dict_internals_obj());
}
#if defined(PYBIND11_SUBINTERPRETER_SUPPORT)
TEST_CASE("Multiple Subinterpreters") {
// Make sure the module is in the main interpreter and save its pointer
auto *main_ext = py::module_::import("external_module").ptr();
auto main_int
= py::module_::import("external_module").attr("internals_at")().cast<uintptr_t>();
py::module_::import("external_module").attr("multi_interp") = "1";
auto *main_tstate = PyThreadState_Get();
/// Create and switch to a subinterpreter.
auto *sub1_tstate = Py_NewInterpreter();
py::detail::get_num_interpreters_seen()++;
py::list(py::module_::import("sys").attr("path")).append(py::str("."));
// The subinterpreter has its own copy of this module which is completely separate from main
auto *sub1_ext = py::module_::import("external_module").ptr();
REQUIRE(sub1_ext != main_ext);
REQUIRE_FALSE(py::hasattr(py::module_::import("external_module"), "multi_interp"));
py::module_::import("external_module").attr("multi_interp") = "2";
// The subinterpreter also has its own internals
auto sub1_int
= py::module_::import("external_module").attr("internals_at")().cast<uintptr_t>();
REQUIRE(sub1_int != main_int);
// Create another interpreter
auto *sub2_tstate = Py_NewInterpreter();
py::detail::get_num_interpreters_seen()++;
py::list(py::module_::import("sys").attr("path")).append(py::str("."));
// The second subinterpreter is separate from both main and the other subinterpreter
auto *sub2_ext = py::module_::import("external_module").ptr();
REQUIRE(sub2_ext != main_ext);
REQUIRE(sub2_ext != sub1_ext);
REQUIRE_FALSE(py::hasattr(py::module_::import("external_module"), "multi_interp"));
py::module_::import("external_module").attr("multi_interp") = "3";
// The subinterpreter also has its own internals
auto sub2_int
= py::module_::import("external_module").attr("internals_at")().cast<uintptr_t>();
REQUIRE(sub2_int != main_int);
REQUIRE(sub2_int != sub1_int);
PyThreadState_Swap(sub1_tstate); // go back to sub1
REQUIRE(py::cast<std::string>(py::module_::import("external_module").attr("multi_interp"))
== "2");
PyThreadState_Swap(main_tstate); // go back to main
auto post_int
= py::module_::import("external_module").attr("internals_at")().cast<uintptr_t>();
// Make sure internals went back the way it was before
REQUIRE(main_int == post_int);
REQUIRE(py::cast<std::string>(py::module_::import("external_module").attr("multi_interp"))
== "1");
PyThreadState_Swap(sub1_tstate);
Py_EndInterpreter(sub1_tstate);
PyThreadState_Swap(sub2_tstate);
Py_EndInterpreter(sub2_tstate);
py::detail::get_num_interpreters_seen() = 1;
PyThreadState_Swap(main_tstate);
}
#endif
#if defined(Py_MOD_PER_INTERPRETER_GIL_SUPPORTED) && defined(PYBIND11_SUBINTERPRETER_SUPPORT)
TEST_CASE("Per-Subinterpreter GIL") {
auto main_int
= py::module_::import("external_module").attr("internals_at")().cast<uintptr_t>();
std::atomic<int> started, sync, failure;
started = 0;
sync = 0;
failure = 0;
// REQUIRE throws on failure, so we can't use it within the thread
# define T_REQUIRE(status) \
do { \
assert(status); \
if (!(status)) \
++failure; \
} while (0)
auto &&thread_main = [&](int num) {
while (started == 0)
std::this_thread::sleep_for(std::chrono::microseconds(1));
++started;
py::gil_scoped_acquire gil;
auto main_tstate = PyThreadState_Get();
// we have the GIL, we can access the main interpreter
auto t_int
= py::module_::import("external_module").attr("internals_at")().cast<uintptr_t>();
T_REQUIRE(t_int == main_int);
py::module_::import("external_module").attr("multi_interp") = "1";
PyThreadState *sub = nullptr;
PyInterpreterConfig cfg;
memset(&cfg, 0, sizeof(cfg));
cfg.check_multi_interp_extensions = 1;
cfg.gil = PyInterpreterConfig_OWN_GIL;
auto status = Py_NewInterpreterFromConfig(&sub, &cfg);
T_REQUIRE(!PyStatus_IsError(status));
py::detail::get_num_interpreters_seen()++;
py::list(py::module_::import("sys").attr("path")).append(py::str("."));
// we have switched to the new interpreter and released the main gil
// widget_module did not provide the mod_per_interpreter_gil tag, so it cannot be imported
bool caught = false;
try {
py::module_::import("widget_module");
} catch (pybind11::error_already_set &pe) {
T_REQUIRE(pe.matches(PyExc_ImportError));
std::string msg(pe.what());
T_REQUIRE(msg.find("does not support loading in subinterpreters")
!= std::string::npos);
caught = true;
}
T_REQUIRE(caught);
T_REQUIRE(!py::hasattr(py::module_::import("external_module"), "multi_interp"));
py::module_::import("external_module").attr("multi_interp") = std::to_string(num);
// wait for something to set sync to our thread number
// we are holding our subinterpreter's GIL
while (sync != num)
std::this_thread::sleep_for(std::chrono::microseconds(1));
// now change it so the next thread can mvoe on
++sync;
// but keep holding the GIL until after the next thread moves on as well
while (sync == num + 1)
std::this_thread::sleep_for(std::chrono::microseconds(1));
// one last check before quitting the thread, the internals should be different
auto sub_int
= py::module_::import("external_module").attr("internals_at")().cast<uintptr_t>();
T_REQUIRE(sub_int != main_int);
Py_EndInterpreter(sub);
PyThreadState_Swap(
main_tstate); // switch back so the scoped_acquire can release the GIL properly
};
std::thread t1(thread_main, 1);
std::thread t2(thread_main, 2);
// we spawned two threads, at this point they are both waiting for started to increase
++started;
// ok now wait for the threads to start
while (started != 3)
std::this_thread::sleep_for(std::chrono::microseconds(1));
// we still hold the main GIL, at this point both threads are waiting on the main GIL
// IN THE CASE of free threading, the threads are waiting on sync (because there is no GIL)
// IF the below code hangs in one of the wait loops, then the child thread GIL behavior did not
// function as expected.
{
// release the GIL and allow the threads to run
py::gil_scoped_release nogil;
// the threads are now waiting on the sync
REQUIRE(sync == 0);
// this will trigger thread 1 and then advance and trigger 2 and then advance
sync = 1;
// wait for thread 2 to advance
while (sync != 3)
std::this_thread::sleep_for(std::chrono::microseconds(1));
// we know now that thread 1 has run and may be finishing
// and thread 2 is waiting for permission to advance
// so we move sync so that thread 2 can finish executing
++sync;
// now wait for both threads to complete
t1.join();
t2.join();
}
// now we have the gil again, sanity check
REQUIRE(py::cast<std::string>(py::module_::import("external_module").attr("multi_interp"))
== "1");
// the threads are stopped. we can now lower this for the rest of the test
py::detail::get_num_interpreters_seen() = 1;
// make sure nothing unexpected happened inside the threads, now that they are completed
REQUIRE(failure == 0);
# undef T_REQUIRE
}
#endif
TEST_CASE("Execution frame") {
// When the interpreter is embedded, there is no execution frame, but `py::exec`
// should still function by using reasonable globals: `__main__.__dict__`.
py::exec("var = dict(number=42)");
REQUIRE(py::globals()["var"]["number"].cast<int>() == 42);
}
TEST_CASE("Threads") {
// Restart interpreter to ensure threads are not initialized
py::finalize_interpreter();
py::initialize_interpreter();
REQUIRE_FALSE(has_pybind11_internals_static());
constexpr auto num_threads = 10;
auto locals = py::dict("count"_a = 0);
{
py::gil_scoped_release gil_release{};
auto threads = std::vector<std::thread>();
for (auto i = 0; i < num_threads; ++i) {
threads.emplace_back([&]() {
py::gil_scoped_acquire gil{};
locals["count"] = locals["count"].cast<int>() + 1;
});
}
for (auto &thread : threads) {
thread.join();
}
}
REQUIRE(locals["count"].cast<int>() == num_threads);
}
// Scope exit utility https://stackoverflow.com/a/36644501/7255855
struct scope_exit {
std::function<void()> f_;
explicit scope_exit(std::function<void()> f) noexcept : f_(std::move(f)) {}
~scope_exit() {
if (f_) {
f_();
}
}
};
TEST_CASE("Reload module from file") {
// Disable generation of cached bytecode (.pyc files) for this test, otherwise
// Python might pick up an old version from the cache instead of the new versions
// of the .py files generated below
auto sys = py::module_::import("sys");
bool dont_write_bytecode = sys.attr("dont_write_bytecode").cast<bool>();
sys.attr("dont_write_bytecode") = true;
// Reset the value at scope exit
scope_exit reset_dont_write_bytecode(
[&]() { sys.attr("dont_write_bytecode") = dont_write_bytecode; });
std::string module_name = "test_module_reload";
std::string module_file = module_name + ".py";
// Create the module .py file
std::ofstream test_module(module_file);
test_module << "def test():\n";
test_module << " return 1\n";
test_module.close();
// Delete the file at scope exit
scope_exit delete_module_file([&]() { std::remove(module_file.c_str()); });
// Import the module from file
auto module_ = py::module_::import(module_name.c_str());
int result = module_.attr("test")().cast<int>();
REQUIRE(result == 1);
// Update the module .py file with a small change
test_module.open(module_file);
test_module << "def test():\n";
test_module << " return 2\n";
test_module.close();
// Reload the module
module_.reload();
result = module_.attr("test")().cast<int>();
REQUIRE(result == 2);
}
TEST_CASE("sys.argv gets initialized properly") {
py::finalize_interpreter();
{
py::scoped_interpreter default_scope;
auto module = py::module::import("test_interpreter");
auto py_widget = module.attr("DerivedWidget")("The question");
const auto &cpp_widget = py_widget.cast<const Widget &>();
REQUIRE(cpp_widget.argv0().empty());
}
{
char *argv[] = {strdup("a.out")};
py::scoped_interpreter argv_scope(true, 1, argv);
std::free(argv[0]);
auto module = py::module::import("test_interpreter");
auto py_widget = module.attr("DerivedWidget")("The question");
const auto &cpp_widget = py_widget.cast<const Widget &>();
REQUIRE(cpp_widget.argv0() == "a.out");
}
py::initialize_interpreter();
}
TEST_CASE("make_iterator can be called before then after finalizing an interpreter") {
// Reproduction of issue #2101 (https://github.com/pybind/pybind11/issues/2101)
py::finalize_interpreter();
std::vector<int> container;
{
pybind11::scoped_interpreter g;
auto iter = pybind11::make_iterator(container.begin(), container.end());
}
REQUIRE_NOTHROW([&]() {
pybind11::scoped_interpreter g;
auto iter = pybind11::make_iterator(container.begin(), container.end());
}());
py::initialize_interpreter();
}