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* feat: require CMake 3.15+ Signed-off-by: Henry Schreiner <henryschreineriii@gmail.com> * Apply suggestions from code review * Update CMakeLists.txt * fix: adapt for CMake 3.30+ (using 3.18+) Signed-off-by: Henry Schreiner <henryschreineriii@gmail.com> --------- Signed-off-by: Henry Schreiner <henryschreineriii@gmail.com>
263 lines
8.3 KiB
ReStructuredText
263 lines
8.3 KiB
ReStructuredText
.. _embedding:
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Embedding the interpreter
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#########################
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While pybind11 is mainly focused on extending Python using C++, it's also
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possible to do the reverse: embed the Python interpreter into a C++ program.
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All of the other documentation pages still apply here, so refer to them for
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general pybind11 usage. This section will cover a few extra things required
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for embedding.
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Getting started
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===============
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A basic executable with an embedded interpreter can be created with just a few
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lines of CMake and the ``pybind11::embed`` target, as shown below. For more
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information, see :doc:`/compiling`.
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.. code-block:: cmake
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cmake_minimum_required(VERSION 3.15...3.30)
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project(example)
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find_package(pybind11 REQUIRED) # or `add_subdirectory(pybind11)`
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add_executable(example main.cpp)
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target_link_libraries(example PRIVATE pybind11::embed)
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The essential structure of the ``main.cpp`` file looks like this:
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.. code-block:: cpp
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#include <pybind11/embed.h> // everything needed for embedding
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namespace py = pybind11;
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int main() {
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py::scoped_interpreter guard{}; // start the interpreter and keep it alive
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py::print("Hello, World!"); // use the Python API
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}
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The interpreter must be initialized before using any Python API, which includes
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all the functions and classes in pybind11. The RAII guard class ``scoped_interpreter``
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takes care of the interpreter lifetime. After the guard is destroyed, the interpreter
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shuts down and clears its memory. No Python functions can be called after this.
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Executing Python code
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=====================
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There are a few different ways to run Python code. One option is to use ``eval``,
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``exec`` or ``eval_file``, as explained in :ref:`eval`. Here is a quick example in
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the context of an executable with an embedded interpreter:
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.. code-block:: cpp
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#include <pybind11/embed.h>
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namespace py = pybind11;
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int main() {
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py::scoped_interpreter guard{};
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py::exec(R"(
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kwargs = dict(name="World", number=42)
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message = "Hello, {name}! The answer is {number}".format(**kwargs)
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print(message)
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)");
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}
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Alternatively, similar results can be achieved using pybind11's API (see
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:doc:`/advanced/pycpp/index` for more details).
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.. code-block:: cpp
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#include <pybind11/embed.h>
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namespace py = pybind11;
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using namespace py::literals;
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int main() {
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py::scoped_interpreter guard{};
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auto kwargs = py::dict("name"_a="World", "number"_a=42);
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auto message = "Hello, {name}! The answer is {number}"_s.format(**kwargs);
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py::print(message);
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}
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The two approaches can also be combined:
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.. code-block:: cpp
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#include <pybind11/embed.h>
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#include <iostream>
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namespace py = pybind11;
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using namespace py::literals;
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int main() {
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py::scoped_interpreter guard{};
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auto locals = py::dict("name"_a="World", "number"_a=42);
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py::exec(R"(
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message = "Hello, {name}! The answer is {number}".format(**locals())
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)", py::globals(), locals);
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auto message = locals["message"].cast<std::string>();
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std::cout << message;
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}
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Importing modules
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=================
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Python modules can be imported using ``module_::import()``:
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.. code-block:: cpp
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py::module_ sys = py::module_::import("sys");
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py::print(sys.attr("path"));
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For convenience, the current working directory is included in ``sys.path`` when
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embedding the interpreter. This makes it easy to import local Python files:
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.. code-block:: python
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"""calc.py located in the working directory"""
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def add(i, j):
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return i + j
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.. code-block:: cpp
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py::module_ calc = py::module_::import("calc");
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py::object result = calc.attr("add")(1, 2);
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int n = result.cast<int>();
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assert(n == 3);
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Modules can be reloaded using ``module_::reload()`` if the source is modified e.g.
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by an external process. This can be useful in scenarios where the application
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imports a user defined data processing script which needs to be updated after
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changes by the user. Note that this function does not reload modules recursively.
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.. _embedding_modules:
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Adding embedded modules
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=======================
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Embedded binary modules can be added using the ``PYBIND11_EMBEDDED_MODULE`` macro.
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Note that the definition must be placed at global scope. They can be imported
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like any other module.
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.. code-block:: cpp
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#include <pybind11/embed.h>
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namespace py = pybind11;
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PYBIND11_EMBEDDED_MODULE(fast_calc, m) {
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// `m` is a `py::module_` which is used to bind functions and classes
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m.def("add", [](int i, int j) {
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return i + j;
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});
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}
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int main() {
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py::scoped_interpreter guard{};
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auto fast_calc = py::module_::import("fast_calc");
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auto result = fast_calc.attr("add")(1, 2).cast<int>();
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assert(result == 3);
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}
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Unlike extension modules where only a single binary module can be created, on
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the embedded side an unlimited number of modules can be added using multiple
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``PYBIND11_EMBEDDED_MODULE`` definitions (as long as they have unique names).
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These modules are added to Python's list of builtins, so they can also be
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imported in pure Python files loaded by the interpreter. Everything interacts
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naturally:
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.. code-block:: python
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"""py_module.py located in the working directory"""
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import cpp_module
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a = cpp_module.a
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b = a + 1
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.. code-block:: cpp
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#include <pybind11/embed.h>
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namespace py = pybind11;
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PYBIND11_EMBEDDED_MODULE(cpp_module, m) {
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m.attr("a") = 1;
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}
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int main() {
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py::scoped_interpreter guard{};
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auto py_module = py::module_::import("py_module");
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auto locals = py::dict("fmt"_a="{} + {} = {}", **py_module.attr("__dict__"));
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assert(locals["a"].cast<int>() == 1);
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assert(locals["b"].cast<int>() == 2);
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py::exec(R"(
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c = a + b
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message = fmt.format(a, b, c)
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)", py::globals(), locals);
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assert(locals["c"].cast<int>() == 3);
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assert(locals["message"].cast<std::string>() == "1 + 2 = 3");
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}
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Interpreter lifetime
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====================
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The Python interpreter shuts down when ``scoped_interpreter`` is destroyed. After
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this, creating a new instance will restart the interpreter. Alternatively, the
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``initialize_interpreter`` / ``finalize_interpreter`` pair of functions can be used
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to directly set the state at any time.
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Modules created with pybind11 can be safely re-initialized after the interpreter
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has been restarted. However, this may not apply to third-party extension modules.
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The issue is that Python itself cannot completely unload extension modules and
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there are several caveats with regard to interpreter restarting. In short, not
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all memory may be freed, either due to Python reference cycles or user-created
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global data. All the details can be found in the CPython documentation.
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.. warning::
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Creating two concurrent ``scoped_interpreter`` guards is a fatal error. So is
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calling ``initialize_interpreter`` for a second time after the interpreter
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has already been initialized.
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Do not use the raw CPython API functions ``Py_Initialize`` and
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``Py_Finalize`` as these do not properly handle the lifetime of
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pybind11's internal data.
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Sub-interpreter support
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=======================
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Creating multiple copies of ``scoped_interpreter`` is not possible because it
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represents the main Python interpreter. Sub-interpreters are something different
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and they do permit the existence of multiple interpreters. This is an advanced
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feature of the CPython API and should be handled with care. pybind11 does not
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currently offer a C++ interface for sub-interpreters, so refer to the CPython
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documentation for all the details regarding this feature.
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We'll just mention a couple of caveats the sub-interpreters support in pybind11:
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1. Sub-interpreters will not receive independent copies of embedded modules.
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Instead, these are shared and modifications in one interpreter may be
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reflected in another.
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2. Managing multiple threads, multiple interpreters and the GIL can be
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challenging and there are several caveats here, even within the pure
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CPython API (please refer to the Python docs for details). As for
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pybind11, keep in mind that ``gil_scoped_release`` and ``gil_scoped_acquire``
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do not take sub-interpreters into account.
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