ext/pybind11/docs/advanced/pycpp/utilities.rst - public/gem5 - Git at Google

 Utilities
 #########

 Using Python's print function in C++
 ====================================

 The usual way to write output in C++ is using ``std::cout`` while in Python one
 would use ``print``. Since these methods use different buffers, mixing them can
 lead to output order issues. To resolve this, pybind11 modules can use the
 :func:`py::print` function which writes to Python's ``sys.stdout`` for consistency.

 Python's ``print`` function is replicated in the C++ API including optional
 keyword arguments ``sep``, ``end``, ``file``, ``flush``. Everything works as
 expected in Python:

 .. code-block:: cpp

     py::print(1, 2.0, "three"); // 1 2.0 three
     py::print(1, 2.0, "three", "sep"_a="-"); // 1-2.0-three

     auto args = py::make_tuple("unpacked", true);
     py::print("->", *args, "end"_a="<-"); // -> unpacked True <-

 .. _ostream_redirect:

 Capturing standard output from ostream
 ======================================

 Often, a library will use the streams ``std::cout`` and ``std::cerr`` to print,
 but this does not play well with Python's standard ``sys.stdout`` and ``sys.stderr``
 redirection. Replacing a library's printing with `py::print <print>` may not
 be feasible. This can be fixed using a guard around the library function that
 redirects output to the corresponding Python streams:

 .. code-block:: cpp

     #include <pybind11/iostream.h>

     ...

     // Add a scoped redirect for your noisy code
     m.def("noisy_func", []() {
         py::scoped_ostream_redirect stream(
             std::cout,                               // std::ostream&
             py::module::import("sys").attr("stdout") // Python output
         );
         call_noisy_func();
     });

 This method respects flushes on the output streams and will flush if needed
 when the scoped guard is destroyed. This allows the output to be redirected in
 real time, such as to a Jupyter notebook. The two arguments, the C++ stream and
 the Python output, are optional, and default to standard output if not given. An
 extra type, `py::scoped_estream_redirect <scoped_estream_redirect>`, is identical
 except for defaulting to ``std::cerr`` and ``sys.stderr``; this can be useful with
 `py::call_guard`, which allows multiple items, but uses the default constructor:

 .. code-block:: py

     // Alternative: Call single function using call guard
     m.def("noisy_func", &call_noisy_function,
           py::call_guard<py::scoped_ostream_redirect,
                          py::scoped_estream_redirect>());

 The redirection can also be done in Python with the addition of a context
 manager, using the `py::add_ostream_redirect() <add_ostream_redirect>` function:

 .. code-block:: cpp

     py::add_ostream_redirect(m, "ostream_redirect");

 The name in Python defaults to ``ostream_redirect`` if no name is passed.  This
 creates the following context manager in Python:

 .. code-block:: python

     with ostream_redirect(stdout=True, stderr=True):
         noisy_function()

 It defaults to redirecting both streams, though you can use the keyword
 arguments to disable one of the streams if needed.

 .. note::

     The above methods will not redirect C-level output to file descriptors, such
     as ``fprintf``. For those cases, you'll need to redirect the file
     descriptors either directly in C or with Python's ``os.dup2`` function
     in an operating-system dependent way.

 .. _eval:

 Evaluating Python expressions from strings and files
 ====================================================

 pybind11 provides the `eval`, `exec` and `eval_file` functions to evaluate
 Python expressions and statements. The following example illustrates how they
 can be used.

 .. code-block:: cpp

     // At beginning of file
     #include <pybind11/eval.h>

     ...

     // Evaluate in scope of main module
     py::object scope = py::module::import("__main__").attr("__dict__");

     // Evaluate an isolated expression
     int result = py::eval("my_variable + 10", scope).cast<int>();

     // Evaluate a sequence of statements
     py::exec(
         "print('Hello')\n"
         "print('world!');",
         scope);

     // Evaluate the statements in an separate Python file on disk
     py::eval_file("script.py", scope);

 C++11 raw string literals are also supported and quite handy for this purpose.
 The only requirement is that the first statement must be on a new line following
 the raw string delimiter ``R"(``, ensuring all lines have common leading indent:

 .. code-block:: cpp

     py::exec(R"(
         x = get_answer()
         if x == 42:
             print('Hello World!')
         else:
             print('Bye!')
         )", scope
     );

 .. note::

     `eval` and `eval_file` accept a template parameter that describes how the
     string/file should be interpreted. Possible choices include ``eval_expr``
     (isolated expression), ``eval_single_statement`` (a single statement, return
     value is always ``none``), and ``eval_statements`` (sequence of statements,
     return value is always ``none``). `eval` defaults to  ``eval_expr``,
     `eval_file` defaults to ``eval_statements`` and `exec` is just a shortcut
     for ``eval<eval_statements>``.
	Utilities
	#########

	Using Python's print function in C++
	====================================

	The usual way to write output in C++ is using ``std::cout`` while in Python one
	would use ``print``. Since these methods use different buffers, mixing them can
	lead to output order issues. To resolve this, pybind11 modules can use the
	:func:`py::print` function which writes to Python's ``sys.stdout`` for consistency.

	Python's ``print`` function is replicated in the C++ API including optional
	keyword arguments ``sep``, ``end``, ``file``, ``flush``. Everything works as
	expected in Python:

	.. code-block:: cpp

	py::print(1, 2.0, "three"); // 1 2.0 three
	py::print(1, 2.0, "three", "sep"_a="-"); // 1-2.0-three

	auto args = py::make_tuple("unpacked", true);
	py::print("->", *args, "end"_a="<-"); // -> unpacked True <-

	.. _ostream_redirect:

	Capturing standard output from ostream
	======================================

	Often, a library will use the streams ``std::cout`` and ``std::cerr`` to print,
	but this does not play well with Python's standard ``sys.stdout`` and ``sys.stderr``
	redirection. Replacing a library's printing with `py::print <print>` may not
	be feasible. This can be fixed using a guard around the library function that
	redirects output to the corresponding Python streams:

	.. code-block:: cpp

	#include <pybind11/iostream.h>

	...

	// Add a scoped redirect for your noisy code
	m.def("noisy_func", []() {
	py::scoped_ostream_redirect stream(
	std::cout, // std::ostream&
	py::module::import("sys").attr("stdout") // Python output
	);
	call_noisy_func();
	});

	This method respects flushes on the output streams and will flush if needed
	when the scoped guard is destroyed. This allows the output to be redirected in
	real time, such as to a Jupyter notebook. The two arguments, the C++ stream and
	the Python output, are optional, and default to standard output if not given. An
	extra type, `py::scoped_estream_redirect <scoped_estream_redirect>`, is identical
	except for defaulting to ``std::cerr`` and ``sys.stderr``; this can be useful with
	`py::call_guard`, which allows multiple items, but uses the default constructor:

	.. code-block:: py

	// Alternative: Call single function using call guard
	m.def("noisy_func", &call_noisy_function,
	py::call_guard<py::scoped_ostream_redirect,
	py::scoped_estream_redirect>());

	The redirection can also be done in Python with the addition of a context
	manager, using the `py::add_ostream_redirect() <add_ostream_redirect>` function:

	.. code-block:: cpp

	py::add_ostream_redirect(m, "ostream_redirect");

	The name in Python defaults to ``ostream_redirect`` if no name is passed. This
	creates the following context manager in Python:

	.. code-block:: python

	with ostream_redirect(stdout=True, stderr=True):
	noisy_function()

	It defaults to redirecting both streams, though you can use the keyword
	arguments to disable one of the streams if needed.

	.. note::

	The above methods will not redirect C-level output to file descriptors, such
	as ``fprintf``. For those cases, you'll need to redirect the file
	descriptors either directly in C or with Python's ``os.dup2`` function
	in an operating-system dependent way.

	.. _eval:

	Evaluating Python expressions from strings and files
	====================================================

	pybind11 provides the `eval`, `exec` and `eval_file` functions to evaluate
	Python expressions and statements. The following example illustrates how they
	can be used.

	.. code-block:: cpp

	// At beginning of file
	#include <pybind11/eval.h>

	...

	// Evaluate in scope of main module
	py::object scope = py::module::import("__main__").attr("__dict__");

	// Evaluate an isolated expression
	int result = py::eval("my_variable + 10", scope).cast<int>();

	// Evaluate a sequence of statements
	py::exec(
	"print('Hello')\n"
	"print('world!');",
	scope);

	// Evaluate the statements in an separate Python file on disk
	py::eval_file("script.py", scope);

	C++11 raw string literals are also supported and quite handy for this purpose.
	The only requirement is that the first statement must be on a new line following
	the raw string delimiter ``R"(``, ensuring all lines have common leading indent:

	.. code-block:: cpp

	py::exec(R"(
	x = get_answer()
	if x == 42:
	print('Hello World!')
	else:
	print('Bye!')
	)", scope
	);

	.. note::

	`eval` and `eval_file` accept a template parameter that describes how the
	string/file should be interpreted. Possible choices include ``eval_expr``
	(isolated expression), ``eval_single_statement`` (a single statement, return
	value is always ``none``), and ``eval_statements`` (sequence of statements,
	return value is always ``none``). `eval` defaults to ``eval_expr``,
	`eval_file` defaults to ``eval_statements`` and `exec` is just a shortcut
	for ``eval<eval_statements>``.