Using C libraries¶
Apart from writing fast code, one of the main use cases of Cython is to call external C libraries from Python code. As Cython code compiles down to C code itself, it is actually trivial to call C functions directly in the code. The following gives a complete example for using (and wrapping) an external C library in Cython code, including appropriate error handling and considerations about designing a suitable API for Python and Cython code.
Imagine you need an efficient way to store integer values in a FIFO
queue. Since memory really matters, and the values are actually
coming from C code, you cannot afford to create and store Python
int
objects in a list or deque. So you look out for a queue
implementation in C.
After some web search, you find the C-algorithms library [CAlg] and decide to use its double ended queue implementation. To make the handling easier, however, you decide to wrap it in a Python extension type that can encapsulate all memory management.
- CAlg
Simon Howard, C Algorithms library, http://c-algorithms.sourceforge.net/
Defining external declarations¶
You can download CAlg here.
The C API of the queue implementation, which is defined in the header
file c-algorithms/src/queue.h
, essentially looks like this:
/* queue.h */
typedef struct _Queue Queue;
typedef void *QueueValue;
Queue *queue_new(void);
void queue_free(Queue *queue);
int queue_push_head(Queue *queue, QueueValue data);
QueueValue queue_pop_head(Queue *queue);
QueueValue queue_peek_head(Queue *queue);
int queue_push_tail(Queue *queue, QueueValue data);
QueueValue queue_pop_tail(Queue *queue);
QueueValue queue_peek_tail(Queue *queue);
int queue_is_empty(Queue *queue);
To get started, the first step is to redefine the C API in a .pxd
file, say, cqueue.pxd
:
# cqueue.pxd
cdef extern from "c-algorithms/src/queue.h":
ctypedef struct Queue:
pass
ctypedef void* QueueValue
Queue* queue_new()
void queue_free(Queue* queue)
int queue_push_head(Queue* queue, QueueValue data)
QueueValue queue_pop_head(Queue* queue)
QueueValue queue_peek_head(Queue* queue)
int queue_push_tail(Queue* queue, QueueValue data)
QueueValue queue_pop_tail(Queue* queue)
QueueValue queue_peek_tail(Queue* queue)
bint queue_is_empty(Queue* queue)
Note how these declarations are almost identical to the header file declarations, so you can often just copy them over. However, you do not need to provide all declarations as above, just those that you use in your code or in other declarations, so that Cython gets to see a sufficient and consistent subset of them. Then, consider adapting them somewhat to make them more comfortable to work with in Cython.
Specifically, you should take care of choosing good argument names for the C functions, as Cython allows you to pass them as keyword arguments. Changing them later on is a backwards incompatible API modification. Choosing good names right away will make these functions more pleasant to work with from Cython code.
One noteworthy difference to the header file that we use above is the
declaration of the Queue
struct in the first line. Queue
is
in this case used as an opaque handle; only the library that is
called knows what is really inside. Since no Cython code needs to
know the contents of the struct, we do not need to declare its
contents, so we simply provide an empty definition (as we do not want
to declare the _Queue
type which is referenced in the C header)
1.
- 1
There’s a subtle difference between
cdef struct Queue: pass
andctypedef struct Queue: pass
. The former declares a type which is referenced in C code asstruct Queue
, while the latter is referenced in C asQueue
. This is a C language quirk that Cython is not able to hide. Most modern C libraries use thectypedef
kind of struct.
Another exception is the last line. The integer return value of the
queue_is_empty()
function is actually a C boolean value, i.e. the
only interesting thing about it is whether it is non-zero or zero,
indicating if the queue is empty or not. This is best expressed by
Cython’s bint
type, which is a normal int
type when used in C
but maps to Python’s boolean values True
and False
when
converted to a Python object. This way of tightening declarations in
a .pxd
file can often simplify the code that uses them.
It is good practice to define one .pxd
file for each library that
you use, and sometimes even for each header file (or functional group)
if the API is large. That simplifies their reuse in other projects.
Sometimes, you may need to use C functions from the standard C
library, or want to call C-API functions from CPython directly. For
common needs like this, Cython ships with a set of standard .pxd
files that provide these declarations in a readily usable way that is
adapted to their use in Cython. The main packages are cpython
,
libc
and libcpp
. The NumPy library also has a standard
.pxd
file numpy
, as it is often used in Cython code. See
Cython’s Cython/Includes/
source package for a complete list of
provided .pxd
files.
Writing a wrapper class¶
After declaring our C library’s API, we can start to design the Queue
class that should wrap the C queue. It will live in a file called
queue.pyx
. 2
- 2
Note that the name of the
.pyx
file must be different from thecqueue.pxd
file with declarations from the C library, as both do not describe the same code. A.pxd
file next to a.pyx
file with the same name defines exported declarations for code in the.pyx
file. As thecqueue.pxd
file contains declarations of a regular C library, there must not be a.pyx
file with the same name that Cython associates with it.
Here is a first start for the Queue class:
# queue.pyx
cimport cqueue
cdef class Queue:
cdef cqueue.Queue* _c_queue
def __cinit__(self):
self._c_queue = cqueue.queue_new()
Note that it says __cinit__
rather than __init__
. While
__init__
is available as well, it is not guaranteed to be run (for
instance, one could create a subclass and forget to call the
ancestor’s constructor). Because not initializing C pointers often
leads to hard crashes of the Python interpreter, Cython provides
__cinit__
which is always called immediately on construction,
before CPython even considers calling __init__
, and which
therefore is the right place to initialise cdef
fields of the new
instance. However, as __cinit__
is called during object
construction, self
is not fully constructed yet, and one must
avoid doing anything with self
but assigning to cdef
fields.
Note also that the above method takes no parameters, although subtypes
may want to accept some. A no-arguments __cinit__()
method is a
special case here that simply does not receive any parameters that
were passed to a constructor, so it does not prevent subclasses from
adding parameters. If parameters are used in the signature of
__cinit__()
, they must match those of any declared __init__
method of classes in the class hierarchy that are used to instantiate
the type.
Memory management¶
Before we continue implementing the other methods, it is important to
understand that the above implementation is not safe. In case
anything goes wrong in the call to queue_new()
, this code will
simply swallow the error, so we will likely run into a crash later on.
According to the documentation of the queue_new()
function, the
only reason why the above can fail is due to insufficient memory. In
that case, it will return NULL
, whereas it would normally return a
pointer to the new queue.
The Python way to get out of this is to raise a MemoryError
3.
We can thus change the init function as follows:
# queue.pyx
cimport cqueue
cdef class Queue:
cdef cqueue.Queue* _c_queue
def __cinit__(self):
self._c_queue = cqueue.queue_new()
if self._c_queue is NULL:
raise MemoryError()
- 3
In the specific case of a
MemoryError
, creating a new exception instance in order to raise it may actually fail because we are running out of memory. Luckily, CPython provides a C-API functionPyErr_NoMemory()
that safely raises the right exception for us. Cython automatically substitutes this C-API call whenever you writeraise MemoryError
orraise MemoryError()
. If you use an older version, you have to cimport the C-API function from the standard packagecpython.exc
and call it directly.
The next thing to do is to clean up when the Queue instance is no
longer used (i.e. all references to it have been deleted). To this
end, CPython provides a callback that Cython makes available as a
special method __dealloc__()
. In our case, all we have to do is
to free the C Queue, but only if we succeeded in initialising it in
the init method:
def __dealloc__(self):
if self._c_queue is not NULL:
cqueue.queue_free(self._c_queue)
Compiling and linking¶
At this point, we have a working Cython module that we can test. To
compile it, we need to configure a setup.py
script for distutils.
Here is the most basic script for compiling a Cython module:
from distutils.core import setup
from distutils.extension import Extension
from Cython.Build import cythonize
setup(
ext_modules = cythonize([Extension("queue", ["queue.pyx"])])
)
To build against the external C library, we need to make sure Cython finds the necessary libraries.
There are two ways to archive this. First we can tell distutils where to find
the c-source to compile the queue.c
implementation automatically. Alternatively,
we can build and install C-Alg as system library and dynamically link it. The latter is useful
if other applications also use C-Alg.
Static Linking¶
To build the c-code automatically we need to include compiler directives in queue.pyx:
# distutils: sources = c-algorithms/src/queue.c
# distutils: include_dirs = c-algorithms/src/
cimport cqueue
cdef class Queue:
cdef cqueue.Queue* _c_queue
def __cinit__(self):
self._c_queue = cqueue.queue_new()
if self._c_queue is NULL:
raise MemoryError()
def __dealloc__(self):
if self._c_queue is not NULL:
cqueue.queue_free(self._c_queue)
The sources
compiler directive gives the path of the C
files that distutils is going to compile and
link (statically) into the resulting extension module.
In general all relevant header files should be found in include_dirs
.
Now we can build the project using:
$ python setup.py build_ext -i
And test whether our build was successful:
$ python -c 'import queue; Q = queue.Queue()'
Dynamic Linking¶
Dynamic linking is useful, if the library we are going to wrap is already installed on the system. To perform dynamic linking we first need to build and install c-alg.
To build c-algorithms on your system:
$ cd c-algorithms
$ sh autogen.sh
$ ./configure
$ make
to install CAlg run:
$ make install
Afterwards the file /usr/local/lib/libcalg.so
should exist.
Note
This path applies to Linux systems and may be different on other platforms,
so you will need to adapt the rest of the tutorial depending on the path
where libcalg.so
or libcalg.dll
is on your system.
In this approach we need to tell the setup script to link with an external library. To do so we need to extend the setup script to install change the extension setup from
ext_modules = cythonize([Extension("queue", ["queue.pyx"])])
to
ext_modules = cythonize([
Extension("queue", ["queue.pyx"],
libraries=["calg"])
])
Now we should be able to build the project using:
$ python setup.py build_ext -i
If the libcalg is not installed in a ‘normal’ location, users can provide the required parameters externally by passing appropriate C compiler flags, such as:
CFLAGS="-I/usr/local/otherdir/calg/include" \
LDFLAGS="-L/usr/local/otherdir/calg/lib" \
python setup.py build_ext -i
Before we run the module, we also need to make sure that libcalg is in the LD_LIBRARY_PATH environment variable, e.g. by setting:
$ export LD_LIBRARY_PATH=$LD_LIBRARY_PATH:/usr/local/lib
Once we have compiled the module for the first time, we can now import it and instantiate a new Queue:
$ export PYTHONPATH=.
$ python -c 'import queue; Q = queue.Queue()'
However, this is all our Queue class can do so far, so let’s make it more usable.
Mapping functionality¶
Before implementing the public interface of this class, it is good
practice to look at what interfaces Python offers, e.g. in its
list
or collections.deque
classes. Since we only need a FIFO
queue, it’s enough to provide the methods append()
, peek()
and
pop()
, and additionally an extend()
method to add multiple
values at once. Also, since we already know that all values will be
coming from C, it’s best to provide only cdef
methods for now, and
to give them a straight C interface.
In C, it is common for data structures to store data as a void*
to
whatever data item type. Since we only want to store int
values,
which usually fit into the size of a pointer type, we can avoid
additional memory allocations through a trick: we cast our int
values
to void*
and vice versa, and store the value directly as the
pointer value.
Here is a simple implementation for the append()
method:
cdef append(self, int value):
cqueue.queue_push_tail(self._c_queue, <void*>value)
Again, the same error handling considerations as for the
__cinit__()
method apply, so that we end up with this
implementation instead:
cdef append(self, int value):
if not cqueue.queue_push_tail(self._c_queue,
<void*>value):
raise MemoryError()
Adding an extend()
method should now be straight forward:
cdef extend(self, int* values, size_t count):
"""Append all ints to the queue.
"""
cdef int value
for value in values[:count]: # Slicing pointer to limit the iteration boundaries.
self.append(value)
This becomes handy when reading values from a C array, for example.
So far, we can only add data to the queue. The next step is to write
the two methods to get the first element: peek()
and pop()
,
which provide read-only and destructive read access respectively.
To avoid compiler warnings when casting void*
to int
directly,
we use an intermediate data type that is big enough to hold a void*
.
Here, Py_ssize_t
:
cdef int peek(self):
return <Py_ssize_t>cqueue.queue_peek_head(self._c_queue)
cdef int pop(self):
return <Py_ssize_t>cqueue.queue_pop_head(self._c_queue)
Normally, in C, we risk losing data when we convert a larger integer type
to a smaller integer type without checking the boundaries, and Py_ssize_t
may be a larger type than int
. But since we control how values are added
to the queue, we already know that all values that are in the queue fit into
an int
, so the above conversion from void*
to Py_ssize_t
to int
(the return type) is safe by design.
Handling errors¶
Now, what happens when the queue is empty? According to the
documentation, the functions return a NULL
pointer, which is
typically not a valid value. But since we are simply casting to and
from ints, we cannot distinguish anymore if the return value was
NULL
because the queue was empty or because the value stored in
the queue was 0
. In Cython code, we want the first case to
raise an exception, whereas the second case should simply return
0
. To deal with this, we need to special case this value,
and check if the queue really is empty or not:
cdef int peek(self) except? -1:
cdef int value = <Py_ssize_t>cqueue.queue_peek_head(self._c_queue)
if value == 0:
# this may mean that the queue is empty, or
# that it happens to contain a 0 value
if cqueue.queue_is_empty(self._c_queue):
raise IndexError("Queue is empty")
return value
Note how we have effectively created a fast path through the method in
the hopefully common cases that the return value is not 0
. Only
that specific case needs an additional check if the queue is empty.
The except? -1
declaration in the method signature falls into the
same category. If the function was a Python function returning a
Python object value, CPython would simply return NULL
internally
instead of a Python object to indicate an exception, which would
immediately be propagated by the surrounding code. The problem is
that the return type is int
and any int
value is a valid queue
item value, so there is no way to explicitly signal an error to the
calling code. In fact, without such a declaration, there is no
obvious way for Cython to know what to return on exceptions and for
calling code to even know that this method may exit with an
exception.
The only way calling code can deal with this situation is to call
PyErr_Occurred()
when returning from a function to check if an
exception was raised, and if so, propagate the exception. This
obviously has a performance penalty. Cython therefore allows you to
declare which value it should implicitly return in the case of an
exception, so that the surrounding code only needs to check for an
exception when receiving this exact value.
We chose to use -1
as the exception return value as we expect it
to be an unlikely value to be put into the queue. The question mark
in the except? -1
declaration indicates that the return value is
ambiguous (there may be a -1
value in the queue, after all) and
that an additional exception check using PyErr_Occurred()
is
needed in calling code. Without it, Cython code that calls this
method and receives the exception return value would silently (and
sometimes incorrectly) assume that an exception has been raised. In
any case, all other return values will be passed through almost
without a penalty, thus again creating a fast path for ‘normal’
values.
Now that the peek()
method is implemented, the pop()
method
also needs adaptation. Since it removes a value from the queue,
however, it is not enough to test if the queue is empty after the
removal. Instead, we must test it on entry:
cdef int pop(self) except? -1:
if cqueue.queue_is_empty(self._c_queue):
raise IndexError("Queue is empty")
return <Py_ssize_t>cqueue.queue_pop_head(self._c_queue)
The return value for exception propagation is declared exactly as for
peek()
.
Lastly, we can provide the Queue with an emptiness indicator in the
normal Python way by implementing the __bool__()
special method
(note that Python 2 calls this method __nonzero__
, whereas Cython
code can use either name):
def __bool__(self):
return not cqueue.queue_is_empty(self._c_queue)
Note that this method returns either True
or False
as we
declared the return type of the queue_is_empty()
function as
bint
in cqueue.pxd
.
Testing the result¶
Now that the implementation is complete, you may want to write some tests for it to make sure it works correctly. Especially doctests are very nice for this purpose, as they provide some documentation at the same time. To enable doctests, however, you need a Python API that you can call. C methods are not visible from Python code, and thus not callable from doctests.
A quick way to provide a Python API for the class is to change the
methods from cdef
to cpdef
. This will let Cython generate two
entry points, one that is callable from normal Python code using the
Python call semantics and Python objects as arguments, and one that is
callable from C code with fast C semantics and without requiring
intermediate argument conversion from or to Python types. Note that cpdef
methods ensure that they can be appropriately overridden by Python
methods even when they are called from Cython. This adds a tiny overhead
compared to cdef
methods.
Now that we have both a C-interface and a Python interface for our
class, we should make sure that both interfaces are consistent.
Python users would expect an extend()
method that accepts arbitrary
iterables, whereas C users would like to have one that allows passing
C arrays and C memory. Both signatures are incompatible.
We will solve this issue by considering that in C, the API could also
want to support other input types, e.g. arrays of long
or char
,
which is usually supported with differently named C API functions such as
extend_ints()
, extend_longs()
, extend_chars()``, etc. This allows
us to free the method name extend()
for the duck typed Python method,
which can accept arbitrary iterables.
The following listing shows the complete implementation that uses
cpdef
methods where possible:
# queue.pyx
cimport cqueue
cdef class Queue:
"""A queue class for C integer values.
>>> q = Queue()
>>> q.append(5)
>>> q.peek()
5
>>> q.pop()
5
"""
cdef cqueue.Queue* _c_queue
def __cinit__(self):
self._c_queue = cqueue.queue_new()
if self._c_queue is NULL:
raise MemoryError()
def __dealloc__(self):
if self._c_queue is not NULL:
cqueue.queue_free(self._c_queue)
cpdef append(self, int value):
if not cqueue.queue_push_tail(self._c_queue,
<void*> <Py_ssize_t> value):
raise MemoryError()
# The `cpdef` feature is obviously not available for the original "extend()"
# method, as the method signature is incompatible with Python argument
# types (Python does not have pointers). However, we can rename
# the C-ish "extend()" method to e.g. "extend_ints()", and write
# a new "extend()" method that provides a suitable Python interface by
# accepting an arbitrary Python iterable.
cpdef extend(self, values):
for value in values:
self.append(value)
cdef extend_ints(self, int* values, size_t count):
cdef int value
for value in values[:count]: # Slicing pointer to limit the iteration boundaries.
self.append(value)
cpdef int peek(self) except? -1:
cdef int value = <Py_ssize_t> cqueue.queue_peek_head(self._c_queue)
if value == 0:
# this may mean that the queue is empty,
# or that it happens to contain a 0 value
if cqueue.queue_is_empty(self._c_queue):
raise IndexError("Queue is empty")
return value
cpdef int pop(self) except? -1:
if cqueue.queue_is_empty(self._c_queue):
raise IndexError("Queue is empty")
return <Py_ssize_t> cqueue.queue_pop_head(self._c_queue)
def __bool__(self):
return not cqueue.queue_is_empty(self._c_queue)
Now we can test our Queue implementation using a python script,
for example here test_queue.py
:
from __future__ import print_function
import time
import queue
Q = queue.Queue()
Q.append(10)
Q.append(20)
print(Q.peek())
print(Q.pop())
print(Q.pop())
try:
print(Q.pop())
except IndexError as e:
print("Error message:", e) # Prints "Queue is empty"
i = 10000
values = range(i)
start_time = time.time()
Q.extend(values)
end_time = time.time() - start_time
print("Adding {} items took {:1.3f} msecs.".format(i, 1000 * end_time))
for i in range(41):
Q.pop()
Q.pop()
print("The answer is:")
print(Q.pop())
As a quick test with 10000 numbers on the author’s machine indicates,
using this Queue from Cython code with C int
values is about five
times as fast as using it from Cython code with Python object values,
almost eight times faster than using it from Python code in a Python
loop, and still more than twice as fast as using Python’s highly
optimised collections.deque
type from Cython code with Python
integers.
Callbacks¶
Let’s say you want to provide a way for users to pop values from the queue up to a certain user defined event occurs. To this end, you want to allow them to pass a predicate function that determines when to stop, e.g.:
def pop_until(self, predicate):
while not predicate(self.peek()):
self.pop()
Now, let us assume for the sake of argument that the C queue provides such a function that takes a C callback function as predicate. The API could look as follows:
/* C type of a predicate function that takes a queue value and returns
* -1 for errors
* 0 for reject
* 1 for accept
*/
typedef int (*predicate_func)(void* user_context, QueueValue data);
/* Pop values as long as the predicate evaluates to true for them,
* returns -1 if the predicate failed with an error and 0 otherwise.
*/
int queue_pop_head_until(Queue *queue, predicate_func predicate,
void* user_context);
It is normal for C callback functions to have a generic void*
argument that allows passing any kind of context or state through the
C-API into the callback function. We will use this to pass our Python
predicate function.
First, we have to define a callback function with the expected signature that we can pass into the C-API function:
cdef int evaluate_predicate(void* context, cqueue.QueueValue value):
"Callback function that can be passed as predicate_func"
try:
# recover Python function object from void* argument
func = <object>context
# call function, convert result into 0/1 for True/False
return bool(func(<int>value))
except:
# catch any Python errors and return error indicator
return -1
The main idea is to pass a pointer (a.k.a. borrowed reference) to the function object as the user context argument. We will call the C-API function as follows:
def pop_until(self, python_predicate_function):
result = cqueue.queue_pop_head_until(
self._c_queue, evaluate_predicate,
<void*>python_predicate_function)
if result == -1:
raise RuntimeError("an error occurred")
The usual pattern is to first cast the Python object reference into
a void*
to pass it into the C-API function, and then cast
it back into a Python object in the C predicate callback function.
The cast to void*
creates a borrowed reference. On the cast
to <object>
, Cython increments the reference count of the object
and thus converts the borrowed reference back into an owned reference.
At the end of the predicate function, the owned reference goes out
of scope again and Cython discards it.
The error handling in the code above is a bit simplistic. Specifically,
any exceptions that the predicate function raises will essentially be
discarded and only result in a plain RuntimeError()
being raised
after the fact. This can be improved by storing away the exception
in an object passed through the context parameter and re-raising it
after the C-API function has returned -1
to indicate the error.