As a dynamic language, Python encourages a programming style of considering classes and objects in terms of their methods and attributes, more than where they fit into the class hierarchy.
This can make Python a very relaxed and comfortable language for rapid development, but with a price - the ‘red tape’ of managing data types is dumped onto the interpreter. At run time, the interpreter does a lot of work searching namespaces, fetching attributes and parsing argument and keyword tuples. This run-time ‘late binding’ is a major cause of Python’s relative slowness compared to ‘early binding’ languages such as C++.
However with Cython it is possible to gain significant speed-ups through the use of ‘early binding’ programming techniques.
注意
Typing is not a necessity
Providing static typing to parameters and variables is convenience to speed up your code, but it is not a necessity. Optimize where and when needed. In fact, typing can slow down your code in the case where the typing does not allow optimizations but where Cython still needs to check that the type of some object matches the declared type.
cdef
statement is used to declare C variables, either local or module-level:
cdef int i, j, k cdef float f, g[42], *h
and C
struct
,
union
or
enum
types:
cdef struct Grail: int age float volume cdef union Food: char *spam float *eggs cdef enum CheeseType: cheddar, edam, camembert cdef enum CheeseState: hard = 1 soft = 2 runny = 3
另请参阅 Styles of struct, union and enum declaration
注意
Structs can be declared as
cdef
packed
struct
, which has the same effect as the C directive
#pragma
pack(1)
.
Declaring an enum as
cpdef
将创建
PEP 435
-style Python wrapper:
cpdef enum CheeseState: hard = 1 soft = 2 runny = 3
There is currently no special syntax for defining a constant, but you can use an anonymous
enum
declaration for this purpose, for example,:
cdef enum: tons_of_spam = 3
注意
the words
struct
,
union
and
enum
are used only when defining a type, not when referring to it. For example, to declare a variable pointing to a
Grail
you would write:
cdef Grail *gp
and not:
cdef struct Grail *gp # WRONG
There is also a
ctypedef
statement for giving names to types, e.g.:
ctypedef unsigned long ULong ctypedef int* IntPtr
It is also possible to declare functions with
cdef
, making them c functions.
cdef int eggs(unsigned long l, float f): ...
You can read more about them in Python 函数 vs C 函数 .
You can declare classes with
cdef
, making them
扩展类型
. Those will have a behavior very close to python classes, but are faster because they use a
struct
internally to store attributes.
Here is a simple example:
from __future__ import print_function cdef class Shrubbery: cdef int width, height def __init__(self, w, h): self.width = w self.height = h def describe(self): print("This shrubbery is", self.width, "by", self.height, "cubits.")
You can read more about them in 扩展类型 .
Cython uses the normal C syntax for C types, including pointers. It provides all the standard C types, namely
char
,
short
,
int
,
long
,
long
long
as well as their
unsigned
versions, e.g.
unsigned
int
. The special
bint
type is used for C boolean values (
int
with 0/non-0 values for False/True) and
Py_ssize_t
for (signed) sizes of Python containers.
Pointer types are constructed as in C, by appending a
*
to the base type they point to, e.g.
int**
for a pointer to a pointer to a C int. Arrays use the normal C array syntax, e.g.
int[10]
, and the size must be known at compile time for stack allocated arrays. Cython doesn’t support variable length arrays from C99. Note that Cython uses array access for pointer dereferencing, as
*x
is not valid Python syntax, whereas
x[0]
is.
Also, the Python types
list
,
dict
,
tuple
, etc. may be used for static typing, as well as any user defined
扩展类型
。例如:
cdef list foo = []
This requires an
exact
match of the class, it does not allow subclasses. This allows Cython to optimize code by accessing internals of the builtin class. For this kind of typing, Cython uses internally a C variable of type
PyObject*
. The Python types int, long, and float are not available for static typing and instead interpreted as C
int
,
long
,和
float
respectively, as statically typing variables with these Python types has zero advantages.
Cython provides an accelerated and typed equivalent of a Python tuple, the
ctuple
。
ctuple
is assembled from any valid C types. For example:
cdef (double, int) bar
They compile down to C-structures and can be used as efficient alternatives to Python tuples.
While these C types can be vastly faster, they have C semantics. Specifically, the integer types overflow and the C
float
type only has 32 bits of precision (as opposed to the 64-bit C
double
which Python floats wrap and is typically what one wants). If you want to use these numeric Python types simply omit the type declaration and let them be objects.
It is also possible to declare
扩展类型
(declared with
cdef
class
). This does allow subclasses. This typing is mostly used to access
cdef
methods and attributes of the extension type. The C code uses a variable which is a pointer to a structure of the specific type, something like
struct
MyExtensionTypeObject*
.
If you have a series of declarations that all begin with
cdef
, you can group them into a
cdef
block like this:
from __future__ import print_function cdef: struct Spam: int tons int i float a Spam *p void f(Spam *s): print(s.tons, "Tons of spam")
There are two kinds of function definition in Cython:
Python functions are defined using the def statement, as in Python. They take Python objects as parameters and return Python objects.
C functions are defined using the new
cdef
statement. They take either Python objects or C values as parameters, and can return either Python objects or C values.
Within a Cython module, Python functions and C functions can call each other freely, but only Python functions can be called from outside the module by interpreted Python code. So, any functions that you want to “export” from your Cython module must be declared as Python functions using def. There is also a hybrid function, called
cpdef
。
cpdef
can be called from anywhere, but uses the faster C calling conventions when being called from other Cython code. A
cpdef
can also be overridden by a Python method on a subclass or an instance attribute, even when called from Cython. If this happens, most performance gains are of course lost and even if it does not, there is a tiny overhead in calling a
cpdef
method from Cython compared to calling a
cdef
方法。
Parameters of either type of function can be declared to have C data types, using normal C declaration syntax. For example,:
def spam(int i, char *s): ... cdef int eggs(unsigned long l, float f): ...
ctuples
may also be used:
cdef (int, float) chips((long, long, double) t): ...
When a parameter of a Python function is declared to have a C data type, it is passed in as a Python object and automatically converted to a C value, if possible. In other words, the definition of
spam
above is equivalent to writing:
def spam(python_i, python_s): cdef int i = python_i cdef char* s = python_s ...
Automatic conversion is currently only possible for numeric types, string types and structs (composed recursively of any of these types); attempting to use any other type for the parameter of a Python function will result in a compile-time error. Care must be taken with strings to ensure a reference if the pointer is to be used after the call. Structs can be obtained from Python mappings, and again care must be taken with string attributes if they are to be used after the function returns.
C functions, on the other hand, can have parameters of any type, since they’re passed in directly using a normal C function call.
Functions declared using
cdef
with Python object return type, like Python functions, will return a
None
value when execution leaves the function body without an explicit return value. This is in contrast to C/C++, which leaves the return value undefined. In the case of non-Python object return types, the equivalent of zero is returned, for example, 0 for
int
,
False
for
bint
and
NULL
for pointer types.
A more complete comparison of the pros and cons of these different method types can be found at 早期速度绑定 .
If no type is specified for a parameter or return value, it is assumed to be a Python object. (Note that this is different from the C convention, where it would default to int.) For example, the following defines a C function that takes two Python objects as parameters and returns a Python object:
cdef spamobjs(x, y): ...
Reference counting for these objects is performed automatically according to the standard Python/C API rules (i.e. borrowed references are taken as parameters and a new reference is returned).
警告
This only applies to Cython code. Other Python packages which are implemented in C like NumPy may not follow these conventions.
The name object can also be used to explicitly declare something as a Python object. This can be useful if the name being declared would otherwise be taken as the name of a type, for example,:
cdef ftang(object int): ...
declares a parameter called int which is a Python object. You can also use object as the explicit return type of a function, e.g.:
cdef object ftang(object int): ...
In the interests of clarity, it is probably a good idea to always be explicit about object parameters in C functions.
Unlike C, it is possible to use optional arguments in
cdef
and
cpdef
functions. There are differences though whether you declare them in a
.pyx
file or the corresponding
.pxd
文件。
To avoid repetition (and potential future inconsistencies), default argument values are not visible in the declaration (in
.pxd
files) but only in the implementation (in
.pyx
文件)。
When in a
.pyx
file, the signature is the same as it is in Python itself:
from __future__ import print_function cdef class A: cdef foo(self): print("A") cdef class B(A): cdef foo(self, x=None): print("B", x) cdef class C(B): cpdef foo(self, x=True, int k=3): print("C", x, k)
When in a
.pxd
file, the signature is different like this example:
cdef
foo(x=*)
. This is because the program calling the function just needs to know what signatures are possible in C, but doesn’t need to know the value of the default arguments.:
cdef class A: cdef foo(self) cdef class B(A): cdef foo(self, x=*) cdef class C(B): cpdef foo(self, x=*, int k=*)
注意
The number of arguments may increase when subclassing, but the arg types and order must be the same, as shown in the example above.
There may be a slight performance penalty when the optional arg is overridden with one that does not have default values.
As in Python 3,
def
functions can have keyword-only arguments listed after a
"*"
parameter and before a
"**"
parameter if any:
def f(a, b, *args, c, d = 42, e, **kwds): ... # We cannot call f with less verbosity than this. foo = f(4, "bar", c=68, e=1.0)
As shown above, the
c
,
d
and
e
arguments can not be passed as positional arguments and must be passed as keyword arguments. Furthermore,
c
and
e
are
required
keyword arguments since they do not have a default value.
A single
"*"
without argument name can be used to terminate the list of positional arguments:
def g(a, b, *, c, d): ... # We cannot call g with less verbosity than this. foo = g(4.0, "something", c=68, d="other")
Shown above, the signature takes exactly two positional parameters and has two required keyword parameters.
Functions declared in a
struct
are automatically converted to function pointers.
For using error return values with function pointers, see the note at the bottom of 错误返回值 .
If you don’t do anything special, a function declared with
cdef
that does not return a Python object has no way of reporting Python exceptions to its caller. If an exception is detected in such a function, a warning message is printed and the exception is ignored.
If you want a C function that does not return a Python object to be able to propagate exceptions to its caller, you need to declare an exception value for it. Here is an example:
cdef int spam() except -1: ...
With this declaration, whenever an exception occurs inside spam, it will immediately return with the value
-1
. Furthermore, whenever a call to spam returns
-1
, an exception will be assumed to have occurred and will be propagated.
When you declare an exception value for a function, you should never explicitly or implicitly return that value. In particular, if the exceptional return value is a
False
value, then you should ensure the function will never terminate via an implicit or empty return.
If all possible return values are legal and you can’t reserve one entirely for signalling errors, you can use an alternative form of exception value declaration:
cdef int spam() except? -1: ...
The “?” indicates that the value
-1
only indicates a possible error. In this case, Cython generates a call to
PyErr_Occurred()
if the exception value is returned, to make sure it really is an error.
There is also a third form of exception value declaration:
cdef int spam() except *: ...
This form causes Cython to generate a call to
PyErr_Occurred()
after every call to spam, regardless of what value it returns. If you have a function returning void that needs to propagate errors, you will have to use this form, since there isn’t any return value to test. Otherwise there is little use for this form.
An external C++ function that may raise an exception can be declared with:
cdef int spam() except +
见 在 Cython 中使用 C++ 了解更多细节。
Some things to note:
Exception values can only declared for functions returning an integer, enum, float or pointer type, and the value must be a constant expression. Void functions can only use the
except
*
form.
The exception value specification is part of the signature of the function. If you’re passing a pointer to a function as a parameter or assigning it to a variable, the declared type of the parameter or variable must have the same exception value specification (or lack thereof). Here is an example of a pointer-to-function declaration with an exception value:
int (*grail)(int, char*) except -1
You don’t need to (and shouldn’t) declare exception values for functions which return Python objects. Remember that a function with no declared return type implicitly returns a Python object. (Exceptions on such functions are implicitly propagated by returning NULL.)
It’s important to understand that the except clause does not cause an error to be raised when the specified value is returned. For example, you can’t write something like:
cdef extern FILE *fopen(char *filename, char *mode) except NULL # WRONG!
and expect an exception to be automatically raised if a call to
fopen()
返回
NULL
. The except clause doesn’t work that way; its only purpose is for propagating Python exceptions that have already been raised, either by a Cython function or a C function that calls Python/C API routines. To get an exception from a non-Python-aware function such as
fopen()
, you will have to check the return value and raise it yourself, for example:
from libc.stdio cimport FILE, fopen from libc.stdlib cimport malloc, free from cpython.exc cimport PyErr_SetFromErrnoWithFilenameObject def open_file(): cdef FILE* p p = fopen("spam.txt", "r") if p is NULL: PyErr_SetFromErrnoWithFilenameObject(OSError, "spam.txt") ... def allocating_memory(number=10): cdef double *my_array = <double *> malloc(number * sizeof(double)) if not my_array: # same as 'is NULL' above raise MemoryError() ... free(my_array)
cpdef
methods can override
cdef
方法:
from __future__ import print_function cdef class A: cdef foo(self): print("A") cdef class B(A): cdef foo(self, x=None): print("B", x) cdef class C(B): cpdef foo(self, x=True, int k=3): print("C", x, k)
When subclassing an extension type with a Python class,
def
methods can override
cpdef
methods but not
cdef
方法:
from __future__ import print_function cdef class A: cdef foo(self): print("A") cdef class B(A): cpdef foo(self): print("B") class C(B): # NOTE: not cdef class def foo(self): print("C")
若
C
above would be an extension type (
cdef
class
), this would not work correctly. The Cython compiler will give a warning in that case.
In most situations, automatic conversions will be performed for the basic numeric and string types when a Python object is used in a context requiring a C value, or vice versa. The following table summarises the conversion possibilities.
| C 类型 | From Python types | To Python types |
|---|---|---|
| [unsigned] char, [unsigned] short, int, long | int, long | int |
| unsigned int, unsigned long, [unsigned] long long | int, long | long |
| float, double, long double | int, long, float | float |
| char* | str/bytes | str/bytes [3] |
| C array | iterable | list [5] |
| struct, union | dict [4] |
| [3] | The conversion is to/from str for Python 2.x, and bytes for Python 3.x. |
| [4] |
The conversion from a C union type to a Python dict will add a value for each of the union fields. Cython 0.23 and later, however, will refuse to automatically convert a union with unsafe type combinations. An example is a union of an
int
和
char*
, in which case the pointer value may or may not be a valid pointer.
|
| [5] | Other than signed/unsigned char[]. The conversion will fail if the length of C array is not known at compile time, and when using a slice of a C array. |
You need to be careful when using a Python string in a context expecting a
char*
. In this situation, a pointer to the contents of the Python string is used, which is only valid as long as the Python string exists. So you need to make sure that a reference to the original Python string is held for as long as the C string is needed. If you can’t guarantee that the Python string will live long enough, you will need to copy the C string.
Cython detects and prevents some mistakes of this kind. For instance, if you attempt something like:
cdef char *s s = pystring1 + pystring2
then Cython will produce the error message
Obtaining
char*
from
temporary
Python
value
. The reason is that concatenating the two Python strings produces a new Python string object that is referenced only by a temporary internal variable that Cython generates. As soon as the statement has finished, the temporary variable will be decrefed and the Python string deallocated, leaving
s
dangling. Since this code could not possibly work, Cython refuses to compile it.
The solution is to assign the result of the concatenation to a Python variable, and then obtain the
char*
from that, i.e.:
cdef char *s p = pystring1 + pystring2 s = p
It is then your responsibility to hold the reference p for as long as necessary.
Keep in mind that the rules used to detect such errors are only heuristics. Sometimes Cython will complain unnecessarily, and sometimes it will fail to detect a problem that exists. Ultimately, you need to understand the issue and be careful what you do.
Where C uses
"("
and
")"
, Cython uses
"<"
and
">"
。例如:
cdef char *p cdef float *q p = <char*>q
When casting a C value to a Python object type or vice versa, Cython will attempt a coercion. Simple examples are casts like
<int>pyobj
, which converts a Python number to a plain C
int
value, or
<bytes>charptr
, which copies a C
char*
string into a new Python bytes object.
注意
Cython will not prevent a redundant cast, but emits a warning for it.
To get the address of some Python object, use a cast to a pointer type like
<void*>
or
<PyObject*>
. You can also cast a C pointer back to a Python object reference with
<object>
, or a more specific builtin or extension type (e.g.
<MyExtType>ptr
). This will increase the reference count of the object by one, i.e. the cast returns an owned reference. Here is an example:
from cpython.ref cimport PyObject cdef extern from *: ctypedef Py_ssize_t Py_intptr_t python_string = "foo" cdef void* ptr = <void*>python_string cdef Py_intptr_t adress_in_c = <Py_intptr_t>ptr address_from_void = adress_in_c # address_from_void is a python int cdef PyObject* ptr2 = <PyObject*>python_string cdef Py_intptr_t address_in_c2 = <Py_intptr_t>ptr2 address_from_PyObject = address_in_c2 # address_from_PyObject is a python int assert address_from_void == address_from_PyObject == id(python_string) print(<object>ptr) # Prints "foo" print(<object>ptr2) # prints "foo"
The precedence of
<...>
is such that
<type>a.b.c
被解释成
<type>(a.b.c)
.
A cast like
<MyExtensionType>x
will cast x to the class
MyExtensionType
without any checking at all.
To have a cast checked, use the syntax like:
<MyExtensionType?>x
. In this case, Cython will apply a runtime check that raises a
TypeError
if
x
不是实例化的
MyExtensionType
. This tests for the exact class for builtin types, but allows subclasses for
扩展类型
.
Control structures and expressions follow Python syntax for the most part. When applied to Python objects, they have the same semantics as in Python (unless otherwise noted). Most of the Python operators can also be applied to C values, with the obvious semantics.
If Python objects and C values are mixed in an expression, conversions are performed automatically between Python objects and C numeric or string types.
Reference counts are maintained automatically for all Python objects, and all Python operations are automatically checked for errors, with appropriate action taken.
There are some differences in syntax and semantics between C expressions and Cython expressions, particularly in the area of C constructs which have no direct equivalent in Python.
An integer literal is treated as a C constant, and will be truncated to whatever size your C compiler thinks appropriate. To get a Python integer (of arbitrary precision) cast immediately to an object (e.g.
<object>100000000000000000000
)。
L
,
LL
,和
U
suffixes have the same meaning as in C.
There is no
->
operator in Cython. Instead of
p->x
,使用
p.x
There is no unary
*
operator in Cython. Instead of
*p
,使用
p[0]
There is an
&
operator, with the same semantics as in C.
The null C pointer is called
NULL
, not
0
(和
NULL
is a reserved word).
Type casts are written
<type>value
, for example,:
cdef char* p, float* q p = <char*>q
Cython determines whether a variable belongs to a local scope, the module scope, or the built-in scope completely statically. As with Python, assigning to a variable which is not otherwise declared implicitly declares it to be a variable residing in the scope where it is assigned. The type of the variable depends on type inference, except for the global module scope, where it is always a Python object.
Cython compiles calls to most built-in functions into direct calls to the corresponding Python/C API routines, making them particularly fast.
Only direct function calls using these names are optimised. If you do something else with one of these names that assumes it’s a Python object, such as assign it to a Python variable, and later call it, the call will be made as a Python function call.
| 函数和自变量 | 返回类型 | Python/C API 等价物 |
|---|---|---|
| abs(obj) | object, double, … | PyNumber_Absolute, fabs, fabsf, … |
| callable(obj) | bint | PyObject_Callable |
| delattr(obj, name) | None | PyObject_DelAttr |
| exec(code, [glob, [loc]]) | 对象 |
|
| dir(obj) | list | PyObject_Dir |
| divmod(a, b) | tuple | PyNumber_Divmod |
| getattr(obj, name, [default]) (Note 1) | 对象 | PyObject_GetAttr |
| hasattr(obj, name) | bint | PyObject_HasAttr |
| hash(obj) | int / long | PyObject_Hash |
| intern(obj) | 对象 | Py*_InternFromString |
| isinstance(obj, type) | bint | PyObject_IsInstance |
| issubclass(obj, type) | bint | PyObject_IsSubclass |
| iter(obj, [sentinel]) | 对象 | PyObject_GetIter |
| len(obj) | Py_ssize_t | PyObject_Length |
| pow(x, y, [z]) | 对象 | PyNumber_Power |
| reload(obj) | 对象 | PyImport_ReloadModule |
| repr(obj) | 对象 | PyObject_Repr |
| setattr(obj, name) | void | PyObject_SetAttr |
Note 1: Pyrex originally provided a function
getattr3(obj,
name,
default)()
corresponding to the three-argument form of the Python builtin
getattr()
. Cython still supports this function, but the usage is deprecated in favour of the normal builtin, which Cython can optimise in both forms.
Keep in mind that there are some differences in operator precedence between Python and C, and that Cython uses the Python precedences, not the C ones.
Cython recognises the usual Python for-in-range integer loop pattern:
for i in range(n): ...
若
i
is declared as a
cdef
integer type, it will optimise this into a pure C loop. This restriction is required as otherwise the generated code wouldn’t be correct due to potential integer overflows on the target architecture. If you are worried that the loop is not being converted correctly, use the annotate feature of the cython commandline (
-a
) to easily see the generated C code. See
自动范围转换
For backwards compatibility to Pyrex, Cython also supports a more verbose form of for-loop which you might find in legacy code:
for i from 0 <= i < n: ...
或:
for i from 0 <= i < n by s: ...
where
s
is some integer step size.
注意
This syntax is deprecated and should not be used in new code. Use the normal Python for-loop instead.
Some things to note about the for-from loop:
<
,
<=
} then it is upwards; if they are both from the set {
>
,
>=
} then it is downwards. (Any other combination is disallowed.)
Like other Python looping statements, break and continue may be used in the body, and the loop may have an else clause.
Cython 有 3 种文件类型:
.py
or
.pyx
后缀。
.pxd
后缀。
.pxi
后缀。
The implementation file, as the name suggest, contains the implementation of your functions, classes, extension types, etc. Nearly all the python syntax is supported in this file. Most of the time, a
.py
file can be renamed into a
.pyx
file without changing any code, and Cython will retain the python behavior.
It is possible for Cython to compile both
.py
and
.pyx
files. The name of the file isn’t important if one wants to use only the Python syntax, and Cython won’t change the generated code depending on the suffix used. Though, if one want to use the Cython syntax, using a
.pyx
file is necessary.
In addition to the Python syntax, the user can also leverage Cython syntax (such as
cdef
) to use C variables, can declare functions as
cdef
or
cpdef
and can import C definitions with
cimport
. Many other Cython features usable in implementation files can be found throughout this page and the rest of the Cython documentation.
There are some restrictions on the implementation part of some 扩展类型 if the corresponding definition file also defines that type.
注意
当
.pyx
file is compiled, Cython first checks to see if a corresponding
.pxd
file exists and processes it first. It acts like a header file for a Cython
.pyx
file. You can put inside functions that will be used by other Cython modules. This allows different Cython modules to use functions and classes from each other without the Python overhead. To read more about what how to do that, you can see
pxd 文件
.
A definition file is used to declare various things.
Any C declaration can be made, and it can be also a declaration of a C variable or function implemented in a C/C++ file. This can be done with
cdef
extern
from
. Sometimes,
.pxd
files are used as a translation of C/C++ header files into a syntax that Cython can understand. This allows then the C/C++ variable and functions to be used directly in implementation files with
cimport
. You can read more about it in
接口外部 C 代码
and
在 Cython 中使用 C++
.
It can also contain the definition part of an extension type and the declarations of functions for an external library.
It cannot contain the implementations of any C or Python functions, or any Python class definitions, or any executable statements. It is needed when one wants to access
cdef
attributes and methods, or to inherit from
cdef
classes defined in this module.
注意
You don’t need to (and shouldn’t) declare anything in a declaration file
public
in order to make it available to other Cython modules; its mere presence in a definition file does that. You only need a public declaration if you want to make something available to external C code.
警告
Historically the
包括
statement was used for sharing declarations. Use
在 Cython 模块间共享声明
代替。
A Cython source file can include material from other files using the include statement, for example,:
include "spamstuff.pxi"
The contents of the named file are textually included at that point. The included file can contain any complete statements or declarations that are valid in the context where the include statement appears, including other include statements. The contents of the included file should begin at an indentation level of zero, and will be treated as though they were indented to the level of the include statement that is including the file. The include statement cannot, however, be used outside of the module scope, such as inside of functions or class bodies.
注意
There are other mechanisms available for splitting Cython code into separate parts that may be more appropriate in many cases. See 在 Cython 模块间共享声明 .
Some features are available for conditional compilation and compile-time constants within a Cython source file.
A compile-time constant can be defined using the DEF statement:
DEF FavouriteFood = u"spam" DEF ArraySize = 42 DEF OtherArraySize = 2 * ArraySize + 17
The right-hand side of the
DEF
must be a valid compile-time expression. Such expressions are made up of literal values and names defined using
DEF
statements, combined using any of the Python expression syntax.
The following compile-time names are predefined, corresponding to the values returned by
os.uname()
.
The following selection of builtin constants and functions are also available:
None, True, False, abs, all, any, ascii, bin, bool, bytearray, bytes, chr, cmp, complex, dict, divmod, enumerate, filter, float, format, frozenset, hash, hex, int, len, list, long, map, max, min, oct, ord, pow, range, reduce, repr, reversed, round, set, slice, sorted, str, sum, tuple, xrange, zipNote that some of these builtins may not be available when compiling under Python 2.x or 3.x, or may behave differently in both.
A name defined using
DEF
can be used anywhere an identifier can appear, and it is replaced with its compile-time value as though it were written into the source at that point as a literal. For this to work, the compile-time expression must evaluate to a Python value of type
int
,
long
,
float
,
bytes
or
unicode
(
str
在 Py3 中)。
from __future__ import print_function DEF FavouriteFood = u"spam" DEF ArraySize = 42 DEF OtherArraySize = 2 * ArraySize + 17 cdef int a1[ArraySize] cdef int a2[OtherArraySize] print("I like", FavouriteFood)
IF
statement can be used to conditionally include or exclude sections of code at compile time. It works in a similar way to the
#if
preprocessor directive in C.:
IF UNAME_SYSNAME == "Windows": include "icky_definitions.pxi" ELIF UNAME_SYSNAME == "Darwin": include "nice_definitions.pxi" ELIF UNAME_SYSNAME == "Linux": include "penguin_definitions.pxi" ELSE: include "other_definitions.pxi"
ELIF
and
ELSE
clauses are optional. An
IF
statement can appear anywhere that a normal statement or declaration can appear, and it can contain any statements or declarations that would be valid in that context, including
DEF
statements and other
IF
语句。
The expressions in the
IF
and
ELIF
clauses must be valid compile-time expressions as for the
DEF
statement, although they can evaluate to any Python value, and the truth of the result is determined in the usual Python way.
