\section{Standard Module \module{pickle}} \declaremodule{standard}{pickle} \modulesynopsis{Convert Python objects to streams of bytes and back.} \index{persistency} \indexii{persistent}{objects} \indexii{serializing}{objects} \indexii{marshalling}{objects} \indexii{flattening}{objects} \indexii{pickling}{objects} The \module{pickle} module implements a basic but powerful algorithm for ``pickling'' (a.k.a.\ serializing, marshalling or flattening) nearly arbitrary Python objects. This is the act of converting objects to a stream of bytes (and back: ``unpickling''). This is a more primitive notion than persistency --- although \module{pickle} reads and writes file objects, it does not handle the issue of naming persistent objects, nor the (even more complicated) area of concurrent access to persistent objects. The \module{pickle} module can transform a complex object into a byte stream and it can transform the byte stream into an object with the same internal structure. The most obvious thing to do with these byte streams is to write them onto a file, but it is also conceivable to send them across a network or store them in a database. The module \module{shelve} provides a simple interface to pickle and unpickle objects on ``dbm''-style database files. \refstmodindex{shelve} \strong{Note:} The \module{pickle} module is rather slow. A reimplementation of the same algorithm in \C{}, which is up to 1000 times faster, is available as the \module{cPickle}\refbimodindex{cPickle} module. This has the same interface except that \code{Pickler} and \code{Unpickler} are factory functions, not classes (so they cannot be used as base classes for inheritance). Unlike the built-in module \module{marshal}, \module{pickle} handles the following correctly: \refbimodindex{marshal} \begin{itemize} \item recursive objects (objects containing references to themselves) \item object sharing (references to the same object in different places) \item user-defined classes and their instances \end{itemize} The data format used by \module{pickle} is Python-specific. This has the advantage that there are no restrictions imposed by external standards such as XDR% \index{XDR} \index{External Data Representation} (which can't represent pointer sharing); however it means that non-Python programs may not be able to reconstruct pickled Python objects. By default, the \module{pickle} data format uses a printable \ASCII{} representation. This is slightly more voluminous than a binary representation. The big advantage of using printable \ASCII{} (and of some other characteristics of \module{pickle}'s representation) is that for debugging or recovery purposes it is possible for a human to read the pickled file with a standard text editor. A binary format, which is slightly more efficient, can be chosen by specifying a nonzero (true) value for the \var{bin} argument to the \class{Pickler} constructor or the \function{dump()} and \function{dumps()} functions. The binary format is not the default because of backwards compatibility with the Python 1.4 pickle module. In a future version, the default may change to binary. The \module{pickle} module doesn't handle code objects, which the \module{marshal} module does. I suppose \module{pickle} could, and maybe it should, but there's probably no great need for it right now (as long as \module{marshal} continues to be used for reading and writing code objects), and at least this avoids the possibility of smuggling Trojan horses into a program. \refbimodindex{marshal} For the benefit of persistency modules written using \module{pickle}, it supports the notion of a reference to an object outside the pickled data stream. Such objects are referenced by a name, which is an arbitrary string of printable \ASCII{} characters. The resolution of such names is not defined by the \module{pickle} module --- the persistent object module will have to implement a method \method{persistent_load()}. To write references to persistent objects, the persistent module must define a method \method{persistent_id()} which returns either \code{None} or the persistent ID of the object. There are some restrictions on the pickling of class instances. First of all, the class must be defined at the top level in a module. Furthermore, all its instance variables must be picklable. \setindexsubitem{(pickle protocol)} When a pickled class instance is unpickled, its \method{__init__()} method is normally \emph{not} invoked. \strong{Note:} This is a deviation from previous versions of this module; the change was introduced in Python 1.5b2. The reason for the change is that in many cases it is desirable to have a constructor that requires arguments; it is a (minor) nuisance to have to provide a \method{__getinitargs__()} method. If it is desirable that the \method{__init__()} method be called on unpickling, a class can define a method \method{__getinitargs__()}, which should return a \emph{tuple} containing the arguments to be passed to the class constructor (\method{__init__()}). This method is called at pickle time; the tuple it returns is incorporated in the pickle for the instance. \ttindex{__getinitargs__()} \ttindex{__init__()} Classes can further influence how their instances are pickled --- if the class defines the method \method{__getstate__()}, it is called and the return state is pickled as the contents for the instance, and if the class defines the method \method{__setstate__()}, it is called with the unpickled state. (Note that these methods can also be used to implement copying class instances.) If there is no \method{__getstate__()} method, the instance's \member{__dict__} is pickled. If there is no \method{__setstate__()} method, the pickled object must be a dictionary and its items are assigned to the new instance's dictionary. (If a class defines both \method{__getstate__()} and \method{__setstate__()}, the state object needn't be a dictionary --- these methods can do what they want.) This protocol is also used by the shallow and deep copying operations defined in the \module{copy} module.\refstmodindex{copy} \ttindex{__getstate__()} \ttindex{__setstate__()} \ttindex{__dict__} Note that when class instances are pickled, their class's code and data are not pickled along with them. Only the instance data are pickled. This is done on purpose, so you can fix bugs in a class or add methods and still load objects that were created with an earlier version of the class. If you plan to have long-lived objects that will see many versions of a class, it may be worthwhile to put a version number in the objects so that suitable conversions can be made by the class's \method{__setstate__()} method. When a class itself is pickled, only its name is pickled --- the class definition is not pickled, but re-imported by the unpickling process. Therefore, the restriction that the class must be defined at the top level in a module applies to pickled classes as well. \setindexsubitem{(in module pickle)} The interface can be summarized as follows. To pickle an object \code{x} onto a file \code{f}, open for writing: \begin{verbatim} p = pickle.Pickler(f) p.dump(x) \end{verbatim} A shorthand for this is: \begin{verbatim} pickle.dump(x, f) \end{verbatim} To unpickle an object \code{x} from a file \code{f}, open for reading: \begin{verbatim} u = pickle.Unpickler(f) x = u.load() \end{verbatim} A shorthand is: \begin{verbatim} x = pickle.load(f) \end{verbatim} The \class{Pickler} class only calls the method \code{f.write()} with a string argument. The \class{Unpickler} calls the methods \code{f.read()} (with an integer argument) and \code{f.readline()} (without argument), both returning a string. It is explicitly allowed to pass non-file objects here, as long as they have the right methods. \ttindex{Unpickler} \ttindex{Pickler} The constructor for the \class{Pickler} class has an optional second argument, \var{bin}. If this is present and nonzero, the binary pickle format is used; if it is zero or absent, the (less efficient, but backwards compatible) text pickle format is used. The \class{Unpickler} class does not have an argument to distinguish between binary and text pickle formats; it accepts either format. The following types can be pickled: \begin{itemize} \item \code{None} \item integers, long integers, floating point numbers \item strings \item tuples, lists and dictionaries containing only picklable objects \item classes that are defined at the top level in a module \item instances of such classes whose \member{__dict__} or \method{__setstate__()} is picklable \end{itemize} Attempts to pickle unpicklable objects will raise the \exception{PicklingError} exception; when this happens, an unspecified number of bytes may have been written to the file. It is possible to make multiple calls to the \method{dump()} method of the same \class{Pickler} instance. These must then be matched to the same number of calls to the \method{load()} method of the corresponding \class{Unpickler} instance. If the same object is pickled by multiple \method{dump()} calls, the \method{load()} will all yield references to the same object. \emph{Warning}: this is intended for pickling multiple objects without intervening modifications to the objects or their parts. If you modify an object and then pickle it again using the same \class{Pickler} instance, the object is not pickled again --- a reference to it is pickled and the \class{Unpickler} will return the old value, not the modified one. (There are two problems here: (a) detecting changes, and (b) marshalling a minimal set of changes. I have no answers. Garbage Collection may also become a problem here.) Apart from the \class{Pickler} and \class{Unpickler} classes, the module defines the following functions, and an exception: \begin{funcdesc}{dump}{object, file\optional{, bin}} Write a pickled representation of \var{obect} to the open file object \var{file}. This is equivalent to \samp{Pickler(\var{file}, \var{bin}).dump(\var{object})}. If the optional \var{bin} argument is present and nonzero, the binary pickle format is used; if it is zero or absent, the (less efficient) text pickle format is used. \end{funcdesc} \begin{funcdesc}{load}{file} Read a pickled object from the open file object \var{file}. This is equivalent to \samp{Unpickler(\var{file}).load()}. \end{funcdesc} \begin{funcdesc}{dumps}{object\optional{, bin}} Return the pickled representation of the object as a string, instead of writing it to a file. If the optional \var{bin} argument is present and nonzero, the binary pickle format is used; if it is zero or absent, the (less efficient) text pickle format is used. \end{funcdesc} \begin{funcdesc}{loads}{string} Read a pickled object from a string instead of a file. Characters in the string past the pickled object's representation are ignored. \end{funcdesc} \begin{excdesc}{PicklingError} This exception is raised when an unpicklable object is passed to \code{Pickler.dump()}. \end{excdesc} \begin{seealso} \seemodule[copyreg]{copy_reg}{pickle interface constructor registration} \seemodule{shelve}{indexed databases of objects; uses \module{pickle}} \seemodule{copy}{shallow and deep object copying} \seemodule{marshal}{high-performance serialization of built-in types} \end{seealso} \section{Built-in Module \module{cPickle}} \declaremodule{builtin}{cPickle} \modulesynopsis{Faster version of \module{pickle}, but not subclassable.} % This section was written by Fred L. Drake, Jr. The \module{cPickle} module provides a similar interface and identical functionality as the \module{pickle} module, but can be up to 1000 times faster since it is implemented in \C{}. The only other important difference to note is that \function{Pickler()} and \function{Unpickler()} are functions and not classes, and so cannot be subclassed. This should not be an issue in most cases. The format of the pickle data is identical to that produced using the \module{pickle} module, so it is possible to use \module{pickle} and \module{cPickle} interchangably with existing pickles.