# -*- coding: utf-8 -*- """ Python advanced pretty printer. This pretty printer is intended to replace the old `pprint` python module which does not allow developers to provide their own pretty print callbacks. This module is based on ruby's `prettyprint.rb` library by `Tanaka Akira`. Example Usage ------------- To directly print the representation of an object use `pprint`:: from pretty import pprint pprint(complex_object) To get a string of the output use `pretty`:: from pretty import pretty string = pretty(complex_object) Extending --------- The pretty library allows developers to add pretty printing rules for their own objects. This process is straightforward. All you have to do is to add a `_repr_pretty_` method to your object and call the methods on the pretty printer passed:: class MyObject(object): def _repr_pretty_(self, p, cycle): ... Depending on the python version you want to support you have two possibilities. The following list shows the python 2.5 version and the compatibility one. Here the example implementation of a `_repr_pretty_` method for a list subclass for python 2.5 and higher (python 2.5 requires the with statement __future__ import):: class MyList(list): def _repr_pretty_(self, p, cycle): if cycle: p.text('MyList(...)') else: with p.group(8, 'MyList([', '])'): for idx, item in enumerate(self): if idx: p.text(',') p.breakable() p.pretty(item) The `cycle` parameter is `True` if pretty detected a cycle. You *have* to react to that or the result is an infinite loop. `p.text()` just adds non breaking text to the output, `p.breakable()` either adds a whitespace or breaks here. If you pass it an argument it's used instead of the default space. `p.pretty` prettyprints another object using the pretty print method. The first parameter to the `group` function specifies the extra indentation of the next line. In this example the next item will either be not breaked (if the items are short enough) or aligned with the right edge of the opening bracked of `MyList`. If you want to support python 2.4 and lower you can use this code:: class MyList(list): def _repr_pretty_(self, p, cycle): if cycle: p.text('MyList(...)') else: p.begin_group(8, 'MyList([') for idx, item in enumerate(self): if idx: p.text(',') p.breakable() p.pretty(item) p.end_group(8, '])') If you just want to indent something you can use the group function without open / close parameters. Under python 2.5 you can also use this code:: with p.indent(2): ... Or under python2.4 you might want to modify ``p.indentation`` by hand but this is rather ugly. Inheritance diagram: .. inheritance-diagram:: IPython.lib.pretty :parts: 3 :copyright: 2007 by Armin Ronacher. Portions (c) 2009 by Robert Kern. :license: BSD License. """ from __future__ import with_statement from contextlib import contextmanager import sys import types import re import datetime from StringIO import StringIO from collections import deque __all__ = ['pretty', 'pprint', 'PrettyPrinter', 'RepresentationPrinter', 'for_type', 'for_type_by_name'] _re_pattern_type = type(re.compile('')) def pretty(obj, verbose=False, max_width=79, newline='\n'): """ Pretty print the object's representation. """ stream = StringIO() printer = RepresentationPrinter(stream, verbose, max_width, newline) printer.pretty(obj) printer.flush() return stream.getvalue() def pprint(obj, verbose=False, max_width=79, newline='\n'): """ Like `pretty` but print to stdout. """ printer = RepresentationPrinter(sys.stdout, verbose, max_width, newline) printer.pretty(obj) printer.flush() sys.stdout.write(newline) sys.stdout.flush() class _PrettyPrinterBase(object): @contextmanager def indent(self, indent): """with statement support for indenting/dedenting.""" self.indentation += indent try: yield finally: self.indentation -= indent @contextmanager def group(self, indent=0, open='', close=''): """like begin_group / end_group but for the with statement.""" self.begin_group(indent, open) try: yield finally: self.end_group(indent, close) class PrettyPrinter(_PrettyPrinterBase): """ Baseclass for the `RepresentationPrinter` prettyprinter that is used to generate pretty reprs of objects. Contrary to the `RepresentationPrinter` this printer knows nothing about the default pprinters or the `_repr_pretty_` callback method. """ def __init__(self, output, max_width=79, newline='\n'): self.output = output self.max_width = max_width self.newline = newline self.output_width = 0 self.buffer_width = 0 self.buffer = deque() root_group = Group(0) self.group_stack = [root_group] self.group_queue = GroupQueue(root_group) self.indentation = 0 def _break_outer_groups(self): while self.max_width < self.output_width + self.buffer_width: group = self.group_queue.deq() if not group: return while group.breakables: x = self.buffer.popleft() self.output_width = x.output(self.output, self.output_width) self.buffer_width -= x.width while self.buffer and isinstance(self.buffer[0], Text): x = self.buffer.popleft() self.output_width = x.output(self.output, self.output_width) self.buffer_width -= x.width def text(self, obj): """Add literal text to the output.""" width = len(obj) if self.buffer: text = self.buffer[-1] if not isinstance(text, Text): text = Text() self.buffer.append(text) text.add(obj, width) self.buffer_width += width self._break_outer_groups() else: self.output.write(obj) self.output_width += width def breakable(self, sep=' '): """ Add a breakable separator to the output. This does not mean that it will automatically break here. If no breaking on this position takes place the `sep` is inserted which default to one space. """ width = len(sep) group = self.group_stack[-1] if group.want_break: self.flush() self.output.write(self.newline) self.output.write(' ' * self.indentation) self.output_width = self.indentation self.buffer_width = 0 else: self.buffer.append(Breakable(sep, width, self)) self.buffer_width += width self._break_outer_groups() def begin_group(self, indent=0, open=''): """ Begin a group. If you want support for python < 2.5 which doesn't has the with statement this is the preferred way: p.begin_group(1, '{') ... p.end_group(1, '}') The python 2.5 expression would be this: with p.group(1, '{', '}'): ... The first parameter specifies the indentation for the next line (usually the width of the opening text), the second the opening text. All parameters are optional. """ if open: self.text(open) group = Group(self.group_stack[-1].depth + 1) self.group_stack.append(group) self.group_queue.enq(group) self.indentation += indent def end_group(self, dedent=0, close=''): """End a group. See `begin_group` for more details.""" self.indentation -= dedent group = self.group_stack.pop() if not group.breakables: self.group_queue.remove(group) if close: self.text(close) def flush(self): """Flush data that is left in the buffer.""" for data in self.buffer: self.output_width += data.output(self.output, self.output_width) self.buffer.clear() self.buffer_width = 0 def _get_mro(obj_class): """ Get a reasonable method resolution order of a class and its superclasses for both old-style and new-style classes. """ if not hasattr(obj_class, '__mro__'): # Old-style class. Mix in object to make a fake new-style class. try: obj_class = type(obj_class.__name__, (obj_class, object), {}) except TypeError: # Old-style extension type that does not descend from object. # FIXME: try to construct a more thorough MRO. mro = [obj_class] else: mro = obj_class.__mro__[1:-1] else: mro = obj_class.__mro__ return mro class RepresentationPrinter(PrettyPrinter): """ Special pretty printer that has a `pretty` method that calls the pretty printer for a python object. This class stores processing data on `self` so you must *never* use this class in a threaded environment. Always lock it or reinstanciate it. Instances also have a verbose flag callbacks can access to control their output. For example the default instance repr prints all attributes and methods that are not prefixed by an underscore if the printer is in verbose mode. """ def __init__(self, output, verbose=False, max_width=79, newline='\n', singleton_pprinters=None, type_pprinters=None, deferred_pprinters=None): PrettyPrinter.__init__(self, output, max_width, newline) self.verbose = verbose self.stack = [] if singleton_pprinters is None: singleton_pprinters = _singleton_pprinters.copy() self.singleton_pprinters = singleton_pprinters if type_pprinters is None: type_pprinters = _type_pprinters.copy() self.type_pprinters = type_pprinters if deferred_pprinters is None: deferred_pprinters = _deferred_type_pprinters.copy() self.deferred_pprinters = deferred_pprinters def pretty(self, obj): """Pretty print the given object.""" obj_id = id(obj) cycle = obj_id in self.stack self.stack.append(obj_id) self.begin_group() try: obj_class = getattr(obj, '__class__', None) or type(obj) # First try to find registered singleton printers for the type. try: printer = self.singleton_pprinters[obj_id] except (TypeError, KeyError): pass else: return printer(obj, self, cycle) # Next walk the mro and check for either: # 1) a registered printer # 2) a _repr_pretty_ method for cls in _get_mro(obj_class): if cls in self.type_pprinters: # printer registered in self.type_pprinters return self.type_pprinters[cls](obj, self, cycle) else: # deferred printer printer = self._in_deferred_types(cls) if printer is not None: return printer(obj, self, cycle) else: # Finally look for special method names. # Some objects automatically create any requested # attribute. Try to ignore most of them by checking for # callability. if '_repr_pretty_' in cls.__dict__: meth = cls._repr_pretty_ if callable(meth): return meth(obj, self, cycle) return _default_pprint(obj, self, cycle) finally: self.end_group() self.stack.pop() def _in_deferred_types(self, cls): """ Check if the given class is specified in the deferred type registry. Returns the printer from the registry if it exists, and None if the class is not in the registry. Successful matches will be moved to the regular type registry for future use. """ mod = getattr(cls, '__module__', None) name = getattr(cls, '__name__', None) key = (mod, name) printer = None if key in self.deferred_pprinters: # Move the printer over to the regular registry. printer = self.deferred_pprinters.pop(key) self.type_pprinters[cls] = printer return printer class Printable(object): def output(self, stream, output_width): return output_width class Text(Printable): def __init__(self): self.objs = [] self.width = 0 def output(self, stream, output_width): for obj in self.objs: stream.write(obj) return output_width + self.width def add(self, obj, width): self.objs.append(obj) self.width += width class Breakable(Printable): def __init__(self, seq, width, pretty): self.obj = seq self.width = width self.pretty = pretty self.indentation = pretty.indentation self.group = pretty.group_stack[-1] self.group.breakables.append(self) def output(self, stream, output_width): self.group.breakables.popleft() if self.group.want_break: stream.write(self.pretty.newline) stream.write(' ' * self.indentation) return self.indentation if not self.group.breakables: self.pretty.group_queue.remove(self.group) stream.write(self.obj) return output_width + self.width class Group(Printable): def __init__(self, depth): self.depth = depth self.breakables = deque() self.want_break = False class GroupQueue(object): def __init__(self, *groups): self.queue = [] for group in groups: self.enq(group) def enq(self, group): depth = group.depth while depth > len(self.queue) - 1: self.queue.append([]) self.queue[depth].append(group) def deq(self): for stack in self.queue: for idx, group in enumerate(reversed(stack)): if group.breakables: del stack[idx] group.want_break = True return group for group in stack: group.want_break = True del stack[:] def remove(self, group): try: self.queue[group.depth].remove(group) except ValueError: pass try: _baseclass_reprs = (object.__repr__, types.InstanceType.__repr__) except AttributeError: # Python 3 _baseclass_reprs = (object.__repr__,) def _default_pprint(obj, p, cycle): """ The default print function. Used if an object does not provide one and it's none of the builtin objects. """ klass = getattr(obj, '__class__', None) or type(obj) if getattr(klass, '__repr__', None) not in _baseclass_reprs: # A user-provided repr. p.text(repr(obj)) return p.begin_group(1, '<') p.pretty(klass) p.text(' at 0x%x' % id(obj)) if cycle: p.text(' ...') elif p.verbose: first = True for key in dir(obj): if not key.startswith('_'): try: value = getattr(obj, key) except AttributeError: continue if isinstance(value, types.MethodType): continue if not first: p.text(',') p.breakable() p.text(key) p.text('=') step = len(key) + 1 p.indentation += step p.pretty(value) p.indentation -= step first = False p.end_group(1, '>') def _seq_pprinter_factory(start, end, basetype): """ Factory that returns a pprint function useful for sequences. Used by the default pprint for tuples, dicts, lists, sets and frozensets. """ def inner(obj, p, cycle): typ = type(obj) if basetype is not None and typ is not basetype and typ.__repr__ != basetype.__repr__: # If the subclass provides its own repr, use it instead. return p.text(typ.__repr__(obj)) if cycle: return p.text(start + '...' + end) step = len(start) p.begin_group(step, start) for idx, x in enumerate(obj): if idx: p.text(',') p.breakable() p.pretty(x) if len(obj) == 1 and type(obj) is tuple: # Special case for 1-item tuples. p.text(',') p.end_group(step, end) return inner def _dict_pprinter_factory(start, end, basetype=None): """ Factory that returns a pprint function used by the default pprint of dicts and dict proxies. """ def inner(obj, p, cycle): typ = type(obj) if basetype is not None and typ is not basetype and typ.__repr__ != basetype.__repr__: # If the subclass provides its own repr, use it instead. return p.text(typ.__repr__(obj)) if cycle: return p.text('{...}') p.begin_group(1, start) keys = obj.keys() try: keys.sort() except Exception as e: # Sometimes the keys don't sort. pass for idx, key in enumerate(keys): if idx: p.text(',') p.breakable() p.pretty(key) p.text(': ') p.pretty(obj[key]) p.end_group(1, end) return inner def _super_pprint(obj, p, cycle): """The pprint for the super type.""" p.begin_group(8, '') def _re_pattern_pprint(obj, p, cycle): """The pprint function for regular expression patterns.""" p.text('re.compile(') pattern = repr(obj.pattern) if pattern[:1] in 'uU': pattern = pattern[1:] prefix = 'ur' else: prefix = 'r' pattern = prefix + pattern.replace('\\\\', '\\') p.text(pattern) if obj.flags: p.text(',') p.breakable() done_one = False for flag in ('TEMPLATE', 'IGNORECASE', 'LOCALE', 'MULTILINE', 'DOTALL', 'UNICODE', 'VERBOSE', 'DEBUG'): if obj.flags & getattr(re, flag): if done_one: p.text('|') p.text('re.' + flag) done_one = True p.text(')') def _type_pprint(obj, p, cycle): """The pprint for classes and types.""" try: mod = obj.__module__ except AttributeError: # Heap allocated types might not have the module attribute. return p.text(obj.__name__) if mod in ('__builtin__', 'exceptions'): name = obj.__name__ else: name = mod + '.' + obj.__name__ p.text(name) def _repr_pprint(obj, p, cycle): """A pprint that just redirects to the normal repr function.""" p.text(repr(obj)) def _function_pprint(obj, p, cycle): """Base pprint for all functions and builtin functions.""" if obj.__module__ in ('__builtin__', 'exceptions') or not obj.__module__: name = obj.__name__ else: name = obj.__module__ + '.' + obj.__name__ p.text('' % name) def _exception_pprint(obj, p, cycle): """Base pprint for all exceptions.""" if obj.__class__.__module__ in ('exceptions', 'builtins'): name = obj.__class__.__name__ else: name = '%s.%s' % ( obj.__class__.__module__, obj.__class__.__name__ ) step = len(name) + 1 p.begin_group(step, name + '(') for idx, arg in enumerate(getattr(obj, 'args', ())): if idx: p.text(',') p.breakable() p.pretty(arg) p.end_group(step, ')') #: the exception base try: _exception_base = BaseException except NameError: _exception_base = Exception #: printers for builtin types _type_pprinters = { int: _repr_pprint, long: _repr_pprint, float: _repr_pprint, str: _repr_pprint, unicode: _repr_pprint, tuple: _seq_pprinter_factory('(', ')', tuple), list: _seq_pprinter_factory('[', ']', list), dict: _dict_pprinter_factory('{', '}', dict), set: _seq_pprinter_factory('{', '}', set), frozenset: _seq_pprinter_factory('frozenset([', '])', frozenset), super: _super_pprint, _re_pattern_type: _re_pattern_pprint, type: _type_pprint, types.FunctionType: _function_pprint, types.BuiltinFunctionType: _function_pprint, types.SliceType: _repr_pprint, types.MethodType: _repr_pprint, datetime.datetime: _repr_pprint, datetime.timedelta: _repr_pprint, _exception_base: _exception_pprint } try: _type_pprinters[types.DictProxyType] = _dict_pprinter_factory('') _type_pprinters[types.ClassType] = _type_pprint except AttributeError: # Python 3 pass try: _type_pprinters[xrange] = _repr_pprint except NameError: _type_pprinters[range] = _repr_pprint #: printers for types specified by name _deferred_type_pprinters = { } def for_type(typ, func): """ Add a pretty printer for a given type. """ oldfunc = _type_pprinters.get(typ, None) if func is not None: # To support easy restoration of old pprinters, we need to ignore Nones. _type_pprinters[typ] = func return oldfunc def for_type_by_name(type_module, type_name, func): """ Add a pretty printer for a type specified by the module and name of a type rather than the type object itself. """ key = (type_module, type_name) oldfunc = _deferred_type_pprinters.get(key, None) if func is not None: # To support easy restoration of old pprinters, we need to ignore Nones. _deferred_type_pprinters[key] = func return oldfunc #: printers for the default singletons _singleton_pprinters = dict.fromkeys(map(id, [None, True, False, Ellipsis, NotImplemented]), _repr_pprint) if __name__ == '__main__': from random import randrange class Foo(object): def __init__(self): self.foo = 1 self.bar = re.compile(r'\s+') self.blub = dict.fromkeys(range(30), randrange(1, 40)) self.hehe = 23424.234234 self.list = ["blub", "blah", self] def get_foo(self): print "foo" pprint(Foo(), verbose=True)