# -*- coding: utf-8 -*- """Display formatters. Inheritance diagram: .. inheritance-diagram:: IPython.core.formatters :parts: 3 """ # Copyright (c) IPython Development Team. # Distributed under the terms of the Modified BSD License. import abc import json import sys import traceback import warnings from decorator import decorator from traitlets.config.configurable import Configurable from IPython.core.getipython import get_ipython from IPython.utils.sentinel import Sentinel from IPython.utils.dir2 import get_real_method from IPython.lib import pretty from traitlets import ( Bool, Dict, Integer, Unicode, CUnicode, ObjectName, List, ForwardDeclaredInstance, default, observe, ) from IPython.utils.py3compat import ( with_metaclass, string_types, unicode_type, ) class DisplayFormatter(Configurable): # When set to true only the default plain text formatter will be used. plain_text_only = Bool(False).tag(config=True) def _plain_text_only_changed(self, name, old, new): warnings.warn("""DisplayFormatter.plain_text_only is deprecated. It will be removed in IPython 5.0 Use DisplayFormatter.active_types = ['text/plain'] for the same effect. """, DeprecationWarning) if new: self.active_types = ['text/plain'] else: self.active_types = self.format_types active_types = List(Unicode(), help="""List of currently active mime-types to display. You can use this to set a white-list for formats to display. Most users will not need to change this value. """).tag(config=True) @default('active_types') def _active_types_default(self): return self.format_types @observe('active_types') def _active_types_changed(self, change): for key, formatter in self.formatters.items(): if key in change['new']: formatter.enabled = True else: formatter.enabled = False ipython_display_formatter = ForwardDeclaredInstance('FormatterABC') @default('ipython_display_formatter') def _default_formatter(self): return IPythonDisplayFormatter(parent=self) # A dict of formatter whose keys are format types (MIME types) and whose # values are subclasses of BaseFormatter. formatters = Dict() @default('formatters') def _formatters_default(self): """Activate the default formatters.""" formatter_classes = [ PlainTextFormatter, HTMLFormatter, MarkdownFormatter, SVGFormatter, PNGFormatter, PDFFormatter, JPEGFormatter, LatexFormatter, JSONFormatter, JavascriptFormatter ] d = {} for cls in formatter_classes: f = cls(parent=self) d[f.format_type] = f return d def format(self, obj, include=None, exclude=None): """Return a format data dict for an object. By default all format types will be computed. The following MIME types are currently implemented: * text/plain * text/html * text/markdown * text/latex * application/json * application/javascript * application/pdf * image/png * image/jpeg * image/svg+xml Parameters ---------- obj : object The Python object whose format data will be computed. include : list or tuple, optional A list of format type strings (MIME types) to include in the format data dict. If this is set *only* the format types included in this list will be computed. exclude : list or tuple, optional A list of format type string (MIME types) to exclude in the format data dict. If this is set all format types will be computed, except for those included in this argument. Returns ------- (format_dict, metadata_dict) : tuple of two dicts format_dict is a dictionary of key/value pairs, one of each format that was generated for the object. The keys are the format types, which will usually be MIME type strings and the values and JSON'able data structure containing the raw data for the representation in that format. metadata_dict is a dictionary of metadata about each mime-type output. Its keys will be a strict subset of the keys in format_dict. """ format_dict = {} md_dict = {} if self.ipython_display_formatter(obj): # object handled itself, don't proceed return {}, {} for format_type, formatter in self.formatters.items(): if include and format_type not in include: continue if exclude and format_type in exclude: continue md = None try: data = formatter(obj) except: # FIXME: log the exception raise # formatters can return raw data or (data, metadata) if isinstance(data, tuple) and len(data) == 2: data, md = data if data is not None: format_dict[format_type] = data if md is not None: md_dict[format_type] = md return format_dict, md_dict @property def format_types(self): """Return the format types (MIME types) of the active formatters.""" return list(self.formatters.keys()) #----------------------------------------------------------------------------- # Formatters for specific format types (text, html, svg, etc.) #----------------------------------------------------------------------------- def _safe_repr(obj): """Try to return a repr of an object always returns a string, at least. """ try: return repr(obj) except Exception as e: return "un-repr-able object (%r)" % e class FormatterWarning(UserWarning): """Warning class for errors in formatters""" @decorator def catch_format_error(method, self, *args, **kwargs): """show traceback on failed format call""" try: r = method(self, *args, **kwargs) except NotImplementedError: # don't warn on NotImplementedErrors return None except Exception: exc_info = sys.exc_info() ip = get_ipython() if ip is not None: ip.showtraceback(exc_info) else: traceback.print_exception(*exc_info) return None return self._check_return(r, args[0]) class FormatterABC(with_metaclass(abc.ABCMeta, object)): """ Abstract base class for Formatters. A formatter is a callable class that is responsible for computing the raw format data for a particular format type (MIME type). For example, an HTML formatter would have a format type of `text/html` and would return the HTML representation of the object when called. """ # The format type of the data returned, usually a MIME type. format_type = 'text/plain' # Is the formatter enabled... enabled = True @abc.abstractmethod def __call__(self, obj): """Return a JSON'able representation of the object. If the object cannot be formatted by this formatter, warn and return None. """ return repr(obj) def _mod_name_key(typ): """Return a (__module__, __name__) tuple for a type. Used as key in Formatter.deferred_printers. """ module = getattr(typ, '__module__', None) name = getattr(typ, '__name__', None) return (module, name) def _get_type(obj): """Return the type of an instance (old and new-style)""" return getattr(obj, '__class__', None) or type(obj) _raise_key_error = Sentinel('_raise_key_error', __name__, """ Special value to raise a KeyError Raise KeyError in `BaseFormatter.pop` if passed as the default value to `pop` """) class BaseFormatter(Configurable): """A base formatter class that is configurable. This formatter should usually be used as the base class of all formatters. It is a traited :class:`Configurable` class and includes an extensible API for users to determine how their objects are formatted. The following logic is used to find a function to format an given object. 1. The object is introspected to see if it has a method with the name :attr:`print_method`. If is does, that object is passed to that method for formatting. 2. If no print method is found, three internal dictionaries are consulted to find print method: :attr:`singleton_printers`, :attr:`type_printers` and :attr:`deferred_printers`. Users should use these dictionaries to register functions that will be used to compute the format data for their objects (if those objects don't have the special print methods). The easiest way of using these dictionaries is through the :meth:`for_type` and :meth:`for_type_by_name` methods. If no function/callable is found to compute the format data, ``None`` is returned and this format type is not used. """ format_type = Unicode('text/plain') _return_type = string_types enabled = Bool(True).tag(config=True) print_method = ObjectName('__repr__') # The singleton printers. # Maps the IDs of the builtin singleton objects to the format functions. singleton_printers = Dict().tag(config=True) # The type-specific printers. # Map type objects to the format functions. type_printers = Dict().tag(config=True) # The deferred-import type-specific printers. # Map (modulename, classname) pairs to the format functions. deferred_printers = Dict().tag(config=True) @catch_format_error def __call__(self, obj): """Compute the format for an object.""" if self.enabled: # lookup registered printer try: printer = self.lookup(obj) except KeyError: pass else: return printer(obj) # Finally look for special method names method = get_real_method(obj, self.print_method) if method is not None: return method() return None else: return None def __contains__(self, typ): """map in to lookup_by_type""" try: self.lookup_by_type(typ) except KeyError: return False else: return True def _check_return(self, r, obj): """Check that a return value is appropriate Return the value if so, None otherwise, warning if invalid. """ if r is None or isinstance(r, self._return_type) or \ (isinstance(r, tuple) and r and isinstance(r[0], self._return_type)): return r else: warnings.warn( "%s formatter returned invalid type %s (expected %s) for object: %s" % \ (self.format_type, type(r), self._return_type, _safe_repr(obj)), FormatterWarning ) def lookup(self, obj): """Look up the formatter for a given instance. Parameters ---------- obj : object instance Returns ------- f : callable The registered formatting callable for the type. Raises ------ KeyError if the type has not been registered. """ # look for singleton first obj_id = id(obj) if obj_id in self.singleton_printers: return self.singleton_printers[obj_id] # then lookup by type return self.lookup_by_type(_get_type(obj)) def lookup_by_type(self, typ): """Look up the registered formatter for a type. Parameters ---------- typ : type or '__module__.__name__' string for a type Returns ------- f : callable The registered formatting callable for the type. Raises ------ KeyError if the type has not been registered. """ if isinstance(typ, string_types): typ_key = tuple(typ.rsplit('.',1)) if typ_key not in self.deferred_printers: # We may have it cached in the type map. We will have to # iterate over all of the types to check. for cls in self.type_printers: if _mod_name_key(cls) == typ_key: return self.type_printers[cls] else: return self.deferred_printers[typ_key] else: for cls in pretty._get_mro(typ): if cls in self.type_printers or self._in_deferred_types(cls): return self.type_printers[cls] # If we have reached here, the lookup failed. raise KeyError("No registered printer for {0!r}".format(typ)) def for_type(self, typ, func=None): """Add a format function for a given type. Parameters ----------- typ : type or '__module__.__name__' string for a type The class of the object that will be formatted using `func`. func : callable A callable for computing the format data. `func` will be called with the object to be formatted, and will return the raw data in this formatter's format. Subclasses may use a different call signature for the `func` argument. If `func` is None or not specified, there will be no change, only returning the current value. Returns ------- oldfunc : callable The currently registered callable. If you are registering a new formatter, this will be the previous value (to enable restoring later). """ # if string given, interpret as 'pkg.module.class_name' if isinstance(typ, string_types): type_module, type_name = typ.rsplit('.', 1) return self.for_type_by_name(type_module, type_name, func) try: oldfunc = self.lookup_by_type(typ) except KeyError: oldfunc = None if func is not None: self.type_printers[typ] = func return oldfunc def for_type_by_name(self, type_module, type_name, func=None): """Add a format function for a type specified by the full dotted module and name of the type, rather than the type of the object. Parameters ---------- type_module : str The full dotted name of the module the type is defined in, like ``numpy``. type_name : str The name of the type (the class name), like ``dtype`` func : callable A callable for computing the format data. `func` will be called with the object to be formatted, and will return the raw data in this formatter's format. Subclasses may use a different call signature for the `func` argument. If `func` is None or unspecified, there will be no change, only returning the current value. Returns ------- oldfunc : callable The currently registered callable. If you are registering a new formatter, this will be the previous value (to enable restoring later). """ key = (type_module, type_name) try: oldfunc = self.lookup_by_type("%s.%s" % key) except KeyError: oldfunc = None if func is not None: self.deferred_printers[key] = func return oldfunc def pop(self, typ, default=_raise_key_error): """Pop a formatter for the given type. Parameters ---------- typ : type or '__module__.__name__' string for a type default : object value to be returned if no formatter is registered for typ. Returns ------- obj : object The last registered object for the type. Raises ------ KeyError if the type is not registered and default is not specified. """ if isinstance(typ, string_types): typ_key = tuple(typ.rsplit('.',1)) if typ_key not in self.deferred_printers: # We may have it cached in the type map. We will have to # iterate over all of the types to check. for cls in self.type_printers: if _mod_name_key(cls) == typ_key: old = self.type_printers.pop(cls) break else: old = default else: old = self.deferred_printers.pop(typ_key) else: if typ in self.type_printers: old = self.type_printers.pop(typ) else: old = self.deferred_printers.pop(_mod_name_key(typ), default) if old is _raise_key_error: raise KeyError("No registered value for {0!r}".format(typ)) return old def _in_deferred_types(self, cls): """ Check if the given class is specified in the deferred type 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) if key in self.deferred_printers: # Move the printer over to the regular registry. printer = self.deferred_printers.pop(key) self.type_printers[cls] = printer return True return False class PlainTextFormatter(BaseFormatter): """The default pretty-printer. This uses :mod:`IPython.lib.pretty` to compute the format data of the object. If the object cannot be pretty printed, :func:`repr` is used. See the documentation of :mod:`IPython.lib.pretty` for details on how to write pretty printers. Here is a simple example:: def dtype_pprinter(obj, p, cycle): if cycle: return p.text('dtype(...)') if hasattr(obj, 'fields'): if obj.fields is None: p.text(repr(obj)) else: p.begin_group(7, 'dtype([') for i, field in enumerate(obj.descr): if i > 0: p.text(',') p.breakable() p.pretty(field) p.end_group(7, '])') """ # The format type of data returned. format_type = Unicode('text/plain') # This subclass ignores this attribute as it always need to return # something. enabled = Bool(True).tag(config=False) max_seq_length = Integer(pretty.MAX_SEQ_LENGTH, help="""Truncate large collections (lists, dicts, tuples, sets) to this size. Set to 0 to disable truncation. """ ).tag(config=True) # Look for a _repr_pretty_ methods to use for pretty printing. print_method = ObjectName('_repr_pretty_') # Whether to pretty-print or not. pprint = Bool(True).tag(config=True) # Whether to be verbose or not. verbose = Bool(False).tag(config=True) # The maximum width. max_width = Integer(79).tag(config=True) # The newline character. newline = Unicode('\n').tag(config=True) # format-string for pprinting floats float_format = Unicode('%r') # setter for float precision, either int or direct format-string float_precision = CUnicode('').tag(config=True) def _float_precision_changed(self, name, old, new): """float_precision changed, set float_format accordingly. float_precision can be set by int or str. This will set float_format, after interpreting input. If numpy has been imported, numpy print precision will also be set. integer `n` sets format to '%.nf', otherwise, format set directly. An empty string returns to defaults (repr for float, 8 for numpy). This parameter can be set via the '%precision' magic. """ if '%' in new: # got explicit format string fmt = new try: fmt%3.14159 except Exception: raise ValueError("Precision must be int or format string, not %r"%new) elif new: # otherwise, should be an int try: i = int(new) assert i >= 0 except ValueError: raise ValueError("Precision must be int or format string, not %r"%new) except AssertionError: raise ValueError("int precision must be non-negative, not %r"%i) fmt = '%%.%if'%i if 'numpy' in sys.modules: # set numpy precision if it has been imported import numpy numpy.set_printoptions(precision=i) else: # default back to repr fmt = '%r' if 'numpy' in sys.modules: import numpy # numpy default is 8 numpy.set_printoptions(precision=8) self.float_format = fmt # Use the default pretty printers from IPython.lib.pretty. @default('singleton_printers') def _singleton_printers_default(self): return pretty._singleton_pprinters.copy() @default('type_printers') def _type_printers_default(self): d = pretty._type_pprinters.copy() d[float] = lambda obj,p,cycle: p.text(self.float_format%obj) return d @default('deferred_printers') def _deferred_printers_default(self): return pretty._deferred_type_pprinters.copy() #### FormatterABC interface #### @catch_format_error def __call__(self, obj): """Compute the pretty representation of the object.""" if not self.pprint: return repr(obj) else: # handle str and unicode on Python 2 # io.StringIO only accepts unicode, # cStringIO doesn't handle unicode on py2, # StringIO allows str, unicode but only ascii str stream = pretty.CUnicodeIO() printer = pretty.RepresentationPrinter(stream, self.verbose, self.max_width, self.newline, max_seq_length=self.max_seq_length, singleton_pprinters=self.singleton_printers, type_pprinters=self.type_printers, deferred_pprinters=self.deferred_printers) printer.pretty(obj) printer.flush() return stream.getvalue() class HTMLFormatter(BaseFormatter): """An HTML formatter. To define the callables that compute the HTML representation of your objects, define a :meth:`_repr_html_` method or use the :meth:`for_type` or :meth:`for_type_by_name` methods to register functions that handle this. The return value of this formatter should be a valid HTML snippet that could be injected into an existing DOM. It should *not* include the ````` or ```
`` tags. """ format_type = Unicode('text/html') print_method = ObjectName('_repr_html_') class MarkdownFormatter(BaseFormatter): """A Markdown formatter. To define the callables that compute the Markdown representation of your objects, define a :meth:`_repr_markdown_` method or use the :meth:`for_type` or :meth:`for_type_by_name` methods to register functions that handle this. The return value of this formatter should be a valid Markdown. """ format_type = Unicode('text/markdown') print_method = ObjectName('_repr_markdown_') class SVGFormatter(BaseFormatter): """An SVG formatter. To define the callables that compute the SVG representation of your objects, define a :meth:`_repr_svg_` method or use the :meth:`for_type` or :meth:`for_type_by_name` methods to register functions that handle this. The return value of this formatter should be valid SVG enclosed in ```