I find it more conveniant to access dict keys as obj.foo instead of obj['foo'], so I wrote this snippet:

class AttributeDict(dict):
    def __getattr__(self, attr):
        return self[attr]
    def __setattr__(self, attr, value):
        self[attr] = value

However, I assume there must be some reason that Python doesn't provide this functionality out of the box. What would be the caveats and pitfalls of accessing dict keys in this manner?

  • 12
    If you're accessing hardcoded keys from a fixed-size limited set everywhere, you might be better off creating objects that hold these. collections.namedtuple is very useful for this. – user395760 Feb 13 '11 at 14:32
  • 5
    stackoverflow.com/questions/3031219/… has a similar solution but goes a step further – keflavich Nov 23 '11 at 0:10
  • Found a module for this at github.com/bcj/AttrDict. I don't know how it compares to the solutions here and in the related questions. – matt wilkie Nov 12 '14 at 0:52
  • I also used similar hacks, now I use easydict.EasyDict – muon May 23 at 18:52

23 Answers 23

The best way to do this is:

class AttrDict(dict):
    def __init__(self, *args, **kwargs):
        super(AttrDict, self).__init__(*args, **kwargs)
        self.__dict__ = self

Some pros:

  • It actually works!
  • No dictionary class methods are shadowed (e.g. .keys() work just fine)
  • Attributes and items are always in sync
  • Trying to access non-existent key as an attribute correctly raises AttributeError instead of KeyError

Cons:

  • Methods like .keys() will not work just fine if they get overwritten by incoming data
  • Causes a memory leak in Python < 2.7.4 / Python3 < 3.2.3
  • Pylint goes bananas with E1123(unexpected-keyword-arg) and E1103(maybe-no-member)
  • For the uninitiated it seems like pure magic.

A short explanation on how this works

  • All python objects internally store their attributes in a dictionary that is named __dict__.
  • There is no requirement that the internal dictionary __dict__ would need to be "just a plain dict", so we can assign any subclass of dict() to the internal dictionary.
  • In our case we simply assign the AttrDict() instance we are instantiating (as we are in __init__).
  • By calling super()'s __init__() method we made sure that it (already) behaves exactly like a dictionary, since that function calls all the dictionary instantiation code.

One reason why Python doesn't provide this functionality out of the box

As noted in the "cons" list, this combines the namespace of stored keys (which may come from arbitrary and/or untrusted data!) with the namespace of builtin dict method attributes. For example:

d = AttrDict()
d.update({'items':["jacket", "necktie", "trousers"]})
for k, v in d.items():    # TypeError: 'list' object is not callable
    print "Never reached!"
  • 1
    Do you think the memorry leak would occur with a simple object like: >>> class MyD(object): ... def init__(self, d): ... self.__dict = d – Rafe Apr 12 '13 at 19:22
  • Causes the leak even in 2.7 – pi. Jul 24 '13 at 14:01
  • 1
    Make that <= 2.7.3, as that's what I am using. – pi. Jul 25 '13 at 9:23
  • 10
    Just found this lib - pypi.python.org/pypi/attrdict – Yurik Aug 15 '14 at 1:56
  • 1
    In the 2.7.4 release notes they mention it fixed (not before). – Robert Siemer Apr 27 '15 at 6:13

You can have all legal string characters as part of the key if you use array notation. For example, obj['!#$%^&*()_']

  • 32
    +1 for actually answering the question – Izkata Jan 9 '13 at 17:41
  • 1
    @Izkata yes. funny thing about SE that there is usually a 'top question' ie. title, and a 'bottom question', perhaps because SE doesn't like to hear "title says it all"; the 'caveats' being the bottom one here. – n611x007 Apr 10 '14 at 12:22
  • 2
    Not that JavaScript is a particularly good example of programming language, but objects in JS support both attribute access and array notation, which allows convenience for the common case and a generic fallback for symbols that aren't legal attribute names. – André Caron Mar 29 '16 at 15:39
  • @Izkata How does this answer the question. This answer just says that keys can have any name. – Melab May 18 '17 at 15:42
  • 2
    @Melab The question is What would be the caveats and pitfalls of accessing dict keys in this manner? (as attributes), and the answer is that most of the characters shown here would not be useable. – Izkata May 18 '17 at 18:05

From This other SO question there's a great implementation example that simplifies your existing code. How about:

class AttributeDict(dict): 
    __getattr__ = dict.__getitem__
    __setattr__ = dict.__setitem__

Much more concise and doesn't leave any room for extra cruft getting into your __getattr__ and __setattr__ functions in the future.

  • 11
    You have to keep in mind that if you add new attributes at runtime they are not added to the dict itself but to the dict attribute. E.g. d = AttributeDict(foo=1). d.bar = 1 the bar attribute is stored inside the dict attribute but not in the dict itself. printing d shows only the foo item. – P3trus Jun 22 '12 at 13:56
  • 4
    -1 for sidestepping the question – Izkata Jan 9 '13 at 17:43
  • 5
    +1 because it works perfectly as far as I can tell. @GringoSuave, @Izkata, @P3trus I request anyone claiming it fails show an example that doesn’t work d = AttributeDict(foo=1);d.bar = 1;print d => {'foo': 1, 'bar': 1} Works for me! – Dave Abrahams Aug 23 '13 at 17:38
  • 4
    @DaveAbrahams Read the full question and look at answers by Hery, Ryan, and TheCommunistDuck. It's not asking about how to do this, but about problems that may arise. – Izkata Apr 10 '14 at 12:45
  • 4
    You should provide a __getattr__ method that raises an AttributeError if the given attribute doesn't exist, otherwise things like getattr(obj, attr, default_value) do not work (i.e. doesn't return default_value if attr doesn't exist on obj) – jcdude May 20 '14 at 8:57

Wherein I Answer the Question That Was Asked

Why doesn't Python offer it out of the box?

I suspect that it has to do with the Zen of Python: "There should be one -- and preferably only one -- obvious way to do it." This would create two obvious ways to access values from dictionaries: obj['key'] and obj.key.

Caveats and Pitfalls

These include possible lack of clarity and confusion in the code. i.e., the following could be confusing to someone else who is going in to maintain your code at a later date, or even to you, if you're not going back into it for awhile. Again, from Zen: "Readability counts!"

>>> KEY = 'spam'
>>> d[KEY] = 1
>>> # Several lines of miscellaneous code here...
... assert d.spam == 1

If d is instantiated or KEY is defined or d[KEY] is assigned far away from where d.spam is being used, it can easily lead to confusion about what's being done, since this isn't a commonly-used idiom. I know it would have the potential to confuse me.

Additonally, if you change the value of KEY as follows (but miss changing d.spam), you now get:

>>> KEY = 'foo'
>>> d[KEY] = 1
>>> # Several lines of miscellaneous code here...
... assert d.spam == 1
Traceback (most recent call last):
  File "<stdin>", line 2, in <module>
AttributeError: 'C' object has no attribute 'spam'

IMO, not worth the effort.

Other Items

As others have noted, you can use any hashable object (not just a string) as a dict key. For example,

>>> d = {(2, 3): True,}
>>> assert d[(2, 3)] is True
>>> 

is legal, but

>>> C = type('C', (object,), {(2, 3): True})
>>> d = C()
>>> assert d.(2, 3) is True
  File "<stdin>", line 1
  d.(2, 3)
    ^
SyntaxError: invalid syntax
>>> getattr(d, (2, 3))
Traceback (most recent call last):
  File "<stdin>", line 1, in <module>
TypeError: getattr(): attribute name must be string
>>> 

is not. This gives you access to the entire range of printable characters or other hashable objects for your dictionary keys, which you do not have when accessing an object attribute. This makes possible such magic as a cached object metaclass, like the recipe from the Python Cookbook (Ch. 9).

Wherein I Editorialize

I prefer the aesthetics of spam.eggs over spam['eggs'] (I think it looks cleaner), and I really started craving this functionality when I met the namedtuple. But the convenience of being able to do the following trumps it.

>>> KEYS = 'spam eggs ham'
>>> VALS = [1, 2, 3]
>>> d = {k: v for k, v in zip(KEYS.split(' '), VALS)}
>>> assert d == {'spam': 1, 'eggs': 2, 'ham': 3}
>>>

This is a simple example, but I frequently find myself using dicts in different situations than I'd use obj.key notation (i.e., when I need to read prefs in from an XML file). In other cases, where I'm tempted to instantiate a dynamic class and slap some attributes on it for aesthetic reasons, I continue to use a dict for consistency in order to enhance readability.

I'm sure the OP has long-since resolved this to his satisfaction, but if he still wants this functionality, then I suggest he download one of the packages from pypi that provides it:

  • Bunch is the one I'm more familiar with. Subclass of dict, so you have all that functionality.
  • AttrDict also looks like it's also pretty good, but I'm not as familiar with it and haven't looked through the source in as much detail as I have Bunch.
  • As noted in the comments by Rotareti, Bunch has been deprecated, but there is an active fork called Munch.

However, in order to improve readability of his code I strongly recommend that he not mix his notation styles. If he prefers this notation then he should simply instantiate a dynamic object, add his desired attributes to it, and call it a day:

>>> C = type('C', (object,), {})
>>> d = C()
>>> d.spam = 1
>>> d.eggs = 2
>>> d.ham = 3
>>> assert d.__dict__ == {'spam': 1, 'eggs': 2, 'ham': 3}


Wherein I Update, to Answer a Follow-Up Question in the Comments

In the comments (below), Elmo asks:

What if you want to go one deeper? ( referring to type(...) )

While I've never used this use case (again, I tend to use nested dict, for consistency), the following code works:

>>> C = type('C', (object,), {})
>>> d = C()
>>> for x in 'spam eggs ham'.split():
...     setattr(d, x, C())
...     i = 1
...     for y in 'one two three'.split():
...         setattr(getattr(d, x), y, i)
...         i += 1
...
>>> assert d.spam.__dict__ == {'one': 1, 'two': 2, 'three': 3}
  • 1
    Super cool! Love the type usage – saranicole Jan 25 '16 at 21:03
  • 1
    Bunch is deprecated, but there is an active fork of it: github.com/Infinidat/munch – Rotareti Jun 13 '17 at 14:57
  • @Rotareti - Thanks for the heads-up! This isn't functionality I use, so I was unaware of that. – Doug R. Jun 13 '17 at 16:10
  • What if you want to go one deeper? ( referring to type(...) ) – Elmo May 31 at 5:37
  • 1
    @Elmo - See update. – Doug R. May 31 at 13:10

What if you wanted a key which was a method, such as __eq__ or __getattr__?

And you wouldn't be able to have an entry that didn't start with a letter, so using 0343853 as a key is out.

And what if you didn't want to use a string?

  • Indeed, or for example other objects as keys. However I would classify the error from that as 'expected behaviour' - with my question I was more aiming towards the unexpected. – Izz ad-Din Ruhulessin Feb 13 '11 at 14:34
  • 2
    +1 for actually answering the question – Izkata Jan 9 '13 at 17:42
  • pickle.dump uses __getstate__ – Cees Timmerman Jul 7 '15 at 16:08

Caveat emptor: For some reasons classes like this seem to break the multiprocessing package. I just struggled with this bug for awhile before finding this SO: Finding exception in python multiprocessing

  • 5
    +1 for actually answering the question – Izkata Jan 9 '13 at 17:42

You can pull a convenient container class from the standard library:

from argparse import Namespace

to avoid having to copy around code bits. No standard dictionary access, but easy to get one back if you really want it. The code in argparse is simple,

class Namespace(_AttributeHolder):
    """Simple object for storing attributes.

    Implements equality by attribute names and values, and provides a simple
    string representation.
    """

    def __init__(self, **kwargs):
        for name in kwargs:
            setattr(self, name, kwargs[name])

    __hash__ = None

    def __eq__(self, other):
        return vars(self) == vars(other)

    def __ne__(self, other):
        return not (self == other)

    def __contains__(self, key):
        return key in self.__dict__

tuples can be used dict keys. How would you access tuple in your construct?

Also, namedtuple is a convenient structure which can provide values via the attribute access.

  • 5
    The drawback of namedtuples is that they are immutable. – Izz ad-Din Ruhulessin Feb 13 '11 at 14:41
  • 8
    Some would say that being immutable is not a bug but a feature of tuples. – ben author Mar 26 '13 at 0:42

It doesn't work in generality. Not all valid dict keys make addressable attributes ("the key"). So, you'll need to be careful.

Python objects are all basically dictionaries. So I doubt there is much performance or other penalty.

Here's a short example of immutable records using built-in collections.namedtuple:

def record(name, d):
    return namedtuple(name, d.keys())(**d)

and a usage example:

rec = record('Model', {
    'train_op': train_op,
    'loss': loss,
})

print rec.loss(..)
  • ....very clever – blakev Apr 7 '16 at 21:43

No need to write your own as setattr() and getattr() already exist.

The advantage of class objects probably comes into play in class definition and inheritance.

I created this based on the input from this thread. I need to use odict though, so I had to override get and set attr. I think this should work for the majority of special uses.

Usage looks like this:

# Create an ordered dict normally...
>>> od = OrderedAttrDict()
>>> od["a"] = 1
>>> od["b"] = 2
>>> od
OrderedAttrDict([('a', 1), ('b', 2)])

# Get and set data using attribute access...
>>> od.a
1
>>> od.b = 20
>>> od
OrderedAttrDict([('a', 1), ('b', 20)])

# Setting a NEW attribute only creates it on the instance, not the dict...
>>> od.c = 8
>>> od
OrderedAttrDict([('a', 1), ('b', 20)])
>>> od.c
8

The class:

class OrderedAttrDict(odict.OrderedDict):
    """
    Constructs an odict.OrderedDict with attribute access to data.

    Setting a NEW attribute only creates it on the instance, not the dict.
    Setting an attribute that is a key in the data will set the dict data but 
    will not create a new instance attribute
    """
    def __getattr__(self, attr):
        """
        Try to get the data. If attr is not a key, fall-back and get the attr
        """
        if self.has_key(attr):
            return super(OrderedAttrDict, self).__getitem__(attr)
        else:
            return super(OrderedAttrDict, self).__getattr__(attr)


    def __setattr__(self, attr, value):
        """
        Try to set the data. If attr is not a key, fall-back and set the attr
        """
        if self.has_key(attr):
            super(OrderedAttrDict, self).__setitem__(attr, value)
        else:
            super(OrderedAttrDict, self).__setattr__(attr, value)

This is a pretty cool pattern already mentioned in the thread, but if you just want to take a dict and convert it to an object that works with auto-complete in an IDE, etc:

class ObjectFromDict(object):
    def __init__(self, d):
        self.__dict__ = d

This doesn't address the original question, but should be useful for people that, like me, end up here when looking for a lib that provides this functionality.

Addict it's a great lib for this: https://github.com/mewwts/addict it takes care of many concerns mentioned in previous answers.

An example from the docs:

body = {
    'query': {
        'filtered': {
            'query': {
                'match': {'description': 'addictive'}
            },
            'filter': {
                'term': {'created_by': 'Mats'}
            }
        }
    }
}

With addict:

from addict import Dict
body = Dict()
body.query.filtered.query.match.description = 'addictive'
body.query.filtered.filter.term.created_by = 'Mats'

Apparently there is now a library for this - https://pypi.python.org/pypi/attrdict - which implements this exact functionality plus recursive merging and json loading. Might be worth a look.

Let me post another implementation, which builds upon the answer of Kinvais, but integrates ideas from the AttributeDict proposed in http://databio.org/posts/python_AttributeDict.html.

The advantage of this version is that it also works for nested dictionaries:

class AttrDict(dict):
    """
    A class to convert a nested Dictionary into an object with key-values
    that are accessible using attribute notation (AttrDict.attribute) instead of
    key notation (Dict["key"]). This class recursively sets Dicts to objects,
    allowing you to recurse down nested dicts (like: AttrDict.attr.attr)
    """

    # Inspired by:
    # http://stackoverflow.com/a/14620633/1551810
    # http://databio.org/posts/python_AttributeDict.html

    def __init__(self, iterable, **kwargs):
        super(AttrDict, self).__init__(iterable, **kwargs)
        for key, value in iterable.items():
            if isinstance(value, dict):
                self.__dict__[key] = AttrDict(value)
            else:
                self.__dict__[key] = value

Just to add some variety to the answer, sci-kit learn has this implemented as a Bunch:

class Bunch(dict):                                                              
    """ Scikit Learn's container object                                         

    Dictionary-like object that exposes its keys as attributes.                 
    >>> b = Bunch(a=1, b=2)                                                     
    >>> b['b']                                                                  
    2                                                                           
    >>> b.b                                                                     
    2                                                                           
    >>> b.c = 6                                                                 
    >>> b['c']                                                                  
    6                                                                           
    """                                                                         

    def __init__(self, **kwargs):                                               
        super(Bunch, self).__init__(kwargs)                                     

    def __setattr__(self, key, value):                                          
        self[key] = value                                                       

    def __dir__(self):                                                          
        return self.keys()                                                      

    def __getattr__(self, key):                                                 
        try:                                                                    
            return self[key]                                                    
        except KeyError:                                                        
            raise AttributeError(key)                                           

    def __setstate__(self, state):                                              
        pass                       

All you need is to get the setattr and getattr methods - the getattr checks for dict keys and the moves on to checking for actual attributes. The setstaet is a fix for fix for pickling/unpickling "bunches" - if inerested check https://github.com/scikit-learn/scikit-learn/issues/6196

You can do it using this class I just made. With this class you can use the Map object like another dictionary(including json serialization) or with the dot notation. I hope help you:

class Map(dict):
    """
    Example:
    m = Map({'first_name': 'Eduardo'}, last_name='Pool', age=24, sports=['Soccer'])
    """
    def __init__(self, *args, **kwargs):
        super(Map, self).__init__(*args, **kwargs)
        for arg in args:
            if isinstance(arg, dict):
                for k, v in arg.iteritems():
                    self[k] = v

        if kwargs:
            for k, v in kwargs.iteritems():
                self[k] = v

    def __getattr__(self, attr):
        return self.get(attr)

    def __setattr__(self, key, value):
        self.__setitem__(key, value)

    def __setitem__(self, key, value):
        super(Map, self).__setitem__(key, value)
        self.__dict__.update({key: value})

    def __delattr__(self, item):
        self.__delitem__(item)

    def __delitem__(self, key):
        super(Map, self).__delitem__(key)
        del self.__dict__[key]

Usage examples:

m = Map({'first_name': 'Eduardo'}, last_name='Pool', age=24, sports=['Soccer'])
# Add new key
m.new_key = 'Hello world!'
print m.new_key
print m['new_key']
# Update values
m.new_key = 'Yay!'
# Or
m['new_key'] = 'Yay!'
# Delete key
del m.new_key
# Or
del m['new_key']
  • 1
    Note that it can shadow dict methods, e.g.: m=Map(); m["keys"] = 42; m.keys() gives TypeError: 'int' object is not callable. – bfontaine Sep 23 '16 at 13:42
  • @bfontaine The idea is to be a kind of field/attribute and not a method, but if you assign a method instead a number you can access that method with m.method(). – epool Sep 23 '16 at 15:46
class AttrDict(dict):

     def __init__(self):
           self.__dict__ = self

if __name__ == '____main__':

     d = AttrDict()
     d['ray'] = 'hope'
     d.sun = 'shine'  >>> Now we can use this . notation
     print d['ray']
     print d.sun

As noted by Doug there's a Bunch package which you can use to achieve the obj.key functionality. Actually there's a newer version called

NeoBunch

It has though a great feature converting your dict to a NeoBunch object through its neobunchify function. I use Mako templates a lot and passing data as NeoBunch objects makes them far more readable, so if you happen to end up using a normal dict in your Python program but want the dot notation in a Mako template you can use it that way:

from mako.template import Template
from neobunch import neobunchify

mako_template = Template(filename='mako.tmpl', strict_undefined=True)
data = {'tmpl_data': [{'key1': 'value1', 'key2': 'value2'}]}
with open('out.txt', 'w') as out_file:
    out_file.write(mako_template.render(**neobunchify(data)))

And the Mako template could look like:

% for d in tmpl_data:
Column1     Column2
${d.key1}   ${d.key2}
% endfor

Solution is:

DICT_RESERVED_KEYS = vars(dict).keys()


class SmartDict(dict):
    """
    A Dict which is accessible via attribute dot notation
    """
    def __init__(self, *args, **kwargs):
        """
        :param args: multiple dicts ({}, {}, ..)
        :param kwargs: arbitrary keys='value'

        If ``keyerror=False`` is passed then not found attributes will
        always return None.
        """
        super(SmartDict, self).__init__()
        self['__keyerror'] = kwargs.pop('keyerror', True)
        [self.update(arg) for arg in args if isinstance(arg, dict)]
        self.update(kwargs)

    def __getattr__(self, attr):
        if attr not in DICT_RESERVED_KEYS:
            if self['__keyerror']:
                return self[attr]
            else:
                return self.get(attr)
        return getattr(self, attr)

    def __setattr__(self, key, value):
        if key in DICT_RESERVED_KEYS:
            raise AttributeError("You cannot set a reserved name as attribute")
        self.__setitem__(key, value)

    def __copy__(self):
        return self.__class__(self)

    def copy(self):
        return self.__copy__()

How about Prodict, the little Python class that I wrote to rule them all:)

Plus, you get auto code completion, recursive object instantiations and auto type conversion!

You can do exactly what you asked for:

p = Prodict()
p.foo = 1
p.bar = "baz"

Example 1: Type hinting

class Country(Prodict):
    name: str
    population: int

turkey = Country()
turkey.name = 'Turkey'
turkey.population = 79814871

auto code complete

Example 2: Auto type conversion

germany = Country(name='Germany', population='82175700', flag_colors=['black', 'red', 'yellow'])

print(germany.population)  # 82175700
print(type(germany.population))  # <class 'int'>

print(germany.flag_colors)  # ['black', 'red', 'yellow']
print(type(germany.flag_colors))  # <class 'list'>
  • installs on python2 via pip, but doesn't work on python2 – Ant6n Sep 7 at 2:46
  • @Ant6n requires python 3.6+ because of type annotations – Ramazan Polat Sep 7 at 9:52

This isn't a 'good' answer, but I thought this was nifty (it doesn't handle nested dicts in current form). Simply wrap your dict in a function:

def make_funcdict(d={}, **kwargs)
    def funcdict(d={}, **kwargs):
        funcdict.__dict__.update(d)
        funcdict.__dict__.update(kwargs)
        return funcdict.__dict__
    funcdict(d, **kwargs)
    return funcdict

Now you have slightly different syntax. To acces the dict items as attributes do f.key. To access the dict items (and other dict methods) in the usual manner do f()['key'] and we can conveniently update the dict by calling f with keyword arguments and/or a dictionary

Example

d = {'name':'Henry', 'age':31}
d = make_funcdict(d)
>>> for key in d():
...     print key
... 
age
name
>>> print d.name
... Henry
>>> print d.age
... 31
>>> d({'Height':'5-11'}, Job='Carpenter')
... {'age': 31, 'name': 'Henry', 'Job': 'Carpenter', 'Height': '5-11'}

And there it is. I'll be happy if anyone suggests benefits and drawbacks of this method.

What would be the caveats and pitfalls of accessing dict keys in this manner?

As @Henry suggests, one reason dotted-access may not be used in dicts is that it limits dict key names to python-valid variables, thereby restricting all possible names.

The following are examples on why dotted-access would not be helpful in general, given a dict, d:

Validity

The following attributes would be invalid in Python:

d.1_foo                           # enumerated names
d./bar                            # path names
d.21.7, d.12:30                   # decimals, time
d.""                              # empty strings
d.john doe, d.denny's             # spaces, misc punctuation 
d.3 * x                           # expressions  

Style

PEP8 conventions would impose a soft constraint on attribute naming:

A. Reserved keyword (or builtin function) names:

d.in
d.False, d.True
d.max, d.min
d.sum
d.id

If a function argument's name clashes with a reserved keyword, it is generally better to append a single trailing underscore ...

B. The case rule on methods and variable names:

Variable names follow the same convention as function names.

d.Firstname
d.Country

Use the function naming rules: lowercase with words separated by underscores as necessary to improve readability.


Sometimes these concerns are raised in libraries like pandas, which permits dotted-access of DataFrame columns by name. The default mechanism to resolve naming restrictions is also array-notation - a string within brackets.

If these constraints do not apply to your use case, there are several options on dotted-access data structures.

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