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I have a dictionary of objects:

# I have thousands of objects in my real world scenario
dic = {'k1':obj1, 'k2':obj2, 'k3':obj3, ...}
# keys are string
# objs are MyObject

Edit: Sorry for letting doubt in the question. Here is the exact class and the like() function:

class MyObject(object):
    def __init__(self, period, dimensions):
        self.id = None
        self.period = period # period is etree.Element
        self.dimensions = dict() # id -> lxml.XMLElements
        for dim in dimensions:
            # there must be only one child: the typed dimension
            self.dimensions[dim.get('dimension')] = dim[0]
        self._hash = None

    def __eq__(self, other):
        return isinstance(other, MyObject)
            and self.period == other.period
            and self.dimensions == other.dimensions

    def like(self, other):
        return (other is not None \
            and self.period == other.period \
           and self.dimensions.keys() == other.dimensions.keys())

I wonder how I can have the best implementation for finding objects in dictionary dic that are similar to a given value val. Something equivalent to:

def find_keys(dic, val):
    return [v for v in dic if v.like(val))

However this method is too slow, because I have thousands of iterations over find-keys() and thousands objects in the dictionary.

Right now, I have implemented a __hash__(self) on these objects, and added the key as a property:

    def __hash__(self):
        if self._hash is None:
            self._hash = hash(self.periodtype) ^ \
                hash(tuple(sorted(self.dimensions.values())))
        return self._hash

Then, I have built a lookup dictionary that is

hash_dic = { hash(obj1): [obj1], hash(obj2): [obj2, obj3] }

And this new search method is much faster:

def find_keys_fast(dic, val):
    prefetched=hash_dic[hash(val)]
    return [x.key for x in prefetched if x.like(val)]

Since __hash__ is a native function internally used by Sets and Dictionaries, is there anything faster or more elegant I could do?

share|improve this question
1  
building key basing on hash is nice idea, but i wouldnt override the original hash whit this. –  Adam Jurczyk Jul 19 '11 at 15:03
    
You don't need to call hash explicitly on dictionary keys, it's done automatically. –  Michael J. Barber Jul 19 '11 at 16:47
    
but what exactly is going on? tell us more about your problem, how does the like function look like? I can't see how clustering by x helps you as you don't use it in like method at all. –  tomasz Jul 19 '11 at 17:17
    
@rds Looking at the diverse responses, it's pretty clear that no one really knows what is being asked. Please try to clarify, if you can. –  Michael J. Barber Jul 20 '11 at 5:28
    
to all, thanks for reading the question. I understand it was not precise enough and have given as much details as I could. –  rds Jul 20 '11 at 8:14

6 Answers 6

up vote 2 down vote accepted

Now that we can see the implementation of like, a quite simple approach seems feasible---far simpler than my other answer, for one. Define a new signature method on MyObject:

def signature(self):
    return (self.period, frozenset(self.dimensions.keys()))

And then iterate through the objects:

import collections
sig_keys = collections.defaultdict(set)
for k, obj in dic.iteritems():
    sig_keys[obj.signature()].add(k)

With that, sig_keys.values() gives all the sets of identifiers for objects which are alike. Lists of objects could instead be directly constructed, if that would better:

sig_objs = collections.defaultdict(list)
for obj in dic.itervalues():
    sig_objs[obj.signature()].append(obj)

If you want, you could define __hash__ to return hash(self.signature()) or the equivalent.

share|improve this answer
    
+1: This looks simple and direct enough. –  EOL Jul 20 '11 at 14:38
    
I Have reimplemented my program using this solution. In terms of performance, it is very close to the hash solution I was exposing in my question. The benefit of this solution is that it becomes unnecessary to define find_keys_fast() since it is simply hash_dic[val.signature()]. The disadvantage is that signature() is not a python function (contrary to __hash__() and it's pending hash()). Overall, I think the code is more redable than it was originally. Thanks for your thoughts on this topic. –  rds Aug 16 '11 at 7:43

Since I don't know the structure of your data or the nature of the similarity you are seeking, I can only guess at what might work. But perhaps you could build some kind of prefix tree using dictionaries. As in:

trie = {'a':{'b':{'e':{}, 's':{}}, 'c':{'t':{}, 'k':{}}}}

These are most commonly used for looking up strings with common prefixes, but perhaps there's some sense in which the data in your objects can be represented as a string. This seems like it would work especially well if there's some order the data can be put in such that earlier data in the string must compare as ==. I think I can even imagine the leaves of the trie including all similar, rather than all strictly equivalent, objects.

A small toy example of how to work with a trie:

>>> trie = {'a':{'b':{'e':{}, 's':{}}, 'c':{'t':{}, 'k':{}}}}
>>> def rec_print(trie, accum=''):
...     if trie:
...         for k in trie:
...             rec_print(trie[k], accum + k)
...     else:
...         print accum
... 
>>> rec_print(trie)
ack
act
abs
abe
share|improve this answer
    
An OrderedDict might also be useful for finding objects based on lt/gt relationships. –  senderle Jul 19 '11 at 16:00
    
Actually, scratch that, that's not what OrderedDicts are for. (Search for 'sort' to see what I mean.) –  senderle Jul 19 '11 at 22:14
    
Yes, I can make a string signature of MyObject, as such a PrefixTree sounds like a good data structure. –  rds Jul 20 '11 at 8:21

Your approach looks quite good to me if you only want the like objects of a few objects.

There is also nothing wrong with defining __hash__() for your own class.

If you want to group all your objects in classes of "like" objects, then there is a faster approach: you can use the transitivity of your like() method. In fact, if like(obj0, obj1) and like(obj1, obj2) are true, then like(obj0, obj2) is automatically true, with no need for further calculations. This means that you can directly group all your objects in classes with the efficient

signature = lambda obj: (obj.period, obj.typed_dimensions.keys())
sorted_objs = sorted(dic.values(), key=signature)
objs_in_like_classes = [list(group) for (_, group) in itertools.groupby(sorted_objs, key=signature)]

This groups like objects together, automatically. This is simpler, and is likely faster than defining __hash__() and __eq__() and doing the prefetching by yourself, because groupby() uses the transitivity of ==.

(PS: I prefer Michael J. Barber's "dictionary of like objects grouped by hashable signature" approach to this solution, because it is probably a tad faster, and is also more general, as no sorting is necessary.)

If you need to keep your current approach, you can do it in a slightly cleaner way: you could check whether you really need any of these if other is not None tests. If you want to handle comparisons (__eq__) properly, you should also handle the case of other being of a different class (instead of checking only for identity with None); an isinstance() would do. like() might be different, if you only ever compare objects of class MyObject. In this case, your code should look something like:

def __eq__(self, other):
    if isinstance(other, MyObject):
        return (self.period == other.period
                and self.typed_dimensions == other.typed_dimensions)
    else:
        return False

def like(self, other):
    return (self.period == other.period  # No need for a backslash
            and self.typed_dimensions.keys() == other.typed_dimensions.keys())

This would make the code cleaner (but not really faster).

You could make your __hash__() function a tad faster by not doing self._hash = None in __init__() and by writing:

def __hash__(self):
    try:
        return self._hash
    except AttributeError:
        self._hash = (hash(self.periodtype) ^
                      hash(tuple(sorted(self.dimensions.values()))))
        return self._hash

In fact, try is fast when no exception is raised (which is the most common case by far, in your case).

As for your hash_dict, it can be constructed quite efficiently with:

hash_dict = dict(itertools.groupby(dic.values(), key=hash))

(maybe that's what you are already doing).

share|improve this answer
    
This is getting good. I didn't know the itertools, and I think it can be faster than by handmade iteration. Thanks for the other code tricks. Just a remark, the dictionary keys are not hashable, I need to keep my hash function or change your lambda with a fronzenset or a tuple of sorted values. –  rds Jul 20 '11 at 10:03
1  
Although I like the idea, I don't think groupby will work here. The objects won't generally be sorted, so you could get multiple groups with the same keys, only the last of which will appear in the dictionary. –  Michael J. Barber Jul 20 '11 at 10:18
    
@rds: You're right. I thought that groupby() did equality comparisons. In this case, you might want to write your own groupby() function that takes the transitivity into account (you would group objects in sets of like objects, and only test the likeliness of a single object from each set), possibly with the help of your hash function, if you want speed. –  EOL Jul 20 '11 at 10:24
    
@EOL: You had it right initially---groupby uses equality for grouping. The key function needs to return a hashable result so that the dict call doesn't have a problem. –  Michael J. Barber Jul 20 '11 at 10:35
1  
@EOL: I still don't think it works. You won't have problems with the hashing, but you can have disjoint groups that have the same key value---groupby assumes the objects are sorted by the same key it groups by, which won't generally be the case for the objects from dic.values(). You need a sort, or just accumulate into a dict with a modified key function, as in my (second, shorter) answer. –  Michael J. Barber Jul 20 '11 at 12:19

I don't exactly follow your prefetch step, as you didn't explain it in detail, but maybe you could just as well precompute the complete result?

Another possibility, which I would have done, if the like method really looks like that is indexing over the y values.

Something like index = { 10 : [obj1], 12 : [obj2, obj3] ,... } where they keys are the objects' y attribute. Hence, you end up with:

def find_keys_in_constant_time(dic, val):
    precomputed = index[val.y]
    return precomputed

Of course, it also returns the original val object, but so does your original method.

share|improve this answer
    
Unfornuately not, the like method is compelex; I have edited the question to reflect the situation. –  rds Jul 19 '11 at 15:03
    
Would prefetching be equivalent to caching? I think prefetching would take a huge time anyway. –  rds Jul 20 '11 at 8:24
    
Not equivalent, but similar. Prefetching means to compute it all, before you need it. Caching means to store it for when you need it again. So prefetching is a kind of caching. –  Frank Jul 20 '11 at 13:52

It's hard to answer he question, as I have no idea what are you requirements. What I would do is creating some kind of Related class and populate your items with it. How to implement it mainly depends on properties of you like function. If your relationship is symmetrical (i.e. a is like b if and only if b is like a), than you can cluster related items and instead of iterating items, you iterate clusters and compare with any item within it; if it matches, all items within cluster are in relationship with your element.

However, the relationship from you example is not symmetrical, so you probably need another approach. You still could cluster by y and z, and on looking up element taking intersection of corresponding cluster_y with union of cluster_z's holding z's greater or equal to element being looked up. However, it might add significant memory overhead if the values differs much.

And you could do something else by examining your relationship properties. We could help if you provided more details.

share|improve this answer
    
My relationship is actually symetrical. I had the idea of clustering, and my clusters are build with the hash method. Maybe this is what should be improved? –  rds Jul 20 '11 at 8:23

NOTE After seeing the implementation of like, the method described is seen to be more complicated than necessary. I'll leave it here, as the approach can be generalized to fuzzier similarity measures, e.g., at least 50% of the dimensions must be the same.

What you're doing looks a lot like an inverted index, although it's impossible to say without really knowing how like is implemented. For an inverted index, you use possible object values as the dictionary keys, mapping to lists (or other collections) of objects taking those values. With several properties, you can make several dictionaries, handling the different types of object values. You then look up all the properties for the object in the inverted index, determining an aggregate similarity for each object based on all properties.

To take full advantage of the inverted index, it's better to think of returning all similar objects from one function. This helps you handle each possible "like" objects just once. As an extreme example, you might have an object like another only if all properties are the same; similar objects are then those objects found in all corresponding lists from the inverted index. To get all of the similar objects, you could just convert the lists to sets and take the intersection.

Here's what it might look like in Python, slightly abbreviated to focus on the dimensions---extension to include period should be easy. There is a mapping from object identifier strings to the objects in dic. You can thus build an inverted index by mapping from the dimensions to sets of the object identifiers that have that dimension. It might be done so:

import collections
invind = collections.defaultdict(set)
for k, obj in dic.iteritems():
    for d in obj.dimensions:
        invind[d].add(k)

Now say that you want to find all objects that have identical dimensions to a specific object test_obj. Just look up the sets of object identifiers with at least one of the dimensions, and take the intersection of all those sets. A concise way to write such a query is:

import operator
similar_keys = reduce(operator.and_, [invind[d] for d in test_ojb.dimensions])
similar_objects = [dic[k] for k in similar_keys]

The operate.and_ will calculate the set intersections, reduce extends it to the whole list of sets. This is not generally the fastest approach to implement the intersections; instead you can manipulate a set of results in-place with the intersection_update method of sets, stopping early once the set is empty---I'll leave the details, as they're easy but verbose.

The advantage of this approach is that any objects with no dimensions in common will not be compared at all. Depending on how your dimensions occur, it could be a dramatic reduction in the number of tests made. You can take the idea further, e.g., using pairs of co-occuring dimensions as the keys in the inverted index. This is more expensive to generate the keys, but generally reduces the sizes of the sets of object identifiers---a bit of experimentation, or just a good understanding of the dimensions, should help to make the right tradeoff.

To include the periods in the comparisons, just add another inverted index mapping periods to sets of object identifiers. Extending the query for similar objects should be straightforward.

share|improve this answer
    
I think it is exactly what I do with my hash_dic. But instead of taking a given property as the key, I use the hash of the object. I do this because the main property is a dictionary which itself is not hashable. –  rds Jul 20 '11 at 8:26
    
@rds Given that you only use the dictionary keys in your like method, you could instead use a frozenset, which is hashable. For an inverted index, however, you'd want to use the keys of typed_dimensions as the keys in the index, mapping to lists of tuples containing the objects and the corresponding value for that key and object. Hashability ceases to be an issue with this structure. –  Michael J. Barber Jul 20 '11 at 8:42
    
Can you detail what I should replace by the frozenset? –  rds Jul 20 '11 at 9:01
    
@rds I wouldn't, actually, that was more a general comment on how you might deal with non-hashable dictionaries; sorry that wasn't clearer. I'd use the inverted index. I'll add some example code. –  Michael J. Barber Jul 20 '11 at 9:13
    
Yet hash(frozenset(self.dimensions.values())) is faster than hash(tuple(sorted(self.dimensions.values())))) :-) –  rds Jul 20 '11 at 10:14

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