Objects/dictnotes.txt - platform/external/python/cpython2 - Git at Google

 NOTES ON OPTIMIZING DICTIONARIES
 ================================


 Principal Use Cases for Dictionaries
 ------------------------------------

 Passing keyword arguments
     Typically, one read and one write for 1 to 3 elements.
     Occurs frequently in normal python code.

 Class method lookup
     Dictionaries vary in size with 8 to 16 elements being common.
     Usually written once with many lookups.
     When base classes are used, there are many failed lookups
         followed by a lookup in a base class.

 Instance attribute lookup and Global variables
     Dictionaries vary in size.  4 to 10 elements are common.
     Both reads and writes are common.

 Builtins
     Frequent reads.  Almost never written.
     Size 126 interned strings (as of Py2.3b1).
     A few keys are accessed much more frequently than others.

 Uniquification
     Dictionaries of any size.  Bulk of work is in creation.
     Repeated writes to a smaller set of keys.
     Single read of each key.
     Some use cases have two consecutive accesses to the same key.

     * Removing duplicates from a sequence.
         dict.fromkeys(seqn).keys()

     * Counting elements in a sequence.
         for e in seqn:
           d[e] = d.get(e,0) + 1

     * Accumulating references in a dictionary of lists:

         for pagenumber, page in enumerate(pages):
           for word in page:
             d.setdefault(word, []).append(pagenumber)

     Note, the second example is a use case characterized by a get and set
     to the same key.  There are similar use cases with a __contains__
     followed by a get, set, or del to the same key.  Part of the
     justification for d.setdefault is combining the two lookups into one.

 Membership Testing
     Dictionaries of any size.  Created once and then rarely changes.
     Single write to each key.
     Many calls to __contains__() or has_key().
     Similar access patterns occur with replacement dictionaries
         such as with the % formatting operator.

 Dynamic Mappings
     Characterized by deletions interspersed with adds and replacements.
     Performance benefits greatly from the re-use of dummy entries.


 Data Layout (assuming a 32-bit box with 64 bytes per cache line)
 ----------------------------------------------------------------

 Smalldicts (8 entries) are attached to the dictobject structure
 and the whole group nearly fills two consecutive cache lines.

 Larger dicts use the first half of the dictobject structure (one cache
 line) and a separate, continuous block of entries (at 12 bytes each
 for a total of 5.333 entries per cache line).


 Tunable Dictionary Parameters
 -----------------------------

 * PyDict_MINSIZE.  Currently set to 8.
     Must be a power of two.  New dicts have to zero-out every cell.
     Each additional 8 consumes 1.5 cache lines.  Increasing improves
     the sparseness of small dictionaries but costs time to read in
     the additional cache lines if they are not already in cache.
     That case is common when keyword arguments are passed.

 * Maximum dictionary load in PyDict_SetItem.  Currently set to 2/3.
     Increasing this ratio makes dictionaries more dense resulting
     in more collisions.  Decreasing it improves sparseness at the
     expense of spreading entries over more cache lines and at the
     cost of total memory consumed.

     The load test occurs in highly time sensitive code.  Efforts
     to make the test more complex (for example, varying the load
     for different sizes) have degraded performance.

 * Growth rate upon hitting maximum load.  Currently set to *2.
     Raising this to *4 results in half the number of resizes,
     less effort to resize, better sparseness for some (but not
     all dict sizes), and potentially doubles memory consumption
     depending on the size of the dictionary.  Setting to *4
     eliminates every other resize step.

 * Maximum sparseness (minimum dictionary load).  What percentage
     of entries can be unused before the dictionary shrinks to
     free up memory and speed up iteration?  (The current CPython
     code does not represent this parameter directly.)

 * Shrinkage rate upon exceeding maximum sparseness.  The current
     CPython code never even checks sparseness when deleting a
     key.  When a new key is added, it resizes based on the number
     of active keys, so that the addition may trigger shrinkage
     rather than growth.

 Tune-ups should be measured across a broad range of applications and
 use cases.  A change to any parameter will help in some situations and
 hurt in others.  The key is to find settings that help the most common
 cases and do the least damage to the less common cases.  Results will
 vary dramatically depending on the exact number of keys, whether the
 keys are all strings, whether reads or writes dominate, the exact
 hash values of the keys (some sets of values have fewer collisions than
 others).  Any one test or benchmark is likely to prove misleading.

 While making a dictionary more sparse reduces collisions, it impairs
 iteration and key listing.  Those methods loop over every potential
 entry.  Doubling the size of dictionary results in twice as many
 non-overlapping memory accesses for keys(), items(), values(),
 __iter__(), iterkeys(), iteritems(), itervalues(), and update().
 Also, every dictionary iterates at least twice, once for the memset()
 when it is created and once by dealloc().

 Dictionary operations involving only a single key can be O(1) unless
 resizing is possible.  By checking for a resize only when the
 dictionary can grow (and may *require* resizing), other operations
 remain O(1), and the odds of resize thrashing or memory fragmentation
 are reduced. In particular, an algorithm that empties a dictionary
 by repeatedly invoking .pop will see no resizing, which might
 not be necessary at all because the dictionary is eventually
 discarded entirely.


 Results of Cache Locality Experiments
 -------------------------------------

 When an entry is retrieved from memory, 4.333 adjacent entries are also
 retrieved into a cache line.  Since accessing items in cache is *much*
 cheaper than a cache miss, an enticing idea is to probe the adjacent
 entries as a first step in collision resolution.  Unfortunately, the
 introduction of any regularity into collision searches results in more
 collisions than the current random chaining approach.

 Exploiting cache locality at the expense of additional collisions fails
 to payoff when the entries are already loaded in cache (the expense
 is paid with no compensating benefit).  This occurs in small dictionaries
 where the whole dictionary fits into a pair of cache lines.  It also
 occurs frequently in large dictionaries which have a common access pattern
 where some keys are accessed much more frequently than others.  The
 more popular entries *and* their collision chains tend to remain in cache.

 To exploit cache locality, change the collision resolution section
 in lookdict() and lookdict_string().  Set i^=1 at the top of the
 loop and move the  i = (i << 2) + i + perturb + 1 to an unrolled
 version of the loop.

 This optimization strategy can be leveraged in several ways:

 * If the dictionary is kept sparse (through the tunable parameters),
 then the occurrence of additional collisions is lessened.

 * If lookdict() and lookdict_string() are specialized for small dicts
 and for largedicts, then the versions for large_dicts can be given
 an alternate search strategy without increasing collisions in small dicts
 which already have the maximum benefit of cache locality.

 * If the use case for a dictionary is known to have a random key
 access pattern (as opposed to a more common pattern with a Zipf's law
 distribution), then there will be more benefit for large dictionaries
 because any given key is no more likely than another to already be
 in cache.

 * In use cases with paired accesses to the same key, the second access
 is always in cache and gets no benefit from efforts to further improve
 cache locality.

 Optimizing the Search of Small Dictionaries
 -------------------------------------------

 If lookdict() and lookdict_string() are specialized for smaller dictionaries,
 then a custom search approach can be implemented that exploits the small
 search space and cache locality.

 * The simplest example is a linear search of contiguous entries.  This is
   simple to implement, guaranteed to terminate rapidly, never searches
   the same entry twice, and precludes the need to check for dummy entries.

 * A more advanced example is a self-organizing search so that the most
   frequently accessed entries get probed first.  The organization
   adapts if the access pattern changes over time.  Treaps are ideally
   suited for self-organization with the most common entries at the
   top of the heap and a rapid binary search pattern.  Most probes and
   results are all located at the top of the tree allowing them all to
   be located in one or two cache lines.

 * Also, small dictionaries may be made more dense, perhaps filling all
   eight cells to take the maximum advantage of two cache lines.


 Strategy Pattern
 ----------------

 Consider allowing the user to set the tunable parameters or to select a
 particular search method.  Since some dictionary use cases have known
 sizes and access patterns, the user may be able to provide useful hints.

 1) For example, if membership testing or lookups dominate runtime and memory
    is not at a premium, the user may benefit from setting the maximum load
    ratio at 5% or 10% instead of the usual 66.7%.  This will sharply
    curtail the number of collisions but will increase iteration time.
    The builtin namespace is a prime example of a dictionary that can
    benefit from being highly sparse.

 2) Dictionary creation time can be shortened in cases where the ultimate
    size of the dictionary is known in advance.  The dictionary can be
    pre-sized so that no resize operations are required during creation.
    Not only does this save resizes, but the key insertion will go
    more quickly because the first half of the keys will be inserted into
    a more sparse environment than before.  The preconditions for this
    strategy arise whenever a dictionary is created from a key or item
    sequence and the number of *unique* keys is known.

 3) If the key space is large and the access pattern is known to be random,
    then search strategies exploiting cache locality can be fruitful.
    The preconditions for this strategy arise in simulations and
    numerical analysis.

 4) If the keys are fixed and the access pattern strongly favors some of
    the keys, then the entries can be stored contiguously and accessed
    with a linear search or treap.  This exploits knowledge of the data,
    cache locality, and a simplified search routine.  It also eliminates
    the need to test for dummy entries on each probe.  The preconditions
    for this strategy arise in symbol tables and in the builtin dictionary.


 Readonly Dictionaries
 ---------------------
 Some dictionary use cases pass through a build stage and then move to a
 more heavily exercised lookup stage with no further changes to the
 dictionary.

 An idea that emerged on python-dev is to be able to convert a dictionary
 to a read-only state.  This can help prevent programming errors and also
 provide knowledge that can be exploited for lookup optimization.

 The dictionary can be immediately rebuilt (eliminating dummy entries),
 resized (to an appropriate level of sparseness), and the keys can be
 jostled (to minimize collisions).  The lookdict() routine can then
 eliminate the test for dummy entries (saving about 1/4 of the time
 spent in the collision resolution loop).

 An additional possibility is to insert links into the empty spaces
 so that dictionary iteration can proceed in len(d) steps instead of
 (mp->mask + 1) steps.  Alternatively, a separate tuple of keys can be
 kept just for iteration.


 Caching Lookups
 ---------------
 The idea is to exploit key access patterns by anticipating future lookups
 based on previous lookups.

 The simplest incarnation is to save the most recently accessed entry.
 This gives optimal performance for use cases where every get is followed
 by a set or del to the same key.
	NOTES ON OPTIMIZING DICTIONARIES
	================================


	Principal Use Cases for Dictionaries
	------------------------------------

	Passing keyword arguments
	Typically, one read and one write for 1 to 3 elements.
	Occurs frequently in normal python code.

	Class method lookup
	Dictionaries vary in size with 8 to 16 elements being common.
	Usually written once with many lookups.
	When base classes are used, there are many failed lookups
	followed by a lookup in a base class.

	Instance attribute lookup and Global variables
	Dictionaries vary in size. 4 to 10 elements are common.
	Both reads and writes are common.

	Builtins
	Frequent reads. Almost never written.
	Size 126 interned strings (as of Py2.3b1).
	A few keys are accessed much more frequently than others.

	Uniquification
	Dictionaries of any size. Bulk of work is in creation.
	Repeated writes to a smaller set of keys.
	Single read of each key.
	Some use cases have two consecutive accesses to the same key.

	* Removing duplicates from a sequence.
	dict.fromkeys(seqn).keys()

	* Counting elements in a sequence.
	for e in seqn:
	d[e] = d.get(e,0) + 1

	* Accumulating references in a dictionary of lists:

	for pagenumber, page in enumerate(pages):
	for word in page:
	d.setdefault(word, []).append(pagenumber)

	Note, the second example is a use case characterized by a get and set
	to the same key. There are similar use cases with a __contains__
	followed by a get, set, or del to the same key. Part of the
	justification for d.setdefault is combining the two lookups into one.

	Membership Testing
	Dictionaries of any size. Created once and then rarely changes.
	Single write to each key.
	Many calls to __contains__() or has_key().
	Similar access patterns occur with replacement dictionaries
	such as with the % formatting operator.

	Dynamic Mappings
	Characterized by deletions interspersed with adds and replacements.
	Performance benefits greatly from the re-use of dummy entries.


	Data Layout (assuming a 32-bit box with 64 bytes per cache line)
	----------------------------------------------------------------

	Smalldicts (8 entries) are attached to the dictobject structure
	and the whole group nearly fills two consecutive cache lines.

	Larger dicts use the first half of the dictobject structure (one cache
	line) and a separate, continuous block of entries (at 12 bytes each
	for a total of 5.333 entries per cache line).


	Tunable Dictionary Parameters
	-----------------------------

	* PyDict_MINSIZE. Currently set to 8.
	Must be a power of two. New dicts have to zero-out every cell.
	Each additional 8 consumes 1.5 cache lines. Increasing improves
	the sparseness of small dictionaries but costs time to read in
	the additional cache lines if they are not already in cache.
	That case is common when keyword arguments are passed.

	* Maximum dictionary load in PyDict_SetItem. Currently set to 2/3.
	Increasing this ratio makes dictionaries more dense resulting
	in more collisions. Decreasing it improves sparseness at the
	expense of spreading entries over more cache lines and at the
	cost of total memory consumed.

	The load test occurs in highly time sensitive code. Efforts
	to make the test more complex (for example, varying the load
	for different sizes) have degraded performance.

	* Growth rate upon hitting maximum load. Currently set to *2.
	Raising this to *4 results in half the number of resizes,
	less effort to resize, better sparseness for some (but not
	all dict sizes), and potentially doubles memory consumption
	depending on the size of the dictionary. Setting to *4
	eliminates every other resize step.

	* Maximum sparseness (minimum dictionary load). What percentage
	of entries can be unused before the dictionary shrinks to
	free up memory and speed up iteration? (The current CPython
	code does not represent this parameter directly.)

	* Shrinkage rate upon exceeding maximum sparseness. The current
	CPython code never even checks sparseness when deleting a
	key. When a new key is added, it resizes based on the number
	of active keys, so that the addition may trigger shrinkage
	rather than growth.

	Tune-ups should be measured across a broad range of applications and
	use cases. A change to any parameter will help in some situations and
	hurt in others. The key is to find settings that help the most common
	cases and do the least damage to the less common cases. Results will
	vary dramatically depending on the exact number of keys, whether the
	keys are all strings, whether reads or writes dominate, the exact
	hash values of the keys (some sets of values have fewer collisions than
	others). Any one test or benchmark is likely to prove misleading.

	While making a dictionary more sparse reduces collisions, it impairs
	iteration and key listing. Those methods loop over every potential
	entry. Doubling the size of dictionary results in twice as many
	non-overlapping memory accesses for keys(), items(), values(),
	__iter__(), iterkeys(), iteritems(), itervalues(), and update().
	Also, every dictionary iterates at least twice, once for the memset()
	when it is created and once by dealloc().

	Dictionary operations involving only a single key can be O(1) unless
	resizing is possible. By checking for a resize only when the
	dictionary can grow (and may require resizing), other operations
	remain O(1), and the odds of resize thrashing or memory fragmentation
	are reduced. In particular, an algorithm that empties a dictionary
	by repeatedly invoking .pop will see no resizing, which might
	not be necessary at all because the dictionary is eventually
	discarded entirely.


	Results of Cache Locality Experiments
	-------------------------------------

	When an entry is retrieved from memory, 4.333 adjacent entries are also
	retrieved into a cache line. Since accessing items in cache is much
	cheaper than a cache miss, an enticing idea is to probe the adjacent
	entries as a first step in collision resolution. Unfortunately, the
	introduction of any regularity into collision searches results in more
	collisions than the current random chaining approach.

	Exploiting cache locality at the expense of additional collisions fails
	to payoff when the entries are already loaded in cache (the expense
	is paid with no compensating benefit). This occurs in small dictionaries
	where the whole dictionary fits into a pair of cache lines. It also
	occurs frequently in large dictionaries which have a common access pattern
	where some keys are accessed much more frequently than others. The
	more popular entries and their collision chains tend to remain in cache.

	To exploit cache locality, change the collision resolution section
	in lookdict() and lookdict_string(). Set i^=1 at the top of the
	loop and move the i = (i << 2) + i + perturb + 1 to an unrolled
	version of the loop.

	This optimization strategy can be leveraged in several ways:

	* If the dictionary is kept sparse (through the tunable parameters),
	then the occurrence of additional collisions is lessened.

	* If lookdict() and lookdict_string() are specialized for small dicts
	and for largedicts, then the versions for large_dicts can be given
	an alternate search strategy without increasing collisions in small dicts
	which already have the maximum benefit of cache locality.

	* If the use case for a dictionary is known to have a random key
	access pattern (as opposed to a more common pattern with a Zipf's law
	distribution), then there will be more benefit for large dictionaries
	because any given key is no more likely than another to already be
	in cache.

	* In use cases with paired accesses to the same key, the second access
	is always in cache and gets no benefit from efforts to further improve
	cache locality.

	Optimizing the Search of Small Dictionaries
	-------------------------------------------

	If lookdict() and lookdict_string() are specialized for smaller dictionaries,
	then a custom search approach can be implemented that exploits the small
	search space and cache locality.

	* The simplest example is a linear search of contiguous entries. This is
	simple to implement, guaranteed to terminate rapidly, never searches
	the same entry twice, and precludes the need to check for dummy entries.

	* A more advanced example is a self-organizing search so that the most
	frequently accessed entries get probed first. The organization
	adapts if the access pattern changes over time. Treaps are ideally
	suited for self-organization with the most common entries at the
	top of the heap and a rapid binary search pattern. Most probes and
	results are all located at the top of the tree allowing them all to
	be located in one or two cache lines.

	* Also, small dictionaries may be made more dense, perhaps filling all
	eight cells to take the maximum advantage of two cache lines.


	Strategy Pattern
	----------------

	Consider allowing the user to set the tunable parameters or to select a
	particular search method. Since some dictionary use cases have known
	sizes and access patterns, the user may be able to provide useful hints.

	1) For example, if membership testing or lookups dominate runtime and memory
	is not at a premium, the user may benefit from setting the maximum load
	ratio at 5% or 10% instead of the usual 66.7%. This will sharply
	curtail the number of collisions but will increase iteration time.
	The builtin namespace is a prime example of a dictionary that can
	benefit from being highly sparse.

	2) Dictionary creation time can be shortened in cases where the ultimate
	size of the dictionary is known in advance. The dictionary can be
	pre-sized so that no resize operations are required during creation.
	Not only does this save resizes, but the key insertion will go
	more quickly because the first half of the keys will be inserted into
	a more sparse environment than before. The preconditions for this
	strategy arise whenever a dictionary is created from a key or item
	sequence and the number of unique keys is known.

	3) If the key space is large and the access pattern is known to be random,
	then search strategies exploiting cache locality can be fruitful.
	The preconditions for this strategy arise in simulations and
	numerical analysis.

	4) If the keys are fixed and the access pattern strongly favors some of
	the keys, then the entries can be stored contiguously and accessed
	with a linear search or treap. This exploits knowledge of the data,
	cache locality, and a simplified search routine. It also eliminates
	the need to test for dummy entries on each probe. The preconditions
	for this strategy arise in symbol tables and in the builtin dictionary.


	Readonly Dictionaries
	---------------------
	Some dictionary use cases pass through a build stage and then move to a
	more heavily exercised lookup stage with no further changes to the
	dictionary.

	An idea that emerged on python-dev is to be able to convert a dictionary
	to a read-only state. This can help prevent programming errors and also
	provide knowledge that can be exploited for lookup optimization.

	The dictionary can be immediately rebuilt (eliminating dummy entries),
	resized (to an appropriate level of sparseness), and the keys can be
	jostled (to minimize collisions). The lookdict() routine can then
	eliminate the test for dummy entries (saving about 1/4 of the time
	spent in the collision resolution loop).

	An additional possibility is to insert links into the empty spaces
	so that dictionary iteration can proceed in len(d) steps instead of
	(mp->mask + 1) steps. Alternatively, a separate tuple of keys can be
	kept just for iteration.


	Caching Lookups
	---------------
	The idea is to exploit key access patterns by anticipating future lookups
	based on previous lookups.

	The simplest incarnation is to save the most recently accessed entry.
	This gives optimal performance for use cases where every get is followed
	by a set or del to the same key.