LMDB Store design for RDFLib
============================
This is a log of subsequent strategies employed to store triples in
LMDB.
Strategy #5a is the one currently used. The rest is kept for historic
reasons and academic curiosity (and also because it was too much work to
just wipe out of memory).
Storage approach
----------------
- Pickle quad and create MD5 or SHA1 hash.
- Store triples in one database paired with key; store indices
separately.
Different strategies involve layout and number of databases.
Strategy #1
-----------
- kq: key: serialized triple (1:1)
- sk: Serialized subject: key (1:m)
- pk: Serialized predicate: key (1:m)
- ok: Serialized object: key (1:m)
- (optional) lok: Serialized literal object: key (1:m)
- (optional) tok: Serialized RDF type: key (1:m)
- ck: Serialized context: key (1:m)
Retrieval approach
~~~~~~~~~~~~~~~~~~
To find all matches for a quad:
- If all terms in the quad are bound, generate the key from the pickled
quad and look up the triple in ``kt``
- If all terms are unbound, return an iterator of all values in ``kt``.
- If some values are bound and some unbound (most common query):
- Get a base list of keys associated wirh the first bound term
- For each subsequent bound term, check if each key associated with
the term matches a key in the base list
- Continue through all the bound terms. If a match is not found at
any point, continue to the next term
- If a match is found in all the bound term databases, look up the
pickled quad matching the key in ``kq`` and yield it
More optimization can be introduced later, e.g. separating literal and
RDF type objects in separate databases. Literals can have very long
values and a database with a longer key setting may be useful. RDF terms
can be indexed separately because they are the most common bound term.
Example lookup
~~~~~~~~~~~~~~
Keys and Triples (should actually be quads but this is a simplified
version):
A: s1 p1 o1 B: s1 p2 o2 C: s2 p3 o1 D: s2 p3 o3
Indices:
- SK:
- s1: A, B
- s2: C, D
- PK:
- p1: A
- p2: B
- p3: C, D
- OK:
- o1: A, C
- o2: B
- o3: D
Queries:
- s1 ?p ?o → {A, B}
- s1 p2 ?o → {A, B} & {B} = {B}
- ?s ?p o3 → {D}
- s1 p2 o5 → {} (Exit at OK: no term matches ‘o5’)
- s2 p3 o2 → {C, D} & {C, D} & {B} = {}
Strategy #2
-----------
Separate data and indices in two environments.
Main data store
~~~~~~~~~~~~~~~
Key to quad; main keyspace; all unique.
Indices
~~~~~~~
None of these databases is of critical preservation concern. They can be
rebuilt from the main data store.
All dupsort and dupfixed.
@TODO The first three may not be needed if computing term hash is fast
enough.
- t2k (term to term key)
- lt2k (literal to term key: longer keys)
- k2t (term key to term)
- s2k (subject key to quad key)
- p2k (pred key to quad key)
- o2k (object key to quad key)
- c2k (context key to quad key)
- sc2qk (subject + context keys to quad key)
- po2qk (predicate + object keys to quad key)
- sp2qk (subject + predicate keys to quad key)
- oc2qk (object + context keys to quad key)
- so2qk (subject + object keys to quad key)
- pc2qk (predicate + context keys to quad key)
Strategy #3
-----------
Contexts are much fewer (even in graph per aspect, 5-10 triples per
graph)
.. _main-data-store-1:
Main data store
~~~~~~~~~~~~~~~
Preservation-worthy data
- tk:t (triple key: triple; dupsort, dupfixed)
- tk:c (context key: triple; unique)
.. _indices-1:
Indices
~~~~~~~
Rebuildable from main data store
- s2k (subject key: triple key)
- p2k (pred key: triple key)
- o2k (object key: triple key)
- sp2k
- so2k
- po2k
- spo2k
Lookup
~~~~~~
1. Look up triples by s, p, o, sp, so, po and get keys
2. If a context is specified, for each key try to seek to (context, key)
in ct to verify it exists
3. Intersect sets
4. Match triple keys with data using kt
Shortcuts
^^^^^^^^^
- Get all contexts: return list of keys from ct
- Get all triples for a context: get all values for a contex from ct
and match triple data with kt
- Get one triple match for all contexts: look up in triple indices and
match triple data with kt
Strategy #4
-----------
Terms are entered individually in main data store. Also, shorter keys
are used rather than hashes. These two aspects save a great deal of
space and I/O, but require an additional index to put the terms together
in a triple.
.. _main-data-store-2:
Main Data Store
~~~~~~~~~~~~~~~
- t:st (term key: serialized term; 1:1)
- spo:c (joined S, P, O keys: context key; 1:m)
- c: (context keys only, values are the empty bytestring)
Storage total: variable
.. _indices-2:
Indices
~~~~~~~
- th:t (term hash: term key; 1:1)
- c:spo (context key: joined triple keys; 1:m)
- s:po (S key: P + O key; 1:m)
- p:so (P key: S + O keys; 1:m)
- o:sp (object key: triple key; 1:m)
- sp:o (S + P keys: O key; 1:m)
- so:p (S + O keys: P key; 1:m)
- po:s (P + O keys: S key; 1:m)
Storage total: 143 bytes per triple
Disadvantages
~~~~~~~~~~~~~
- Lots of indices
- Terms can get orphaned:
- No easy way to know if a term is used anywhere in a quad
- Needs some routine cleanup
- On the other hand, terms are relatively light-weight and can be
reused
- Almost surely not reusable are UUIDs, message digests, timestamps
etc.
Strategy #5
-----------
Reduce number of indices and rely on parsing and splitting keys to find
triples with two bound parameters.
This is especially important for keeping indexing synchronous to achieve
fully ACID writes.
.. _main-data-store-3:
Main data store
~~~~~~~~~~~~~~~
Same as Strategy #4:
- t:st (term key: serialized term; 1:1)
- spo:c (joined S, P, O keys: context key; dupsort, dupfixed)
- c: (context keys only, values are the empty bytestring; 1:1)
Storage total: variable (same as #4)
.. _indices-3:
Indices
~~~~~~~
- th:t (term hash: term key; 1:1)
- s:po (S key: joined P, O keys; dupsort, dupfixed)
- p:so (P key: joined S, O keys; dupsort, dupfixed)
- o:sp (O key: joined S, P keys; dupsort, dupfixed)
- c:spo (context → triple association; dupsort, dupfixed)
Storage total: 95 bytes per triple
Lookup strategy
~~~~~~~~~~~~~~~
- ? ? ? c: [c:spo] all SPO for C → split key → [t:st] term from term
key
- s p o c: [c:spo] exact SPO & C match → split key → [t:st] term from
term key
- s ? ?: [s:po] All PO for S → split key → [t:st] term from term key
- s p ?: [s:po] All PO for S → filter result by P in split key → [t:st]
term from term key
Advantages
~~~~~~~~~~
- Less indices: smaller index size and less I/O
.. _disadvantages-1:
Disadvantages
~~~~~~~~~~~~~
- Possibly slower retrieval for queries with 2 bound terms (run
metrics)
Further optimization
~~~~~~~~~~~~~~~~~~~~
In order to minimize traversing and splittig results, the first
retrieval should be made on the term with less average keys. Search
order can be balanced by establishing a lookup order for indices.
This can be achieved by calling stats on the index databases and looking
up the database with *most* keys. Since there is an equal number of
entries in each of the (s:po, p:so, o:sp) indices, the one with most
keys will have the least average number of values per key. If that
lookup is done first, the initial data set to traverse and filter will
be smaller.
Strategy #5a
------------
This is a slightly different implementation of #5 that somewhat
simplifies and perhaps speeds up things a bit. It is the currently
employed solution.
The indexing and lookup strtegy is the same; but instead of using a
separator byte for splitting compound keys, the logic relies on the fact
that keys have a fixed length and are sliced instead. This *should*
result in faster key manipulation, also because in most cases
``memoryview`` buffers can be used directly instead of being copied from
memory.
Index storage is 90 bytes per triple.