Suppose you have a sqlite database with several thousand rows -- each of which either contains or references a sizable, unique blob -- and you want to sparsely sample this collection, pulling rows based on rowid or some equivalent primary key. I find that the first time I attempt to fetch several (500) datapoints after connecting (out of 20k rows), the call takes over 10 seconds to return; and, with every successive iteration, the calls get shorter and shorter, until converging to around 100 milliseconds after 50-100 such queries.
Clearly, either sqlite or its python wrapper must be caching... something. If I clear out inactive memory (I'm in OS X, but I think Linux has a comparable if-not-identical "purge" command?), the behavior can be replicated exactly. The question is, what is it caching that an index doesn't address? And furthermore, is it possible to automatically pull whatever information is accelerating these queries into memory from the start? Or is there something else I've missed entirely?
A few notes in case someone doesn't immediately know the answer...
Each blob is around 40kB, and are a large (ha) source of the problem. I've some code below for anyone who wants to play along at home, but I've had better luck keeping separate tables for sortable information and data. This introduces an inner join, but it's generally been better than keeping it all together (although if anyone feels this is wrong, I'm keen to hear it). Without the inner join / data fetch, things start at 4 seconds and drop to 3 ms in a hurry.
I feel like this might be a PRAGMA thing, but I fiddled with some settings suggested by others in the wilderness of the web and didn't really see any benefit.
In-memory databases are not an option. For one, I'm trying to share across threads (which might not actually be a problem for in-mems...? not sure), but more importantly the database files are typically on the order of 17 GB. So, that's out.
That being said, there's no problem caching a reasonable amount of information. After a few dozen calls, inactive memory gets somewhat bloated anyways, but I'd rather do it (1) right and (2) efficiently.
Okay, now some code for anyone who wants to try to replicate things. You should be able to copy and paste it into a stand-alone script (that's basically what I did, save for formatting).
import sqlite3 import numpy as np import time ref_uid_index = """CREATE INDEX ref_uid_idx ON data(ref_uid)""" def populate_db_split(db_file, num_classes=10, num_points=20000, VERBOSE=False): def_schema_split0 = """ CREATE TABLE main ( uid INTEGER PRIMARY KEY, name TEXT, label INTEGER, ignore INTEGER default 0, fold INTEGER default 0)""" def_schema_split1 = """ CREATE TABLE data ( uid INTEGER PRIMARY KEY, ref_uid INTEGER REFERENCES main(uid), data BLOB)""" def_insert_split0 = """ INSERT INTO main (name, label, fold) VALUES (?,?,?)""" def_insert_split1 = """ INSERT INTO data (ref_uid, data) VALUES (?,?)""" blob_size= 5000 k_folds = 5 some_names = ['apple', 'banana', 'cherry', 'date'] dbconn = sqlite3.connect(db_file) dbconn.execute(def_schema_split0) dbconn.execute(def_schema_split1) rng = np.random.RandomState() for n in range(num_points): if n%1000 == 0 and VERBOSE: print n # Make up some data data = buffer(rng.rand(blob_size).astype(float)) fold = rng.randint(k_folds) label = rng.randint(num_classes) rng.shuffle(some_names) # And add it dbconn.execute(def_insert_split0,[some_names, label, fold]) ref_uid = dbconn.execute("SELECT uid FROM main WHERE rowid=last_insert_rowid()").fetchone() dbconn.execute(def_insert_split1,[ref_uid,data]) dbconn.execute(ref_uid_index) dbconn.commit() return dbconn def timeit_join(dbconn, n_times=10, num_rows=500): qmarks = "?,"*(num_rows-1)+"?" q_join = """SELECT data.data, main.uid, main.label FROM data INNER JOIN main ON main.uid=data.ref_uid WHERE main.uid IN (%s)"""%qmarks row_max = dbconn.execute("SELECT MAX(rowid) from main").fetchone() tstamps =  for n in range(n_times): now = time.time() uids = np.random.randint(low=1,high=row_max,size=num_rows).tolist() res = dbconn.execute(q_join, uids).fetchall() tstamps += [time.time()-now] print tstamps[-1]
Now, if you want to replicate things, do the following. On my machine, this creates an 800MB database and produces something like below.
>>> db = populate_db_split('/some/file/path.db') >>> timeit_join(db) 12.0593519211 5.56209111214 3.51154184341 2.20699000359 1.73895692825 1.18351387978 1.27329611778 0.934082984924 0.780968904495 0.834318161011
So... what say you, knowledgable sages?