1
0
mirror of https://github.com/arsenetar/dupeguru.git synced 2024-10-31 22:05:58 +00:00
dupeguru/core/pe/matchblock.py

230 lines
10 KiB
Python
Raw Normal View History

# Created By: Virgil Dupras
# Created On: 2007/02/25
2015-01-03 21:30:57 +00:00
# Copyright 2015 Hardcoded Software (http://www.hardcoded.net)
#
# This software is licensed under the "GPLv3" License as described in the "LICENSE" file,
# which should be included with this package. The terms are also available at
# http://www.gnu.org/licenses/gpl-3.0.html
import logging
import multiprocessing
2011-03-04 10:15:04 +00:00
from itertools import combinations
from hscommon.util import extract, iterconsume
from hscommon.trans import tr
from hscommon.jobprogress import job
from core.engine import Match
from .block import avgdiff, DifferentBlockCountError, NoBlocksError
2011-03-04 10:15:04 +00:00
# OPTIMIZATION NOTES:
# The bottleneck of the matching phase is CPU, which is why we use multiprocessing. However, another
# bottleneck that shows up when a lot of pictures are involved is Disk IO's because blocks
# constantly have to be read from disks by subprocesses. This problem is especially big on CPUs
# with a lot of cores. Therefore, we must minimize Disk IOs. The best way to achieve that is to
# separate the files to scan in "chunks" and it's by chunk that blocks are read in memory and
# compared to each other. Each file in a chunk has to be compared to each other, of course, but also
# to files in other chunks. So chunkifying doesn't save us any actual comparison, but the advantage
# is that instead of reading blocks from disk number_of_files**2 times, we read it
# number_of_files*number_of_chunks times.
# Determining the right chunk size is tricky, bceause if it's too big, too many blocks will be in
# memory at the same time and we might end up with memory trashing, which is awfully slow. So,
# because our *real* bottleneck is CPU, the chunk size must simply be enough so that the CPU isn't
# starved by Disk IOs.
MIN_ITERATIONS = 3
BLOCK_COUNT_PER_SIDE = 15
2011-03-04 10:15:04 +00:00
DEFAULT_CHUNK_SIZE = 1000
MIN_CHUNK_SIZE = 100
# Enough so that we're sure that the main thread will not wait after a result.get() call
2011-03-04 10:15:04 +00:00
# cpucount+1 should be enough to be sure that the spawned process will not wait after the results
# collection made by the main process.
try:
RESULTS_QUEUE_LIMIT = multiprocessing.cpu_count() + 1
except Exception:
# I had an IOError on app launch once. It seems to be a freak occurrence. In any case, we want
# the app to launch, so let's just put an arbitrary value.
logging.warning("Had problems to determine cpu count on launch.")
RESULTS_QUEUE_LIMIT = 8
def get_cache(cache_path, readonly=False):
if cache_path.endswith('shelve'):
from .cache_shelve import ShelveCache
return ShelveCache(cache_path, readonly=readonly)
else:
from .cache_sqlite import SqliteCache
return SqliteCache(cache_path, readonly=readonly)
2011-03-04 10:15:04 +00:00
def prepare_pictures(pictures, cache_path, with_dimensions, j=job.nulljob):
# The MemoryError handlers in there use logging without first caring about whether or not
# there is enough memory left to carry on the operation because it is assumed that the
# MemoryError happens when trying to read an image file, which is freed from memory by the
# time that MemoryError is raised.
cache = get_cache(cache_path)
cache.purge_outdated()
prepared = [] # only pictures for which there was no error getting blocks
try:
for picture in j.iter_with_progress(pictures, tr("Analyzed %d/%d pictures")):
if not picture.path:
# XXX Find the root cause of this. I've received reports of crashes where we had
# "Analyzing picture at " (without a path) in the debug log. It was an iPhoto scan.
# For now, I'm simply working around the crash by ignoring those, but it would be
# interesting to know exactly why this happens. I'm suspecting a malformed
# entry in iPhoto library.
logging.warning("We have a picture with a null path here")
continue
picture.unicode_path = str(picture.path)
logging.debug("Analyzing picture at %s", picture.unicode_path)
2011-03-04 10:15:04 +00:00
if with_dimensions:
picture.dimensions # pre-read dimensions
try:
if picture.unicode_path not in cache:
blocks = picture.get_blocks(BLOCK_COUNT_PER_SIDE)
cache[picture.unicode_path] = blocks
prepared.append(picture)
except (IOError, ValueError) as e:
logging.warning(str(e))
except MemoryError:
logging.warning("Ran out of memory while reading %s of size %d", picture.unicode_path, picture.size)
if picture.size < 10 * 1024 * 1024: # We're really running out of memory
raise
except MemoryError:
logging.warning('Ran out of memory while preparing pictures')
cache.close()
return prepared
2011-03-04 10:15:04 +00:00
def get_chunks(pictures):
min_chunk_count = multiprocessing.cpu_count() * 2 # have enough chunks to feed all subprocesses
chunk_count = len(pictures) // DEFAULT_CHUNK_SIZE
chunk_count = max(min_chunk_count, chunk_count)
chunk_size = (len(pictures) // chunk_count) + 1
chunk_size = max(MIN_CHUNK_SIZE, chunk_size)
logging.info(
"Creating %d chunks with a chunk size of %d for %d pictures", chunk_count,
chunk_size, len(pictures)
)
2011-03-04 10:15:04 +00:00
chunks = [pictures[i:i+chunk_size] for i in range(0, len(pictures), chunk_size)]
return chunks
def get_match(first, second, percentage):
if percentage < 0:
percentage = 0
return Match(first, second, percentage)
2011-03-04 10:15:04 +00:00
def async_compare(ref_ids, other_ids, dbname, threshold, picinfo):
# The list of ids in ref_ids have to be compared to the list of ids in other_ids. other_ids
# can be None. In this case, ref_ids has to be compared with itself
# picinfo is a dictionary {pic_id: (dimensions, is_ref)}
cache = get_cache(dbname, readonly=True)
limit = 100 - threshold
2011-03-04 10:15:04 +00:00
ref_pairs = list(cache.get_multiple(ref_ids))
if other_ids is not None:
other_pairs = list(cache.get_multiple(other_ids))
comparisons_to_do = [(r, o) for r in ref_pairs for o in other_pairs]
else:
comparisons_to_do = list(combinations(ref_pairs, 2))
results = []
2011-03-04 10:15:04 +00:00
for (ref_id, ref_blocks), (other_id, other_blocks) in comparisons_to_do:
ref_dimensions, ref_is_ref = picinfo[ref_id]
other_dimensions, other_is_ref = picinfo[other_id]
if ref_is_ref and other_is_ref:
continue
if ref_dimensions != other_dimensions:
continue
try:
diff = avgdiff(ref_blocks, other_blocks, limit, MIN_ITERATIONS)
percentage = 100 - diff
except (DifferentBlockCountError, NoBlocksError):
percentage = 0
if percentage >= threshold:
results.append((ref_id, other_id, percentage))
cache.close()
return results
def getmatches(pictures, cache_path, threshold, match_scaled=False, j=job.nulljob):
2011-03-04 10:15:04 +00:00
def get_picinfo(p):
if match_scaled:
return (None, p.is_ref)
else:
return (p.dimensions, p.is_ref)
2011-03-04 10:15:04 +00:00
def collect_results(collect_all=False):
# collect results and wait until the queue is small enough to accomodate a new results.
nonlocal async_results, matches, comparison_count, comparisons_to_do
2011-03-04 10:15:04 +00:00
limit = 0 if collect_all else RESULTS_QUEUE_LIMIT
while len(async_results) > limit:
ready, working = extract(lambda r: r.ready(), async_results)
for result in ready:
matches += result.get()
async_results.remove(result)
comparison_count += 1
# About the NOQA below: I think there's a bug in pyflakes. To investigate...
progress_msg = tr("Performed %d/%d chunk matches") % (comparison_count, len(comparisons_to_do)) # NOQA
2011-03-04 10:15:04 +00:00
j.set_progress(comparison_count, progress_msg)
j = j.start_subjob([3, 7])
2011-03-04 10:15:04 +00:00
pictures = prepare_pictures(pictures, cache_path, with_dimensions=not match_scaled, j=j)
j = j.start_subjob([9, 1], tr("Preparing for matching"))
cache = get_cache(cache_path)
id2picture = {}
for picture in pictures:
try:
picture.cache_id = cache.get_id(picture.unicode_path)
id2picture[picture.cache_id] = picture
except ValueError:
pass
cache.close()
pictures = [p for p in pictures if hasattr(p, 'cache_id')]
pool = multiprocessing.Pool()
2011-03-04 10:15:04 +00:00
async_results = []
matches = []
2011-03-04 10:15:04 +00:00
chunks = get_chunks(pictures)
# We add a None element at the end of the chunk list because each chunk has to be compared
# with itself. Thus, each chunk will show up as a ref_chunk having other_chunk set to None once.
comparisons_to_do = list(combinations(chunks + [None], 2))
comparison_count = 0
j.start_job(len(comparisons_to_do))
try:
for ref_chunk, other_chunk in comparisons_to_do:
picinfo = {p.cache_id: get_picinfo(p) for p in ref_chunk}
ref_ids = [p.cache_id for p in ref_chunk]
if other_chunk is not None:
other_ids = [p.cache_id for p in other_chunk]
picinfo.update({p.cache_id: get_picinfo(p) for p in other_chunk})
else:
other_ids = None
args = (ref_ids, other_ids, cache_path, threshold, picinfo)
async_results.append(pool.apply_async(async_compare, args))
collect_results()
collect_results(collect_all=True)
except MemoryError:
# Rare, but possible, even in 64bit situations (ref #264). What do we do now? We free us
# some wiggle room, log about the incident, and stop matching right here. We then process
# the matches we have. The rest of the process doesn't allocate much and we should be
# alright.
del comparisons_to_do, chunks, pictures # some wiggle room for the next statements
logging.warning("Ran out of memory when scanning! We had %d matches.", len(matches))
del matches[-len(matches)//3:] # some wiggle room to ensure we don't run out of memory again.
2011-03-04 10:15:04 +00:00
pool.close()
result = []
myiter = j.iter_with_progress(
iterconsume(matches, reverse=False),
tr("Verified %d/%d matches"),
every=10,
count=len(matches),
)
for ref_id, other_id, percentage in myiter:
ref = id2picture[ref_id]
other = id2picture[other_id]
if percentage == 100 and ref.md5 != other.md5:
percentage = 99
if percentage >= threshold:
2011-03-04 10:15:04 +00:00
ref.dimensions # pre-read dimensions for display in results
other.dimensions
result.append(get_match(ref, other, percentage))
return result
multiprocessing.freeze_support()