import base64, os, re, struct, sys
import boto
+from boto.s3.key import Key
# The BlueSky 'struct cloudlog_header' data type.
-HEADER_FORMAT = '<4sb16sQIII'
+HEADER_FORMAT = '<4s48sb16sQIII'
+HEADER_CRYPTBYTES = 48
HEADER_MAGIC = 'AgI-'
HEADER_SIZE = struct.calcsize(HEADER_FORMAT)
fp.write(data)
fp.close()
+ def delete(self, filename):
+ os.unlink(os.path.join(self.path, filename))
+
+ def loc_to_name(self, location):
+ return "log-%08d-%08d" % (location)
+
+ def name_to_loc(self, name):
+ m = re.match(r"^log-(\d+)-(\d+)$", name)
+ if m: return (int(m.group(1)), int(m.group(2)))
+
+class S3Backend:
+ """An interface to BlueSky where the log segments are on in Amazon S3."""
+
+ def __init__(self, bucket, path='', cachedir="."):
+ self.conn = boto.connect_s3(is_secure=False)
+ self.bucket = self.conn.get_bucket(bucket)
+ self.path = path
+ self.cachedir = cachedir
+ self.cache = {}
+
+ def list(self):
+ files = []
+ for k in self.bucket.list(self.path + 'log-'):
+ files.append((k.key, k.size))
+ return files
+
+ def read(self, filename):
+ if filename in self.cache:
+ fp = open(os.path.join(self.cachedir, filename), 'rb')
+ return fp.read()
+ else:
+ k = Key(self.bucket)
+ k.key = self.path + filename
+ data = k.get_contents_as_string()
+ fp = open(os.path.join(self.cachedir, filename), 'wb')
+ fp.write(data)
+ fp.close()
+ self.cache[filename] = True
+ return data
+
+ def write(self, filename, data):
+ k = Key(self.bucket)
+ k.key = self.path + filename
+ k.set_contents_from_string(data)
+ if filename in self.cache:
+ del self.cache[filename]
+
+ def delete(self, filename):
+ k = Key(self.bucket)
+ k.key = self.path + filename
+ k.delete()
+ if filename in self.cache:
+ del self.cache[filename]
+
def loc_to_name(self, location):
return "log-%08d-%08d" % (location)
class LogItem:
"""In-memory representation of a single item stored in a log file."""
+ def __init__(self):
+ self.cryptkeys = '\0' * HEADER_CRYPTBYTES
+
def __str__(self):
return "<Item ty=%s location=%s size=%d id=%s...>" % (self.type, self.location, self.size, base64.b16encode(self.id).lower()[0:8])
link_locs = ''.join(link_locs)
header = struct.pack(HEADER_FORMAT,
- HEADER_MAGIC, ord(self.type), self.id, self.inum,
+ HEADER_MAGIC, self.cryptkeys,
+ ord(self.type), self.id, self.inum,
len(self.data), len(link_ids), len(link_locs))
return header + self.data + link_ids + link_locs
def parse_item(data):
if len(data) < HEADER_SIZE: return
header = struct.unpack_from(HEADER_FORMAT, data, 0)
- size = HEADER_SIZE + sum(header[4:7])
+ size = HEADER_SIZE + sum(header[5:8])
if header[0] != HEADER_MAGIC:
print "Bad header magic!"
return
if len(data) != size:
- print "Item size does not match!"
+ print "Item size does not match: %d != %d" % (size, len(data))
return
item = LogItem()
- item.id = header[2]
- item.inum = header[3]
+ item.cryptkeys = header[1]
+ item.id = header[3]
+ item.inum = header[4]
item.location = None
- item.type = chr(header[1])
+ item.type = chr(header[2])
item.size = size
- item.data = data[HEADER_SIZE : HEADER_SIZE + header[4]]
+ item.data = data[HEADER_SIZE : HEADER_SIZE + header[5]]
links = []
- link_ids = data[HEADER_SIZE + header[4]
- : HEADER_SIZE + header[4] + header[5]]
- link_locs = data[HEADER_SIZE + header[4] + header[5]
- : HEADER_SIZE + sum(header[4:7])]
+ link_ids = data[HEADER_SIZE + header[5]
+ : HEADER_SIZE + header[5] + header[6]]
+ link_locs = data[HEADER_SIZE + header[5] + header[6]
+ : HEADER_SIZE + sum(header[5:8])]
for i in range(len(link_ids) // 16):
id = link_ids[16*i : 16*i + 16]
if id == '\0' * 16:
offset = 0
while len(data) - offset >= HEADER_SIZE:
header = struct.unpack_from(HEADER_FORMAT, data, offset)
- size = HEADER_SIZE + sum(header[4:7])
+ size = HEADER_SIZE + sum(header[5:8])
if header[0] != HEADER_MAGIC:
print "Bad header magic!"
break
def load_checkpoint_record(backend):
for (log, size) in reversed(backend.list()):
for item in reversed(list(parse_log(backend.read(log), log))):
+ print item
if item.type == ITEM_TYPE.CHECKPOINT:
return item
print
print "Segment utilizations:"
for (s, u) in sorted(util.segments.items()):
- #if u[1] > 0:
print "%s: %s %s" % (s, u, float(u[1]) / u[0])
+ if u[1] == 0:
+ print "Deleting..."
+ backend.delete(s)
self.inodes = inodes
self.util = util
log.write(inode, 1)
inode_map.mark_updated(inum)
-def run_cleaner(backend, inode_map, log):
+def run_cleaner(backend, inode_map, log, repack_inodes=False):
# Determine which segments are poorly utilized and should be cleaned. We
# need better heuristics here.
for (s, u) in sorted(inode_map.util.segments.items()):
- if float(u[1]) / u[0] < 0.95 and u[1] > 0:
+ if (float(u[1]) / u[0] < 0.6 or u[1] < 32768) and u[1] > 0:
print "Should clean segment", s
loc = backend.name_to_loc(s)
if s: inode_map.obsolete_segments.add(loc)
# Given that list of segments to clean, scan through those segments to find
# data which is still live and mark relevant inodes as needing to be
# rewritten.
- dirty_inodes = set()
+ if repack_inodes:
+ dirty_inodes = set(inode_map.inodes)
+ else:
+ dirty_inodes = set()
dirty_inode_data = set()
for s in inode_map.obsolete_segments:
filename = backend.loc_to_name(s)
rewrite_inode(backend, inode_map, i, log, i in dirty_inode_data)
if __name__ == '__main__':
- backend = FileBackend(".")
+ backend = S3Backend("mvrable-bluesky", cachedir=".")
chkpt = load_checkpoint_record(backend)
+ print backend.list()
imap = InodeMap()
imap.build(backend, chkpt)
print chkpt
- log_dir = LogDirectory(backend, 1)
+ log_dir = LogDirectory(backend, 0)
run_cleaner(backend, imap, log_dir)
imap.write(backend, log_dir)
log_dir.close_all()