Note
This section was excerpted from a blog post by Darrell Bishop and has since been edited.
An OpenStack Object Storage cluster is a collection of many daemons that work together across many nodes. With so many different components, you must be able to tell what is going on inside the cluster. Tracking server-level meters like CPU utilization, load, memory consumption, disk usage and utilization, and so on is necessary, but not sufficient.
The Swift Recon middleware (see Cluster Telemetry and Monitoring)
provides general machine statistics, such as load average, socket
statistics, /proc/meminfo
contents, as well as Swift-specific meters:
MD5
sum of each ring file.Swift Recon is middleware that is installed in the object servers
pipeline and takes one required option: A local cache directory. To
track async_pendings
, you must set up an additional cron job for
each object server. You access data by either sending HTTP requests
directly to the object server or using the swift-recon
command-line
client.
There are Object Storage cluster statistics but the typical
server meters overlap with existing server monitoring systems. To get
the Swift-specific meters into a monitoring system, they must be polled.
Swift Recon acts as a middleware meters collector. The
process that feeds meters to your statistics system, such as
collectd
and gmond
, should already run on the storage node.
You can choose to either talk to Swift Recon or collect the meters
directly.
Swift-Informant middleware (see
swift-informant) has
real-time visibility into Object Storage client requests. It sits in the
pipeline for the proxy server, and after each request to the proxy server it
sends three meters to a StatsD
server:
obj.GET.200
or
cont.PUT.404
.acct.GET.200
or obj.GET.200
.
[The README says the meters look like duration.acct.GET.200
, but
I do not see the duration
in the code. I am not sure what the
Etsy server does but our StatsD server turns timing meters into five
derivative meters with new segments appended, so it probably works as
coded. The first meter turns into acct.GET.200.lower
,
acct.GET.200.upper
, acct.GET.200.mean
,
acct.GET.200.upper_90
, and acct.GET.200.count
].tfer.obj.PUT.201
.This is used for receiving information on the quality of service clients experience with the timing meters, as well as sensing the volume of the various modifications of a request server type, command, and response code. Swift-Informant requires no change to core Object Storage code because it is implemented as middleware. However, it gives no insight into the workings of the cluster past the proxy server. If the responsiveness of one storage node degrades, you can only see that some of the requests are bad, either as high latency or error status codes.
The Statsdlog project increments StatsD counters based on logged events. Like Swift-Informant, it is also non-intrusive, however statsdlog can track events from all Object Storage daemons, not just proxy-server. The daemon listens to a UDP stream of syslog messages, and StatsD counters are incremented when a log line matches a regular expression. Meter names are mapped to regex match patterns in a JSON file, allowing flexible configuration of what meters are extracted from the log stream.
Currently, only the first matching regex triggers a StatsD counter increment, and the counter is always incremented by one. There is no way to increment a counter by more than one or send timing data to StatsD based on the log line content. The tool could be extended to handle more meters for each line and data extraction, including timing data. But a coupling would still exist between the log textual format and the log parsing regexes, which would themselves be more complex to support multiple matches for each line and data extraction. Also, log processing introduces a delay between the triggering event and sending the data to StatsD. It would be preferable to increment error counters where they occur and send timing data as soon as it is known to avoid coupling between a log string and a parsing regex and prevent a time delay between events and sending data to StatsD.
The next section describes another method for gathering Object Storage operational meters.
StatsD (see Measure Anything, Measure Everything)
was designed for application code to be deeply instrumented. Meters are
sent in real-time by the code that just noticed or did something. The
overhead of sending a meter is extremely low: a sendto
of one UDP
packet. If that overhead is still too high, the StatsD client library
can send only a random portion of samples and StatsD approximates the
actual number when flushing meters upstream.
To avoid the problems inherent with middleware-based monitoring and after-the-fact log processing, the sending of StatsD meters is integrated into Object Storage itself. The submitted change set (see https://review.openstack.org/#change,6058) currently reports 124 meters across 15 Object Storage daemons and the tempauth middleware. Details of the meters tracked are in the Administrator’s Guide.
The sending of meters is integrated with the logging framework. To
enable, configure log_statsd_host
in the relevant config file. You
can also specify the port and a default sample rate. The specified
default sample rate is used unless a specific call to a statsd logging
method (see the list below) overrides it. Currently, no logging calls
override the sample rate, but it is conceivable that some meters may
require accuracy (sample_rate=1
) while others may not.
[DEFAULT]
# ...
log_statsd_host = 127.0.0.1
log_statsd_port = 8125
log_statsd_default_sample_rate = 1
Then the LogAdapter object returned by get_logger()
, usually stored
in self.logger
, has these new methods:
set_statsd_prefix(self, prefix)
Sets the client library stat
prefix value which gets prefixed to every meter. The default prefix
is the name
of the logger such as object-server
,
container-auditor
, and so on. This is currently used to turn
proxy-server
into one of proxy-server.Account
,
proxy-server.Container
, or proxy-server.Object
as soon as the
Controller object is determined and instantiated for the request.update_stats(self, metric, amount, sample_rate=1)
Increments
the supplied meter by the given amount. This is used when you need
to add or subtract more that one from a counter, like incrementing
suffix.hashes
by the number of computed hashes in the object
replicator.increment(self, metric, sample_rate=1)
Increments the given counter
meter by one.decrement(self, metric, sample_rate=1)
Lowers the given counter
meter by one.timing(self, metric, timing_ms, sample_rate=1)
Record that the
given meter took the supplied number of milliseconds.timing_since(self, metric, orig_time, sample_rate=1)
Convenience method to record a timing meter whose value is “now”
minus an existing timestamp.Note
These logging methods may safely be called anywhere you have a logger object. If StatsD logging has not been configured, the methods are no-ops. This avoids messy conditional logic each place a meter is recorded. These example usages show the new logging methods:
# swift/obj/replicator.py
def update(self, job):
# ...
begin = time.time()
try:
hashed, local_hash = tpool.execute(tpooled_get_hashes, job['path'],
do_listdir=(self.replication_count % 10) == 0,
reclaim_age=self.reclaim_age)
# See tpooled_get_hashes "Hack".
if isinstance(hashed, BaseException):
raise hashed
self.suffix_hash += hashed
self.logger.update_stats('suffix.hashes', hashed)
# ...
finally:
self.partition_times.append(time.time() - begin)
self.logger.timing_since('partition.update.timing', begin)
# swift/container/updater.py
def process_container(self, dbfile):
# ...
start_time = time.time()
# ...
for event in events:
if 200 <= event.wait() < 300:
successes += 1
else:
failures += 1
if successes > failures:
self.logger.increment('successes')
# ...
else:
self.logger.increment('failures')
# ...
# Only track timing data for attempted updates:
self.logger.timing_since('timing', start_time)
else:
self.logger.increment('no_changes')
self.no_changes += 1
Except where otherwise noted, this document is licensed under Creative Commons Attribution 3.0 License. See all OpenStack Legal Documents.