[DEFAULT]
# bind_ip = 0.0.0.0
bind_port = 6200
# keep_idle = 600
# bind_timeout = 30
# backlog = 4096
# user = swift
# swift_dir = /etc/swift
# devices = /srv/node
# mount_check = true
# disable_fallocate = false
#
# Use an integer to override the number of pre-forked processes that will
# accept connections.  NOTE: if servers_per_port is set, this setting is
# ignored.
# workers = auto
#
# Make object-server run this many worker processes per unique port of "local"
# ring devices across all storage policies. The default value of 0 disables this
# feature.
# servers_per_port = 0
#
# If running in a container, servers_per_port may not be able to use the
# bind_ip to lookup the ports in the ring.  You may instead override the port
# lookup in the ring using the ring_ip.  Any devices/ports associted with the
# ring_ip will be used when listening on the configured bind_ip address.
# ring_ip = <bind_ip>
#
# Maximum concurrent requests per worker
# max_clients = 1024
#
# You can specify default log routing here if you want:
log_name = swift-object
# log_facility = LOG_LOCAL0
# log_level = INFO
# log_address = /dev/log
# The following caps the length of log lines to the value given; no limit if
# set to 0, the default.
# log_max_line_length = 0
#
# Hashing algorithm for log anonymization. Must be one of algorithms supported
# by Python's hashlib.
# log_anonymization_method = MD5
#
# Salt added during log anonymization
# log_anonymization_salt =
#
# Template used to format logs. All words surrounded by curly brackets
# will be substituted with the appropriate values
# log_format = {remote_addr} - - [{time.d}/{time.b}/{time.Y}:{time.H}:{time.M}:{time.S} +0000] "{method} {path}" {status} {content_length} "{referer}" "{txn_id}" "{user_agent}" {trans_time:.4f} "{additional_info}" {pid} {policy_index}
#
# comma separated list of functions to call to setup custom log handlers.
# functions get passed: conf, name, log_to_console, log_route, fmt, logger,
# adapted_logger
# log_custom_handlers =
#
# If set, log_udp_host will override log_address
# log_udp_host =
# log_udp_port = 514
#
# You can enable StatsD logging here:
# log_statsd_host =
# log_statsd_port = 8125
# log_statsd_default_sample_rate = 1.0
# log_statsd_sample_rate_factor = 1.0
# log_statsd_metric_prefix =
#
# eventlet_debug = false
#
# You can set fallocate_reserve to the number of bytes or percentage of disk
# space you'd like fallocate to reserve, whether there is space for the given
# file size or not. Percentage will be used if the value ends with a '%'.
# fallocate_reserve = 1%
#
# Time to wait while attempting to connect to another backend node.
# conn_timeout = 0.5
# Time to wait while sending each chunk of data to another backend node.
# node_timeout = 3
# Time to wait while sending a container update on object update.
# container_update_timeout = 1.0
# Time to wait while receiving each chunk of data from a client or another
# backend node.
# client_timeout = 60.0
#
# network_chunk_size = 65536
# disk_chunk_size = 65536
#
# Reclamation of tombstone files is performed primarily by the replicator and
# the reconstructor but the object-server and object-auditor also reference
# this value - it should be the same for all object services in the cluster,
# and not greater than the container services reclaim_age
# reclaim_age = 604800
#
# Non-durable data files may also get reclaimed if they are older than
# reclaim_age, but not if the time they were written to disk (i.e. mtime) is
# less than commit_window seconds ago. The commit_window also prevents the
# reconstructor removing recently written non-durable data files from a handoff
# node after reverting them to a primary. This gives the object-server a window
# in which to finish a concurrent PUT on a handoff and mark the data durable. A
# commit_window greater than zero is strongly recommended to avoid unintended
# removal of data files that were about to become durable; commit_window should
# be much less than reclaim_age.
# commit_window = 60.0
#
# You can set scheduling priority of processes. Niceness values range from -20
# (most favorable to the process) to 19 (least favorable to the process).
# nice_priority =
#
# You can set I/O scheduling class and priority of processes. I/O niceness
# class values are IOPRIO_CLASS_RT (realtime), IOPRIO_CLASS_BE (best-effort) and
# IOPRIO_CLASS_IDLE (idle). I/O niceness priority is a number which goes from
# 0 to 7. The higher the value, the lower the I/O priority of the process.
# Work only with ionice_class.
# ionice_class =
# ionice_priority =

[pipeline:main]
pipeline = healthcheck recon backend_ratelimit object-server

[app:object-server]
use = egg:swift#object
# You can override the default log routing for this app here:
set log_name = swift-object-server
# set log_facility = LOG_LOCAL0
# set log_level = INFO
# set log_requests = true
# set log_address = /dev/log
#
# max_upload_time = 86400
#
# slow is the total amount of seconds an object PUT/DELETE request takes at
# least. If it is faster, the object server will sleep this amount of time minus
# the already passed transaction time.  This is only useful for simulating slow
# devices on storage nodes during testing and development.
# slow = 0
#
# Objects smaller than this are not evicted from the buffercache once read
# keep_cache_size = 5242880
#
# If true, objects for authenticated GET requests may be kept in buffer cache
# if small enough
# keep_cache_private = false
#
# If true, SLO object's manifest file for GET requests may be kept in buffer cache
# if smaller than 'keep_cache_size'. And this config will only matter when
# 'keep_cache_private' is false.
# keep_cache_slo_manifest = false
#
# cooperative_period defines how frequent object server GET/PUT request will
# perform the cooperative yielding during iterating the disk chunks. For
# example, value of '5' will insert one sleep() after every 5 disk_chunk_size
# chunk reads/writes. A value of '0' (the default) will turn off cooperative
# yielding.
# cooperative_period = 0
#
# By default, the object-server will always validate the MD5 of object data
# while streaming a complete object response. Occassionally this is identified
# as a CPU bottleneck, consuming as much as 40% of the CPU time of the
# object-server. Since range-request-heavy clients don't get these integrity
# checks, it seems reasonable to give operators a chance to tune it down and
# instead rely on the object-auditor to detect and quarantine corrupted objects.
# etag_validate_pct = 100
#
# on PUTs, sync data every n MB
# mb_per_sync = 512
#
# Comma separated list of headers that can be set in metadata on an object.
# This list is in addition to X-Object-Meta-* headers and cannot include
# Content-Type, etag, Content-Length, or deleted
# allowed_headers = Content-Disposition, Content-Encoding, X-Delete-At, X-Object-Manifest, X-Static-Large-Object, Cache-Control, Content-Language, Expires, X-Robots-Tag

# The number of threads in eventlet's thread pool. Most IO will occur
# in the object server's main thread, but certain "heavy" IO
# operations will occur in separate IO threads, managed by eventlet.
#
# The default value is auto, whose actual value is dependent on the
# servers_per_port value:
#
#  - When servers_per_port is zero, the default value of
#    eventlet_tpool_num_threads is empty, which uses eventlet's default
#    (currently 20 threads).
#
#  - When servers_per_port is nonzero, the default value of
#    eventlet_tpool_num_threads is 1.
#
# But you may override this value to any integer value.
#
# Note that this value is threads per object-server process, so to
# compute the total number of IO threads on a node, you must multiply
# this by the number of object-server processes on the node.
#
# eventlet_tpool_num_threads = auto

# You can disable REPLICATE and SSYNC handling (default is to allow it). When
# deploying a cluster with a separate replication network, you'll want multiple
# object-server processes running: one for client-driven traffic and another
# for replication traffic. The server handling client-driven traffic may set
# this to false. If there is only one object-server process, leave this as
# true.
# replication_server = true
#
# Set to restrict the number of concurrent incoming SSYNC requests
# Set to 0 for unlimited
# Note that SSYNC requests are only used by the object reconstructor or the
# object replicator when configured to use ssync.
# replication_concurrency = 4
#
# Set to restrict the number of concurrent incoming SSYNC requests per
# device; set to 0 for unlimited requests per device. This can help control
# I/O to each device. This does not override replication_concurrency described
# above, so you may need to adjust both parameters depending on your hardware
# or network capacity.
# replication_concurrency_per_device = 1
#
# Number of seconds to wait for an existing replication device lock before
# giving up.
# replication_lock_timeout = 15
#
# These next two settings control when the SSYNC subrequest handler will
# abort an incoming SSYNC attempt. An abort will occur if there are at
# least threshold number of failures and the value of failures / successes
# exceeds the ratio. The defaults of 100 and 1.0 means that at least 100
# failures have to occur and there have to be more failures than successes for
# an abort to occur.
# replication_failure_threshold = 100
# replication_failure_ratio = 1.0
#
# Use splice() for zero-copy object GETs. This requires Linux kernel
# version 3.0 or greater. If you set "splice = yes" but the kernel
# does not support it, error messages will appear in the object server
# logs at startup, but your object servers should continue to function.
#
# splice = no
#
# You can set scheduling priority of processes. Niceness values range from -20
# (most favorable to the process) to 19 (least favorable to the process).
# nice_priority =
#
# You can set I/O scheduling class and priority of processes. I/O niceness
# class values are IOPRIO_CLASS_RT (realtime), IOPRIO_CLASS_BE (best-effort) and
# IOPRIO_CLASS_IDLE (idle). I/O niceness priority is a number which goes from
# 0 to 7. The higher the value, the lower the I/O priority of the process.
# Work only with ionice_class.
# ionice_class =
# ionice_priority =
#
# When reloading servers with SIGUSR1, workers running with old config/code
# are allowed some time to finish serving in-flight requests. Use this to
# configure the grace period (in seconds), after which the reloaded server
# will issue SIGKILLs to remaining stale workers.
# stale_worker_timeout = 86400

[filter:healthcheck]
use = egg:swift#healthcheck
# An optional filesystem path, which if present, will cause the healthcheck
# URL to return "503 Service Unavailable" with a body of "DISABLED BY FILE"
# disable_path =

[filter:recon]
use = egg:swift#recon
#recon_cache_path = /var/cache/swift
#recon_lock_path = /var/lock

[filter:backend_ratelimit]
use = egg:swift#backend_ratelimit
# Config options can optionally be loaded from a separate config file. Config
# options in this section will be used unless the same option is found in the
# config file, in which case the config file option will be used. See the
# backend-ratelimit.conf-sample file for details of available config options.
# backend_ratelimit_conf_path = /etc/swift/backend-ratelimit.conf

# The minimum interval between attempts to reload any config file at
# backend_ratelimit_conf_path while the server is running. A value of 0 means
# that the file is loaded at start-up but not subsequently reloaded. Note that
# config options in this section are never reloaded after start-up.
# config_reload_interval = 60

[object-replicator]
# You can override the default log routing for this app here (don't use set!):
log_name = swift-object-replicator
# log_facility = LOG_LOCAL0
# log_level = INFO
# log_address = /dev/log
#
# daemonize = on
#
# Time in seconds to wait between replication passes
# interval = 30.0
# run_pause is deprecated, use interval instead
# run_pause = 30.0
#
# Number of concurrent replication jobs to run. This is per-process,
# so replicator_workers=W and concurrency=C will result in W*C
# replication jobs running at once.
# concurrency = 1
#
# Number of worker processes to use. No matter how big this number is,
# at most one worker per disk will be used. 0 means no forking; all work
# is done in the main process.
# replicator_workers = 0
#
# stats_interval = 300.0
#
# default is rsync, alternative is ssync
# sync_method = rsync
#
# max duration of a partition rsync
# rsync_timeout = 900
#
# bandwidth limit for rsync in kB/s. 0 means unlimited. rsync 3.2.2 and later
# accept suffixed values like 10M or 1.5G; see the --bwlimit option for rsync(1)
# rsync_bwlimit = 0
#
# passed to rsync for both io op timeout and connection timeout
# rsync_io_timeout = 30
#
# Allow rsync to compress data which is transmitted to destination node
# during sync. However, this is applicable only when destination node is in
# a different region than the local one.
# NOTE: Objects that are already compressed (for example: .tar.gz, .mp3) might
# slow down the syncing process.
# rsync_compress = no
#
# Format of the rsync module where the replicator will send data. See
# etc/rsyncd.conf-sample for some usage examples.
# rsync_module = {replication_ip}::object
#
# node_timeout = <whatever's in the DEFAULT section or 10>
# max duration of an http request; this is for REPLICATE finalization calls and
# so should be longer than node_timeout
# http_timeout = 60
#
# attempts to kill all workers if nothing replicates for lockup_timeout seconds
# lockup_timeout = 1800
#
# ring_check_interval = 15.0
# recon_cache_path = /var/cache/swift
#
# By default, per-file rsync transfers are logged at debug if successful and
# error on failure. During large rebalances (which both increase the number
# of diskfiles transferred and increases the likelihood of failures), this
# can overwhelm log aggregation while providing little useful insights.
# Change this to false to disable per-file logging.
# log_rsync_transfers = true
#
# limits how long rsync error log lines are
# 0 means to log the entire line
# rsync_error_log_line_length = 0
#
# handoffs_first and handoff_delete are options for a special case
# such as disk full in the cluster. These two options SHOULD NOT BE
# CHANGED, except for such an extreme situations. (e.g. disks filled up
# or are about to fill up. Anyway, DO NOT let your drives fill up)
# handoffs_first is the flag to replicate handoffs prior to canonical
# partitions. It allows to force syncing and deleting handoffs quickly.
# If set to a True value(e.g. "True" or "1"), partitions
# that are not supposed to be on the node will be replicated first.
# handoffs_first = False
#
# handoff_delete is the number of replicas which are ensured in swift.
# If the number less than the number of replicas is set, object-replicator
# could delete local handoffs even if all replicas are not ensured in the
# cluster. Object-replicator would remove local handoff partition directories
# after syncing partition when the number of successful responses is greater
# than or equal to this number. By default(auto), handoff partitions will be
# removed  when it has successfully replicated to all the canonical nodes.
# handoff_delete = auto
#
# You can set scheduling priority of processes. Niceness values range from -20
# (most favorable to the process) to 19 (least favorable to the process).
# nice_priority =
#
# You can set I/O scheduling class and priority of processes. I/O niceness
# class values are IOPRIO_CLASS_RT (realtime), IOPRIO_CLASS_BE (best-effort) and
# IOPRIO_CLASS_IDLE (idle). I/O niceness priority is a number which goes from
# 0 to 7. The higher the value, the lower the I/O priority of the process.
# Work only with ionice_class.
# ionice_class =
# ionice_priority =

[object-reconstructor]
# You can override the default log routing for this app here (don't use set!):
# Unless otherwise noted, each setting below has the same meaning as described
# in the [object-replicator] section, however these settings apply to the EC
# reconstructor
#
log_name = swift-object-reconstructor
# log_facility = LOG_LOCAL0
# log_level = INFO
# log_address = /dev/log
#
# daemonize = on
#
# Time in seconds to wait between reconstruction passes
# interval = 30.0
# run_pause is deprecated, use interval instead
# run_pause = 30.0
#
# Maximum number of worker processes to spawn.  Each worker will handle a
# subset of devices.  Devices will be assigned evenly among the workers so that
# workers cycle at similar intervals (which can lead to fewer workers than
# requested).  You can not have more workers than devices.  If you have no
# devices only a single worker is spawned.
# reconstructor_workers = 0
#
# concurrency = 1
# stats_interval = 300.0
# node_timeout = 10
# http_timeout = 60
# lockup_timeout = 1800
# ring_check_interval = 15.0
# recon_cache_path = /var/cache/swift
#
# The handoffs_only mode option is for special case emergency situations during
# rebalance such as disk full in the cluster.  This option SHOULD NOT BE
# CHANGED, except for extreme situations.  When handoffs_only mode is enabled
# the reconstructor will *only* revert fragments from handoff nodes to primary
# nodes and will not sync primary nodes with neighboring primary nodes.  This
# will force the reconstructor to sync and delete handoffs' fragments more
# quickly and minimize the time of the rebalance by limiting the number of
# rebuilds.  The handoffs_only option is only for temporary use and should be
# disabled as soon as the emergency situation has been resolved.  When
# handoffs_only is not set, the deprecated handoffs_first option will be
# honored as a synonym, but may be ignored in a future release.
# handoffs_only = False
#
# The default strategy for unmounted drives will stage rebuilt data on a
# handoff node until updated rings are deployed.  Because fragments are rebuilt
# on offset handoffs based on fragment index and the proxy limits how deep it
# will search for EC frags we restrict how many nodes we'll try.  Setting to 0
# will disable rebuilds to handoffs and only rebuild fragments for unmounted
# devices to mounted primaries after a ring change.
# Setting to -1 means "no limit".
# rebuild_handoff_node_count = 2
#
# By default the reconstructor attempts to revert all objects from handoff
# partitions in a single batch using a single SSYNC request. In exceptional
# circumstances max_objects_per_revert can be used to temporarily limit the
# number of objects reverted by each reconstructor revert type job. If more
# than max_objects_per_revert are available in a sender's handoff partition,
# the remaining objects will remain in the handoff partition and will not be
# reverted until the next time the reconstructor visits that handoff partition
# i.e. with this option set, a single cycle of the reconstructor may not
# completely revert all handoff partitions. The option has no effect on
# reconstructor sync type jobs between primary partitions. A value of 0 (the
# default) means there is no limit.
# max_objects_per_revert = 0
#
# You can set scheduling priority of processes. Niceness values range from -20
# (most favorable to the process) to 19 (least favorable to the process).
# nice_priority =
#
# You can set I/O scheduling class and priority of processes. I/O niceness
# class values are IOPRIO_CLASS_RT (realtime), IOPRIO_CLASS_BE (best-effort) and
# IOPRIO_CLASS_IDLE (idle). I/O niceness priority is a number which goes from
# 0 to 7. The higher the value, the lower the I/O priority of the process.
# Work only with ionice_class.
# ionice_class =
# ionice_priority =
#
# When upgrading from liberasurecode<=1.5.0, you may want to continue writing
# legacy CRCs until all nodes are upgraded and capabale of reading fragments
# with zlib CRCs. liberasurecode>=1.6.2 checks for the environment variable
# LIBERASURECODE_WRITE_LEGACY_CRC; if set (value doesn't matter), it will use
# its legacy CRC. Set this option to true or false to ensure the environment
# variable is or is not set. Leave the option blank or absent to not touch
# the environment (default). For more information, see
# https://bugs.launchpad.net/liberasurecode/+bug/1886088
# write_legacy_ec_crc =
#
# When attempting to reconstruct a missing fragment on another node from a
# fragment on the local node, the reconstructor may fail to fetch sufficient
# fragments to reconstruct the missing fragment. This may be because most or
# all of the remote fragments have been deleted, and the local fragment is
# stale, in which case the reconstructor will never succeed in reconstructing
# the apparently missing fragment and will log errors. If the object's
# tombstones have been reclaimed then the stale fragment will never be deleted
# (see https://bugs.launchpad.net/swift/+bug/1655608). If an operator suspects
# that stale fragments have been re-introduced to the cluster and is seeing
# error logs similar to those in the bug report, then the quarantine_threshold
# option may be set to a value greater than zero. This enables the
# reconstructor to quarantine the stale fragments when it fails to fetch more
# than the quarantine_threshold number of fragments (including the stale
# fragment) during an attempt to reconstruct. For example, setting the
# quarantine_threshold to 1 would cause a fragment to be quarantined if no
# other fragments can be fetched. The value may be reset to zero after the
# reconstructor has run on all affected nodes and the error logs are no longer
# seen.
# Note: the quarantine_threshold applies equally to all policies, but for each
# policy it is effectively capped at (ec_ndata - 1) so that a fragment is never
# quarantined when sufficient fragments exist to reconstruct the object.
# quarantine_threshold = 0
#
# Fragments are not quarantined until they are older than
# quarantine_age, which defaults to the value of reclaim_age.
# quarantine_age =
#
# Sets the maximum number of nodes to which requests will be made before
# quarantining a fragment. You can use '* replicas' at the end to have it use
# the number given times the number of replicas for the ring being used for the
# requests. The minimum number of nodes to which requests are made is the
# number of replicas for the policy minus 1 (the node on which the fragment is
# to be rebuilt). The minimum is only exceeded if request_node_count is
# greater, and only for the purposes of quarantining.
# request_node_count = 2 * replicas

[object-updater]
# You can override the default log routing for this app here (don't use set!):
log_name = swift-object-updater
# log_facility = LOG_LOCAL0
# log_level = INFO
# log_address = /dev/log
#
# interval = 300.0
# node_timeout = <whatever's in the DEFAULT section or 10>
#
# updater_workers controls how many processes the object updater will
# spawn, while concurrency controls how many async_pending records
# each updater process will operate on at any one time. With
# concurrency=C and updater_workers=W, there will be up to W*C
# async_pending records being processed at once.
# concurrency = 8
# updater_workers = 1
#
# Send at most this many object updates per second
# objects_per_second = 50
#
# Send at most this many object updates per bucket per second. The value must
# be a float greater than or equal to 0. Set to 0 for unlimited.
# max_objects_per_container_per_second = 0
#
# The per_container ratelimit implementation uses a hashring to constrain
# memory requirements.  Orders of magnitude more buckets will use (nominally)
# more memory, but will ratelimit smaller groups of containers. The value must
# be an integer greater than 0.
# per_container_ratelimit_buckets = 1000
#
# Updates that cannot be sent due to per-container rate-limiting may be
# deferred and re-tried at the end of the updater cycle. This option constrains
# the size of the in-memory data structure used to store deferred updates.
# Must be an integer value greater than or equal to 0.
# max_deferred_updates = 10000
#
# Maximum number of oldest async pending timestamps to track for each
# account-container pair.
# async_tracker_max_entries = 100
# Maximum number of oldest async pending timestamps to dump to recon cache.
# async_tracker_dump_count = 5
#
# slowdown will sleep that amount between objects. Deprecated; use
# objects_per_second instead.
# slowdown = 0.01
#
# Log stats (at INFO level) every report_interval seconds. This
# logging is per-process, so with concurrency > 1, the logs will
# contain one stats log per worker process every report_interval
# seconds.
# report_interval = 300.0
#
# recon_cache_path = /var/cache/swift
#
# You can set scheduling priority of processes. Niceness values range from -20
# (most favorable to the process) to 19 (least favorable to the process).
# nice_priority =
#
# You can set I/O scheduling class and priority of processes. I/O niceness
# class values are IOPRIO_CLASS_RT (realtime), IOPRIO_CLASS_BE (best-effort) and
# IOPRIO_CLASS_IDLE (idle). I/O niceness priority is a number which goes from
# 0 to 7. The higher the value, the lower the I/O priority of the process.
# Work only with ionice_class.
# ionice_class =
# ionice_priority =

[object-auditor]
# You can override the default log routing for this app here (don't use set!):
log_name = swift-object-auditor
# log_facility = LOG_LOCAL0
# log_level = INFO
# log_address = /dev/log
#
# Time in seconds to wait between auditor passes
# interval = 30.0
#
# You can set the disk chunk size that the auditor uses making it larger if
# you like for more efficient local auditing of larger objects
# disk_chunk_size = 65536
# files_per_second = 20
# concurrency = 1
# bytes_per_second = 10000000
# log_time = 3600
# zero_byte_files_per_second = 50
# recon_cache_path = /var/cache/swift

# Takes a comma separated list of ints. If set, the object auditor will
# increment a counter for every object whose size is <= to the given break
# points and report the result after a full scan.
# object_size_stats =
#
# You can set scheduling priority of processes. Niceness values range from -20
# (most favorable to the process) to 19 (least favorable to the process).
# nice_priority =
#
# You can set I/O scheduling class and priority of processes. I/O niceness
# class values are IOPRIO_CLASS_RT (realtime), IOPRIO_CLASS_BE (best-effort) and
# IOPRIO_CLASS_IDLE (idle). I/O niceness priority is a number which goes from
# 0 to 7. The higher the value, the lower the I/O priority of the process.
# Work only with ionice_class.
# ionice_class =
# ionice_priority =

# The auditor will cleanup old rsync tempfiles after they are "old
# enough" to delete.  You can configure the time elapsed in seconds
# before rsync tempfiles will be unlinked, or the default value of
# "auto" try to use object-replicator's rsync_timeout + 900 and fallback
# to 86400 (1 day).
# rsync_tempfile_timeout = auto

# A comma-separated list of watcher entry points. This lets operators
# programmatically see audited objects.
#
# The entry point group name is "swift.object_audit_watcher". If your
# setup.py has something like this:
#
# entry_points={'swift.object_audit_watcher': [
#     'some_watcher = some_module:Watcher']}
#
# then you would enable it with "watchers = some_package#some_watcher".
# For example, the built-in reference implementation is enabled as
# "watchers = swift#dark_data".
#
# watchers =

# Watcher-specific parameters can be added in a section with a name
# [object-auditor:watcher:some_package#some_watcher]. The following
# example uses the built-in reference watcher.
#
# [object-auditor:watcher:swift#dark_data]
#
# Action type can be 'log' (default), 'delete', or 'quarantine'.
# action=log
#
# The watcher ignores the objects younger than certain minimum age.
# This prevents spurious actions upon fresh objects while container
# listings eventually settle.
# grace_age=604800

[object-expirer]
# If this true, this expirer will execute tasks from legacy expirer task queue,
# at least one object server should run with dequeue_from_legacy = true
# dequeue_from_legacy = false
#
# Note: Be careful not to enable ``dequeue_from_legacy`` on too many expirers
# as all legacy tasks are stored in a single hidden account and the same hidden
# containers. On a large cluster one may inadvertently make the
# acccount/container server for the hidden too busy.
#
# Note: the processes and process options can only be used in conjunction with
# notes using `dequeue_from_legacy = true`.  These options are ignored on nodes
# with `dequeue_from_legacy = false`.
#
# processes is how many parts to divide the legacy work into, one part per
# process that will be doing the work
# processes set 0 means that a single legacy process will be doing all the work
# processes can also be specified on the command line and will override the
# config value
# processes = 0
#
# process is which of the parts a particular legacy process will work on
# process can also be specified on the command line and will override the config
# value
# process is "zero based", if you want to use 3 processes, you should run
# processes with process set to 0, 1, and 2
# process = 0
#
# internal_client_conf_path = /etc/swift/internal-client.conf
#
# You can override the default log routing for this app here (don't use set!):
log_name = swift-object-expirer
# log_facility = LOG_LOCAL0
# log_level = INFO
# log_address = /dev/log
#
# interval = 300.0
#
# report_interval = 300.0
#
# request_tries is the number of times the expirer's internal client will
# attempt any given request in the event of failure. The default is 3.
# request_tries = 3
#
# concurrency is the level of concurrency to use to do the work, this value
# must be set to at least 1
# concurrency = 1
#
# deletes can be ratelimited to prevent the expirer from overwhelming the cluster
# tasks_per_second = 50.0
#
# The expirer will re-attempt expiring if the source object is not available
# up to reclaim_age seconds before it gives up and deletes the entry in the
# queue.
# reclaim_age = 604800

# Number of tasks objects to cache before processing.  With many nodes it may
# take some time to fill a larger cache_size but may also have a better chance
# to distribute DELETEs to multiple target containers.
# round_robin_task_cache_size = 100000

# recon_cache_path = /var/cache/swift
#
# You can set scheduling priority of processes. Niceness values range from -20
# (most favorable to the process) to 19 (least favorable to the process).
# nice_priority =
#
# You can set I/O scheduling class and priority of processes. I/O niceness
# class values are realtime, best-effort and idle. I/O niceness
# priority is a number which goes from 0 to 7. The higher the value, the lower
# the I/O priority of the process. Work only with ionice_class.
# ionice_class =
# ionice_priority =
#
# The expirer can delay the reaping of expired objects on disk (and in
# container listings) with an account level or container level delay_reaping
# time.
# After the delay_reaping time has passed objects will be reaped as normal.
# You may configure this delay_reaping value in seconds with dynamic config
# option names prefixed with delay_reaping_<ACCT> for account level delays
# and delay_reaping_<ACCT>/<CNTR> for container level delays.
# Special characters in <ACCT> or <CNTR> should be quoted.
# The delay_reaping value should be a float value greater than or equal to
# zero.
# A container level delay_reaping does not require an account level
# delay_reaping but overrides the account level delay_reaping for the same
# account if it exists.
# For example:
# delay_reaping_AUTH_test = 300.0
# delay_reaping_AUTH_test2 = 86400.0
# delay_reaping_AUTH_test/test = 400.0
# delay_reaping_AUTH_test/test2 = 600.0
# delay_reaping_AUTH_test/special%0Achars%3Dshould%20be%20quoted
# N.B. By default no delay_reaping value is configured for any accounts or
# containers.

# Note: Put it at the beginning of the pipleline to profile all middleware. But
# it is safer to put this after healthcheck. Not intended for production
# environments!
[filter:xprofile]
use = egg:swift#xprofile
# This option enable you to switch profilers which should inherit from python
# standard profiler. Currently the supported value can be 'cProfile',
# 'eventlet.green.profile' etc.
# profile_module = eventlet.green.profile
#
# This prefix will be used to combine process ID and timestamp to name the
# profile data file.  Make sure the executing user has permission to write
# into this path (missing path segments will be created, if necessary).
# If you enable profiling in more than one type of daemon, you must override
# it with an unique value like: /var/log/swift/profile/object.profile
# log_filename_prefix = /tmp/log/swift/profile/default.profile
#
# the profile data will be dumped to local disk based on above naming rule
# in this interval.
# dump_interval = 5.0
#
# Be careful, this option will enable profiler to dump data into the file with
# time stamp which means there will be lots of files piled up in the directory.
# dump_timestamp = false
#
# This is the path of the URL to access the mini web UI.
# path = /__profile__
#
# Clear the data when the wsgi server shutdown.
# flush_at_shutdown = false
#
# unwind the iterator of applications
# unwind = false

[object-relinker]
# You can override the default log routing for this app here (don't use set!):
log_name = swift-object-relinker
# log_facility = LOG_LOCAL0
# log_level = INFO
# log_address = /dev/log
#
# Start up to this many sub-processes to process disks in parallel. Each disk
# will be handled by at most one child process. By default, one process is
# spawned per disk.
# workers = auto
#
# Target this many relinks/cleanups per second for each worker, to reduce the
# likelihood that the added I/O from a partition-power increase impacts
# client traffic. Use zero for unlimited.
# files_per_second = 0.0
#
# stats_interval = 300.0
# recon_cache_path = /var/cache/swift