OntapClusterCollector is a diamond plugin to collect metrics from a NetApp Ontap OS 7-Mode or/and C-Mode (Cluster Mode) using the NetApp Manageability SDK. It is smart enought to work out the dependencies to gather a specific metric, and also calculate the value depending if it is a delta, a rate, a derivative metric or a "second" derivative metric.
It is not only a plugin, it is also a standalone program to see and check the performance objects on NetApp.
$ ./ontapng.py --help
Standalone program and/or Diamond plugin to retrive metrics
and info from NetApp devices. It supports 7-Mode anc C-Mode.
Usage:
./ontapng.py [-h | --help]
./ontapng.py [-v <api.version>] -s <server> -u <user> -p <password> [action]
Where <action> could be:
* objects : returns all objects available on the device
* info <object> : returns all metrics for <object>
* instances <object> : returns the name of all instaces of <object>
* metrics <object> [instace]: returns all counters for all instances
or if one instances is provided, only for that one.
(c) Jose Riguera Lopez, 2013-2015 <[email protected]>
This plugin supports Diamond v4.x and Diamond v3.x, please check the tags and
branchs of this repository. The parent class Collector provided by Diamond has
changed with Diamond 4.x, it is not compatible with Diamond v3.x because of
the changes in the scheduler system. Starting with Diamond 4.x all the devices
defined in the configuration file are gathered in sequencial mode, be careful!.
If you want to have a process per device (like threads in version 0.1.x with Diamond v3.x),
just define different configuration files per device, by creating a file like
OntapClusterCollector instance.conf [1], have a look at the Diamond documentation.
[1] Yes ... WTF!, a configuration file with whitespace!. I think it is the
only program I know where authors decided to do in that way, using configuration
files with white spaces. I do not know if it is compatible with LSB, but I
suggested them using a more elegant way to define instances like for example
OntapClusterCollector.instance.conf (keeping the compatibility with white spaces),
and they did not accept ... I do not see advantages using white spaces, I see it
a way to look for problems, but it is my opinion.
Branch 0.1.x and tags 0.1.x are designed for Diamond 3.x versions. Master, develop branchs (and tags 0.2.x and up) are to Diamond 4.x releases.
In order to get working these modules, you will need the SDK on the system. This module has been developed using v5.0 of the SDK. As of writing the SDK can be found at https://communities.netapp.com/docs/DOC-1152
Diamond is a python daemon that collects system metrics and publishes them to
Graphite
(and others). It is
capable of collecting cpu, memory, network, i/o, load and disk metrics.
Additionally, it features an API for implementing custom collectors for
gathering metrics from almost any source.
Diamond collectors run within the diamond process and collect metrics that can be published to a graphite server.
To get the diamond code using the git reference on each branch, just type:
$ git submodule init
$ git submodule update
# now you can play using vagrant
$ vagrant up
The NetAPP python API is bundled with the collector.
Example OntapClusterCollector.conf:
# Configuration for OntapClusterCollector
enabled = True
path_prefix = netapp
reconnect = 60
hostname_method = none
splay = 10
interval = 50 # Could be 60 ... but just to avoid gaps
# Warning, all devices are gathered in sequential mode, single thread/process
[devices]
# [[cluster]]
# ip = 123.123.123.123
# user = root
# password = strongpassword
# apiversion = 1.15
# publish = 1 # 1 = publish all metrics
# # 2 = do not publish zeros
# # 0 = do not publish
#
# #[[[na_object=pretty.path.@.${metric1}|filters]]]
# # This is the list of metrics to collect.
# # The na_object is the object name in the NetApp API.
# # For each object we have a list of metrics to retrieve.
# # The purpose of the pretty name is to enable replacement of reported
# # metric names, since some the names in the API can be confusing.
#
# [[[aggregate=${node_name}.aggr.$instance_name]]]
# total_transfers = rate_ops
# user_reads = rate_ops_reads
# user_writes = rate_ops_writes
# cp_reads = -
#
# Device in cluster mode (v 8.x):
[[cluster]]
ip = 10.3.3.176
user = admin
password = password
publish = 1
apiversion = 1.15
[[[aggregate=nodes.${node_name}.aggr.${instance_name}]]]
total_transfers = rate_ops
user_reads = rate_ops_reads
user_writes = rate_ops_writes
cp_reads = rate_ops_cp_reads
user_read_blocks = rate_blocks_user_reads
user_write_blocks = rate_blocks_user_writes
cp_read_blocks = rate_blocks_cp_reads
wv_fsinfo_blks_used = blocks_used
wv_fsinfo_blks_total = blocks_total
[[[disk=nodes.${node_name}.aggr.${raid_group}.${instance_name}]]]
disk_speed = rpm
total_transfers = rate_iops
user_reads = rate_ops_reads
user_writes = rate_ops_writes
cp_reads = rate_read_cp
disk_busy = pct_busy
io_pending = avg_iops_pending
io_queued = avg_iops_queued
user_write_blocks = rate_blocks_write
user_write_latency = avg_latency_micros_write
user_read_blocks = rate_blocks_read
user_read_latency = avg_latency_micros_read
cp_read_blocks = rate_blocks_cp_read
cp_read_latency = avg_latency_micros_cp_read
[[[processor=nodes.${node_name}.processor.${instance_name}]]]
processor_busy = pct_busy
processor_elapsed_time = time_elapsed
domain_busy = -
[[[system=nodes.${node_name}.${instance_name}]]]
nfs_ops = rate_ops_nfs
cifs_ops = rate_ops_cifs
fcp_ops = rate_ops_fcp
iscsi_ops = rate_ops_iscsi
read_ops = rate_ops_read
write_ops = rate_ops_write
sys_write_latency = avg_latency_ms_write
sys_read_latency = avg_latency_ms_read
total_ops = rate_ops
sys_avg_latency = avg_latency_ms
net_data_recv = rate_kbytes_net_recv
net_data_sent = rate_kbytes_net_sent
fcp_data_recv = rate_kbytes_fcp_recv
fcp_data_sent = rate_kbytes_fcp_sent
disk_data_read = rate_kbytes_disk_read
disk_data_written = rate_kbytes_disk_written
cpu_busy = pct_cpu_busy
cpu_elapsed_time = base_time_cpu_elapsed
avg_processor_busy = pct_processors_all_avg_busy
cpu_elapsed_time1 = base_time_cpu_elapsed_avg
total_processor_busy = pct_processors_all_total_busy
cpu_elapsed_time2 = base_time_cpu_elapsed_total
[[[ifnet=nodes.${node_name}.net.${instance_name}]]]
recv_packets = rate_pkts_recv
recv_errors = rate_recv_errors
send_packets = rate_pkts_send
send_errors = rate_send_errors
collisions = rate_collisions
recv_drop_packets = rate_pkts_drop
recv_data = rate_bytes_recv
send_data = rate_bytes_send
[[[ext_cache_obj=nodes.${node_name}.ext_cache.${instance_name}]]]
usage = pct_usage_blocks
accesses = cnt_delta_accesses
blocks = cnt_blocks
disk_reads_replaced = rate_disk_replaced_readio
hit = rate_hit_buffers
hit_flushq = rate_flushq_hit_buffers
hit_once = rate_once_hit_buffers
hit_age = rate_age_hit_buffers
miss = rate_miss_buffers
miss_flushq = rate_flushq_miss_buffers
miss_once = rate_once_miss_buffers
miss_age = rate_age_miss_buffers
hit_percent = pct_hit
inserts = rate_inserts_buffers
inserts_flushq = rate_flushq_inserts_buffers
inserts_once = rate_once_inserts_buffers
inserts_age = rate_age_inserts_buffers
reuse_percent = pct_reuse
evicts = rate_evicts_blocks
evicts_ref = rate_ref_evicts_blocks
invalidates = rate_invalidates_blocks
[[[wafl=nodes.${node_name}.${instance_name}]]]
name_cache_hit = rate_cache_hits
total_cp_msecs = cnt_msecs_spent_cp
wafl_total_blk_writes = rate_blocks_written
wafl_total_blk_readaheads = rate_blocks_readaheads
wafl_total_blk_reads = rate_blocks_read
[[[volume=vservers.${vserver_name}.volumes.${instance_name}]]]
total_ops = rate_ops
read_ops = rate_ops_read
write_ops = rate_ops_write
other_ops = rate_ops_other
avg_latency = avg_latency_micros
read_blocks = rate_blocks_read
write_blocks = rate_blocks_write
read_latency = avg_latency_micros_read
write_latency = avg_latency_micros_write
read_data = rate_bytes_read
write_data = rate_bytes_write
other_latency = avg_latency_micros_other
wv_fsinfo_blks_total = cnt_blocks_total
wv_fsinfo_blks_reserve = cnt_blocks_reserved
wv_fsinfo_blks_used = cnt_blocks_used
[[[nfsv3=vservers.${instance_name}.nfsv3]]]
nfsv3_ops = rate_ops_nfsv3
nfsv3_read_ops = rate_ops_nfsv3_read
nfsv3_write_ops = rate_ops_nfsv3_write
read_total = cnt_ops_read
write_total = cnt_ops_write
write_avg_latency = avg_latency_micros_nfsv3_write
read_avg_latency = avg_latency_micros_nfsv3_read
nfsv3_write_throughput = rate_throughput_nfsv3_write
nfsv3_read_throughput = rate_throughput_nfsv3_read
nfsv3_throughput = rate_throughput_nfsv3
nfsv3_dnfs_ops = rate_ops_nfsv3_oracle
[[[iscsi_lif:vserver=vservers.${instance_name}.iscsi]]]
iscsi_read_ops = rate_ops_iscsi_read
iscsi_write_ops = rate_ops_iscsi_write
avg_write_latency = avg_latency_micros_iscsi_write
avg_read_latency = avg_latency_micros_iscsi_read
avg_latency = avg_latency_micros_iscsi
data_in_sent = cnt_blocks_recv
data_out_blocks = cnt_blocks_sent
[[[cifs=vservers.${instance_name}.cifs]]]
cifs_ops = rate_ops_cifs
cifs_read_ops = rate_ops_cifs_read
cifs_write_ops = rate_ops_cifs_write
cifs_latency = avg_latency_micros_cifs
cifs_write_latency = avg_latency_micros_cifs_write
cifs_read_latency = avg_latency_micros_cifs_read
connected_shares = cnt_cifs_connected_shares
reconnection_requests_total = cnt_cifs_reconnection_requests_total
# Old vfiler 7.x:
[[sever-mode]]
ip = 172.29.1.161
user = root
password = password
publish = 1
apiversion = 1.12
[[[aggregate=aggregate.@]]]
total_transfers = rate_ops
user_reads = rate_ops_reads
user_writes = rate_ops_writes
cp_reads = rate_ops_cp_reads
user_read_blocks = rate_blocks_user_reads
user_write_blocks = rate_blocks_user_writes
cp_read_blocks = rate_blocks_cp_reads
wv_fsinfo_blks_used = blocks_used
wv_fsinfo_blks_total = blocks_total
[[[processor=processor.@]]]
processor_busy = pct_busy
processor_elapsed_time = time_elapsed
#domain_busy = -
[[[system=@]]]
nfs_ops = rate_ops_nfs
cifs_ops = rate_ops_cifs
fcp_ops = rate_ops_fcp
iscsi_ops = rate_ops_iscsi
read_ops = rate_ops_read
write_ops = rate_ops_write
sys_write_latency = avg_latency_ms_write
sys_read_latency = avg_latency_ms_read
total_ops = rate_ops
sys_avg_latency = avg_latency_ms
net_data_recv = rate_kbytes_net_recv
net_data_sent = rate_kbytes_net_sent
fcp_data_recv = rate_kbytes_fcp_recv
fcp_data_sent = rate_kbytes_fcp_sent
disk_data_read = rate_kbytes_disk_read
disk_data_written = rate_kbytes_disk_written
cpu_busy = pct_cpu_busy
cpu_elapsed_time = base_time_cpu_elapsed
avg_processor_busy = pct_processors_all_avg_busy
cpu_elapsed_time1 = base_time_cpu_elapsed_avg
total_processor_busy = pct_processors_all_total_busy
cpu_elapsed_time2 = base_time_cpu_elapsed_total
[[[disk=disk.${raid_name}]]]
disk_speed = rpm
total_transfers = rate_iops
user_reads = rate_ops_reads
user_writes = rate_ops_writes
cp_reads = rate_read_cp
disk_busy = pct_busy
io_pending = avg_iops_pending
io_queued = avg_iops_queued
user_write_blocks = rate_blocks_write
user_write_latency = avg_latency_micros_write
user_read_blocks = rate_blocks_read
user_read_latency = avg_latency_micros_read
cp_read_blocks = rate_blocks_cp_read
cp_read_latency = avg_latency_micros_cp_read
[[[ifnet=net.@]]]
recv_packets = rate_pkts_recv
recv_errors = rate_recv_errors
send_packets = rate_pkts_send
send_errors = rate_send_errors
collisions = rate_collisions
recv_drop_packets = rate_pkts_drop
recv_data = rate_bytes_recv
send_data = rate_bytes_send
[[[ext_cache_obj=ext_cache.@]]]
usage = pct_usage_blocks
accesses = cnt_delta_accesses
blocks = cnt_blocks
disk_reads_replaced = rate_disk_replaced_readio
hit = rate_hit_buffers
hit_flushq = rate_flushq_hit_buffers
hit_once = rate_once_hit_buffers
hit_age = rate_age_hit_buffers
miss = rate_miss_buffers
miss_flushq = rate_flushq_miss_buffers
miss_once = rate_once_miss_buffers
miss_age = rate_age_miss_buffers
hit_percent = pct_hit
inserts = rate_inserts_buffers
inserts_flushq = rate_flushq_inserts_buffers
inserts_once = rate_once_inserts_buffers
inserts_age = rate_age_inserts_buffers
reuse_percent = pct_reuse
evicts = rate_evicts_blocks
evicts_ref = rate_ref_evicts_blocks
invalidates = rate_invalidates_blocks
[[[wafl=@]]]
name_cache_hit = rate_cache_hits
total_cp_msecs = cnt_msecs_spent_cp
wafl_total_blk_writes = rate_blocks_written
wafl_total_blk_readaheads = rate_blocks_readaheads
wafl_total_blk_reads = rate_blocks_read
[[[volume=volume.@]]]
total_ops = rate_ops
read_ops = rate_ops_read
write_ops = rate_ops_write
other_ops = rate_ops_other
avg_latency = avg_latency_micros
read_blocks = rate_blocks_read
write_blocks = rate_blocks_write
read_latency = avg_latency_micros_read
write_latency = avg_latency_micros_write
read_data = rate_bytes_read
write_data = rate_bytes_write
other_latency = avg_latency_micros_other
wv_fsinfo_blks_total = cnt_blocks_total
wv_fsinfo_blks_reserve = cnt_blocks_reserved
wv_fsinfo_blks_used = cnt_blocks_used
[[[nfsv3=nfsv3.@]]]
nfsv3_ops = rate_ops_nfsv3
nfsv3_read_ops = rate_ops_nfsv3_read
nfsv3_write_ops = rate_ops_nfsv3_write
nfsv3_avg_write_latency_base = cnt_base_latency_nfsv3_avg_write
nfsv3_write_latency = avg_latency_ms_nfsv3_write
nfsv3_avg_read_latency_base = cnt_base_latency_nfsv3_avg_read
nfsv3_read_latency = avg_latency_ms_nfsv3_read
nfsv3_op_count = cnt_ops_null, cnt_ops_getattr, cnt_ops_setattr, cnt_ops_lookup, cnt_ops_access, cnt_ops_readlink, cnt_ops_read, cnt_ops_write, cnt_ops_create, cnt_ops_mkdir, cnt_ops_symlink, cnt_ops_mknod, cnt_ops_remove, cnt_ops_rmdir, cnt_ops_rename, cnt_ops_link, cnt_ops_readdir, cnt_ops_readdirplus, cnt_ops_fsstat, cnt_ops_fsinfo, cnt_ops_pathconf, cnt_ops_commit
nfsv3_op_percent = pct_ops_null, pct_ops_getattr, pct_ops_setattr, pct_ops_lookup, pct_ops_access, pct_ops_readlink, pct_ops_read, pct_ops_write, pct_ops_create, pct_ops_mkdir, pct_ops_symlink, pct_ops_mknod, pct_ops_remove, pct_ops_rmdir, pct_ops_rename, pct_ops_link, pct_ops_readdir, pct_ops_readdirplus, pct_ops_fsstat, pct_ops_fsinfo, pct_ops_pathconf, pct_ops_commit
[[[cifs=cifs.@]]]
cifs_ops = rate_ops
cifs_op_count = cnt_delta_ops
cifs_read_ops = rate_ops_read
cifs_write_ops = rate_ops_write
cifs_latency = avg_latency_ms
cifs_write_latency = avg_latency_ms_writes
cifs_read_latency = avg_latency_ms_reads
#EOF
The format for each object is [[[OBJECT-TYPE=PRETTY.PATH]]], where OBJECT-TYPE is a type
of object available on the device. PRETTY.PATH is a string to tell the program how build the
parent path for all the metrics for each OBJECT-TYPE instance found. To see all the object's
type, instances and metrics just use the command line feature. This is the definition format:
fixed.path.string: strings, just a static path to include in all instances.@: special variable to point to instance name reported by the API.${metric}: reference to a metric name available on the instance. A difference with the rest of the metrics, is this one can be a string, in that case you cannot reference it on the list of the metrics to gather. You can mix those format to build a metric path.
To specify the list of metrics to be gather per OBJECT-TYPE instance, the format is easy:
NetApp_api_metric = pretty_name, meaning that it will rewrite the API metric name topretty_nameand send it to the handler.NetApp_api_array_metric = pretty_name1, pretty_name2 ..., it does the same but for each metric in an array.NetApp_api_array_metric = -it will not rewrite the names, it will use the ones provided by the API.
To run this collector in test mode you can invoke the diamond server with the -r option and specify the collector path.
diamond -f -r path/to/ontapng.py -c conf/diamond.conf
running diamond in the foreground (-f) while logging to stdout (-l) is a good way to quickly see if a custom collector is unable to load.
diamond -f -l
Also, if you want to use Docker container to run the collector, have a look at the docker.sh about howto build it, run it
and pass the variables to define the configuration file.
Author:: Jose Riguera López (Springer SBM) ([email protected])
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