DOCA Telemetry Service
NVIDIA DOCA Telemetry Service Guide
This document provides instructions on how to use the DOCA Telemetry Service (DTS) container on top of NVIDIA® BlueField® DPU.
DOCA Telemetry Service (DTS) collects data from built-in providers and from external telemetry applications. The following 3 providers are available:
- sysfs
- ethtool
- tc (traffic controll)
Sysfs provider is enabled by default.
DTS stores collected data into binary files under the /opt/mellanox/doca/services/telemetry/data
directory. Data write is disabled by default due to BlueField storage restrictions.
DTS can export the data via Prometheus Endpoint (pull) or Fluent Bit (push).
DTS allows exporting NetFlow packets when data is collected from the DOCA Telemetry NetFlow API client application. NetFlow exporter is enabled from dts_config.ini
by setting NetFlow collector IP/address and port.
For more information about the deployment of DOCA containers on top of the BlueField DPU, refer to NVIDIA DOCA Container Deployment Guide.
2.1. DOCA Service on NGC
DTS is available on NGC, NVIDIA's container catalog. Service-specific configuration steps and deployment instructions can be found under the service's container page.
2.2. Default Deployment – BlueField OS
DTS starts automatically on BlueField boot according to the .yaml file located at /etc/kubelet.d/doca_telemetry_standalone.yaml
. Removing the .yaml file from this path stops the automatic DTS boot.
DTS files can be found under the directory /opt/mellanox/doca/services/telemetry/.
- Container folder mounts:
- config
- data
- ipc_sockets
- Backup files:
- doca_telemetry_service_${version}_arm64.tar.gz – DTS image
- doca_telemetry_standalone.yaml – copy of the default boot .yaml file
The configuration of DTS is placed under /opt/mellanox/doca/services/telemetry/config
by DTS during initialization. The user can interact with the dts_config.ini
file and fluent_bit_configs
folder. dts_config.ini
contains the main configuration for the service and must be used to enable/disable providers, exporters, data writing. More details are provided in the corresponding sections. For every update in this file, DST must be restarted. Interaction with fluent_bit_configs
folder is described in section Fluent Bit.
3.1. Init Scripts
The InitContainers
section of the .yaml
file has 2 scripts for config initialization:
/usr/bin/telemetry-init.sh
– generates the default configuration files if, and only if, the/opt/mellanox/doca/services/telemetry/config
folder is empty./usr/bin/enable-forward-to-morpheus.sh
– configures the destination host and port for Fluent Bit forwarding. The scripts requires that both the host and port are present, and only in this case it would start. The script overwrites the/opt/mellanox/doca/services/telemetry/config/fluent_bit_configs
folder and configures theforward.exp
file. It inputs 3 arguments:host
,port
, anddata_set
. Thedata_set
argument must be set toall_data
which signifies no data filtering.Note:Not setting
data_set
argument filters out all data from the exporter.
3.2. Enabling Fluent Bit Forwarding
If enabling Fluent Bit forwarding is desired, add the destination host and port to the command line found in the initContainers
section of the .yaml
file:
command: ["/bin/bash/", "-c", /usr/bin/telemetry-init.sh && /usr/bin/enable-fluent-forward.sh 127.0.0.1 24224 0 all_data"]
The host and port shown above are just an example and all_data
must be set as a 4th argument to allow data streaming. The 3rd parameter must be set to zero. See section Fluent Bit to learn about manual configuration.
3.3. Generating Configuration
The configuration folder /opt/mellanox/doca/services/telemetry/config
starts empty by default. Once the service starts, the initial scripts run as a part of the initial container and create configuration as described in section Enabling Fluent Bit Forwarding.
3.4. Resetting Configuration
Resetting the configuration can be done by deleting the content found in the configuration folder and restarting the service to generate the default configuration.
3.5. Disabling Providers
Disabling a provider can be done using the dts_config.ini
configuration file. Uncomment the disable-provider=$provider-name
line to disable data collection for this provider. For example, uncommenting the following line disables the ethtool
provider:
#disable-provider=ethtool
More information about telemetry providers can be found under the Providers section.
3.6. Enabling Data Write
Uncomment the following line in dts_config.ini
:
#output=/data
Changes in dts_config.ini
force the main DTS process to restart in 60 seconds to apply the new settings.
4.1. Providers
DTS supports on-board data collection from sysf, ethtool, and tc providers.
4.1.1. Sysfs Counters List
The sysfs provider has several components: ib_port, hw_port, mr_cache, and eth. By default, all the components are enabled when the provider is enabled:
#disable-provider=sysfs
The components can be disabled separately. For instance, to disable eth:
enable-provider=sysfs
disable-provider=sysfs.eth
ib_port
and ib_hvw
are state counters which are collected per port. These counters are only collected for ports whose state is active.
ib_port
counters:{hca_name}:{port_num}:ib_port_state {hca_name}:{port_num}:VL15_dropped {hca_name}:{port_num}:excessive_buffer_overrun_errors {hca_name}:{port_num}:link_downed {hca_name}:{port_num}:link_error_recovery {hca_name}:{port_num}:local_link_integrity_errors {hca_name}:{port_num}:multicast_rcv_packets {hca_name}:{port_num}:multicast_xmit_packets {hca_name}:{port_num}:port_rcv_constraint_errors {hca_name}:{port_num}:port_rcv_data {hca_name}:{port_num}:port_rcv_errors {hca_name}:{port_num}:port_rcv_packets {hca_name}:{port_num}:port_rcv_remote_physical_errors {hca_name}:{port_num}:port_rcv_switch_relay_errors {hca_name}:{port_num}:port_xmit_constraint_errors {hca_name}:{port_num}:port_xmit_data {hca_name}:{port_num}:port_xmit_discards {hca_name}:{port_num}:port_xmit_packets {hca_name}:{port_num}:port_xmit_wait {hca_name}:{port_num}:symbol_error {hca_name}:{port_num}:unicast_rcv_packets {hca_name}:{port_num}:unicast_xmit_packets
ib_hw
counters:{hca_name}:{port_num}:hw_state {hca_name}:{port_num}:hw_duplicate_request {hca_name}:{port_num}:hw_implied_nak_seq_err {hca_name}:{port_num}:hw_lifespan {hca_name}:{port_num}:hw_local_ack_timeout_err {hca_name}:{port_num}:hw_out_of_buffer {hca_name}:{port_num}:hw_out_of_sequence {hca_name}:{port_num}:hw_packet_seq_err {hca_name}:{port_num}:hw_req_cqe_error {hca_name}:{port_num}:hw_req_cqe_flush_error {hca_name}:{port_num}:hw_req_remote_access_errors {hca_name}:{port_num}:hw_req_remote_invalid_request {hca_name}:{port_num}:hw_resp_cqe_error {hca_name}:{port_num}:hw_resp_cqe_flush_error {hca_name}:{port_num}:hw_resp_local_length_error {hca_name}:{port_num}:hw_resp_remote_access_errors {hca_name}:{port_num}:hw_rnr_nak_retry_err {hca_name}:{port_num}:hw_rx_atomic_requests {hca_name}:{port_num}:hw_rx_dct_connect {hca_name}:{port_num}:hw_rx_icrc_encapsulated {hca_name}:{port_num}:hw_rx_read_requests {hca_name}:{port_num}:hw_rx_write_requests
ib_mr_cache
counters:Note:n
ranges from 0 to 24.{hca_name}:mr_cache:size_{n}:cur {hca_name}:mr_cache:size_{n}:limit {hca_name}:mr_cache:size_{n}:miss {hca_name}:mr_cache:size_{n}:size
eth
counters:{hca_name}:{device_name}:eth_collisions {hca_name}:{device_name}:eth_multicast {hca_name}:{device_name}:eth_rx_bytes {hca_name}:{device_name}:eth_rx_compressed {hca_name}:{device_name}:eth_rx_crc_errors {hca_name}:{device_name}:eth_rx_dropped {hca_name}:{device_name}:eth_rx_errors {hca_name}:{device_name}:eth_rx_fifo_errors {hca_name}:{device_name}:eth_rx_frame_errors {hca_name}:{device_name}:eth_rx_length_errors {hca_name}:{device_name}:eth_rx_missed_errors {hca_name}:{device_name}:eth_rx_nohandler {hca_name}:{device_name}:eth_rx_over_errors {hca_name}:{device_name}:eth_rx_packets {hca_name}:{device_name}:eth_tx_aborted_errors {hca_name}:{device_name}:eth_tx_bytes {hca_name}:{device_name}:eth_tx_carrier_errors {hca_name}:{device_name}:eth_tx_compressed {hca_name}:{device_name}:eth_tx_dropped {hca_name}:{device_name}:eth_tx_errors {hca_name}:{device_name}:eth_tx_fifo_errors {hca_name}:{device_name}:eth_tx_heartbeat_errors {hca_name}:{device_name}:eth_tx_packets {hca_name}:{device_name}:eth_tx_window_errors
4.1.2. Ethtool Counters
Ethtool counters is the generated list of counters which corresponds to Ethtool utility. Counters are generated on a per-device basis. See this community post for more information on mlx5 ethtool counters.
4.1.3. Traffic Control Info
The following TC objects are supported and reported regarding the ingress filters:
- Filters
- Actions
The info is provided as one of the following events:
- Basic filter event
- flower/ipv4 filter event
- flower/ipv6 filter event
- Basic action event
- mirred action event
- tunnel_key/ipv4 action event
- tunnel_key/ipv6 action event
General notes:
- Actions always belong to a filter, so action events share the filter event's ID via the
event_id
data member - Basic filter event only contains textual kind (so users can see which real life objects' support they are lacking)
- Basic action event only contains textual kind and some basic common statistics if available
4.2. Data Outputs
DTS can send the collected data to the following outputs:
- Data writer (saves binary data to disk)
- Fluent Bit (push-model streaming)
- Prometheus endpoint (keeps the most recent data to be pulled).
4.2.1. Data Writer
The data writer is disabled by default to save space on BlueField. Steps for activating data write during debug can be found under section Enabling Data Write.
The schema folder contains JSON-formatted metadata files which allow reading the binary files containing the actual data. The binary files are written according to the naming convention shown in the following example (apt install tree
):
tree /opt/mellanox/doca/services/telemetry/data/
/opt/mellanox/doca/services/telemetry/data/
├── {year}
│ └── {mmdd}
│ └── {hash}
│ ├── {source_id}
│ │ └── {source_tag}{timestamp}.bin
│ └── {another_source_id}
│ └── {another_source_tag}{timestamp}.bin
└── schema
└── schema_{MD5_digest}.json
New binary files appears when the service starts or when binary file age/size restriction is reached. If no schema or no data folders are present, refer to the Troubleshooting section.
source_id
is usually set to the machine hostname. source_tag
is a line describing the collected counters, and it is often set as the provider's name or name of user-counters.
Reading the binary data can be done from within the DTS container using the following command:
crictl exec -it <Container ID> /opt/mellanox/collectx/bin/clx_read -s /data/schema /data/path/to/datafile.bin
The path to the data file must be an absolute path.
Example output:
{
"timestamp": 1634815738799728,
"event_number": 0,
"iter_num": 0,
"string_number": 0,
"example_string": "example_str_1"
}
{
"timestamp": 1634815738799768,
"event_number": 1,
"iter_num": 0,
"string_number": 1,
"example_string": "example_str_2"
}
…
4.2.2. Prometheus
The Prometheus endpoint keeps the most recent data to be pulled by the Prometheus server and is enabled by default. To check that data is available, run the following command on BlueField:
curl -s http://0.0.0.0:9100/metrics
The command dumps every counter in the following format:
counter_name {list of label fields} counter_value timestamp
The default port for Prometheus can be changed in dts_config.ini
.
4.2.3. Configuration Details
Prometheus is configured as a part of dts_config.ini. By default, the Prometheus HTTP endpoint is set to port 9100. Comment this line out to disable Prometheus export.
prometheus=http://0.0.0.0:9100
Prometheus can use the data field as an index to keep several data records with different index values. Index fields are added to Prometheus labels.
# Comma-separated counter set description for Prometheus indexing:
#prometheus-indexes=idx1,idx2
# Comma-separated fieldset description for prometheus indexing
#prometheus-fset-indexes=idx1,idx2
The default fset index is device_name
. It allows Prometheus to keep ethtool data up for both the p0
and p1
devices.
prometheus-fset-indexes=device_name
If the fset index is not set, the data from p1
overwrites p0
's data.
For quick name filtering, the Prometheus exporter supports being provided with a comma-separated list of counter names to be ignored:
#prometheus-ignore-names=counter_name1,counter_name_2
For quick filtering of data by tag, the Prometheus exporter supports being provided with a comma-separated list of data source tags to be ignored.
Users should add tags for all streaming data since the Prometheus exporter cannot be used for streaming. By default, FI_metrics
are disabled.
prometheus-ignore-tags=FI_metrics
4.2.4. Fluent Bit
Fluent Bit allows streaming to multiple destinations. Destinations are configured in .exp
files that are documented in-place and can be found under:
/opt/mellanox/doca/services/telemetry/config/fluent_bit_configs
Fluent Bit allows exporting data via "Forward" protocol which connects to the Fluent Bit/FluentD instance on customer side. Export can be enabled manually:
- Uncomment the line with
fluent_bit_configs=
indts_config.ini
. - Set
enable=1
in required.exp
files for the desired plugins. - Additional configurations can be set according to instructions in the
.exp
file if needed. - Restart the DTS.
- Set up receiving instance of Fluent Bit/FluentD if needed.
- See the data on the receiving side.
Export file destinations are set by configuring .exp
files or creating new ones. It is recommended to start by going over documented example files. Documented examples exist for the following supported plugins:
- forward
- file
- stdout
All .exp
files are disabled by default if not configured by initContainer
entry point through .yaml
file.
To forward the data to several destinations, create several forward_{num}.exp
files. Each of these files must have their own destination host and port.
4.2.4.1. Export File Configuration Details
Each export destination has the following fields:
name
– configuration nameplugin_name
– Fluent Bit plugin nameenable
– 1 or 0 values to enable/disable this destinationhost
– the host for Fluent Bit pluginport
– port for Fluent Bit pluginmsgpack_data_layout
– the msgpacked data format. Default isflb_std
. The other option iscustom
. See section Msgpack Data Layout for details.plugin_key=val
– key-value pairs of Fluent Bit plugin parameter (optional)counterset
/fieldset
– file paths (optional). See details in section Cset/Fset Filtering.source_tag=source_tag1,source_tag2
– comma separated list of data page source tags for filtering. The rest tags will be filtered out during export.
Use #
to comment a configuration line.
4.2.4.2. Msgpack Data Layout
Data layout can be configured using .exp
files by setting msgpack_data_layout=layout
. There are two available layouts: Standard and Custom.
The standard flb_std
data layout is an array of 2 fields:
- timestamp double value
- a plain dictionary (key-value pairs)
The standard layout is appropriate for all Fluent Bit plugins. For example:
[timestamp_val, {"timestamp"->ts_val, type=>"counters/events", "source"=>"source_val", "key_1"=>val_1, "key_2"=>val_2,...}]
The custom data layout is a dictionary of meta-fields and counter fields. Values are placed into a separate plain dictionary. Custom data format can be dumped with stdout_raw
output plugin of Fluent-Bit installed, or can be forwarded with forward
output plugin.
Counters example:
{"timestamp"=>timestamp_val, "type"=>"counters", "source"=>"source_val", "values"=> {"key_1"=>val_1, "key_2"=>val_2,...}}
Events example
{"timestamp"=>timestamp_val, "type"=>"events", "type_name"=>"type_name_val", "source"=>" source_val", "values"=>{"key_1"=>val_1, "key_2"=>val_2,...}}
4.2.4.3. Cset/Fset Filtering
Each export file can optionally use one cset and one fset file to filter UFM telemetry counters and events data.
- Cset contains tokens per line to filter data with
"type"="counters"
. - Fset contains several blocks started with the header line
[event_type_name]
and tokens under that header. An Fset file is used to filter data with"type"="events"
.Note:Event type names could be prefixed to apply the same tokens to all fitting types. For example, to filter all ethtool events, use
[ethtool_event_*]
.
If several tokens must be matched simultaneously, use <tok1>+<tok2>+<tok3>
. Exclusive tokens are available as well. For example, the line <tok1>+<tok2>-<tok3>-<tok4>
filters names that match both tok1 and tok2 and do not match tok3 or tok4.
The following are the details of writing cset files:
# Put tokens on separate lines
# Tokens are the actual name 'fragments' to be matched
# port$ # match names ending with token "port"
# ^port # match names starting with token "port"
# ^port$ # include name that is exact token "port
# port+xmit # match names that contain both tokens "port" and "xmit"
# port-support # match names that contain the token "port" and do not match the "-" token "support"
#
# Tip: To disable counter export put a single token line that fits nothing
The following are the details of writing fset files:
# Put your events here
# Usage:
#
# [type_name_1]
# tokens
# [type_name_2]
# tokens
# [type_name_3]
# tokens
# ...
# Tokens are the actual name 'fragments' to be matched
# port$ # match names ending with token "port"
# ^port # match names starting with token "port"
# ^port$ # include name that is exact token "port
# port+xmit # match names that contain both tokens "port" and "xmit"
# port-support # match names that contain the token "port" and do not match the "-" token "support"
# The next example will export all the "tc" events and all events with type prefix "ethtool_" "ethtool" are filtered with token "port":
# [tc]
#
# [ethtool_*]
# packet
# To know which event type names are available check export and find field "type_name"=>"ethtool_event_p0"
# ...
# Corner cases:
# 1. Empty fset file will export all events.
# 2. Tokens written above/without [event_type] will be ignored.
# 3. If cannot open fset file, warning will be printed, all event types will be exported.
4.2.5. NetFlow Exporter
NetFlow exporter must be used when data is collected as NetFlow packets from the telemetry client applications. In this case, DOCA Telemetry NetFlow API sends NetFlow data packages to DTS via IPC. DTS uses NetFlow exporter to send data to the NetFlow collector (3rd party service).
To enable NetFlow exporter, set netflow-collector-ip
and netflow-collector-port
in dts_config.ini
. netflow-collector-ip
could be set either to IP or an address.
For additional information, refer to the dts_config.ini
file.
On top of the troubleshooting section found in the NVIDIA DOCA Container Deployment Guide, here are additional troubleshooting tips for DTS:
- For general troubleshooting, refer to the NVIDIA DOCA Troubleshooting Guide
- If the pod's state fails to be marked as "Ready", refer to the log
/var/log/syslog
. - Check if the service is configured to write data to the disk, as this may cause the system to run out of disk space.
- If
/opt/mellanox/doca/services/telemetry/data folder
contains no schema or data folder, refer to theclx.log
file:crictl exec -it <Container ID> cat /var/log/clx.log
Failed to allocate data page od size 16384…
appears in the log, it signifies that the buffer size is not big enough to fit the data.[2021-07-22 12:42:26.675] [error][data_page] Failed to allocate data page of size 16384 which is less then header size 720 + block size 30112 [2021-07-22 12:42:26.675] [error] Data page allocation failed
Increase the buffer size by modifying the buffer size line in the file:# vi /opt/mellanox/doca/services/telemetry/config/dts_config.ini
Refresh the
.yaml
file and check the data using the tree command as shown earlier. - If a PIC bus error occurs, configure the following files inside the container:
crictl exec -it <Container ID> /bin/bash # Add to /config/clx.env the following line: "export UCX_TLS=tcp "
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