A metric is a numeric representation of data measured over intervals of time. Metrics are malleable to statistical transformations such as sampling, aggregation and correlation, which make them suited to report the overall health of a system.
A trace is a representation of a series of causally related distributed events that encode information about the end-to-end request flow through a distributed system. Traces are used to identify the amount of work done at each layer in an application while preserving causality.
The main difference between metrics and traces is therefore that metrics are system-centric and traces are request-centric: metrics give you insight into how a particular system is doing, while traces help teams identify the path of requests through various services.
For most things, you likely want a metric, except for two scenarios:
- For contributors, traces are a good profiling tool
- For end-users that run complicated infrastructure, traces in the RPC component makes sense
To add metrics use the metrics
crate.
- Add the code emitting the metric.
- Add the metrics description in the crate's metrics describer module, e.g.: network metrics describer.
- Document the metric in this file.
There are three types of metrics:
- Counters: Represent (ideally) monotonically increasing values, e.g. the number of errors that have occurred, the number of blocks processed, etc.
- Gauges: Represent metrics that can go up or down arbitrarily over time. Usually they are used to measure things like resource usage (memory, CPU, ...) and throughput.
- Histograms: Used to store an arbitrary number of observations of a specific measurement, and provides statistical analysis over the observed values. A typical use case is latency of some operation (writing to disk, responding to a request, ...).
Each metric is identified by a Key
, which itself is composed of a KeyName
and an arbitrary number of Label
s.
The KeyName
represents the actual metric name, and the labels are used to further drill down into the metric.
For example, a metric that represents stage progress would have a key name of stage_progress
and a stage
label that can be used to get the progress of individual stages.
There will only ever exist one description per metric KeyName
; it is not possible to add a description for a label, or a KeyName
/Label
group.
The metrics
crate provides three macros per metric variant: register_<metric>!
, <metric>!
, and describe_<metric>!
. Prefer to use these where possible, since they generate the code necessary to register and update metrics under various conditions.
- The
register_<metric>!
macro simply creates the metric and returns a handle to it (e.g. aCounter
). These metric structs are thread-safe and cheap to clone. - The
<metric>!
macro registers the metric if it does not exist, and updates its value. - The
describe_<metric>!
macro adds an end-user description for the metric.
How the metrics are exposed to the end-user is determined by the CLI.
- Use
.
to namespace metrics- The top-level namespace should NOT be
reth
1
- The top-level namespace should NOT be
- Metric names should not contain spaces
- Add a unit to the metric where appropriate
- Use the Prometheus base units
- Do not add rate-metrics
- Rates can be calculated by e.g. Prometheus on the fly
- Avoid duplicate metrics
- An example would be adding two metrics for connections:
reth.p2p.connections
for current connections andreth.p2p.connections.total
for total connections. One of these metrics can be used to infer the other.
- An example would be adding two metrics for connections:
This list may be non-exhaustive.
stages.headers.counter
: Number of headers successfully retrievedstages.headers.timeout_error
: Number of timeout errors while requesting headersstages.headers.validation_errors
: Number of validation errors while requesting headersstages.headers.unexpected_errors
: Number of unexpected errors while requesting headersstages.headers.request_time
: Elapsed time of successful header requests
transaction_pool.inserted_transactions
: Number of transactions inserted in the pooltransaction_pool.invalid_transactions
: Number of invalid transactionstransaction_pool.removed_transactions
: Number of removed transactions from the pooltransaction_pool.pending_pool_transactions
: Number of transactions in the pending sub-pooltransaction_pool.pending_pool_size_bytes
: Total amount of memory used by the transactions in the pending sub-pool in bytestransaction_pool.basefee_pool_transactions
: Number of transactions in the basefee sub-pooltransaction_pool.basefee_pool_size_bytes
: Total amount of memory used by the transactions in the basefee sub-pool in bytestransaction_pool.queued_pool_transactions
: Number of transactions in the queued sub-pooltransaction_pool.queued_pool_size_bytes
: Total amount of memory used by the transactions in the queued sub-pool in bytestransaction_pool.blob_pool_transactions
: Number of transactions in the blob sub-pooltransaction_pool.blob_pool_size_bytes
: Total amount of memory used by the transactions in the blob sub-pool in bytes
network.connected_peers
: Number of currently connected peersnetwork.tracked_peers
: Number of peers known to the nodenetwork.pending_session_failures
: Cumulative number of failures of pending sessionsnetwork.closed_sessions
: Total number of sessions closednetwork.incoming_connections
: Number of active incoming connectionsnetwork.outgoing_connections
: Number of active outgoing connectionsnetwork.total_incoming_connections
: Total number of incoming connections handlednetwork.total_outgoing_connections
: Total number of outgoing connections establishednetwork.invalid_messages_received
: Number of invalid/malformed messages received from peersnetwork.propagated_transactions
: Total number of propagated transactions
Footnotes
-
The top-level namespace is added by the CLI using
metrics_util::layers::PrefixLayer
. ↩