Metrics (deprecated)
Note
The metrics solution based on this documentation has been retired. We're actively developing a new solution that will make tracking and debugging any issues in your application easier. Learn more.
Sentry supports the emission of pre-aggregated metrics information via the statsd envelope item. This emission bypasses relay-side sampling and assumes a client side aggregator. In the product these are referred to as "custom metrics" and internally the system sometimes carries the name "DDM". The functionality sits on top of the generics metrics platform which is also used for span and transaction level metrics.
These metrics are considered "trace seeking" which means that they should attempt to establish a relationship to the current span or trace.
Custom metrics are sent into the custom namespace in the generic metrics platform. The features exposed from the generic metrics platform to the SDKs are all metric types (counters, distributions, gauges and sets). SDKs are required to perform local aggregation unless they perform on-shot emissions.
Metrics are aggregated into a process wide aggregator which is required to flush in intervals that are reasonable for the SDK. These aggregations are lossless (unless the metric type is already lossy which for instance applies to sets and gauges) and are required to support tags. The following general guidelines exist:
- 10 Second Bucketing: SDKs are required to bucket into 10 second intervals (rollup in seconds) which is the current lower bound of metric accuracy.
- Flush Shift: SDKs are required to shift the flush interval by
random() * rollup_in_seconds. That shift is determined once per startup to create jittering. - Force flush: an SDK is required to perform force flushing ahead of scheduled time if the memory pressure is too high. There is no rule for this other than that SDKs should be tracking abstract aggregation complexity (eg: a counter only carries a single float, whereas a distribution is a float per emission). For Mobile SDKs, where a low memory footprint is crucial, the recommendation is to use a maximum memory footprint of around 10 KiB for metrics, which requires the SDKs to force flush for around every 1000 SetMetric entries, for example.
- Background Aggregation: SDKs are encouraged to defer flushing and aggregation into a background thread. For SDKs where
fork()is to be expected, the background thread needs to ensure it restarts after fork (eg: python). - Tagging: metrics can be tagged with a unique key and an optional value for each key. Both keys and values are limited to strings, but the SDK can expose other types if it has a reasonable way to stringify these.
In abstract terms the aggregator is recommended to look a bit like this:
class Aggregator:
def __init__(self):
self.buckets = {}
def get_bucket(self, ts):
return self.buckets.setdefault(ts // 10, {})
def add(self, type, key, value, unit, tags):
mri = "%s:%s" % (type, key)
Normalization shall be done for statsd envelope items with unicode support if possible:
- Metric Name: Regex
[^a-zA-Z0-9_\-.]+with replacement character_. - Metric Namespace and Unit: Regex
[^a-zA-Z0-9_]+with no replacement character. - Metric Tag Key: Regex
[^a-zA-Z0-9_\-.\/]+with no replacement character. - Metric Tag Value: See below.
Tag Values support the full UTF-8 character range, except for control characters. Reserved characters for Tag Values are \n, \r, \t, \, |, ,. The replacement map is as follows.
| Character | Replacement |
|---|---|
Line Feed (<LF>) | \n |
Carriage Return (<CR>) | \r |
Tab (<HT>) | \t |
Backslash (\) | \\ |
Pipe (|) | \u{7c} |
Comma (,) | \u{2c} |
The lengths of the following components of the statsd envelope items should be limited:
- Metric Name: 150 characters.
- Metric Unit: 15 characters.
SDKs should permit any string unit, but some of them are known to the system and will in the future permit recalculations. They are documented as part of relay: MetricUnit.
When a metric is emitted it shall either determine the current span (span seeking) or create a new span (span creating).
In span seeking mode, the span is determined based on the current span on the scope. APIs such as .increment(), .distribution(), .gauge() and .set() operate in span seeking mode.
In span creating mode a new active span is started. The .timing() API operates in span creating mode.
In span creating mode the span should be setup the following way:
span.op = "metric.timing"span.description = key(the metric key)- the metric tags should be applied to the span as well
- the span is finished once the timing callback finishes
From there two things shall be happening unless they are disabled:
- Common tag attaching: the tags
transaction,releaseandenvironmentshall be automatically added to the metric. - Span local aggregation: the metric shall be attached to the determined span as a local summary (a form of gauge). For more information see below.
API wise the SDKs are required to expose static metric functions which are to be defined in a metrics module. This also documents the aggregation state for each metric type. They are constructed with an initial value, have an add method to add another value and a serialize method that returns the values for the final emission as array.
The following attributes are common for all metrics. These should be emitted via keyword arguments, some configuration struct or whatever is reasonable in the target language.
key: the name of the metric. SDKs are required to normalize this name.value: the value to be emitted, this is specific by metric type.unit: the unit for the metric, see below.tags: a dictionary or list of tuples of tags and their values.stacklevel: a utility attribute for SDKs where n stack level shall be ignored for code location recording. In languages that have better facilities this can be removed.
On a span every metric is aggregated as a gauge. For each metric the following attributes are retained per span:
min: the minimum value observed.max: the maximum value observed.count: the number of emissions.sum: the sum of all values.tags: the metric tags and their values.
The local aggregator behaves as such:
class LocalAggregator:
def add(self, type, value, value, unit, tags):
# Assumes sorted tags
bucket_key = ("%s:%s@%s" % (ty, key, unit), tags)
old = self._measurements.get(bucket_key)
if old is not None:
v_min, v_max, v_count, v_sum = old
v_min = min(v_min, value)
v_max = max(v_max, value)
v_count += 1
v_sum += value
else:
v_min = v_max = v_sum = value
v_count = 1
self._measurements[bucket_key] = (v_min, v_max, v_count, v_sum)
Counters (c) have a single method for emission:
increment(key, value: int | float = 1.0, unit = "none", ...): increments the given key by one in the bucket.
Aggregation state:
class Counter:
def __init__(self, initial):
self.value = initial
def add(self, value):
self.value += value
def serialize(self):
return [self.value]
Span aggregation: the value is added to the span local aggregator.
A distribution (d) holds all values observed. There are multiple methods that shall exist on an SDK to support common use cases. The basic way to emit a distribution is the low level distribution function, higher level methods depend on the facilities in the language.
distribution(key, value: int | float, unit = "none", ...): emits a single value into a distribution.
For languages with context managers (eg: with in Python):
timing(key, ...): this shall measure the time of a code block and emit the measured time as distribution with a time unit (second,millisecond, etc.). The default unit shall besecondin current SDKs as we are not yet normalizing values on the server.
For languages with lambda callback patterns (eg: timed(() => { ... })):
timing(key, ..., callback): this shall measure the time of the invoked lambda and emit the measured time as distribution with a time unit (second,millisecond, etc.). The default unit shall besecondin current SDKs as we are not yet normalizing values on the server.
For languages with decorators:
@timing(key, ...)or@timed(key, ...): Can be used to annotate a function so that every time it is invoked, a timing is emitted.
Aggregation state:
class Distribution:
def __init__(self, initial):
self.values = [initial]
def add(self, value):
self.values.append(value)
def serialize(self):
return self.values
Span aggregation: the value is added to the span local aggregator.
Gauges (g) are often also called "summaries" as they are similar in nature to distributions, but somewhat lossy. They are however emitted per span when metric summaries are enabled. As they are hard to aggregate across different emitters they can be tricky to use properly in practice.
They are emitted by a single function called gauge:
gauge(key, value: int | float, unit = "none", ...): emits a single value into the gauge.
Aggregation state:
class Gauge:
def __init__(self, initial):
self.last = initial
self.min = initial
self.max = initial
self.sum = initial
self.count = 1
def add(self, value):
self.last = value
self.min = min(self.min, value)
self.max = max(self.max, value)
self.sum += value
self.count += 1
def serialize(self):
return (
self.last,
self.min,
self.max,
self.sum,
self.count,
)
Span aggregation: the value is added to the span local aggregator.
Sets (s) are used to count unique members. SDKs are supposed to accept integers and strings at least, but they are encouraged to use CRC32 to fold them into a 32bit integer. As such the aggregation state is partially lossy.
They are emitted with a single method:
set(key, value: int | string, unit = "none", ...): marks a single value to be in the set.
Aggregation state:
class Set:
def __init__(self, initial):
self.value = {initial}
def add(self, value):
self.value.add(value)
def serialize(self):
def _hash(x):
if isinstance(x, str):
return crc32(x.encode("utf-8")) & 0xFFFFFFFF
return int(x)
return [_hash(value) for value in self.value]
Span aggregation: the value 1 is added to the span local aggregator for new members.
Metrics are emitted in regular flush intervals (every 5 seconds, with a random offset that is determined once per startup) as envelope items. The item type is statsd and the serialization format is statsd compatible. Unlike normal statsd, more than one value can be emitted separated by a colon. These values are the results of calling serialize or similar on the aggregation state.
The format is documented as part of relay: relay_metrics.
Additionally metric summaries retained on the spans shall be emitted as _metrics_summary on the metrics as documented by this RFC: RFC-0123.
SDKs are encouraged to provide a before_emit_metric callback allowing developers to discard a metric from being emitted and later aggregated. The provided parameters are the metric key and the tags. The callback either returns True or False, indicating if the metric should be emitted or not.
def before_emit_metric(key, tags):
if key in ["metric_a", "metric_b"]:
return False
return True
sentry_sdk.init(
_experiments={
"enable_metrics": True,
"before_emit_metric": before_emit_metric
}
)
Additionally SDKs are encouraged to capture location information once per metric. At metric emission time the system shall be collecting which code location emitted a metric and retain it. For that the same format as for the frame on the stacktrace shall be used. stacklevel number of frames shall be ignored.
The meta data is emitted in JSON as envelope item called metric_meta:
{
"timestamp": 1701743645,
"mapping": {
"encoded_mri": [
{
"type": "location",
"filename": "..."
}
]
}
}
Today only code mappings are supported. Each key is an encoded MRI (eg: c:custom/foo@none), each value in the mapping array has a key called type which today can only be "location". All other keys are the same format as the frame on the stacktrace. Today SDKs should send code locations at least once a day, and they can round the timestamp.
The Python SDK holds a reference implementation in the metrics.py module for the full feature set: metrics.py.
Our documentation is open source and available on GitHub. Your contributions are welcome, whether fixing a typo (drat!) or suggesting an update ("yeah, this would be better").