Profile and control Node.js processes and clusters using StrongOps.
NOTE: This project is not released under an open source license. We welcome bug reports as we continue development, but we are not accepting pull requests at this time.
Register with StrongLoop. It's free for evaluation.
Then:
npm install -g strong-cli
slc update
cd .../where/your/app/is
slc strongops # ... provide email/password
slc run your_server.js
Go to the dashboard to see your application.
strong-agent requires an API key and application name, and will not start profiling without them.
Can be defined in:
userKey
: in profile'suserKey
argumentSTRONGLOOP_KEY
: in the environmentuserKey
: in strongloop.json (typically created withslc strongops
)
Can be defined in:
STRONGLOOP_LICENSE
: in the environmentagent_license
: in strongloop.json
Using custom metrics (the .use()
and dynamic object tracking start-stop APIs)
requires a license, please contact
[email protected].
Can be defined in:
appName
: in profile'sappName
argumentSTRONGLOOP_APPNAME
: in the environmentname
: in package.json (typical location)appName
: in strongloop.json (not typical, most package.json has aname
)
Proxy defined as protocol://[user:pass@]domain[:port]
, where protocol is one
of "http", "https", or "https+noauth". The user:pass@
is optional, as is
:port
.
Can be defined in:
proxy
: in optionshttps_proxy
,HTTPS_PROXY
,http_proxy
,HTTP_PROXY
: in the environment (lower-case proxy environment variables are traditional on some systems, and these variables may be present already if a proxy is required)proxy
: in strongloop.json
Default is none.
There is no reason to configure this, except to use HTTP instead of HTTPS if your environment prevents outgoing HTTPS.
endpoint
in optionsSTRONGLOOP_ENDPOINT
: in environmentendpoint
in strongloop.json
Default is https://
, it can be defined as http://
if necessary.
strong-agent provides hooks for integration with other metrics aggregators, like statsd. An example application can be found here.
Usage is straightforward:
require('strong-agent').use(function(name, value) {
console.log('%s=%d', name, value);
});
Names are always strings and values are always numbers. The agent reports metrics at a currently fixed interval of 60 seconds. The reported metrics are for the last interval only, i.e. they cover only the last 60 seconds. All values are for the current process only.
-
cpu.system
System CPU time. CPU time spent inside the kernel on behalf of the process, expressed as a percentage of wall clock time. Can exceed 100% on multi-core systems.
CPU time is the subset of wall clock time where the CPU is executing instructions on behalf of the process, i.e. where the process or its corresponding kernel thread is actually running.
-
cpu.total
Total CPU time. Sum of user and system time, expressed as a percentage of wall clock time. Can exceed 100% on multi-core systems.
CPU time is the subset of wall clock time where the CPU is executing instructions on behalf of the process, i.e. where the process or its corresponding kernel thread is actually running.
-
cpu.user
User CPU time. CPU time directly attributable to execution of the userspace process, expressed as a percentage of wall clock time. Can exceed 100% on multi-core systems.
CPU time is the subset of wall clock time where the CPU is executing instructions on behalf of the process, i.e. where the process or its corresponding kernel thread is actually running.
-
gc.heap.used
The part of the V8 heap that is still in use after a minor or major garbage collector cycle, expressed in bytes.
The V8 heap is where JS objects and values are stored, excluding integers in the range -2,147,483,648 to 2,147,483,647. (FIXME: exact range differs for ia32 and x64.)
-
heap.total
Total size of the V8 heap, expressed in bytes.
The V8 heap is where JS objects and values are stored, excluding integers in the range -2,147,483,648 to 2,147,483,647. (FIXME: exact range differs for ia32 and x64.)
-
heap.used
The part of the V8 heap that is currently in use. Expressed in bytes.
The V8 heap is where JS objects and values are stored, excluding integers in the range -2,147,483,648 to 2,147,483,647. (FIXME: exact range differs for ia32 and x64.)
-
http.connection.count
Number of new HTTP connections in the last interval. (FIXME: Tracks only one HTTP server per process and it's not very deterministic what server that is. Fortunately, most applications start only one server.)
-
loop.count
The number of event loop ticks in the last interval.
-
loop.minimum
The shortest (i.e. fastest) tick in milliseconds.
-
loop.maximum
The longest (slowest) tick in milliseconds.
-
loop.average
The mean average tick time in milliseconds.
-
messages.in.count
-
messages.out.count
-
<probe>.count
-
<probe>.average
-
<probe>.maximum
-
<probe>.minimum
The agent collects count, average, maximum and minimum metrics for several popular third-party modules. The list of supported modules and recorded metrics are as follows:
module | metric |
---|---|
http | request time in ms |
leveldown | query time in ms |
loopback-datasource-juggler | query time in ms (reported as dao.<metric> ) |
memcache | query time in ms (reported as memcached.<metric> ) |
memcached | query time in ms |
mongodb | query time in ms |
mysql | query time in ms |
oracle | query time in ms |
oracledb | query time in ms (reported as oracle.<metric> ) |
postgres | query time in ms |
redis | query time in ms |
riak-js | query time in ms (reported as riak.<metric> ) |
strong-oracle | query time in ms (reported as oracle.<metric> ) |
Metrics are reported once per time interval. Modules that have more than one command or query method have query times for their individual methods summed.
For example, the oracle modules have .execute()
, .commit()
and
.rollback()
methods. The reponse times for those methods are summed and
reported as one metric, where:
oracle.count
is the number of calls in the last intervaloracle.average
the mean average query response timeoracle.maximum
the slowest query response timeoracle.minimum
the fastest query response time
Future agent releases will also report metrics for individual methods.
The agent can optionally track the creation and reclamation of JS objects over time. Tracking objects is an indispensable tool for hunting down memory leaks but as it imposes some CPU and memory overhead, it's disabled by default.
-
agent.metrics.startTrackingObjects()
Start tracking objects.
Object tracking works by taking snapshots of the JavaScript heap at times
t0
andt1
, then calculating their set difference and intersection. To a first approximation, memory overhead isO(n)
and computational complexityO(n * lg n)
, wheren
is the number of objects in the snapshots. -
agent.metrics.stopTrackingObjects()
Stop tracking objects. No further metrics will be reported.
When enabled, the following metrics are reported at 15 second intervals:
-
object.<type>.count
The number of objects created and reclaimed of type
<type>
in the last interval.<type>
is the name of the constructor that created the object, e.g.Array
,Date
, etc.If the count is less than zero, it means more objects have been reclaimed than created.
Due to a known bug in the version of V8 that is bundled with node.js v0.10, it is possible that the reported number is slightly lower than the actual instance count. Node.js v0.11 and newer are not affected.
-
object.<type>.size
The total size of the objects created and reclaimed of type
<type>
in the last interval.<type>
is the name of the constructor that created the object, e.g.Array
,Date
, etc.If the size is less than zero, it means more objects have been reclaimed than created.
The agent has a built-in CPU profiler that produces output in a format that can be imported into the Chrome Developer Tools. The profiler is available with Node.js v0.11 and up. Reduced functionality is available with Node.js v0.10; top-level and bottom-up views work, chart and timeline views don't.
-
agent.metrics.startCpuProfiling()
- Start the CPU profiler. Throws an Error when the CPU profiler is unavailable.Calling this method multiple times is mostly harmless: the first call starts the profiler, successive calls are no-ops.
-
agent.metrics.stopCpuProfiling()
- Stop the CPU profiler. Returns the CPU profiler information as a JSON string that can be saved to disk for further inspection. Throws an Error when the CPU profile is unavailable, or has not been started.The filename must have a
.cpuprofile
suffix in order for the Chrome Developer Tools importer to recognize it.
Example usage:
// Start collecting CPU profile traces whenever the
// average event loop tick time exceeds 100 ms.
var agent = require('strong-agent');
var fs = require('fs');
var profiling = false;
agent.use(function(name, value) {
if (name !== 'loop.average') return;
if (value > 100) {
if (profiling === true) return;
agent.metrics.startCpuProfiling();
profiling = true;
} else if (profiling === true) {
var filename = 'CPU-' + Date.now() + '.cpuprofile';
var data = agent.metrics.stopCpuProfiling();
fs.writeFileSync(filename, data);
profiling = false;
}
});
Custom metrics can be injected dynamically into running node processes, and will be reported via the Metrics API.
Currently, custom metrics can only be injected by using the command line, slc runctl patch ...
, see strong-supervisor for information on how to call it.
Supported metrics are counts and timers.
Counts can be incremented and decremented, and require no context.
Timers have a start, and a stop, and require a unique context capable of having a timer property created.
Patch files are JSON descriptions of a patch set. A patchset is:
{
FILESPEC: [
PATCH,
...
],
...
}
The FILESPEC
is a regex string long enough to uniquely match a script name.
index.js
is unlikely to be unique, your-app/index.js
is probably unique.
Note that the script names matched against are fully qualified when they were
required (so lengthening the file path can always result in a unique spec), and
short when builtin to node (^util.js$
).
A file may have multiple patches applied. A patch is:
{
type: TYPE,
line: LINE,
metric: METRIC,
[context: CONTEXT,]
}
TYPE
is one of:
- increment: increment the metric count
- decrement: decrement the metric count
- timer-start: start a metric timer
- timer-stop: stop a metric timer
LINE
is the line number (the first line is line number 1
) at which the
metrics code will be inserted.
METRIC
is a dot-separated metric name. It will have custom.
prepended to
avoid conflict with built-in metric names, and will have either .count
or
.timer
appended (as appropriate), to indicate the type.
CONTEXT
is a javascript expression that must result in an object that can
have a timer property created on it.
With the following code in file path/to/your-app/index.js
:
// save as `dyninst-metrics-example.js`
var http = require('http');
http.createServer(request).listen(process.env.PORT || 3000);
function request(req, res) {
setTimeout(function() { // line 7
res.end('OK\n'); // line 8
}, Math.random() > 0.1 ? 10 : 100);
}
The above can be patched to keep a count of concurrent requests and a timer for
each request by passing the following patch.json
to slc runctl patch
:
{
"dyninst-metrics-example.js": [
{ "type": "increment", "line": 7, "metric": "get.delay" },
{ "type": "decrement", "line": 8, "metric": "get.delay" },
{ "type": "timer-start", "line": 7, "metric": "get.delay", "context": "res" },
{ "type": "timer-stop", "line": 8, "metric": "get.delay", "context": "res" }
]
}
In order to design your patch set, consider what the effect of the patch insertion will be. Patches must be lexically valid at the insertion point, which is always the beginning of the line. The above patch set will, conceptually, result in the patched file looking like:
// save as `dyninst-metrics-example.js`
var http = require('http');
http.createServer(request).listen(process.env.PORT || 3000);
function request(req, res) {
res.___timer = start('get.delay');increment('get.delay'); setTimeout(function() { // line 7
res.___timer.stop();decrement('get.delay'); res.end('OK\n'); // line 8
}, Math.random() > 0.1 ? 10 : 100);
}
Note from the above:
- Patches must by valid when inserted at the beginning of the specified line.
- Patches can be cumulative, and previous patches don't change the line numbering of the file.
- The context is used to store a timer on start, that can be accessed on stop. The context expression does not have to be identical for start and stop, but must evaluate to the same object.
- Duplicate stops as well as non-existence of a timer are ignored.
- Metrics can have the same name, since the type is appended.